The Worst Things in Life are Free: The Role of Free Heme in Sickle Cell Disease

Abstract

Hemolysis is a pathological feature of several diseases of diverse etiology such as hereditary anemias, malaria, and sepsis. A major complication of hemolysis involves the release of large quantities of hemoglobin into the blood circulation and the subsequent generation of harmful metabolites like labile heme. Protective mechanisms like haptoglobin-hemoglobin and hemopexin-heme binding, and heme oxygenase-1 enzymatic degradation of heme limit the toxicity of the hemolysis-related molecules. The capacity of these protective systems is exceeded in hemolytic diseases, resulting in high residual levels of hemolysis products in the circulation, which pose a great oxidative and proinflammatory risk. Sickle cell disease (SCD) features a prominent hemolytic anemia which impacts the phenotypic variability and disease severity. Not only is circulating heme a potent oxidative molecule, but it can act as an erythrocytic danger-associated molecular pattern (eDAMP) molecule which contributes to a proinflammatory state, promoting sickle complications such as vaso-occlusion and acute lung injury. Exposure to extracellular heme in SCD can also augment the expression of placental growth factor (PlGF) and interleukin-6 (IL-6), with important consequences to enthothelin-1 (ET-1) secretion and pulmonary hypertension, and potentially the development of renal and cardiac dysfunction. This review focuses on heme-induced mechanisms that are implicated in disease pathways, mainly in SCD. A special emphasis is given to heme-induced PlGF and IL-6 related mechanisms and their role in SCD disease progression.

Introduction

Sickle Cell Disease (SCD) is an inherited hematological disorders, with a multi-organ complication affecting millions of people worldwide, especially in sub-Saharan Africa (1). In the United States, there are about 100,000 people with SCD. There are variability and often concurrent complications related to the disease, which may differ in frequency and severity. Accumulating evidence suggests that intravascular hemolysis and hemolysis byproducts including hemoglobin and heme instigate a series of events leading to vascular damage. While hemolysis is a prominent feature of SCD, it is certainly not unique to this disease. Red cell destruction may occur as a result of a hereditary hemolytic disorder, an infection, a medication, cancer, an autoimmune disorder, a cardiomyopathy, a hemorrhagic stroke, trauma or even a blood transfusion, to mention a few (2). The current review focuses on the heme-induced mechanisms that are implicated in disease pathways, mainly in SCD and downstream effects of non-bound (free) heme as a result of intravascular hemolysis caused by sickle cell anemia and other hemolytic disorders (Figure 1).

Figure 1

Heme as a Signaling Molecule in Normal Physiology

Heme synthesis, transport and turnover occurs under normal physiological conditions, and it exerts a physiological signal that helps to control these pathways. For example, heme feeds back to the first committed step in porphyrin synthesis, α-levulinic acid synthase. Heme regulates the Ras-Mitogen Activated Protein Kinase (MAPK) pathway, and it regulates the BACH1 transcriptional repressor, impacting expression of HMOX-1 and β-globin. Heme-regulated inhibitor (HRI) is a eukaryotic initiation factor 2α kinase that coordinates protein synthesis with heme availability in reticulocytes (3). Heme is a crucial prosthetic group for activity of many hemoproteins, include oxygen transport, electron transport, oxygen reduction, and others (4). Heme modulates macrophage differentiation of monocytes to tissue-resident macrophages and stimulates macrophage inflammatory response (5). In sickle cell disease, heme from red cells is turned over via both intravascular and extravascular hemolysis pathways that leads to extensive pathology described in the remainder of this review.

Oxidative Stress and Hemolysis in Sickle Cell Disease

Reactive Oxygen Species Production in SCD Contributes to Hemolysis

Oxidative stress occurs due to dysregulation between production of reactive oxygen species (ROS) and antioxidants. ROS are vital for cell signaling and homeostasis and are produced as a natural by-product of the normal metabolism of oxygen or exogenously by ionizing radiation and xenobiotic compounds (6–8). Oxidative stress contributes to pathophysiological pathways that underlie inflammation in many hemolytic disorders including SCD (8), β-thalassemia (9, 10), paroxysmal nocturnal hemoglobinuria (11, 12), hereditary spherocytosis (13), and glucose-6-phosphate dehydrogenase deficiency (14–16). RBCs are constantly subjected to oxidative stress due to their role as an oxygen transporter and continuous exposure to both endogenous and exogenous sources of ROS that can damage the RBC and alter blood rheology in SCD patients (17, 18). ROS is generated in SCD through several pathways. Sickle hemoglobin (HbS) produces ROS such as superoxide anion (O2^-), hydrogen peroxide (H₂O₂), peroxynitrite (OONO^-) and hydroxyl radical (OH.) following auto-oxidation (19). Auto-oxidation is a normal physiological process that generates methemoglobin (metHb, Hb oxidized to Fe³⁺ state with no ability to bind O₂) and in about 3% of the total Hb every day (19). A small rate of auto-oxidation can produce substantial levels of ROS due to the high concentration of oxygenated Hb (about 5 mM), which can cause enormous damage to the RBC itself, because RBCs make up 40% of the blood volume (20). Moreover, O2^- is spontaneously converted to H₂O₂ by superoxide dismutase, thereby increasing ROS in the system (19). Excessive amounts of reactive oxygen metabolites is produced due to the unstable nature of HbS resulting in conformational change in the Hb in low O₂ environment and the continuous auto-oxidation of iron in heme released from Hb (6–8). This heme can oxidize membrane lipids and proteins (21), as evidenced by elevated levels of products of lipid peroxidation including malondialdehyde (MDA) in the plasma of SCD patients (22). Other Hb oxidation products such as ferryl Hb which is also formed in RBCs under conditions of oxidative stress also occurs in HbS (23–25), causing actin remodeling, thereby compromising membrane integrity and transport (26, 27).

Mitochondrial Dysfunction

The major source of intracellular ROS is the mitochondria in most cells (28) but mature red blood cells (RBCs) from healthy individuals extrude their mitochondria and other organelles during the terminal process of erythropoiesis (29–32). In contrast, a higher percentage of mature RBCs from SCD patients and mice retain their mitochondria leading to excessive ROS accumulation and oxidative stress (25, 33, 34). It has been shown that treatment with products of hemolysis including ferric Hb, ferryl Hb or heme causes bioenergetics changes, abnormal membrane permeability and ROS-induced lipid peroxidation in endothelial and alveolar cells mitochondria (35, 36), which may contribute to inflammatory process and lung injury (37, 38). Additionally, platelets from SCD patients have abnormal mitochondrial activity resulting in oxidant generation and increased activation during vaso-occlusive crisis (VOC) (39). Exposure to cell-free hemoglobin exacerbates this aberrant platelet mitochondrial activity and correlates with markers of hemolysis, NO scavenging and severity of pulmonary arterial hypertension (40).

Microparticles

Another source of oxidative stress in SCD is erythrocyte-derived submicron membrane vesicles called microparticles (eMPs) (41–44). Plasma eMPs are elevated in sickle cell mice (25), in SCD patients at steady state (41, 44) and during vaso occlusive crisis (45, 46). These eMPs are generated during reoxygenation of sickled erythrocyte (42, 43) or during hemolysis (41, 47). Additionally, thrombospondin-1 (TSP1) may trigger shedding of phosphatidylserine positive eMPs and injection of these eMPs into SCD mice caused vaso occlusion in the kidney (48). These hemoglobin-laden eMPs can transfer heme to endothelial cells, adhere to vascular endothelium and scavenge NO thereby mediating oxidative stress (49–51). Staining of human renal biopsies has been shown to contain hemoglobin-laden eMPs adherent to the capillary endothelium in kidney tissue samples from hyperalbuminuric SCD patients, suggesting that eMPs may contribute to renal injury in SCD (51). Finally, other blood cells such as neutrophils and macrophages also release ROS into the plasma which are neutralized by anti-oxidants such as superoxide dismutase before they can be taken up by RBCs (52).

Nicotinamide Adenine Dinucleotide Phosphate Oxidases

Vascular smooth muscle and phagocytic cells express nicotinamide adenine dinucleotide phosphate (NADPH) oxidases, which can generate endogenous ROS (53). NADPH oxidase activity is mediated by activation of the small Ras-like GTPase Rac via protein kinase C (PKC) stimulation (53). Some plasma factors such as transforming growth factor β1 (TGFβ1) and endothelin-1 (ET-1) have also been shown to stimulate NADPH oxidase activity in neutrophils, monocytes and endothelial cells and many of these factors are present at higher levels in the plasma of SCD patients as a result of persistent inflammatory state associated with SCD (54). RBCs from SCD patients also contain NADPH oxidases, which can generate endogenous ROS, thereby contributing to RBC rigidity and fragility (55).

Oxidant–Antioxidant Balance

Accumulation of oxidative injury to the erythrocyte distorts membrane integrity, alters blood flow rheology, membrane transport abnormalities, exposure of phosphatidylserine, and cell death (56–58). Despite the numerous pathways by which ROS is generated in SCD, oxidative stress in patients appears to be compensated at steady state, and only becomes deleterious when the balance between ROS production and antioxidants is perturbed due to excessive ROS generation, low antioxidant levels or during crisis (59). Likewise, ROS production becomes markedly amplified in low antioxidant microenvironments, as found in SCD, resulting in damage of macromolecules including lipids (60, 61), DNA (62, 63), and proteins (64, 65).

However, studies of antioxidant levels in SCD patients have yielded variable results, with several studies reporting low (66–69) and others reporting high levels (70, 71) of activity of antioxidant enzymes including glutathione peroxidase (66, 67), superoxide dismutase (67, 70, 72), and catalase (68, 72). These differences may be due to variations in level of disease severity including hemolysis, lipid peroxidation, VOC, acute splenic sequestration and pulmonary hypertension reported in these patients (73–78). Irrespective of the levels detected, the total antioxidant capacity in SCD patients is insufficient to neutralize excess ROS, resulting in oxidative stress (79). Other non-enzymatic antioxidants such as vitamin C and E (80, 81), zinc (76), and selenium (69, 77, 80) are also decreased in SCD patients.

Several approaches to mitigate the harmful effects of oxidative stress in SCD have been proposed such as use of antioxidants (82), neutralization of products of hemolysis with haptoglobin (Hp) and hemopexin (Hpx) (83) and moderate strength and endurance exercise therapy (84). Recent studies showed that increase in physical activity improves blood rheology, increases NO bioavailability and reduction in oxidative stress and hemolysis in mice (85–87) and SCD patients (88).

Intravascular Hemolysis, Free Hemoglobin, and NO Deficiency

Intravascular and extravascular hemolysis, due in large part to recurrent sickling and unsickling and oxidative stress discussed above, causes premature destruction of RBCs, and contributes to anemia in SCD (56, 89). Rapid production of RBCs ensues to compensate for anemia, resulting in an increased proportion of reticulocytes and younger RBCsin the circulation. Younger RBCs have a higher content of arginase, and with lysis of these younger cells, arginase is released into the plasma during hemolysis (90). This ectopic plasma arginase consumes plasma L-arginine (substrate needed for NO production), and together with consumption of endothelial NO by cell-free plasma Hb contributes to decreased NO bioavailability (91–93). Although consequences of hemolysis in SCD are multifactorial, induction of NO deficiency and oxidative stress by acute and chronic release of products of hemolysis into circulation are major sequelae of hemolysis (94). Depletion of NO promotes a chronic vasculopathy endophenotype that predisposes to pre-capillary pulmonary hypertension, leg ulceration, cerebrovascular arteriopathy, chronic kidney disease and priapism. Details of nitric oxide deficiency and pulmonary hypertension are beyond the scope of this review and have been reviewed in detail elsewhere (94–96).

Compensatory Mechanisms

Several distinct and overlapping mechanisms have evolved to mitigate the cytotoxic effect of products of hemolysis. Hb dimers are avidly bound by the serum glycoprotein haptoglobin (Hp), in the plasma to form Hb-Hp complex, which protects against oxidative damage (97–100). The Hb-Hp complex is recognized and internalized via its receptor, CD163, and subsequently cleared by the phagocytic cells in the reticuloendothelial system (97–99). Continuous formation of Hb-Hp complexes in diseases with severe intravascular hemolysis including SCD and paroxysmal nocturnal hemoglobinuria results in depletion of Hp to undetectable levels, leading to some accumulation in plasma of cell-free Hb (101, 102).

Heme Scavenging Proteins

Cell-free Hb that becomes oxidized or denatured prior to clearance is prone to release free heme. Plasma free heme becomes elevated in SCD patients (103, 104). About 80% of total heme initially binds to plasma lipoproteins including low-density lipoproteins (LDLs) (105, 106) and high-density lipoproteins (HDLs) (107, 108), before being transferred to albumin and Hpx (107, 109). Low levels of these lipoproteins are reported in SCD patients which may be due to increased catabolism or decreased synthesis (110, 111), as low plasma levels also negatively correlated with markers of hemolysis in SCD patients (112–114). Free heme reversibly binds to albumin to form metalbumin (115–117), or with high affinity to hemopexin (Hpx) (118, 119), and α1-microglobulin (120–122).

Hemopexin

Of all these plasma proteins, Hpx, a plasma glycoprotein produced in the liver has the highest affinity for binding free heme (118, 119, 123), resulting in the formation of Hpx-heme complexes that are removed by endocytosis via the Hpx receptor (CD91) in hepatocytes and macrophages (124, 125). After delivering heme to CD91-expressing cells for internalization and degradation by heme oxygenase 1 (HMOX-1), at least some of the Hpx molecules can be recycled back into plasma. Elevated eMPs also correlated with increase in hemolysis markers and low Hpx in SCD patients (126). In the same patients cohort, high eMPs positively correlated with elevated TRV, linking Hpx depletion to increased eMPs and hemolysis, which may predispose patients to pulmonary hypertension (126). In another study, low Hpx negatively correlated with lipid oxidation in human and mice with SCD, with postmortem analysis in SCD patients showing oxidized LDL deposits in the pulmonary artery (127). These reports showed that delayed clearance of heme in circulation due to low plasma Hpx may activate deleterious downstream pathological pathways that may contribute to morbidity and mortality in SCD patients.

Heme Oxygenase-1

HMOX-1 is an evolutionarily conserved and rate limiting enzyme that degrades heme into equimolar amount of iron, biliverdin and carbon monoxide (108, 128, 129). HMOX-1 is highly expressed in human and mice with SCD and further upregulated on exposure to heme (130, 131). Heme-induced oxidative stress exceeds the capacity of HMOX-1 to prevent cellular and organ injury in transgenic murine model of SCD. Augmentation of HMOX-1 level and activity via gene transfer approaches, or pharmacological activation through NRF2 (132), the transcription factor that regulates HMOX-1 expression, conferred protection from heme-induced lung injury (133), vaso-occlusion (134), liver injury (135), kidney injury (136), erythrocyte membrane damage (137), endothelium activation and adherence (135), activation of immune cells and production of inflammatory cytokines (138). Still, the effect of NRF2 activation on hemolysis, γ-globin levels or stress erythropoiesis in mouse model of SCD is controversial (136–138). Not all heme and Hb are bound to proteins or other macromolecules. Unbound heme or hemoglobin in circulation causes erythrocyte membrane damage and injury, activates proinflammatory signaling pathways in RBCs, immune and endothelial cells, hepatocytes, macrophages and neutrophils (105, 139).

Antioxidant Enzymes

Heme induces a program of antioxidant enzymes that compensate for its intrinsic oxidant stress. These include glutathione S-transferase pi (GSTpi) and NAD(P)H dehydrogenase [quinone] 1 (NQO1) (140).

Heme and Sterile Inflammation in Sickle Cell Disease

Hemolysis is a major driver of sterile inflammation in pathological conditions including SCD (94, 103, 141), malaria (142, 143), sepsis (144, 145), and also a marker of severity and survival in these patients (146–149). Following hemolysis, Hb is oxidized to unstable methemoglobin resulting in release of free heme (139), which can intercalate into cell membrane and alter cellular structures or taken up by cells (150, 151).

Intravascular Hemolysis Releases Cell-Free Heme

Free heme accumulates in the plasma in both acute and chronic hemolysis when the rate of intravascular hemolysis exceeds the capacity of circulating heme-binding proteins (152), including Hp and Hpx, which are depleted in human and mice with SCD patients (59, 104, 114, 126, 127, 153–156). There is an emerging concept of small molecular weight scavenging protein such as α1-microglobulin, becoming the predominant heme scavenger when plasma Hpx is low (59). Binding of free heme to different scavenger impacts clinical manifestation of excess heme in circulation as heme-Hpx is trafficked to and recycled primarily in the liver while heme-bound α1-microglobulin are taken to the kidney (59). This phenomenon was demonstrated in a recent publication from Ofori-Acquah and colleagues. They showed that hemopexin deficiency correlates with a compensatory increase in α1-microglobulin in both human and mice with SCD (155). Elevated α1-microglobulin and low hemopexin was also associated with increase in acute kidney injury biomarkers urinary KIM-1 and serum NGAL in SCD patients. The authors showed that this heme-bound α1-microglobulin is directed to the kidney for clearance resulting in acute kidney injury in sickle cell mice (155). Also, acute kidney injury may occur via complement deposition in the kidney during intravascular hemolysis and in Hpx deficient condition in SCD mice (157). Patients with SCD with higher plasma levels of free heme also have greater frequency of VOC and acute chest syndrome (158). Accumulation of free heme in plasma is not only cytotoxic, but also mediates generation of free radicals via the Fenton pathway (159–161).

Detection of Heme and Hemoglobin

Assay of cell-free heme and Hb may be an important tool for diagnosis in disease conditions characterized by hemolysis (152, 162). Accurate quantification of heme species may result in early therapeutic intervention before irreversible damage to organs occurs. Currently, most commercially available assays measure total heme (free heme and heme bound to proteins) and are not specific for measuring cell-free heme or Hb. There is a possibility of overestimating or underestimating these heme species. Moreover, free heme is likely a more potent mediator of organ injury and signal transductions, its accurate quantification as a biomarker in disease conditions may be vital. Researchers have developed detection methods using the spectral deconvolution method, antibody capture ELISA or western blotting, reversed‐high‐performance liquid chromatography, and fluorescence-based assays to measure Hb and CFH (103, 152, 162–165). Although these are not commercially available currently, they present an opportunity to quantify different heme species in relation to pathogenesis and therapeutic efficacy in hemolytic conditions.

Cell-Free Heme in Inflammation

Free heme can induce inflammation via direct activation of RBCs (166, 167), macrophages (168–170), neutrophils (171), and endothelial cells (139, 172–174) to secret proinflammatory cytokines including toll-like receptors (TLRs), tumor necrosis factor (TNF), interleukin-6 (IL-6), placenta growth factor (PlGF), interleukin 1 beta (IL-1β) (105, 139, 169, 175, 176) and release of erythroid damage-associated molecular patterns (eDAMPs) that potentiates inflammation (177, 178). Heme has been shown to induce production of IL-1β by activated monocytes/macrophages, endothelial and smooth muscle cells through a nucleotide-binding domain and leucine-rich repeat-containing protein 3 (NLRP3) inflammasome dependent mechanism (139, 169, 172). High mobility group box 1 (HMGB1), a nuclear protein released during systemic inflammatory response, has also been shown to mediate ROS-dependent activation of endothelial cells to secrete IL-1β via NLRP3 activation (179, 180). Elevated circulating HMGB1 is associated with inflammation in hemolytic disorders including SCD and sepsis (181–184), suggesting a shared inflammatory signaling pathway through TLR4/Bruton tyrosine kinase for both heme and HMGB1 in SCD (185, 186). Heme can also directly affect the vasculature in mice, as recently shown with loss of heme exporter, feline leukemia virus subgroup C receptor 1a (FLVCR1a) in endothelial cells resulted in disruption of microvessel architecture (187).

Cell Adhesion Pathways

Cell-free heme also contributes to inflammation by activating cell adhesion pathways. This includes activation of adhesion molecules such as vascular cell adhesion molecule-1 (VCAM-1), intercellular adhesion molecule 1 (ICAM-1), selectins (L, P and E), all involved in mediating cell adhesion to the vascular endothelium via activation of integrin αMβ2 on neutrophils (188–192). Besides, several studies in the last decade have associated hemolysis and selectins expression with RBCs adhesion to endothelial cells (193–195), acute lung injury (196), vaso occlusion (197), pain (198, 199), liver injury (200–202), and kidney injury in SCD (83).

P-selectin is associated with platelet-neutrophil aggregate formation that contributes to inflammation, pulmonary dysfunction and lung vaso occlusion in SCD (200, 203). In addition, a recent study by Merle and colleagues, showed a direct link between heme-induced TLR4 and complement system activation on liver endothelium mediated by P-selectin, with genetic or pharmacological blockade of P-selectin or complement system ameliorating liver injury in mice (202). This expansive body of works culminated in clinical trial and eventual FDA approval of P-selectin blockade therapy for the prevention of pain crises in SCD (198, 199). Furthermore, persistent inducibility of endothelium-derived adhesion molecules by proinflammatory cytokines such as TNF-α and IL-6 coupled with chronic hemolysis in SCD patients ultimately results in VOC, organ dysfunction and early mortality (101, 204–208). There are several ongoing clinical trials in SCD looking at mediating the effect of inflammation-induced organ damage via some of the mechanisms discussed above.

Hemolysis, Inflammation, and microRNAs

Recent evidence supports a potential role of microRNAs (miRNAs) in complications of SCD (209, 210) and malaria (211, 212), both pathological conditions with hemolysis, suggesting a role for heme modulation of miRNAs. miRNAs are noncoding RNAs of 22 nucleotides in length that regulate the expression of their target genes post-transcriptionally (213). miRNAs are involved in important biological processes including apoptosis (214), hematopoietic differentiation (215) and cell proliferation (216). miRNAs are important regulatory molecules and activation of immune response during initiation and progression of many diseases inflammatory diseases such as cancer, Crohn’s disease, rheumatoid arthritis, systemic lupus erythematosus, and asthma, via expression of proinflammatory cytokines including TNF-α and TLRs (217–222). There are studies linking heme and miRNAs processing in mammalian cells. Heme binds directly to the RNA-binding protein DiGeorge critical region-8 (DGCR8), which is essential for the first miRNA processing step (213, 223–225). Hemolysis elevates the expression of several miRNAs found in RBCs including miR-16, miR-92a, miR-451, and miR-486 (226, 227). There is upregulation of some miRNAs including miR-16, miR-451 and miR-144 in reticulocytes from SCD patients (228, 229). Conversely, elevated levels of these miRNAs also correlated with severe anemia, increased sensitivity to oxidative stress, downregulation of NRF2 and decreased intracellular glutathione levels (230, 231). On the other hand, members of the miR-154, the miR-329 and miR-376 family, involved in TGF-β signaling pathway are downregulated in platelets of SCD patients (210). Although few numbers of studies have reported the involvement of miRNAs in complications of SCD (232), however, there is a gap in knowledge of how stress or heme regulation of these miRNAs and exposure of immune cells to proinflammatory cytokines that are elevated in SCD might play a role in organ dysfunction. Targeting these miRNAs in SCD might offer novel therapeutic strategy in preventing hemolysis-induced inflammation and end organ damage, especially in the heart, lung, liver, and kidney where miRNAs are abundant (222, 233–240).

Hemolysis and Organ Damage in Sickle Cell Disease

SCD patients on average live longer today than 50 years ago. This is due to progress in understanding the mechanisms and risk factors of several complications of the disease, associated clinical findings and mouse models, approval of new treatment therapies, multi-disciplinary approach to care, penicillin prophylaxis and high-tech diagnostic tools (241). However, this reduction in childhood mortality gives rise to an older population of patients that develop age-related chronic organ damage, driven in part by hemolysis (94). Hemolysis-induced extensive and sometimes irreversible organ damage continues to be a major source of morbidity and mortality in SCD. Even transplanted organs are also at risk of failure in SCD patients due to hemolysis and sickling (242). Therefore, there is a need for research to understand the fundamental mechanisms involved in heme-mediated organ damage in SCD patients. Over the years, several studies in the general population as well as in SCD suggest that hemolysis causes injury to the kidney (243–245), lung (246), heart, and liver. We have summarized some of the impacts of hemolysis on different organs in Table 1.

Placenta Growth Factor

In addition to its role as a DAMP, heme promotes the expression and secretion of placenta growth factor (PlGF), a pleiotropic growth factor already known to influence multiple pathways contributing to the pathophysiology of SCD (167, 176, 280). PlGF is a member of the Vascular Endothelial Growth Factor (VEGF) family. It was originally cloned from a human placenta cDNA library in 1991 (281), hence the name, but since then it has been detected in a wide variety of tissues (282). PlGF has a partial sequence similarity to VEGF-A but the two molecules share a remarkable topological identity (283). There are four human isoforms (PlGF 1–4), which are generated by alternative splicing and are slightly different in size. PlGF-1 (131 aa) and PlGF-2 (152 aa) are the predominant isoforms in humans. On the contrary, mice carry a single isoform, PlGF-2 (140 aa).

PlGF exists as a homodimer or as a heterodimer with VEGF. PlGF is a ligand for the transmembrane and soluble form of the vascular endothelial growth factor receptor 1 (VEGFR-1, Flt-1) (284), which can also bind VEGF. Distinct from VEGF, PlGF does not bind vascular endothelial growth factor receptor 2 (VEGFR-2, Flk-1) but it can affect VEGFR-2 signaling in an indirect manner (285–287). PlGF-2 can also bind heparin and the transmembrane neuropilin receptors 1 and 2 (NRP1 and NRP2) (288, 289). In addition to its role as a receptor binding competitor of VEGF (284), PlGF can exert its own biological effect upon binding to VEGFR-1. Depending on the cell type, PlGF binding upregulates VEGF, fibroblast growth factor 2 (FGF2), platelet derived growth factor beta (PDGFB) and matrix metalloproteases (MMPs) (290, 291). Furthermore, PlGF receptor binding is shown to activate an intermolecular crosstalk regulator between VEGFR-1 and VEGFR-2, often resulting in enhancing VEGF/VEGFR-2 signaling (287). It is important to emphasize here that PlGF or VEGF binding to FLT1 results in discernible receptor phosphorylation patterns and induction of distinct signaling pathways (287, 292, 293). PlGF expression is induced by hypoxia, probably in a cell specific manner, but the exact mechanism remains elusive in the absence of hypoxia responsive elements (HRE) at the gene’s promoter region (294, 295). So far, the association of only a few transcription factors has been verified for the PlGF promoter: metal transcription factor 1 (MTF-1) (295), NF-kB (296), forkhead box D1 (FoxD) (297), erythroid Kruppel-like factor (EKLF) (167), nuclear factor erythroid 2 like 2 (NRF2) (176), glial cell missing 1 (GCM1) (298). Posttrascriptional regulation of PlGF has also been reported through the regulation of the protein kinase C (PKC), p38 mitogen activated protein kinases (p38 MAPK), c-jun N-terminal kinase (JNK) and Ras-dependent extracellular signal-regulated kinase 1/2 (ERK1/2) signaling pathways (299, 300).

Surprisingly, PlGF seems to have a redundant role under normal conditions (285) but becomes very important in disease situations, where fluctuations of its levels cause a variety of issues in multiple biological processes. Because of that reason, PlGF-based therapeutic approaches have been proposed as disease specific with minimal impact for healthy cells (301). The most well established role of PlGF is in angiogenesis and more specifically in neo-angiogenesis in pathological conditions such as ischemia or cancer (285, 302, 303). PlGF’s pleiotropic nature in evident in its angiogenic role where it exerts a paracrine or autocrine effect on endothelial cells, smooth-muscle cells, fibroblasts, bone marrow progenitor cells and monocytes, to orchestrate vessel growth and maturation (304). The description of the full spectrum of PlGF’s biological role is beyond the scope of this review but to mention a few, PlGF plays a role in inflammatory response (305, 306), promotes bone repair (307), sustains the proangiogenic M2 phenotype of tumor associated macrophages (308), affects dendritic cell differentiation and maturation (309), supports the generation of an inflammatory status driving adaptive cardiac remodeling (310). To summarize, all the evidence to date supports a role for PlGF in pathogenic angiogenesis and inflammation well outside the realm of pregnancy. Through mitogen and migratory effects on endothelial cells as well as macrophage activation and chemoattraction, PlGF emerges as a driver and marker of a plethora of seemingly diverse pathologies, especially angiogenesis and inflammation.

Hemolysis, PLGF, and Complications of Sickle Cell Disease

One of the least appreciated roles of PlGF is the one that it has in hematopoiesis (311, 312) and in hemoglobinopathies (313) (Figure 2). Plasma PlGF is elevated in SCD patients and the increase correlates with the severity of hemolysis, endothelin 1 (ET-1) expression, the occurrence of pulmonary hypertension (167, 280, 314, 315) and VOC (316, 317).

Figure 2

Pulmonary Hypertension

PH is a serious complication in sickle cell patients, which is associated with high mortality (318). A variety of biological pathways and disease related pathologies contribute to the development of PH and many of them involve free heme and upregulation of PlGF. Along with PlGF, ET-1, a potent vasoconstrictor, is significantly higher in the blood of sickle patients (167, 316, 319, 320) suggesting a mechanistic link between the two factors. In support of this connection, the overexpression of PlGF in healthy mice using lentiviral gene transfer results in increased ET-1, increased right ventricle pressure and right ventricle hypertrophy as early as 8 weeks after PlGF gene transfer (280). In vitro PlGF stimulation of cultured human pulmonary microvascular endothelial cells (HPMVEC) revealed that ET-1 induction was mediated by PI-3 Kinase, NADPH-oxidase, and HIF-1a (314). Interestingly, HIF-1a stimulation of the ET-1 promoter is hypoxia independent and occurs upon the direct binding of HIF-1a on the HRE elements of the ET-1 promoter. In a similar manner, PlGF upregulates endothelin-B receptor (ET-BR) in monocytes, priming them to be over-stimulated by ET-1 and produce higher levels of chemokines MCP-1 and IL-8 (314). Both MCP-1 and IL-8 are elevated in SCD patients (321) supporting the PlGF-ET-1 synergy as another contributing factor to the development of PH in SCD.

Regulation of miRNAs

On a post-transcriptional level, PlGF attenuates miR-648 and miR-454, which recognize and bind the 3’ UTR of ET-1 mRNA. The association of low miR-648/miR-454 with high ET-1 and PlGF levels is supported in both in vivo and in vitro studies (322, 323). Furthermore, PlGF attenuates miR-199-5p, which binds the 3’UTR of HIF-1a mRNA, creating another level of control over ET-1 expression (324). The molecular repression of miR-199-5p by PlGF is mediated by the upregulation of the activating transcription factor 3 (ATF3) which upon binding causes deacetylation and chromatin condensation at the miR-199-5p locus (325). Similar to miR-648, the association of low miR-199-5p levels with high PlGF and ET-1 levels is supported by in vivo and in vitro studies (324).

Plasminogen Activator Inhibitor 1

PlGF is also linked to the increase in PAI-1 levels in the plasma and lungs of sickle cell patients and humanized sickle mice respectively (326). PAI-1 is increased during steady state SCD but its expression is exacerbated during VOC. Elevation of PAI-1 levels is associated with decreased fibrinolytic capacity (327) and is believed to contribute to the SCD prothrombotic state and the development of PH (328). In vitro PlGF stimulation induced PAI-1 expression in pulmonary microvascular endothelial cells and monocytes through the activation of c-jun N-terminal kinase (JNK), hypoxia inducible factor 1a (HIF-1a) and nicotinamide adenine dinucleotide phosphate (NADPH) oxidase (326). In addition, PlGF expression affects the stability of PAI-1 mRNA by downregulating microRNAs miR-454, miR-301a, and miR-30c which recognize and bind the PAI-1 3’-UTR. PlGF regulation of miR-454 and miR-301 is mediated by PPARa and HIF-1a (323). All of these microRNAs are detected in significantly lower levels in SCD patients compared to healthy controls (323, 329). In vivo experiments using PlGF null and SS sickle mice as well as adenoviral overexpression of PlGF, have confirmed that PlGF plays a significant role in PAI-1 regulation (326).

Inflammation and Airway Hyper-Reactivity

Airway hyper-reactivity is a common complication in SCD, especially in younger patients (330), and correlates with biomarkers of hemolysis (331). Patients show elevated levels of circulating leukotrienes (332) and their monocytes express higher levels of 5-lipoxygenase (5-LO) and 5-lipoxygenase activating protein (FLAP), both involved in leukotriene synthesis (333). Consistent to its proinflammatory nature, PlGF induces leukotriene production which in turn increases inflammation and airway hyper-reactivity, both key features of SCD. As in the case of PAI-1, the induction is mediated by HIF-1a and NADPH oxidase (333). Further studies have confirmed PlGF as an important regulator of leukotriene production and airway hyperactivity in SCD and asthma (332).

Vaso-Occlusion

Activated leukocytes in sickle cell patients are considered a significant promoting factor for VOC (334). Activated mononuclear cells from SCD patients express high levels of the cytochemokines VEGF, IL-1β, monocyte chemotactic protein 1 (MCP-1), IL-8 and macrophage inflammatory protein-1 beta (MIP-1β). In vitro studies have shown that monocytes from healthy individuals can be activated by PlGF to increase the expression of proinflammatory cytokines and chemokines such as TNF-α, IL-1β, MCP-1, IL-8, and MIP-1β (316, 335). This activation is achieved by the PlGF-VEGFR-1 interaction and involves the PI-3 kinase/AKT and ERK-1/2 signaling pathways (335). Because VOC in SCD is promoted by inflammation and leukocyte adhesion stimulated by cytokines (197, 336, 337), antibody neutralization of PlGF was tried successfully for reduction of inflammation and vaso-occlusive complications in murine SCD models (317). Regulation of PlGF levels could also be achieved by manipulating factors that control its transcriptional or translational expression. Per instance, pharmacological upregulation of miR-214 which is known to bind PlGF 3’-UTR, could be engaged to reduce PlGF levels (338).

Renal Dysfunction

PlGF is significantly upregulated in the serum of patients with chronic kidney disease and decreased renal function, supporting a potential mechanistic link between PlGF and kidney function (339, 340). Sickle cell nephropathy (SCN) is an complex phenotype which encompasses almost every physiological process in the kidney, leading to complications that may range from common and relatively mild to rare and life-limiting (243). In SCD patients markers of renal dysfunction are associated with elevated ET-1 serum levels (341) and studies in sickle cell mice have shown that ET-1 can cause renal injury, likely mediated by ROS (342). Although it has not been shown experimentally, sickle cell-related elevated PlGF levels could possibly contribute to higher ET-1 levels (167, 314) driving renal dysfunction. However, administration of exogenous heme in control and sickle cell mice has been shown to result in the upregulation of PlGF in the murine kidneys in agreement with heme uptake from renal cells and HMOX-1induction (343). In addition to ET-1, PAI-1 has also been shown to play a role in nephropathies (344) but its role in SCD or its potential regulation by PlGF remains unexplored.

Cardiac Dysfunction

Cardiac complications are common in SCD patients and along with the pulmonary complications raise their morbidity and mortality risk (94, 345). There has been accumulating evidence that PlGF dysregulation is present in multiple heart conditions although it is often unclear if it is only a disease biomarker or it actively promotes disease pathogenesis. In patients with chronic kidney disease, PlGF levels are associated with higher incidence of cardiovascular events and mortality (340). In the same disease, PlGF is an independent risk predictor for left ventricular diastolic dysfunction (346). In human atherosclerotic plaques, the expression of PlGF is associated with plaque destabilization and disease manifestation (347). The pro-atherosclerotic role of PlGF is corroborated in rabbits where PlGF adenoviral expression promotes atherogenic intimal thickening and macrophage accumulation in the carotid artery (348). PlGF is also elevated in the plasma of patients with acute coronary syndromes where it can be used as a risk predicting biomarker (349). PlGF promotes cardiac hypertrophy via endothelial cell release of NO which induces cardiomyocyte growth (350) and by inducing the secretion of paracrine factors (IL-6, IL-1b, Cxcl1) from endothelia and fibroblasts that promote cardiac adaptation and hypertrophy (351–353). In the case of ischemic cardiomyopathy, PlGF has been reported both as promoting the disease (354) and as a potential therapeutic (355). The apparent controversy could be due to differences between a local and acute administration of an angiogenic factor (355) compared to a more systemic and chronic upregulation (354). Our research has shown that PlGF is elevated in the hearts of sickle mice and it is further induced after administering exogenous heme (343). Surprisingly, the level of PlGF induction is comparable to that of the liver which is considered the major heme detoxifying organ (343). An interesting finding of this study is that mouse hearts have high levels of HMOX-1, which are further increased by heme induction, and that they show no heme accumulation unless NRF2 is depleted. These data suggest that cardiac tissue has the ability to detoxify heme via the NRF2 antioxidant response pathway.

Hemolysis, Interleukin-6, and Cardiovascular Dysfunction

IL-6 is a ubiquitous and pleiotropic proinflammatory cytokine produced by many cells including macrophages (356, 357), neutrophils (358, 359), endothelial and smooth muscle cells (360, 361), cardiomyocytes (362) and fibroblasts (363), when stimulated by ligands for toll-like receptors or other pattern recognition receptors. IL-6 is a glycoprotein composed of 184 amino acids and of 26 kDa in molecular weight (364). Currently, there are ten cytokines belonging to the IL-6 family; IL-6, IL-11, ciliary neurotrophic factor (CNTF), leukemia inhibitory factor (LIF), oncostatin M (OSM), cardiotropin-1 (CT-1), cardiotrophin-like cytokine (CLC), IL-27, neuropoietin (NP), and IL-31 (365). IL-6 regulates many biological functions including hematopoiesis (366), oncogenesis (367) and differentiation of B cells (368), induction of acute phase proteins and immune regulation (369). Additionally, IL-6 plays a vital role in chronic inflammatory processes in various cells and disease conditions (364). IL-6 signaling is through two pathways; classic/cis-mediated signaling via membrane-bound IL-6 receptor (mIL-6R) or trans-mediated signaling via the soluble form of IL-6R (sIL-6R) (364, 369). Classic/cis-signaling occurs in cells that express IL-6R such as hepatocytes, neutrophils and monocytes (365, 369). Conversely, trans-mediated signaling occurs after secretion of sIL-6R by RNA alternative splicing, ectodomain shedding or proteolytic cleavage of mIL-6R (370), which in turn stimulate cells (365, 369). Once IL-6 binds to mIL-6R or sIL-6R, the cytokine forms a complex with the ubiquitously expressed membrane protein gp130, a shared signal-transducing receptor of all IL-6 type cytokines (370). Dimerization of the receptor complex activates Janus kinases (JAKs) resulting in phosphorylation of the tyrosine residues in the cytoplasmic domain of gp130 (364, 371). Activation of JAKs triggers the extracellular-signal-regulated kinase (ERK), mitogen-activated protein kinase (MAPK) and signal transducer and activator of transcription (STAT) signaling pathways (370, 371). However, IL-6 role in pathophysiology of chronic inflammation and diseases is driven via IL-6 trans-signaling because classic/cis-signaling via the mIL-6R is limited to few cells that express IL-6R (372). Blockade of IL-6 trans-signaling is effective in attenuating proinflammatory activities of IL-6 in several disease conditions (365).

Several studies in human and rodents found hemolysis and elevated IL-6 occurring concurrently. Hemolysis and elevated IL-6 are associated with disease severity in malaria (373, 374), sepsis (375) and pre-eclampsia (376), with cardiac dysfunction as an additional comorbidity in these diseases. Besides, elevated cardiac IL-6 is also associated with cardiac hypertrophy and fibrosis in the general population (362, 377) and in rodents (378, 379). In malaria, elevated IL-6 is found in patients with severe Plasmodium falciparum/vivax malaria and associated with development of cardiac complications (373, 374). Sepsis patients with elevated IL-6 are at a higher risk of developing cardiac dysfunction which may be due to direct negative inotropic effect of IL-6 mediated via altered production of myocardial nitric oxide (375), altered calcium homeostasis (380, 381) and impaired β-adrenergic signaling (382–384). Elevated IL-6 in pre-eclampsia patients result in reduced anti-inflammatory protection in the maternal vascular system (385) and stimulation of vasoactive substances including angiotensin II type 1 receptor and endothelin-1 (386). Although, elevated plasma IL-6 have been reported in human and mice with SCD (168, 387, 388), and hemolysis is a major comorbidity of SCD (94), however, there has been no direct link between these two processes. Conversely, left ventricular hypertrophy (LVH) is found in over 60% of children and 37% in adults with SCD (389, 390), with cardiopulmonary complications accounting for about 26% of deaths in adults with SCD (391). In this current issue and for the first time, our group investigated the expression of plasma and cardiac IL-6 and its inducibility by heme in Townes sickle cell (SS) mouse model (392). We observed significantly elevated cardiac IL-6 and direct heme induction of circulating and cardiac IL-6 transcripts and protein in SS mice compared to controls. We showed that this heme-induced IL-6 is NRF2-independent in the heart. Our results of heme-induced IL-6 is in agreement with elevated levels of IL-6 reported in cardiac cells treated with Hpx and in heart isolated from Hpx deficient mice (393). Because our data showed upregulation of cardiac hypertrophy genes following heme treatment in SS mice, there is a possibility that heme is inducing IL-6 in the heart and prolonged activation and exposure to IL-6 could contribute to LVH in SCD patients. We are currently investigating potential mechanism(s) and specific cell-types secreting IL-6 in the heart of SS mice. There are several pathways through which heme may induce IL-6 expression. It is possible that parallel heme-induced pathways are activating IL-6 indirectly and with continuous hemolysis forming a feedback loop. With elevated cardiac PlGF at baseline in SCD mice and further inducibility by heme (343), cardiac hypertrophy may develop via IL-6 signaling (350). Therefore, it can be envisaged that prolonged hemolysis induced PlGF and IL-6 in SCD feeds the vicious cycle of inflammation via an autocrine feedback system resulting in reactivation of genetic cardiac hypertrophy program.

Therapeutic Intervention in Hemolysis and Inflammation

The role of hemolysis and its attendant oxidant stress and inflammatory activation in SCD has been supported by the success of therapies that normalize these pathways. Hydroxyurea has pleiotropic effects that reduce hemolysis and offset its pathobiological consequences. The approval of hydroxyurea by the FDA in 1998 provided a watershed moment in the history of SCD (394, 395). Hydroxyurea treatment yielded an improved quality of life for SCD patients attributable to induction of fetal hemoglobin, slowing of chronic damage to several organs, including the brain (394–400). More than twenty years later, three new drugs; L-glutamine (Endari; reduction of pain-related hospital visit and length of stay) and crizanlizumab-tmca (Adakveo; reduction of frequency of VOC) and voxelotor (Oxbryta; inhibition of deoxygenated sickle hemoglobin polymerization), have been approved by the FDA for treatment of SCD (401). L-glutamine is thought to reverse the redox imbalance imposed by hemolysis and other sources of oxidative stress. Crizanlizumab blocks the inflammation-activated P-selection adhesive pathway. Voxelotor inhibits polymerization of sickle hemoglobin, with the most apparent effect of reduced hemolysis. Curative intent therapies have also shown evidence of reduced hemolysis. Although permanent cure afforded to patients through bone marrow transplant and gene therapy would be ideal, it would be quite expensive and the majority of patients with SCD live in areas lacking both economic and human resources needed to make these curative therapies broadly accessible (402). Importantly, the global majority of SCD patients live in resource-poor countries, with minimal access to these newer therapies and limited capacity for hematological monitoring requirements and other diagnostic equipment (1, 403). High childhood mortality rate ranging from 50–90% still prevail in these areas and acceptance of hydroxyurea as therapy is very low compared to developed countries (403–405).

Encouragingly, recent studies show the efficacy, safety and feasibility of using hydroxyurea treatment in children and adults with sickle cell anemia living in sub-Saharan Africa (406–408).

Clinical trials are underway to assess the potential of hemopexin intravenous infusion in the treatment of SCD (Clinicaltrials.gov identifier NCT04285827). In the Townes SCD mouse model, infusion of hemopexin reduced microvascular occlusion induced by hemoglobin infusion, hypoxia-reoxygenation, or lipopolysaccharide (83). Hemopexin mitigated induction of ICAM-1 and VCAM-1 via inhibition of NF-κB activation (83). In another study, treatment with Hpx attenuated free heme activation of complement pathways and kidney injury caused by complement deposition and inflammation in mice during hemolysis (157). Hemopexin also significantly decreased plasma heme concentration, pulmonary neutrophil extracellular trap (NET) formation, plasma DNA, neutrophil activation and NET-associated hypothermia in SCD mice (171).

Conclusion

Hemolysis is a feature of many diseases, and in most cases occurring with acute and chronic inflammation that contributes to organ injury. Products of hemolysis activate several inflammatory pathways in many cell types, including cells in the innate immune system. Hemolysis appears to serve as a priming stimulus that combines with TLR4 signaling to a cascade of production of inflammatory cytokines which activate downstream pathophysiology. Therapeutic intervention targeting the upstream effects of hemolysis has potential to mitigate downstream innate immune system response and inflammation in treating patients with intravascular hemolytic disease.

Funding

GK received support from NIH grants HL133864, MD009162 and from the Institute for Transfusion Medicine Hemostasis and Vascular Biology Research Institute at the University of Pittsburgh School of Medicine. OTG is supported by the American Society of Hematology Scholar Award.

References

• 1

  PielFBHaySIGuptaSWeatherallDJWilliamsTN. Global burden of sickle cell anaemia in children under five, 2010-2050: modelling based on demographics, excess mortality, and interventions. PloS Med (2013) 10(7):e1001484. doi: 10.1371/journal.pmed.1001484

  • CrossRef
  • Google Scholar

• 2

  PhillipsJHendersonAC. Hemolytic Anemia: Evaluation and Differential Diagnosis. Am Fam Physician (2018) 98(6):354–61.

  • Google Scholar

• 3

  MenseSMZhangL. Heme: a versatile signaling molecule controlling the activities of diverse regulators ranging from transcription factors to MAP kinases. Cell Res (2006) 16(8):681–92. doi: 10.1038/sj.cr.7310086

  • CrossRef
  • Google Scholar

• 4

  ShimizuTLengalovaAMartinekVMartinkovaM. Heme: emergent roles of heme in signal transduction, functional regulation and as catalytic centres. Chem Soc Rev (2019) 48(24):5624–57. doi: 10.1039/C9CS00268E

  • CrossRef
  • Google Scholar

• 5

  PradhanPVijayanVGuelerFImmenschuhS. Interplay of Heme with Macrophages in Homeostasis and Inflammation. Int J Mol Sci (2020) 21(3):1–14. doi: 10.3390/ijms21030740

  • CrossRef
  • Google Scholar

• 6

  HebbelRMorganWEatonJHedlundB. Accelerated autoxidation and heme loss due to instability of sickle hemoglobin. Proc Natl Acad Sci USA (1988) 85(1):237–41. doi: 10.1073/pnas.85.1.237

  • CrossRef
  • Google Scholar

• 7

  HebbelR. Beyond hemoglobin polymerization: The red blood cell membrane and sickle disease pathophysiology. Blood (1991) 77:214–37. doi: 10.1182/blood.V77.2.214.214

  • CrossRef
  • Google Scholar

• 8

  HebbelREatonJBalasingamMSteinbergM. Spontaneous oxygen radical generation by sickle erythrocytes. J Clin Investigation (1982) 70(6):1253–9. doi: 10.1172/JCI110724

  • CrossRef
  • Google Scholar

• 9

  FibachERachmilewitzE. The role of oxidative stress in hemolytic anemia. Curr Mol Med (2008) 8(7):609–19. doi: 10.2174/156652408786241384

  • CrossRef
  • Google Scholar

• 10

  AdvaniRRubinEMohandasNSchrierSL. Oxidative red blood cell membrane injury in the pathophysiology of severe mouse beta-thalassemia. Blood (1992) 79(4):1064–7. doi: 10.1182/blood.V79.4.1064.1064

  • CrossRef
  • Google Scholar

• 11

  AmerJZeligOFibachE. Oxidative status of red blood cells, neutrophils, and platelets in paroxysmal nocturnal hemoglobinuria. Exp Hematol (2008) 36(4):369–77. doi: 10.1016/j.exphem.2007.12.003

  • CrossRef
  • Google Scholar

• 12

  FibachEDanaM. Oxidative stress in paroxysmal nocturnal hemoglobinuria and other conditions of complement-mediated hemolysis. Free Radical Biol Med (2015) 88(Pt A):63–9. doi: 10.1016/j.freeradbiomed.2015.04.027

  • CrossRef
  • Google Scholar

• 13

  CaprariPBozziAFerroniLStromRSalvatiAM. Oxidative erythrocyte membrane damage in hereditary spherocytosis. Biochem Int (1992) 26(2):265–74.

  • Google Scholar

• 14

  CappelliniMDFiorelliG. Glucose-6-phosphate dehydrogenase deficiency. Lancet (2008) 371(9606):64–74. doi: 10.1016/S0140-6736(08)60073-2

  • CrossRef
  • Google Scholar

• 15

  PandolfiPPSonatiFRiviRMasonPGrosveldFLuzzattoL. Targeted disruption of the housekeeping gene encoding glucose 6-phosphate dehydrogenase (G6PD): G6PD is dispensable for pentose synthesis but essential for defense against oxidative stress. EMBO J (1995) 14(21):5209–15. doi: 10.1002/j.1460-2075.1995.tb00205.x

  • CrossRef
  • Google Scholar

• 16

  SchrierSLMohandasN. Globin-chain specificity of oxidation-induced changes in red blood cell membrane properties. Blood (1992) 79(6):1586–92. doi: 10.1182/blood.V79.6.1586.1586

  • CrossRef
  • Google Scholar

• 17

  MohantyJNagababuERifkindJ. Red blood cell oxidative stress impairs oxygen delivery and induces red blood cell aging. Front Physiol (2014) 5(84):1–6. doi: 10.3389/fphys.2014.00084

  • CrossRef
  • Google Scholar

• 18

  CaprariPMassimiSDianaLSorrentinoFMaffeiLMaterazziSet al. Hemorheological Alterations and Oxidative Damage in Sickle Cell Anemia. Front Mol Biosciences (2019) 6:142. doi: 10.3389/fmolb.2019.00142

  • CrossRef
  • Google Scholar

• 19

  NagababuEFabryMNagelRRifkindJ. Heme degradation and oxidative stress in murine models for hemoglobinopathies: Thalassemia, sickle cell disease and hemoglobin C disease. Blood Cells Molecules Diseases (2008) 41(1):60–6. doi: 10.1016/j.bcmd.2007.12.003

  • CrossRef
  • Google Scholar

• 20

  JohnsonRGoyetteGJRavindranathYHoY. Hemoglobin autoxidation and regulation of endogenous H2O2 levels in erythrocytes. Free Radical Biol Med (2005) 39(11):1407–17. doi: 10.1016/j.freeradbiomed.2005.07.002

  • CrossRef
  • Google Scholar

• 21

  RankBCarlssonJHebbelR. Abnormal redox status of membrane-protein thiols in sickle erythrocytes. J Clin Investigation (1985) 75:1531–7. doi: 10.1172/JCI111857

  • CrossRef
  • Google Scholar

• 22

  WoodKHsuLGladwinM. Sickle cell disease vasculopathy: a state of nitric oxide resistance. Free Radical Biol Med (2008) 44(8):1506–28. doi: 10.1016/j.freeradbiomed.2008.01.008

  • CrossRef
  • Google Scholar

• 23

  SvistunenkoDPatelRVoloshchenkoSWilsonM. The globin-based free radical of ferryl hemoglobin is detected in normal human blood. J Biol Chem (1997) 272(11):7114–21. doi: 10.1074/jbc.272.11.7114

  • CrossRef
  • Google Scholar

• 24

  GiuliviCDaviesKJ. A novel antioxidant role for hemoglobin. The comproportionation of ferrylhemoglobin with oxyhemoglobin. J Biol Chem (1990) 265:19453–60.

  • Google Scholar

• 25

  JanaSStraderMBMengFHicksWKassaTTarandovskiyIet al. Hemoglobin oxidation-dependent reactions promote interactions with band 3 and oxidative changes in sickle cell-derived microparticles. JCI Insight (2018) 3(21):1–20. doi: 10.1172/jci.insight.120451

  • CrossRef
  • Google Scholar

• 26

  FarahMSirotkinVHaarerBKakhniashviliDAmbergD. Diverse protective roles of the actin cytoskeleton during oxidative stress. Cytoskeleton (2011) 68:340–54. doi: 10.1002/cm.20516

  • CrossRef
  • Google Scholar

• 27

  CyrklaffMSanchezCKilianNBisseyeCSimporeJFrischknechtFet al. Hemoglobins S and C interfere with actin remodeling in Plasmodium falciparum-infected erythrocytes. Science (2011) 334(6060):1283–6. doi: 10.1126/science.1213775

  • CrossRef
  • Google Scholar

• 28

  TurrensJ. Mitochondrial formation of reactive oxygen species. J Physiol (2003) 552(Pt 2):335–44. doi: 10.1113/jphysiol.2003.049478

  • CrossRef
  • Google Scholar

• 29

  SchweersRLZhangJRandallMSLoydMRLiWDorseyFCet al. NIX is required for programmed mitochondrial clearance during reticulocyte maturation. Proc Natl Acad Sci USA (2007) 104(49):19500–5. doi: 10.1073/pnas.0708818104

  • CrossRef
  • Google Scholar

• 30

  ZhangJLoydMRRandallMSWaddellMBKriwackiRWNeyPA. A short linear motif in BNIP3L (NIX) mediates mitochondrial clearance in reticulocytes. Autophagy (2012) 8(9):1325–32. doi: 10.4161/auto.20764

  • CrossRef
  • Google Scholar

• 31

  KunduMLindstenTYangCYWuJZhaoFZhangJet al. Ulk1 plays a critical role in the autophagic clearance of mitochondria and ribosomes during reticulocyte maturation. Blood (2008) 112(4):1493–502. doi: 10.1182/blood-2008-02-137398

  • CrossRef
  • Google Scholar

• 32

  GnanapragasamMNMcGrathKECathermanSXueLPalisJBiekerJJ. EKLF/KLF1-regulated cell cycle exit is essential for erythroblast enucleation. Blood (2016) 128(12):1631–41. doi: 10.1182/blood-2016-03-706671

  • CrossRef
  • Google Scholar

• 33

  JagadeeswaranRVazquezBAThiruppathiMGaneshBBIbanezVCuiSet al. Pharmacological inhibition of LSD1 and mTOR reduces mitochondrial retention and associated ROS levels in the red blood cells of sickle cell disease. Exp Hematol (2017) 50:46–52. doi: 10.1016/j.exphem.2017.02.003

  • CrossRef
  • Google Scholar

• 34

  JagadeeswaranRRiversA. Evolving treatment paradigms in sickle cell disease. Hematol Am Soc Hematol Educ Program (2017) 2017(1):440–6. doi: 10.1182/asheducation-2017.1.440

  • CrossRef
  • Google Scholar

• 35

  HigdonANBenavidesGAChackoBKOuyangXJohnsonMSLandarAet al. Hemin causes mitochondrial dysfunction in endothelial cells through promoting lipid peroxidation: the protective role of autophagy. Am J Physiol Heart Circ Physiol (2012) 302(7):H1394–409. doi: 10.1152/ajpheart.00584.2011

  • CrossRef
  • Google Scholar

• 36

  KassaTJanaSStraderMBMengFJiaYWilsonMTet al. Sickle Cell Hemoglobin in the Ferryl State Promotes betaCys-93 Oxidation and Mitochondrial Dysfunction in Epithelial Lung Cells (E10). J Biol Chem (2015) 290(46):27939–58. doi: 10.1074/jbc.M115.651257

  • CrossRef
  • Google Scholar

• 37

  ChintagariNRJanaSAlayashAI. Oxidized Ferric and Ferryl Forms of Hemoglobin Trigger Mitochondrial Dysfunction and Injury in Alveolar Type I Cells. Am J Respir Cell Mol Biol (2016) 55(2):288–98. doi: 10.1165/rcmb.2015-0197OC

  • CrossRef
  • Google Scholar

• 38

  JanaSMengFHirschREFriedmanJMAlayashAI. Oxidized Mutant Human Hemoglobins S and E Induce Oxidative Stress and Bioenergetic Dysfunction in Human Pulmonary Endothelial Cells. Front Physiol (2017) 8:1082. doi: 10.3389/fphys.2017.01082

  • CrossRef
  • Google Scholar

• 39

  CardenesNCoreyCGearyLJainSZharikovSBargeSet al. Platelet bioenergetic screen in sickle cell patients reveals mitochondrial complex V inhibition, which contributes to platelet activation. Blood (2014) 123(18):2864–72. doi: 10.1182/blood-2013-09-529420

  • CrossRef
  • Google Scholar

• 40

  VillagraJShivaSHunterLAMachadoRFGladwinMTKatoGJ. Platelet activation in patients with sickle disease, hemolysis-associated pulmonary hypertension, and nitric oxide scavenging by cell-free hemoglobin. Blood (2007) 110(6):2166–72. doi: 10.1182/blood-2006-12-061697

  • CrossRef
  • Google Scholar

• 41

  WestermanMPizzeyAHirschmanJCerinoMWeil-WeinerYRamotarPet al. Microvesicles in haemoglobinopathies offer insights into mechanisms of hypercoagulability, haemolysis and the effects of therapy. Br J Haematol (2008) 142(1):126–35. doi: 10.1111/j.1365-2141.2008.07155.x

  • CrossRef
  • Google Scholar

• 42

  AllanDLimbrickARThomasPWestermanMP. Release of spectrin-free spicules on reoxygenation of sickled erythrocytes. Natur (1982) 295(5850):612–3. doi: 10.1038/295612a0

  • CrossRef
  • Google Scholar

• 43

  LanePAO’ConnellJLMarlarRA. Erythrocyte membrane vesicles and irreversibly sickled cells bind protein S. Am J Hematol (1994) 47(4):295–300. doi: 10.1002/ajh.2830470409

  • CrossRef
  • Google Scholar

• 44

  MahfoudhiELecluseYDrissFAbbesSFlaujacCGarconL. Red cells exchanges in sickle cells disease lead to a selective reduction of erythrocytes-derived blood microparticles. Br J Haematol (2012) 156(4):545–7. doi: 10.1111/j.1365-2141.2011.08897.x

  • CrossRef
  • Google Scholar

• 45

  van TitsLJvan HeerdeWLLandburgPPBoderieMJMuskietFAJacobsNet al. Plasma annexin A5 and microparticle phosphatidylserine levels are elevated in sickle cell disease and increase further during painful crisis. Biochem Biophys Res Commun (2009) 390(1):161–4. doi: 10.1016/j.bbrc.2009.09.102

  • CrossRef
  • Google Scholar

• 46

  van BeersEJSchaapMCBerckmansRJNieuwlandRSturkAvan DoormaalFFet al. Circulating erythrocyte-derived microparticles are associated with coagulation activation in sickle cell disease. Haematologica (2009) 94(11):1513–9. doi: 10.3324/haematol.2009.008938

  • CrossRef
  • Google Scholar

• 47

  PlattOSBrambillaDJRosseWFMilnerPFCastroOSteinbergMHet al. Mortality in sickle cell disease. Life expectancy and risk factors for early death. New Engl J Med (1994) 330(23):1639–44. doi: 10.1056/NEJM199406093302303

  • CrossRef
  • Google Scholar

• 48

  CamusSMGausseresBBonninPLoufraniLGrimaudLCharueDet al. Erythrocyte microparticles can induce kidney vaso-occlusions in a murine model of sickle cell disease. Blood (2012) 120(25):5050–8. doi: 10.1182/blood-2012-02-413138

  • CrossRef
  • Google Scholar

• 49

  DonadeeCRaatNJKaniasTTejeroJLeeJSKelleyEEet al. Nitric oxide scavenging by red blood cell microparticles and cell-free hemoglobin as a mechanism for the red cell storage lesion. Circulation (2011) 124(4):465–76. doi: 10.1161/CIRCULATIONAHA.110.008698

  • CrossRef
  • Google Scholar

• 50

  LiuCZhaoWChristGJGladwinMTKim-ShapiroDB. Nitric oxide scavenging by red cell microparticles. Free Radical Biol Med (2013) 65:1164–73. doi: 10.1016/j.freeradbiomed.2013.09.002

  • CrossRef
  • Google Scholar

• 51

  CamusSMDe MoraesJABonninPAbbyadPLe JeuneSLionnetFet al. Circulating cell membrane microparticles transfer heme to endothelial cells and trigger vasoocclusions in sickle cell disease. Blood (2015) 125(24):3805–14. doi: 10.1182/blood-2014-07-589283

  • CrossRef
  • Google Scholar

• 52

  NagababuERifkindJ. Formation of fluorescent heme degradation products during the oxidation of hemoglobin by hydrogen peroxide. Biochem Biophys Res Commun (1998) 247(3):592–6. doi: 10.1006/bbrc.1998.8846

  • CrossRef
  • Google Scholar

• 53

  BedardKKrauseK. The NOX family of ROS-generating NADPH oxidases: physiology and pathophysiology. Physiol Rev (2007) 87(1):245–313. doi: 10.1152/physrev.00044.2005

  • CrossRef
  • Google Scholar

• 54

  LanaroCFranco-PenteadoCAlbuquequeDSaadSConranNCostaF. Altered levels of cytokines and inflammatory mediators in plasma and leukocytes of sickle cell anemia patients and effects of hydroxyurea therapy. J Leukocyte Biol (2009) 85(2):235–42. doi: 10.1189/jlb.0708445

  • CrossRef
  • Google Scholar

• 55

  GeorgeAPushkaranSKonstantinidisDGKoochakiSMalikPMohandasNet al. Erythrocyte NADPH oxidase activity modulated by Rac GTPases, PKC, and plasma cytokines contributes to oxidative stress in sickle cell disease. Blood (2013) 121(11):2099–107. doi: 10.1182/blood-2012-07-441188

  • CrossRef
  • Google Scholar

• 56

  LewBookchinR. Ion transport pathology in the mechanism of sickle cell dehydration. Physiol Rev (2005) 85(1):179–200. doi: 10.1152/physrev.00052.2003

  • CrossRef
  • Google Scholar

• 57

  LangKSLangPABauerCDurantonCWiederTHuberSMet al. Mechanisms of suicidal erythrocyte death. Cell Physiol Biochem Int J Exp Cell Physiol Biochem Pharmacol (2005) 15(5):195–202. doi: 10.1159/000086406

  • CrossRef
  • Google Scholar

• 58

  GbotoshoOTCytlakUMHannemannAReesDCTewariSGibsonJS. Inhibitors of second messenger pathways and Ca(2+)-induced exposure of phosphatidylserine in red blood cells of patients with sickle cell disease. Pflugers Archiv Eur J Physiol (2014) 466(7):1477–85. doi: 10.1007/s00424-013-1343-8

  • CrossRef
  • Google Scholar

• 59

  DetterichJALiuHSurianySKatoRMChalachevaPTedlaBet al. Erythrocyte and plasma oxidative stress appears to be compensated in patients with sickle cell disease during a period of relative health, despite the presence of known oxidative agents. Free Radical Biol Med (2019) 141:408–15. doi: 10.1016/j.freeradbiomed.2019.07.004

  • CrossRef
  • Google Scholar

• 60

  TappelAL. The mechanism of the oxidation of unsaturated fatty acids catalyzed by hematin compounds. Arch Biochem Biophys (1953) 44(2):378–95. doi: 10.1016/0003-9861(53)90056-3

  • CrossRef
  • Google Scholar

• 61

  VincentSHGradyRWShaklaiNSniderJMMuller-EberhardU. The influence of heme-binding proteins in heme-catalyzed oxidations. Arch Biochem Biophys (1988) 265(2):539–50. doi: 10.1016/0003-9861(88)90159-2

  • CrossRef
  • Google Scholar

• 62

  AftRLMuellerGC. Hemin-mediated DNA strand scission. J Biol Chem (1983) 258(19):12069–72.

  • Google Scholar

• 63

  GaoJLLuYBrowneGYapBCTrewhellaJHunterNet al. The role of heme binding by DNA-protective protein from starved cells (Dps) in the Tolerance of Porphyromonas gingivalis to heme toxicity. J Biol Chem (2012) 287(50):42243–58. doi: 10.1074/jbc.M112.392787

  • CrossRef
  • Google Scholar

• 64

  VasconcellosLRDutraFFSiqueiraMSPaula-NetoHADahanJKiarelyEet al. Protein aggregation as a cellular response to oxidative stress induced by heme and iron. Proc Natl Acad Sci USA (2016) 113(47):E7474–E82. doi: 10.1073/pnas.1608928113

  • CrossRef
  • Google Scholar

• 65

  AftRLMuellerGC. Hemin-mediated oxidative degradation of proteins. J Biol Chem (1984) 259(1):301–5.

  • Google Scholar

• 66

  BiswalSRizwanHPalSSabnamSParidaPPalA. Oxidative stress, antioxidant capacity, biomolecule damage, and inflammation symptoms of sickle cell disease in children. Hematol (Amsterdam Netherlands) (2019) 24(1):1–9. doi: 10.1080/10245332.2018.1498441

  • CrossRef
  • Google Scholar

• 67

  AlsultanAISeifMAAminTTNaboliMAlsulimanAM. Relationship between oxidative stress, ferritin and insulin resistance in sickle cell disease. Eur Rev Med Pharmacol Sci (2010) 14(6):527–38.

  • Google Scholar

• 68

  Ama MoorVJPiemeCAChetcha ChemegneBManonjiHNjinkio NonoBLTchoula MamiafoCet al. Oxidative profile of sickle cell patients in a Cameroonian urban hospital. BMC Clin Pathol (2016) 16:15. doi: 10.1186/s12907-016-0037-5

  • CrossRef
  • Google Scholar

• 69

  NattaCLChenLCChowCK. Selenium and glutathione peroxidase levels in sickle cell anemia. Acta Haematol (1990) 83(3):130–2. doi: 10.1159/000205188

  • CrossRef
  • Google Scholar

• 70

  RenouxCJolyPFaesCMuryPEglenenBTurkayMet al. Association between Oxidative Stress, Genetic Factors, and Clinical Severity in Children with Sickle Cell Anemia. J Pediatrics (2018) 195:228–35. doi: 10.1016/j.jpeds.2017.12.021

  • CrossRef
  • Google Scholar

• 71

  MockeschBConnesPCharlotKSkinnerSHardy-DessourcesMDRomanaMet al. Association between oxidative stress and vascular reactivity in children with sickle cell anaemia and sickle haemoglobin C disease. Br J Haematol (2017) 178(3):468–75. doi: 10.1111/bjh.14693

  • CrossRef
  • Google Scholar

• 72

  Antwi-BoasiakoCDankwahGBAryeeRHayfron-BenjaminCDonkorESCampbellAD. Oxidative Profile of Patients with Sickle Cell Disease. Med Sci (Basel Switzerland) (2019) 7(2):1–8. doi: 10.3390/medsci7020017

  • CrossRef
  • Google Scholar

• 73

  SchacterLWarthJAGordonEMPrasadAKleinBL. Altered amount and activity of superoxide dismutase in sickle cell anemia. FASEB J (1988) 2(3):237–43. doi: 10.1096/fasebj.2.3.3350236

  • CrossRef
  • Google Scholar

• 74

  FariasICCMendonca-BelmontTFda SilvaASdoOKFerreiraFMedeirosFSet al. Association of the SOD2 Polymorphism (Val16Ala) and SOD Activity with Vaso-occlusive Crisis and Acute Splenic Sequestration in Children with Sickle Cell Anemia. Mediterranean J Hematol Infect Diseases (2018) 10(1):e2018012. doi: 10.4084/mjhid.2018.012

  • CrossRef
  • Google Scholar

• 75

  ArmenisIKalotychouVTzaneteaRMoyssakisIAnastasopoulouDPantosCet al. Reduced peripheral blood superoxide dismutase 2 expression in sickle cell disease. Ann Hematol (2019) 98(7):1561–72. doi: 10.1007/s00277-019-03709-8

  • CrossRef
  • Google Scholar

• 76

  SmithOSAjoseOAAdegokeSAAdegokeOAAdedejiTAOderinuKA. Plasma level of antioxidants is related to frequency of vaso-occlusive crises in children with sickle cell anaemia in steady state in Nigeria. Pediatr Hematol Oncol J (2019) 4(1):17–22. doi: 10.1016/j.phoj.2019.03.003

  • CrossRef
  • Google Scholar

• 77

  DelesderrierECople-RodriguesCSOmenaJKneip FleuryMBarbosa BritoFCosta BaceloAet al. Selenium Status and Hemolysis in Sickle Cell Disease Patients. Nutrients (2019) 11(9):1–11. doi: 10.3390/nu11092211

  • CrossRef
  • Google Scholar

• 78

  ManfrediniVLazzarettiLLGriebelerIHSantinAPBrandaoVDWagnerSet al. Blood antioxidant parameters in sickle cell anemia patients in steady state. J Natl Med Assoc (2008) 100(8):897–902. doi: 10.1016/S0027-9684(15)31402-4

  • CrossRef
  • Google Scholar

• 79

  MorrisCSuhJHagarWLarkinSBlandDSteinbergMet al. Erythrocyte glutamine depletion, altered redox environment, and pulmonary hypertension in sickle cell disease. Blood (2008) 111(1):402–10. doi: 10.1182/blood-2007-04-081703

  • CrossRef
  • Google Scholar

• 80

  HamdyMMMosallamDSJamalAMRabieWA. Selenium and Vitamin E as antioxidants in chronic hemolytic anemia: Are they deficient? A case-control study in a group of Egyptian children. J Adv Res (2015) 6(6):1071–7. doi: 10.1016/j.jare.2015.01.002

  • CrossRef
  • Google Scholar

• 81

  ArrudaMMMecaboGRodriguesCAMatsudaSSRabeloIBFigueiredoMSet al. and E supplementation increases markers of haemolysis in sickle cell anaemia patients: a randomized, double-blind, placebo-controlled trial. Br J Haematol (2013) 160(5):688–700. doi: 10.1111/bjh.12185

  • CrossRef
  • Google Scholar

• 82

  MuhammadAWaziriADForcadosGESanusiBSaniHMalamiIet al. Sickling-preventive effects of rutin is associated with modulation of deoxygenated haemoglobin, 2,3-bisphosphoglycerate mutase, redox status and alteration of functional chemistry in sickle erythrocytes. Heliyon (2019) 5(6):e01905. doi: 10.1016/j.heliyon.2019.e01905

  • CrossRef
  • Google Scholar

• 83

  BelcherJDChenCNguyenJAbdullaFZhangPNguyenHet al. Haptoglobin and hemopexin inhibit vaso-occlusion and inflammation in murine sickle cell disease: Role of heme oxygenase-1 induction. PloS One (2018) 13(4):e0196455. doi: 10.1371/journal.pone.0196455

  • CrossRef
  • Google Scholar

• 84

  GellenBMessonnierLAGalacterosFAudureauEMerletANRuppTet al. Moderate-intensity endurance-exercise training in patients with sickle-cell disease without severe chronic complications (EXDRE): an open-label randomised controlled trial. Lancet Haematol (2018) 5(11):e554–e62. doi: 10.1016/S2352-3026(18)30163-7

  • CrossRef
  • Google Scholar

• 85

  ChatelBMessonnierLABargeQVilmenCNoirezPBernardMet al. Endurance training reduces exercise-induced acidosis and improves muscle function in a mouse model of sickle cell disease. Mol Genet Metab (2018) 123(3):400–10. doi: 10.1016/j.ymgme.2017.11.010

  • CrossRef
  • Google Scholar

• 86

  CharrinEAufradetEDouillardARomdhaniASouzaGDBessaadAet al. Oxidative stress is decreased in physically active sickle cell SAD mice. Br J Haematol (2015) 168(5):747–56. doi: 10.1111/bjh.13207

  • CrossRef
  • Google Scholar

• 87

  GouraudECharrinEDubeJJOfori-AcquahSFMartinCSkinnerSet al. Effects of Individualized Treadmill Endurance Training on Oxidative Stress in Skeletal Muscles of Transgenic Sickle Mice. Oxid Med Cell Longevity (2019) 2019:3765643. doi: 10.1155/2019/3765643

  • CrossRef
  • Google Scholar

• 88

  GrauMNaderEJerkeMSchenkARenouxCDietzTet al. Impact of A Six Week Training Program on Ventilatory Efficiency, Red Blood Cell Rheological Parameters and Red Blood Cell Nitric Oxide Signaling in Young Sickle Cell Anemia Patients: A Pilot Study. J Clin Med (2019) 8(12):1–16. doi: 10.3390/jcm8122155

  • CrossRef
  • Google Scholar

• 89

  KatoGMcGowanVMachadoRLittleJTaylorJMorrisCet al. Lactate dehydrogenase as a biomarker of hemolysis-associated nitric oxide resistance, priapism, leg ulceration, pulmonary hypertension, and death in patients with sickle cell disease. Blood (2006) 107(6):2279–85. doi: 10.1182/blood-2005-06-2373

  • CrossRef
  • Google Scholar

• 90

  MorrisCKatoGPoljakovicMWangXBlackwelderWSachdevVet al. Dysregulated arginine metabolism, hemolysis-associated pulmonary hypertension, and mortality in sickle cell disease. J Am Med Assoc (2005) 294(1):81–90. doi: 10.1001/jama.294.1.81

  • CrossRef
  • Google Scholar

• 91

  ReiterCWangXTanus-SantosJHoggNCannonRRSchechterAet al. Cell-free hemoglobin limits nitric oxide bioavailability in sickle-cell disease. Nat Med (2002) 8(12):1383–9. doi: 10.1038/nm1202-799

  • CrossRef
  • Google Scholar

• 92

  PalmerRFerrigeAMoncadaS. Nitric oxide release accounts for the biological activity of endothelium-derived relaxing factor. Nature (1987) 327:524 – 6. doi: 10.1038/327524a0

  • CrossRef
  • Google Scholar

• 93

  ArnoldWMittalCKatsukiSMuradF. Nitric oxide activates guanylate cyclase and increases guanosine 3′:5′-cyclic monophosphate levels in various tissue preparations. Proc Natl Acad Sci USA (1977) 74:3203–7. doi: 10.1073/pnas.74.8.3203

  • CrossRef
  • Google Scholar

• 94

  KatoGJSteinbergMHGladwinMT. Intravascular hemolysis and the pathophysiology of sickle cell disease. J Clin Invest (2017) 127(3):750–60. doi: 10.1172/JCI89741

  • CrossRef
  • Google Scholar

• 95

  PotokaKPGladwinMT. Vasculopathy and pulmonary hypertension in sickle cell disease. Am J Physiol Lung Cell Mol Physiol (2015) 308(4):L314–24. doi: 10.1152/ajplung.00252.2014

  • CrossRef
  • Google Scholar

• 96

  GordeukVRCastroOLMachadoRF. Pathophysiology and treatment of pulmonary hypertension in sickle cell disease. Blood (2016) 127(7):820–8. doi: 10.1182/blood-2015-08-618561

  • CrossRef
  • Google Scholar

• 97

  KristiansenMGraversenJHJacobsenCSonneOHoffmanHJLawSKet al. Identification of the haemoglobin scavenger receptor. Nature (2001) 409(6817):198–201. doi: 10.1038/35051594

  • CrossRef
  • Google Scholar

• 98

  SchaerDJSchaerCABuehlerPWBoykinsRASchoedonGAlayashAIet al. CD163 is the macrophage scavenger receptor for native and chemically modified hemoglobins in the absence of haptoglobin. Blood (2006) 107(1):373–80. doi: 10.1182/blood-2005-03-1014

  • CrossRef
  • Google Scholar

• 99

  NielsenMJAndersenCBMoestrupSK. CD163 binding to haptoglobin-hemoglobin complexes involves a dual-point electrostatic receptor-ligand pairing. J Biol Chem (2013) 288(26):18834–41. doi: 10.1074/jbc.M113.471060

  • CrossRef
  • Google Scholar

• 100

  SmithAMcCullohRJ. Hemopexin and haptoglobin: allies against heme toxicity from hemoglobin not contenders. Front Physiol (2015) 6:187. doi: 10.3389/fphys.2015.00187

  • CrossRef
  • Google Scholar

• 101

  RotherRPBellLHillmenPGladwinMT. The clinical sequelae of intravascular hemolysis and extracellular plasma hemoglobin: a novel mechanism of human disease. JAMA (2005) 293(13):1653–62. doi: 10.1001/jama.293.13.1653

  • CrossRef
  • Google Scholar

• 102

  ImmenschuhSVijayanVJanciauskieneSGuelerF. Heme as a Target for Therapeutic Interventions. Front Pharmacol (2017) 8:146. doi: 10.3389/fphar.2017.00146

  • CrossRef
  • Google Scholar

• 103

  OhJYHammJXuXGenschmerKZhongMLebensburgerJet al. Absorbance and redox based approaches for measuring free heme and free hemoglobin in biological matrices. Redox Biol (2016) 9:167–77. doi: 10.1016/j.redox.2016.08.003

  • CrossRef
  • Google Scholar

• 104

  ThomasAMGerogianniAMcAdamMBFloisandYLauCEspevikTet al. Complement Component C5 and TLR Molecule CD14 Mediate Heme-Induced Thromboinflammation in Human Blood. J Immunol (2019) 203(6):1571–8. doi: 10.4049/jimmunol.1900047

  • CrossRef
  • Google Scholar

• 105

  BallaJVercellottiGMJeneyVYachieAVargaZEatonJWet al. Heme, heme oxygenase and ferritin in vascular endothelial cell injury. Mol Nutr Food Res (2005) 49(11):1030–43. doi: 10.1002/mnfr.200500076

  • CrossRef
  • Google Scholar

• 106

  GrinshteinNBammVVTsemakhovichVAShaklaiN. Mechanism of low-density lipoprotein oxidation by hemoglobin-derived iron. Biochemistry (2003) 42(23):6977–85. doi: 10.1021/bi020647r

  • CrossRef
  • Google Scholar

• 107

  MillerYIShaklaiN. Kinetics of hemin distribution in plasma reveals its role in lipoprotein oxidation. Biochim Biophys Acta (1999) 1454(2):153–64. doi: 10.1016/S0925-4439(99)00027-7

  • CrossRef
  • Google Scholar

• 108

  GozzelinoRJeneyVSoaresMP. Mechanisms of cell protection by heme oxygenase-1. Annu Rev Pharmacol Toxicol (2010) 50:323–54. doi: 10.1146/annurev.pharmtox.010909.105600

  • CrossRef
  • Google Scholar

• 109

  FasanoMMattuMColettaMAscenziP. The heme-iron geometry of ferrous nitrosylated heme-serum lipoproteins, hemopexin, and albumin: a comparative EPR study. J Inorganic Biochem (2002) 91(3):487–90. doi: 10.1016/S0162-0134(02)00473-7

  • CrossRef
  • Google Scholar

• 110

  SasakiJWatermanMRBuchananGRCottamGL. Plasma and erythrocyte lipids in sickle cell anaemia. Clin Lab Haematol (1983) 5(1):35–44. doi: 10.1111/j.1365-2257.1983.tb00494.x

  • CrossRef
  • Google Scholar

• 111

  AkinladeKSAdewaleCORahamonSKFasolaFAOlaniyiJAAtereAD. Defective lipid metabolism in sickle cell anaemia subjects in vaso-occlusive crisis. Nigerian Med J J Nigeria Med Assoc (2014) 55(5):428–31. doi: 10.4103/0300-1652.140388

  • CrossRef
  • Google Scholar

• 112

  ZorcaSFreemanLHildesheimMAllenDRemaleyATJGtTet al. Lipid levels in sickle-cell disease associated with haemolytic severity, vascular dysfunction and pulmonary hypertension. Br J Haematol (2010) 149(3):436–45. doi: 10.1111/j.1365-2141.2010.08109.x

  • CrossRef
  • Google Scholar

• 113

  YalcinkayaAUnalSOztasY. Altered HDL particle in sickle cell disease: decreased cholesterol content is associated with hemolysis, whereas decreased Apolipoprotein A1 is linked to inflammation. Lipids Health Disease (2019) 18(1):225. doi: 10.1186/s12944-019-1174-5

  • CrossRef
  • Google Scholar

• 114

  VendrameFOlopsLSaadSTOCostaFFFertrinKY. Differences in heme and hemopexin content in lipoproteins from patients with sickle cell disease. J Clin Lipidol (2018) 12(6):1532–8. doi: 10.1016/j.jacl.2018.08.002

  • CrossRef
  • Google Scholar

• 115

  FasanoMFanaliGLeboffeLAscenziP. Heme binding to albuminoid proteins is the result of recent evolution. IUBMB Life (2007) 59(7):436–40. doi: 10.1080/15216540701474523

  • CrossRef
  • Google Scholar

• 116

  AscenziPFasanoM. Serum heme-albumin: an allosteric protein. IUBMB Life (2009) 61(12):1118–22. doi: 10.1002/iub.263

  • CrossRef
  • Google Scholar

• 117

  BunnHFJandlJH. Exchange of heme among hemoglobins and between hemoglobin and albumin. J Biol Chem (1968) 243(3):465–75.

  • Google Scholar

• 118

  HvidbergVManieckiMBJacobsenCHojrupPMollerHJMoestrupSK. Identification of the receptor scavenging hemopexin-heme complexes. Blood (2005) 106(7):2572–9. doi: 10.1182/blood-2005-03-1185

  • CrossRef
  • Google Scholar

• 119

  TolosanoEFagooneeSMorelloNVinchiFFioritoV. Heme scavenging and the other facets of hemopexin. Antioxidants Redox Signaling (2010) 12(2):305–20. doi: 10.1089/ars.2009.2787

  • CrossRef
  • Google Scholar

• 120

  AllhornMBerggardTNordbergJOlssonMLAkerstromB. Processing of the lipocalin alpha(1)-microglobulin by hemoglobin induces heme-binding and heme-degradation properties. Blood (2002) 99(6):1894–901. doi: 10.1182/blood.V99.6.1894

  • CrossRef
  • Google Scholar

• 121

  MeiningWSkerraA. The crystal structure of human alpha(1)-microglobulin reveals a potential haem-binding site. Biochem J (2012) 445(2):175–82. doi: 10.1042/BJ20120448

  • CrossRef
  • Google Scholar

• 122

  AllhornMKlapytaAAkerstromB. Redox properties of the lipocalin alpha1-microglobulin: reduction of cytochrome c, hemoglobin, and free iron. Free Radical Biol Med (2005) 38(5):557–67. doi: 10.1016/j.freeradbiomed.2004.12.013

  • CrossRef
  • Google Scholar

• 123

  HahlPHuntRBjesESSkaffAKeightleyASmithA. Identification of oxidative modifications of hemopexin and their predicted physiological relevance. J Biol Chem (2017) 292(33):13658–71. doi: 10.1074/jbc.M117.783951

  • CrossRef
  • Google Scholar

• 124

  PaoliMAndersonBFBakerHMMorganWTSmithABakerEN. Crystal structure of hemopexin reveals a novel high-affinity heme site formed between two beta-propeller domains. Nat Struct Biol (1999) 6(10):926–31. doi: 10.1038/13294

  • CrossRef
  • Google Scholar

• 125

  GkouvatsosKPapanikolaouGPantopoulosK. Regulation of iron transport and the role of transferrin. Biochim Biophys Acta (2012) 1820(3):188–202. doi: 10.1016/j.bbagen.2011.10.013

  • CrossRef
  • Google Scholar

• 126

  OlatunyaOSLanaroCLonghiniALPenteadoCFFFertrinKYAdekileAet al. Red blood cells microparticles are associated with hemolysis markers and may contribute to clinical events among sickle cell disease patients. Ann Hematol (2019) 98(11):2507–21. doi: 10.1007/s00277-019-03792-x

  • CrossRef
  • Google Scholar

• 127

  YalamanogluADeuelJWHuntRCBaekJHHassellKRediniusKet al. Depletion of haptoglobin and hemopexin promote hemoglobin-mediated lipoprotein oxidation in sickle cell disease. Am J Physiol Lung Cell Mol Physiol (2018) 315(5):L765–L74. doi: 10.1152/ajplung.00269.2018

  • CrossRef
  • Google Scholar

• 128

  SoaresMPBachFH. Heme oxygenase-1: from biology to therapeutic potential. Trends Mol Med (2009) 15(2):50–8. doi: 10.1016/j.molmed.2008.12.004

  • CrossRef
  • Google Scholar

• 129

  WagenerFAVolkHDWillisDAbrahamNGSoaresMPAdemaGJet al. Different faces of the heme-heme oxygenase system in inflammation. Pharmacol Rev (2003) 55(3):551–71. doi: 10.1124/pr.55.3.5

  • CrossRef
  • Google Scholar

• 130

  AlamJKilleenEGongPNaquinRHuBStewartDet al. Heme activates the heme oxygenase-1 gene in renal epithelial cells by stabilizing Nrf2. Am J Physiol Renal Physiol (2003) 284(4):F743–52. doi: 10.1152/ajprenal.00376.2002

  • CrossRef
  • Google Scholar

• 131

  BelcherJDBeckmanJDBallaGBallaJVercellottiG. Heme degradation and vascular injury. Antioxidants Redox Signaling (2010) 12(2):233–48. doi: 10.1089/ars.2009.2822

  • CrossRef
  • Google Scholar

• 132

  BoyleJJJohnsMLoJChiodiniAAmbroseNEvansPCet al. Heme induces heme oxygenase 1 via Nrf2: role in the homeostatic macrophage response to intraplaque hemorrhage. Arteriosclerosis thrombosis Vasc Biol (2011) 31(11):2685–91. doi: 10.1161/ATVBAHA.111.225813

  • CrossRef
  • Google Scholar

• 133

  GhoshSHazraRIhunnahCAWeidertFFlageBOfori-AcquahSF. Augmented NRF2 activation protects adult sickle mice from lethal acute chest syndrome. Br J Haematol (2018) 182(2):271–5. doi: 10.1111/bjh.15401

  • CrossRef
  • Google Scholar

• 134

  BelcherJDVineyardJVBruzzoneCMChenCBeckmanJDNguyenJet al. Heme oxygenase-1 gene delivery by Sleeping Beauty inhibits vascular stasis in a murine model of sickle cell disease. J Mol Med (Berlin Germany) (2010) 88(7):665–75. doi: 10.1007/s00109-010-0613-6

  • CrossRef
  • Google Scholar

• 135

  BelcherJDMahasethHWelchTEOtterbeinLEHebbelRPVercellottiGM. Heme oxygenase-1 is a modulator of inflammation and vaso-occlusion in transgenic sickle mice. J Clin Investig (2006) 116(3):808–16. doi: 10.1172/JCI26857

  • CrossRef
  • Google Scholar

• 136

  BelcherJDChenCNguyenJZhangPAbdullaFNguyenPet al. Control of Oxidative Stress and Inflammation in Sickle Cell Disease with the Nrf2 Activator Dimethyl Fumarate. Antioxidants Redox Signaling (2017) 26(14):748–62. doi: 10.1089/ars.2015.6571

  • CrossRef
  • Google Scholar

• 137

  KrishnamoorthySPaceBGuptaDSturtevantSLiBMakalaLet al. Dimethyl fumarate increases fetal hemoglobin, provides heme detoxification, and corrects anemia in sickle cell disease. JCI Insight (2017) 2(20):1–16. doi: 10.1172/jci.insight.96409

  • CrossRef
  • Google Scholar

• 138

  Keleku-LukweteNSuzukiMOtsukiATsuchidaKKatayamaSHayashiMet al. Amelioration of inflammation and tissue damage in sickle cell model mice by Nrf2 activation. Proc Natl Acad Sci USA (2015) 112(39):12169–74. doi: 10.1073/pnas.1509158112

  • CrossRef
  • Google Scholar

• 139

  BallaJJacobHSBallaGNathKEatonJWVercellottiGM. Endothelial-cell heme uptake from heme proteins: induction of sensitization and desensitization to oxidant damage. Proc Natl Acad Sci USA (1993) 90(20):9285–9. doi: 10.1073/pnas.90.20.9285

  • CrossRef
  • Google Scholar

• 140

  IwasakiKMackenzieELHailemariamKSakamotoKTsujiY. Hemin-mediated regulation of an antioxidant-responsive element of the human ferritin H gene and role of Ref-1 during erythroid differentiation of K562 cells. Mol Cell Biol (2006) 26(7):2845–56. doi: 10.1128/MCB.26.7.2845-2856.2006

  • CrossRef
  • Google Scholar

• 141

  ConranNBelcherJD. Inflammation in sickle cell disease. Clin Hemorheol Microcirc (2018) 68(2-3):263–99. doi: 10.3233/CH-189012

  • CrossRef
  • Google Scholar

• 142

  PamplonaAFerreiraABallaJJeneyVBallaGEpiphanioSet al. Heme oxygenase-1 and carbon monoxide suppress the pathogenesis of experimental cerebral malaria. Nat Med (2007) 13(6):703–10. doi: 10.1038/nm1586

  • CrossRef
  • Google Scholar

• 143

  PereiraMLMMarinhoCRFEpiphanioS. Could Heme Oxygenase-1 Be a New Target for Therapeutic Intervention in Malaria-Associated Acute Lung Injury/Acute Respiratory Distress Syndrome? Front Cell Infection Microbiol (2018) 8:161. doi: 10.3389/fcimb.2018.00161

  • CrossRef
  • Google Scholar

• 144

  EkregbesiPShankar-HariMBottomleyCRileyEMMooneyJP. Relationship between Anaemia, Haemolysis, Inflammation and Haem Oxygenase-1 at Admission with Sepsis: a pilot study. Sci Rep (2018) 8(1):11198. doi: 10.1038/s41598-018-29558-5

  • CrossRef
  • Google Scholar

• 145

  AdamzikMHamburgerTPetratFPetersJde GrootHHartmannM. Free hemoglobin concentration in severe sepsis: methods of measurement and prediction of outcome. Crit Care (2012) 16(4):R125. doi: 10.1186/cc11425

  • CrossRef
  • Google Scholar

• 146

  ClarkIAAwburnMMHarperCGLiombaNGMolyneuxME. Induction of HO-1 in tissue macrophages and monocytes in fatal falciparum malaria and sepsis. Malaria J (2003) 2(1):41. doi: 10.1186/1475-2875-2-41

  • CrossRef
  • Google Scholar

• 147

  KatoGGladwinMSteinbergM. Deconstructing sickle cell disease: reappraisal of the role of hemolysis in the development of clinical subphenotypes. Blood Rev (2007) 21(1):37–47. doi: 10.1016/j.blre.2006.07.001

  • CrossRef
  • Google Scholar

• 148

  TakakiSTakeyamaNKajitaYYabukiTNoguchiHMikiYet al. Beneficial effects of the heme oxygenase-1/carbon monoxide system in patients with severe sepsis/septic shock. Intensive Care Med (2010) 36(1):42–8. doi: 10.1007/s00134-009-1575-4

  • CrossRef
  • Google Scholar

• 149

  JanzDRBastaracheJASillsGWickershamNMayAKBernardGRet al. Association between haptoglobin, hemopexin and mortality in adults with sepsis. Crit Care (2013) 17(6):R272. doi: 10.1186/cc13108

  • CrossRef
  • Google Scholar

• 150

  BallaGJacobHSEatonJWBelcherJDVercellottiGM. Hemin: a possible physiological mediator of low density lipoprotein oxidation and endothelial injury. Arterioscler Thromb J Vasc Biol (1991) 11(6):1700–11. doi: 10.1161/01.ATV.11.6.1700

  • CrossRef
  • Google Scholar

• 151

  DutraFFBozzaMT. Heme on innate immunity and inflammation. Front Pharmacol (2014) 5:115. doi: 10.3389/fphar.2014.00115

  • CrossRef
  • Google Scholar

• 152

  GouveiaZCarlosARYuanXAires-da-SilvaFStockerRMaghzalGJet al. Characterization of plasma labile heme in hemolytic conditions. FEBS J (2017) 284(19):3278–301. doi: 10.1111/febs.14192

  • CrossRef
  • Google Scholar

• 153

  SantiagoRPGuardaCCFigueiredoCVBFiuzaLMAleluiaMMAdanhoCSAet al. Serum haptoglobin and hemopexin levels are depleted in pediatric sickle cell disease patients. Blood Cells Mol Dis (2018) 72:34–6. doi: 10.1016/j.bcmd.2018.07.002

  • CrossRef
  • Google Scholar

• 154

  VercellottiGMZhangPNguyenJAbdullaFChenCNguyenPet al. Hepatic Overexpression of Hemopexin Inhibits Inflammation and Vascular Stasis in Murine Models of Sickle Cell Disease. Mol Med (Cambridge Mass) (2016) 22:1–15. doi: 10.2119/molmed.2016.00063

  • CrossRef
  • Google Scholar

• 155

  Ofori-AcquahSFHazraROrikogboOOCrosbyDFlageBAckahEBet al. Hemopexin deficiency promotes acute kidney injury in sickle cell disease. Blood (2020) 135(13):1044–8. doi: 10.1182/blood.2019002653

  • CrossRef
  • Google Scholar

• 156

  Muller-EberhardUJavidJLiemHHHansteinAHannaM. Plasma concentrations of hemopexin, haptoglobin and heme in patients with various hemolytic diseases. Blood (1968) 32(5):811–5. doi: 10.1182/blood.V32.5.811.811

  • CrossRef
  • Google Scholar

• 157

  MerleNSGrunenwaldARajaratnamHGnemmiVFrimatMFigueresMLet al. Intravascular hemolysis activates complement via cell-free heme and heme-loaded microvesicles. JCI Insight (2018) 3(12):1–17. doi: 10.1172/jci.insight.96910

  • CrossRef
  • Google Scholar

• 158

  AdisaOAHuYGhoshSAryeeDOsunkwoIOfori-AcquahSF. Association between plasma free haem and incidence of vaso-occlusive episodes and acute chest syndrome in children with sickle cell disease. Br J Haematol (2013) 162(5):702–5. doi: 10.1111/bjh.12445

  • CrossRef
  • Google Scholar

• 159

  SadrzadehSMGrafEPanterSSHallawayPEEatonJW. Hemoglobin. A biologic fenton reagent. J Biol Chem (1984) 259(23):14354–6.

  • Google Scholar

• 160

  ThomasDDEspeyMGVitekMPMirandaKMWinkDA. Protein nitration is mediated by heme and free metals through Fenton-type chemistry: an alternative to the NO/O2- reaction. Proc Natl Acad Sci USA (2002) 99(20):12691–6. doi: 10.1073/pnas.202312699

  • CrossRef
  • Google Scholar

• 161

  WinterbournCC. Toxicity of iron and hydrogen peroxide: the Fenton reaction. Toxicol Lett (1995) 82-83:969–74. doi: 10.1016/0378-4274(95)03532-x

  • CrossRef
  • Google Scholar

• 162

  MengFAlayashAI. Determination of extinction coefficients of human hemoglobin in various redox states. Anal Biochem (2017) 521:11–9. doi: 10.1016/j.ab.2017.01.002

  • CrossRef
  • Google Scholar

• 163

  HannaDAHarveyRMMartinez-GuzmanOYuanXChandrasekharanBRajuGet al. Heme dynamics and trafficking factors revealed by genetically encoded fluorescent heme sensors. Proc Natl Acad Sci USA (2016) 113(27):7539–44. doi: 10.1073/pnas.1523802113

  • CrossRef
  • Google Scholar

• 164

  NewtonLDPascuSITyrrellRMEgglestonIM. Development of a peptide-based fluorescent probe for biological heme monitoring. Org Biomol Chem (2019) 17(3):467–71. doi: 10.1039/C8OB02290A

  • CrossRef
  • Google Scholar

• 165

  HargroveMSWhitakerTOlsonJSValiRJMathewsAJ. Quaternary structure regulates hemin dissociation from human hemoglobin. J Biol Chem (1997) 272(28):17385–9. doi: 10.1074/jbc.272.28.17385

  • CrossRef
  • Google Scholar

• 166

  AndersonHLBrodskyIEMangalmurtiNS. The Evolving Erythrocyte: Red Blood Cells as Modulators of Innate Immunity. J Immunol (2018) 201(5):1343–51. doi: 10.4049/jimmunol.1800565

  • CrossRef
  • Google Scholar

• 167

  WangXMendelsohnLRogersHLeitmanSRaghavachariNYangYet al. Heme-bound iron activates placenta growth factor in erythroid cells via erythroid Krüppel-like factor. Blood (2014) 124(6):946–54. doi: 10.1182/blood-2013-11-539718

  • CrossRef
  • Google Scholar

• 168

  VinchiFCosta da SilvaMIngogliaGPetrilloSBrinkmanNZuercherAet al. Hemopexin therapy reverts heme-induced proinflammatory phenotypic switching of macrophages in a mouse model of sickle cell disease. Blood (2016) 127(4):473–86. doi: 10.1182/blood-2015-08-663245

  • CrossRef
  • Google Scholar

• 169

  DutraFFAlvesLSRodriguesDFernandezPLde OliveiraRBGolenbockDTet al. Hemolysis-induced lethality involves inflammasome activation by heme. Proc Natl Acad Sci USA (2014) 111(39):E4110–8. doi: 10.1073/pnas.1405023111

  • CrossRef
  • Google Scholar

• 170

  SparkenbaughEMChantrathammachartPWangSJonasWKirchhoferDGailaniDet al. Excess of heme induces tissue factor-dependent activation of coagulation in mice. Haematologica (2015) 100(3):308–14. doi: 10.3324/haematol.2014.114728

  • CrossRef
  • Google Scholar

• 171

  ChenGZhangDFuchsTAManwaniDWagnerDDFrenettePS. Heme-induced neutrophil extracellular traps contribute to the pathogenesis of sickle cell disease. Blood (2014) 123(24):3818–27. doi: 10.1182/blood-2013-10-529982

  • CrossRef
  • Google Scholar

• 172

  ErdeiJTothABaloghENyakundiBBBanyaiERyffelBet al. Induction of NLRP3 Inflammasome Activation by Heme in Human Endothelial Cells. Oxid Med Cell Longevity (2018) 2018:4310816. doi: 10.1155/2018/4310816

  • CrossRef
  • Google Scholar

• 173

  BelcherJDChenCNguyenJMilbauerLAbdullaFAlayashAIet al. Heme triggers TLR4 signaling leading to endothelial cell activation and vaso-occlusion in murine sickle cell disease. Blood (2014) 123(3):377–90. doi: 10.1182/blood-2013-04-495887

  • CrossRef
  • Google Scholar

• 174

  DeuelJWVallelianFSchaerCAPugliaMBuehlerPWSchaerDJ. Different target specificities of haptoglobin and hemopexin define a sequential protection system against vascular hemoglobin toxicity. Free Radical Biol Med (2015) 89:931–43. doi: 10.1016/j.freeradbiomed.2015.09.016

  • CrossRef
  • Google Scholar

• 175

  FigueiredoRTFernandezPLMourao-SaDSPortoBNDutraFFAlvesLSet al. Characterization of heme as activator of Toll-like receptor 4. J Biol Chem (2007) 282(28):20221–9. doi: 10.1074/jbc.M610737200

  • CrossRef
  • Google Scholar

• 176

  KapetanakiMGGbotoshoOTSharmaDWeidertFOfori-AcquahSFKatoGJ. Free heme regulates placenta growth factor through NRF2-antioxidant response signaling. Free Radic Biol Med (2019) 143:300–8. doi: 10.1016/j.freeradbiomed.2019.08.009

  • CrossRef
  • Google Scholar

• 177

  GladwinMTOfori-AcquahSF. Erythroid DAMPs drive inflammation in SCD. Blood (2014) 123(24):3689–90. doi: 10.1182/blood-2014-03-563874

  • CrossRef
  • Google Scholar

• 178

  MendoncaRSilveiraAAConranN. Red cell DAMPs and inflammation. Inflammation Res (2016) 65(9):665–78. doi: 10.1007/s00011-016-0955-9

  • CrossRef
  • Google Scholar

• 179

  XiangMShiXLiYXuJYinLXiaoGet al. Hemorrhagic shock activation of NLRP3 inflammasome in lung endothelial cells. J Immunol (2011) 187(9):4809–17. doi: 10.4049/jimmunol.1102093

  • CrossRef
  • Google Scholar

• 180

  VogelSTheinSL. Platelets at the crossroads of thrombosis, inflammation and haemolysis. Br J Haematol (2018) 180(5):761–7. doi: 10.1111/bjh.15117

  • CrossRef
  • Google Scholar

• 181

  MaedaRKawasakiYKumeYGoHSuyamaKHosoyaM. Involvement of high mobility group box 1 in the pathogenesis of severe hemolytic uremic syndrome in a murine model. Am J Physiol Renal Physiol (2019) 317(6):F1420–F9. doi: 10.1152/ajprenal.00263.2019

  • CrossRef
  • Google Scholar

• 182

  AtagaKIOrringerEP. Hypercoagulability in sickle cell disease: a curious paradox. Am J Med (2003) 115(9):721–8. doi: 10.1016/j.amjmed.2003.07.011

  • CrossRef
  • Google Scholar

• 183

  WangHBloomOZhangMVishnubhakatJMOmbrellinoMCheJet al. HMG-1 as a late mediator of endotoxin lethality in mice. Science (1999) 285(5425):248–51. doi: 10.1126/science.285.5425.248

  • CrossRef
  • Google Scholar

• 184

  XuHWanderseeNJGuoYJonesDWHolzhauerSLHansonMSet al. Sickle cell disease increases high mobility group box 1: a novel mechanism of inflammation. Blood (2014) 124(26):3978–81. doi: 10.1182/blood-2014-04-560813

  • CrossRef
  • Google Scholar

• 185

  VogelSAroraTWangXMendelsohnLNicholsJAllenDet al. The platelet NLRP3 inflammasome is upregulated in sickle cell disease via HMGB1/TLR4 and Bruton tyrosine kinase. Blood Adv (2018) 2(20):2672–80. doi: 10.1182/bloodadvances.2018021709

  • CrossRef
  • Google Scholar

• 186

  MurthyPDurcoFMiller-OcuinJLTakedaiTShankarSLiangXet al. The NLRP3 inflammasome and bruton’s tyrosine kinase in platelets co-regulate platelet activation, aggregation, and in vitro thrombus formation. Biochem Biophys Res Commun (2017) 483(1):230–6. doi: 10.1016/j.bbrc.2016.12.161

  • CrossRef
  • Google Scholar

• 187

  PetrilloSChiabrandoDGenovaTFioritoVIngogliaGVinchiFet al. Heme accumulation in endothelial cells impairs angiogenesis by triggering paraptosis. Cell Death Differ (2018) 25(3):573–88. doi: 10.1038/s41418-017-0001-7

  • CrossRef
  • Google Scholar

• 188

  WagenerFAFeldmanEde WitteTAbrahamNG. Heme induces the expression of adhesion molecules ICAM-1, VCAM-1, and E selectin in vascular endothelial cells. Proc Soc Exp Biol Med Soc Exp Biol Med (1997) 216(3):456–63. doi: 10.3181/00379727-216-44197

  • CrossRef
  • Google Scholar

• 189

  TelenMJ. Cellular adhesion and the endothelium: E-selectin, L-selectin, and pan-selectin inhibitors. Hematology/Oncology Clinics North America (2014) 28(2):341–54. doi: 10.1016/j.hoc.2013.11.010

  • CrossRef
  • Google Scholar

• 190

  HidalgoAChangJJangJEPeiredAJChiangEYFrenettePS. Heterotypic interactions enabled by polarized neutrophil microdomains mediate thromboinflammatory injury. Nat Med (2009) 15(4):384–91. doi: 10.1038/nm.1939

  • CrossRef
  • Google Scholar

• 191

  GeeBEPlattOS. Sickle reticulocytes adhere to VCAM-1. Blood (1995) 85(1):268–74. doi: 10.1182/blood.V85.1.268.bloodjournal851268

  • CrossRef
  • Google Scholar

• 192

  KucukalEIlichAKeyNSLittleJAGurkanUA. Red Blood Cell Adhesion to Heme-Activated Endothelial Cells Reflects Clinical Phenotype in Sickle Cell Disease. Am J Hematol (2018) 93(8):1050–60. doi: 10.1002/ajh.25159

  • CrossRef
  • Google Scholar

• 193

  MatsuiNMBorsigLRosenSDYaghmaiMVarkiA. Embury SH. P-selectin mediates the adhesion of sickle erythrocytes to the endothelium. Blood (2001) 98(6):1955–62. doi: 10.1182/blood.V98.6.1955

  • CrossRef
  • Google Scholar

• 194

  MatsuiNMVarkiAEmburySH. Heparin inhibits the flow adhesion of sickle red blood cells to P-selectin. Blood (2002) 100(10):3790–6. doi: 10.1182/blood-2002-02-0626

  • CrossRef
  • Google Scholar

• 195

  EmburySHMatsuiNMRamanujamSMayadasTNNoguchiCTDiwanBAet al. The contribution of endothelial cell P-selectin to the microvascular flow of mouse sickle erythrocytes in vivo. Blood (2004) 104(10):3378–85. doi: 10.1182/blood-2004-02-0713

  • CrossRef
  • Google Scholar

• 196

  GhoshSFlageBWeidertFOfori-AcquahSF. P-selectin plays a role in haem-induced acute lung injury in sickle mice. Br J Haematol (2019) 186(2):329–33. doi: 10.1111/bjh.15807

  • CrossRef
  • Google Scholar

• 197

  ChangJPattonJTSarkarAErnstBMagnaniJLFrenettePS. GMI-1070, a novel pan-selectin antagonist, reverses acute vascular occlusions in sickle cell mice. Blood (2010) 116(10):1779–86. doi: 10.1182/blood-2009-12-260513

  • CrossRef
  • Google Scholar

• 198

  AtagaKIKutlarAKanterJLilesDCancadoRFriedrischJet al. Crizanlizumab for the Prevention of Pain Crises in Sickle Cell Disease. New Engl J Med (2017) 376(5):429–39. doi: 10.1056/NEJMoa1611770

  • CrossRef
  • Google Scholar

• 199

  KutlarAKanterJLilesDKAlvarezOACancadoRDFriedrischJRet al. Effect of crizanlizumab on pain crises in subgroups of patients with sickle cell disease: A SUSTAIN study analysis. Am J Hematol (2019) 94(1):55–61. doi: 10.1002/ajh.25308

  • CrossRef
  • Google Scholar

• 200

  Polanowska-GrabowskaRWallaceKFieldJJChenLMarshallMAFiglerRet al. P-selectin-mediated platelet-neutrophil aggregate formation activates neutrophils in mouse and human sickle cell disease. Arteriosclerosis thrombosis Vasc Biol (2010) 30(12):2392–9. doi: 10.1161/ATVBAHA.110.211615

  • CrossRef
  • Google Scholar

• 201

  Keleku-LukweteNSuzukiMPandaHOtsukiAKatsuokaFSaitoRet al. Nrf2 activation in myeloid cells and endothelial cells differentially mitigates sickle cell disease pathology in mice. Blood Adv (2019) 3(8):1285–97. doi: 10.1182/bloodadvances.2018017574

  • CrossRef
  • Google Scholar

• 202

  MerleNSPauleRLeonJDauganMRobe-RybkineTPoilleratVet al. P-selectin drives complement attack on endothelium during intravascular hemolysis in TLR-4/heme-dependent manner. Proc Natl Acad Sci USA (2019) 116(13):6280–5. doi: 10.1073/pnas.1814797116

  • CrossRef
  • Google Scholar

• 203

  BennewitzMFJimenezMAVatsRTutuncuogluEJonassaintJKatoGJet al. Lung vaso-occlusion in sickle cell disease mediated by arteriolar neutrophil-platelet microemboli. JCI Insight (2017) 2(1):e89761. doi: 10.1172/jci.insight.89761

  • CrossRef
  • Google Scholar

• 204

  KatoGJMartyrSBlackwelderWCNicholsJSColesWAHunterLAet al. Levels of soluble endothelium-derived adhesion molecules in patients with sickle cell disease are associated with pulmonary hypertension, organ dysfunction, and mortality. Br J Haematol (2005) 130(6):943–53. doi: 10.1111/j.1365-2141.2005.05701.x

  • CrossRef
  • Google Scholar

• 205

  Antwi-BoasiakoCDonkorESSeyFDzudzorBDankwahGBOtuKHet al. Levels of Soluble Endothelium Adhesion Molecules and Complications among Sickle Cell Disease Patients in Ghana. Diseases (2018) 6(2):1–7. doi: 10.3390/diseases6020029

  • CrossRef
  • Google Scholar

• 206

  SettyBNStuartMJDampierCBrodeckiDAllenJL. Hypoxaemia in sickle cell disease: biomarker modulation and relevance to pathophysiology. Lancet (2003) 362(9394):1450–5. doi: 10.1016/S0140-6736(03)14689-2

  • CrossRef
  • Google Scholar

• 207

  ElmariahHGarrettMEDe CastroLMJonassaintJCAtagaKIEckmanJRet al. Factors associated with survival in a contemporary adult sickle cell disease cohort. Am J Hematol (2014) 89(5):530–5. doi: 10.1002/ajh.23683

  • CrossRef
  • Google Scholar

• 208

  KeikhaeiBMohseniARNorouziradRAlinejadiMGhanbariSShiraviFet al. Altered levels of pro-inflammatory cytokines in sickle cell disease patients during vaso-occlusive crises and the steady state condition. Eur Cytokine Netw (2013) 24(1):45–52. doi: 10.1684/ecn.2013.0328

  • CrossRef
  • Google Scholar

• 209

  KhalyfaAKhalyfaAAAkbarpourMConnesPRomanaMLapping-CarrGet al. Extracellular microvesicle microRNAs in children with sickle cell anaemia with divergent clinical phenotypes. Br J Haematol (2016) 174(5):786–98. doi: 10.1111/bjh.14104

  • CrossRef
  • Google Scholar

• 210

  JainSKapetanakiMGRaghavachariNWoodhouseKYuGBargeSet al. Expression of regulatory platelet microRNAs in patients with sickle cell disease. PloS One (2013) 8(4):e60932. doi: 10.1371/journal.pone.0060932

  • CrossRef
  • Google Scholar

• 211

  BarkerKRLuZKimHZhengYChenJConroyALet al. miR-155 Modifies Inflammation, Endothelial Activation and Blood-Brain Barrier Dysfunction in Cerebral Malaria. Mol Med (Cambridge Mass) (2017) 23:24–33. doi: 10.2119/molmed.2016.00139

  • CrossRef
  • Google Scholar

• 212

  CohenAZingerATibertiNGrauGERCombesV. Differential plasma microvesicle and brain profiles of microRNA in experimental cerebral malaria. Malaria J (2018) 17(1):192. doi: 10.1186/s12936-018-2330-5

  • CrossRef
  • Google Scholar

• 213

  FallerMMatsunagaMYinSLooJAGuoF. Heme is involved in microRNA processing. Nat Struct Mol Biol (2007) 14(1):23–9. doi: 10.1038/nsmb1182

  • CrossRef
  • Google Scholar

• 214

  CimminoACalinGAFabbriMIorioMVFerracinMShimizuMet al. miR-15 and miR-16 induce apoptosis by targeting BCL2. Proc Natl Acad Sci USA (2005) 102(39):13944–9. doi: 10.1073/pnas.0506654102

  • CrossRef
  • Google Scholar

• 215

  ChenCZLiLLodishHFBartelDP. MicroRNAs modulate hematopoietic lineage differentiation. Science (2004) 303(5654):83–6. doi: 10.1126/science.1091903

  • CrossRef
  • Google Scholar

• 216

  BrenneckeJHipfnerDRStarkARussellRBCohenSM. bantam encodes a developmentally regulated microRNA that controls cell proliferation and regulates the proapoptotic gene hid in Drosophila. Cell (2003) 113(1):25–36. doi: 10.1016/S0092-8674(03)00231-9

  • CrossRef
  • Google Scholar

• 217

  GuoZWuRGongJZhuWLiYWangZet al. Altered microRNA expression in inflamed and non-inflamed terminal ileal mucosa of adult patients with active Crohn’s disease. J Gastroenterol Hepatology (2015) 30(1):109–16. doi: 10.1111/jgh.12644

  • CrossRef
  • Google Scholar

• 218

  LuJGetzGMiskaEAAlvarez-SaavedraELambJPeckDet al. MicroRNA expression profiles classify human cancers. Nature (2005) 435(7043):834–8. doi: 10.1038/nature03702

  • CrossRef
  • Google Scholar

• 219

  AlevizosIIlleiGG. MicroRNAs as biomarkers in rheumatic diseases. Nat Rev Rheumatol (2010) 6(7):391–8. doi: 10.1038/nrrheum.2010.81

  • CrossRef
  • Google Scholar

• 220

  NakasaTMiyakiSOkuboAHashimotoMNishidaKOchiMet al. Expression of microRNA-146 in rheumatoid arthritis synovial tissue. Arthritis Rheumatism (2008) 58(5):1284–92. doi: 10.1002/art.23429

  • CrossRef
  • Google Scholar

• 221

  PekowJRKwonJH. MicroRNAs in inflammatory bowel disease. Inflammatory bowel Diseases (2012) 18(1):187–93. doi: 10.1002/ibd.21691

  • CrossRef
  • Google Scholar

• 222

  TomankovaTPetrekMKriegovaE. Involvement of microRNAs in physiological and pathological processes in the lung. Respiratory Res (2010) 11:159. doi: 10.1186/1465-9921-11-159

  • CrossRef
  • Google Scholar

• 223

  WeitzSHGongMBarrIWeissSGuoF. Processing of microRNA primary transcripts requires heme in mammalian cells. Proc Natl Acad Sci USA (2014) 111(5):1861–6. doi: 10.1073/pnas.1309915111

  • CrossRef
  • Google Scholar

• 224

  NguyenTAParkJDangTLChoiYGKimVN. Microprocessor depends on hemin to recognize the apical loop of primary microRNA. Nucleic Acids Res (2018) 46(11):5726–36. doi: 10.1093/nar/gky248

  • CrossRef
  • Google Scholar

• 225

  BarrISmithATChenYSenturiaRBurstynJNGuoF. Ferric, not ferrous, heme activates RNA-binding protein DGCR8 for primary microRNA processing. Proc Natl Acad Sci USA (2012) 109(6):1919–24. doi: 10.1073/pnas.1114514109

  • CrossRef
  • Google Scholar

• 226

  KirschnerMBEdelmanJJKaoSCVallelyMPvan ZandwijkNReidG. The Impact of Hemolysis on Cell-Free microRNA Biomarkers. Front Genet (2013) 4:94. doi: 10.3389/fgene.2013.00094

  • CrossRef
  • Google Scholar

• 227

  PizzamiglioSZanuttoSCiniselliCMBelfioreABottelliSGariboldiMet al. A methodological procedure for evaluating the impact of hemolysis on circulating microRNAs. Oncol Lett (2017) 13(1):315–20. doi: 10.3892/ol.2016.5452

  • CrossRef
  • Google Scholar

• 228

  ChenSYWangYTelenMJChiJT. The genomic analysis of erythrocyte microRNA expression in sickle cell diseases. PloS One (2008) 3(6):e2360. doi: 10.1371/journal.pone.0002360

  • CrossRef
  • Google Scholar

• 229

  ByonJCPapayannopoulouT. MicroRNAs: Allies or foes in erythropoiesis? J Cell Physiol (2012) 227(1):7–13. doi: 10.1002/jcp.22729

  • CrossRef
  • Google Scholar

• 230

  SangokoyaCTelenMJChiJT. microRNA miR-144 modulates oxidative stress tolerance and associates with anemia severity in sickle cell disease. Blood (2010) 116(20):4338–48. doi: 10.1182/blood-2009-04-214817

  • CrossRef
  • Google Scholar

• 231

  LiBZhuXWardCMStarlard-DavenportATakezakiMBerryAet al. MIR-144-mediated NRF2 gene silencing inhibits fetal hemoglobin expression in sickle cell disease. Exp Hematol (2019) 70:85–96 e5. doi: 10.1016/j.exphem.2018.11.002

  • CrossRef
  • Google Scholar

• 232

  DesaiAAZhouTAhmadHZhangWMuWTrevinoSet al. A novel molecular signature for elevated tricuspid regurgitation velocity in sickle cell disease. Am J Respir Crit Care Med (2012) 186(4):359–68. doi: 10.1164/rccm.201201-0057OC

  • CrossRef
  • Google Scholar

• 233

  HaTY. MicroRNAs in Human Diseases: From Lung, Liver and Kidney Diseases to Infectious Disease, Sickle Cell Disease and Endometrium Disease. Immune Netw (2011) 11(6):309–23. doi: 10.4110/in.2011.11.6.309

  • CrossRef
  • Google Scholar

• 234

  LuMZhangQDengMMiaoJGuoYGaoWet al. An analysis of human microRNA and disease associations. PloS One (2008) 3(10):e3420. doi: 10.1371/journal.pone.0003420

  • CrossRef
  • Google Scholar

• 235

  SmallEMFrostRJOlsonEN. MicroRNAs add a new dimension to cardiovascular disease. Circulation (2010) 121(8):1022–32. doi: 10.1161/CIRCULATIONAHA.109.889048

  • CrossRef
  • Google Scholar

• 236

  BarringhausKGZamorePD. MicroRNAs: regulating a change of heart. Circulation (2009) 119(16):2217–24. doi: 10.1161/CIRCULATIONAHA.107.715839

  • CrossRef
  • Google Scholar

• 237

  LatronicoMVCondorelliG. MicroRNAs and cardiac pathology. Nat Rev Cardiol (2009) 6(6):419–29. doi: 10.1038/nrcardio.2009.56

  • CrossRef
  • Google Scholar

• 238

  JoplingCLYiMLancasterAMLemonSMSarnowP. Modulation of hepatitis C virus RNA abundance by a liver-specific MicroRNA. Science (2005) 309(5740):1577–81. doi: 10.1126/science.1113329

  • CrossRef
  • Google Scholar

• 239

  WangKZhangSMarzolfBTroischPBrightmanAHuZet al. Circulating microRNAs, potential biomarkers for drug-induced liver injury. Proc Natl Acad Sci USA (2009) 106(11):4402–7. doi: 10.1073/pnas.0813371106

  • CrossRef
  • Google Scholar

• 240

  PandeyPBrorsBSrivastavaPKBottABoehnSNGroeneHJet al. Microarray-based approach identifies microRNAs and their target functional patterns in polycystic kidney disease. BMC Genomics (2008) 9:624. doi: 10.1186/1471-2164-9-624

  • CrossRef
  • Google Scholar

• 241

  ChaturvediSDeBaunMR. Evolution of sickle cell disease from a life-threatening disease of children to a chronic disease of adults: The last 40 years. Am J Hematol (2016) 91(1):5–14. doi: 10.1002/ajh.24235

  • CrossRef
  • Google Scholar

• 242

  HuangEParkeCMehrniaAKamgarMPhamPTDanovitchGet al. Improved survival among sickle cell kidney transplant recipients in the recent era. Nephrol Dial Transplant Off Publ Eur Dialysis Transplant Assoc - Eur Renal Assoc (2013) 28(4):1039–46. doi: 10.1093/ndt/gfs585

  • CrossRef
  • Google Scholar

• 243

  NathKAHebbelRP. Sickle cell disease: renal manifestations and mechanisms. Nat Rev Nephrol (2015) 11(3):161–71. doi: 10.1038/nrneph.2015.8

  • CrossRef
  • Google Scholar

• 244

  DayTGDrasarERFulfordTSharpeCCTheinSL. Association between hemolysis and albuminuria in adults with sickle cell anemia. Haematologica (2012) 97(2):201–5. doi: 10.3324/haematol.2011.050336

  • CrossRef
  • Google Scholar

• 245

  PlewesKKingstonHWFGhoseAMaudeRJHerdmanMTLeopoldSJet al. Cell-free hemoglobin mediated oxidative stress is associated with acute kidney injury and renal replacement therapy in severe falciparum malaria: an observational study. BMC Infect Dis (2017) 17(1):313. doi: 10.1186/s12879-017-2373-1

  • CrossRef
  • Google Scholar

• 246

  GaggarAPatelRP. There is blood in the water: hemolysis, hemoglobin, and heme in acute lung injury. Am J Physiol Lung Cell Mol Physiol (2016) 311(4):L714–L8. doi: 10.1152/ajplung.00312.2016

  • CrossRef
  • Google Scholar

• 247

  GliozziMLRbaibiYLongKRVitturiDAWeiszOA. Hemoglobin alters vitamin carrier uptake and vitamin D metabolism in proximal tubule cells: implications for sickle cell disease. Am J Physiol Cell Physiol (2019) 317(5):C993–C1000. doi: 10.1152/ajpcell.00287.2019

  • CrossRef
  • Google Scholar

• 248

  van SwelmRPWetzelsJFVerweijVGLaarakkersCMPertijsJCvan der WijstJet al. Renal Handling of Circulating and Renal-Synthesized Hepcidin and Its Protective Effects against Hemoglobin-Mediated Kidney Injury. J Am Soc Nephrol JASN (2016) 27(9):2720–32. doi: 10.1681/ASN.2015040461

  • CrossRef
  • Google Scholar

• 249

  ScheinAEnriquezCCoatesTDWoodJC. Magnetic resonance detection of kidney iron deposition in sickle cell disease: a marker of chronic hemolysis. J Magn Reson Imaging (2008) 28(3):698–704. doi: 10.1002/jmri.21490

  • CrossRef
  • Google Scholar

• 250

  VasavdaNGutierrezLHouseMJDrasarESt PierreTGTheinSL. Renal iron load in sickle cell disease is influenced by severity of haemolysis. Br J Haematol (2012) 157(5):599–605. doi: 10.1111/j.1365-2141.2012.09093.x

  • CrossRef
  • Google Scholar

• 251

  GurkanSScarponiKJHotchkissHSavageBDrachtmanR. Lactate dehydrogenase as a predictor of kidney involvement in patients with sickle cell anemia. Pediatr Nephrol (2010) 25(10):2123–7. doi: 10.1007/s00467-010-1560-8

  • CrossRef
  • Google Scholar

• 252

  SarafSLZhangXKaniasTLashJPMolokieREOzaBet al. Haemoglobinuria is associated with chronic kidney disease and its progression in patients with sickle cell anaemia. Br J Haematol (2014) 164(5):729–39. doi: 10.1111/bjh.12690

  • CrossRef
  • Google Scholar

• 253

  BarberBEGriggMJPieraKAWilliamTCooperDJPlewesKet al. Intravascular haemolysis in severe Plasmodium knowlesi malaria: association with endothelial activation, microvascular dysfunction, and acute kidney injury. Emerging microbes Infect (2018) 7(1):106. doi: 10.1038/s41426-018-0105-2

  • CrossRef
  • Google Scholar

• 254

  NathKAGrandeJPHaggardJJCroattAJKatusicZSSoloveyAet al. Oxidative stress and induction of heme oxygenase-1 in the kidney in sickle cell disease. Am J Pathol (2001) 158(3):893–903. doi: 10.1016/S0002-9440(10)64037-0

  • CrossRef
  • Google Scholar

• 255

  NathKAHaggardJJCroattAJGrandeJPPossKDAlamJ. The indispensability of heme oxygenase-1 in protecting against acute heme protein-induced toxicity in vivo. Am J Pathol (2000) 156(5):1527–35. doi: 10.1016/S0002-9440(10)65024-9

  • CrossRef
  • Google Scholar

• 256

  NathKAVercellottiGMGrandeJPMiyoshiHPayaCVManivelJCet al. Heme protein-induced chronic renal inflammation: suppressive effect of induced heme oxygenase-1. Kidney Int (2001) 59(1):106–17. doi: 10.1046/j.1523-1755.2001.00471.x

  • CrossRef
  • Google Scholar

• 257

  Rubio-NavarroAVazquez-CarballoCGuerrero-HueMGarcia-CaballeroCHerenciaCGutierrezEet al. Nrf2 Plays a Protective Role Against Intravascular Hemolysis-Mediated Acute Kidney Injury. Front Pharmacol (2019) 10:740. doi: 10.3389/fphar.2019.00740

  • CrossRef
  • Google Scholar

• 258

  NathKABelcherJDNathMCGrandeJPCroattAJAckermanAWet al. Role of TLR4 signaling in the nephrotoxicity of heme and heme proteins. Am J Physiol Renal Physiol (2018) 314(5):F906–F14. doi: 10.1152/ajprenal.00432.2017

  • CrossRef
  • Google Scholar

• 259

  PiazzaMDamoreGCostaBGioanniniTLWeissJPPeriF. Hemin and a metabolic derivative coprohemin modulate the TLR4 pathway differently through different molecular targets. Innate Immun (2011) 17(3):293–301. doi: 10.1177/1753425910369020

  • CrossRef
  • Google Scholar

• 260

  WeiQHillWDSuYHuangSDongZ. Heme oxygenase-1 induction contributes to renoprotection by G-CSF during rhabdomyolysis-associated acute kidney injury. Am J Physiol Renal Physiol (2011) 301(1):F162–70. doi: 10.1152/ajprenal.00438.2010

  • CrossRef
  • Google Scholar

• 261

  Gonzalez-MichacaLFarrugiaGCroattAJAlamJNathKA. Heme: a determinant of life and death in renal tubular epithelial cells. Am J Physiol Renal Physiol (2004) 286(2):F370–7. doi: 10.1152/ajprenal.00300.2003

  • CrossRef
  • Google Scholar

• 262

  IrwinDCBaekJHHassellKNussREigenbergerPLiskCet al. Hemoglobin-induced lung vascular oxidation, inflammation, and remodeling contribute to the progression of hypoxic pulmonary hypertension and is attenuated in rats with repeated-dose haptoglobin administration. Free Radical Biol Med (2015) 82:50–62. doi: 10.1016/j.freeradbiomed.2015.01.012

  • CrossRef
  • Google Scholar

• 263

  GhoshSAdisaOAChappaPTanFJacksonKAArcherDRet al. Extracellular hemin crisis triggers acute chest syndrome in sickle mice. J Clin Investig (2013) 123(11):4809–20. doi: 10.1172/JCI64578

  • CrossRef
  • Google Scholar

• 264

  BilanVPSchneiderFNovelliEMKelleyEEShivaSGladwinMTet al. Experimental intravascular hemolysis induces hemodynamic and pathological pulmonary hypertension: association with accelerated purine metabolism. Pulmonary circulation (2018) 8(3):1–15. doi: 10.1177/2045894018791557

  • CrossRef
  • Google Scholar

• 265

  ShaverCMUpchurchCPJanzDRGroveBSPutzNDWickershamNEet al. Cell-free hemoglobin: a novel mediator of acute lung injury. Am J Physiol Lung Cell Mol Physiol (2016) 310(6):L532–41. doi: 10.1152/ajplung.00155.2015

  • CrossRef
  • Google Scholar

• 266

  SinglaSSysolJRDilleBJonesNChenJMachadoRF. Hemin Causes Lung Microvascular Endothelial Barrier Dysfunction by Necroptotic Cell Death. Am J Respir Cell Mol Biol (2017) 57(3):307–14. doi: 10.1165/rcmb.2016-0287OC

  • CrossRef
  • Google Scholar

• 267

  LiuYJingFYiWMendelsonAShiPWalshRet al. HO-1(hi) patrolling monocytes protect against vaso-occlusion in sickle cell disease. Blood (2018) 131(14):1600–10. doi: 10.1182/blood-2017-12-819870

  • CrossRef
  • Google Scholar

• 268

  FeldJJKatoGJKohCShieldsTHildesheimMKleinerDEet al. Liver injury is associated with mortality in sickle cell disease. Alimentary Pharmacol Ther (2015) 42(7):912–21. doi: 10.1111/apt.13347

  • CrossRef
  • Google Scholar

• 269

  DeySBinduSGoyalMPalCAlamAIqbalMSet al. Impact of intravascular hemolysis in malaria on liver dysfunction: involvement of hepatic free heme overload, NF-kappaB activation, and neutrophil infiltration. J Biol Chem (2012) 287(32):26630–46. doi: 10.1074/jbc.M112.341255

  • CrossRef
  • Google Scholar

• 270

  HsuLChampionHCampbell-LeeSBivalacquaTManciEDiwanBet al. Hemolysis in sickle cell mice causes pulmonary hypertension due to global impairment in nitric oxide bioavailability. Blood (2007) 109(7):3088–98. doi: 10.1182/blood-2006-08-039438

  • CrossRef
  • Google Scholar

• 271

  GladwinMTKatoGJ. Cardiopulmonary complications of sickle cell disease: role of nitric oxide and hemolytic anemia. Hematol Am Soc Hematol Educ Program (2005) 2005:51–7. doi: 10.1182/asheducation-2005.1.51

  • CrossRef
  • Google Scholar

• 272

  MoraesJABarcellos-de-SouzaPRodriguesGNascimento-SilvaVSilvaSVAssreuyJet al. Heme modulates smooth muscle cell proliferation and migration via NADPH oxidase: a counter-regulatory role for heme oxygenase system. Atherosclerosis (2012) 224(2):394–400. doi: 10.1016/j.atherosclerosis.2012.07.043

  • CrossRef
  • Google Scholar

• 273

  QiLvan DamRMRexrodeKHuFB. Heme iron from diet as a risk factor for coronary heart disease in women with type 2 diabetes. Diabetes Care (2007) 30(1):101–6. doi: 10.2337/dc06-1686

  • CrossRef
  • Google Scholar

• 274

  FangXAnPWangHWangXShenXLiXet al. Dietary intake of heme iron and risk of cardiovascular disease: a dose-response meta-analysis of prospective cohort studies. Nutrition metabolism Cardiovasc Dis NMCD (2015) 25(1):24–35. doi: 10.1016/j.numecd.2014.09.002

  • CrossRef
  • Google Scholar

• 275

  IngogliaGSagCMRexNDe FranceschiLVinchiFCiminoJet al. Hemopexin counteracts systolic dysfunction induced by heme-driven oxidative stress. Free Radical Biol Med (2017) 108:452–64. doi: 10.1016/j.freeradbiomed.2017.04.003

  • CrossRef
  • Google Scholar

• 276

  VinchiFDe FranceschiLGhigoATownesTCiminoJSilengoLet al. Hemopexin therapy improves cardiovascular function by preventing heme-induced endothelial toxicity in mouse models of hemolytic diseases. Circulation (2013) 127(12):1317–29. doi: 10.1161/CIRCULATIONAHA.112.130179

  • CrossRef
  • Google Scholar

• 277

  KhechaduriABayevaMChangHCArdehaliH. Heme levels are increased in human failing hearts. J Am Coll Cardiol (2013) 61(18):1884–93. doi: 10.1016/j.jacc.2013.02.012

  • CrossRef
  • Google Scholar

• 278

  SawickiKTShangMWuRChangHCKhechaduriASatoTet al. Increased Heme Levels in the Heart Lead to Exacerbated Ischemic Injury. J Am Heart Assoc (2015) 4(8):e002272. doi: 10.1161/JAHA.115.002272

  • CrossRef
  • Google Scholar

• 279

  AlvaradoGJeneyVTothACsoszEKalloGHuynhATet al. Heme-induced contractile dysfunction in human cardiomyocytes caused by oxidant damage to thick filament proteins. Free Radical Biol Med (2015) 89:248–62. doi: 10.1016/j.freeradbiomed.2015.07.158

  • CrossRef
  • Google Scholar

• 280

  SundaramNTailorAMendelsohnLWansapuraJWangXHigashimotoTet al. High levels of placenta growth factor in sickle cell disease promote pulmonary hypertension. Blood (2010) 116(1):109–12. doi: 10.1182/blood-2009-09-244830

  • CrossRef
  • Google Scholar

• 281

  MaglioneDGuerrieroVVigliettoGDelli-BoviPPersicoMG. Isolation of a human placenta cDNA coding for a protein related to the vascular permeability factor. Proc Natl Acad Sci U S A (1991) 88(20):9267–71. doi: 10.1073/pnas.88.20.9267

  • CrossRef
  • Google Scholar

• 282

  PersicoMGVincentiVDiPalmaT. Structure, expression and receptor-binding properties of placenta growth factor (PlGF). Curr Top Microbiol Immunol (1999) 237:31–40. doi: 10.1007/978-3-642-59953-8_2

  • CrossRef
  • Google Scholar

• 283

  IyerSLeonidasDDSwaminathanGJMaglioneDBattistiMTucciMet al. The crystal structure of human placenta growth factor-1 (PlGF-1), an angiogenic protein, at 2.0 A resolution. J Biol Chem (2001) 276(15):12153–61. doi: 10.1074/jbc.M008055200

  • CrossRef
  • Google Scholar

• 284

  ParkJEChenHHWinerJHouckKAFerraraN. Placenta growth factor. Potentiation of vascular endothelial growth factor bioactivity, in vitro and in vivo, and high affinity binding to Flt-1 but not to Flk-1/KDR. J Biol Chem (1994) 269(41):25646–54. doi: 10.1074/jbc.M008055200

  • CrossRef
  • Google Scholar

• 285

  CarmelietPMoonsLLuttunAVincentiVCompernolleVDe MolMet al. Synergism between vascular endothelial growth factor and placental growth factor contributes to angiogenesis and plasma extravasation in pathological conditions. Nat Med (2001) 7(5):575–83. doi: 10.1038/87904

  • CrossRef
  • Google Scholar

• 286

  TaralloVVesciLCapassoOEspositoMTRiccioniTPastoreLet al. A placental growth factor variant unable to recognize vascular endothelial growth factor (VEGF) receptor-1 inhibits VEGF-dependent tumor angiogenesis via heterodimerization. Cancer Res (2010) 70(5):1804–13. doi: 10.1158/0008-5472.CAN-09-2609

  • CrossRef
  • Google Scholar

• 287

  AutieroMWaltenbergerJCommuniDKranzAMoonsLLambrechtsDet al. Role of PlGF in the intra- and intermolecular cross talk between the VEGF receptors Flt1 and Flk1. Nat Med (2003) 9(7):936–43. doi: 10.1038/nm884

  • CrossRef
  • Google Scholar

• 288

  MamlukRGechtmanZKutcherMEGasiunasNGallagherJKlagsbrunM. Neuropilin-1 binds vascular endothelial growth factor 165, placenta growth factor-2, and heparin via its b1b2 domain. J Biol Chem (2002) 277(27):24818–25. doi: 10.1074/jbc.M200730200

  • CrossRef
  • Google Scholar

• 289

  GaurPBielenbergDRSamuelSBoseDZhouYGrayMJet al. Role of class 3 semaphorins and their receptors in tumor growth and angiogenesis. Clin Cancer Res (2009) 15(22):6763–70. doi: 10.1158/1078-0432.CCR-09-1810

  • CrossRef
  • Google Scholar

• 290

  RoyHBhardwajSBabuMJauhiainenSHerzigKHBelluARet al. Adenovirus-mediated gene transfer of placental growth factor to perivascular tissue induces angiogenesis via upregulation of the expression of endogenous vascular endothelial growth factor-A. Hum Gene Ther (2005) 16(12):1422–8. doi: 10.1089/hum.2005.16.1422

  • CrossRef
  • Google Scholar

• 291

  MarcelliniMDe LucaNRiccioniTCiucciAOrecchiaALacalPMet al. Increased melanoma growth and metastasis spreading in mice overexpressing placenta growth factor. Am J Pathol (2006) 169(2):643–54. doi: 10.2353/ajpath.2006.051041

  • CrossRef
  • Google Scholar

• 292

  HuangXXMcCaughanGWShackelNAGorrellMD. Up-regulation of proproliferative genes and the ligand/receptor pair placental growth factor and vascular endothelial growth factor receptor 1 in hepatitis C cirrhosis. Liver Int (2007) 27(7):960–8. doi: 10.1111/j.1478-3231.2007.01542.x

  • CrossRef
  • Google Scholar

• 293

  ClaussMWeichHBreierGKniesURöcklWWaltenbergerJet al. The Vascular Endothelial Growth Factor Receptor Flt-1 Mediates Biological Activities: Implications For A Functional Role Of Placenta Growth Factor In Monocyte Activation And Chemotaxis. J Biol Chem (1996) 271(30):17629–34. doi: 10.1074/jbc.271.30.17629

  • CrossRef
  • Google Scholar

• 294

  KellyBDHackettSFHirotaKOshimaYCaiZBerg-DixonSet al. Cell type-specific regulation of angiogenic growth factor gene expression and induction of angiogenesis in nonischemic tissue by a constitutively active form of hypoxia-inducible factor 1. Circ Res (2003) 93(11):1074–81. doi: 10.1161/01.RES.0000102937.50486.1B

  • CrossRef
  • Google Scholar

• 295

  GreenCJLichtlenPHuynhNTYanovskyMLaderouteKRSchaffnerWet al. Placenta growth factor gene expression is induced by hypoxia in fibroblasts: a central role for metal transcription factor-1. Cancer Res (2001) 61(6):2696–703. doi: 10.1074/jbc.271.30.17629

  • CrossRef
  • Google Scholar

• 296

  CramerMNagyIMurphyBJGassmannMHottigerMOGeorgievOet al. NF-kappaB contributes to transcription of placenta growth factor and interacts with metal responsive transcription factor-1 in hypoxic human cells. Biol Chem (2005) 386(9):865–72. doi: 10.1515/BC.2005.101

  • CrossRef
  • Google Scholar

• 297

  ZhangHPalmerRGaoXKreidbergJGeraldWHsiaoLet al. Transcriptional activation of placental growth factor by the forkhead/winged helix transcription factor FoxD1. Curr Biol (2003) 13(18):1625–9. doi: 10.1016/j.cub.2003.08.054

  • CrossRef
  • Google Scholar

• 298

  ChiuYHYangMRWangLJChenMHChangGDChenH. New insights into the regulation of placental growth factor gene expression by the transcription factors GCM1 and DLX3 in human placenta. J Biol Chem (2018) 293(25):9801–11. doi: 10.1074/jbc.RA117.001384

  • CrossRef
  • Google Scholar

• 299

  YaoYGYangHSCaoZDanielssonJDuhEJ. Upregulation of placental growth factor by vascular endothelial growth factor via a post-transcriptional mechanism. FEBS Lett (2005) 579(5):1227–34. doi: 10.1016/j.febslet.2005.01.017

  • CrossRef
  • Google Scholar

• 300

  ShawJHLloydPG. Post-transcriptional regulation of placenta growth factor mRNA by hydrogen peroxide. Microvasc Res (2012) 84(2):155–60. doi: 10.1016/j.mvr.2012.05.009

  • CrossRef
  • Google Scholar

• 301

  DewerchinMCarmelietP. PlGF: A Multitasking Cytokine with Disease-Restricted Activity. Cold Spring Harbor Perspect Med (2012) 2(8):1227–34. doi: 10.1101/cshperspect.a011056

  • CrossRef
  • Google Scholar

• 302

  RakicJMLambertVDevyLLuttunACarmelietPClaesCet al. Placental growth factor, a member of the VEGF family, contributes to the development of choroidal neovascularization. Invest Ophthalmol Vis Sci (2003) 44(7):3186–93. doi: 10.1167/iovs.02-1092

  • CrossRef
  • Google Scholar

• 303

  LuttunATjwaMMoonsLWuYAngelillo-ScherrerALiaoFet al. Revascularization of ischemic tissues by PlGF treatment, and inhibition of tumor angiogenesis, arthritis and atherosclerosis by anti-Flt1. Nat Med (2002) 8(8):831–40. doi: 10.1038/nm731

  • CrossRef
  • Google Scholar

• 304

  De FalcoS. The discovery of placenta growth factor and its biological activity. Exp Mol Med (2012) 44(1):1–9. doi: 10.3858/emm.2012.44.1.025

  • CrossRef
  • Google Scholar

• 305

  OuraHBertonciniJVelascoPBrownLFCarmelietPDetmarM. A critical role of placental growth factor in the induction of inflammation and edema formation. Blood (2003) 101(2):560–7. doi: 10.1182/blood-2002-05-1516

  • CrossRef
  • Google Scholar

• 306

  YooSAYoonHJKimHSChaeCBDe FalcoSChoCSet al. Role of placenta growth factor and its receptor flt-1 in rheumatoid inflammation: a link between angiogenesis and inflammation. Arthritis Rheumatol (2009) 60(2):345–54. doi: 10.1002/art.24289

  • CrossRef
  • Google Scholar

• 307

  MaesCCoenegrachtsLStockmansIDaciELuttunAPetrykAet al. Placental growth factor mediates mesenchymal cell development, cartilage turnover, and bone remodeling during fracture repair. J Clin Invest (2006) 116(5):1230–42. doi: 10.1172/JCI26772

  • CrossRef
  • Google Scholar

• 308

  RolnyCMazzoneMTuguesSLaouiDJohanssonICoulonCet al. HRG inhibits tumor growth and metastasis by inducing macrophage polarization and vessel normalization through downregulation of PlGF. Cancer Cell (2011) 19(1):31–44. doi: 10.1016/j.ccr.2010.11.009

  • CrossRef
  • Google Scholar

• 309

  LinYLLiangYCChiangBL. Placental growth factor down-regulates type 1 T helper immune response by modulating the function of dendritic cells. J Leukoc Biol (2007) 82(6):1473–80. doi: 10.1189/jlb.0307164

  • CrossRef
  • Google Scholar

• 310

  CarnevaleDCifelliGMascioGMadonnaMSbroggioMPerrinoCet al. Placental growth factor regulates cardiac inflammation through the tissue inhibitor of metalloproteinases-3/tumor necrosis factor-alpha-converting enzyme axis: crucial role for adaptive cardiac remodeling during cardiac pressure overload. Circulation (2011) 124(12):1337–50. doi: 10.1161/CIRCULATIONAHA.111.050500

  • CrossRef
  • Google Scholar

• 311

  HattoriKHeissigBWuYDiasSTejadaRFerrisBet al. Placental growth factor reconstitutes hematopoiesis by recruiting VEGFR1(+) stem cells from bone-marrow microenvironment. Nat Med (2002) 8(8):841–9. doi: 10.1038/nm740

  • CrossRef
  • Google Scholar

• 312

  Carlo-StellaCDi NicolaMLongoniPClerisLLavazzaCMilaniRet al. Placental growth factor-1 potentiates hematopoietic progenitor cell mobilization induced by granulocyte colony-stimulating factor in mice and nonhuman primates. Stem Cells (2007) 25(1):252–61. doi: 10.1634/stemcells.2006-0020

  • CrossRef
  • Google Scholar

• 313

  KalraVKZhangSMalikPTaharaSM. Placenta growth factor mediated gene regulation in sickle cell disease. Blood Rev (2018) 32(1):61–70. doi: 10.1016/j.blre.2017.08.008

  • CrossRef
  • Google Scholar

• 314

  PatelNGonsalvesCSMalikPKalraVK. Placenta growth factor augments endothelin-1 and endothelin-B receptor expression via hypoxia-inducible factor-1α. Blood (2008) 112(3):856–65. doi: 10.1182/blood-2007-12-130567

  • CrossRef
  • Google Scholar

• 315

  BrittainJEHulkowerBJonesSKStrayhornDDe CastroLTelenMJet al. Placenta growth factor in sickle cell disease: association with hemolysis and inflammation. Blood (2010) 115(10):2014–20. doi: 10.1182/blood-2009-04-217950

  • CrossRef
  • Google Scholar

• 316

  PerelmanNSelvarajSKBatraSLuckLRErdreich-EpsteinACoatesTDet al. Placenta growth factor activates monocytes and correlates with sickle cell disease severity. Blood (2003) 102(4):1506–14. doi: 10.1182/blood-2002-11-3422

  • CrossRef
  • Google Scholar

• 317

  GuJ-MYuanSSimDAbeKLiuPRosenbruchMet al. Blockade of placental growth factor reduces vaso-occlusive complications in murine models of sickle cell disease. Exp Hematol (2018) 60:73–82.e3. doi: 10.1016/j.exphem.2018.01.002

  • CrossRef
  • Google Scholar

• 318

  GladwinMTSachdevVJisonMLShizukudaYPlehnJFMinterKet al. Pulmonary hypertension as a risk factor for death in patients with sickle cell disease. New Engl J Med (2004) 350(9):886–95. doi: 10.1056/NEJMoa035477

  • CrossRef
  • Google Scholar

• 319

  Graido-GonzalezEDohertyJCBergreenEWOrganGTelferMMcMillenMA. Plasma endothelin-1, cytokine, and prostaglandin E2 levels in sickle cell disease and acute vaso-occlusive sickle crisis. Blood (1998) 92(7):2551–5. doi: 10.1182/blood.V92.7.2551

  • CrossRef
  • Google Scholar

• 320

  RybickiACBenjaminLJ. Increased levels of endothelin-1 in plasma of sickle cell anemia patients. Blood (1998) 92(7):2594–6. doi: 10.1182/blood.V92.7.2594.2594_2594_2596

  • CrossRef
  • Google Scholar

• 321

  QariMHDierUMousaSA. Biomarkers of inflammation, growth factor, and coagulation activation in patients with sickle cell disease. Clin Appl Thromb Hemost (2012) 18(2):195–200. doi: 10.1177/1076029611420992

  • CrossRef
  • Google Scholar

• 322

  LiCGonsalvesCSEiymo Mwa MpolloMSMalikPTaharaSMKalraVK. MicroRNA 648 Targets ET-1 mRNA and is cotranscriptionally regulated with MICAL3 by PAX5. Mol Cell Biol (2015) 35(3):514–28. doi: 10.1128/MCB.01199-14

  • CrossRef
  • Google Scholar

• 323

  GonsalvesCSLiCMalikPTaharaSMKalraVK. Peroxisome proliferator-activated receptor-alpha-mediated transcription of miR-301a and miR-454 and their host gene SKA2 regulates endothelin-1 and PAI-1 expression in sickle cell disease. Biosci Rep (2015) 35(6):195–200. doi: 10.1042/BSR20150190

  • CrossRef
  • Google Scholar

• 324

  LiCMpolloMSGonsalvesCSTaharaSMMalikPKalraVK. Peroxisome proliferator-activated receptor-alpha-mediated transcription of miR-199a2 attenuates endothelin-1 expression via hypoxia-inducible factor-1alpha. J Biol Chem (2014) 289(52):36031–47. doi: 10.1074/jbc.M114.600775

  • CrossRef
  • Google Scholar

• 325

  LiCZhouYLobergATaharaSMMalikPKalraVK. Activated Transcription Factor 3 in Association with Histone Deacetylase 6 Negatively Regulates MicroRNA 199a2 Transcription by Chromatin Remodeling and Reduces Endothelin-1 Expression. Mol Cell Biol (2016) 36(22):2838–54. doi: 10.1128/MCB.00345-16

  • CrossRef
  • Google Scholar

• 326

  PatelNSundaramNYangMMadiganCKalraVKMalikP. Placenta Growth Factor (PlGF), a Novel Inducer of Plasminogen Activator Inhibitor-1 (PAI-1) in Sickle Cell Disease (SCD). J Biol Chem (2010) 285(22):16713–22. doi: 10.1074/jbc.M110.101691

  • CrossRef
  • Google Scholar

• 327

  NsiriBGritliNMazighCGhazouaniEFattoumSMachghoulS. Fibrinolytic response to venous occlusion in patients with homozygous sickle cell disease. Hematol Cell Ther (1997) 39(5):229–32. doi: 10.1007/s00282-997-0229-7

  • CrossRef
  • Google Scholar

• 328

  HilleryCAPanepintoJA. Pathophysiology of stroke in sickle cell disease. Microcirculation (2004) 11(2):195–208. doi: 10.1080/10739680490278600

  • CrossRef
  • Google Scholar

• 329

  PatelNTaharaSMMalikPKalraVK. Involvement of miR-30c and miR-301a in immediate induction of plasminogen activator inhibitor-1 by placental growth factor in human pulmonary endothelial cells. Biochem J (2011) 434(3):473–82. doi: 10.1042/BJ20101585

  • CrossRef
  • Google Scholar

• 330

  LeongMADampierCVarlottaLAllenJL. Airway hyperreactivity in children with sickle cell disease. J Pediatr (1997) 131(2):278–83. doi: 10.1016/S0022-3476(97)70166-5

  • CrossRef
  • Google Scholar

• 331

  FieldJJStocksJKirkhamFJRosenCLDietzenDJSemonTet al. Airway hyperresponsiveness in children with sickle cell anemia. Chest (2011) 139(3):563–8. doi: 10.1378/chest.10-1243

  • CrossRef
  • Google Scholar

• 332

  Eiymo Mwa MpolloM-SBrandtEBShanmukhappaSKArumugamPITiwariSLobergAet al. Placenta growth factor augments airway hyperresponsiveness via leukotrienes and IL-13. J Clin Invest (2016) 126(2):571–84. doi: 10.1172/JCI77250

  • CrossRef
  • Google Scholar

• 333

  PatelNGonsalvesCSYangMMalikPKalraVK. Placenta growth factor induces 5-lipoxygenase-activating protein to increase leukotriene formation in sickle cell disease. Blood (2009) 113(5):1129–38. doi: 10.1182/blood-2008-07-169821

  • CrossRef
  • Google Scholar

• 334

  TurhanAWeissLAMohandasNCollerBSFrenettePS. Primary role for adherent leukocytes in sickle cell vascular occlusion: a new paradigm. Proc Natl Acad Sci USA (2002) 99(5):3047–51. doi: 10.1073/pnas.052522799

  • CrossRef
  • Google Scholar

• 335

  SelvarajSKGiriRKPerelmanNJohnsonCMalikPKalraVK. Mechanism of monocyte activation and expression of proinflammatory cytochemokines by placenta growth factor. Blood (2003) 102(4):1515–24. doi: 10.1182/blood-2002-11-3423

  • CrossRef
  • Google Scholar

• 336

  KaulDKLiuXDChoongSBelcherJDVercellottiGMHebbelRP. Anti-inflammatory therapy ameliorates leukocyte adhesion and microvascular flow abnormalities in transgenic sickle mice. Am J Physiol - Heart Circulatory Physiol (2004) 287(1 56-1):H293–301. doi: 10.1152/ajpheart.01150.2003

  • CrossRef
  • Google Scholar

• 337

  MousaviZYazdaniZMoradabadiAHoseinpourkasgariFHassanshahiG. Role of some members of chemokine/cytokine network in the pathogenesis of thalassemia and sickle cell hemoglobinopathies: a mini review. Exp Hematol Oncol (2019) 8(1):21. doi: 10.1186/s40164-019-0145-x

  • CrossRef
  • Google Scholar

• 338

  GonsalvesCSLiCMpolloMSPullarkatVMalikPTaharaSMet al. Erythropoietin-mediated expression of placenta growth factor is regulated via activation of hypoxia-inducible factor-1alpha and post-transcriptionally by miR-214 in sickle cell disease. Biochem J (2015) 468(3):409–23. doi: 10.1042/BJ20141138

  • CrossRef
  • Google Scholar

• 339

  ZakiyanovOKalousováMZimaTTesařV. Placental Growth Factor in Patients with Decreased Renal Function. Renal Failure (2011) 33(3):291–7. doi: 10.3109/0886022X.2011.560402

  • CrossRef
  • Google Scholar

• 340

  MatsuiMUemuraSTakedaYSamejimaKMatsumotoTHasegawaAet al. Placental Growth Factor as a Predictor of Cardiovascular Events in Patients with CKD from the NARA-CKD Study. J Am Soc Nephrol (2015) 26(11):2871–81. doi: 10.1681/ASN.2014080772

  • CrossRef
  • Google Scholar

• 341

  AtagaKIDerebailVKCaugheyMElsherifLShenJHJonesSKet al. Albuminuria Is Associated with Endothelial Dysfunction and Elevated Plasma Endothelin-1 in Sickle Cell Anemia. PloS One (2016) 11(9):e0162652. doi: 10.1371/journal.pone.0162652

  • CrossRef
  • Google Scholar

• 342

  HeimlichJBSpeedJSO’ConnorPMPollockJSTownesTMMeilerSEet al. Endothelin-1 contributes to the progression of renal injury in sickle cell disease via reactive oxygen species. Br J Pharmacol (2016) 173(2):386–95. doi: 10.1111/bph.13380

  • CrossRef
  • Google Scholar

• 343

  GbotoshoOTGhoshSKapetanakiMGLinYWeidertFBullockGCet al. Cardiac expression of HMOX1 and PGF in sickle cell mice and haem-treated wild type mice dominates organ expression profiles via Nrf2 (Nfe2l2). Br J Haematol (2019) 187(5):666–75. doi: 10.1111/bjh.16129

  • CrossRef
  • Google Scholar

• 344

  MalgorzewiczSSkrzypczak-JankunEJankunJ. Plasminogen activator inhibitor-1 in kidney pathology (Review). Int J Mol Med (2013) 31(3):503–10. doi: 10.3892/ijmm.2013.1234

  • CrossRef
  • Google Scholar

• 345

  GladwinMTSachdevV. Cardiovascular abnormalities in sickle cell disease. J Am Coll Cardiol (2012) 59(13):1123–33. doi: 10.1016/j.jacc.2011.10.900

  • CrossRef
  • Google Scholar

• 346

  PeiskerováMKalousováMDanzigVMíkováBHodkováMNěmečekEet al. Placental growth factor may predict increased left ventricular mass index in patients with mild to moderate chronic kidney disease–a prospective observational study. BMC Nephrol (2013) 14:142–. doi: 10.1186/1471-2369-14-142

  • CrossRef
  • Google Scholar

• 347

  PilarczykKSattlerKJGaliliOVersariDOlsonMLMeyerFBet al. Placenta growth factor expression in human atherosclerotic carotid plaques is related to plaque destabilization. Atherosclerosis (2008) 196(1):333–40. doi: 10.1016/j.atherosclerosis.2006.10.038

  • CrossRef
  • Google Scholar

• 348

  KhuranaRMoonsLShafiSLuttunACollenDMartinJFet al. Placental growth factor promotes atherosclerotic intimal thickening and macrophage accumulation. Circulation (2005) 111(21):2828–36. doi: 10.1161/CIRCULATIONAHA.104.495887

  • CrossRef
  • Google Scholar

• 349

  HeeschenCDimmelerSFichtlschererSHammCWBergerJSimoonsMLet al. Prognostic Value of Placental Growth Factor in Patients With Acute Chest Pain. JAMA (2004) 291(4):435–41. doi: 10.1001/jama.291.4.435

  • CrossRef
  • Google Scholar

• 350

  JabaIMZhuangZWLiNJiangYMartinKASinusasAJet al. NO triggers RGS4 degradation to coordinate angiogenesis and cardiomyocyte growth. J Clin Invest (2013) 123(4):1718–31. doi: 10.1172/JCI65112

  • CrossRef
  • Google Scholar

• 351

  AccorneroFvan BerloJHBenardMJLorenzJNCarmelietPMolkentinJD. Placental growth factor regulates cardiac adaptation and hypertrophy through a paracrine mechanism. Circ Res (2011) 109(3):272–80. doi: 10.1161/CIRCRESAHA.111.240820

  • CrossRef
  • Google Scholar

• 352

  HaradaENakagawaOYoshimuraMHaradaMNakagawaMMizunoYet al. Effect of interleukin-1 beta on cardiac hypertrophy and production of natriuretic peptides in rat cardiocyte culture. J Mol Cell Cardiol (1999) 31(11):1997–2006. doi: 10.1006/jmcc.1999.1030

  • CrossRef
  • Google Scholar

• 353

  WangLZhangYLLinQYLiuYGuanXMMaXLet al. CXCL1-CXCR2 axis mediates angiotensin II-induced cardiac hypertrophy and remodelling through regulation of monocyte infiltration. Eur Heart J (2018) 39(20):1818–31. doi: 10.1093/eurheartj/ehy085

  • CrossRef
  • Google Scholar

• 354

  NakamuraTFunayamaHKuboNYasuTKawakamiMMomomuraSet al. Elevation of plasma placental growth factor in the patients with ischemic cardiomyopathy. Int J Cardiol (2009) 131(2):186–91. doi: 10.1016/j.ijcard.2007.10.050

  • CrossRef
  • Google Scholar

• 355

  KolakowskiSJr.BerryMFAtluriPGrandTFisherOMoiseMAet al. Placental growth factor provides a novel local angiogenic therapy for ischemic cardiomyopathy. J Card Surg (2006) 21(6):559–64. doi: 10.1111/j.1540-8191.2006.00296.x

  • CrossRef
  • Google Scholar

• 356

  RollaSIngogliaGBardinaVSilengoLAltrudaFNovelliFet al. Acute-phase protein hemopexin is a negative regulator of Th17 response and experimental autoimmune encephalomyelitis development. J Immunol (2013) 191(11):5451–9. doi: 10.4049/jimmunol.1203076

  • CrossRef
  • Google Scholar

• 357

  MorseDPischkeSEZhouZDavisRJFlavellRALoopTet al. Suppression of inflammatory cytokine production by carbon monoxide involves the JNK pathway and AP-1. J Biol Chem (2003) 278(39):36993–8. doi: 10.1074/jbc.M302942200

  • CrossRef
  • Google Scholar

• 358

  ZimmermannMAguileraFBCastellucciMRossatoMCostaSLunardiCet al. Chromatin remodelling and autocrine TNFalpha are required for optimal interleukin-6 expression in activated human neutrophils. Nat Commun (2015) 6:6061. doi: 10.1038/ncomms7061

  • CrossRef
  • Google Scholar

• 359

  ZimmermannMArruda-SilvaFBianchetto-AguileraFFinottiGCalzettiFScapiniPet al. IFNalpha enhances the production of IL-6 by human neutrophils activated via TLR8. Sci Rep (2016) 6:19674. doi: 10.1038/srep19674

  • CrossRef
  • Google Scholar

• 360

  ChiLLiYStehno-BittelLGaoJMorrisonDCStechschulteDJet al. Interleukin-6 production by endothelial cells via stimulation of protease-activated receptors is amplified by endotoxin and tumor necrosis factor-alpha. J interferon cytokine Res Off J Int Soc Interferon Cytokine Res (2001) 21(4):231–40. doi: 10.1089/107999001750169871

  • CrossRef
  • Google Scholar

• 361

  ZampetakiAZhangZHuYXuQ. Biomechanical stress induces IL-6 expression in smooth muscle cells via Ras/Rac1-p38 MAPK-NF-kappaB signaling pathways. Am J Physiol Heart Circ Physiol (2005) 288(6):H2946–54. doi: 10.1152/ajpheart.00919.2004

  • CrossRef
  • Google Scholar

• 362

  FredjSBescondJLouaultCDelwailALecronJCPotreauD. Role of interleukin-6 in cardiomyocyte/cardiac fibroblast interactions during myocyte hypertrophy and fibroblast proliferation. J Cell Physiol (2005) 204(2):428–36. doi: 10.1002/jcp.20307

  • CrossRef
  • Google Scholar

• 363

  SanoMFukudaKKodamaHPanJSaitoMMatsuzakiJet al. Interleukin-6 family of cytokines mediate angiotensin II-induced cardiac hypertrophy in rodent cardiomyocytes. J Biol Chem (2000) 275(38):29717–23. doi: 10.1074/jbc.M003128200

  • CrossRef
  • Google Scholar

• 364

  FontesJARoseNRCihakovaD. The varying faces of IL-6: From cardiac protection to cardiac failure. Cytokine (2015) 74(1):62–8. doi: 10.1016/j.cyto.2014.12.024

  • CrossRef
  • Google Scholar

• 365

  SuHLeiCTZhangC. Interleukin-6 Signaling Pathway and Its Role in Kidney Disease: An Update. Front Immunol (2017) 8:405. doi: 10.3389/fimmu.2017.00405

  • CrossRef
  • Google Scholar

• 366

  PetersMMullerAMRose-JohnS. Interleukin-6 and soluble interleukin-6 receptor: direct stimulation of gp130 and hematopoiesis. Blood (1998) 92(10):3495–504. doi: 10.1182/blood.V92.10.3495.422k47_3495_3504

  • CrossRef
  • Google Scholar

• 367

  GuoYXuFLuTDuanZZhangZ. Interleukin-6 signaling pathway in targeted therapy for cancer. Cancer Treat Rev (2012) 38(7):904–10. doi: 10.1016/j.ctrv.2012.04.007

  • CrossRef
  • Google Scholar

• 368

  HiranoTYasukawaKHaradaHTagaTWatanabeYMatsudaTet al. Complementary DNA for a novel human interleukin (BSF-2) that induces B lymphocytes to produce immunoglobulin. Nature (1986) 324(6092):73–6. doi: 10.1038/324073a0

  • CrossRef
  • Google Scholar

• 369

  LacroixMRousseauFGuilhotFMalingePMagistrelliGHerrenSet al. Novel Insights into Interleukin 6 (IL-6) Cis- and Trans-signaling Pathways by Differentially Manipulating the Assembly of the IL-6 Signaling Complex. J Biol Chem (2015) 290(45):26943–53. doi: 10.1074/jbc.M115.682138

  • CrossRef
  • Google Scholar

• 370

  SchellerJGarbersCRose-JohnS. Interleukin-6: from basic biology to selective blockade of pro-inflammatory activities. Semin Immunol (2014) 26(1):2–12. doi: 10.1016/j.smim.2013.11.002

  • CrossRef
  • Google Scholar

• 371

  MiharaMHashizumeMYoshidaHSuzukiMShiinaM. IL-6/IL-6 receptor system and its role in physiological and pathological conditions. Clin Sci (Lond) (2012) 122(4):143–59. doi: 10.1042/CS20110340

  • CrossRef
  • Google Scholar

• 372

  JonesSASchellerJRose-JohnS. Therapeutic strategies for the clinical blockade of IL-6/gp130 signaling. J Clin Invest (2011) 121(9):3375–83. doi: 10.1172/JCI57158

  • CrossRef
  • Google Scholar

• 373

  LykeKEBurgesRCissokoYSangareLDaoMDiarraIet al. Serum levels of the proinflammatory cytokines interleukin-1 beta (IL-1beta), IL-6, IL-8, IL-10, tumor necrosis factor alpha, and IL-12(p70) in Malian children with severe Plasmodium falciparum malaria and matched uncomplicated malaria or healthy controls. Infection Immunity (2004) 72(10):5630–7. doi: 10.1128/IAI.72.10.5630-5637.2004

  • CrossRef
  • Google Scholar

• 374

  NayakKCMeenaSLGuptaBKKumarSPareekV. Cardiovascular involvement in severe vivax and falciparum malaria. J Vector Borne Dis (2013) 50(4):285–91. doi: 10.1074/jbc.M115.682138

  • CrossRef
  • Google Scholar

• 375

  FinkelMSOddisCVJacobTDWatkinsSCHattlerBGSimmonsRL. Negative inotropic effects of cytokines on the heart mediated by nitric oxide. Science (1992) 257(5068):387–9. doi: 10.1126/science.1631560

  • CrossRef
  • Google Scholar

• 376

  BurwickRMRinconMBeerakaSSGuptaMFeinbergBB. Evaluation of Hemolysis as a Severe Feature of Preeclampsia. Hypertension (Dallas Tex 1979) (2018) 72(2):460–5. doi: 10.1161/HYPERTENSIONAHA.118.11211

  • CrossRef
  • Google Scholar

• 377

  KumarSWangGZhengNChengWOuyangKLinHet al. HIMF (Hypoxia-Induced Mitogenic Factor)-IL (Interleukin)-6 Signaling Mediates Cardiomyocyte-Fibroblast Crosstalk to Promote Cardiac Hypertrophy and Fibrosis. Hypertension (Dallas Tex 1979) (2019) 73(5):1058–70. doi: 10.1161/HYPERTENSIONAHA.118.12267

  • CrossRef
  • Google Scholar

• 378

  MelendezGCMcLartyJLLevickSPDuYJanickiJSBrowerGL. Interleukin 6 mediates myocardial fibrosis, concentric hypertrophy, and diastolic dysfunction in rats. Hypertension (Dallas Tex 1979) (2010) 56(2):225–31. doi: 10.1161/HYPERTENSIONAHA.109.148635

  • CrossRef
  • Google Scholar

• 379

  DinhWFuthRNicklWKrahnTEllinghausPScheffoldTet al. Elevated plasma levels of TNF-alpha and interleukin-6 in patients with diastolic dysfunction and glucose metabolism disorders. Cardiovasc Diabetol (2009) 8:58. doi: 10.1186/1475-2840-8-58

  • CrossRef
  • Google Scholar

• 380

  SugishitaKKinugawaKShimizuTHaradaKMatsuiHTakahashiTet al. Cellular basis for the acute inhibitory effects of IL-6 and TNF- alpha on excitation-contraction coupling. J Mol Cell Cardiol (1999) 31(8):1457–67. doi: 10.1006/jmcc.1999.0989

  • CrossRef
  • Google Scholar

• 381

  HagiwaraYMiyoshiSFukudaKNishiyamaNIkegamiYTanimotoKet al. SHP2-mediated signaling cascade through gp130 is essential for LIF-dependent I CaL, [Ca2+]i transient, and APD increase in cardiomyocytes. J Mol Cell Cardiol (2007) 43(6):710–6. doi: 10.1016/j.yjmcc.2007.09.004

  • CrossRef
  • Google Scholar

• 382

  DrosatosKLymperopoulosAKennelPJPollakNSchulzePCGoldbergIJ. Pathophysiology of sepsis-related cardiac dysfunction: driven by inflammation, energy mismanagement, or both? Curr Heart failure Rep (2015) 12(2):130–40. doi: 10.1007/s11897-014-0247-z

  • CrossRef
  • Google Scholar

• 383

  ZhangWQuXChenBSnyderMWangMLiBet al. Critical Roles of STAT3 in beta-Adrenergic Functions in the Heart. Circulation (2016) 133(1):48–61. doi: 10.1161/CIRCULATIONAHA.115.017472

  • CrossRef
  • Google Scholar

• 384

  de MontmollinEAboabJMansartAAnnaneD. Bench-to-bedside review: Beta-adrenergic modulation in sepsis. Crit Care (2009) 13(5):230. doi: 10.1186/cc8026

  • CrossRef
  • Google Scholar

• 385

  WangYLewisDFGuYZhaoSGroomeLJ. Elevated maternal soluble Gp130 and IL-6 levels and reduced Gp130 and SOCS-3 expressions in women complicated with preeclampsia. Hypertension (Dallas Tex 1979) (2011) 57(2):336–42. doi: 10.1161/HYPERTENSIONAHA.110.163360

  • CrossRef
  • Google Scholar

• 386

  LamarcaBBrewerJWallaceK. IL-6-induced pathophysiology during pre-eclampsia: potential therapeutic role for magnesium sulfate? Int J interferon cytokine Mediator Res (2011) 2011(3):59–64. doi: 10.2147/IJICMR.S16320

  • CrossRef
  • Google Scholar

• 387

  SarraySSalehLRLisa SaldanhaFAl-HabboubiHHMahdiNAlmawiWY. Serum IL-6, IL-10, and TNFalpha levels in pediatric sickle cell disease patients during vasoocclusive crisis and steady state condition. Cytokine (2015) 72(1):43–7. doi: 10.1016/j.cyto.2014.11.030

  • CrossRef
  • Google Scholar

• 388

  TaylorSCShacksSJMitchellRABanksA. Serum interleukin-6 levels in the steady state of sickle cell disease. J interferon cytokine Res Off J Int Soc Interferon Cytokine Res (1995) 15(12):1061–4. doi: 10.1089/jir.1995.15.1061

  • CrossRef
  • Google Scholar

• 389

  LesterLASodtPCHutcheonNArcillaRA. Cardiac abnormalities in children with sickle cell anemia. Chest (1990) 98(5):1169–74. doi: 10.1378/chest.98.5.1169

  • CrossRef
  • Google Scholar

• 390

  FaroGBMenezes-NetoOABatistaGSSilva-NetoAPCipolottiR. Left ventricular hypertrophy in children, adolescents and young adults with sickle cell anemia. Rev Bras Hematol Hemoter (2015) 37(5):324–8. doi: 10.1016/j.bjhh.2015.07.001

  • CrossRef
  • Google Scholar

• 391

  CrockerPWerbZGordonSBaintonD. Ultrastructural localization of a macrophage-restricted sialic acid binding hemagglutinin, SER, in macrophage-hematopoietic cell clusters. Blood (1990) 76(6):1131–8. doi: 10.1182/blood.V76.6.1131.bloodjournal7661131

  • CrossRef
  • Google Scholar

• 392

  GbotoshoOTKapetanakiMGGhoshSVillanuevaFSOfori-AcquahSFKatoGJ. Heme Induces IL-6 and Cardiac Hypertrophy Genes Transcripts in Sickle Cell Mice. Front Immunol (2020) 72(1):43–7. doi: 10.3389/fimmu.2020.01910

  • CrossRef
  • Google Scholar

• 393

  IngogliaGSagCMRexNDe FranceschiLVinchiFCiminoJet al. Data demonstrating the anti-oxidant role of hemopexin in the heart. Data Brief (2017) 13:69–76. doi: 10.1016/j.dib.2017.05.026

  • CrossRef
  • Google Scholar

• 394

  StrouseJJHeeneyMM. Hydroxyurea for the treatment of sickle cell disease: efficacy, barriers, toxicity, and management in children. Pediatr Blood Cancer (2012) 59(2):365–71. doi: 10.1002/pbc.24178

  • CrossRef
  • Google Scholar

• 395

  KatoGJ. New insights into sickle cell disease: mechanisms and investigational therapies. Curr Opin Hematol (2016) 23(3):224–32. doi: 10.1097/MOH.0000000000000241

  • CrossRef
  • Google Scholar

• 396

  ReesDWilliamsTGladwinM. Sickle-cell disease. Lancet (2010) 376(9757):2018–31. doi: 10.1016/S0140-6736(10)61029-X

  • CrossRef
  • Google Scholar

• 397

  KatoGJPielFBReidCDGastonMHOhene-FrempongKKrishnamurtiLet al. Sickle cell disease. Nat Rev Dis Primers (2018) 4:18010. doi: 10.1038/nrdp.2018.10

  • CrossRef
  • Google Scholar

• 398

  ZimmermanSASchultzWHBurgettSMortierNAWareRE. Hydroxyurea therapy lowers transcranial Doppler flow velocities in children with sickle cell anemia. Blood (2007) 110(3):1043–7. doi: 10.1182/blood-2006-11-057893

  • CrossRef
  • Google Scholar

• 399

  PlattOS. Hydroxyurea for the treatment of sickle cell anemia. New Engl J Med (2008) 358(13):1362–9. doi: 10.1056/NEJMct0708272

  • CrossRef
  • Google Scholar

• 400

  WangWCWareREMillerSTIyerRVCasellaJFMinnitiCPet al. Hydroxycarbamide in very young children with sickle-cell anaemia: a multicentre, randomised, controlled trial (BABY HUG). Lancet (2011) 377(9778):1663–72. doi: 10.1016/S0140-6736(11)60355-3

  • CrossRef
  • Google Scholar

• 401

  VoelkerR. New Option for Sickle Cell Disease. JAMA (2020) 323(1):18. doi: 10.1001/jama.2019.20640

  • CrossRef
  • Google Scholar

• 402

  GluckmanE. Allogeneic transplantation strategies including haploidentical transplantation in sickle cell disease. Hematol Am Soc Hematol Educ Program (2013) 2013:370–6. doi: 10.1182/asheducation-2013.1.370

  • CrossRef
  • Google Scholar

• 403

  MakaniJOfori-AcquahSFNnoduOWonkamAOhene-FrempongK. Sickle cell disease: new opportunities and challenges in Africa. TheScientificWorldJournal (2013) 2013:193252. doi: 10.1155/2013/193252

  • CrossRef
  • Google Scholar

• 404

  RogersDWClarkeJMCupidoreLRamlalAMSparkeBRSerjeantGR. Early deaths in Jamaican children with sickle cell disease. Br Med J (1978) 1(6126):1515–6. doi: 10.1136/bmj.1.6126.1515

  • CrossRef
  • Google Scholar

• 405

  GrosseSDOdameIAtrashHKAmendahDDPielFBWilliamsTN. Sickle cell disease in Africa: a neglected cause of early childhood mortality. Am J Preventive Med (2011) 41(6 Suppl 4):S398–405. doi: 10.1016/j.amepre.2011.09.013

  • CrossRef
  • Google Scholar

• 406

  TshiloloLTomlinsonGWilliamsTNSantosBOlupot-OlupotPLaneAet al. Hydroxyurea for Children with Sickle Cell Anemia in Sub-Saharan Africa. New Engl J Med (2019) 380(2):121–31. doi: 10.1056/NEJMoa1813598

  • CrossRef
  • Google Scholar

• 407

  TayoBOAkingbolaTSSarafSLShahBNEzekekwuCASonubiOet al. Fixed Low-Dose Hydroxyurea for the Treatment of Adults with Sickle Cell Anemia in Nigeria. Am J Hematol (2018) 377(9778):1663–72. doi: 10.1002/ajh.25412

  • CrossRef
  • Google Scholar

• 408

  LagunjuIBrownBJSodeindeO. Hydroxyurea lowers transcranial Doppler flow velocities in children with sickle cell anaemia in a Nigerian cohort. Pediatr Blood Cancer (2015) 62(9):1587–91. doi: 10.1002/pbc.25529

  • CrossRef
  • Google Scholar