Abstract
Sepsis is a potentially life-threatening, pathological condition caused by a dysregulated host response to infection. Pathologically, systemic inflammation can initiate coagulation activation, leading to organ dysfunction, and ultimately to multiple organ failure and septic death. The inflammasomes are cytosolic multiprotein signaling complexes that control the host response to diverse pathogen-associated molecular patterns (PAMPs) from microorganisms as well as damage-associated molecular patterns (DAMPs) from dead or dying host cells. Recent studies highlight that the activation of canonical and non-canonical inflammasomes not only mediate the maturation and secretion of interleukin-1 (IL1) family cytokines, but also trigger the release of coagulation factor III, tissue factor (F3, best known as TF) in activated macrophages and monocytes. These emerging functions of inflammasomes in immunocoagulation are further positively regulated by stimulator of interferon response cGAMP interactor 1 (STING1, also known as STING or TMEM173, a hub of the innate immune signaling network) and high mobility group box 1 (HMGB1, a nuclear DAMP). This mini-review will discuss the regulation and function of inflammasome-dependent coagulation activation in sepsis.
Introduction
Sepsis is a challenging clinical syndrome characterized by life-threatening organ dysfunction or failure due to the dysregulated host immune response to pathogen infection, including bacteria, viruses, and fungi (1). The typical pathological process of sepsis involves the early hyperinflammatory state and the late immunosuppressive stage. This dynamic change of the host immune response is closely related to local or systemic coagulation abnormalities (2). Disseminated intravascular coagulation (DIC) is a common complication of sepsis, characterized by systemic activation of the coagulation cascade with microthrombosis, platelet consumption, and subsequent clotting factor exhaustion (3). Clinical studies have shown that the mortality rate of septic shock patients with DIC is twice that of septic patients without DIC (4), highlighting the importance of understanding the pathogenesis, diagnosis, and treatment of DIC in sepsis.
Cells of the innate immune system, such as macrophages, monocytes, neutrophils, and dendritic cells, are the first line of defense against foreign pathogens. However, excessive activation of these professional phagocytes may lead to inflammation, immune dysfunction, and abnormal blood clotting. Inflammasomes are multiprotein intracellular complexes that detect the components of microorganisms [namely pathogen-associated molecular patterns (PAMPs)] and endogenous danger signals released by injured cells [namely damage-associated molecular patterns (DAMPs)] using various pattern recognition receptors (PRRs) (5). Generally, according to whether caspase-1 (CASP1) or caspase-11 (CASP11 in mouse, also known as CASP4 and CASP5 in humans) is activated, inflammasomes can be divided into canonical and non-canonical subtypes (6, 7). Although they play an important role in host immune defense, the vigorous activation of inflammasomes also cause detrimental consequences, providing the pathogenicity of disease, including septic shock (8). In contrast, genetic depletion of core components of inflammasomes, such as Nlrp3, Casp1, Casp11, and gasdermin D (Gsdmd), protects against septic shock (9–15) or lethal endotoxemia (7) in mice, turning them into a promising target for treatment of sepsis.
In this mini-review, we introduce the types and activation of inflammasomes, discuss their roles in coagulation and thrombosis, and highlight their implications in sepsis.
Types and Activation of Inflammasomes in Sepsis
Inflammasomes typically contain a sensor (cytosolic PRRs), an adaptor [apoptosis-associated speck-like protein containing a caspase recruitment domain (ASC)], and a zymogen (pro-CASP1) (16). Assembly of inflammasome is initiated when PRRs sensing PAMPs, DAMPs, or stress signals. Certain PRRs then recruit ASC, a bipartite protein that bridges the sensors and the effector pro-CASP1 (17). Pro-CASP1 is subsequently cleaved into active caspase, ultimately leading to maturation and secretion of interleukin 1 (IL1) family cytokines (such as IL1B and IL18) or cleaved GSDMD-mediated pyroptosis. Functionally, pyroptosis is a form of pro-inflammatory cell death. Although pyroptosis has been found to occur in various immune and non-immune cells, it was first discovered in macrophages during bacterial infections (18). GSDMD-formed pores not only mediate pyroptosis, but also facilitate the release of IL1B in a pyroptosis-independent manner (19, 20). Below, we summarize the main types of inflammasomes related to sepsis.
Canonical Inflammasome
The NLRP3 Inflammasome
The most extensively studied inflammasome is the NLR family pyrin domain containing 3 (NLRP3) inflammasome, which is activated by a variety of stimuli, including PAMPs, DAMPs, pore-forming toxins, crystals, and nucleic acid (21). Of note, the basic expression of NLRP3 and pro-IL1B in macrophages is very low, and a priming signal (such as TLR ligands or IFN) is required to activate the NF-κB pathway to upregulate the expression of the components for NLRP3 inflammasome in macrophages (22). The second signal triggers NLRP3 activation by multiple mechanisms, including potassium (K+) efflux, increased calcium (Ca2+) signaling, mitochondrial translocation of NLRP3, excessive mitochondrial reactive oxygen species (ROS) generation, release of mitochondrial DNA and cardiolipin, and lysosomal leakage of cathepsins into cytosol (5, 23). Many studies have found that inhibiting the activation of NLRP3 inflammasome has a protective effect on septic animals (24). In particular, the NLRP3 inhibitor MCC950 attenuates multi-organ injuries in septic rats (25), highlighting the potential of using NLRP3 inhibitors in the treatment of sepsis.
The NLRC4 Inflammasome
The NLRC4 inflammasome responds to more stringent types of stimulation. NLRC4 forms a complex with certain NLR family apoptosis inhibitory protein (NAIP) family proteins, which directly bind to the NLRC4-activating ligands. For example, mouse Naip1 or Naip2 binds to the needle protein or rod component of bacterial type III secretory system (T3SS), respectively (26, 27). Moreover, both mouse Naip5 and Naip6 can recognize bacterial flagellin (27, 28). In humans, only one NAIP homolog has been identified to recognize the needle structure of T3SS. Once bound to their ligands, NAIPs oligomerize with NLRC4 to form the NLRC4 inflammasomes, leading to CASP1 activation. In vivo, a severe systemic inflammation is caused by activating NLRC4 inflammasomes with flagellin in monocytes, macrophage and neutrophils (29). Systemic coagulation and massive thrombosis are induced by T3SS infection in mice through the activation of inflammasome, possibly the NLRC4 inflammasome (30). Therefore, inappropriate NLRC4 activation may result in detrimental consequence in sepsis.
Non-canonical Inflammasome
Clinically, septic shock is a multi-step process and mainly related to Gram-negative bacterial infection. Lipopolysaccharides (LPS), the main component of the outer membrane of Gram-negative bacteria, is a prototypical PAMP for studying innate immune response. Historically, the activity of LPS was determined by the membrane receptor toll-like receptor 4 (TLR4). Recent breakthroughs confirmed that CASP11 can act as a receptor for cytoplasmic LPS, which is independent of TLR4 (31, 32). The activation of CASP11 inflammasome also can promote CASP1-dependent IL1B and IL18 production by triggering the activation of NLRP3 inflammasome. CASP11 induces CASP1-independent pyroptosis, which still requires the production of cleaved GSDMD at the N-terminus (termed GSDMD-N) and subsequent translocation of GSDMD-N to the cell membrane (7). Similar function of human non-canonical inflammasome has been identified by the deletion of CASP4 or CASP5 in human macrophage, which impairs pyroptosis and NLRP3 inflammasome-mediated cytokine release (33–36). The contribution of non-canonical inflammasome to sepsis has been reported in septic mice model (7, 37–39). The deletion of CASP11 or using CASP11-targeting inhibitor (e.g., oxPAPC) protects mice against LPS-induced lethality (7, 38). In addition, transgenic expression of CASP4 in Casp1−/−/11−/− mice renders increased susceptibility to LPS-induced shock (40), indicating the pathogenetic role of human non-canonical inflammasome in sepsis.
Modulation and Function of Inflammasome in Coagulation
Most patients with sepsis show hemostatic changes, while DIC occurs in ~35% of patients, resulting in organ dysfunction and death (41). The most principal initiator of coagulopathy in sepsis is coagulation factor III (F3). It is a transmembrane single-chain glycoprotein composed of 263 amino acid residues, with a molecular weight of about 47 kDa (42). F3 initiates the blood coagulation cascade by binding to coagulation factor VII/VIIa (F3:VIIa complex) on the cell surface (42). During sepsis, the host immune response to PAMPs (such as LPS) rapidly triggers the activation of coagulation by inducing the expression of F3 on monocytes, platelets or endothelial cells (43–46). Additionally, the mechanism of regulating F3 activity by transforming F3 from an inactive state to an active state (a process called F3 decryption) also contributes to coagulation activation. Exposure of anionic phospholipids, such as phosphatidylserine (PS), on the outer leaflet of the plasma membrane is considered to be the main cause of F3 decryption (47). This process optimizes the presentation of F3:VIIa complex to provide more efficient binding sites to their substrates factors IX and X. Increased PS exposure on the surface of circulating leukocytes is observed in sepsis (47). Genetic deletion of F3 or blocking F3 activity using neutralizing antibodies in sepsis animal models prevents activation of coagulation and decreases the mortality (30, 48, 49). The administration of PS-neutralizing binding protein lactadherin markedly ameliorates sepsis-induced coagulation and lethality (50). These evidences suggest that treatment of the altered coagulation would be a reasonable approach to improve the mortality of sepsis. Some DAMPs, such as cell-free DNA, histones, heat shock proteins, and high mobility group box 1 protein (HMGB1) (51, 52), have been reported to induce coagulopathy in sepsis by furtherly augmenting systemic inflammation (53) or impairing the activation of anticoagulants (e.g., protein C) (54). These DAMPs may be released from damaged cells due to apoptosis, necroptosis, or pyroptosis, but the contribution of cell death to coagulation in sepsis is context-dependent. Recently, three independent groups found that both CASP1 and CASP11-dependent inflammasomes trigger systemic coagulation in mice through GSDMD-N-mediated increased F3 release or F3 activity in macrophages and monocytes (Figure 1).
Figure 1
Caspase Activation
Either CASP1 or CASP11 can promote the coagulation cascade, depending on the type of bacterial infection. CASP1 is required to release active F3 in mouse bone marrow-derived macrophages (BMDM) challenged or stimulated by bacterial T3SS inner rod protein, including EprJ and EscI from Escherichia coli (E.coli), BsaK of Burkholderia pseudomallei, and PrgJ of Salmonella typhimurium (30). Similarly, T3SS treatment or E. coli infection induces CASP1-dependent F3 release in THP1 cells, a human monocytic cell line derived from an acute monocytic leukemia patient (30). In vivo, lack of Casp1 (instead of CASP11) protects mice from EprJ-induced lethality associated with the reduction of DIC biomarkers in blood (30). In polymicrobial sepsis induced by cecal ligation and puncture (CLP), inhibiting the activity of CASP1 with the NLRP3 inhibitor MCC950 also reduces platelet activation in rats (25, 55). These animal studies suggest that CASP1 has a potential role in regulating septic coagulation in mice and rats.
The activation of CASP11-dependent inflammasomes also mediates the release or activation of F3 in sepsis caused by CLP, E. coli infection, bacterial outer membrane vesicle (OMV) infection, and LPS stimulation in vivo (56, 57). Similar to clinical anticoagulant heparin treatment, in the lethal endotoxemia mouse model, the absence of Casp11 inhibits the activation of coagulation (56, 57). In Casp11-deficient mice, systemic coagulation triggered by the initiation of poly(I:C) and subsequent LPS administration is also blocked (30, 56). Extracellular HMGB1 is not only a DAMP, but also a carrier that brings LPS into the intracellular space (58). In particular, extracellular HMGB1 from liver mediates LPS uptake and promotes the externalization of phosphatidylserine (PS), which is important for F3 activation in macrophages. In contrast, depletion of Casp11 limits HMGB1/LPS-induced PS exposure and subsequent F3 activation in macrophages (59). Therefore, CASP11-dependent inflammasome is an important regulator of F3 release and activation in macrophages. While TLR4 is essential for LPS-induced gene expression of Casp11, TLR4 is considered to be dispensable in most inflammasome-mediated coagulation (30). Injection of LPS primed with poly(I:C) also induces coagulation cascade in Tlr4-deficient mice (56). The function of human CASP4 or CASP5 in sepsis-induced coagulopathy remains poorly understood, but it will be enlightened by these investigations of CASP11 in mouse models.
In certain bacterial infections (especially Y. pestis and Y. pseudotuberculosis), the apoptotic non-inflammatory caspase CASP8 also participates in inducing pyroptosis by activating the NLRP3 inflammasome (60) or acting as a structural component of the inflammasome (61). Consequently, CASP8 (but not CASP1 or CASP11)-mediated GSDMD-N production is required for F3 release in BMDM during Streptococcus pneumoniae (S. pneumoniae) infection (62). Collectively, these studies indicate that inhibition of caspase activation may have a potential therapeutic effect on fatal coagulopathy during sepsis.
GSDMD Cleavage
The activation of CASP1, CASP11, or CASP8 causes the cleavage of GSDMD, thereby generating a pyroptotic p30 fragment, namely GSDMD-N. GSDMD-N-mediated pore formation has been regarded as the terminal event of pyroptosis or hyperactivation state. Genetic or pharmacological inhibition of GSDMD expression or cleavage prevents F3 release or activation in vitro or systemic activation of coagulation in mice induced by CLP, E.coli infection, bacterial rod proteins or OMVs stimulation, as well as LPS challenge in the absence or presence of HMGB1 (30, 56, 57, 59, 62). GSDMD-mediated F3 release is pyroptosis-dependent. Glycine (an osmotic protectant) inhibits the release of F3 in EprJ-infected BMDM by pyroptosis-driven cell membrane rupture instead of GSDMD-mediated pore formation (30). Although the purinergic receptor P2X7 (P2RX7) has been shown to mediate pyroptosis in a GSDMD-independent manner (63), it seems that P2RX7 is not required for the coagulation cascade in endotoxemic mice (30, 56).
It is worth noting that the GSDMD-mediated coagulation cascade may occur in a pyroptosis-independent manner. Glycine is unable to affect F3 activation in mouse peritoneal macrophages (PM) stimulated by cytoplasmic LPS, suggesting another mechanism independent of pyroptosis. Alternatively, the pores formed by GSDMD render cells into a hyperactivation state, which is adequate to permit Ca2+ influx, thereby promoting PS exposure through Ca2+-dependent scramblase anoctamin 6 (ANO6). After the externalization of PS is increased, the activity of F3 is enhanced after LPS challenge in vivo and in vitro, which can be attenuated by using specific PS binding proteins, such as lactadherin and MFG-E8 (56). These studies describe a direct link between GSDMD and coagulopathy, although its mechanism of action is stimulus-dependent.
Cell membrane rupture also occurs in necroptosis, a form of regulated necrosis depending on several kinases, including receptor interacting protein kinase 1 (RIPK1). RIPK1 expressed in epithelial cells favors tumor necrosis factor (TNF)- or TNF/Z-VAD-FMK-induced coagulation with increased plasma F3 in mice (64). These findings indicate that multiple types of necrosis contribute to coagulation through different mechanisms.
STING1 Activation
Stimulator of interferon response cGAMP interactor 1 (STING1) is an ER-associated membrane protein and plays a complex role in innate immune sensing of pathogens. Excessive activation of STING1 pathway is involved in pathogenesis of sepsis and is recently reported to drive lethal coagulation in sepsis through GSDMD-dependent mechanism. STING1, coupled with inositol 1,4,5-trisphosphate receptor type 1 [ITPR1, a calcium release channel of endoplasmic reticulum (ER)] and the ATPase sarcoplasmic/ER Ca2+ transporting 2 (ATP2A2, a calcium uptake pump of ER), mediates cytosolic calcium influx to activate CASP1, CASP11, or CASP8 in macrophages/monocytes in response to different infections (62). Therefore, Sting1 depletion limits the production of GSDMD-N in THP1 cells mediated by CASP1/11/8, resulting in a decrease in F3 release. Reduced coagulation activation and prolonged animal survival are observed in septic mice (CLP, E.coli and S. pneumoniae infection) with conditional deletion of Sting1 in myeloid cells (62). Moreover, mRNA expression of STING1 and GSDMD in peripheral blood mononuclear cell (PBMC) closely correlates with DIC severity in patients with sepsis, highlighting the regulatory role of STING1 in DIC during sepsis (62). Notably, STING1-mediated type I interferon (IFN) response does not seem to be important for inflammasome-mediated coagulation response during sepsis, because deletion of type I IFN receptor (Ifnar) or interferon regulatory factor 3 (Irf3) in mice fails to block infection-induced coagulation activation (62). However, another study suggests that IFNs may contribute to coagulation activation due to its ability to induce hepatocyte HMGB1 release, leading CASP11-dependent GSDMD activation and PS exposure (59). Further animal experiments are needed to understand the role of IFN-dependent HMGB1 release in blood coagulation.
Ca2+ Influx
Increased cytosolic Ca2+ influx, either released from ER or entered extracellularly through calcium channels, is a critical signal for immune response (65, 66), including modulating inflammasome activation (67–70). Inhibiting cytosolic calcium accumulation by calcium chelator (BAPTA-AM and EDTA) or ER stress inhibitor (TUCDA and 4PBA) leads to reduced F3 release or activity in THP1 or murine macrophages (56, 62). Similarly, decreased Ca2+ released by TUCDA or Ca2+ channel modulator (2-APB) protects against coagulation activation in CLP mice. (56). In contrast, raising Ca2+ influx by ER stress agonist (tunicamycin and thapsigargin) (62) or calcium inophore (A23187) (56) promotes F3 release or activity. These drug studies support the function of cytosolic Ca2+ influx in mediating coagulation activation during sepsis. In addition, the production of GSDMD-N in THP1 or BMDM during inflammasome activation is also inhibited by blocking cytosolic Ca2+ influx using the knockdown of ITPR1, overexpression of ATP2A2 or inhibition of phospholipase C gamma 1 (PLCG1) (62). Moreover, extracellular Ca2+ also enters through GSDMD-N-formed pores to trigger coagulation cascade by promoting PS exposure (56). In general, these findings suggest that during sepsis, Ca2+ influx can act as both a regulator and an effector of inflammasome activation during septic coagulation. Approaches that control the Ca2+ concentration may improve the therapeutic effect of anticoagulation.
Conclusion and Outlook
The molecular mechanisms of how systemic coagulation is triggered by the inflammasome during lethal sepsis brings a new understanding of the inflammasome function and sets a new stage for immunocoagulation studies. However, some questions have raised and remain unsolved. First, it is not yet clear how different types of inflammasomes coordinate to regulate the coagulation response, because clinical sepsis is usually caused by polymicrobial infection. Second, most studies have focused on the direct effects inflammasomes have on the release and activation of F3. However, whether F3 in turn regulates inflammasome activation is still unknown. Third, how to transform these new understandings into treatment of inflammasome-dependent coagulation during sepsis in human patients? Since the treatment with anticoagulant after onset of sepsis has not resulted in improved clinical outcomes, administration or combination of inflammasome-associated inhibitors may be a favorable approach to fight against sepsis-induced coagulation. Some drugs have displayed a promising effect to protect inflammasome-related coagulation during sepsis (Table 1). The existing small molecules that block inflammasome activation could also be investigated for their potential role in controlling coagulation.
Table 1
| Mechanism | Function | Name | Usage | Model | References |
|---|---|---|---|---|---|
| Reduce Ca2+ influx | Calcium chelator | BAPTA-AM | Up to 10 μM | PMs WT or ITPR1-KD BMDMs/THP1 | (56, 62) |
| Ethylenediaminetetraacetic acid (EDTA) | Up to 600 μM | PMs | (56) | ||
| ER stress inhibitor | Tauroursodeoxycholic acid (TUDCA) | 200 mg/kg | WT or Tmem173−/− mice | (62) | |
| 50 μM | THP1 | (62) | |||
| 4-phenyl butyric acid (4PBA) | 1 mM | THP1 | (62) | ||
| D-myo-inositol 1,4,5-trisphosphate (IP3) receptor antagonist | 2-Aminoethoxydiphenylborane (2-APB) | 20 mg/kg | WT or Tmem173−/− mice | (62) | |
| TMEM16F inhibitor | Tannic acid (TA) | NA | PMs | (56) | |
| Niflumic acid (NFA) | NA | PMs | (56) | ||
| PLCG1 inhibitor | U73122 | 10 μM | THP1 | (62) | |
| 30 mg/kg | WT or Gsdmd105N/105N mice | (62) | |||
| Inhibit caspase 8 cleavage | Caspase 8 inhibitor | Z-IETD-FMK | 20 μM | WT or Casp1−/−Casp11−/− BMDMs | (62) |
| Prevent NLRP3 oligomerization | NLRP3 inhibitor | MCC950 | 50 mg/kg | Rat | (25) |
| Delete in vivo macrophage | Macrophage remover | Clodronate liposomes | 40 mg/kg | Mice | (30, 56) |
| Neutralize HMGB1 | HMGB1 antibody | 2G7 | 160 μg/mouse | Mice | (56) |
| Prevent membrane rupture | Osmoprotectant | Glycine | 5 mM | BMDMs | (30) |
Potential inhibitors of inflammasome-dependent coagulation.
Regulated inflammasome activity is still essential for host defense against pathogens because mounting the immune response with its associated secretory cytokines would further contribute to the adaptive immune response. Thus, treatment of sepsis-induced coagulation by inhibiting inflammasome activity should be strictly monitored to avoid severe side effects caused by a suppressed immune response. Therefore, an in-depth understanding of the mechanism of coagulopathy triggered by inflammasomes is essential for identifying new therapeutic targets and developing more beneficial therapies.
Statements
Author contributions
RK and DT conceived of the topic for this review. All authors listed have made a substantial, direct and intellectual contribution to the work, and approved it for publication.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
References
1.
SingerMDeutschmanCSSeymourCWShankar-HariMAnnaneDBauerMet al. The third international consensus definitions for sepsis and septic shock (Sepsis-3). JAMA. (2016) 315:801–10. 10.1001/jama.2016.0287
2.
LeviMvan der PollT. Coagulation and sepsis. Thromb Res. (2017) 149:38–44. 10.1016/j.thromres.2016.11.007
3.
GandoSLeviMTohCH. Disseminated intravascular coagulation. Nat Rev Dis Primers. (2016) 2:16037. 10.1038/nrdp.2016.37
4.
GandoSSaitohDIshikuraHUeyamaMOtomoYOdaSet al. A randomized, controlled, multicenter trial of the effects of antithrombin on disseminated intravascular coagulation in patients with sepsis. Crit Care. (2013) 17:R297. 10.1186/cc13163
5.
LamkanfiMDixitVM. Mechanisms and functions of inflammasomes. Cell. (2014) 157:1013–22. 10.1016/j.cell.2014.04.007
6.
MartinonFBurnsKTschoppJ. The inflammasome: a molecular platform triggering activation of inflammatory caspases and processing of proIL-beta. Mol Cell. (2002) 10:417–26. 10.1016/S1097-2765(02)00599-3
7.
KayagakiNWarmingSLamkanfiMVande WalleLLouieSDongJet al. Non-canonical inflammasome activation targets caspase-11. Nature. (2011) 479:117–21. 10.1038/nature10558
8.
KumarV. Inflammasomes: pandora's box for sepsis. J Inflamm Res. (2018) 11:477–502. 10.2147/JIR.S178084
9.
MaoKChenSChenMMaYWangYHuangBet al. Nitric oxide suppresses NLRP3 inflammasome activation and protects against LPS-induced septic shock. Cell Res. (2013) 23:201–12. 10.1038/cr.2013.6
10.
GongZZhouJLiHGaoYXuCZhaoSet al. Curcumin suppresses NLRP3 inflammasome activation and protects against LPS-induced septic shock. Mol Nutr Food Res. (2015) 59:2132–42. 10.1002/mnfr.201500316
11.
WangPHuangJLiYChangRWuHLinJet al. Exogenous carbon monoxide decreases sepsis-induced acute kidney injury and inhibits NLRP3 inflammasome activation in rats. Int J Mol Sci. (2015) 16:20595–608. 10.3390/ijms160920595
12.
MoonJSLeeSParkMASiemposIIHaslipMet al. UCP2-induced fatty acid synthase promotes NLRP3 inflammasome activation during sepsis. J Clin Invest. (2015) 125:665–80. 10.1172/JCI78253
13.
LuoYPJiangLKangKFeiDSMengXLNanCCet al. Hemin inhibits NLRP3 inflammasome activation in sepsis-induced acute lung injury, involving heme oxygenase-1. Int Immunopharmacol. (2014) 20:24–32. 10.1016/j.intimp.2014.02.017
14.
LongHXuBLuoYLuoK. Artemisinin protects mice against burn sepsis through inhibiting NLRP3 inflammasome activation. Am J Emerg Med. (2016) 34:772–7. 10.1016/j.ajem.2015.12.075
15.
KalbitzMFattahiFGrailerJJJajouLMalanEAZetouneFSet al. Complement-induced activation of the cardiac NLRP3 inflammasome in sepsis. FASEB J. (2016) 30:3997–4006. 10.1096/fj.201600728R
16.
RathinamVAFitzgeraldKA. Inflammasome complexes: emerging mechanisms and effector functions. Cell. (2016) 165:792–800. 10.1016/j.cell.2016.03.046
17.
SrinivasulaSMPoyetJLRazmaraMDattaPZhangZAlnemriES. The PYRIN-CARD protein ASC is an activating adaptor for caspase-1. J Biol Chem. (2002) 277:21119–22. 10.1074/jbc.C200179200
18.
ZychlinskyAPrevostMCSansonettiPJ. Shigella flexneri induces apoptosis in infected macrophages. Nature. (1992) 358:167–9. 10.1038/358167a0
19.
ZanoniITanYDi GioiaMBroggiARuanJShiJet al. An endogenous caspase-11 ligand elicits interleukin-1 release from living dendritic cells. Science. (2016) 352:1232–6. 10.1126/science.aaf3036
20.
EvavoldCLRuanJTanYXiaSWuHKaganJC. The pore-forming protein gasdermin d regulates interleukin-1 secretion from living macrophages. Immunity. (2018) 48:35–44.e6. 10.1016/j.immuni.2017.11.013
21.
HeYHaraHNunezG. Mechanism and regulation of NLRP3 inflammasome activation. Trends Biochem Sci. (2016) 41:1012–21. 10.1016/j.tibs.2016.09.002
22.
LamkanfiMDixitVM. Inflammasomes and their roles in health and disease. Annu Rev Cell Dev Biol. (2012) 28:137–61. 10.1146/annurev-cellbio-101011-155745
23.
SutterwalaFSHaaskenSCasselSL. Mechanism of NLRP3 inflammasome activation. Ann N Y Acad Sci. (2014) 1319:82–95. 10.1111/nyas.12458
24.
DanielskiLGGiustinaADBonfanteSBarichelloTPetronilhoF. The NLRP3 inflammasome and its role in sepsis development. Inflammation. (2020) 43:24–31. 10.1007/s10753-019-01124-9
25.
CorneliusDCTravisOKTramelRWBorges-RodriguezMBaikCHGreerMet al. NLRP3 inflammasome inhibition attenuates sepsis-induced platelet activation and prevents multi-organ injury in cecal-ligation puncture. PLoS ONE. (2020) 15:e0234039. 10.1371/journal.pone.0234039
26.
MiaoEAMaoDPYudkovskyNBonneauRLorangCGWarrenSEet al. Innate immune detection of the type III secretion apparatus through the NLRC4 inflammasome. Proc Natl Acad Sci USA. (2010) 107:3076–80. 10.1073/pnas.0913087107
27.
KofoedEMVanceRE. Innate immune recognition of bacterial ligands by NAIPs determines inflammasome specificity. Nature. (2011) 477:592–5. 10.1038/nature10394
28.
ZhaoYYangJShiJGongYNLuQXuHet al. The NLRC4 inflammasome receptors for bacterial flagellin and type III secretion apparatus. Nature. (2011) 477:596–600. 10.1038/nature10510
29.
NicholsRDvon MoltkeJVanceRE. NAIP/NLRC4 inflammasome activation in MRP8(+) cells is sufficient to cause systemic inflammatory disease. Nat Commun. (2017) 8:2209. 10.1038/s41467-017-02266-w
30.
WuCLuWZhangYZhangGShiXHisadaYet al. Inflammasome activation triggers blood clotting and host death through pyroptosis. Immunity. (2019) 50:1401–11.e4. 10.1016/j.immuni.2019.04.003
31.
KayagakiNWongMTStoweIBRamaniSRGonzalezLCAkashi-TakamuraSet al. Noncanonical inflammasome activation by intracellular LPS independent of TLR4. Science. (2013) 341:1246–9. 10.1126/science.1240248
32.
ShiJZhaoYWangYGaoWDingJLiPet al. Inflammatory caspases are innate immune receptors for intracellular LPS. Nature. (2014) 514:187–92. 10.1038/nature13683
33.
SollbergerGStrittmatterGEKistowskaMFrenchLEBeerHD. Caspase-4 is required for activation of inflammasomes. J Immunol. (2012) 188:1992–2000. 10.4049/jimmunol.1101620
34.
ViganoEDiamondCESpreaficoRBalachanderASobotaRMMortellaroA. Human caspase-4 and caspase-5 regulate the one-step non-canonical inflammasome activation in monocytes. Nat Commun. (2015) 6:8761. 10.1038/ncomms9761
35.
KnodlerLACrowleySMShamHPYangHWrandeMMaCet al. Noncanonical inflammasome activation of caspase-4/caspase-11 mediates epithelial defenses against enteric bacterial pathogens. Cell Host Microbe. (2014) 16:249–56. 10.1016/j.chom.2014.07.002
36.
CassonCNYuJReyesVMTaschukFOYadavACopenhaverAMet al. Human caspase-4 mediates noncanonical inflammasome activation against gram-negative bacterial pathogens. Proc Natl Acad Sci USA. (2015) 112:6688–93. 10.1073/pnas.1421699112
37.
HagarJAPowellDAAachouiYErnstRKMiaoEA. Cytoplasmic LPS activates caspase-11: implications in TLR4-independent endotoxic shock. Science. (2013) 341:1250–3. 10.1126/science.1240988
38.
ChuLHIndramohanMRatsimandresyRAGangopadhyayAMorrisEPMonackDMet al. The oxidized phospholipid oxPAPC protects from septic shock by targeting the non-canonical inflammasome in macrophages. Nat Commun. (2018) 9:996. 10.1038/s41467-018-03409-3
39.
KayagakiNStoweIBLeeBLO'RourkeKAndersonKWarmingSet al. Caspase-11 cleaves gasdermin D for non-canonical inflammasome signalling. Nature. (2015) 526:666–71. 10.1038/nature15541
40.
KajiwaraYSchiffTVoloudakisGGama SosaMAElderGBozdagiOet al. A critical role for human caspase-4 in endotoxin sensitivity. J Immunol. (2014) 193:335–43. 10.4049/jimmunol.1303424
41.
LeviMde JongeEvan der PollT. Sepsis and disseminated intravascular coagulation. J Thromb Thrombolysis. (2003) 16:43–7. 10.1023/B:THRO.0000014592.27892.11
42.
ButenasS. Tissue factor structure and function. Scientifica. (2012) 2012:964862. 10.6064/2012/964862
43.
PawlinskiRMackmanN. Cellular sources of tissue factor in endotoxemia and sepsis. Thromb Res. (2010) 125(Suppl.1):S70–3. 10.1016/j.thromres.2010.01.042
44.
GregorySAMorrisseyJHEdgingtonTS. Regulation of tissue factor gene expression in the monocyte procoagulant response to endotoxin. Mol Cell Biol. (1989) 9:2752–5. 10.1128/MCB.9.6.2752
45.
BrandKFowlerBJEdgingtonTSMackmanN. Tissue factor mRNA in THP-1 monocytic cells is regulated at both transcriptional and posttranscriptional levels in response to lipopolysaccharide. Mol Cell Biol. (1991) 11:4732–8. 10.1128/MCB.11.9.4732
46.
MackmanNBrandKEdgingtonTS. Lipopolysaccharide-mediated transcriptional activation of the human tissue factor gene in THP-1 monocytic cells requires both activator protein 1 and nuclear factor kappa B binding sites. J Exp Med. (1991) 174:1517–26. 10.1084/jem.174.6.1517
47.
ZhangYMengHMaRHeZWuXCaoMet al. Circulating microparticles, blood cells, and endothelium induce procoagulant activity in sepsis through phosphatidylserine exposure. Shock. (2016) 45:299–307. 10.1097/SHK.0000000000000509
48.
TaylorFBJrChangARufWMorrisseyJHHinshawLet al. Lethal E. coli septic shock is prevented by blocking tissue factor with monoclonal antibody. Circ Shock. (1991) 33:127–34.
49.
DackiwAPMcGilvrayIDWoodsideMNathensABMarshallJCRotsteinOD. Prevention of endotoxin-induced mortality by antitissue factor immunization. Arch Surg. (1996) 131:1273–8; discussion 8–9. 10.1001/archsurg.1996.01430240027003
50.
ShahKGWuRJacobAMolmentiEPNicastroJCoppaGFet al. Recombinant human milk fat globule-EGF factor 8 produces dose-dependent benefits in sepsis. Intensive Care Med. (2012) 38:128–36. 10.1007/s00134-011-2353-7
51.
RittirschDFlierlMAWardPA. Harmful molecular mechanisms in sepsis. Nat Rev Immunol. (2008) 8:776–87. 10.1038/nri2402
52.
GouldTJVuTTSwystunLLDwivediDJMaiSHWeitzJIet al. Neutrophil extracellular traps promote thrombin generation through platelet-dependent and platelet-independent mechanisms. Arterioscler Thromb Vasc Biol. (2014) 34:1977–84. 10.1161/ATVBAHA.114.304114
53.
Sunden-CullbergJNorrby-TeglundATreutigerCJ. The role of high mobility group box-1 protein in severe sepsis. Curr Opin Infect Dis. (2006) 19:231–6. 10.1097/01.qco.0000224816.96986.67
54.
AmmolloCTSemeraroFXuJEsmonNLEsmonCT. Extracellular histones increase plasma thrombin generation by impairing thrombomodulin-dependent protein C activation. J Thromb Haemost. (2011) 9:1795–803. 10.1111/j.1538-7836.2011.04422.x
55.
CorneliusDCBaikCHTravisOKWhiteDLYoungCMAustin PierceWet al. NLRP3 inflammasome activation in platelets in response to sepsis. Physiol Rep. (2019) 7:e14073. 10.14814/phy2.14073
56.
YangXChengXTangYQiuXWangYKangHet al. Bacterial endotoxin activates the coagulation cascade through gasdermin D-dependent phosphatidylserine exposure. Immunity. (2019) 51:983–96.e6. 10.1016/j.immuni.2019.11.005
57.
PengYGaoMLiuYQiuXChengXYangXet al. Bacterial outer membrane vesicles induce disseminated intravascular coagulation through the caspase-11-gasdermin D pathway. Thromb Res. (2020) 196:159–66. 10.1016/j.thromres.2020.08.013
58.
DengMTangYLiWWangXZhangRZhangXet al. The endotoxin delivery protein HMGB1 mediates caspase-11-dependent lethality in sepsis. Immunity. (2018) 49:740–53.e7. 10.1016/j.immuni.2018.08.016
59.
YangXChengXTangYQiuXWangZFuGet al. The role of type 1 interferons in coagulation induced by gram-negative bacteria. Blood. (2020) 135:1087–100. 10.1182/blood.2019002282
60.
GurungPAnandPKMalireddiRKVande WalleLVan OpdenboschNDillonCPet al. FADD and caspase-8 mediate priming and activation of the canonical and noncanonical Nlrp3 inflammasomes. J Immunol. (2014) 192:1835–46. 10.4049/jimmunol.1302839
61.
SagulenkoVThygesenSJSesterDPIdrisACridlandJAVajjhalaPRet al. AIM2 and NLRP3 inflammasomes activate both apoptotic and pyroptotic death pathways via ASC. Cell Death Differ. (2013) 20:1149–60. 10.1038/cdd.2013.37
62.
ZhangHZengLXieMLiuJZhouBWuRet al. TMEM173 drives lethal coagulation in sepsis. Cell Host Microbe. (2020) 27:556–70 e6. 10.1016/j.chom.2020.02.004
63.
YangDHeYMunoz-PlanilloRLiuQNunezG. Caspase-11 requires the pannexin-1 channel and the purinergic P2X7 pore to mediate pyroptosis and endotoxic shock. Immunity. (2015) 43:923–32. 10.1016/j.immuni.2015.10.009
64.
ZelicMRoderickJEO'DonnellJALehmanJLimSEJanardhanHPet al. RIP kinase 1-dependent endothelial necroptosis underlies systemic inflammatory response syndrome. J Clin Invest. (2018) 128:2064–75. 10.1172/JCI96147
65.
BettigoleSEGlimcherLH. Endoplasmic reticulum stress in immunity. Annu Rev Immunol. (2015) 33:107–38. 10.1146/annurev-immunol-032414-112116
66.
VigMKinetJP. Calcium signaling in immune cells. Nat Immunol. (2009) 10:21–7. 10.1038/ni.f.220
67.
LeeGSSubramanianNKimAIAksentijevichIGoldbach-ManskyRSacksDBet al. The calcium-sensing receptor regulates the NLRP3 inflammasome through Ca2+ and cAMP. Nature. (2012) 492:123–7. 10.1038/nature11588
68.
ChenRZengLZhuSLiuJZehHJKroemerGet al. cAMP metabolism controls caspase-11 inflammasome activation and pyroptosis in sepsis. Sci Adv. (2019) 5:eaav5562. 10.1126/sciadv.aav5562
69.
ZhouBLiuJZengLZhuSWangHBilliarTRet al. Extracellular SQSTM1 mediates bacterial septic death in mice through insulin receptor signalling. Nat Microbiol. (2020) 5:1576–87. 10.1038/s41564-020-00795-7
70.
KangRZengLZhuSXieYLiuJWenQet al. Lipid peroxidation drives gasdermin d-mediated pyroptosis in lethal polymicrobial sepsis. Cell Host Microbe. (2018) 24:97–108.e4. 10.1016/j.chom.2018.05.009
Summary
Keywords
inflammation, inflammasome, sepsis, DIC, coagulation
Citation
Wu R, Wang N, Comish PB, Tang D and Kang R (2021) Inflammasome-Dependent Coagulation Activation in Sepsis. Front. Immunol. 12:641750. doi: 10.3389/fimmu.2021.641750
Received
14 December 2020
Accepted
22 February 2021
Published
16 March 2021
Volume
12 - 2021
Edited by
Yong Ming Yao, First Affiliated Hospital of Chinese PLA General Hospital, China
Reviewed by
Krzysztof Guzik, Jagiellonian University, Poland; Xu-Lin Chen, First Affiliated Hospital of Anhui Medical University, China
Updates
Copyright
© 2021 Wu, Wang, Comish, Tang and Kang.
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Daolin Tang daolin.tang@utsouthwestern.eduRui Kang rui.kang@utsouthwestern.edu
This article was submitted to Inflammation, a section of the journal Frontiers in Immunology
Disclaimer
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.