Nitric oxide produced by eNOS is a major medium which mediates relaxation and vasodilatation of the vessels. Production and bioavailability of NO are reduced in the early stages of DR (47), while PPARγ activation increases production and bioavailability of NO. PPARγ ligands, such as 15-deoxy-Δ (12, 14)-prostaglandin J₂ (15d-PGJ₂), rosiglitazone, and nitrooleate, are able to increase eNOS activity and NO release through increased interaction between heat shock protein 90 (HSP90) and eNOS (48, 49). Rudnicki et al. assessed the effect of 3 thiazolidinediones (TZDs), GQ-32, GQ-169, and LYSO-7, on NO, ROS, and adhesion molecules on ECs (50). Although all of three activated PPARγ and enhanced the intracellular NO level, only LYSO-7 significantly increased the NO release from ECs. They all suppressed the adhesion molecule expressions induced by TNF-α. Additionally, GQ-169 and LYSO-7 inhibited ROS production in response to high glucose. PPARγ activation decreases expressions of NADPH oxidase subunits and enhances the expression of superoxide dismutase (SOD), which result in enhanced NO bioavailability to reduce oxidative stress in the membrane of human umbilical vein endothelial cells (HUVECs) (51).

Aleglitazar, a dual-PPARα/γ agonist, has been shown to increase eNOS, Akt, and telomerase activities in circulating angiogenic cells (52). Rosiglitazone increases eNOS and Akt activity and NO synthesized by endothelial progenitor cells (EPCs), which are reduced by AGEs. Its beneficial effect can be blocked by the eNOS inhibitor and phosphoinositide 3-kinase/protein kinase B (PI3K/AKT) inhibitor, indicating that rosiglitazone can improve AGE-induced EPC dysfunction by AGEs through upregulating the AKT/eNOS signal pathways in EPCs (53).

Hyperglycemia induces oxidative stress in patients with diabetes. Oxidative stress, which resulted from increased NADPH oxidase, is a key factor involved in the development of DR (11, 12). It activates inhibitory redox-regulated transcription factors to attenuate PPARγ expression and activity in vascular ECs (54). PPARγ exerts its antioxidative function through transcriptional activation of a number of antioxidant genes (55–57). The major ROS produced in response to hyperglycemia is superoxide anion (O2-) which combines with NO to produce peroxynitrite (ONOO?). This leads to decrease in NO bioavailability, which causes endothelial dysfunction (58).

PPARγ can transcriptionally regulate HO-1 expression in vascular cells (56). Its activation induces the expression of glutathione peroxidase 3 (GPx3), which detoxifies the extracellular H₂O₂ level. The inhibition of GPx3 expression prevents the antioxidant effects of the PPARγ ligand on oxidative stress in insulin-resistant cells (59). Troglitazone and pioglitazone increases Cu²⁺, Zn²⁺-superoxide dismutase (CuZn-SOD) gene expression and protein levels (60). 15d-PGJ₂ or ciglitazone reduces gene and protein expressions of the NADPH oxidase subunits, such as nox-2 and nox-4, and stimulates protein expression and activity of Cu/Zn-SOD in HUVECs (51).

Oxidative stress also impairs reendothelialization ability of EPCs derived from patients with diabetes, while rosiglitazone improves reendothelialization EPC therapy potential by reduces NADPH oxidase activity (61). Pioglitazone can inhibit NADPH oxidase p22 (phox) and Rac1. The latter is responsible for producing ROS, which negatively regulates EPC migration, proliferation, and differentiation. Recently, Liu et al. have demonstrated that PPARγ activation can transcriptionally upregulate the expression of long intergenic noncoding RNA 01230 (Linc01230), which reduces oxide low-density lipoprotein-induced endothelial dysfunction and affects the phosphorylation of AKT (62).

In addition to directly modulating oxidative stress response, PPARγ can indirectly modulate through nuclear factor E2-related factor 2 (Nrf2) activation (63). Nrf2 is a transcription factor that regulates the expression of antioxidant proteins (64, 65). When transported inside the nucleus, Nrf2 works with other activators to form a protein complex. The latter binds to the antioxidant response elements (AREs) in the upstream promoter regions of cytoprotective and detoxifying genes to activate their transcription (64, 66). Studies have shown that there is a reciprocal transcriptional regulation between Nrf2 and PPARγ pathways to enhance the expression of one another (57, 63). PPARγ is upregulated in mice in which Nrf2 is increased and is downregulated in Nrf2^−/− mice (57, 67). ChIP assays have shown that with cofactor Brg1, Nrf2 is coimmunoprecipitated on the ARE containing the upstream promotor region of PPAR-γ (67). Nrf2 expression is reduced in mice with decreased PPARγ (68). PPARγ may act directly or through the upstream pathway to activate Nrf2 (57). A peroxisome proliferator response element, through which PPARγ regulates Nrf2 expression, in the promoter region of Nrf2 gene has been proposed (57). Future studies are needed to prove a direct effect of PPARγ on Nrf2.

Although PPARγ activation promotes antioxidant response and promotes the expression of antioxidant enzymes and NO product in ECs, PPARγ receptors are downregulated in the diabetic eye and their suppression is involved in the pathogenesis of DR (45, 46). Thus, it is not easy to fully reverse endothelial dysfunction using only PPARγ ligands in DR. Strategies aiming to improve the sensitivity or upregulate PPARγ receptor expression in ECs of DR are valuable therapeutic approaches.

Proinflammatory cytokines, such as TNF-α, IL-1, IL-6, IL-8, and IFN-γ, are the major players in inflammation in DR. Increased concentrations of TNF-α, IL-1, IL-6, IL-8, and IFN-γ have been found in the vitreous (74) or in aqueous humor (75) of patients with DR. Their concentrations may be associated with the severity of DR (75).

Monocyte chemoattractant protein-1 attracts and activates monocyte and macrophages (112, 113) and stimulates fibrosis and angiogenesis (114). MCP-1 is produced by Müller cells, microglia cells, astrocytes, retinal neurons, ECs, and retinal pigment epithelial cells in patients with diabetes (115). The migration of monocyte into the retina is mediated by MCP-1 coupling to its receptor CCR2 (116). Elevated MCP-1 has been observed in ocular tissues from patients with NPDR or PDR, (10, 82, 104, 117) and its level is higher in the vitreous than in the serum (74). The vitreous MCP-1 level has been shown to be associated with DR severity (100). Intravitreal increase in MCP-1 level may be associated with the progression of NPDR to active PDR (95). Through increasing vascular cell permeability and leukocytes' recruitment, MCP-1 affects BRB in animal eyes of DR (118). In response to IL-1β or TNF-α, retinal ECs or microglial cells will express a high level of MCP-1 to attract macrophages (119), which may adhere to the retinal capillary endothelium, which leads to capillary occlusion and retinal ischemia (120). TNF-α and IL-6 produced by glial cells and microglial cells can stimulate ECs to release MCP-1, IL-6, and VEGF, all of which increase vascular permeability in NPDR (121). MCP-1 exerts its cytotoxic effect through oxidative stress produced by activated macrophage and microglia (122). Although MCP-1 is a potent inducer of angiogenesis, its angiogenic effect is achieved through induction of VEGF-A (123, 124). A significantly positive correlation has been observed between the MCP-1 and VEGF in PDR (125). Although lower levels of MCP-1 have been reported in the aqueous humor from NPDR and PDR patients (126, 127), the discrepancy may be due to different sample preservation and measurement techniques used.

Increased vitreous concentrations of the growth factors, such as VEGF, FGF (128), PDGF (129), placental growth factor (PlGF) (130), angiopoietin (131), insulin-like growth factor (IGF-1) (132), and hepatocyte growth factor (HGF), have been reported in patients with PDR. Among these, VEGF has received particular attention and will be summarized in this section.

Over the decades, VEGF has been recognized as a major angiogenic growth factor, which is responsible for pathologic retinal neovascularization in DR (133). VEGF is an angiogenic factor that not only induces new blood vessel sprouting from preexisting vessels but also increases vascular permeability. In addition to ECs, other retina cells, such as retinal pigment epithelial cells, pericytes, Müller cells, astrocytes, and glial cells, are also able to produce VEGF upon activation or stimulated by long-term high glucose (9, 134–139).

Increased VEGF level has been observed in the vitreous humor and in fibrovascular tissues from eyes with PDR (140–142). Serum and vitreous VEGF levels have been found to correlate with glycemic control in patients with diabetes (143). A strong correlation between increased level of intravitreal VEGF and the development of DR has been detected (144, 145). Vitreous level of VEGF may be correlated with retinopathy activity (142, 146, 147). More recently, serum VEGF level in subjects with diabetes has been proposed to be a biomarker of severity of DR as it is associated with the severity of DR (148, 149).

VEGF is a key regulator of ocular angiogenesis and vascular permeability. It is involved in the pathogenesis of a number of complications of DR, such as DME and PDR (150). It has been shown that intraocular injection of VEGF alone produced many features of NPDR and PDR: areas of non-perfusion capillaries, vessel dilation, and tortuosity arterioles with endothelial hyperplasia and microaneurysm formation (151). A positive correlation has been found between the level of serum VEGF and the grade of the external limiting membrane (ELM) disruption, indicating that an increased level of VEGF is associated with DR severity and the grade of the external limiting membrane disruption (149).

VEGF modulates DR-associated inflammatory responses at the early stage of DR (13). It acts as a pro-inflammatory factor to promote the expressions of other proinflammatory cytokines, chemokines, and adhesion molecules, such as TNF-α, IL-1, IL-6, IL-8, IFN-γ, MCP-1, and ICAM-1 (102, 152, 153). Vice versa, activated glial cells, macrophages, and microglia cells will produce TNF-α, IL-6, and MCP-1, which in turn can stimulate VEGF release from retinal ECs (123). Increased activation of NF-κB in NPDR and PDR subjects may be involved in increased upregulation of VEGF (154). VEGF induces MCP-1, IL-8, TNF-α, and ICAM-1 expression in retinal ECs by activating NF-kB pathways (13, 102, 153). Müller glia-specific VEGF deletion resulted in 48% percent reduction in the NF-κB activation in diabetic mouse retina (13). This was associated with 50% reduction of TNFα and ICAM-1 in retina and 75% reduction of leukocyte adhesion in the retinal microvasculature.

VEGF enhances the leukocyte adhesion to vessel walls through increasing ICAM-1 and VCAM-1 expressions on ECs (155). In addition, VEGF may initiate early diabetic retinal leukocyte adhesion in retinal arterioles through upregulated ICAM-1 expression (152, 156). Increased serum VEGF levels stimulate ROS generation, which causes endothelial activation (157).

Studies show that adhesion molecules play important roles in pathogenesis of vascular complications (158). Adhesion molecules participate in cell growth, differentiation, formation of cell junction, or cell polarity, as well as activation, circulation, or accumulation of white leukocytes at the inflammatory site (158). They participate in initiating the process of monocyte and lymphocyte adhesion to ECs and mediate their transmigration (158).

Numerous endothelial molecules, primarily located at junctions, such as ICAM-1, VCAM-1, platelet/endothelial-cell adhesion molecule-1 (PECAM-1), and endothelial leukocyte adhesion molecule-1 (ELAM-1), are involved in leukocyte transmigration (158–160). ICAM-1 and VCAM-1 are upregulated in the conjunctiva of patients with DR (161). Blood serum soluble forms of VCAM-1, ICAM-1, and ELAM-1 are increased in patients with DR (162). ICAM-1 can act cooperatively with RAGE to mediate leukocyte recruitment during acute inflammation in vivo (36). The lymphocyte function-associated antigen-1 can distribute to form a ring-like structure to cocluster with endothelial ICAM-1 to mediate the neutrophil transmigration (130). A positive correlation is found between the level of serum ICAM-1 and the grade of the retinal ELM disruption (149), suggesting, in addition to VEGF, that serum ICAM-1 level is also associated with an increased DR severity and the grade of the external limiting membrane disruption (149). Thus, monitoring serum-soluble VCAM-1 levels in patients with diabetes may be clinically useful for assessing the severity and possibly the activity of diabetic retinopathy (163). The soluble ICAM-1 is a biomarker of endothelial injury and inflammation. ICAM-1, VCAM, and ELAM-1 expressions in ECs can be stimulated by IL-1, TNF-α, and VEGF through activation of the NF-κB pathway (152, 164, 165).

PECAM-1 is important in maintaining vascular integrity (166). Although endothelial PECAM-1 homophilic interactions are required for the maintenance of EC barrier function (166), PECAM-1 also promotes leukocyte transmigration by undergoing homophilic interactions with PECAM-1 on monocytes to facilitate transmigration (167). More recently, soluble vascular adhesion protein-1/semicarbazide-sensitive amine oxidase has been shown to generate H₂O₂ and toxic aldehyde acrolein, which cause oxidative stress in eyes with PDR (168).

CD40 and Toll-like receptors play roles in inflammation in the development of DR (169–172).

Increased miRNAs, such as miR-21 and miR-195, have been demonstrated to be associated with fibrosis and oxidative stress in DR (189, 190). Increased miR-21 level in the vitreous has been shown to be associated with retinal fibrosis in PDR (189). High glucose and TGF-β induce miR-21 expression in retinal pigment epithelial cells. Furthermore, gain and loss of function studies have shown that miR-21 promotes proliferation and migration of the human retinal pigment epithelium (189). miR-21 affects PPARα expression through inhibition of PPARα mRNA translation (191). Intravitreal injection of the miR-21 inhibitor attenuates PPARα downregulation and ameliorates retinal inflammation in db/db mice (191). Knockout of miR-21 prevents the reduction of PPARα, which is associated with alleviated inflammation and microvascular damage in the retina of db/db mice. miR-221 enhances retinal EC viability and angiogenesis through activation of PI3K/Akt/VEGF and inhibits the expression of PTEN (192). miR-21 downregulates the expression of Krev interaction trapped protein 1 (KRIT1), Nrf2, and SOD2, all of which are involved in ROS homeostasis, while the miR-21 inhibitor improves KRIT1 and SOD2 expressions, reduces ROS production, and ameliorates mitochondrial membrane potential in HUVECs treated with high glucose (193). More recently, plasma miR-21 has been proposed to be an early marker for diagnosis and identification of diabetic nephropathy in type 1 diabetes mellitus (T1DM), as it starts to rise before microalbuminuria in patients with T1DM and has a greater sensitivity (94.1%) and specificity (100%) to identify DN than the urinary albumin/creatinine ratio at level 45 mg/gm with sensitivity of 88.2% and specificity of 89% (194).

High glucose stimulates miR-21-5p expression, in parallel with increased VEGF and VEGFR2 expressions and proliferation of human retinal microvascular ECs (195). Inhibition of miR-21-5p reduces proliferation, migration, and tube formation of human retinal microvascular ECs (HRMECs) through PI3K/AKT and ERK pathways (195).

Upregulated miR-195 and downregulated SIRT1 have been observed in human retinal ECs exposed to high glucose and in the retinas of diabetic rats (190). Inhibition of miR-195 recovers SIRT1 expression and decreases retinal damage in DR (190). In addition, oxidative stress induces overexpression of miR-195 which downregulates mitofusin two expression in human retinal ECs and diabetic retinas, leading to increased permeability of retinal BRB (196).

Decreased miRNAs, such as miR-126, miR-146a, and miR-200b, have been shown to increase the angiogenic factor product, promote the NF-κB pathway, and enhance VEGF-A expression and oxidative stress in DR, respectively. miR-126 is involved in the production of angiogenic factors to mediate retinal neovascularization (197, 198). A significant reduction of miR-126 in the serum is detected in patients with diabetes and macrovascular complications (199) or PDR (200). Downregulated miR-126 is observed in the retinas of oxygen-induced retinopathy, while restoring its level reduces high expression levels of VEGF, IGF, and HIF-1α, which limits retinal neovascularization through p38MAPK and ERK pathways (197). miR-126 is downregulated in hypoxia-treated rhesus retinal ECs and in retinas of diabetic rats, while restoring miR-126 expression inhibits the hypoxia-induced neovascularization by inhibiting cell-cycle progression and the expression of VEGF and matrix metallopeptidase nine. Interestingly, hyperglycemic/hypoxia-treated mesenchymal stem cell-derived extracellular vesicles downregulate miR-126 in pericytes, which express more VEGF and HIF-1α (201).

miR-146a has a regulatory role in the NF-κB-mediated inflammatory pathway. It binds to the 3′-UTR of I IL-1 receptor-associated kinase 1 to reduce the expression of NF-κB-responsive ICAM-1 in both human retinal ECs and retinas of diabetic rats (202). Intravitreal delivery of miR-146a inhibits the hyperglycemia-induced upregulation of ICAM1 and reduces microvascular leakage and retinal functional defects. Increased miR-146a protects human retinal ECs from high glucose-induced apoptosis through suppressing the STAT3/VEGF pathway (203). Decreased miR-146a expression has been shown to be associated with the overexpression of fibronectin in high glucose-treated ECs and retinas of diabetic rats (204). Decreased miR-146b-3p has been shown to be associated with increased adenosine deaminase-2 (ADA-2) activity in the vitreous of patients with diabetes, while elevated expression of miR-146b-3p suppresses the ADA2 activity and TNF-α release in amadori-glycated albumin (AGA)-treated human macrophages (205) and decreases human retinal EC permeability and leukocyte adhesion by upregulating ICAM-1 (205).

Decreased miR-200b and increased VEGF-A gene expression were observed in the sera of patients with DR (206). Decreased miR-200b is observed in high glucose-treated human retinal ECs and is accompanied with increased expressions of VEGF and transforming growth factor β (206). Increased miR-200b expression inhibits the oxidation resistance one expression, which enhances resistance to apoptosis and oxidative stress (207).

A number of miRNAs have been investigated and are considered as a therapeutic target of DR. However, as a single miRNA can regulate several target genes that modulate different signaling pathways, miRNA-based therapy should be more refined and controlled for its targeting genes. The systematic understanding miRNA action mechanism may help for the early diagnosis and improved therapeutics for DR.