Endothelial progenitor cells in age-related vascular remodeling

EPC status in age-related vascular remodeling

Previous study has shown that the number of circulating EPCs decreases reversibly with aging, especially in patients with coronary artery disease ⁴² . For example, Scheubel et al. reported an age-related reduction of circulating EPCs in aged patients undergoing coronary artery bypass grafting ⁴³ . The number of EPC-CFUs in culture was found to be inversely correlated with cardiovascular risks in adults ²⁸ . Among patients with low, intermediate, and high numbers of CFU-ECs, those with the highest levels were considered to be the healthiest ²⁸ . Indeed, decreased ability of EPCs to proliferate in vitro and to express the endothelial phenotype was associated with the risk factors for coronary artery disease and endothelial dysfunction ^28,44 .

The circulating number of EPCs can serve as a predicting factor for the patient’s outcome ⁴⁵ . Dysfunctional EPCs may lead to impaired ability to restore endothelial damage ⁴⁶ . EPC number was found to be a strong and independent negative predictor of atherosclerotic plaque occurrence in the common carotid artery ^47,48 . Meanwhile, it has also been demonstrated that EPC number is reduced with the presence and progression of preclinical atherosclerosis, and the risk factors constitute a decrease in aortic and femoral sites, but not in carotid circulation ⁴⁹ . Peripheral arterial disease was associated with lower cell counts of CD34⁺ and CD34⁺/VEGFR2^{+ 50} . A decrease of EPCs to below 0.0038% of total circulating peripheral blood MNCs represents a six-fold higher risk for the development of CVDs ⁴⁶ . Coronary artery disease patients with the highest EPC number have the highest likelihood of remaining event-free ⁴⁴ .

Therefore, EPCs serve as promising biomarkers of cardiovascular health ⁴⁸ . However, some investigators reported no correlation between EPC subsets and vascular remodeling, with no direct association of EPC number change with CVD progression ^51,52 . Differences in methods used for identifying EPCs may lead to such disparity.

Involvement of EPCs in age-related vascular remodeling

Endothelial damage is an important early step in the initiation and development of atherosclerosis, a hallmark of aging ¹ . Structural and functional endothelial damage contributing to atherosclerosis is a common event, and endothelial regeneration is critical for maintaining endothelial homeostasis ^53,54 . In the context of regeneration, animal studies have shown that EPCs efficiently contribute to restoring endothelial function and decrease neointimal formation after arterial injury ^{55 –60} . An adequate homing of EPCs plays a central role in this regenerative arterial remodeling ⁵⁷ . The process of EPC homing, including mobilization, recruitment, and adhesion, is regulated by key angiogenic chemokines (CXCL1, CXCL7, CXCL12, CCL2) and their respective receptors (CXCR2, CXCR4, CCR2) ⁵⁷ . Hristov et al. showed that CXCR2 is crucial for the homing of circulating EPCs to sites of arterial injury and for endothelial repair ⁵⁵ . It was also found that rat bone marrow-derived EPC functional activity could be ameliorated by decreasing cellular senescence via AKT/endothelial nitric oxide synthase (eNOS) pathways and improving homing capacity via increasing CXCR4 expression levels ⁶¹ . Walter et al. reported that the use of statins increased circulating rat EPCs and promoted adhesion of cultured human EPCs by augmentation of integrin subunits α₅, α_v, β₁, and β₅ of human EPCs ⁵⁸ . Augmentation of integrin receptor expression may thus promote adhesion and enhance homing of EPCs to foci of ischemia or vascular injury ⁵⁸ . Meanwhile, EPCs play an important role in the neovascularization of ischemic tissue by promoting the formation of new vessels and releasing angiogenic growth factors ^11,12 . Currently, the common clinical concept claims a protective role for EPCs even during the initiation and development of atherosclerosis, further suggesting that EPCs may reflect the endogenous vascular repair ability ^46,62 . Intramyocardial injection by synergistic local co-administration of angiogenic compounds may help to further promote the homing of EPCs and neovascularization after myocardial infarction ⁶³ . The therapeutic effects are exerted even in the chronic stage, when acute inflammation and oxidative stress are attenuated ^63,64 . Kaushal et al. coated vascular grafts with endogenous EPCs and found that EPCs can exert functions similar to arterial ECs, thereby conferring longer vascular-graft survival ⁶⁵ . Thus, the coating of stents with EPC-attracting peptides or antibodies to capture EPCs in terms of promoting endothelialization and diminishing in-stent stenosis remains an exciting alternative for clinical application ^66,67 .

Although therapeutic effects of EPCs in the treatment of atherosclerotic diseases have been observed in animal models and humans, the crucial involvement of EPCs in the pathogenesis of atherosclerosis has newly emerged. Interestingly, transplanted EPCs increase the lipid content and decrease collagen amounts in atherosclerotic plaques of Apoe^−/− mice ⁶⁸ . Furthermore, higher serum concentrations of IL-6 and monocyte chemoattractant protein-1, and lower serum concentration of IL-10, were found in mice transfused with EPCs ⁶⁸ . Increased plasma CXCR2 receptor ligands such as CXCL1 and CXCL7 were clinically related to plaque destabilization, while blocking of CXCR2 was associated with a more stable plaque phenotype in experimental models ^{69 –71} . The influx of CXCR2⁺ monocyte subsets containing putative endothelial precursors with inflammatory, proteolytic, and angiogenic properties may partly contribute to these findings ^55,71 . Vega et al. found that the atherosclerotic plaque secretome promotes EPC proliferation, mobilization, permeability, contraction, and adhesion ⁷² . Furthermore, the up-regulated expression of proteins that are mostly involved in cell proliferation, migration, and vascular remodeling was observed in the atherosclerotic plaque secretome treated cells ⁷² . It was also found that increased circulating CD34⁺ cells after coronary stenting may serve as an independent risk factor for predicting in-stent restenosis and indicate the involvement of CD34⁺ subpopulations in neointimal hyperplasia ⁷³ . Thus, the dual contribution of EPC subpopulations to vascular remodeling in atherosclerosis needs a critical reevaluation ⁸ .

In the early stage of primary and secondary atherosclerosis after injury, which is characterized by endothelial dysfunction, EPCs (mainly as late-outgrowth EPCs) mobilize to the injured area, penetrate the site of vessel injury, and differentiate into mature ECs. This in turn replaces the dysfunctional endothelium, further avoiding the development of atherosclerosis (Figure 1(a)). Hence, EPCs may provide a circulating pool of cells that could generate a cellular patch at the site of denuding injury or serve as a cellular reservoir to substitute the injured endothelium ²⁸ . In recent years, accumulating evidence has indicated that activation of tissue-resident ECs through paracrine mechanisms may become more crucial for EPC-based neovascularization than direct differentiation and incorporation into the vasculature ^74,75 . Early-outgrowth EPCs secrete several cytokines, such as VEGF, HGF, G-CSF, and GM-CSF ^20,21 . Therefore, EPCs (mainly as early-outgrowth EPCs) could also repair the injured ECs by secreting growth factors (Figure 1(a)). Advanced atherosclerosis is characterized by redundant sub-endothelial accumulation of lipids and immune cells, neointimal hyperplasia, excessive proliferation of SMCs, matrix deposition, and foam cell formation ³⁸ . It involves widespread mobilization of EPCs associated with that of monocytes in response to inflammatory factors, such as monocyte chemoattractant protein 1, and may promote plaque instability/vascularization ¹² (Figure 1(b)). Again, the contribution of EPCs during vascular remodeling in the early and advanced disease stages, as well as primary and secondary atherosclerosis, requires a more careful and critical reevaluation ⁷⁶ .

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Figure 1.

Involvement of EPCs in age-related vascular remodeling. (a) In the early stage of primary and secondary atherosclerosis after injury, characterized by endothelial dysfunction, endothelial progenitor cells (EPCs, mainly as late-outgrowth EPCs) can be mobilized to the injured area, penetrate the site of vessel injury, and differentiate into mature endothelial cells (ECs), replacing the dysfunctional endothelium and avoiding further atherosclerosis development. EPCs (mainly as early-outgrowth EPCs) could also repair injured ECs by secreting growth factors. (b) In advanced atherosclerosis, characterized by redundant sub-endothelial accumulation of lipids and immune cells, neointimal hyperplasia, excessive proliferation of smooth muscle cells (SMCs), matrix deposition, and foam cell formation, a widespread EPC mobilization concomitant with that of monocytes in response to inflammatory factors may, rather, promote plaque instability/vascularization.

In addition, it should be mentioned that aging may also affect the pathways involved in the contribution of EPCs to vascular remodeling. A significant reduction in the expression of CXCR4 was found in the CD34⁺ cell population with aging ⁷⁷ . It was also found that the surface CXCR4 expression on bone marrow-derived cells was significantly reduced in aged mice compared with young mice ^78,79 . Xia et al. showed no difference in the surface expression of CXCR4 receptor in EPCs between older and younger men ⁸⁰ . However, phosphorylation of JAK-2, a downstream signaling of CXCR4, is markedly decreased in EPCs derived from elderly men ⁸⁰ . It was suggested that bone marrow-derived EPC functional activity could be ameliorated by decreasing cellular senescence and improving homing capacity through increasing CXCR4 expression levels ⁶¹ . So, aging may impair the protective effects of EPCs in vascular remodeling via affecting CXCR4-JAK-2 pathways.

Obstacles and possible solutions

There is no specific marker for EPCs, and many studies assessing EPCs have included limited analyses regarding the cell phenotypes. The use of an often poorly defined label “progenitor cells” for heterogeneous therapeutic cell subtypes complicates study comparisons, making it quite challenging to reach definitive conclusions concerning their efficacy ⁸¹ . Defining and standardizing EPC surface markers are extremely important for comparing more EPC studies ⁸² . In addition, the methods for culturing EPCs should be more standardized and, if possible, this should be done in a uniform manner.

Convincing evidence has emerged that EPCs from the elderly are impaired in terms of number, function, and survival ^{83 –87} . Clinical application of cardiovascular cell repair therapy showed some limitations in older patients ^88,89 . The major obstacles include degradation of functionality of autologous stem or progenitor cells in older individuals, and difficulties in engraftment and survival of transplanted cells in the hostile host microenvironment ⁷ . EPC-based therapy showed that an increase in the number or function of circulating EPCs may be effective in the treatment of atherosclerotic diseases ⁹⁰ . However, large-scale use of cell-based therapy was limited due to the poor viability of EPCs after transplantation ⁹⁰ . Therefore, enhancement strategies to reactivate the proliferation and function of EPCs in aged patients need to be explored urgently ⁹¹ .

EPC function enhancement was observed after administration of growth factors such as HGF and insulin-like growth factor (IGF)-1 ^92,93 . Recombinant bone morphogenetic protein 4 also markedly improved the migration and adhesion capacity of human EPCs ⁹⁴ . In clinical application, the most feasible method to improve EPC number and function is drug treatment. To date, the most practicable strategies applied in the clinic are pharmacological treatments with anti-hypertensive and anti-hyperglycemic effects ⁹¹ . Previous studies reported that beta blockers, calcium channel blockers, and angiotensin II receptor antagonists significantly increased EPC counts ^{95 –99} . In diabetic and non-diabetic patients, pharmacological products, such as anti-diabetic peroxisome proliferator-activated receptor gamma (PPARG) agonists, have been shown to enhance EPC number and function ^100,101 . Other drugs, for example rosuvastatin and cilostazol, also exerted positive effects on circulating EPC levels ¹⁰² . As well as Western medicine, traditional Chinese drugs have recently shown beneficial effects on EPC function. Tanshinone IIA may have the potential to protect EPCs against damage induced by tumor necrosis factor-α ¹⁰³ . Danhong injection, extracted from Radix Salvia miltiorrhiza and Flos Carthamus tinctorius L, is effective in repairing endothelial lesions by mobilizing EPCs ¹⁰⁴ .

Although the drug treatment mentioned earlier could increase the number and function of EPCs, adverse effects of the drugs, such as headache, nausea, and asthenia, may also occur, especially in the elderly population. Non-drug therapies may be good choices to enhance EPC function and avoid adverse effects. Interestingly, exercise has direct beneficial effects on EPC number and function in the aged population ^{80,105 –108} . Meanwhile, other interesting studies have shown that Mediterranean diets and black tea exert protective effects on EPC level and function ^{109 –112} . As concomitant strategies to enhance EPC number and function, lifestyle and diet modifications should be strongly encouraged in aged patients ⁹¹ .

Recent attempts to improve the number and function of transplanted EPCs with gene modification may facilitate repair of the injured endothelium and accelerate reendothelialization ¹¹³ . Transplantation of genetically modified EPCs that overexpress PDGFR-β, β2AR, and CXCR7, or with reduced Lnk levels, significantly enhanced the vascular repair ability of EPCs, improving the inhibition of adverse remodeling after vascular injury ^{113 –117} . EPC transplantation combined with gene transfer may be a promising EPC therapeutic strategy in the future for age-related vascular remodeling.