Keywords
fibrosis, CD14+ cells, pluripotent stem cells, monocyte-derived multipotential cells, early endothelial progenitor cells, monocytic pro-angiogenic hematopoietic cells, fibroblast-like cells, fibrocytes,
fibrosis, CD14+ cells, pluripotent stem cells, monocyte-derived multipotential cells, early endothelial progenitor cells, monocytic pro-angiogenic hematopoietic cells, fibroblast-like cells, fibrocytes,
Systemic sclerosis (SSc) is a chronic, complex, and not yet completely understood autoimmune disease characterized by the presence of immunological events, the onset of fibrosis, and the development of vascular alterations1. The development of fibrosis seems to be a consequence of the initial ischemic process related to an endothelial injury2. In the early disease phase (first year from diagnosis), there is an increase of pro-angiogenic factors—vascular endothelial growth factor (VEGF), platelet-derived growth factor, and stromal-derived growth factor-1—in response to the vascular damage that correlates to the nailfold capillaroscopy changes observed by clinicians (giant capillaries and new vessel formation)3. But in the late phase of SSc, the anti-angiogenic response and the fibrosis seem to dominate over the initial pro-angiogenic phase4. The initial trigger event in SSc is still unknown, but circulating progenitor cells (CPCs) might play a key role4.
Since 1994, when Bucala et al. first described these fibrocytes as circulating leukocytes able to produce collagen (Col), different types of progenitor cells have been described as key players in different entities, such as pulmonary artery hypertension (PAH), asthma, interstitial lung disease (ILD), idiopathic pulmonary fibrosis, and sclerosing diseases (cirrhosis, atherosclerosis, SSc, chronic kidney disease, and so on), and as initially described in wound healing. Such cells have the ability to traffic into injury sites, exhibiting both inflammatory features of macrophages and tissue remodeling properties of fibroblasts5. Interestingly, some of the CPCs are also able to differentiate into endothelial cells playing a role in the vasculogenesis process5. In this review, we will summarize the existing evidence regarding the role of CPCs in SSc.
Since 1994, different subtypes of CPCs have been described as quantitatively or functionally altered in patients with SSc (Table 1)6–19. The different subtypes of CPCs described thus far in SSc arise from a pool of circulating monocyte precursors (CD14+ cells) and probably correspond to a different degree of differentiation from a single cell of origin. The pluripotent stem cells (PSCs) seem to correspond to a very early degree of differentiation. The monocyte-derived mesenchymal progenitors (MOMCs), also known as monocyte-derived mesenchymal progenitors, are multipotent cells with a spindle-shaped morphology and a unique phenotype (CD14+, CD45+, CD34+, and type I Col+) that might correspond to the PSCs described by Zhao et al.6, but with the ability to produce Col (a further degree of differentiation). MOMCs show mixed morphologic and phenotypic features of phagocytes, mesenchymal cells, and endothelial cells2,4,8. It has been demonstrated that circulating CD14+ monocytes with an activated phenotype (CD68+, CD204+, and Singlec-1+) are increased in patients with SSc when compared with normal subjects12–14,16. CD14+, CD34+, and Col I+ spindle-shaped cells (compatible with MOMCs) have been found in increased numbers in the lungs of SSc patients with ILD15,16. In 2004, Postlethwaite et al. reported an elevated number of spindle-shaped cells with a new phenotype (CD14+, CD45+, CD34−, and Col I+) in patients with SSc after culturing peripheral blood monocyte cells (PBMCs) with type I Col. They called these particular cells fibroblast-like cells (FLCs). They differ from the already-known PSCs and MOMCs by the absence of CD34 expression and from fibrocytes by the presence of CD14 and the absence of CD34 as surface markers11. They also suggested that the increased outgrowth of FLCs from patients with SSc may be a marker of diffuse disease and pulmonary fibrosis11.
Other subtypes of CPCs have been related to the vascular alterations seen in patients with SSc, as the circulating endothelial precursor cells (EPCs) that seem to contribute to the initial phase of SSc. In 2009, the European League Against Rheumatism (EULAR) Scleroderma Trials and Research group provided recommendations for standardization for future research in EPCs10. The consensus panel agreed to classify EPCs in two groups:
1. Early EPCs, characterized by the positive expression of CD14, CD45, the low expression of CD34, and the variable expression of VEGFR2 (+/−), have also been described as monocytic pro-angiogenic hematopoietic cells by Yamaguchi et al.2 and as circulating hemotopoietic progenitor cells (CD45+, CXCR4+, c-kit+, and CD117+) by Campioni et al.9. Early EPCs have the ability to differentiate into endothelial cells, fibroblasts, smooth muscle cells, and pericytes2. Elevated blood levels of early EPCs have been found in patients with SSc by different groups of researchers and such levels correlate directly with interstitial lung involvement2,9. In a pro-fibrotic environment—elevated levels of both endothelin-1 (ET-1) and transforming growth factor-beta (TGF-β)—early EPCs differentiate mainly into fibroblasts and promote fibrosis2.
2. Late EPCs are a population of bone marrow-derived cells that are characterized by the phenotype CD14−, CD34+, CD133+, and VEGFR2+, and that are able to differentiate into mature endothelial cells and participate in vasculogenesis. In patients affected by SSc, late EPCs are able to differentiate into myofibroblasts and play a role in the development of fibrosis20. The number of circulating late EPCs is inversely proportional to the SSc disease duration: in the early phase such cells are increased and at late stages they are decreased, as confirmed by different authors4,9,10,20. Lower levels of late EPCs particularly are found in patients with past or current digital ulcers and PAH20. Such cells not only decrease in a late phase of SSc but are also functionally impaired and resistant to in vitro maturation treatments, suggesting a defect in the vasculogenesis process (the failure of new blood vessel formation because of a failure in recruitment and in situ differentiation of late EPCs)4. A plausible explanation for the decrease of late EPCs during the late phase of SSc regards the recruitment into injured tissues of such cells, decreasing the circulating numbers20.
CPCs subtypes | Author/Date | Cellular markers | Alteration in SSc (increase/ decrease) | Differentiation capability |
---|---|---|---|---|
Pluripotent Stem Cells (PSC) | Zhao et al., 20036 | CD14+, CD45+, CD34+ | Increased | Macrophages, T-lymphocytes, epithelial, neuronal cells, hepatocytes and endothelial cells. Fibroblasts (unknown) |
Monocyte-derived multipotential cells (MOMCs) or monocyte-derived mesenchymal progenitors (MOMPs) | Kuwana et al., 2003, Seta et al., 2010, Yamaguchi et al., 20132,6–8 | CD14+, CD45+, CD34+, Col I+, CD11b+, CD68+, CD-105+, VEGFR1+ | Increased | Endothelial cells, fibroblasts, hematopoietic and monocyte lineage, phagocytes, mesenchymal cells |
Early endothelial progenitor cells (EPCs) or monocytic pro-angiogenic hematopoietic cells (PHC) or circulating hematopoietic cells | Kuwana et al., 2004, Campioni et al., 2008, Distler et al., 2009, Yamaguchi et al., 2013,2,4,9,10 | CD14+, CD45+, CD34low/-, VEGFR2+/-, CXCR4+, c-kit+, DC117+ | Increased and directly correlate with interstitial lung involvement | Smooth muscle cells, pericytes, endothelial cells, fibroblasts |
Late-EPCs: | Kuwana et al., 2004, Campioni et al., 2008, Distler et al., 20094,9,10 | CD14-, CD133+, VEGFR2+, CD144+ (VE- cadherin)+, CD146+ | Increase in early phase or with severe vascular involvement (PAH, SRC, Ray) and decrease in late phase or fibrosis. Not only quantitative alterations but also in SSc patients functional impairment (defective vasculogenesis) | Myofibroblasts and endothelial cells |
Fibroblasts like cells (FLC)/circulating collagen producing monocytes (CPM): | Postlethwaite et al., 2004, York et al., 2007, Higashi-Kuwata et al., 2010, Mathaiet al., 2010, Tourkina et al., 2011, Binai et al., 201210–16 | CD14+, CD45+, CD34+/-, Col I+ | Increased not only in circulation but also in lungs of SSc patients with interstitial lung disease. | Myofibroblasts and endothelial cells |
Fibrocytes: | Schmidt et al., 2003, Quanet al., 2004, Strieter et al., 20095,17–19 | CD14-, CD45+, CD34+, Col I+, CXCR4+ | Increased | Fibroblasts, myofibroblasts |
The importance of CPCs relies on the capacity of such cells to migrate into SSc injury tissues (mediated by CXCR4 /CXCL12 interaction), to differentiate into both endothelial cells and fibroblasts, to cause defective vasculogenesis or fibrosis (or both), and to have immunomodulatory effects19. The prevalence of hematopoietic markers expressed by CPCs that migrate from blood into injury sites in SSc differs and changes according to the degree of differentiation. CXCR4 is the most commonly expressed marker, followed by CD34 and CD45 at the end stage of differentiation15. Such difference also indicates a continuous process of cell differentiation that might relate to the SSc clinical phenotype (degree of fibrosis and vascular involvement).
In patients with SSc, the fraction of CD14+ monocytes in circulation is higher than the CD14− monocytes and a greater portion of circulating monocytes express Col I, suggesting that SSc monocyte preparations may contain a significant number of Col-producing cells that are partially differentiated into different subtypes of CPCs (MOMCs, FLCs, EPCs, and fibrocytes)14. Such circulating Col-producing cells have an increased migration capacity into injury sites because of the overexpression of CXCR4 and the deficiency in caveolin-1. CPCs that have finished their differentiation process generate fibrocytes that produce Col, extracellular matrix and cause fibrosis at injury sites (skin, lung, kidneys, and so on)15. Interestingly, it has been described that African-Americans may be predisposed to lung fibrosis and SSc because of low baseline caveolin-1 levels in their monocytes, potentially affecting signaling, migration, and fibrocyte differentiation21. The finding that CD14+/Col I+ monocytes are present in the lung tissue of patients with SSc-ILD and not in healthy donors supports this hypothesis15. It is interesting that, in a pro-fibrotic environment (elevated levels of ET-1 and TGF-β), early EPCs that normally give rise to endothelial cells can also differentiate into FLCs and promote fibrosis2. Fibrosis occurs after the activation of tissue-resident fibroblasts and their transdifferentiation into myofibroblasts, but is also due to differentiation of bone marrow-derived CPCs and transition of endothelial epithelial cells, pericytes, and adipocytes into activated mesenchymal cells1,22,23. Fibrocytes (CD14−, CD34+, CD45+, CXCR4+, CCR3, and Col I+), defined as FLCs that differentiate from a different pool of bone marrow-derived monocytic CD14+ progenitor cells, are involved in both ischemic and fibrotic processes in SSc8,19,22,23. It is worth noting that CD14+ circulating monocytes in the presence of T cells give rise to fibrocytes (CD14− cells)22. Fibrocytes cultured with TGF-β or ET-1 downregulate CD34 and upregulate alpha-smooth muscle actin (α-SMA) expression and differentiate into myofibroblasts17. Fibrocytes are considered to be mesenchymal cells that arise from a pool of circulating monocyte precursors24. The number of circulating fibrocytes in patients with idiopathic pulmonary fibrosis directly correlates with exacerbations of the disease, and patients with fibrocytes more than 5% of total circulating blood leukocytes had a worse prognosis than patients with levels under this cut-off19.
Both late EPCs and FLCs have been found to be significantly increased not only in blood of patients with SSc but also at injury sites (lungs with ILD-SSc)20. Late EPCs contribute to new vessel formation and vascular repair via secretion angiogenic factors under normal conditions, a mechanism that is disrupted in patients with SSc20. FLCs are key effectors of fibrosis11. The number of circulating late EPCs is inversely proportional to the disease duration10,21. Lower levels of late EPCs are found in the late phase of SSc, in patients with diffuse fibrosis, and particularly in patients with past or current digital ulcers and PAH21. Late EPCs not only decrease in a late phase of SSc but also are functionally impaired and resistant to in vitro maturation treatment, suggesting a defective vasculogenesis (the failure in new blood vessel formation because of a failure in recruitment and in situ differentiation of late EPCs)4. The total number of circulating CD45+/pro-Col-1α cells (that might correspond to FLCs and fibrocytes) has been reported to be 0.34 ± 0.12 × 106 cells/ml, and the percentage of such cells between PBMCs to be between 1.34 ± 0.25 (ILD-SSc) and 2.5% (SSc)10,15. CD14+, CD11b+, and Col I+ cells have been reported to be 1.5% of PBMCs in patients with SSc, versus 0.95% in healthy donors (P <0.05)14. EPC frequency in peripheral blood is quite low: 0.01% to 0.0001% of PBMCs20.
In the past 15 years, a pool of circulating monocyte precursors has been found to be altered both quantitatively and qualitatively in different sclerosing conditions, including SSc. Such alterations have been partially related to the subtype of SSc (diffuse versus limited forms), the duration of the SSc, and the prominent clinical manifestations (vascular involvement versus fibrosis). The exact role of each subtype of CPCs needs to be further defined. A deeper understanding of the role of each subtype of CPCs in the development of the disease will help us to better classify patients in order to offer them personalized therapeutic approaches in the future25–28. It might also open a door regarding the modulation/regulation of the differentiation of CPCs in order to avoid a pro-fibrotic phenotype and to reverse the altered vascular phenotype of such cells. Autologous hematopoietic stem cell transplantation (HSTC) seems to reintroduce immunological tolerance in patients with SSc, and we hypothesize that such tolerance might be due to the regulation of CPC differentiation. It has been demonstrated that after HSTC there is an improvement of vasculopathy, modified Rodnan skin score, and lung function in patients with SSc26.
This review had the intention to summarize the available data regarding CPCs in SSc; considering the fact that several studies have been conducted with single CPC subsets, we herein intended to describe the whole spectrum of CPCs in SSc described thus far and their roles in the pathogenesis of SSc. During this review process, we faced several difficulties: the same cell has been studied by different research groups and named differently, several subsets of CPCs that might correspond to the same cell have been described, there are no studies available that compare different subsets of CPCs in the same patients, and there is no direct correlation in the literature between different CPC subsets and clinical manifestations of SSc.
The authors declare that they have no competing interests and received no funding support.
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Competing Interests: No competing interests were disclosed.
Competing Interests: No competing interests were disclosed.
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