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Fibrosis in connective tissue disease: the role of the myofibroblast and fibroblast-epithelial cell interactions

Abstract

Fibrosis, characterized by excessive extracellular matrix accumulation, is a common feature of many connective tissue diseases, notably scleroderma (systemic sclerosis). Experimental studies suggest that a complex network of intercellular interactions involving endothelial cells, epithelial cells, fibroblasts and immune cells, using an array of molecular mediators, drives the pathogenic events that lead to fibrosis. Transforming growth factor-β and endothelin-1, which are part of a cytokine hierarchy with connective tissue growth factor, are key mediators of fibrogenesis and are primarily responsible for the differentiation of fibroblasts toward a myofibroblast phenotype. The tight skin mouse (Tsk-1) model of cutaneous fibrosis suggests that numerous other genes may also be important.

Introduction

Fibrosis, the result of excess synthesis and deposition of collagen, is a feature of many connective tissue diseases (CTDs) and is the hallmark of scleroderma (systemic sclerosis [SSc]). In this rare, progressive and life-threatening autoimmune disease, fibrosis affects not only the skin but also internal organs such as lungs and kidneys, leading to organ dysfunction and failure [1]. In SSc, fibrosis is the final stage in a series of pathological events that begins with vascular dysfunction, manifesting as altered vascular tone, endothelial activation and oxidative stress, followed by immunological activation and leucocyte-mediated extra-vascular inflammation [2]. A complex network of intercellular interactions that involves a diverse range of molecules, including growth factors, cytokines, chemokines and endothelin, is believed to drive the pathological events that ultimately result in uncontrolled connective tissue fibrosis. In this review, which describes results from in vitro systems and animal models of cutaneous and visceral fibrosis, we explore cellular and molecular events associated with the initiation and maintenance of fibrosis in CTDs.

Initiators of fibrosis in connective tissue diseases

Fibrosis arises from excessive collagen synthesis by fibroblasts [3]. Of the many potential mediators of fibrosis in CTDs, three molecular entities appear to be of particular importance: transforming growth factor (TGF)-β, endothelin (ET)-1 and connective tissue growth factor (CTGF/CCN2). In connective tissues, endothelin participates in stimulating the formation of myofibroblasts (the myofibroblast is a specialized type of fibroblast that is a normal cellular constituent of healing tissues) and increases levels of CTGF and matrix proteins [4] (Figure 1). It also interacts with other profibrotic cytokines including TGF-β, which is a key component in the induction and progression of fibrosis [5] and is a potent stimulator of CTGF. Indeed, CTGF is a common target for both TGF-β and ET-1.

Figure 1
figure 1

Effects of endothelin include stimulating myofibroblast formation, leading to a concomitant increase in collagen production and fibrosis. Binding of endothelin (ET)-1 to ET-1 receptor subtype A (ETA) and ETB has different effects in different cell types. The binding of ET-1 to smooth muscle cell ETA and ETB receptors leads to vasoconstriction and mitogenesis, and activation of ETB receptors on endothelial cells promotes the release of nitric oxide and prostacyclin, and plays a minor role in endothelial dependent vasodilatation. In fibroblasts ET-1 results in the increased production of collagen and leads to fibrosis. Reproduced with permission from Galiè et al. Cardiovascular Research © Elsevier 2004 [4].

Data from experimental animal studies have shed light on the relationship between these three key mediators of fibrosis and pointed to the existence of a cytokine hierarchy. This hierarchy involves induction of ET-1 by TGF-β, induction of CTGF by both ET-1 and TGF-β, and potential mediation of the effects of TGF-β and ET-1 on extracellular matrix (ECM) by CTGF [6] (Figure 2).

Figure 2
figure 2

Schematic diagram of the hierarchy and interplay between ET-1, TGF-β and CTGF. CTGF, connective tissue growth factor; ET, endothelin; NF-κB, nuclear factor-κB; TGF, transforming growth factor. Reproduced from [6] by permission of the publisher (Taylor & Francis Ltd, http://www.informaworld.com).

Evidence that TGF-β increases ET-1 mRNA expression has come from several studies including an RNase protection assay, in which bovine endothelial cells were incubated in the presence or absence TGF-β and ET-1 mRNA expression was measured over time. In cells exposed to TGF-β there was a marked, dose-dependent increase in ET-1 mRNA expression, peaking at 4 hours after exposure [7]. Moreover, recent studies have also shown that TGF-β can induce ET-1 production by pulmonary fibroblasts via a Smad-independent signalling pathway involving c-Jun amino-terminal kinase and the transcription factor activator protein-1. This pathway was found to be constitutively activated in injured cells [8]. Results from in vivo studies suggest that the effect of TGF-β on ET-1 production occurs primarily in response to cell injury. In injured cells taken from bile duct ligated animals and exposed to TGF-β, there was a notable increase in ET-1 production in the injured stellate cells but not in injured endothelial cells (Figure 3a) [9].

Figure 3
figure 3

TGF-β plays a pivotal role in the induction of ET-1. (a) Stellate (top panel) and sinusoidal endothelial (bottom panel) cells were isolated from normal rat livers or those injured by bile duct ligation (BDL). Transforming growth factor (TGF)-β1 was applied at the indicated concentration in serum-free medium for 24 hours. Endothelin (ET)-1 was measured by radioimmunoassay. *P < 0.05 versus no TGF-β1 (n = 5). (b) Stellate and endothelial cells were isolated from normal rat livers, and those after BDL and those after soluble TGF-β1 receptor (STR) antagonist during BDL (BDL + STR). *P < 0.05 versus normal and *P < 0.05 versus BDL (n = 8). Reproduced with permission from Shao et al. Mol Biol Cell 2003 © The American Society for Cell Biology [9].

These findings suggest that induction of ET-1 by TGF-β requires an activation step, perhaps dependent on inflammatory status or other cellular signals. Interestingly, blocking the effects of TGF-β with a soluble TGF-β receptor (STR) antagonist leads to inhibition of ET-1 production by both injured stellate and normal endothelial cells in vivo (Figure 3b) [9]. The concept of a cytokine hierarchy, in which ET-1 is induced by TGF-β, is also supported by data from experimental studies that showed that ET-1 does not increase TGF-β gene expression or increase TGF-β protein production in vascular smooth muscle cells [10].

As mentioned above, CTGF is a common target for both TGF-β and ET-1. Recent studies showed that ET-1 regulates CTGF independently of TGF-β and that, in turn, CTGF mediates ET-1 induced ECM accumulation. In an experimental study in which vascular smooth muscle cells were treated with 8 to 10 mol/l ET-1, there was a marked increase in type 1 collagen expression compared with control cells. However, when the treated cells were exposed to a CTGF antisense oligonucleotide that blocks the action of CTGF, type 1 collagen expression was markedly suppressed. Similar results were reported for levels of fibronectin, the production of which is also influenced by both ET-1 and CTGF [10].

From the available evidence it seems clear that TGF-β can induce ET-1, although its induction is variable and may be dependent on other signals such as inflammation. Both TGF-β and ET-1 can induce CTGF, with ET-1 acting independently of TGF-β. CTGF, a cytokine that stimulates fibroblast growth and upregulation of collagen and fibronectin in vitro [11], is a difficult molecule to study experimentally, but there is evidence to suggest it mediates certain effects of TGF-β and ET-1 on ECM production [12, 13]. More complex interactions between TGF-β and ET-1 are likely to depend on cross-regulation of receptors and activators.

Models of the profibrotic microenvironment

Models of organ fibrosis

The in vivo effects of ET-1 on cardiac, renal and pulmonary tissue have been studied in a number of animal models of fibrosis. Experimental work on salt-induced hypertension in rodents (deoxycorticosterone acetate-salt hypertensive rats), for example, found a marked increase in fibrosis in the myocardium of affected animals compared with controls. However, when animals were given treatment with a selective endothelin-1 receptor subtype A antagonist, effective endothelin blockade resulted in no collagen deposition in cardiac tissue [14]. Earlier work on ET-1 transgenic mice, created by the transfer of the human ET-1 gene locus into the germline of mice, resulted in a pathological phenotype characterized by glomerulosclerosis, interstitial fibrosis and renal cysts without hypertension. In this model, pronounced renal fibrosis was associated with an age-dependent decrease in glomerular filtration that culminated in fatal kidney disease [15]. The severe ET-1-induced renal disease seen in this model of fibrosis is consistent with evidence from patients that an activated renal endothelin system is associated with glomerular and interstitial injury [15]. Other work in a transgenic mouse model has shown ET-1 over-expression to lead to the recruitment of inflammatory cells in respiratory tissues and subsequent development of progressive pulmonary fibrosis [16].

Models of skin fibrosis

More recently, a tight-skin mouse (Tsk-1) model has been used to enhance understanding of the underlying pathology of skin fibrosis in SSc. Tsk-1 mice develop tightening of the skin to the underlying tissues, due to a mutation in the gene encoding fibrillin 1. Fibrillin is a large ECM structural protein and the major component of microfibrils, found with or without associated elastin [17]. The primary role of fibrillin is to form the scaffolding for elastic fibres. In Tsk-1 mice, fibrillin appears to alter fibrillin matrix structure, with a notable. increase in fibrillin in the superficial fascia of these animals. Tsk-1 mice exhibit increased elastogenesis in the superficial fascia (gain-of-function) and a loss of the dense elastic fibre band normally found at the interface between the intradermal muscle and deep connective tissue (loss-of-function).

To test the hypothesis that Tsk fibrillin causes skin tethering and fibrosis by altering interactions between fibrillin-1 and other proteins, we conducted a series of experiments focusing in particular on microfibril-associated glycoprotein (MAGP)-1 and MAGP-2, fibulins, versican, decorin (small leucine-rich repeat proteoglycans) and latent TGF-β binding proteins, all of which are proteins known to interact or co-localize with fibrillin. Our results showed that MAGP-2 is upregulated in Tsk-1 skin and in cells expressing Tsk fibrillin, with the greatest increase seen in the hypodermis/superficial fascia of Tsk skin (Figure 4a) [18]. Tsk-1 mice also lose fibulin-5 expression at the interface between muscle and superficial fascia; fibulin-5 is important in regulating elastogenesis (Figure 4b). Fibulin-2, a molecule related to fibulin-5, was found to bind to both fibrillin and tropoelastin, and to be present in increased amounts in the superficial fascia (Figure 4c) [19]. Overall, these findings suggest that Tsk fibrillin alters the binding of fibrillin to other matrix proteins and that this altered binding appears to stimulate increased MAGP-2 and fibulin-2 matrix. Increased MAGP-2 or fibulin-2 may in turn, directly or indirectly, stimulate collagen and elastic fibre deposition leading to skin tethering. However, MAGP-2 and fibulin-2 mRNA is also upregulated in Tsk skin, raising the question of how matrix regulates matrix at the mRNA level. There is evidence that Tsk fibrillin-1 alters TGF-β activity in Tsk skin as well as altering the binding of fibrillin to latent TGF-β binding proteins. Interestingly, TGF-β deleted heterozygotes exhibit less fibrosis than do littermate Tsk mice. Furthermore, studies using a hammerhead ribozyme to specifically silence the mutant fibrillin in skin fibroblasts derived from Tsk dermal biopsies revealed a striking decrease in the expression of TGF-β dependent genes, including that encoding CTGF, in Tsk skin cells where the mutant fibrillin-1 had been deleted [20]. Ongoing studies in which global changes in gene expression in Tsk-1 mice are being assessed show that a variety of other proteins, in addition to those mentioned above, may be of importance in this model of skin fibrosis.

Figure 4
figure 4

The Tsk-1 model of cutaneous fibrosis exhibits increased MAGP-2, loss of fibulin-5 and increased fibulin-2 matrix. (a) Tissue sections from tight skin (Tsk) mice (panels 1 and 3) and control (panels 2 and 4) mice were immunostained for microfibril-associated glycoprotein (MAGP)-2. MAGP-2 is indicated by arrowheads. MAGP-2 was detected at higher levels in all dermal layers (panel 1 versus panel 2). Hypodermis (H) is shown (panel 3 versus panel 4). PC, panniculus carnosus; D, dermis. (b) Control (left panel) and Tsk (right panel) mice skin sections from 6-week-old mice were stained in parallel for fibulin-5 by immunohistochemistry. Positive staining is indicated by arrows at the muscle-connective tissue (M-CT) interface. Hypodermal connective tissue (HD) and hypodermal muscle (M) are indicated. Original magnification: 400×. (c) Control (panels 1 and 3) and Tsk (panels 2 and 4) mouse skin sections from 6-week-old mice were stained in parallel for fibulin-2 by immunohistochemistry. Positive staining is indicated by arrows (M-CT interface) and in panel 4 around hair follicles (F). (a) Reproduced with permission from Lemaire et al. Arthritis Rheum 2004 © John Wiley & Sons/American College of Rheumatology [18]. (b) and (c) Reproduced with permission from [19].

The Tsk-1 mouse clearly provides a good model for evaluating how matrix regulates its own composition. Although there is evidence from this model to suggest that Tsk fibrillin regulates gene expression through altered interactions with other matrix proteins, the identities of these mediators remain to be elucidated.

A further model is the bleomycin-induced model of dermal fibrosis, in which bleomycin has been found to increase expression of ECM proteins, potentially via the mediation of TGF-β and CTGF/CCN2 [21]. This model has been widely used to evaluate potential antifibrotic drugs. For example, using this model, the protein kinase inhibitor imatinib mesylate (a selective, dual inhibitor of TGF-β and platelet-derived growth factor) was shown to have potent antifibrotic effects [22], although perhaps not in later stages of fibrosis [23]. Peptide inhibitors of TGF-β1 applied topically are also showing some promise [24]. Other agents targeting other components of the fibrotic process have similarly demonstrated attenuation of bleomycin-induced skin sclerosis in mice [25].

Fibroblast to myofibroblast differentiation

In comparison with normal skin, biopsies of skin from SSc patients show a significant increase in myofibroblasts, particularly in the deep dermis. These cells, which are characterized by the presence of stress fibres containing α-smooth muscle actin (SMA), play a pivotal role in ECM deposition and wound contraction during the normal wound healing process [26]. A strong correlation has also been observed between myofibroblast intensity in the skin of SSc patients and the Rodnan skin score, which reflects disease throughout the body. Thus, cutaneous changes in SSc patients may reflect what is happening systemically, even though the disease may not be clinically evident in large parts of the body.

There has been much speculation on the origin of activated fibroblasts in the skin of SSc patients and what influences their differentiation toward a myofibroblast phenotype. There is evidence that activated fibroblasts may arise from local conversion of dermal fibroblasts by soluble factors, a finding that is consistent with our CTGF staining data. It is also possible that activated fibroblasts are recruited from circulating or resting mesenchymal precursor cells in the tissue, or induced by cell-cell contacts, cytokines or other chemokines, or selected as an active subpopulation by one or other mechanism. Alternatively, they may be generated by clonal selection. As is discussed in greater detail below, in wound healing the differentiation of fibroblasts toward a myofibroblast phenotype is governed by several factors, including the proximity of fibroblasts to keratinocytes, the presence of endogenous TGF-β, and direct cell-cell contact between fibroblasts and keratinocytes to allow initial TGF-β activation.

Orchestrating fibrosis: interactions between endothelial and other cells

In the initial stages of any fibrotic condition, and certainly in SSc, there appears to be significant crosstalk between different cell types, including endothelial and mesenchymal cells. In vitro studies carried out during different stages of wound healing have shed light on the general activation mechanisms that are involved in fibrosis and on the intercellular crosstalk that influences cell behaviour. In the very early stages of wound healing, fibroblast activation is induced by epithelial cells in response to injury. In the skin, regulation during this very early phase of wound healing is due to direct contact between keratinocytes and the underlying fibroblasts, or to the release of cytokines from one cell to another, or, indeed, a combination of both. Interaction of fibroblasts and keratinocytes has also been found to modulate levels of two key enzymes that are involved in wound healing and remodelling: matrix metalloproteinase-2 and -9 [27]. This interaction may be critical for optimal healing quality at a later stage in the wound healing process.

There is, in addition, close interplay and crosstalk between the cells that control activation and downregulation of both cell types. Thus, fibroblasts are known to release keratinocyte growth factor, which induces keratinocytes to proliferate. Importantly, it also acts as a switch, turning on the production of other growth factors such as vascular endothelial growth factor, which then signal to endothelial cells [28, 29]. In a recent series of experiments that included the incubation of normal keratinocytes with fibroblasts in vitro, it was shown that keratinocytes, either directly or indirectly, induced α-SMA expression in fibroblasts [30]. Subsequently, it was discovered that induction of α-SMA was associated with induction of collagen RNA; myofibroblasts induced by keratinocytes were found to produce large amounts of collagen. For induction to take place, however, the keratinocytes and fibroblasts had to be in very close contact. The genes induced as a result of the interaction between keratinocytes and fibroblasts included ECM genes such as collagens, tenascin C, decorin, transglutaminase and lysyl-hydroxylase; cytoskeleton genes such as α-SMA; and cell-cell signalling genes such as monocyte chemoattractant protein 1, CTGF, activin A, ET-1 and angiopoietin (Table 1). Angiopoietin-related growth factor can potently promote adhesion, spreading and migration of keratinocytes, fibroblasts and endothelial cells, with the adhesion and migration events likely to be mediated by αv containing integrins [31]. It has been suggested that α2β1 integrins are responsible for cell attachment, spreading and migration. However, a recent study [32] showed that although the α2β1 integrin is absolutely required for keratinocyte adhesion to collagens, for fibroblasts other collagen-binding integrins may partially make up for the lack of α2β1 in simple adhesion to collagen monomers.

Table 1 Selected genes induced by keratinocyte-fibroblast interactions

As later experiments have demonstrated, TGF-β is responsible, at least in part, for the induction of α-SMA in fibroblasts. Other important molecules involved in the regulation of myofibroblast differentiation included the cytokine granulocyte macrophage-colony stimulating factor, which inhibited myofibroblast differentiation via induction of the nuclear factor-κB pathway [33], and ET-1. In common with TGF-β, ET-1 was also shown to induce α-SMA. However, it appears to act synergistically with TGF-β to induce the myofibroblast phenotype rather than acting alone (Figure 5). Although there is evidence that additional factors are involved, the data suggest that ET-1 and TGF-β are responsible for most of the induction of α-SMA-positive cells. In cell culture experiments in which an anti-TGF-β antibody and inhibitor of ET-1 were added to the co-culture, there was significant downregulation of α-SMA activity. Moreover, a recent study has shown TGF-β preferentially induces ET-1 expression [34].

Figure 5
figure 5

Synergistic effects of TGF-β and ET-1 in fibroblast activation. Signal intensities from Western blots of fibroblasts isolated from co-cultures of HaCaT keratinocytes and fibroblasts after 7 days in Dulbecco's modified Eagle medium/0.5% foetal calf serum. α-Smooth muscle actin (α-SMA) expression increased in co-cultures (see lane 1) as compared with fibroblasts alone (compare dotted line). Addition of an anti-transforming growth factor (TGF)-β antibody or the endothelin (ET)-1 inhibitor PD 156252 resulted in reduced α-SMA expression. Addition of anti-TGF-β and PD 156252 blocked α-SMA expression to almost basal levels [33].

Results from these experimental studies indicate that highly complex epithelial-mesenchymal crosstalk is involved in controlling the extent to which fibroblastic cells are induced in the underlying mesenchyma and in their subsequent differentiation to myofibroblasts.

Conclusion

As the experimental studies described here illustrate, myofibroblasts play a central role in mediating tissue fibrosis, which is the major clinical manifestation of CTDs such as SSc. TGF-β, ET-1, and CTGF are among the most important molecular mediators of fibrogenesis, with TGF-β and ET-1 intimately involved in the differentiation of fibroblasts toward a myofibroblast phenotype, characterized by the presence of stress fibres containing α-SMA. Cell culture experiments show that direct cell-cell contact between fibroblasts and keratinocytes is important for TGF-β activation and initiation of myofibroblast formation. Data from animal models of cardiac, renal, pulmonary and cutaneous fibrosis confirm the importance of these profibrotic mediators in fibrogenesis, while also highlighting other molecular entities that may be important as well. The Tsk-1 model of cutaneous fibrosis, for example, illustrates the importance of Tsk fibrillin and how it regulates gene expression through altered interactions with other matrix proteins.

Abbreviations

CTD:

connective tissue disease

CTGF:

connective tissue growth factor

ECM:

extracellular matrix

ET:

endothelin

MAGP:

microfibril-associated glycoprotein

SMA:

smooth muscle actin

SSc:

systemic sclerosis

TGF:

transforming growth factor

Tsk:

tight skin.

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Acknowledgements

The authors would like to acknowledge medical writing support funded by an educational grant from Actelion Pharmaceuticals Ltd.

This article is part of Arthritis Research & Therapy Volume 9 Supplement 2: Advances in systemic sclerosis and related fibrotic and vascular conditions, and is based on presentations made at a symposium entitled Advances in systemic sclerosis and connective tissue disease, sponsored by Actelion Pharmaceuticals Ltd, held in Athens, Greece in April 2006. The full contents of the supplement are available online at http://arthritis-research.com/supplements/9/S2. This supplement has been supported by an educational grant from Actelion Pharmaceuticals Ltd.

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Correspondence to Thomas Krieg.

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TK, DA and RL have received grant support and consulting fees from Actelion Pharmaceuticals Ltd, the manufacturer of bosentan.

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Krieg, T., Abraham, D. & Lafyatis, R. Fibrosis in connective tissue disease: the role of the myofibroblast and fibroblast-epithelial cell interactions. Arthritis Res Ther 9 (Suppl 2), S4 (2007). https://0-doi-org.brum.beds.ac.uk/10.1186/ar2188

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