Interactions between Skeletal Muscle Myoblasts and their Extracellular Matrix Revealed by a Serum Free Culture System

Decellularisation of skeletal muscle provides a system to study the interactions of myoblasts with muscle extracellular matrix (ECM). This study describes the efficient decellularisation of quadriceps muscle with the retention of matrix components and the use of this matrix for myoblast proliferation and differentiation under serum free culture conditions. Three decellularisation approaches were examined; the most effective was phospholipase A2 treatment, which removed cellular material while maximizing the retention of ECM components. Decellularised muscle matrices were then solubilized and used as substrates for C2C12 mouse myoblast serum free cultures. The muscle matrix supported myoblast proliferation and differentiation equally as well as collagen and fibronectin. Immunofluorescence analyses revealed that myoblasts seeded on muscle matrix and fibronectin differentiated to form long, well-aligned myotubes, while myoblasts seeded on collagen were less organized. qPCR analyses showed a time dependent increase in genes involved in skeletal muscle differentiation and suggested that muscle-derived matrix may stimulate an increased rate of differentiation compared to collagen and fibronectin. Decellularized whole muscle three-dimensional scaffolds also supported cell adhesion and spreading, with myoblasts aligning along specific tracts of matrix proteins within the scaffolds. Thus, under serum free conditions, intact acellular muscle matrices provided cues to direct myoblast adhesion and migration. In addition, myoblasts were shown to rapidly secrete and organise their own matrix glycoproteins to create a localized ECM microenvironment. This serum free culture system has revealed that the correct muscle ECM facilitates more rapid cell organisation and differentiation than single matrix glycoprotein substrates.     

Osteopontin and skeletal muscle myoblasts: association with muscle regeneration and regulation of myoblast function in vitro

Osteopontin is a secreted glycoprotein expressed by many cell types including osteoblasts and lymphocytes; it is a constituent of the extracellular matrix (ECM) in bone, and a mitogen for lymphocytes. To investigate the role of osteopontin in muscle repair and development, expression of osteopontin by muscle cells in vivo and in vitro, and the effects of osteopontin on myoblast function in vitro were investigated. Osteopontin staining was weak in sections of muscle from normal mice, but associated with desmin-positive cells in areas of regeneration in muscles from mdx mice. In immunocytochemical, PCR and ELISA studies, cultured myoblasts were found to express osteopontin and secrete it into medium. Treatment of myoblast cultures with fibroblast growth factor-2, transforming growth factor beta1, interleukin-1beta or thrombin significantly increased osteopontin expression. Osteopontin-coated substrata promoted adhesion and fusion, but not proliferation or migration, of myoblasts. The effect of osteopontin on myoblast adhesion was RGD-dependent. In solution, osteopontin significantly increased proliferation and decreased fusion and migration of myoblasts. These results suggest that myoblasts are an important source of osteopontin in damaged muscle and that osteopontin released by myoblasts may assist in controlling both the myogenic and inflammatory processes during the early stages of muscle regeneration.     

Induction of migration of periodontal ligament cells by selective regulation of integrin subunits

The recruitment of tissue‐resident stem cells is important for wound regeneration. Periodontal ligament cells (PDL cells) are heterogeneous cell populations with stemness features that migrate into wound sites to regenerate periodontal fibres and neighbouring hard tissues. Cell migration is regulated by the local microenvironment, coordinated by growth factors and the extracellular matrix (ECM). Integrin‐mediated cell adhesion to the ECM provides essential signals for migration. We hypothesized that PDL cell migration could be enhanced by selective expression of integrins. The migration of primary cultured PDL cells was induced by platelet‐derived growth factor‐BB (PDGF‐BB). The effects of blocking specific integrins on migration and ECM adhesion were investigated based on the integrin expression profiles observed during migration. Up‐regulation of integrins α3, α5, and fibronectin was identified at distinct localizations in migrating PDL cells. Treatment with anti‐integrin α5 antibodies inhibited PDL cell migration. Treatment with anti‐integrin α3, α3‐blocking peptide, and α3 siRNA significantly enhanced cell migration, comparable to treatment with PDGF‐BB. Furthermore, integrin α3 inhibition preferentially enhanced adhesion to fibronectin via integrin α5. These findings indicate that PDL cell migration is reciprocally regulated by integrin α3‐mediated inhibition and α5‐mediated promotion. Thus, targeting integrin expression is a possible therapeutic strategy for periodontal regeneration.     

Exercise builds the scaffold of life: muscle extracellular matrix biomarker responses to physical activity,inactivity, and aging

Skeletal muscle extracellular matrix (ECM) is critical for muscle force production and the regulation of important physiological processes during growth, regeneration, and remodelling. ECM remodelling is a tightly orchestrated process, sensitive to multi-directional tensile and compressive stresses and damaging stimuli, and its assessment can convey important information on rehabilitation effectiveness, injury, and disease. Despite its profound importance, ECM biomarkers are underused in studies examining the effects of exercise, disuse, or aging on muscle function, growth, and structure. This review examines patterns of short- and long-term changes in the synthesis and concentrations of ECM markers in biofluids and tissues, which may be useful for describing the time course of ECM remodelling following physical activity and disuse. Forces imposed on the ECM during physical activity critically affect cell signalling while disuse causes non-optimal adaptations, including connective tissue proliferation. The goal of this review is to inform researchers, and rehabilitation, medical, and exercise practitioners better about the role of ECM biomarkers in research and clinical environments to accelerate the development of targeted physical activity treatments, improve ECM status assessment, and enhance function in aging, injury, and disease.     

Dermatan sulfate exerts an enhanced growth factor response on skeletal muscle satellite cell proliferation and migration

Skeletal muscle regeneration is a complex process in which many agents are involved. When skeletal muscle suffers an injury, quiescent resident myoblasts called satellite cells are activated to proliferate, migrate, and finally differentiate. This whole process occurs in the presence of growth factors, the extracellular matrix (ECM), and infiltrating macrophages. We have shown previously that different proteoglycans, either present at the plasma membrane or the ECM, are involved in the differentiation process by regulating growth factor activity. In this article, we evaluated the role of glycosaminoglycans (GAGs) in myoblast proliferation and migration, using C2C12, a satellite cell-derived cell line. A synergic stimulatory effect on myoblast proliferation was observed with hepatocyte growth factor (HGF) and fibroblast growth factor type 2 (FGF-2), which was dependent on cell sulfation. The GAG dermatan sulfate (DS) enhanced HGF/FGF-2-dependent proliferation at 1-10 ng/ml. However, decorin, a proteoglycan containing DS, was unable to reproduce this enhanced proliferative effect. On the other hand, HGF strongly increased myoblast migration. The HGF-dependent migratory process required the presence of sulfated proteoglycans/GAGs present on the myoblast surface, as inhibition of both cell sulfation, and heparitinase (Hase) and chondroitinase ABC (Ch(abc)) treatment of myoblasts, resulted in a very strong inhibition of cell migration. Among the GAGs analyzed, DS most increased HGF-dependent myoblast migration. Taken together, these findings showed that DS is an enhancer of growth factor-dependent proliferation and migration, two critical processes involved in skeletal muscle formation.     

Role of matrix metalloproteinases in skeletal muscle: Migration,differentiation, regeneration and fibrosis

Matrix metalloproteases (MMPs) are key regulatory molecules in the formation, remodeling and degradation of extracellular matrix (ECM) components in both physiological and pathological processes in many tissues. In skeletal muscle, MMPs play an important role in the homeostasis and maintenance of myofiber functional integrity by breaking down ECM and regulating skeletal muscle cell migration, differentiation and regeneration. Skeletal muscle satellite cells, a group of quiescent stem cells located between the basement membrane and the plasmalemma of myofibers, are responsible for lifelong maintenance and repairing, which can be activated and as a result migrate underneath the basement membrane to promote regeneration at the injured site. MMPs are able to degrade ECM components, thereby facilitating satellite cell migration and differentiation. This current review will focus on the critical roles of MMPs in skeletal muscle injury and repair, which include satellite cell activation with migration and differentiation. The effect of MMPs on muscle regeneration and fibrous scar tissue formation, as well as therapeutic insights for the future will be explored.Key words: matrix metalloproteinases, skeletal muscle satellite cells, migration, differentiation, regeneration, fibrosis     

A dynamic spatiotemporal extracellular matrix facilitates epicardial-mediated vertebrate heart regeneration

Unlike humans, certain adult vertebrates such as newts and zebrafish possess extraordinary abilities to functionally regenerate lost appendages and injured organs, including cardiac muscle. Here, we present new evidence that a remodeled extracellular matrix (ECM) directs cell activities essential for cardiac muscle regeneration. Comprehensive mining of DNA microarrays and Gene Ontology term enrichment analyses for regenerating newt and zebrafish hearts revealed that distinct ECM components and ECM-modifying proteases are among the most significantly enriched genes in response to local injury. In contrast, data analyses for mammalian cardiac injury models indicated that inflammation and metabolic processes are the most significantly activated gene groups. In the regenerating newt heart, we show dynamic spatial and temporal changes in tenascin-C, hyaluronic acid, and fibronectin ECM distribution as early as 3 days postamputation. Linked to distinct matrix remodeling, we demonstrate a myocardium-wide proliferative response and radial migration of progenitor cells. In particular, we report dramatic upregulation of a regeneration-specific matrix in the epicardium that precedes the accumulation and migration of progenitor cells. For the first time, we show that the regenerative ECM component tenascin-C significantly increases newt cardiomyocyte cell cycle reentry in vitro. Thus, the engineering of nature-tested extracellular matrices may provide new strategic opportunities for the enhancement of regenerative responses in mammals.     

Role of matrix metalloproteinases in skeletal muscle

Matrix metalloproteases (MMPs) are key regulatory molecules in the formation, remodeling, and degradation of extracellular matrix (ECM) components in both physiological and pathological processes in many tissues. In skeletal muscle, MMPs play an important role in the homeostasis and maintenance of myofiber functional integrity by breaking down ECM and regulating skeletal muscle cell migration, differentiation and regeneration. Skeletal muscle satellite cells, a group of quiescent stem cells located between the basement membrane and the plasmalemma of myofibers, are responsible for lifelong maintenance and repairing, which can be activated and as a result migrate underneath the basement membrane to promote regeneration at the injured site. MMPs are able to degrade ECM components, thereby facilitating satellite cell migration and differentiation. This current review will focus on the critical roles of MMPs in skeletal muscle injury and repair, which include satellite cell activation with migration and differentiation. The effect of MMPs on muscle regeneration and fibrous scar tissue formation, as well as therapeutic insights for the future will be explored.     

Exosomes from hypoxic endothelial cells have increased collagen crosslinking activity through up‐regulation of lysyl oxidase‐like 2

Exosomes are important mediators of intercellular communication. Additionally, they contain a variety of components capable of interacting with the extracellular matrix (ECM), including integrins, matrix metalloproteinases and members of the immunoglobin superfamily. Despite these observations, research on exosome‐ECM interactions is limited. Here, we investigate whether the exosome‐associated lysyl oxidase family member lysyl oxidase‐like 2 (LOXL2) is involved in ECM remodelling. We found that LOXL2 is present on the exterior of endothelial cell (EC)‐derived exosomes, placing it in direct vicinity of the ECM. It is up‐regulated twofold in EC‐derived exosomes cultured under hypoxic conditions. Intact exosomes from hypoxic EC and LOXL2 overexpressing EC show increased activity in a fluorometric lysyl oxidase enzymatic activity assay as well as in a collagen gel contraction assay. Concordantly, knockdown of LOXL2 in exosome‐producing EC in both normal and hypoxic conditions reduces activity of exosomes in both assays. Our findings show for the first time that ECM crosslinking by EC‐derived exosomes is mediated by LOXL2 under the regulation of hypoxia, and implicate a role for exosomes in hypoxia‐regulated focal ECM remodelling, a key process in both fibrosis and wound healing.     

Optimization of the scratch assay for in vitro skeletal muscle wound healing analysis

Myoblast migration is essential for muscle development, regeneration, and repair. Various assays are available for the study of migration; however, many are not suitable for the analysis of myoblast migration during skeletal muscle wound repair. Furthermore, versatility (e.g., to investigate the effect of the extracellular matrix on cell movement) is limited within these methods. Here we report the optimization of the scratch assay specifically for two-dimensional myoblast migration and discuss the advantages of this assay in comparison with other commercially available methods.     

ECM‐dependent mRNA expression profiles and phosphorylation patterns of p130Cas,FAK, ERK and p38 MAPK of osteoblast‐like cells

Osteoblast cells synthesize collagen‐rich ECM (extracellular matrix) in response to various environmental cues, but little is known about ECM‐dependent variations in phosphorylation patterns. Using MC3T3 E1 osteoblast‐like cells and mouse whole‐genome microarrays, we investigated molecular signalling affected by collagen‐based ECMs. A genome‐wide expression analysis revealed that cells grown in the 3D collagen matrix partially suppressed the genes associated with cell adhesion and cell cycling. Western analysis demonstrated that the expression of the active (phosphorylated) form of p130Cas, FAK (focal adhesion kinase) and ERK1/2 (extracellular‐signal‐regulated protein kinase 1/2) was reduced in cells grown in the 3D matrix. Conversely, phosphorylation of p38 MAPK (p38 mitogen‐activated protein kinase) was elevated in the 3D matrix, and its up‐regulation was linked to an increase in mRNA levels of dentin matrix protein 1 and bone sialoprotein. Although multiple characteristics such as surface topography, chemical composition and mechanical properties differ in the preparations of our collagen‐rich milieu, our observations support the notion that geometrical alterations in ECM environments can alter the phosphorylation pattern of p130Cas, FAK, ERK1/2 and p38 MAPK and lead to a differential developmental fate.     

The connexin mimetic peptide Gap27 increases human dermal fibroblast migration in hyperglycemic and hyperinsulinemic conditions in vitro

Significant increases in skin wound healing rates occur by reducing connexin-mediated communication (CMC). Gap27, a connexin (Cx) mimetic peptide targeted to the second extracellular loop of Cx43, which inhibits CMC, increases migration of human keratinocytes and dermal fibroblasts. To examine the efficacy of Gap27 in a hyperglycemic and hyperinsulinemic in vitro environment, cell migration, gap junction, and Cx hemichannel functionality and cell-substrate adhesion assays were performed on human dermal fibroblasts and diabetic fibroblast and keratinocytes. To investigate fibroblast genes involved in these processes, extra-cellular matrix (ECM) and adhesion gene expression was determined with a PCR array. Gap27 increased fibroblast migration in both euglycemia/euinsulinemia and hyperglycemia/hyperinsulinemia, and influenced migration in diabetic keratinocytes. Hyperglycemia/hyperinsulinemia reduced gap junction coupling in fibroblasts and Gap27 reduced CMC and cell adhesion to substrata in fibroblasts cultured in high glucose. Migrating dermal fibroblast ECM and cell adhesion genes were found to be differentially regulated by Gap27 in euglycemia and hyperglycemia. The PCR array showed that Gap27 upregulated 34 genes and downregulated 1 gene in euglycemic migrating fibroblasts. By contrast in hyperglycemia, Gap27 upregulated 1 gene and downregulated 9 genes. In euglycemic conditions, Gap27 induced upregulation of genes associated with ECM remodeling, whereas in hyperglycemia, ECM component genes were downregulated by Gap27. Thus, Gap27 improves cell migration during scrape-wound repair in hyperglycemia/hyperinsulinemia conditions in vitro, although migration of diabetic cells is less influenced. Our results suggest that this increase in motility may occur by decreasing gap junction and hemichannel activity and altering gene expression in the adhesion and ECM pathway.     

PDGF-BB enhances expression of,and reduces adhesion to,laminin-5 in vascular smooth muscle cells

The laminin family of extracellular matrix (ECM) proteins plays crucial roles in regulating cellular growth, migration, and differentiation. We report here that laminin-5 is expressed in the tunica media of the rat aorta and pulmonary arteries. Using indirect immunofluorescence microscopy, Western blots, and RT-PCR analysis, we found that primary cultures of rat arterial smooth muscle cells express laminin-5 and deposit it into their insoluble ECM. These cells also attach strongly to laminin-5 via beta1 integrin receptors in 30 min adhesion assays. Laminin-5 expression in these cells is upregulated by growth factors in vitro and platelet-derived growth factor (PDGF-BB) stimulation reduces adhesion to laminin-5. As laminin-5 promotes enhanced migration of other cell types, the production of and adhesion to laminin-5 by vascular smooth muscle cells may play a role in the pathological growth and migration of these cells associated with restenosis following vascular injury.     

MicroRNA‐488 suppresses cell migration through modulation of the focal adhesion activity during chondrogenic differentiation of chick limb mesenchymal cells

miRNAs (microRNAs) have proven to play essential roles in diverse biological processes including early development, cell proliferation and cell death, and cell differentiation. However, there is only limited amount of information about their potential role in chondrogenesis. In the present study, we investigated the role of miRNA‐488 in the cellular condensation, which is essential initiation for chondrogenic differentiation. We found that miRNA‐488 expression is up‐regulated at the precondensation stage and then down‐regulated at the postcondensation stage. Blockade of miRNA‐488 via the use of PNA (peanut agglutinin)‐based ASOs (antisense oligonucleotides) decreased the protein level of integrins β1 and phosphorylated FAK (focal adhesion kinase) and resulted in the suppression of cell motility and migration. Moreover, in parallel with theses observation, treatment of anti‐miRNA‐488 oligonucleotides up‐regulated the level of MMP (matrix metalloprotease)‐2 activity, and co‐treatment with GM6001, an MMP inhibitor, induced recovery of cellular condensation inhibited by blockade of miRNA‐488. Collectively, our results suggest that miRNA‐488 is one of regulator in cell to ECM (extracellular matrix) interaction through modulation of focal adhesion activity by MMP‐2 during chondrogenesis of limb mesenchymal cells.     

Progressive myopathy and defects in the maintenance of myotendinous junctions in mice that lack talin 1 in skeletal muscle

The development and function of skeletal muscle depend on molecules that connect the muscle fiber cytoskeleton to the extracellular matrix (ECM). beta1 integrins are ECM receptors in skeletal muscle, and mutations that affect the alpha7beta1 integrin cause myopathy in humans. In mice, beta1 integrins control myoblast fusion, the assembly of the muscle fiber cytoskeleton, and the maintenance of myotendinous junctions (MTJs). The effector molecules that mediate beta1 integrin functions in muscle are not known. Previous studies have shown that talin 1 controls the force-dependent assembly of integrin adhesion complexes and regulates the affinity of integrins for ligands. Here we show that talin 1 is essential in skeletal muscle for the maintenance of integrin attachment sites at MTJs. Mice with a skeletal muscle-specific ablation of the talin 1 gene suffer from a progressive myopathy. Surprisingly, myoblast fusion and the assembly of integrin-containing adhesion complexes at costameres and MTJs advance normally in the mutants. However, with progressive ageing, the muscle fiber cytoskeleton detaches from MTJs. Mechanical measurements on isolated muscles show defects in the ability of talin 1-deficient muscle to generate force. Collectively, our findings show that talin 1 is essential for providing mechanical stability to integrin-dependent adhesion complexes at MTJs, which is crucial for optimal force generation by skeletal muscle.     

Exosome-mediated transduction of mechanical force regulates prostate cancer migration via microRNA

Physical cues in the extracellular microenvironment regulate cancer cell metastasis. Functional microRNA (miRNA) carried by cancer derived exosomes play a critical role in extracellular communication between cells and the extracellular microenvironment. However, little is known about the role of exosomes loaded miRNAs in the mechanical force transmission between cancer cells and extracellular microenvironment. Herein, our results suggest that stiff extracellular matrix (ECM) induced exosomes promote cancer cell migration. The ECM mechanical force regulated the exosome miRNA cargo of prostate cancer cells. Exosome miRNAs regulated by the ECM mechanical force modulated cancer cell metastasis by regulating cell motility, ECM remodeling and the interaction between cancer cells and nerves. Focal adhesion kinase mediated-ECM mechanical force regulated the intracellular miRNA expression, and F-actin mediate-ECM mechanical force regulated miRNA packaging into exosomes. The above results demonstrated that the exosome miRNA cargo promoted cancer metastasis by transmitting the ECM mechanical force. The ECM mechanical force may play multiple roles in maintaining the microenvironment of cancer metastasis through the exosome miRNA cargo.     

Proteoglycans of L6J1 myoblast extracellular matrix: Properties and effect on myoblast adhesion

Proteoglycans were isolated from the extracellular matrix (ECM) of L6J1 rat myoblasts; their influence on myoblast adhesion has been studied. Proteoglycan digestion with chondroitinase AC and heparinase III, which degrade polysaccharide moieties, has revealed that chondroitin sulfate proteoglycans are a major class of myoblast extracellular matrix proteoglycans. Electrophoresis of enzymatically processed proteoglycans was used to examine their core proteins. Myoblast adhesion was suppressed by proteoglycans or a mixture of proteoglycans and a fibronectin-extracellular matrix. Myoblast adhesion to a substrate composed of fibronectin and proteoglycans is restored after the substrate was treated with chondroitinase AC. In conclusion, proteoglycans of L6J1 rat myoblast ECMs were isolated and purified. Chondroitin sulfate proteoglycans are a major class of proteoglycans. Isolated proteoglycans suppressed myoblast adhesion; the effect was mediated by polysaccharide moieties of proteoglycans.     

Extracellular vesicles from human umbilical cord mesenchymal stem cells improve nerve regeneration after sciatic nerve transection in rats

Peripheral nerve injury results in limited nerve regeneration and severe functional impairment. Mesenchymal stem cells (MSCs) are a remarkable tool for peripheral nerve regeneration. The involvement of human umbilical cord MSC‐derived extracellular vesicles (hUCMSC‐EVs) in peripheral nerve regeneration, however, remains unknown. In this study, we evaluated functional recovery and nerve regeneration in rats that received hUCMSC‐EV treatment after nerve transection. We observed that hUCMSC‐EV treatment promoted the recovery of motor function and the regeneration of axons; increased the sciatic functional index; resulted in the generation of numerous axons and of several Schwann cells that surrounded individual axons; and attenuated the atrophy of the gastrocnemius muscle. hUCMSC‐EVs aggregated to rat nerve defects, down‐regulated interleukin (IL)‐6 and IL‐1β, up‐regulated IL‐10 and modulated inflammation in the injured nerve. These effects likely contributed to the promotion of nerve regeneration. Our findings indicate that hUCMSC‐EVs can improve functional recovery and nerve regeneration by providing a favourable microenvironment for nerve regeneration. Thus, hUCMSC‐EVs have considerable potential for application in the treatment of peripheral nerve injury.     

Proteolytic and non-proteolytic migration of tumour cells and leucocytes

The migration of different cell types, such as leucocytes and tumour cells, involves cellular strategies to overcome the physical resistance of three-dimensional tissue networks, including proteolytic degradation of extracellular matrix (ECM) components. High-resolution live-cell imaging techniques have recently provided structural and biochemical insight into the differential use of matrix-degrading enzymes in the migration processes of different cell types within the three-dimensional ECM. Proteolytic migration is achieved by slow-moving cells, such as fibroblasts and mesenchymally moving tumour cells, by engaging matrix metalloproteinases, cathepsins and serine proteases at the cell surface in a focalized manner ('pericellular proteolysis'), while adhesion and migratory traction are provided by integrins. Pericellular breakdown of ECM components generates localized matrix defects and remodelling along migration tracks. In contrast with tumour cells, constitutive non-proteolytic migration is used by rapidly moving T lymphocytes. This migration type does not generate proteolytic matrix remodelling, but rather depends on shape change to allow cells to glide and squeeze through gaps and trails present in connective tissues. In addition, constitutive proteolytic migration can be converted into non-proteolytic movement by protease inhibitors. After the simultaneous inhibition of matrix metalloproteinases, serine/threonine proteases and cysteine proteases in tumour cells undergoing proteolysis-dependent movement, a fundamental adaptation towards amoeboid movement is able to sustain non-proteolytic migration in these tumour cells (the mesenchymal-amoeboid transition). Instead of using proteases for matrix degradation, the tumour cells use leucoyte-like strategies of shape change and squeezing through matrix gaps along tissue scaffolds. The diversity of protease function in cell migration by different cell types highlights response diversity and molecular adaptation of cell migration upon pharmacotherapeutic protease inhibitor treatment.     

Fibroblast adhesion results in the induction of a matrix remodeling gene expression program

Fibrosis is believed to occur through the failure to terminate the normal tissue remodeling program. Tissue repair intimately involves the ability of fibroblasts to attach to extracellular matrix (ECM), resulting in cell migration and ECM contraction. Elevated, activated adhesive signaling is a key phenotypic hallmark of fibrotic cells. The precise contribution of adhesion to tissue remodeling and repair and fibrotic responses in fibroblasts is unclear, but involves focal adhesion kinase (FAK). FAK signals downstream of integrin-mediates attachment of fibroblasts to extracellular matrix. In this report, we show that FAK is required for the expression of a cohort of mRNAs encoding ECM and matrix remodeling genes including CCN2, alpha-smooth muscle actin (SMA) and type I collagen. Adhesion of fibroblasts to fibronectin, a component of the provisional matrix deposited in the initial phases of tissue repair, also resulted in the induction of CCN2, alpha-SMA and type I collagen mRNAs. Endothelin-1 (ET-1), a key inducer of pro-fibrotic gene expression, was also induced upon fibroblast attachment to ECM, and antagonism of the ET-1 receptors significantly reduced the ability of adhesion to induce expression of CCN2, alpha-SMA and type I collagen mRNAs. These results suggest that adhesion of fibroblasts to matrix during the initial phases of tissue remodeling and repair may actively contribute to the tissue repair program through the induction of pro-fibrotic gene expression.