A Subset of Malignant Mesothelioma Tumors Retain Osteogenic Potential.

Malignant mesothelioma (MM) is an aggressive serosal tumor associated with asbestos exposure. We previously demonstrated that mesothelial cells differentiate into cells of different mesenchymal lineages and hypothesize that osseous tissue observed in a subset of MM patients is due to local differentiation of MM cells. In this study, the capacity of human and mouse MM cells to differentiate into osteoblast-like cells was determined in vitro using a functional model of bone nodule formation and in vivo using an established model of MM. Human and murine MM cell lines cultured in osteogenic medium expressed alkaline phosphatase and formed mineralized bone-like nodules. Several human and mouse MM cell lines also expressed a number of osteoblast phenotype markers, including runt-related transcription factor 2 (RUNX2), osteopontin, osteonectin and bone sialoprotein mRNA and protein. Histological analysis of murine MM tumors identified areas of ossification within the tumor, similar to those observed in human MM biopsies. These data demonstrate the ability of MM to differentiate into another mesenchymal cell type and suggest that MM cells may contribute to the formation of the heterologous elements observed in MM tumors.

Spontaneously immortalized mouse mesothelial cells display characteristics of malignant transformation.

OBJECTIVES: Mesotheliomas occur in occult serous cavities after chronic exposure of mesothelial cells to asbestos fibres. Molecular events that contribute to the development of this cancer are therefore not readily accessible for study. We have used in vitro culture systems to study and compare induced and spontaneous transformation events in primary mouse mesothelial cells. MATERIALS AND METHODS: Mouse mesothelial cells were cultivated until small populations of proliferating cells emerged from senescing cultures. Spontaneously transformed cultures of cells were characterized and compared to malignantly transformed cells. RESULTS: Human mesothelial cells had a finite lifespan of 10-15 population doublings when cultured in vitro; mouse mesothelial cells typically exhibit this same pattern. Here, we show that mouse mesothelial cells can be cultured for extended periods and that these cells can transform spontaneously. Lines of spontaneously transformed cells generated in this study are immortal and growth factor-independent. They display the salient characteristic features of transformation, including increased proliferation rate, lack of contact inhibition, aneuploidy and ability to grow in anchorage-independent conditions. A subset of these cell lines developed into tumours in syngeneic mice. Comparative gene expression analysis demonstrated that spontaneously transformed cell lines were more closely related to neoplastic cells than to primary cells. CONCLUSION: These findings have implications for interpretation of in vitro transformation studies, demonstrating broad similarity between spontaneous and induced genetic changes.

The origin of regenerating mesothelium: a historical perspective.

Bichat first described the mesothelium in 1827 but despite its early discovery, it has only been in recent years that its importance both in health and disease has been realised. One area still poorly understood is that of the mechanisms regulating mesothelial repair. Mesothelial cells are derived from the mesoderm but express many epithelial characteristics. However, mesothelium does not heal in the same way as other epithelial-like cells. Epithelium heals by centripetal migration, with cells at the edge of the wound proliferating and migrating into the injured area. Hertzler in 1919 noted that both large and small peritoneal injuries healed within the same time frame, concluding that the mesothelium could not heal solely by centripetal migration. The exact mechanisms involved in mesothelial regeneration following injury are controversial with a number of proposals suggested to explain the origin of the regenerating cells. This review will examine these proposals and give some insights into the likely mechanisms involved.

The potential of mesothelial cells in tissue engineering and regenerative medicine applications.

Injury to the serosa through injurious agents such as radiation, surgery, infection and disease results in the loss of the protective surface mesothelium and often leads to fibrous adhesion formation. Mechanisms that increase the rate of mesothialisation are therefore actively being investigated in order to reduce the formation of adhesions. These include intraperitoneal delivery of cultured mesothelial cells as well as administration of factors that are known to increase mesothelial proliferation and migration. An exciting alternative that has only recently received attention, is the possible role of mesothelial progenitor cells in the repair and regeneration of denuded serosal areas. Accumulating evidence suggests that such a population exists and under certain conditions is able to form a number of defined cell types indicating a degree of plasticity. Such properties may explain the extensive use of mesothelial cells in various tissue engineering applications including the development of vascular conduits and peripheral nerve replacements. It is likely that with the rapid explosion in the fields of tissue engineering and regenerative medicine, a greater understanding of the potential of mesothelial progenitor cells to repair, replace and possibly regenerate damaged or defective tissue will be uncovered.

Structure and function of mesothelial cells.

The mesothelium was first described about 180 years ago but only in the last twenty years have we begun to appreciate the roles that mesothelial cells play in maintaining normal serosal membrane integrity and function. Mesothelial cells are sentinel cells that can sense and respond to signals within their microenvironment. They secrete glycosaminoglycans and surfactant to allow the parietal and visceral serosa to slide over each other. They actively transport fluids, cells and particulates across the serosal membrane and between serosal cavities. They synthesise and secrete a diverse array of mediators in response to external signals which play important roles in regulating inflammatory, immune and tissue repair responses. In addition, they are likely to protect from peritoneal dissemination of tumours until the integrity of the mesothelium is breached. Although the importance of the mesothelial cell is being realised, we still do not understand the mechanisms regulating many of their functions. How the cells communicate with each other and surrounding cells, whether mesothelial cells differentiate into different cell types or if a mesothelial stem cell exists, the mechanisms regulating mesothelial repair and the role mesothelial cells play in serosal pathologies, all need further study. Although it has long been accepted that mesothelial cells are similar irrespective of site or species, apart from morphology, few studies have truly compared biochemical and functional characteristics of these cells between species and within different anatomical sites. In a recent study examining the effect of aging on human peritoneal mesothelial cells, there was a positive correlation between the age of the donor's cells and the proinflammatory profile. Although mesothelial cells share many similarities, it is likely that functional and physiological adaptation will alter these cells. Addressing these questions are paramount if we hope to find better ways to protect serosal integrity and prevent peritoneal dissemination of tumours.

Short course dexamethasone treatment following injury inhibits bleomycin induced fibrosis in rats.

BACKGROUND: Corticosteroids are routinely used in patients with pulmonary fibrosis. The timing for initiation of treatment is likely to be crucial for corticosteroids to exert an antifibrotic effect. Experimental studies in animals have examined the effect of corticosteroid treatment starting before or at the time of lung injury. However, this is not representative of the human condition as treatment only begins after disease has been established. We examined the effect of a short course corticosteroid treatment starting 3 days after bleomycin induced lung injury on the development of pulmonary fibrosis. METHODS: Bleomycin (1.5 mg/kg) was instilled intratracheally into rats to induce pulmonary fibrosis. The effect of a 3-day course of dexamethasone (0.5 mg/kg) initiated 3 days after bleomycin induced lung injury on cell proliferation and collagen deposition was examined by analysing bronchoalveolar lavage (BAL) fluid and lung tissue. RESULTS: Treating bleomycin exposed animals after injury with dexamethasone for 3 days inhibited lung collagen deposition compared with animals exposed to bleomycin without dexamethasone treatment (15.2 (2.2) mg collagen/lung v 22.5 (2.1) mg/lung; p<0.05). Dexamethasone treatment reduced pulmonary parenchymal cell proliferation in bleomycin exposed rats but did not influence BAL fluid mitogenic activity for lung fibroblasts or alter the BAL fluid levels of the fibrogenic mediators transforming growth factor-beta(1), platelet derived growth factor-AB, and thrombin. CONCLUSIONS: A 3 day course of dexamethasone treatment initiated 3 days after bleomycin induced lung injury reduces lung cell proliferation and collagen deposition by mechanisms other than through reduction of transforming growth factor-beta(1), platelet derived growth factor-AB, and thrombin levels in BAL fluid. We propose that an early short course treatment with dexamethasone may be useful in inhibiting pulmonary fibrosis.

Presence and distribution of sensory nerve fibers in human peritoneal adhesions.

OBJECTIVE: To assess the distribution and type of nerve fibers present in human peritoneal adhesions and to relate data on location and size of nerves with estimated age and with clinical parameters such as reports of chronic pelvic pain. SUMMARY BACKGROUND DATA: Peritoneal adhesions are implicated in the cause of chronic abdominopelvic pain, and many patients are relieved of their symptoms after adhesiolysis. Adhesions are thought to cause pain indirectly by restricting organ motion, thus stretching and pulling smooth muscle of adjacent viscera or the abdominal wall. However, in mapping studies using microlaparoscopic techniques, 80% of patients with pelvic adhesions reported tenderness when these structures were probed, an observation suggesting that adhesions themselves are capable of generating pain stimuli. METHODS: Human peritoneal adhesions were collected from 25 patients undergoing laparotomy, 20 of whom reported chronic pelvic pain. Tissue samples were prepared for histologic, immunohistochemical, and ultrastructural analysis. Nerve fibers were characterized using antibodies against several neuronal markers, including those expressed by sensory nerve fibers. In addition, the distribution of nerve fibers, their orientation, and their association with blood vessels were investigated by acetylcholinesterase histochemistry and dual immunolocalization. RESULTS: Nerve fibers, identified histologically, ultrastructurally, and immunohistochemically, were present in all the peritoneal adhesions examined. The location of the adhesion, its size, and its estimated age did not influence the type of nerve fibers found. Further, fibers expressing the sensory neuronal markers calcitonin gene-related protein and substance P were present in all adhesions irrespective of reports of chronic abdominopelvic pain. The nerves comprised both myelinated and nonmyelinated axons and were often, but not invariably, associated with blood vessels. CONCLUSIONS: This study provides the first direct evidence for the presence of sensory nerve fibers in human peritoneal adhesions, suggesting that these structures may be capable of conducting pain after appropriate stimulation.

HGF/SF induces mesothelial cell migration and proliferation by autocrine and paracrine pathways.

Mesothelial repair differs from that of other epithelial-like surfaces as healing does not occur solely by centripetal in-growth of cells as a sheet from the wound margins. Mesothelial cells lose their cell-cell junctions, divide, and adopt a fibroblast-like morphology while scattering across and covering the wound surface. These features are consistent with a cellular response to hepatocyte growth factor/scatter factor (HGF/SF). In this study, we examined the ability of mesothelial cells to secrete HGF/SF and investigated its possible role as an autocrine regulator of mesothelial cell motility and proliferation. We found that human primary mesothelial cells expressed HGF/SF mRNA and secreted active HGF/SF into conditioned medium as determined by ELISA and in a scattering bioassay. These cells also expressed the HGF/SF receptor, Met, as shown by RT-PCR and by Western blot analysis and immunofluorescence. Incubation of mesothelial cells with neutralizing antibodies to HGF/SF decreased cell migration to 25% of controls, whereas addition of HGF/SF disrupted cell-cell junctions and induced scattering and enhanced mesothelial cell migration. Furthermore, HGF/SF showed a small but significant mitogenic effect on all mesothelial cell lines examined. In conclusion, HGF/SF is produced by mesothelial cells and induces both motility and proliferation of these cells. These data are consistent with HGF/SF playing an autocrine role in mesothelial healing.

Growth of nerve fibres into murine peritoneal adhesions.

Adhesions in the peritoneal cavity have been implicated in the cause of intestinal obstruction and infertility, but their role in the aetiology of chronic pelvic pain is unclear. Nerves have been demonstrated in human pelvic adhesions, but the presence of pain-conducting fibres has not been established. The purpose of this study was to use an animal model to examine the growth of nerves during adhesion formation at various times following injury and to characterize the types of fibres present. Adhesions were generated in mice by injuring the surface of the caecum and adjacent abdominal wall, with apposition. At 1-8 weeks post-surgery, adhesions were processed and nerve fibres characterized histologically, immunohistochemically, and ultrastructurally. Peritoneal adhesions had consistently formed by 1 week after surgery and from 2 weeks onwards, all adhesions contained some nerve fibres which were synaptophysin, calcitonin gene-related peptide, and substance P-immunoreactive, and were seen to originate from the caecum. By 4 weeks post-surgery, nerve fibres were found to originate from both the caecum and the abdominal wall, and as demonstrated by acetylcholinesterase histochemistry, many traversed the entire adhesion. Ultrastructural analysis showed both myelinated and non-myelinated nerve fibres within the adhesion. This study provides the first direct evidence for the growth of sensory nerve fibres within abdominal visceral adhesions in a murine model and suggests that there may be nerve fibres involved in the conduction of pain stimuli.

Human peritoneal adhesions are highly cellular, innervated, and vascularized.

Peritoneal adhesions are a major complication of healing following surgery or infection and can lead to conditions such as intestinal obstruction, infertility, and chronic pain. Mature adhesions are the result of aberrant peritoneal healing and historically have been thought to consist of non-functional scar tissue. The aim of the present study was to analyse the cellular composition, vascularity, and extracellular matrix distribution of human peritoneal adhesions, to determine whether adhesions represent redundant scar tissue or are dynamic regenerating structures. Furthermore, the histological appearance of each adhesion was correlated with the clinical history of the patient, to determine whether maturity or intraperitoneal pathology influences adhesion structure. Human peritoneal adhesions were collected from 29 patients undergoing laparotomy for various conditions and were prepared for histology, immunocytochemistry, and transmission electron microscopy. All adhesions were highly vascularized, containing well-developed arterioles, venules, and capillaries. Nerve fibres, with both myelinated and non-myelinated axons, were present in adhesions from nearly two-thirds of the patients, with increased incidence in those with a malignancy. Approximately one-third of the adhesions contained conspicuous smooth muscle cell clusters lined by collagen fibres of heterogeneous size. Adipose tissue was a consistent feature of all the adhesions, with some areas displaying fibrosis. There appeared to be no correlation between the estimated maturity or site of each adhesion and its histological appearance. However, intraperitoneal pathology at the time of surgery did influence the incidence of some histological features, such as the presence of nerve fibres, clusters of smooth muscle cells, and inflammation. This study challenges previous concepts that adhesions represent non-functional scar tissue and clearly demonstrates that established adhesions are highly cellular, vascularized, and innervated, features more consistent with dynamic, regenerating structures.

Mesothelial regeneration is not dependent on subserosal cells.

It has been proposed that after mesothelial injury, resident cells within the subserosal connective tissue proliferate, differentiate, and migrate to the serosal surface. The aim of this study was to examine the temporal and spatial changes of proliferating cells in a murine model of testicular mesothelial healing and assess the potential of submesothelial cells to reconstitute the damaged mesothelium. Histology and autoradiography were employed to determine the number of cells within the submesothelial connective tissue, as well as the proportion of cells undergoing DNA synthesis on and beneath the injured serosa. Mesothelial cells surrounding the wound demonstrated maximal DNA synthesis 48 h after injury (27. 82+/-5.64% SEM, compared with 0.17+/-0.16% (3)H-TdR labelled cells for resting mesothelium), whereas a significant increase in proliferating submesothelial cells was not seen until day 4 post-injury (7.79+/-3.31% compared with 0.85+/-0.64% (3)H-TdR labelled cells at day 2). Furthermore, this small number of dividing submesothelial cells must include cells other than the proposed mesothelial precursors, indicating a very low proportion of precursor cells in the submesothelial cell population. As large numbers of mesothelial cells were seen at the wound centre by 3-4 days after injury, it is unlikely that submesothelial cells contributed significantly to the repopulation of the injured mesothelium. It is hypothesized that regenerating mesothelium is more likely to originate from the surrounding uninjured mesothelial cell population.

Focal accumulation of intra-axonal mitochondria in demyelination of the cat optic nerve.

Mitochondrial accumulation has been reported at sites of degenerating nerve fibres. The reason for focal accumulation of mitochondria within axons has not previously been investigated. The aim of this study was to quantitate changes in mitochondrial concentration within demyelinated axons and determine if these changes were due to obstruction of the free passage of organelles within the fibre. The average number of mitochondria per unit area of axon within axons of normal cat optic nerve and optic nerve in which demyelination had been induced with anti-galactocerebroside (GC) was determined using transmission electron microscopy. Increased numbers of mitochondria were demonstrated at the site of demyelination, peaking at approximately two and a half times the value for normal non-lesioned nerves at 6-7 days after anti-GC administration [0.66+/-0.06 (SD) mitochondria per microm2 of axon compared to 0.28+/-0.04 in controls; P < 0.05]. The mitochondrial concentration gradually decreased over the next 20 days towards normal values. The concentration of mitochondria within non-myelinated axons of cat retina (0.55+/-0.18) was also determined and shown to be comparable to the values for the demyelinated optic axons (0.66+/-0.06). It is proposed that the accumulation of mitochondria within demyelinated axons reflects the adaptive process of the axon during the early restoration of impulse conduction rather than the obstruction of the free passage of organelles within the fibre.

Fibroblast mitogens in bronchoalveolar lavage (BAL) fluid from asbestos-exposed subjects with and without clinical evidence of asbestosis: no evidence for the role of PDGF, TNF-alpha, IGF-1, or IL-1 beta.

Asbestosis is a fibrotic lung disease resulting from inhalation of asbestos fibres. Its pathogenesis is poorly understood but probably involves stimulation of fibroblast proliferation and collagen production by mediators released from inflammatory and resident lung cells. In vitro studies have implicate PDGF, TNF-alpha, IGF-1, TGF-beta, and IL-1 in asbestosis, but the role of these mediators in vivo is not known. This study aimed to characterize mediators in bronchoalveolar lavage (BAL) fluid from patients exposed to asbestos with (n = 24) or without (n = 34) asbestosis, compared with ten normal subjects. Human lung fibroblasts were exposed to serial dilutions of BAL fluids and the effects on fibroblast proliferation were assessed. The median mitogenic activity of BAL fluid from asbestos-exposed (17 per cent above medium control, range 3-44 per cent) and asbestosis (14 per cent, range 2-60 per cent) groups was higher than that of BAL fluid from controls (10 per cent, range 2-20 per cent; P < 0.01 and P < 0.05, respectively), but there was no significant difference between the patient groups. The mitogenic activity of BAL fluids was not reduced by incubation with neutralizing antibodies to PDGF-AA, PDGF-AB, PDGF-BB, TNF-alpha, IGF-1, and IL-1 beta. We conclude that BAL fluids from patients exposed to asbestos contain mitogens for human lung fibroblasts, but that PDGF, TNF-alpha, IGF-1, or IL-1 beta do not contribute to this activity.

Increased endothelin-1 and its localization during the development of bleomycin-induced pulmonary fibrosis in rats.

Endothelin-1 (Et-1) has been implicated in the pathogenesis of pulmonary fibrosis with increased levels in the lung tissue of patients with pulmonary fibrosis and profibrotic effects in vitro. In this study we have investigated the temporal changes in lung Et-1 levels and immunohistochemical localization in relation to collagen deposition during the development of bleomycin-induced pulmonary fibrosis in rats. Lung Et-1 content doubled by 3 d following the intratracheal instillation of bleomycin, and continued to increase up to 7 d when values were about threefold greater than controls. Thereafter, the values for bleomycin-treated animals remained constant up to 21 d. There was no change in collagen content at 3 d but after 7 d there was a 25% increase and by 21 d levels were almost double those of the controls. In normal lung, Et-1 was predominantly associated with epithelial cells of conducting and nonconducting airways. Following bleomycin administration, intense staining of macrophages and conducting airway and alveolar epithelial cells was observed with marked staining of perivascular, peribronchiolar, and alveolar septal connective tissue, as well as the venular and arterial intima and media. These results demonstrate elevation of Et-1 levels prior to an increase in collagen content which, along with its localization within developing fibrotic lesions, provides further evidence of a profibrotic role for Et-1 in the pathogenesis of pulmonary fibrosis.

Effect of endothelin receptor antagonists (BQ-485, Ro 47-0203) on collagen deposition during the development of bleomycin-induced pulmonary fibrosis in rats.

Previous evidence suggests a role for endothelin-1 (ET-1) in the pathogenesis of pulmonary fibrosis. To determine if ET-1 regulates collagen deposition in pulmonary fibrosis, we examined the effect of the non-selective ETA and ETB receptor antagonist bosentan (Ro 47-0203), and a selective ETA receptor antagonist, BQ-485, on collagen deposition during the development of bleomycin-induced pulmonary fibrosis in rats. Lung collagen content, derived from measurements of hydroxyproline and expressed as mg collagen/lung, was increased in the bleomycin-treated animals by day 7 (bleomycin, 22.88+/-1.46; control 18.50+/-0.98; P<0.05), continued to increase up to day 14 (bleomycin, 38.80+/-2.17; control 22.57+/-0.77; P<0.001) and then remained constant to 21 days. Daily treatment by gavage with bosentan (100 mg/kg) did not prevent the increase in collagen deposition induced by instillation of bleomycin at any of the times measured. Continuous administration of BQ-485, by subcutaneously implanted minipump (7.5 mg/day), also failed to prevent the bleomycin-induced collagen deposition at 14 days. These findings suggest that ET-1 does not modulate collagen deposition during the development of bleomycin-induced pulmonary fibrosis. Further studies are required to assess whether endothelin receptor antagonists modulate other components of the fibrotic response or play a role in man.

Indomethacin suppresses the anti-proliferative effects of transforming growth factor-beta isoforms on fibroblast cell cultures.

The transforming growth factor-beta (TGFbeta) family of mediators consists of five closely related isoforms, of which three are present in mammals. TGFbeta1 has been shown to exert a biphasic effect on the proliferation of several cell types, including fibroblasts, with stimulation at low concentrations and inhibition at higher concentrations. The stimulatory effects are well characterized, but the mechanisms by which TGFbeta1 inhibits cell proliferation are incompletely understood. In the present study we have compared the effects of all three mammalian TGFbeta isoforms on human lung fibroblast proliferation, and have elucidated the role of the TGFbeta-induced synthesis of prostaglandin E2 (PGE2) in mediating their actions. All three isoforms stimulated fibroblast proliferation with maximal effects at 5 pg/ml (0.2 pM) and an order of potency of TGFbeta3 > TGFbeta2 > TGFbeta1. At higher concentrations, proliferation declined, and at 40 pg/ml and above all isoforms inhibited fibroblast proliferation. Again TGFbeta3 was the most potent, but there were no significant differences between the inhibitory effects of TGFbeta1 and TGFbeta2. Addition of indomethacin, an inhibitor of PGE2 synthesis, did not alter the proliferative activity of any of the TGFbeta isoforms, but completely overcame their inhibitory effects, restoring the stimulatory actions observed at lower TGFbeta concentrations. All TGFbeta isoforms stimulated PGE2 synthesis; TGFbeta3 was approximately twice as potent as TGFbeta1 and TGFbeta2, each of which had similar effects. These data suggest that the inhibition of fibroblast proliferation at higher concentrations of TGFbeta isoforms may be mediated by autocrine stimulation of PGE2 synthesis.

Cytokine regulation of mesothelial cell proliferation in vitro and in vivo.

Previous studies have demonstrated mitogenic effects of several mediators on mesothelial cells in vitro, but their effects in vivo have not been investigated. The aim of this study was to examine the effects of various cytokines on normal mesothelial cell proliferation in vitro and in vivo and correlate the findings in both assay systems. In vitro proliferation was assessed using a technique based on the uptake and subsequent release of methylene blue. Autoradiographic methods were applied in a murine model to assess mitogenic activity of these factors on mesothelium in vivo. In vitro data demonstrated a dose-dependent increase in human mesothelial cell proliferation by all mediators examined: at optimal concentrations, proliferation was enhanced between 26.53 +/- 3.77% standard deviation (SD), p < 0.001 for fibroblast growth factor-2 (FGF-2) and 114.58 +/- 6.97%, p < 0.001 for platelet-derived growth factor-AB (PDGF-AB) above control medium. In vivo, DNA synthesis in mesothelial cells was stimulated by FGF-2 (29.52 +/- 5.85% labeled cells, compared with 7.04 +/- 4.36% for control medium; p < 0.001), tumor necrosis factor-alpha (TNF-alpha; 13.14 +/- 4.55% compared with 7.23 +/- 2.85; p < 0.005) and PDGF-BB (11.53 +/- 4.74% compared with 4.67 +/- 3.48%; p < 0.005). Transforming growth factor-beta1 (TGF-beta1) and epidermal growth factor (EGF) had no effect on DNA synthesis in mesothelial cells in vivo. It is concluded that FGF2, TNF-alpha, and PDGF stimulate mesothelial cell proliferation in vitro and in vivo, whereas TGF-beta1 and EGF only had a mitogenic effect in vitro at the concentrations examined. The mitogenic potency of the different PDGF isoforms in vitro was consistent with PDGF-alpha and beta receptor expression.

Mechanisms of tissue repair: from wound healing to fibrosis.

To set the scene for this Directed Issue on Mechanisms of Tissue Repair of The International Journal of Biochemistry and Cell Biology, this introductory overview briefly describes the process of wound healing and highlights some of the key recent advances in this field of research. It emphasizes the importance of cell-cell and cell-matrix interactions, particularly relating to the role of cell surface adhesion molecules, and describes developments that have led to a better understanding of the dynamic nature of matrix turnover with reference to negative and positive mediators that regulate procollagen gene expression and protein production. An important component of this Directed Issue is concerned with the development of tissue fibrosis, which accompanies a number of disease states and demonstrates remarkable parallels with the normal wound healing process; excessive amounts of matrix are laid down but the resolution of scarring, which would be anticipated in wound healing, is impaired. The possible mechanisms involved in fibrosis are discussed here. Since cytokines play an important role in regulating cell function such as proliferation, migration and matrix synthesis, it is the balance of these mediators which is likely to play a key role in regulating the initiation, progression and resolution of wounds. Finally, this review highlights areas of tissue repair research in which recent developments have important clinical implications that may lead to novel therapeutic strategies.