The internal region leucine-rich repeat 6 of decorin interacts with low density lipoprotein receptor-related protein-1, modulates transforming growth factor (TGF)-ß-dependent signaling, and inhibits TGF-ß-dependent fibrotic response in skeletal muscles.

Decorin is a small proteoglycan, composed of 12 leucine-rich repeats (LRRs) that modulates the activity of transforming growth factor type ß (TGF-ß) and other growth factors, and thereby influences proliferation and differentiation in a wide array of physiological and pathological processes, such as fibrosis, in several tissues and organs. Previously we described two novel modulators of the TGF-ß-dependent signaling pathway: LDL receptor-related protein (LRP-1) and decorin. Here we have determined the regions in decorin that are responsible for interaction with LRP-1 and are involved in TGF-ß-dependent binding and signaling. Specifically, we used decorin deletion mutants, as well as peptides derived from internal LRR regions, to determine the LRRs responsible for these decorin functions. Our results indicate that LRR6 and LRR5 participate in the interaction with LRP-1 and TGF-ß as well as in its dependent signaling. Furthermore, the internal region (LRR6i), composed of 11 amino acids, is responsible for decorin binding to LRP-1 and subsequent TGF-ß-dependent signaling. Furthermore, using an in vivo approach, we also demonstrate that the LRR6 region of decorin can inhibit TGF-ß mediated action in response to skeletal muscle injury.

CTGF/CCN-2 over-expression can directly induce features of skeletal muscle dystrophy.

Muscular dystrophies are diseases characterized by muscle weakness together with cycles of degeneration and regeneration of muscle fibres, resulting in a progressive decrease of muscle mass, diminished muscle force generation and an increase in fibrosis. Fibrotic disorders are the endpoint of many chronic diseases in different tissues, where accumulation of the extracellular matrix (ECM) occurs. Connective tissue growth factor CTGF/CCN2, which is over-expressed in muscular dystrophies, plays a major role in many progressive scarring conditions. To test the hypothesis that CTGF might not only contribute conversion of already damaged muscle into scar tissue, but that it could by itself also directly contribute to skeletal muscle deterioration, we evaluated the effect of CTGF over-expression in tibialis anterior muscle of wild-type mice, using an adenovirus containing the CTGF mouse sequence (Ad-mCTGF). CTGF over-expression induced extensive skeletal muscle damage, which was followed by a massive regeneration of the damaged muscle, as evidenced by increased embryonic myosin and fibres with centrally located nuclei. It also induced strong fibrosis with increased levels of fibronectin, collagen, decorin and α-smooth muscle actin (α-SMA). Moreover, CTGF over-expression caused a decrease of the specific isometric contractile force. Strikingly, when CTGF over-expression stopped, the entire phenotype proved to be reversible, in parallel with normalization of CTGF levels. Thus, CTGF not merely acts downstream of muscle injury but also contributes directly to the deterioration of skeletal muscle phenotype and function. Moreover, normalization of expression levels led to spontaneous reversal of the CTGF-induced phenotype and to full recovery of muscle structure. These observations underscore the importance of CTGF in the pathophysiology of muscular dystrophies and suggest that targeting CTGF might have significant potential in the development of novel therapies for Duchenne muscular dystrophy and related diseases.

Decorin interacts with connective tissue growth factor (CTGF)/CCN2 by LRR12 inhibiting its biological activity.

Fibrotic disorders are the end point of many chronic diseases in different tissues, where an accumulation of the extracellular matrix occurs, mainly because of the action of the connective tissue growth factor (CTGF/CCN2). Little is known about how this growth factor activity is regulated. We found that decorin null myoblasts are more sensitive to CTGF than wild type myoblasts, as evaluated by the accumulation of fibronectin or collagen III. Decorin added exogenously negatively regulated CTGF pro-fibrotic activity and the induction of actin stress fibers. Using co-immunoprecipitation and in vitro interaction assays, decorin and CTGF were shown to interact in a saturable manner with a K(d) of 4.4 nM. This interaction requires the core protein of decorin. Experiments using the deletion mutant decorin indicated that the leucine-rich repeats (LRR) 10-12 are important for the interaction with CTGF and the negative regulation of the cytokine activity, moreover, a peptide derived from the LRR12 was able to inhibit CTGF-decorin complex formation and CTGF activity. Finally, we showed that CTGF specifically induced the synthesis of decorin, suggesting a mechanism of autoregulation. These results suggest that decorin interacts with CTGF and regulates its biological activity.

TGF-beta receptors, in a Smad-independent manner, are required for terminal skeletal muscle differentiation.

Skeletal muscle differentiation is strongly inhibited by transforming growth factor type beta (TGF-beta), although muscle formation as well as regeneration normally occurs in an environment rich in this growth factor. In this study, we evaluated the role of intracellular regulatory Smads proteins as well as TGF-beta-receptors (TGF-beta-Rs) during skeletal muscle differentiation. We found a decrease of TGF-beta signaling during differentiation. This phenomenon is explained by a decline in the levels of the regulatory proteins Smad-2, -3, and -4, a decrease in the phosphorylation of Smad-2 and lost of nuclear translocation of Smad-3 and -4 in response to TGF-beta. No change in the levels and inhibitory function of Smad-7 was observed. In contrast, we found that TGF-beta-R type I (TGF-beta-RI) and type II (TGF-beta-RII) increased on the cell surface during skeletal muscle differentiation. To analyze the direct role of the serine/threonine kinase activities of TGF-beta-Rs, we used the specific inhibitor SB 431542 and the dominant-negative form of TGF-beta-RII lacking the cytoplasmic domain. The TGF-beta-Rs were important for successful muscle formation, determined by the induction of myogenin, creatine kinase activity, and myosin. Silencing of Smad-2/3 expression by specific siRNA treatments accelerated myogenin, myosin expression, and myotube formation; although when SB 431542 was present inhibition in myosin induction and myotube formation was observed, suggesting that these last steps of skeletal muscle differentiation require active TGF-beta-Rs. These results suggest that both down-regulation of Smad regulatory proteins and cell signaling through the TGF-beta receptors independent of Smad proteins are essential for skeletal muscle differentiation.

Syndecan-4 and beta1 integrin are regulated by electrical activity in skeletal muscle: Implications for cell adhesion.

Syndecan-4 and integrins are involved in the cell migration and adhesion processes in several cell types. Syndecan-4, a transmembrane heparan sulfate proteoglycan, is associated to focal adhesions in adherent cells and has been described as a marker of satellite cells in skeletal muscle. In this tissue, beta1 integrin forms heterodimers with alpha5 and alpha6 during myoblast differentiation and with alpha7 in adult muscle. Here, we show that the levels of these two cell surface membrane molecules are regulated by spontaneous electrical activity during the differentiation of rat primary myoblasts. Syndecan-4 and beta1 integrin protein levels decrease after the inhibition of electrical activity using tetrodotoxin (TTX). Syndecan-4 also decreases substantially in denervated rat tibialis anterior muscle. Indirect immunofluorescence analysis shows that syndecan-4 and beta1 integrin co-localize with vinculin, a molecular marker of costameres in skeletal muscle myofibers. Co-localization is lost in inactive myotubes adopting a diffuse pattern, suggesting that the costameric organization is disrupted in TTX-treated myotubes. Moreover, the inhibition of spontaneous electrical activity decreases myotube cell adhesion. In summary, this work shows that syndecan-4 and beta1 integrin protein levels and their localization in costameric structures are regulated by electrical activity and suggests that this regulatory mechanism influences the adhesion properties of skeletal myotubes during differentiation.

Betaglycan induces TGF-beta signaling in a ligand-independent manner, through activation of the p38 pathway.

Betaglycan, a cell surface heparan sulphate proteoglycan, is traditionally thought to function by binding transforming growth factor type beta (TGF-beta) via its core protein and then transferring the growth factor to its signaling receptor, the type II receptor. However, there is increasing evidence that the function of betaglycan is more complex. Here, we have evaluated the role of betaglycan through adenoviral expression (Adv-BG) in myoblasts and fibroblasts and found that in Adv-BG-infected cells, the activity of p3TP-Lux and pCTGF-Luc reporter after transient transfection, as well as fibronectin synthesis, all of which are target processes for TGF-beta, were highly increased in the absence of TGF-beta. It is known that this cytokine strongly inhibits myogenin induction in myoblasts. In Adv-BG-infected myoblasts, the activity of pMyo-Luc reporter after transient transfection was strongly inhibited in the absence of TGF-beta. These effects were not precluded by applying TGF-beta-blocking antibodies, the soluble TGF-beta type II receptor, or soluble betaglycan to sequester TGF-beta present in the cell medium. Furthermore, the data suggest that the cytoplasmic domain of betaglycan is required for this TGF-beta-independent response, giving further support to a ligand-independent signaling effect for betaglycan. The process also seemed independent of Smad-2 phosphorylation, although Adv-BG infection induced p38 phosphorylation, and SB239063, an inhibitor of the p38 pathway, inhibited p3TP-Lux-driven activity. These results suggest a novel signaling mechanism for betaglycan, which is independent of the canonical TGF-beta signal pathway although it involves TGF-beta receptors and takes place through p38 pathways.

Inhibition of myoblast migration via decorin expression is critical for normal skeletal muscle differentiation.

During limb skeletal muscle formation, committed muscle cells proliferate and differentiate in the presence of extracellular signals that stimulate or repress each process. Proteoglycans are extracellular matrix organizers and modulators of growth factor activities, regulating muscle differentiation in vitro. Previously, we characterized proteoglycan expression during early limb muscle formation and showed a spatiotemporal relation between the onset of myogenesis and the expression of decorin, an important muscle extracellular matrix component and potent regulator of TGF-beta activity. To evaluate decorin's role during in vivo differentiation in committed muscle cells, we grafted wild type and decorin-null myoblasts onto chick limb buds. The absence of decorin enhanced the migration and distribution of myoblasts in the limb, correlating with the inhibition of skeletal muscle differentiation. Both phenotypes were reverted by de novo decorin expression. In vitro, we determined that both decorin core protein and its glycosaminoglycan chain were required to reverse the migration phenotype. Results presented here suggest that the enhanced migration observed in decorin-null myoblasts may not be dependent on chemotactic growth factor signaling nor the differentiation status of the cells. Decorin may be involved in the establishment and/or coordination of a critical myoblast density, through inhibition of migration, that permits normal muscle differentiation during embryonic myogenesis.

Specific binding of the endocytosis tracer horseradish peroxidase to intestinal fatty acid-binding protein (I-FABP) in apical membranes of carp enterocytes.

In a previous study we had demonstrated that a 15-kDa protein present in carp intestinal brush-border membrane vesicles (BBMV) was able to bind the endocytosis tracer horseradish peroxidase (HRP) with high specificity. Here we show that this protein corresponds to a peripheral membrane protein, identified by partial amino acid sequence analysis as the intestinal fatty acid-binding protein (I-FABP), a member of the small cytosolic fatty acid binding protein family (FABPs). The presence of I-FABP and its HRP-binding activity was demonstrated both in the cytosolic and membrane-associated fractions of intestinal mucosa by Western and ligand blot analyses, respectively. Also, both fractions displayed significant capacity to bind [(3)H]palmitic acid, a known ligand for I-FABP. Immunohistochemical analysis showed that I-FABP localizes both in the cytosol and in the brush-border membranes of epithelial cells. Taken together the unusual extra-cellular localization of I-FABP as well as its ability to interact with HRP suggests a novel function for this protein in the intestinal mucosa.