Calpains: markers of tumor aggressiveness?

Rhabdomyosarcoma (RMS) are soft-tissue sarcoma commonly encountered in childhood. RMS cells can acquire invasive behavior and form metastases. The metastatic dissemination implicates many proteases among which are mu-calpain and m-calpain. Study of calpain expression and activity underline the deregulation of calpain activity in RMS. Analysis of kinetic characteristics of RMS cells, compared to human myoblasts LHCN-M2 cells, shows an important migration velocity in RMS cells. One of the major results of this study is the positive linear correlation between calpain activity and migration velocity presenting calpains as a marker of tumor aggressiveness. The RMS cytoskeleton is disorganized. Specifying the role of mu- and m-calpain using antisense oligonucleotides led to show that both calpains up-regulate alpha- and beta-actin in ARMS cells. Moreover, the invasive behavior of these cells is higher than that of LHCN-M2 cells. However, it is similar to that of non-treated LHCN-M2 cells, when calpains are inhibited. In summary, calpains may be involved in the anarchic adhesion, migration and invasion of RMS. The direct relationship between calpain activity and migration velocities or invasive behavior indicates that calpains could be considered as markers of tumor aggressiveness and as potential targets for limiting development of RMS tumor as well as their metastatic behavior.

Involvement of the ERK/MAP kinase signalling pathway in milli-calpain activation and myogenic cell migration.

Recent research carried out in our laboratory has shown that IGF-1, TGF-beta1, and insulin were able to strongly stimulate myoblast migration by increasing milli-calpain expression and activity. However, the signalling pathways involved in these phenomena remain unknown. The aim of this study was to identify the signalling pathway(s) responsible for the effects of IGF-1, TGF-beta1, and insulin on myoblast migration and on milli-calpain expression and activity. For this purpose, wound healing assays were carried out in the presence of growth factors with or without specific inhibitors of ERK/MAP kinase and PI3K/Akt pathways. The results clearly showed that the inhibition of the ERK/MAP kinase pathway prevents the effects of growth factors on myoblast migration. Secondly, the expression and the activity of milli-calpain were studied in cells treated with growth factor, alone or with ERK/MAP kinase inhibitor. The results demonstrated that the up-regulation of milli-calpain expression and activity was mediated by the ERK/MAP kinase pathway. Finally, the possible implication of MyoD and myogenin, myogenic regulatory factors able to regulate milli-calpain expression, was studied. Taken together our results clearly showed that the ERK/MAP kinase signalling pathway is responsible for the effects of the three growth factors on myoblast migration and on milli-calpain expression and activity. On the opposite, the PI3K/Akt signalling pathway, MyoD and myogenin seem to be not implicated in these phenomena.

Involvement of calpains in growth factor-mediated migration.

Previous research in our laboratory has already shown the importance of the role played by ubiquitous calpains during myoblast migration. The aim of this study was to investigate calpain expression during myoblast migration and, to enhance this phenomenon via calpain stimulation. Ubiquitous calpains are members of a large family of calcium-dependent cysteine proteases. They play an important role in numerous biological and pathological phenomena, such as signal transduction, apoptosis, cell-cycle regulation, cell spreading, adhesion, invasion, myogenesis, and motility. Myoblast migration is a crucial step in myogenesis, as it is necessary for myoblast alignment and fusion to form myotubes. This study started by examining changes in calpain expression during migration, then investigated the possibility of activating myoblast migration via the stimulation of calpain expression and/or activity. The migration rate of myoblasts overexpressing mu- or milli-calpain was quantified. The results showed that calpain overexpression dramatically inhibited myoblast migration. Growth-factor treatments were then used to enhance myoblast migration. The results showed that treatment with IGF-1, TGF-beta1, or insulin induced a major increase in migration and caused a significant increase in m-calpain expression and activity. The increase in migration was totally inhibited by adding calpeptin, a calpain-specific inhibitor. These findings suggest that milli-calpain is involved in growth factor-mediated migration.

Myoblast attachment and spreading are regulated by different patterns by ubiquitous calpains.

The calcium-dependent proteolytic system is a large family of well-conserved ubiquitous and tissue-specific proteases, known as calpains, and an endogenous inhibitor, calpastatin. Ubiquitous calpains are involved in many physiological phenomena, such as the cell cycle, muscle cell differentiation, and cell migration. This study investigates the regulation of crucial steps of cell motility, myoblast adhesion and spreading, by calpains. Inhibition of each ubiquitous calpain isoform by antisense strategy pinpointed the involvement of each of these proteases in myoblast adhesion and spreading. Moreover, the actin cytoskeleton and microtubules were observed in transfected cells, demonstrating that each ubiquitous calpain could be involved in the actin fiber organization. C2C12 cells with reduced mu- or m-calpain levels have a rounded morphology and disorganized stress fibers, but no modification in the microtubule cytoskeleton. Antisense strategy directed against MARCKS, a calpain substrate during C2C12 migration, showed that this protein could play a role in stress fiber polymerization. A complementary proteomic analysis using C2C12 cells over-expressing calpastatin indicated that two proteins were under-expressed, while six, which are involved in the studied phenomena, were overexpressed after calpain inhibition. The possible role of these proteins in adhesion, spreading, and migration was discussed.

Involvement of micro-calpain (CAPN 1) in muscle cell differentiation.

Several studies have already demonstrated that micro- and milli-calpains (CAPN 1-CAPN 2), calcium-dependent intracellular cysteine-proteases are involved in many biological phenomenon including muscle growth and development. More particularly, recent studies have demonstrated that milli-calpain is implicated in myoblast fusion. Moreover, in primary muscle cells, these proteases do not appear simultaneously throughout muscle cell differentiation. Because micro- and milli-calpains do not have the same intracellular localization, it appears likely that these two calcium-dependent proteases have different biological roles during muscle cell differentiation. The goal of this study is to determine the role of micro-calpain. We therefore, have developed a muscle cell line in which micro-calpain is over-expressed, using the inducible Tet Regulated Expression System. The outcome is observed by following the behavior of different proteins, considered to be potential substrates of the protease. The present study shows important decreases in the expression level of ezrin (68%), vimentin (64%) and caveolin 3 (76%) whereas many other cytoskeletal proteins remain remarkably stable. Concerning the myogenic transcription factors, only the level of myogenin decreased (59%) after the over-expression of micro-calpain. Ultra structural studies have shown that the myofibrils formed near the cell periphery are normally oriented, lying along the longitudinal axis. This regularity is lost progressively towards the cell center where the cytoskeleton presented an increasing disorganization. All these results indicate that micro-calpain is involved in regulation pathway of myogenesis via at least its action on ezrin, vimentin, caveolin 3 and myogenin, a muscle transcription factor.

Myoblast migration is regulated by calpain through its involvement in cell attachment and cytoskeletal organization.

Cell migration is a fundamental cellular function particularly during skeletal muscle development. Ubiquitous calpains are well known to play a pivotal role during muscle differentiation, especially at the onset of fusion. In this study, the possible positive regulation of myoblast migration by calpains, a crucial step required to align myoblasts to permit them to fuse, was investigated. Inhibition of calpain activity by different pharmacological inhibitors argues for the involvement of these proteinases during the migration of myoblasts. Moreover, a clonal cell line that fourfold overexpresses calpastatin, the endogenous inhibitor of calpains, and that exhibits deficient calpain activities was obtained. The results showed that the migratory capacity of C2C12 and fusion into multinucleated myotubes were completely prevented in these clonal cells. Calpastatin-overexpressing myoblasts unable to migrate were characterized by rounded morphology, the loss of membrane extensions, the disorganization of stress fibers and exhibited a major defect in new adhesion formation. Surprisingly, the proteolytic patterns of desmin, talin, vinculin, focal adhesion kinase (FAK) and ezrin, radixin, moesin (ERM) proteins are the same in calpastatin-overexpressing myoblasts as compared to control cells. However, an important accumulation of myristoylated alanine-rich C kinase substrate (MARCKS) was observed in cells showing a reduced calpain activity, suggesting that the proteolysis of this actin-binding protein is calpain-dependent and could be involved in both myoblast adhesion and migration.

Transactivation of capn2 by myogenic regulatory factors during myogenesis.

The calcium-activated cysteine protease m-calpain plays a pivotal role during the earlier stages of myogenesis, particularly during fusion. The enzyme is a heterodimer, encoded by the genes capn2, for the large subunit, and capn4, for the small subunit. To study the regulation of m-calpain, the DNA sequence upstream of capn2 was analyzed for promoter elements, revealing the existence of five consensus-binding sites (E-box) for several myogenic regulatory factors and one binding site for myocyte enhancer factor-2 (MEF-2). Transient transfections with reporter gene constructs containing the E-box revealed that MyoD presents a high level of transactivation of reporter constructs containing this region, in particular the sequences including the MEF-2/E4-box. In addition, over-expression of various myogenic factors demonstrated that MyoD and myogenin with much less efficiency, can up-regulate capn2, both singly and synergistically, while Myf5 has no effect on synthesis of the protease. Experiments with antisense oligonucleotides directed against each myogenic factor revealed that MyoD plays a specific and pivotal role during capn2 regulation, and cannot be replaced wholly by myogenin and Myf5.

Calpain and myogenesis: development of a convenient cell culture model.

Previous studies have led us to hypothesize that m-calpain plays a pivotal role in myoblast fusion through its involvement in cell membrane and cytoskeleton component reorganization. To support this hypothesis, a convenient and simple myoblast culture model using frozen embryonic myoblasts was developed, which resolved a number of problems inherent to cell primary culture. Biological assays on cultured myoblasts using different media to define the characteristics of the fusion process were first conducted. Proteinase was detectable before the initiation of the fusion process and was closely correlated to the phenomenon of fusion under each culture condition studied. In addition, the study of calpastatin showed that the initiation of fusion does not require a decrease in the level of this endogenous inhibitor of calpains and also confirmed that calpastatin may be implicated in the determination of the end of fusion. On the other hand, analysis of the evolution of myogenic factors revealed that myogenins, MyoD and Myf5, increase very significantly during the formation of multinucleated myotubes. Moreover, the antisense technique against myogenin is capable of preventing the process of fusion by 50%, confirming the pivotal role of this factor in the early stages of differentiation. The possible role of myogenic regulator factors on m-calpain gene expression is discussed.

Development of an inducible system to assess p94 (CAPN3) function in cultured muscle cells.

p94 belongs to the calpain family of enzymes, also called calcium-activated neutral proteases and is mainly expressed in the skeletal muscle. Mutations affecting the gene coding for p94 are responsible for a myopathy syndrome called Limb Girdle Muscular Dystrophy type 2A (LGMD2A). Although the activity of p94 seems necessary for muscle function, the biological role of the enzyme is still unknown. The goal of this study was to develop a muscle cell line in which the expression level of p94 can be regulated, by an inducible way. In this study, a biological system was developed which allowed mimicking, in vitro, of part of the events occurring in patients (i.e. a decrease of p94 activity). The first results indicate that the decrease in p94 activity results in a significant increase of myogenin level, a high specific transcription factor involved in myoblast fusion. This muscle specific inducible system is an interesting biological tool to assess specifically p94 function(s) in cultured muscle cells. According to the present results, p94 seems at least to be involved in a myogenesis regulation pathway via its action on certain proteins belonging to the myogenic regulator factor family.

Involvement of myogenic regulator factors during fusion in the cell line C2C12.

The myogenic factors, MyoD, myogenin, Myf5 and MRF4, can activate skeletal muscle differentiation when overexpressed in non-muscular cells. Gene targeting experiments have provided much insight into the in vivo functions of MRF and have defined two functional groups of MRFs. MyoD and Myf5 may be necessary for myoblast determination while myogenin and MRF4 may be required later during differentiation. However, the specific role of these myogenic factors has not been clearly defined during one important stage of myogenesis: the fusion of myoblasts. Using cultured C2C12 mouse muscular cells, the time-course of these proteins was analyzed and a distinct expression pattern in fusing cells was revealed. In an attempt to clarify the role of each of these regulators during myoblast fusion, an antisense strategy using oligonucleotides with phosphorothioate backbone modification was adoped. The results showed that the inhibition of myogenin and Myf5 activity is capable of significantly preventing fusion. Furthermore, the inhibition of MyoD can wholly arrest the engaged fusion process in spite of high endogenous expression of both myogenin and Myf5. Consequently, each MRF seems to have, at this defined step of myogenesis, a specific set of functions that can not be substituted for by the others and therefore may regulate a distinct subset of muscle-specific genes at the onset of fusion.

Characterization of the calcium-dependent proteolytic system in a mouse muscle cell line.

Many studies have demonstrated that the calcium-dependent proteolytic system (calpains and calpastatin) is involved in myoblast differentiation. It is also known that myogenic differentiation can be studied in vitro. In the present experiments, using a mouse muscle cell line (C2C12) we have analyzed both the sequences of appearance and the expression profiles of calpains 1, 2, 3 and calpastatin during the course of myoblast differentiation. Our results mainly show that the expression of ubiquitous calpains (calpain 1 and 2) and muscle-specific calpain (calpain 3) at the mRNAs level as well as at the protein level do not change significantly all along this biological process. In the same time, the specific inhibitor of ubiquitous calpains, calpastatin, presents a stable expression at mRNAs level as well as protein level, all along myoblast to myotube transition. A comparison with other myogenic cells is presented.

Segregation of Primordial Germ Cells from the Endoderm of the Early Xenopus Embryo by Applying Fibronectin, an Extracellular Matrix, in vitro: (in vitro culture/endodermal mass/extracellular matrix/primordial germ cells/Xenopus laevis).

Two in vitro culture systems were used in order to identify Xenopus primordial germ cells in the early stages of their migration through the endodermal mass. For this study, whole endodermal mass and dissociated endodermal cells were cultured on fibronectin substrates. In the early stages of the explantation, each system used permits the spotting of particular cells among somatic endodermal cells. These cells exhibit an elongated shape, they present random locomotion and they move on the substrate by elongation-contraction. Ultrastructural studies of these cells confirm their germinal quality.