Jerzy Moraczewski

Distinct patterns of MMP-9 and MMP-2 activity in slow and fast twitch skeletal muscle regeneration in vivo

Skeletal muscles exhibit great plasticity and an ability to reconstruct in response to injury. However, the repair process is often inefficient and hindered by the development of fibrosis. We explored the possibility that during muscle repair, the different regeneration ability of the fast (extensor digitorum longus; EDL) and slow twitch (Soleus) muscles depends on the differential expression of metalloproteinases (MMP-9 and MMP-2) involved in the remodeling of the extracellular matrix. Our results show that MMP-9 and MMP-2 are present in the intact muscle and are up-regulated after crush-induced muscle injury. The expression and the activity of these two enzymes depend on the type of muscle and the phase of muscle regeneration. In the regenerating Soleus muscle, elevated levels of MMP-9 occurred during the myolysis and reconstruction phase. In contrast, regenerating EDL muscles exhibited decreased MMP-9 levels during myolysis and increased MMP-2 activity at the reconstruction phase. Moreover, satellite cells (mononuclear myoblasts) derived from Soleus and EDL muscles showed no differences in localization or activity of MMP-9 and MMP-2 during proliferation and differentiation in vitro. MMP-9 activity was present during all stages of myoblast differentiation, whereas MMP-2 activity reached its highest level during myoblast fusion. We conclude that MMPs are involved in muscle repair, and that fast and slow twitch muscles exhibit different patterns of MMP-9 and MMP-2 activity.

Comparison of satellite cell-derived myoblasts and C2C12 differentiation in two- and three-dimensional cultures: changes in adhesion protein expression.

Changes in the expression of adhesion proteins involved in myoblast differentiation were investigated in monolayer (two‐dimensional) and 3D (three‐dimensional) cell cultures. The expression of integrin alpha3 subunit, integrin beta1 subunit, ADAM12 (a disintegrin and metalloproteinase 12), tetraspanins CD9 and CD81 and M‐cadherin were examined in the murine myoblast cell line C2C12 and in a primary culture of rat satellite cells. Myoblasts in monolayer and 3D cultures showed significant differences in their morphology and cytoskeletal organization. All of the studied proteins participated in myoblast fusion in each culture examined, but differences in their levels of expression were observed. Satellite cell‐derived myoblasts exhibited higher expression of adhesion protein mRNAs than C2C12 cells. Also, C2C12 cells from a 3D culture showed slightly higher expression of adhesion protein transcripts than the same cells cultured as a monolayer. Significantly, the levels of adhesion protein mRNAs were found to change in parallel in all cell culture types. Despite this finding, it is important that differences between satellite cell‐derived myoblasts and cell line C2C12 grown in monolayer and 3D cultures are taken into account when studying processes of myoblast differentiation in vitro.

Asexual reproduction and regeneration ofCatenula (Turbellaria, Archoophora)

SummaryStudies were made onCatenula, a turbellarian of the order Catenulida, which had been cultured for 6 years in our laboratory. Fission begins inCatenula when the animal exceeds a specifically defined length. Neoblasts accumulate where the body wall narrows, near the subepithelial nerve cell. These cells have a large nucleus of condensed chromatin and a large active nucleolus. They have little cytoplasm, which in addition to free ribosomes, contains a small number of rough endoplastic reticular cisternae and a few mitochondria. Stem cells of epithelium were also found. These cells are similar to neoblasts, having additionally a bundle of centrioles in the cytoplasm.Differentiation of tissues and cells during regeneration proceeds in a manner identical to that during paratomy. After injury the neoblasts collect in two primordia of the brain, but do not form blastemae, as occurs in Tricladida. It is likely that dedifferentiation plays some role in each of the processes examined. A theoretical model of the mechanisms controlling paratomy and regeration is presented. The factors controlling these processes include the inductor formed by the subepithelial nerve cells and the inhibitor blocking it, formed by the brain. The inductor is probably a neurosecretion that combines with a competent receptor on the surface of cells capable of dedifferentiation.

Heparan Sulfate Mimetics Modulate Calpain Activity During Rat Soleus Muscle Regeneration

Skeletal muscle regenerates after injury. Tissue remodelling, which takes place during muscle regeneration, is a complex process involving proteolytic enzymes. It is inferred that micro and milli calpains are involved in the protein turnover and structural adaptation associated with muscle myolysis and reconstruction. Using a whole‐crush injured skeletal muscle, we previously have shown that in vivo muscle treatment with synthetic heparan sulfate mimetics, called RGTAs (for ReGeneraTing Agents), greatly accelerates and improves muscle regeneration after crushing. This effect was particularly striking in the case of the slow muscle Soleus that otherwise would be atrophied. Therefore, we used this regeneration model to study milli and micro calpain expressions in the regenerating Soleus muscle and to address the question of a possible effect of RGTAs treatment on calpain levels. Micro and milli calpain contents increased by about five times to culminate at days 7 and 14 after crushing respectively, thus during the phases of fibre reconstruction and reinnervation. After 64 days of regeneration, muscles still displayed higher levels of both calpains than an intact uninjured muscle. Milli calpain detected by immunocytochemistry was shown in the cytoplasm whereas micro calpain was in both nuclei and cytoplasm in small myofibres but appeared almost exclusively in nuclei of more mature fibres. Interestingly, the treatment of muscles with RGTA highly reduced the increase of both milli and micro calpain contents in Soleus regenerating muscles. These results suggest that the improvement of muscle regeneration induced by RGTA may be partly mediated by minimising the consequences of calpain activity.

Organization and ultrastructure of the nervous system in Catenulida (Turbellaria)

SummaryThe fine structure of the nervous system of lower fresh-water Turbellaria was investigated. This system consists of a brain, short nerve trunks and a network of subepithelial nerve cells. The brain structure shows ganglion cells and their proccesses, forming a neuropil. The ganglion cells are most probably unipolar. The perikaryon contains numerous ribosomes, few mitochondria, and golgi complexes. Thus it corresponds structurally to neuroblasts of higher animals. The neurites contain mitochondria, neurotubules, and empty or dense core vesicles. All (inStenostomum sp.) or some of the nerve cells (inCatenula sp.) have neurosecretory vesicles.

Differential changes in protein kinase C associated with regeneration of rat extensor digitorum longus and soleus muscles.

We used a model of crush-induced regeneration in rat in order to characterize biochemically and histologically the implication of protein kinase C (PKC) in muscle repair after damage. In this model, slow soleus and fast extensor digitorum longus (EDL) muscle regeneration proceed differently. PKC activity has been assayed in regenerating muscles and their intact contralateral during the first 14 days following crushing. Degeneration (myolysis) occurring shortly after crush was associated with a marked down-regulation of the enzyme in both wound muscles and notable increase in the corresponding contralateral muscles. Muscle fiber reconstruction in EDL was associated with a rise in PKC activity which peaked at day 7 in regenerating muscle where it was twice higher than in intact muscle. At variance, muscle PKC activity in soleus increased slower than that of EDL and reached later intact level. Western blot analysis and immunohistochemical studies of representative members of the three PKC subfamilies were performed. All the isoform tested were much less expressed in regenerating than in control intact muscles suggesting that the overall PKC activity in regenerating muscles was more activable than in controls. We have shown that PKC isoforms were sequentially expressed during regeneration in both muscle types. PKC theta; being present the earliest, then delta, epsilon and alpha and finally zeta, beta and eta. Some isoforms were differentially expressed according muscle type. PKC delta being more expressed in soleus whereas beta and eta appeared earlier in EDL. Histochemical studies have revealed that the isoforms were differently localized in muscle tissue and that fiber regeneration was associated with PKC alpha translocation from sarcoplasma to sarcolemma. Together these data have shown that multiple PKC isoforms are implicated in the regenerative process acting at different in times and location and suggesting that individual isoform may fulfill distinct functions.

Restricted Myogenic Potential of Mesenchymal Stromal Cells Isolated From Umbilical Cord

Nonhematopoietic cord blood cells and mesenchymal cells of umbilical cord Whartons jelly have been shown to be able to differentiate into various cell types. Thus, as they are readily available and do not raise any ethical issues, these cells are considered to be a potential source of material that can be used in regenerative medicine. In our previous study, we tested the potential of whole mononucleated fraction of human umbilical cord blood cells and showed that they are able to participate in the regeneration of injured mouse skeletal muscle. In the current study, we focused at the umbilical cord mesenchymal stromal cells isolated from Whartons jelly. We documented that limited fraction of these cells express markers of pluripotent and myogenic cells. Moreover, they are able to undergo myogenic differentiation in vitro, as proved by coculture with C2C12 myoblasts. They also colonize injured skeletal muscle and, with low frequency, participate in the formation of new muscle fibers. Pretreatment of Whartons jelly mesenchymal stromal cells with SDF-1 has no impact on their incorporation into regenerating muscle fibers but significantly increased muscle mass. As a result, transplantation of mesenchymal stromal cells enhances the skeletal muscle regeneration.

Pax3 and Pax7 expression during myoblast differentiation in vitro and fast and slow muscle regeneration in vivo

In this report, we focused on Pax3 and Pax7 expression in vitro during myoblast differentiation and in vivo during skeletal muscle regeneration. We showed that Pax3 and Pax7 were present in EDL (extensor digitorum longus) and Soleus muscle derived cells. These cells express in vitro a similar level of Pax3 mRNA, however, differ in the levels of mRNA encoding Pax7. Analysis of Pax3 and Pax7 proteins showed that Soleus and EDL satellite cells differ in the level of Pax3/7 proteins and also in the number of Pax3/7 positive cells. Moreover, Pax3/7 expression was restricted to undifferentiated cells, and both proteins were absent at further stages of myoblast differentiation, indicating that Pax3 and Pax7 are down‐regulated during myoblast differentiation. However, we noted that the population of undifferentiated Pax3/7 positive cells was constantly present in both in vitro cultured satellite cells of EDL and Soleus. In contrast, there was no significant difference in Pax3 and Pax7 during in vivo differentiation accompanying regeneration of EDL and Soleus muscle. We demonstrated that Pax3 and Pax7, both in vitro and in vivo, participated in the differentiation and regeneration events of muscle and detected differences in the Pax7 expression pattern during in vitro differentiation of myoblasts isolated from fast and slow muscles.

From Planarians to Mammals - the many faces of regeneration

This report presents the history of the involvement of the Department of Cytology in studies of different aspects of regeneration. It can be divided into two major phases; the first focused on the regeneration of Turbellarians and the second on the regeneration of rat skeletal muscles including the differentiation of satellite cells in vitro. Regeneration of Turbellarians was investigated both at the cellular and molecular levels including the role of the protein kinase C (PKC) in this process. Studies on skeletal muscle regeneration initially focused on factors involved in regulation of signal transduction pathways. Next, we explored the influence of growth factors on the modulation of the regeneration process. Another important aspect of our studies was investigating of the distribution and function of different proteins involved in adhesion and fusion of myoblasts. Finally, we are also conducting research on the role of stem cells from other tissues in the regeneration of skeletal muscle.

Protein kinase C activity and phorbol ester binding to rat myogenic cells during growth and differentiation.

Phorbol esters have been reported to induce opposite responses in fetal myoblasts and in satellite cells isolated from adult skeletal muscles. We examined the possibility that different levels of protein kinase C (PKC) activity and different phorbol ester binding characteristics account for these responses. For this purpose, the subcellular distributions of PKC were compared in primary cultures of myogenic cells from fetal and adult rat muscles and in the L6 cell line. Cells were used at the proliferative stage or after differentiation into myotubes. Binding of phorbol dibutyrate (PDBu) was assayed. In all three cell types, the levels of PKC specific activity were comparable at the proliferating and the differentiated stages, and partial translocation of PKC activity from the membrane to the cytosolic compartment was observed after differentiation into myotubes. PDBu binding, which had a Kd of 6 to 13 nM in proliferative cells, rose to between 30 and 52 nM in myotubes. Simultaneously, a small increase was observed in the total number of PDBu binding sites. These results suggest that the role of PKC might change with the stage of differentiation. They also imply that the difference described by others between the sensitivity to phorbol esters of fetal myoblasts and satellite cells is not connected with the phorbol ester receptor (i.e., PKC), but might be caused by events subsequent to PKC activation.