Slowing down differentiation of engrafted human myoblasts into immunodeficient mice correlates with increased proliferation and migration.

We have used a model of xenotransplantation in which human myoblasts were transplanted intramuscularly into immunodeficient Rag2(-/-)γC(-/-) mice, in order to investigate the kinetics of proliferation and differentiation of the transplanted cells. After injection, most of the human myoblasts had already differentiated by day 5. This differentiation correlated with reduction in proliferation and limited migration of the donor cells within the regenerating muscle. These results suggest that the precocious differentiation, already detected at 3 days postinjection, is a limiting factor for both the migration from the injection site and the participation of the donor cells to muscle regeneration. When we stimulated in vivo proliferation of human myoblasts, transplanting them in a serum-containing medium, we observed 5 days post-transplantation a delay of myogenic differentiation and an increase in cell numbers, which colonized a much larger area within the recipient's muscle. Importantly, these myoblasts maintained their ability to differentiate, since we found higher numbers of myofibers seen 1 month postengraftment, as compared to controls. Conceptually, these data suggest that in experimental myoblast transplantation, any intervention upon the donor cells and/or the recipient's microenvironment aimed at enhancing proliferation and migration should be done before differentiation of the implanted cells, e.g., day 3 postengraftment.

EphB2-mediated interactions are essential for proper migration of T cell progenitors during fetal thymus colonization.

The ephrin-Eph ligand receptor pair is known to control the repulsion/adhesion process in different tissues, including the immune system. Herein, we evaluated the role of EphB2 receptors in T cell progenitor migration during in vitro thymus colonization and to ECM or chemokine stimuli. EphB2 and their ligands, ephrin-B1 and ephrin-B2, are expressed in BM-derived progenitors, and EphB2(-/-) cells had diminished thymus colonization capacity. Conversely, EphB2(LacZ) cells, which maintain a preserved ephrin-binding domain, were capable of colonizing WT thymuses similarly to WT progenitors, highlighting the importance of reverse signals transmitted to normal fetal thymus. However, the EphB2 receptor expressed by microenvironmental cells also drives progenitor immigration, as recolonization of EphB2-deficient fetal thymuses was compromised profoundly. Additionally, we observed lower depositions of ECM and chemokines on EphB2-deficient thymuses but no changes in their receptor expression on BM-derived progenitors and developing thymocytes. Migration of EphB2-deficient progenitors and thymocytes was also reduced through ECM or chemokine stimuli. Furthermore, ephrin-B1 costimulation also inhibited haptotaxis and chemotaxis of WT but not EphB2(LacZ) cells, demonstrating the specific involvement of EphB2 signaling on T cell progenitor migration. Our data suggest the relevance of a nonactivated EphB2 for regulating T cell progenitor migration and its modulation upon ephrin-B engagement.

Changes in cell migration-related molecules expressed by thymic microenvironment during experimental Plasmodium berghei infection: consequences on thymocyte development.

We previously showed alterations in the thymus during experimental infection with Plasmodium berghei. Such alterations comprised histological changes, with loss of cortical-medullary limits, and the intrathymic presence of parasites. As the combination of chemokines, adhesion molecules and extracellular matrix (ECM) is critical to appropriate thymocyte development, we analysed the thymic expression of ECM ligands and receptors, as well as chemokines and their respective receptors during the experimental P. berghei infection. Increased expression of ECM components was observed in thymi from infected mice. In contrast, down-regulated surface expression of fibronectin and laminin receptors was observed in thymocytes from these animals. Moreover, in thymi from infected mice there was increased CXCL12 and CXCR4, and a decreased expression of CCL25 and CCR9. An altered thymocyte migration towards ECM elements and chemokines was seen when the thymi from infected mice were analysed. Evaluation of ex vivo migration patterns of CD4/CD8-defined thymocyte subpopulations revealed that double-negative (DN), and CD4(+) and CD8(+) single-positive (SP) cells from P. berghei-infected mice have higher migratory responses compared with controls. Interestingly, increased numbers of DN and SP subpopulations were found in the spleens of infected mice. Overall, we show that the thymic atrophy observed in P. berghei-infected mice is accompanied by thymic microenvironmental changes that comprise altered expression of thymocyte migration-related molecules of the ECM and chemokine protein families, which in turn can alter the thymocyte migration pattern. These thymic disturbances may have consequences for the control of the immune response against this protozoan.

Human myoblast engraftment is improved in laminin-enriched microenvironment.

BACKGROUND: One major challenge in developing cell therapy for muscle diseases is to define the best condition for the recipient's muscle to niche donor cells. We have examined the efficiency of human myoblast transplantation in an immunodeficient animal model, after local irradiation, as well as the potential impact of laminin on myoblast behavior. METHODS: Human myoblasts were injected into preirradiated tibialis anterior muscles from immunodeficient mice. The donor cell engraftment, proliferation, and laminin content within the transplanted muscles were evaluated by immunocytochemistry. Additionally, the effect of laminin upon myoblast proliferation, migration, and survival was ascertained in vitro. RESULTS: Engraftment of human myoblasts into the skeletal muscle of immunodeficient Rag2-/gammac-/C5- mice presubjected to local irradiation provided the best niche for myoblast engraftment, as demonstrated by the number of viable and proliferating donor cells found in the host muscle. Local irradiation significantly enhanced laminin deposition within the recipient's muscle and donor cells were preferentially located in laminin-enriched areas. The same batch of myoblasts used for in vivo injections also responded to laminin in vitro with increased proliferation and cell survival, as well as an improved migratory response. CONCLUSIONS: We show that local irradiation enhances the laminin content in the host muscle microenvironment and provides a better engraftment of human myoblasts. In addition, laminin increases myoblast proliferation, survival, and migration in vitro. These data provide combined in vivo and in vitro evidence that laminin status should be taken into account when designing experimental and clinical cell therapy strategies for muscle disease.

Comparative analysis of genetically engineered immunodeficient mouse strains as recipients for human myoblast transplantation.

The development of an optimized animal model for the in vivo analysis of human muscle cells remains an important goal in the search of therapy for muscular dystrophy. Here we examined the efficiency of human myoblast xenografts in three distinct immunodeficient mouse models. We found that different conditioning regimes used to provoke host muscle regeneration (i.e., cardiotoxin versus cryodamage) had a marked impact on xenograft success. Tibialis anterior muscle of Rag2-, Rag-/gammac-, and Rag-/gammac-/C5- mice was treated by cardiotoxin or cryodamage, submitted to enzymatic digestion, and analyzed by cytofluorometry to quantitate inflammatory cells. Human myoblasts were injected into pretreated muscles from immunodeficient recipients and the cell engraftment evaluated by immunocytochemistry, 4-8 weeks after transplantation. Donor cell differentiation and dispersion within the host muscles was also investigated. Host regeneration in cardiotoxin-treated mice was accompanied by a higher inflammatory cell infiltration when compared to that induced by cryodamage. Accordingly, when compared to the cardiotoxin group, more human myogenic cells were found after cryodamage. When the distinct immunodeficient mice were compared, we found that the alymphoid strain lacking the complement component C5 (Rag-/gammac-/C5- mice) was the most efficient host for human muscle xenografts, when compared with C5(+)Rag-/gammac- mice or Rag- mice. Our results demonstrate that cryolesion-conditioned muscles of Rag-/gammac-/C5- mice provide the best environment for long-term in vivo human myoblast differentiation, opening the way for a novel approach to study the pathophysiology of human muscle disorders.

Local antilaminin antibody treatment alters the rejection pattern of murine cardiac allografts: correlation between cellular infiltration and extracellular matrix.

BACKGROUND: Emerging data place extracellular matrix (ECM) proteins as important elements in lymphocyte positioning and effector function in alloreactive responses. Using a non-vascularized model of allogeneic heart transplantation in Swiss mice, we have observed a correlation between the cellular infiltration and ECM deposition towards the interior of the graft during the kinetics of rejection. METHODS: To confirm the importance of ECM during the rejection process in this model, we treated the transplanted animals with local injections of antilaminin monoclonal antibody and analyzed, by histology and immunohistochemistry, the grafts on day 15, which corresponds to the peak of cellular infiltration and ECM deposition. RESULTS: The treatment with mAb antilaminin decreased the cellular infiltrate and ECM deposition within the grafts, as compared to controls. Moreover, we found a diminished IFN-gamma, TNF-alpha and IL-2 deposition in the transplant area, and a reduced co-localization of these cytokines with laminin. By contrast, the antilaminin treatment increased tenascin deposition, a molecule with immunosuppressive properties, and also caused an increase in apoptosis of the cellular infiltrate. CONCLUSIONS: These data hallmark the importance of laminin, in distinct aspects concerning the events leading to allograft rejection, and also reinforce this molecule as a potential target for immune intervention in organ transplantation.