In Vitro and In Vivo neuronal differentiation capacity of human adult bone marrow-derived mesenchymal stem cells

Abstract

Discovery of the ability of mesenchymal stem cells (MSCs) to differentiate into cells of non-mesodermal tissues, particularly neuronal cells, have raised the possibility of utilising MSCs in regenerative/reparative therapies for neurological disorders. However, a number of hurdles remain to be resolved. This thesis aims to address some of these issues by investigating the characteristics of bone marrow-derived human MSCs (hMSCs) during long-term culture, the potential of hMSCs to differentiate in vitro toward the neuronal lineage under the influence of cytokines, and the effects of intracerebral transplantation in the hemiparkinsonian rat model.

During expansion culture hMSCs were found to display the expected characteristics of MSC populations, and also constitutively expressed neural and pluripotency markers simultaneously with mesodermal markers. Analysis of hMSC long-term subcultivation revealed an optimal period for commencing neuronal differentiation (first 6-8 passages), and also showed the absence of spontaneous neural differentiation.

Application of neural-inducing cytokines and culture conditions resulted in the generation of an immature neuronal-like phenotype by hMSCs. Through live cell microscopy it was demonstrated for the first time that cytokine-based hMSC neuronal differentiation occurs through active and dynamic cellular processes involving outgrowth and motility of cellular extensions. In addition, single- and multiple-stage cytokine-based strategies for inducing dopaminergic neuronal-like cells from hMSCs were investigated. These studies revealed that FGF-2 and EGF exerted the greatest benefits for hMSC neuronal differentiation.

Undifferentiated and neuronal-primed hMSCs were transplanted intracerebrally into the striatum and substantia nigra of cyclosporine-treated hemiparkinsonian rats. Grafted hMSCs could be clearly identified at 1-day and 7-days post-transplantation; however, grafts were gradually lost over time, with complete absence by 21-days. Co-transplantation with olfactory ensheathing cells, neuronal-priming prior to grafting, and nigral as well as striatal grafting could not provide engraftment and differentiation advantages. Immunohistological analysis demonstrated the presence of innate inflammatory responses (microglia and astrocyte activation) at graft sites, fibronectin deposition by hMSCs, and lack of endogenous host neurogenesis.

The results of my PhD work indicate that cytokine-based culture methods are capable of differentiating hMSCs to an immature neuronal-like phenotype, and host-mediated innate inflammatory responses may be a key contributing factor for the failure of in vivo hMSC engraftment.