Jennifer Mallery scite author profile

Filgratism (granulocyte colony stimulating factor, G-CSF)-mobilized peripheral blood progenitor cells (PBPCs) have replaced bone marrow (BM) as a preferred source of autologous stem cells, in light of the faster hematologic recovery and lesser supportive care requirement exhibited by PBPC transplants. Other hematopoietic stem cells, like the human umbilical cord blood-derived stem cells (hUCBs), and nonhematopoietic stem cells have been shown to improve motor function in rodent models of injury and degenerative disease. In the present study we transplanted either G-CSF-mobilized PBPCs or hUCBs in rats 24 h after permanent middle cerebral artery occlusion (MCAO), and assessed their behavioral abnormalities in spontaneous activity and spontaneous motor asymmetry. In both transplanted groups of rats we observed a significant reduction of the stroke-induced hyperactivity compared with nontransplanted, stroked animals. In addition, transplantation of G-CSF PBPC and hUCB cells prevented the development of extensive motor asymmetry. Our findings raise the possibility that PBPCs could provide a novel transplantation therapy to treat stroke.

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Survival of Rat or Mouse Ventral Mesencephalon Neurons after Cotransplantation with Rat Sertoli Cells in the Mouse Striatum

Shamekh

Newcomb

Mallery

et al. 2005

Cell Transplant

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Transplanting cells across species (xenotransplantation) for the treatment of Parkinson's disease has been considered an option to alleviate ethical concerns and shortage of tissues. However, using this approach leads to decreased cell survival; the xenografted cells are often rejected. Sertoli cells (SCs) are testis-derived cells that provide immunological protection to developing germ cells and can enhance survival of both allografted and xenografted cells. It is not clear whether these cells will maintain their immunosuppressive support of cografted cells if they are transplanted across species. In this study, we investigated the immune modulatory capacity of SCs and the feasibility of xenografting these cells alone or with allografted and xenografted neural tissue. Transplanting xenografts of rat SCs into the mouse striatum with either rat or mouse ventral mesencephalon prevented astrocytic infiltration of the graft site, although all transplants showed activated microglia within the core of the graft. Surviving tyrosine hydroxylase-positive neurons were observed in all conditions, but the size of the grafts was small at best. SCs were found at 1 and 2 weeks posttransplant. However, few SCs were found at 2 months posttransplant. Further investigation is under way to characterize the immune capabilities of SCs in a xenogeneic environment.

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Enhancing tyrosine hydroxylase expression and survival of fetal ventral mesencephalon neurons with rat or porcine Sertoli cells in vitro

et al. 2006

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Formation and Structure of Transplantable Tissue Constructs Generated in Simulated Microgravity from Sertoli Cells and Neuron Precursors

et al. 2004

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Cell transplantation therapy for Parkinson's disease (PD) has received much attention as a potential treatment protocol for this neurodegenerative condition. Although there have been promising successes with this approach, it remains problematic, especially regarding the inability to provide immediate trophic support to the newly grafted cells and the inability to prevent acute and/or long-term graft rejection by the host. To address these issues of cell graftability, we have created a novel tissue construct from isolated rat Sertoli cells (SC) and the NTerra-2 immortalized human neuron precursor cell line (NT2) utilizing NASA-developed simulated microgravity technology. The two cell types were cocultured at a 1:4 (SC/NT2) ratio in the High Aspect Rotating Vessel (HARV) biochamber for 3 days, after which a disc-shaped aggregate (1-4 mm diameter) was formed. Sertoli neuron aggregated cells (SNAC) were collected by gravity sedimentation and processed either for light and electron microscopy or for fluorescent immunocytochemistry. Intra-SNAC clusters of SC and NT2 cells were identified by anti-human mitochondrial protein (huMT-specific for NT2 cells) and cholera toxin subunit B (CTb-specific for SC). There was little evidence of cell death throughout the aggregate and the absence of central necrosis, as might be expected in such a large aggregate in vitro. Ultrastructurally, SC did not express junctional modifications with NT2 cells nor with adjacent SC as is typical of SC in vivo and, in some protocols, in vitro. NT2 cells, however, showed distinct intercellular junction-like densities with adjacent NT2 cells, often defining canaliculi-like channels between the microvillus borders of the cells. The results show that the use of simulated microgravity coculture provides a culture environment suitable for the formation of a unique and viable Sertoli-NT2 (i.e., SNAC) tissue construct displaying intra-aggregate cellular organization. The structural integration of SC with NT2 cells provides a novel transplantable tissue source, which can be tested to determine if SC will suppress rejection of the grafted NT2 cells and provide for their short-and long-term trophic support in situ in the treatment of experimental PD.

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