Abstract P815: Decoding the Cross-Talk Between Grafted Neural Stem Cells and Host Brain to Predict the Molecular Mechanisms of Stem Cell-Induced Functional Recovery After Stroke

Abstract

Stroke is a leading cause of long-term disability and death in the united states. The development of new therapies for stroke are sorely needed. There is great hope that stem cell therapy will create a paradigm shift in the treatment of stroke patients. A barrier to ensuring clinical success of stem cell therapy is the paucity of understanding of the mechanisms by which stem cells exert their beneficial effects. Using a novel mRNA purification method, we identified 50 genes encoding extracellular space proteins, expressed by human neural stem cells (hNSCs) whose expression positively correlated with functional recovery. In this study, we focus on one of the paracrine factors from grafted hNSCs that correlated best with functional recovery, to investigate its therapeutic potential in promoting recovery after stroke. Male nude rats underwent stroke using the distal middle cerebral artery occlusion (dMCAo) model. One week following stroke, osmotic pumps were prepared and loaded with recombinant MTN-2. The osmotic pumps were inserted into the peri-infarct area and infused recombinant MTN-2 for 5 days. Post-stroke, animals were assessed for functional recovery for 5 weeks using both the Montoya staircase test and the whisker-paw reflex test to assess for forelimb function, dexterity, side bias, and placing deficits. After 5 weeks, brain tissue was isolated to assess glial cell morphology. Brain sections were stained with GFAP and IBA1 to visualize astrocytes and microglia, respectively. Confocal images were processed and analyzed using the Bitplane Imaris image analysis software. Output measurements of number of cells/mm2, cell volume, cell branching, and process length and thickness were obtained to characterize the changes in astrocytic and microglial response to injury and paracrine factor treatment. By identifying paracrine factors that are responsible for the regeneration of brain tissue following implantation of hNSCs in stroke brain, this work will increase the likelihood of successful clinical translation of stem cell therapy for stroke. Moreover, elucidating these molecular pathways important for brain recovery may ultimately identify novel therapeutic targets and offer hope to millions of Americans who live with the devastating effects of stroke.