Engraftment of human nasal olfactory stem cells restores neuroplasticity in mice with hippocampal lesions
Emmanuel Nivet, … , François Féron, François S. Roman
Emmanuel Nivet, … , François Féron, François S. Roman
Published June 13, 2011
Citation Information: J Clin Invest. 2011;121(7):2808-2820. https://doi.org/10.1172/JCI44489.
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Research Article Neuroscience

Engraftment of human nasal olfactory stem cells restores neuroplasticity in mice with hippocampal lesions

Abstract

Stem cell–based therapy has been proposed as a potential means of treatment for a variety of brain disorders. Because ethical and technical issues have so far limited the clinical translation of research using embryonic/fetal cells and neural tissue, respectively, the search for alternative sources of therapeutic stem cells remains ongoing. Here, we report that upon transplantation into mice with chemically induced hippocampal lesions, human olfactory ecto–mesenchymal stem cells (OE-MSCs) — adult stem cells from human nasal olfactory lamina propria — migrated toward the sites of neural damage, where they differentiated into neurons. Additionally, transplanted OE-MSCs stimulated endogenous neurogenesis, restored synaptic transmission, and enhanced long-term potentiation. Mice that received transplanted OE-MSCs exhibited restoration of learning and memory on behavioral tests compared with lesioned, nontransplanted control mice. Similar results were obtained when OE-MSCs were injected into the cerebrospinal fluid. These data show that OE-MSCs can induce neurogenesis and contribute to restoration of hippocampal neuronal networks via trophic actions. They provide evidence that human olfactory tissue is a conceivable source of nervous system replacement cells. This stem cell subtype may be useful for a broad range of stem cell–related studies.

Authors

Emmanuel Nivet, Michel Vignes, Stéphane D. Girard, Caroline Pierrisnard, Nathalie Baril, Arnaud Devèze, Jacques Magnan, Fabien Lanté, Michel Khrestchatisky, François Féron, François S. Roman

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Figure 5

Human OE-MSCs transplanted into lesioned mouse hippocampi survived, migrated, and differentiated into neurons.

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Human OE-MSCs transplanted into lesioned mouse hippocampi survived, migr...
(A) 5 weeks after transplantation, exogenous GFP+ human OE-MSCs were present in the different fields (CA1, CA3, DG) of the lesioned hippocampus. (B and C) GFP+ human OE-MSCs were mostly found in pyramidal (CA3, B) and granule cell layers (DG, C). (D) Within these layers, a high proportion (69%) of GFP+ human OE-MSCs (green) expressed III–β-tubulin (red) (white arrows in D). (E) High magnification of the merged picture of human GFP+ OE-MSCs (green) expressing III–β-tubulin (red). (F) A small proportion of human GFP+ OE-MSCs (green) expressed MAP2 (white arrow), a marker for mature neurons (red). (G) No GFP+ human OE-MSC (green) was ever found to express the astrocytic marker GFAP (red). (H) 4 weeks after lesioning the right hippocampus, GFP+ OE-MSCs were transplanted into the intact hippocampus (i.e., left hemisphere). At day 0 (D0) after transplantation, cells formed clusters and were only observed within the injection site as a cell cluster (I). At D4 after transplantation, numerous GFP+ cells were observed migrating outside the injection site toward the contralateral lesioned hippocampus (J). At D7 after transplantation, few GFP+ OE-MSCs were observed inside the contralateral hippocampus (K). Scale bars: 250 μm (A); 200 μm (J); 100 μm (B, C, D, F, G, I, and K); 20 μm (E). See also Supplemental Video 3.