OBJECTIVE: In contrast to embryonic stem (ES) cells, which are able to give rise to all cell types of the body, somatic stem cells have been thought to be more limited in their differentiation potential in that they are committed to generate only cells of their tissue of origin. Unexpectedly, some recent data suggest that somatic stem cells isolated from one tissue can also generate cells of heterologous tissues and organs, implying that somatic stem cells have a greater potential for differentiation. METHODS: To explore further the developmental potential of murine neural stem cells (NSCs) we injected cultured NSCs as neurospheres into preimplantation blastocysts and determined the seeding by donor cells in tissues of developing chimeric fetal and adult animals. RESULTS: We frequently detected progeny of injected NSCs both in embryos and in adult animals. In embryos we observed transient seeding of donor cells to hematopoietic tissues and generation of NSC-derived cells that express globin genes and an erythroid-specific cell-surface marker. In adults progeny of NSCs were mostly detected in neural tissues. The observed low level of chimerism of wild-type NSCs was increased if we injected stem cells expressing a bcl-2 transgene, without changing the seeding pattern. CONCLUSION: These results suggest that cultured NSCs, following their injection into blastocysts, generate at mid-gestation erythroid-like cells but later, in adult chimeric mice, engraftment mainly persisted in neural tissues.
OBJECTIVE: In contrast to embryonic stem (ES) cells, which are able to give rise to all cell types of the body, somatic stem cells have been thought to be more limited in their differentiation potential in that they are committed to generate only cells of their tissue of origin. Unexpectedly, some recent data suggest that somatic stem cells isolated from one tissue can also generate cells of heterologous tissues and organs, implying that somatic stem cells have a greater potential for differentiation. METHODS: To explore further the developmental potential of murine neural stem cells (NSCs) we injected cultured NSCs as neurospheres into preimplantation blastocysts and determined the seeding by donor cells in tissues of developing chimeric fetal and adult animals. RESULTS: We frequently detected progeny of injected NSCs both in embryos and in adult animals. In embryos we observed transient seeding of donor cells to hematopoietic tissues and generation of NSC-derived cells that express globin genes and an erythroid-specific cell-surface marker. In adults progeny of NSCs were mostly detected in neural tissues. The observed low level of chimerism of wild-type NSCs was increased if we injected stem cells expressing a bcl-2 transgene, without changing the seeding pattern. CONCLUSION: These results suggest that cultured NSCs, following their injection into blastocysts, generate at mid-gestation erythroid-like cells but later, in adult chimeric mice, engraftment mainly persisted in neural tissues.
Authors: Carolin Schmittwolf; Nicole Kirchhof; Anna Jauch; Michael Dürr; Friedrich Harder; Martin Zenke; Albrecht M Müller Journal: EMBO J Date: 2005-01-20 Impact factor: 11.598
Authors: Hong Xia; Vidya Bodempudi; Alexey Benyumov; Polla Hergert; Damien Tank; Jeremy Herrera; Jeff Braziunas; Ola Larsson; Matthew Parker; Daniel Rossi; Karen Smith; Mark Peterson; Andrew Limper; Jose Jessurun; John Connett; David Ingbar; Sem Phan; Peter B Bitterman; Craig A Henke Journal: Am J Pathol Date: 2014-03-13 Impact factor: 4.307