BACKGROUND: End-organ repair by adult haemopoietic stem cells is under great scrutiny with investigators challenging the notion of these cells' plasticity. Some investigations of animals and short-term human bone marrow transplants suggest that bone marrow can repair brain. We looked for evidence of clinically relevant marrow-derived restorative neurogenesis: long-term, multilineage, neural engraftment that is not the result of cell-fusion events. METHODS: We examined autopsy brain specimens from three sex-mismatched female bone-marrow-transplantation patients, a female control, and a male control. We did immunohistochemistry, fluorescence in-situ hybridisation, and tissue analysis to look for multilineage, donor-derived neurogenesis. FINDINGS: Hippocampal cells containing a Y chromosome were present up to 6 years post-transplant in all three patients. Transgender neurons accounted for 1% of all neurons; there was no evidence of fusion events since only one X chromosome was present. Moreover, transgender astrocytes and microglia made up 1-2% of all glial cells. INTERPRETATION: Postnatal human neuropoiesis happens, and human haemopoietic cells can transdifferentiate into neurons, astrocytes, and microglia in a long-term setting without fusing. Transplantable human haemopoietic cells could serve as a therapeutic source for long-term regenerative neuropoiesis.
BACKGROUND: End-organ repair by adult haemopoietic stem cells is under great scrutiny with investigators challenging the notion of these cells' plasticity. Some investigations of animals and short-term human bone marrow transplants suggest that bone marrow can repair brain. We looked for evidence of clinically relevant marrow-derived restorative neurogenesis: long-term, multilineage, neural engraftment that is not the result of cell-fusion events. METHODS: We examined autopsy brain specimens from three sex-mismatched female bone-marrow-transplantation patients, a female control, and a male control. We did immunohistochemistry, fluorescence in-situ hybridisation, and tissue analysis to look for multilineage, donor-derived neurogenesis. FINDINGS: Hippocampal cells containing a Y chromosome were present up to 6 years post-transplant in all three patients. Transgender neurons accounted for 1% of all neurons; there was no evidence of fusion events since only one X chromosome was present. Moreover, transgender astrocytes and microglia made up 1-2% of all glial cells. INTERPRETATION: Postnatal human neuropoiesis happens, and human haemopoietic cells can transdifferentiate into neurons, astrocytes, and microglia in a long-term setting without fusing. Transplantable human haemopoietic cells could serve as a therapeutic source for long-term regenerative neuropoiesis.
Authors: Eric D Laywell; Sean M Kearns; Tong Zheng; K Amy Chen; Jie Deng; Huan-Xin Chen; Steven N Roper; Dennis A Steindler Journal: J Comp Neurol Date: 2005-12-19 Impact factor: 3.215