TY - JOUR
T1 - Environmental signals regulate lineage choice and temporal maturation of neural stem cells from human embryonic stem cells
AU - Joannides, Alexis J.
AU - Webber, Daniel J.
AU - Raineteau, Olivier
AU - Kelly, Claire
AU - Irvine, Karen Amanda
AU - Watts, Colin
AU - Rosser, Anne E.
AU - Kemp, Paul J.
AU - Blakemore, William F.
AU - Compston, Alastair
AU - Caldwell, Maeve A.
AU - Allen, Nicholas D.
AU - Chandran, Siddharthan
PY - 2007/5/1
Y1 - 2007/5/1
N2 - Human embryonic stem cells (hESCs) are a potential source of defined tissue for cell-based therapies in regenerative neurology. In order for this potential to be realized, there is a need for the evaluation of the behaviour of human embryonic stem cell-derived neural stem cells (hES-NSCs) both in the normal and the injured CNS. Using normal tissue and two experimental models, we examined the response of clinically compatible hES-NSCs to physiological and pathological signals. We demonstrate that the phenotypic potential of a multipotent population of hES-NSCs is influenced by these cues both in vitro and in vivo. hES-NSCs display a temporal profile of neurogenic and gliogenic differentiation, with the generation of mature neurons and glia over 4 weeks in vitro, and 20 weeks in the uninjured rodent brain. However, transplantation into the pathological CNS accelerates maturation and polarizes hES-NSC differentiation potential. This study highlights the role of environmental signals in determining both lineage commitment and temporal maturation of human neural stem cells. Controlled manipulation of environmental signals appropriate to the pathological specificity of the targeted disease will be necessary in the design of therapeutic stem cell-based strategies.
AB - Human embryonic stem cells (hESCs) are a potential source of defined tissue for cell-based therapies in regenerative neurology. In order for this potential to be realized, there is a need for the evaluation of the behaviour of human embryonic stem cell-derived neural stem cells (hES-NSCs) both in the normal and the injured CNS. Using normal tissue and two experimental models, we examined the response of clinically compatible hES-NSCs to physiological and pathological signals. We demonstrate that the phenotypic potential of a multipotent population of hES-NSCs is influenced by these cues both in vitro and in vivo. hES-NSCs display a temporal profile of neurogenic and gliogenic differentiation, with the generation of mature neurons and glia over 4 weeks in vitro, and 20 weeks in the uninjured rodent brain. However, transplantation into the pathological CNS accelerates maturation and polarizes hES-NSC differentiation potential. This study highlights the role of environmental signals in determining both lineage commitment and temporal maturation of human neural stem cells. Controlled manipulation of environmental signals appropriate to the pathological specificity of the targeted disease will be necessary in the design of therapeutic stem cell-based strategies.
KW - Cell transplantation
KW - Human embryonic stem cells
KW - Neural stem cells
KW - Phenotypic potential
KW - Temporal maturation
UR - http://www.scopus.com/inward/record.url?scp=34249659986&partnerID=8YFLogxK
U2 - 10.1093/brain/awm070
DO - 10.1093/brain/awm070
M3 - Article
C2 - 17472984
AN - SCOPUS:34249659986
SN - 0006-8950
VL - 130
SP - 1263
EP - 1275
JO - Brain
JF - Brain
IS - 5
ER -