TY - JOUR
T1 - Regenerating Corticospinal Axons Innervate Phenotypically Appropriate Neurons within Neural Stem Cell Grafts
AU - Kumamaru, Hiromi
AU - Lu, Paul
AU - Rosenzweig, Ephron S.
AU - Kadoya, Ken
AU - Tuszynski, Mark H.
N1 - Funding Information:
We thank L. Graham, E. Staufenberg, J. Conner, and J. Weber for technical assistance; T. Müller and C. Birchmeier, Max-Delbrück-Center for Molecular Medicine, Berlin, Germany, for providing Tlx3 and Lbx1 antibodies; S. Ross, University of Pittsburgh, Pittsburgh, for providing Bhlhlb5 and Prdm8 antibodies; and Lynn Enquist, CNNV, Princeton University, NJ, for providing Cre-dependent HSV-H129ΔTK-tdTomato. Human 566RSC-UBQT neural stem cells were a gift from NeuralStem, Inc. Supported by the Veterans Administration Gordon Mansfield Spinal Cord Injury Consortium (to M.H.T.), the NIH ( NS042291 and EB014986 , to M.H.T.); the Craig H. Neilsen Foundation (to H.K. and K.K.); the Japan Society for the Promotion of Science (to H.K. and K.K.); the Bernard and Anne Spitzer Charitable Trust (to M.H.T.); and the Dr. Miriam and Sheldon G. Adelson Medical Research Foundation (to M.H.T.).
Funding Information:
We thank L. Graham, E. Staufenberg, J. Conner, and J. Weber for technical assistance; T. Müller and C. Birchmeier, Max-Delbrück-Center for Molecular Medicine, Berlin, Germany, for providing Tlx3 and Lbx1 antibodies; S. Ross, University of Pittsburgh, Pittsburgh, for providing Bhlhlb5 and Prdm8 antibodies; and Lynn Enquist, CNNV, Princeton University, NJ, for providing Cre-dependent HSV-H129ΔTK-tdTomato. Human 566RSC-UBQT neural stem cells were a gift from NeuralStem, Inc. Supported by the Veterans Administration Gordon Mansfield Spinal Cord Injury Consortium (to M.H.T.), the NIH (NS042291 and EB014986, to M.H.T.); the Craig H. Neilsen Foundation (to H.K. and K.K.); the Japan Society for the Promotion of Science (to H.K. and K.K.); the Bernard and Anne Spitzer Charitable Trust (to M.H.T.); and the Dr. Miriam and Sheldon G. Adelson Medical Research Foundation (to M.H.T.).
Funding Information:
We thank L. Graham, E. Staufenberg, J. Conner, and J. Weber for technical assistance; T. M?ller and C. Birchmeier, Max-Delbr?ck-Center for Molecular Medicine, Berlin, Germany, for providing Tlx3 and Lbx1 antibodies; S. Ross, University of Pittsburgh, Pittsburgh, for providing Bhlhlb5 and Prdm8 antibodies; and Lynn Enquist, CNNV, Princeton University, NJ, for providing Cre-dependent HSV-H129?TK-tdTomato. Human 566RSC-UBQT neural stem cells were a gift from NeuralStem, Inc. Supported by the Veterans Administration Gordon Mansfield Spinal Cord Injury Consortium (to M.H.T.), the NIH (NS042291 and EB014986, to M.H.T.); the Craig H. Neilsen Foundation (to H.K. and K.K.); the Japan Society for the Promotion of Science (to H.K. and K.K.); the Bernard and Anne Spitzer Charitable Trust (to M.H.T.); and the Dr. Miriam and Sheldon G. Adelson Medical Research Foundation (to M.H.T.).
Publisher Copyright:
© 2019 The Author(s)
PY - 2019/2/26
Y1 - 2019/2/26
N2 - Neural progenitor cell grafts form new relays across sites of spinal cord injury (SCI). Using a panel of neuronal markers, we demonstrate that spinal neural progenitor grafts to sites of rodent SCI adopt diverse spinal motor and sensory interneuronal fates, representing most neuronal subtypes of the intact spinal cord, and spontaneously segregate into domains of distinct cell clusters. Host corticospinal motor axons regenerating into neural progenitor grafts innervate appropriate pre-motor interneurons, based on trans-synaptic tracing with herpes simplex virus. A human spinal neural progenitor cell graft to a non-human primate also received topographically appropriate corticospinal axon regeneration. Thus, grafted spinal neural progenitor cells give rise to a variety of neuronal progeny that are typical of the normal spinal cord; remarkably, regenerating injured adult corticospinal motor axons spontaneously locate appropriate motor domains in the heterogeneous, developing graft environment, without a need for additional exogenous guidance. Kumamaru et al. demonstrate that spinal cord neural progenitor cell grafts spontaneously segregate into motor and sensory domains when implanted into sites of spinal cord injury in rats and primates. Host corticospinal axons regenerating into grafts preferentially regenerate and synapse onto motor interneuron-rich domains, avoiding inappropriate sensory domains.
AB - Neural progenitor cell grafts form new relays across sites of spinal cord injury (SCI). Using a panel of neuronal markers, we demonstrate that spinal neural progenitor grafts to sites of rodent SCI adopt diverse spinal motor and sensory interneuronal fates, representing most neuronal subtypes of the intact spinal cord, and spontaneously segregate into domains of distinct cell clusters. Host corticospinal motor axons regenerating into neural progenitor grafts innervate appropriate pre-motor interneurons, based on trans-synaptic tracing with herpes simplex virus. A human spinal neural progenitor cell graft to a non-human primate also received topographically appropriate corticospinal axon regeneration. Thus, grafted spinal neural progenitor cells give rise to a variety of neuronal progeny that are typical of the normal spinal cord; remarkably, regenerating injured adult corticospinal motor axons spontaneously locate appropriate motor domains in the heterogeneous, developing graft environment, without a need for additional exogenous guidance. Kumamaru et al. demonstrate that spinal cord neural progenitor cell grafts spontaneously segregate into motor and sensory domains when implanted into sites of spinal cord injury in rats and primates. Host corticospinal axons regenerating into grafts preferentially regenerate and synapse onto motor interneuron-rich domains, avoiding inappropriate sensory domains.
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U2 - 10.1016/j.celrep.2019.01.099
DO - 10.1016/j.celrep.2019.01.099
M3 - Article
C2 - 30811984
AN - SCOPUS:85061650723
SN - 2211-1247
VL - 26
SP - 2329-2339.e4
JO - Cell Reports
JF - Cell Reports
IS - 9
ER -