Literature DB >> 21949375

Grafted human-induced pluripotent stem-cell-derived neurospheres promote motor functional recovery after spinal cord injury in mice.

Satoshi Nori1, Yohei Okada, Akimasa Yasuda, Osahiko Tsuji, Yuichiro Takahashi, Yoshiomi Kobayashi, Kanehiro Fujiyoshi, Masato Koike, Yasuo Uchiyama, Eiji Ikeda, Yoshiaki Toyama, Shinya Yamanaka, Masaya Nakamura, Hideyuki Okano.   

Abstract

Once their safety is confirmed, human-induced pluripotent stem cells (hiPSCs), which do not entail ethical concerns, may become a preferred cell source for regenerative medicine. Here, we investigated the therapeutic potential of transplanting hiPSC-derived neurospheres (hiPSC-NSs) into nonobese diabetic (NOD)-severe combined immunodeficient (SCID) mice to treat spinal cord injury (SCI). For this, we used a hiPSC clone (201B7), established by transducing four reprogramming factors (Oct3/4, Sox2, Klf4, and c-Myc) into adult human fibroblasts. Grafted hiPSC-NSs survived, migrated, and differentiated into the three major neural lineages (neurons, astrocytes, and oligodendrocytes) within the injured spinal cord. They showed both cell-autonomous and noncell-autonomous (trophic) effects, including synapse formation between hiPSC-NS-derived neurons and host mouse neurons, expression of neurotrophic factors, angiogenesis, axonal regrowth, and increased amounts of myelin in the injured area. These positive effects resulted in significantly better functional recovery compared with vehicle-treated control animals, and the recovery persisted through the end of the observation period, 112 d post-SCI. No tumor formation was observed in the hiPSC-NS-grafted mice. These findings suggest that hiPSCs give rise to neural stem/progenitor cells that support improved function post-SCI and are a promising cell source for its treatment.

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Year:  2011        PMID: 21949375      PMCID: PMC3189018          DOI: 10.1073/pnas.1108077108

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  57 in total

1.  Marrow stromal cells form guiding strands in the injured spinal cord and promote recovery.

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Journal:  Proc Natl Acad Sci U S A       Date:  2002-02-19       Impact factor: 11.205

2.  Experimental modeling of spinal cord injury: characterization of a force-defined injury device.

Authors:  Stephen W Scheff; Alexander G Rabchevsky; Isabella Fugaccia; John A Main; James E Lumpp
Journal:  J Neurotrauma       Date:  2003-02       Impact factor: 5.269

Review 3.  Neurotrophic factors, cellular bridges and gene therapy for spinal cord injury.

Authors:  L L Jones; M Oudega; M B Bunge; M H Tuszynski
Journal:  J Physiol       Date:  2001-05-15       Impact factor: 5.182

Review 4.  Mammalian neural stem cells.

Authors:  F H Gage
Journal:  Science       Date:  2000-02-25       Impact factor: 47.728

5.  Protein-based human iPS cells efficiently generate functional dopamine neurons and can treat a rat model of Parkinson disease.

Authors:  Yong-Hee Rhee; Ji-Yun Ko; Mi-Yoon Chang; Sang-Hoon Yi; Dohoon Kim; Chun-Hyung Kim; Jae-Won Shim; A-Young Jo; Byung-Woo Kim; Hyunsu Lee; Suk-Ho Lee; Wonhee Suh; Chang-Hwan Park; Hyun-Chul Koh; Yong-Sung Lee; Robert Lanza; Kwang-Soo Kim; Sang-Hun Lee
Journal:  J Clin Invest       Date:  2011-05-16       Impact factor: 14.808

6.  Spinal cord transplants permit the growth of serotonergic axons across the site of neonatal spinal cord transection.

Authors:  B S Bregman
Journal:  Brain Res       Date:  1987-08       Impact factor: 3.252

7.  Transplantation of in vitro-expanded fetal neural progenitor cells results in neurogenesis and functional recovery after spinal cord contusion injury in adult rats.

Authors:  Y Ogawa; K Sawamoto; T Miyata; S Miyao; M Watanabe; M Nakamura; B S Bregman; M Koike; Y Uchiyama; Y Toyama; H Okano
Journal:  J Neurosci Res       Date:  2002-09-15       Impact factor: 4.164

8.  Platelet-activating factor enhances the expression of vascular endothelial growth factor in normal human astrocytes.

Authors:  Hidemi Yoshida; Tadaatsu Imaizumi; Kunikazu Tanji; Tomoh Matsumiya; Hirotaka Sakaki; Daisuke Kimura; Xue-Fan Cui; Mika Kumagai; Wakako Tamo; Takeo Shibata; Masaharu Hatakeyama; Yoshihiro Sato; Kei Satoh
Journal:  Brain Res       Date:  2002-07-19       Impact factor: 3.252

9.  Involvement of GABA and glycine in recurrent inhibition of spinal motoneurons.

Authors:  S P Schneider; R E Fyffe
Journal:  J Neurophysiol       Date:  1992-08       Impact factor: 2.714

10.  Retinoic-acid-concentration-dependent acquisition of neural cell identity during in vitro differentiation of mouse embryonic stem cells.

Authors:  Yohei Okada; Takuya Shimazaki; Gen Sobue; Hideyuki Okano
Journal:  Dev Biol       Date:  2004-11-01       Impact factor: 3.582
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  181 in total

Review 1.  Delineating nuclear reprogramming.

Authors:  Jolene Ooi; Pentao Liu
Journal:  Protein Cell       Date:  2012-03-31       Impact factor: 14.870

Review 2.  Preclinical studies for induced pluripotent stem cell-based therapeutics.

Authors:  John Harding; Oleg Mirochnitchenko
Journal:  J Biol Chem       Date:  2013-12-20       Impact factor: 5.157

3.  Axonal regeneration of different tracts following transplants of human glial restricted progenitors into the injured spinal cord in rats.

Authors:  Ying Jin; Jed S Shumsky; Itzhak Fischer
Journal:  Brain Res       Date:  2018-02-01       Impact factor: 3.252

4.  Injectable polypeptide hydrogels via methionine modification for neural stem cell delivery.

Authors:  A L Wollenberg; T M O'Shea; J H Kim; A Czechanski; L G Reinholdt; M V Sofroniew; T J Deming
Journal:  Biomaterials       Date:  2018-04-05       Impact factor: 12.479

Review 5.  Transplantation of stem cell-derived astrocytes for the treatment of amyotrophic lateral sclerosis and spinal cord injury.

Authors:  Charles Nicaise; Dinko Mitrecic; Aditi Falnikar; Angelo C Lepore
Journal:  World J Stem Cells       Date:  2015-03-26       Impact factor: 5.326

6.  Allogeneic Neural Stem/Progenitor Cells Derived From Embryonic Stem Cells Promote Functional Recovery After Transplantation Into Injured Spinal Cord of Nonhuman Primates.

Authors:  Hiroki Iwai; Hiroko Shimada; Soraya Nishimura; Yoshiomi Kobayashi; Go Itakura; Keiko Hori; Keigo Hikishima; Hayao Ebise; Naoko Negishi; Shinsuke Shibata; Sonoko Habu; Yoshiaki Toyama; Masaya Nakamura; Hideyuki Okano
Journal:  Stem Cells Transl Med       Date:  2015-05-27       Impact factor: 6.940

7.  3D bioprinter applied picosecond pulsed electric fields for targeted manipulation of proliferation and lineage specific gene expression in neural stem cells.

Authors:  Ross A Petrella; Peter A Mollica; Martina Zamponi; John A Reid; Shu Xiao; Robert D Bruno; Patrick C Sachs
Journal:  J Neural Eng       Date:  2018-05-31       Impact factor: 5.379

Review 8.  Cell transplantation therapies for spinal cord injury focusing on induced pluripotent stem cells.

Authors:  Masaya Nakamura; Hideyuki Okano
Journal:  Cell Res       Date:  2012-12-11       Impact factor: 25.617

9.  Localized delivery of brain-derived neurotrophic factor-expressing mesenchymal stem cells enhances functional recovery following cervical spinal cord injury.

Authors:  Heather M Gransee; Wen-Zhi Zhan; Gary C Sieck; Carlos B Mantilla
Journal:  J Neurotrauma       Date:  2014-12-10       Impact factor: 5.269

10.  Adipose-Derived Stem Cells Expressing the Neurogenin-2 Promote Functional Recovery After Spinal Cord Injury in Rat.

Authors:  Linjun Tang; Xiaocheng Lu; Ronglan Zhu; Tengda Qian; Yi Tao; Kai Li; Jinyu Zheng; Penglai Zhao; Shuai Li; Xi Wang; Lixin Li
Journal:  Cell Mol Neurobiol       Date:  2015-08-18       Impact factor: 5.046
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