Literature DB >> 28635509

Induced Pluripotent Stem Cell-Derived Dopaminergic Neurons from Adult Common Marmoset Fibroblasts.

Scott C Vermilyea1,2, Scott Guthrie2, Michael Meyer2, Kim Smuga-Otto2,3, Katarina Braun2, Sara Howden3, James A Thomson2,3,4, Su-Chun Zhang5, Marina E Emborg1,2,6, Thaddeus G Golos2,7.   

Abstract

The common marmoset monkey (Callithrix jacchus; Cj) is an advantageous nonhuman primate species for modeling age-related disorders, including Parkinson's disease, due to their shorter life span compared to macaques. Cj-derived induced pluripotent stem cells (Cj-iPSCs) from somatic cells are needed for in vitro disease modeling and testing regenerative medicine approaches. Here we report the development of a novel Cj-iPSC line derived from adult marmoset fibroblasts. The Cj-iPSCs showed potent pluripotency properties, including the development of mesodermal lineages in tumors after injection to immunocompromised mice, as well as ectoderm and endoderm lineages after in vitro differentiation regimens, demonstrating differentiated derivatives of all three embryonic layers. In addition, expression of key pluripotency genes (ZFP42, PODXL, DNMT3B, C-MYC, LIN28, KLF4, NANOG, SOX2, and OCT4) was observed. We then tested the neural differentiation capacity and gene expression profiles of Cj-iPSCs and a marmoset embryonic stem cell line (Cj-ESC) after dual-SMAD inhibition. Exposure to CHIR99021 and sonic hedgehog (SHH) for 12 and 16 days, respectively, patterned the cells toward a ventralized midbrain dopaminergic phenotype, confirmed by expression of FOXA2, OTX2, EN-1, and tyrosine hydroxylase. These results demonstrate that common marmoset stem cells will be able to serve as a platform for investigating regenerative medicine approaches targeting the dopaminergic system.

Entities:  

Keywords:  Parkinson's disease; induced pluripotent stem cells; neural differentiation; nonhuman primate model

Mesh:

Year:  2017        PMID: 28635509      PMCID: PMC5576272          DOI: 10.1089/scd.2017.0069

Source DB:  PubMed          Journal:  Stem Cells Dev        ISSN: 1547-3287            Impact factor:   3.272


  17 in total

1.  Specification of midbrain dopamine neurons from primate pluripotent stem cells.

Authors:  Jiajie Xi; Yan Liu; Huisheng Liu; Hong Chen; Marina E Emborg; Su-Chun Zhang
Journal:  Stem Cells       Date:  2012-08       Impact factor: 6.277

2.  Pluripotent cell lines derived from common marmoset (Callithrix jacchus) blastocysts.

Authors:  J A Thomson; J Kalishman; T G Golos; M Durning; C P Harris; J P Hearn
Journal:  Biol Reprod       Date:  1996-08       Impact factor: 4.285

3.  Directed neural differentiation of induced pluripotent stem cells from non-human primates.

Authors:  Steven L Farnsworth; Zhifang Qiu; Anuja Mishra; Peter J Hornsby
Journal:  Exp Biol Med (Maywood)       Date:  2013-03

4.  Induction of pluripotent stem cells from fibroblast cultures.

Authors:  Kazutoshi Takahashi; Keisuke Okita; Masato Nakagawa; Shinya Yamanaka
Journal:  Nat Protoc       Date:  2007       Impact factor: 13.491

5.  Induced pluripotent stem cell lines derived from human somatic cells.

Authors:  Junying Yu; Maxim A Vodyanik; Kim Smuga-Otto; Jessica Antosiewicz-Bourget; Jennifer L Frane; Shulan Tian; Jeff Nie; Gudrun A Jonsdottir; Victor Ruotti; Ron Stewart; Igor I Slukvin; James A Thomson
Journal:  Science       Date:  2007-11-20       Impact factor: 47.728

6.  Efficient derivation of multipotent neural stem/progenitor cells from non-human primate embryonic stem cells.

Authors:  Hiroko Shimada; Yohei Okada; Keiji Ibata; Hayao Ebise; Shin-ichi Ota; Ikuo Tomioka; Toshihiro Nomura; Takuji Maeda; Kazuhisa Kohda; Michisuke Yuzaki; Erika Sasaki; Masaya Nakamura; Hideyuki Okano
Journal:  PLoS One       Date:  2012-11-14       Impact factor: 3.240

7.  Generating induced pluripotent stem cells from common marmoset (Callithrix jacchus) fetal liver cells using defined factors, including Lin28.

Authors:  Ikuo Tomioka; Takuji Maeda; Hiroko Shimada; Kenji Kawai; Yohei Okada; Hiroshi Igarashi; Ryo Oiwa; Tsuyoshi Iwasaki; Mikio Aoki; Toru Kimura; Seiji Shiozawa; Haruka Shinohara; Hiroshi Suemizu; Erika Sasaki; Hideyuki Okano
Journal:  Genes Cells       Date:  2010-07-28       Impact factor: 1.891

8.  Non-viral generation of marmoset monkey iPS cells by a six-factor-in-one-vector approach.

Authors:  Katharina Debowski; Rita Warthemann; Jana Lentes; Gabriela Salinas-Riester; Ralf Dressel; Daniel Langenstroth; Jörg Gromoll; Erika Sasaki; Rüdiger Behr
Journal:  PLoS One       Date:  2015-03-18       Impact factor: 3.240

9.  Simultaneous Reprogramming and Gene Correction of Patient Fibroblasts.

Authors:  Sara E Howden; John P Maufort; Bret M Duffin; Andrew G Elefanty; Edouard G Stanley; James A Thomson
Journal:  Stem Cell Reports       Date:  2015-11-12       Impact factor: 7.765

10.  piggyBac transposition reprograms fibroblasts to induced pluripotent stem cells.

Authors:  Knut Woltjen; Iacovos P Michael; Paria Mohseni; Ridham Desai; Maria Mileikovsky; Riikka Hämäläinen; Rebecca Cowling; Wei Wang; Pentao Liu; Marina Gertsenstein; Keisuke Kaji; Hoon-Ki Sung; Andras Nagy
Journal:  Nature       Date:  2009-03-01       Impact factor: 49.962
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  9 in total

Review 1.  Stem cell therapy for neurological disorders: A focus on aging.

Authors:  Hung Nguyen; Sydney Zarriello; Alexandreya Coats; Cannon Nelson; Chase Kingsbury; Anna Gorsky; Mira Rajani; Elliot G Neal; Cesar V Borlongan
Journal:  Neurobiol Dis       Date:  2018-09-13       Impact factor: 5.996

2.  Generation of Marmoset Monkey iPSCs with Self-Replicating VEE-mRNAs in Feeder-Free Conditions.

Authors:  Stoyan G Petkov; Rüdiger Behr
Journal:  Methods Mol Biol       Date:  2022

3.  Immortalized common marmoset (Callithrix jacchus) hepatic progenitor cells possess bipotentiality in vitro and in vivo.

Authors:  Zhenglong Guo; Renwei Jing; Quan Rao; Ludi Zhang; Yimeng Gao; Fengyong Liu; Xin Wang; Lijian Hui; HaiFang Yin
Journal:  Cell Discov       Date:  2018-05-15       Impact factor: 10.849

4.  Hepatic Differentiation of Marmoset Embryonic Stem Cells and Functional Characterization of ESC-Derived Hepatocyte-Like Cells.

Authors:  Rajagopal N Aravalli; Daniel P Collins; Joel H Hapke; Andrew T Crane; Clifford J Steer
Journal:  Hepat Med       Date:  2020-02-13

5.  Differentiation of Baboon (Papio anubis) Induced-Pluripotent Stem Cells into Enucleated Red Blood Cells.

Authors:  Emmanuel N Olivier; Kai Wang; Joshua Grossman; Nadim Mahmud; Eric E Bouhassira
Journal:  Cells       Date:  2019-10-19       Impact factor: 6.600

6.  Controlling the Switch from Neurogenesis to Pluripotency during Marmoset Monkey Somatic Cell Reprogramming with Self-Replicating mRNAs and Small Molecules.

Authors:  Stoyan Petkov; Ralf Dressel; Ignacio Rodriguez-Polo; Rüdiger Behr
Journal:  Cells       Date:  2020-11-05       Impact factor: 6.600

Review 7.  Non-human primate pluripotent stem cells for the preclinical testing of regenerative therapies.

Authors:  Ignacio Rodriguez-Polo; Rüdiger Behr
Journal:  Neural Regen Res       Date:  2022-09       Impact factor: 5.135

8.  Standards for Deriving Nonhuman Primate-Induced Pluripotent Stem Cells, Neural Stem Cells and Dopaminergic Lineage.

Authors:  Guang Yang; Hyenjong Hong; April Torres; Kristen E Malloy; Gourav R Choudhury; Jeffrey Kim; Marcel M Daadi
Journal:  Int J Mol Sci       Date:  2018-09-17       Impact factor: 5.923

9.  Non-viral Induction of Transgene-free iPSCs from Somatic Fibroblasts of Multiple Mammalian Species.

Authors:  Sho Yoshimatsu; Mayutaka Nakajima; Aozora Iguchi; Tsukasa Sanosaka; Tsukika Sato; Mari Nakamura; Ryusuke Nakajima; Eri Arai; Mitsuru Ishikawa; Kent Imaizumi; Hirotaka Watanabe; Junko Okahara; Toshiaki Noce; Yuta Takeda; Erika Sasaki; Rüdiger Behr; Kazuya Edamura; Seiji Shiozawa; Hideyuki Okano
Journal:  Stem Cell Reports       Date:  2021-04-01       Impact factor: 7.765
  9 in total

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