Literature DB >> 22737183

Making skeletal muscle from progenitor and stem cells: development versus regeneration.

Chen-Ming Fan1, Lydia Li, Michelle E Rozo, Christoph Lepper.   

Abstract

For locomotion, vertebrate animals use the force generated by contractile skeletal muscles. These muscles form an actin/myosin-based biomachinery that is attached to skeletal elements to affect body movement and maintain posture. The mechanics, physiology, and homeostasis of skeletal muscles in normal and disease states are of significant clinical interest. How muscles originate from progenitors during embryogenesis has attracted considerable attention from developmental biologists. How skeletal muscles regenerate and repair themselves after injury by the use of stem cells is an important process to maintain muscle homeostasis throughout lifetime. In recent years, much progress has been made toward uncovering the origins of myogenic progenitors and stem cells as well as the regulation of these cells during development and regeneration.

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Year:  2012        PMID: 22737183      PMCID: PMC3378334          DOI: 10.1002/wdev.30

Source DB:  PubMed          Journal:  Wiley Interdiscip Rev Dev Biol        ISSN: 1759-7684            Impact factor:   5.814


  88 in total

1.  Identification and characterization of a non-satellite cell muscle resident progenitor during postnatal development.

Authors:  Kathryn J Mitchell; Alice Pannérec; Bruno Cadot; Ara Parlakian; Vanessa Besson; Edgar R Gomes; Giovanna Marazzi; David A Sassoon
Journal:  Nat Cell Biol       Date:  2010-01-31       Impact factor: 28.824

2.  Inducible lineage tracing of Pax7-descendant cells reveals embryonic origin of adult satellite cells.

Authors:  Christoph Lepper; Chen-Ming Fan
Journal:  Genesis       Date:  2010-07       Impact factor: 2.487

3.  Wnt7a activates the planar cell polarity pathway to drive the symmetric expansion of satellite stem cells.

Authors:  Fabien Le Grand; Andrew E Jones; Vanessa Seale; Anthony Scimè; Michael A Rudnicki
Journal:  Cell Stem Cell       Date:  2009-06-05       Impact factor: 24.633

4.  Numb promotes an increase in skeletal muscle progenitor cells in the embryonic somite.

Authors:  Aurélie Jory; Isabelle Le Roux; Barbara Gayraud-Morel; Pierre Rocheteau; Michel Cohen-Tannoudji; Ana Cumano; Shahragim Tajbakhsh
Journal:  Stem Cells       Date:  2009-11       Impact factor: 6.277

5.  Myogenin and class II HDACs control neurogenic muscle atrophy by inducing E3 ubiquitin ligases.

Authors:  Viviana Moresi; Andrew H Williams; Eric Meadows; Jesse M Flynn; Matthew J Potthoff; John McAnally; John M Shelton; Johannes Backs; William H Klein; James A Richardson; Rhonda Bassel-Duby; Eric N Olson
Journal:  Cell       Date:  2010-10-01       Impact factor: 41.582

6.  BCL9 is an essential component of canonical Wnt signaling that mediates the differentiation of myogenic progenitors during muscle regeneration.

Authors:  Andrew S Brack; Fabienne Murphy-Seiler; Jasmine Hanifi; Jürgen Deka; Sven Eyckerman; Charles Keller; Michel Aguet; Thomas A Rando
Journal:  Dev Biol       Date:  2009-08-21       Impact factor: 3.582

7.  Embryonic and fetal limb myogenic cells are derived from developmentally distinct progenitors and have different requirements for beta-catenin.

Authors:  David A Hutcheson; Jia Zhao; Allyson Merrell; Malay Haldar; Gabrielle Kardon
Journal:  Genes Dev       Date:  2009-04-03       Impact factor: 11.361

8.  Progenitors of skeletal muscle satellite cells express the muscle determination gene, MyoD.

Authors:  Onur Kanisicak; Julio J Mendez; Shoko Yamamoto; Masakazu Yamamoto; David J Goldhamer
Journal:  Dev Biol       Date:  2009-05-21       Impact factor: 3.582

9.  Adult satellite cells and embryonic muscle progenitors have distinct genetic requirements.

Authors:  Christoph Lepper; Simon J Conway; Chen-Ming Fan
Journal:  Nature       Date:  2009-07-30       Impact factor: 49.962

10.  Relative roles of TGF-beta1 and Wnt in the systemic regulation and aging of satellite cell responses.

Authors:  Morgan E Carlson; Michael J Conboy; Michael Hsu; Laurel Barchas; Jaemin Jeong; Anshu Agrawal; Amanda J Mikels; Smita Agrawal; David V Schaffer; Irina M Conboy
Journal:  Aging Cell       Date:  2009-09-02       Impact factor: 9.304
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  12 in total

Review 1.  Animal regeneration: ancestral character or evolutionary novelty?

Authors:  Jonathan Mw Slack
Journal:  EMBO Rep       Date:  2017-07-26       Impact factor: 8.807

Review 2.  BAF60 A, B, and Cs of muscle determination and renewal.

Authors:  Pier Lorenzo Puri; Mark Mercola
Journal:  Genes Dev       Date:  2012-12-07       Impact factor: 11.361

Review 3.  Circular RNAs in myogenesis.

Authors:  Arundhati Das; Aniruddha Das; Debojyoti Das; Kotb Abdelmohsen; Amaresh C Panda
Journal:  Biochim Biophys Acta Gene Regul Mech       Date:  2019-04-01       Impact factor: 4.490

4.  A series of Cre-ER(T2) drivers for manipulation of the skeletal muscle lineage.

Authors:  Sheryl Southard; SiewHui Low; Lydia Li; Michelle Rozo; Tyler Harvey; Chen-Ming Fan; Christoph Lepper
Journal:  Genesis       Date:  2014-06-03       Impact factor: 2.487

5.  Distinct gene expression dynamics in developing and regenerating crustacean limbs.

Authors:  Chiara Sinigaglia; Alba Almazán; Marie Lebel; Marie Sémon; Benjamin Gillet; Sandrine Hughes; Eric Edsinger; Michalis Averof; Mathilde Paris
Journal:  Proc Natl Acad Sci U S A       Date:  2022-07-01       Impact factor: 12.779

6.  Study on the transcriptional regulatory mechanism of the MyoD1 gene in Guanling bovine.

Authors:  Di Zhou; Houqiang Xu; Wei Chen; Yuanyuan Wang; Ming Zhang; Tao Yang
Journal:  RSC Adv       Date:  2018-04-03       Impact factor: 4.036

7.  Notch signaling genes: myogenic DNA hypomethylation and 5-hydroxymethylcytosine.

Authors:  Jolyon Terragni; Guoqiang Zhang; Zhiyi Sun; Sriharsa Pradhan; Lingyun Song; Gregory E Crawford; Michelle Lacey; Melanie Ehrlich
Journal:  Epigenetics       Date:  2014-03-26       Impact factor: 4.528

8.  Transcriptomic analysis of tail regeneration in the lizard Anolis carolinensis reveals activation of conserved vertebrate developmental and repair mechanisms.

Authors:  Elizabeth D Hutchins; Glenn J Markov; Walter L Eckalbar; Rajani M George; Jesse M King; Minami A Tokuyama; Lauren A Geiger; Nataliya Emmert; Michael J Ammar; April N Allen; Ashley L Siniard; Jason J Corneveaux; Rebecca E Fisher; Juli Wade; Dale F DeNardo; J Alan Rawls; Matthew J Huentelman; Jeanne Wilson-Rawls; Kenro Kusumi
Journal:  PLoS One       Date:  2014-08-20       Impact factor: 3.240

9.  CaMKK2 Suppresses Muscle Regeneration through the Inhibition of Myoblast Proliferation and Differentiation.

Authors:  Cheng Ye; Duo Zhang; Lei Zhao; Yan Li; Xiaohan Yao; Hui Wang; Shengjie Zhang; Wei Liu; Hongchao Cao; Shuxian Yu; Yucheng Wang; Jingjing Jiang; Hui Wang; Xihua Li; Hao Ying
Journal:  Int J Mol Sci       Date:  2016-10-24       Impact factor: 5.923

10.  Assessment of different strategies for scalable production and proliferation of human myoblasts.

Authors:  Min-Wen Jason Chua; Ege Deniz Yildirim; Jun-Hao Elwin Tan; Yan-Jiang Benjamin Chua; Suet-Mei Crystal Low; Suet Lee Shirley Ding; Chun-Wei Li; Zongmin Jiang; Bin Tean Teh; Kang Yu; Ng Shyh-Chang
Journal:  Cell Prolif       Date:  2019-03-19       Impact factor: 6.831
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