Sustained elevation of MG53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function

MG53 is a protein that regulates the cell membrane repair process, and it’s been suggested that it might play a role in diabetes. Here, the authors demonstrate that circulating MG53 functions as a myokine to facilitate tissue injury-repair and regeneration without impacting glucose handling.

Guardado en:
Detalles Bibliográficos
Autores principales: Zehua Bian, Qiang Wang, Xinyu Zhou, Tao Tan, Ki Ho Park, H. Fritz Kramer, Alan McDougal, Nicholas J. Laping, Sanjay Kumar, T. M. Ayodele Adesanya, Matthew Sermersheim, Frank Yi, Xinxin Wang, Junwei Wu, Kristyn Gumpper, Qiwei Jiang, Duofen He, Pei-Hui Lin, Haichang Li, Fangxia Guan, Jingsong Zhou, Mark J. Kohr, Chunyu Zeng, Hua Zhu, Jianjie Ma
Formato: article
Lenguaje:EN
Publicado: Nature Portfolio 2019
Materias:
Q
Acceso en línea:https://doaj.org/article/e6e90eddc7d9412a80c0edb861c8f4a1
Etiquetas: Agregar Etiqueta
Sin Etiquetas, Sea el primero en etiquetar este registro!
id oai:doaj.org-article:e6e90eddc7d9412a80c0edb861c8f4a1
record_format dspace
spelling oai:doaj.org-article:e6e90eddc7d9412a80c0edb861c8f4a12021-12-02T14:39:03ZSustained elevation of MG53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function10.1038/s41467-019-12483-02041-1723https://doaj.org/article/e6e90eddc7d9412a80c0edb861c8f4a12019-10-01T00:00:00Zhttps://doi.org/10.1038/s41467-019-12483-0https://doaj.org/toc/2041-1723MG53 is a protein that regulates the cell membrane repair process, and it’s been suggested that it might play a role in diabetes. Here, the authors demonstrate that circulating MG53 functions as a myokine to facilitate tissue injury-repair and regeneration without impacting glucose handling.Zehua BianQiang WangXinyu ZhouTao TanKi Ho ParkH. Fritz KramerAlan McDougalNicholas J. LapingSanjay KumarT. M. Ayodele AdesanyaMatthew SermersheimFrank YiXinxin WangJunwei WuKristyn GumpperQiwei JiangDuofen HePei-Hui LinHaichang LiFangxia GuanJingsong ZhouMark J. KohrChunyu ZengHua ZhuJianjie MaNature PortfolioarticleScienceQENNature Communications, Vol 10, Iss 1, Pp 1-16 (2019)
institution DOAJ
collection DOAJ
language EN
topic Science
Q
spellingShingle Science
Q
Zehua Bian
Qiang Wang
Xinyu Zhou
Tao Tan
Ki Ho Park
H. Fritz Kramer
Alan McDougal
Nicholas J. Laping
Sanjay Kumar
T. M. Ayodele Adesanya
Matthew Sermersheim
Frank Yi
Xinxin Wang
Junwei Wu
Kristyn Gumpper
Qiwei Jiang
Duofen He
Pei-Hui Lin
Haichang Li
Fangxia Guan
Jingsong Zhou
Mark J. Kohr
Chunyu Zeng
Hua Zhu
Jianjie Ma
Sustained elevation of MG53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function
description MG53 is a protein that regulates the cell membrane repair process, and it’s been suggested that it might play a role in diabetes. Here, the authors demonstrate that circulating MG53 functions as a myokine to facilitate tissue injury-repair and regeneration without impacting glucose handling.
format article
author Zehua Bian
Qiang Wang
Xinyu Zhou
Tao Tan
Ki Ho Park
H. Fritz Kramer
Alan McDougal
Nicholas J. Laping
Sanjay Kumar
T. M. Ayodele Adesanya
Matthew Sermersheim
Frank Yi
Xinxin Wang
Junwei Wu
Kristyn Gumpper
Qiwei Jiang
Duofen He
Pei-Hui Lin
Haichang Li
Fangxia Guan
Jingsong Zhou
Mark J. Kohr
Chunyu Zeng
Hua Zhu
Jianjie Ma
author_facet Zehua Bian
Qiang Wang
Xinyu Zhou
Tao Tan
Ki Ho Park
H. Fritz Kramer
Alan McDougal
Nicholas J. Laping
Sanjay Kumar
T. M. Ayodele Adesanya
Matthew Sermersheim
Frank Yi
Xinxin Wang
Junwei Wu
Kristyn Gumpper
Qiwei Jiang
Duofen He
Pei-Hui Lin
Haichang Li
Fangxia Guan
Jingsong Zhou
Mark J. Kohr
Chunyu Zeng
Hua Zhu
Jianjie Ma
author_sort Zehua Bian
title Sustained elevation of MG53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function
title_short Sustained elevation of MG53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function
title_full Sustained elevation of MG53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function
title_fullStr Sustained elevation of MG53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function
title_full_unstemmed Sustained elevation of MG53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function
title_sort sustained elevation of mg53 in the bloodstream increases tissue regenerative capacity without compromising metabolic function
publisher Nature Portfolio
publishDate 2019
url https://doaj.org/article/e6e90eddc7d9412a80c0edb861c8f4a1
work_keys_str_mv AT zehuabian sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT qiangwang sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT xinyuzhou sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT taotan sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT kihopark sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT hfritzkramer sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT alanmcdougal sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT nicholasjlaping sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT sanjaykumar sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT tmayodeleadesanya sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT matthewsermersheim sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT frankyi sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT xinxinwang sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT junweiwu sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT kristyngumpper sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT qiweijiang sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT duofenhe sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT peihuilin sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT haichangli sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT fangxiaguan sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT jingsongzhou sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT markjkohr sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT chunyuzeng sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT huazhu sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
AT jianjiema sustainedelevationofmg53inthebloodstreamincreasestissueregenerativecapacitywithoutcompromisingmetabolicfunction
_version_ 1718390804942159872