Exercise Preconditioning Promotes Autophagy to Cooperate for Cardioprotection by Increasing LC3 Lipidation-Associated Proteins

The cardioprotection of exercise preconditioning (EP) has been well documented. EP can be divided into two phases that are the induction of exercise preconditioning (IEP) and the protection of exercise preconditioning (PEP). PEP is characterized by biphasic protection, including early exercise preco...

Full description

Saved in:
Bibliographic Details
Published inFrontiers in physiology Vol. 12; p. 599892
Main Authors Wan, Dong-Feng, Pan, Shan-Shan, Tong, Yi-Shan, Huang, Yue
Format Journal Article
LanguageEnglish
Published Frontiers Media S.A 05.05.2021
Subjects
autophagy-related gene 3
autophagy-related gene 4B
autophagy-related gene 7
cardioprotection
exercise preconditioning
LC3
Physiology
Online AccessGet full text

Cover

Abstract The cardioprotection of exercise preconditioning (EP) has been well documented. EP can be divided into two phases that are the induction of exercise preconditioning (IEP) and the protection of exercise preconditioning (PEP). PEP is characterized by biphasic protection, including early exercise preconditioning (EEP) and late exercise preconditioning (LEP). LC3 lipidation-mediated autophagy plays a pivotal role in cardioprotection. This study aimed to investigate the alterations of LC3 lipidation-associated proteins during EP-induced cardioprotection against myocardial injury induced by exhaustive exercise (EE) was used in a rat model of EP. These rats were subjected to an intermittent exercise consisting of four periods, with each period including 10 min of running at 30 m/min and 0% grade (approximately 75% VO 2max ) followed by 10 min of intermittent rest. A model of EE-induced myocardial injury was developed by subjecting rats to a consecutive running (30 m/min, 0% grade) till exhaustion. Following EEP, the colocalization of LC3 with Atg7 was significantly increased, and LC3-I, LC3-II, LC3-II/LC3-I, Atg7, Atg4B, and Atg3 levels were significantly increased. Atg7, Atg4B, and Atg3 mRNAs were all significantly upregulated, and LC3 mRNAs tended to be higher. Following LEP, Atg4B, and Atg3 levels were significantly increased. Atg7, Atg4B, and Atg3 mRNAs were all significantly upregulated, and LC3 mRNAs tended to be higher. A group of rats were subjected to EEP followed by EE, and the co-localization of LC3 with Atg7 was significantly increased, while LC3-I, LC3-II, LC3-II/LC3-I, Atg7, Atg4B, and Atg3 levels were also significantly increased. Moreover, there was a significant increase in the co-localization of LC3 with Atg7, LC3-I, LC3-II, Atg7, and Atg4B levels during LEP followed by EE. The formation of autophagosome during LEP followed by EE may have been weaker than that during EEP followed by EE due to the lower lipidation of LC3. EP may promote autophagy to maintain cell homeostasis and survival, which cooperates for cardioprotection of alleviating exhaustive exercise-induced myocardial injury by increasing LC3 lipidation-associated proteins. There is a difference between EEP and LEP in terms of the mechanisms of cardioprotection afforded by these respective conditions. The positive regulation of transcription and translation level of LC3 lipidation-associated proteins may all be involved in the mechanism of EEP and LEP, while compared with LEP, the regulation of translation level of EEP is more positively to promote autophagy.
AbstractList The cardioprotection of exercise preconditioning (EP) has been well documented. EP can be divided into two phases that are the induction of exercise preconditioning (IEP) and the protection of exercise preconditioning (PEP). PEP is characterized by biphasic protection, including early exercise preconditioning (EEP) and late exercise preconditioning (LEP). LC3 lipidation-mediated autophagy plays a pivotal role in cardioprotection. This study aimed to investigate the alterations of LC3 lipidation-associated proteins during EP-induced cardioprotection against myocardial injury induced by exhaustive exercise (EE) was used in a rat model of EP. These rats were subjected to an intermittent exercise consisting of four periods, with each period including 10 min of running at 30 m/min and 0% grade (approximately 75% VO 2max ) followed by 10 min of intermittent rest. A model of EE-induced myocardial injury was developed by subjecting rats to a consecutive running (30 m/min, 0% grade) till exhaustion. Following EEP, the colocalization of LC3 with Atg7 was significantly increased, and LC3-I, LC3-II, LC3-II/LC3-I, Atg7, Atg4B, and Atg3 levels were significantly increased. Atg7, Atg4B, and Atg3 mRNAs were all significantly upregulated, and LC3 mRNAs tended to be higher. Following LEP, Atg4B, and Atg3 levels were significantly increased. Atg7, Atg4B, and Atg3 mRNAs were all significantly upregulated, and LC3 mRNAs tended to be higher. A group of rats were subjected to EEP followed by EE, and the co-localization of LC3 with Atg7 was significantly increased, while LC3-I, LC3-II, LC3-II/LC3-I, Atg7, Atg4B, and Atg3 levels were also significantly increased. Moreover, there was a significant increase in the co-localization of LC3 with Atg7, LC3-I, LC3-II, Atg7, and Atg4B levels during LEP followed by EE. The formation of autophagosome during LEP followed by EE may have been weaker than that during EEP followed by EE due to the lower lipidation of LC3. EP may promote autophagy to maintain cell homeostasis and survival, which cooperates for cardioprotection of alleviating exhaustive exercise-induced myocardial injury by increasing LC3 lipidation-associated proteins. There is a difference between EEP and LEP in terms of the mechanisms of cardioprotection afforded by these respective conditions. The positive regulation of transcription and translation level of LC3 lipidation-associated proteins may all be involved in the mechanism of EEP and LEP, while compared with LEP, the regulation of translation level of EEP is more positively to promote autophagy.
The cardioprotection of exercise preconditioning (EP) has been well documented. EP can be divided into two phases that are the induction of exercise preconditioning (IEP) and the protection of exercise preconditioning (PEP). PEP is characterized by biphasic protection, including early exercise preconditioning (EEP) and late exercise preconditioning (LEP). LC3 lipidation-mediated autophagy plays a pivotal role in cardioprotection. This study aimed to investigate the alterations of LC3 lipidation-associated proteins during EP-induced cardioprotection against myocardial injury induced by exhaustive exercise (EE) was used in a rat model of EP. These rats were subjected to an intermittent exercise consisting of four periods, with each period including 10 min of running at 30 m/min and 0% grade (approximately 75% VO2max) followed by 10 min of intermittent rest. A model of EE-induced myocardial injury was developed by subjecting rats to a consecutive running (30 m/min, 0% grade) till exhaustion. Following EEP, the colocalization of LC3 with Atg7 was significantly increased, and LC3-I, LC3-II, LC3-II/LC3-I, Atg7, Atg4B, and Atg3 levels were significantly increased. Atg7, Atg4B, and Atg3 mRNAs were all significantly upregulated, and LC3 mRNAs tended to be higher. Following LEP, Atg4B, and Atg3 levels were significantly increased. Atg7, Atg4B, and Atg3 mRNAs were all significantly upregulated, and LC3 mRNAs tended to be higher. A group of rats were subjected to EEP followed by EE, and the co-localization of LC3 with Atg7 was significantly increased, while LC3-I, LC3-II, LC3-II/LC3-I, Atg7, Atg4B, and Atg3 levels were also significantly increased. Moreover, there was a significant increase in the co-localization of LC3 with Atg7, LC3-I, LC3-II, Atg7, and Atg4B levels during LEP followed by EE. The formation of autophagosome during LEP followed by EE may have been weaker than that during EEP followed by EE due to the lower lipidation of LC3. EP may promote autophagy to maintain cell homeostasis and survival, which cooperates for cardioprotection of alleviating exhaustive exercise-induced myocardial injury by increasing LC3 lipidation-associated proteins. There is a difference between EEP and LEP in terms of the mechanisms of cardioprotection afforded by these respective conditions. The positive regulation of transcription and translation level of LC3 lipidation-associated proteins may all be involved in the mechanism of EEP and LEP, while compared with LEP, the regulation of translation level of EEP is more positively to promote autophagy.
Author Tong, Yi-Shan
Wan, Dong-Feng
Huang, Yue
Pan, Shan-Shan
AuthorAffiliation School of Kinesiology, Shanghai University of Sport , Shanghai , China
AuthorAffiliation_xml – name: School of Kinesiology, Shanghai University of Sport , Shanghai , China
Author_xml – sequence: 1
  givenname: Dong-Feng
  surname: Wan
  fullname: Wan, Dong-Feng
– sequence: 2
  givenname: Shan-Shan
  surname: Pan
  fullname: Pan, Shan-Shan
– sequence: 3
  givenname: Yi-Shan
  surname: Tong
  fullname: Tong, Yi-Shan
– sequence: 4
  givenname: Yue
  surname: Huang
  fullname: Huang, Yue
BookMark eNpVkk1vEzEQhi1UREvpD-DmI5cN_tqNfUGKVgUiRYIDSNwsrz2buNrYi-0gcuG3420qROfiGc87jz3S-xpdhRgAobeUrDiX6v04H855xQijq1YpqdgLdEO7TjREsB9X_-XX6C7nB1JDEEYIfYWuec1aIcQN-nP_G5L1GfDXBDYG54uPwYd9reMxFsh4cypxPpj9GZeI-xhnSKYAHmPCvUnOxzlVnV3m8HDG22ATmLwgdj3HOz97Z5Zms8k5Wl9n3QIv4EN-g16OZspw93Teou8f77_1n5vdl0_bfrNrrBCsNFS2ijHWdYMEkC1rnQGiwFnWUWFHMhgKo6kLOsqZlJITCuAUtE4ZCx3lt2h74bpoHvSc_NGks47G68eLmPbapOLtBFpYQ0dhiV2TUVBOB2bduhKlgs4waSvrw4U1n4Zj_QOEksz0DPq8E_xB7-MvLStNdbIC3j0BUvx5glz00WcL02QCxFPWrOW05WvCWZXSi9SmmHOC8d8zlOjFBvrRBnqxgb7YgP8FwiSqnA
CitedBy_id crossref_primary_10_3389_fphys_2022_910452
crossref_primary_10_1016_j_exger_2021_111508
crossref_primary_10_1016_j_neulet_2024_137629
crossref_primary_10_1016_j_prmcm_2023_100308
crossref_primary_10_1007_s10735_023_10152_7
crossref_primary_10_1007_s10989_021_10323_8
crossref_primary_10_1016_j_biopha_2022_114178
crossref_primary_10_1016_j_fbio_2023_103493
crossref_primary_10_1038_s41598_022_23466_5
crossref_primary_10_3389_fcvm_2022_1015639
crossref_primary_10_3389_fcell_2022_950479
crossref_primary_10_3389_fonc_2022_975758
crossref_primary_10_1007_s10495_022_01752_x
Cites_doi 10.1155/2018/1916841
10.1016/j.amjcard.2014.01.438
10.1097/FJC.0000000000000191
10.5935/abc.20150024
10.1080/15548627.2019.1569925
10.1007/s00395-009-0011-9
10.1155/2019/5697380
10.1089/ars.2019.8009
10.3389/fphys.2018.00571
10.1161/CIRCRESAHA.116.303787
10.1007/s12576-017-0555-7
10.3389/fphar.2019.00175
10.1536/ihj.17-003
10.1161/CIRCRESAHA.110.237339
10.2165/11317870-000000000-00000
10.1152/japplphysiol.00418.2017
10.1016/S0008-6363(02)00334-6
10.1007/s10741-012-9367-2
10.1249/MSS.0000000000000774
10.17161/kjm.v12i3.11797
10.1186/s12576-020-00738-1
10.1146/annurev-biophys-060414-034248
10.1152/japplphysiol.00429.2011
10.1007/BF00581173
10.1080/15548627.2015.1100356
10.1038/nature10758
10.1536/ihj.18-310
10.1055/s-0034-1384545
10.1001/jamacardio.2017.4495
10.1253/circj.CJ-12-0132
10.1101/cshperspect.a029777
10.1016/j.ymeth.2014.11.021
10.1097/FJC.0000000000000572
ContentType Journal Article
Copyright Copyright © 2021 Wan, Pan, Tong and Huang. 2021 Wan, Pan, Tong and Huang
Copyright_xml – notice: Copyright © 2021 Wan, Pan, Tong and Huang. 2021 Wan, Pan, Tong and Huang
DBID AAYXX
CITATION
7X8
5PM
DOA
DOI 10.3389/fphys.2021.599892
DatabaseName CrossRef
MEDLINE - Academic
PubMed Central (Full Participant titles)
DOAJ : Directory of Open Access Journals
DatabaseTitle CrossRef
MEDLINE - Academic
DatabaseTitleList CrossRef
Database_xml – sequence: 1
  dbid: DOA
  name: DOAJ Directory of Open Access Journals
  url: https://www.doaj.org/
  sourceTypes: Open Website
DeliveryMethod fulltext_linktorsrc
EISSN 1664-042X
EndPage 599892
ExternalDocumentID oai_doaj_org_article_4ca1f4c0c70f4131b2cd783089e6a28c
10_3389_fphys_2021_599892
GrantInformation_xml – fundername: National Natural Science Foundation of China
  grantid: 31471136
GroupedDBID 53G
5VS
9T4
AAFWJ
AAKDD
AAYXX
ACGFO
ACGFS
ACXDI
ADBBV
ADRAZ
AENEX
AFPKN
ALMA_UNASSIGNED_HOLDINGS
AOIJS
BCNDV
CITATION
DIK
EMOBN
F5P
GROUPED_DOAJ
GX1
HYE
IAO
IEA
IHR
IHW
ISR
KQ8
M48
M~E
O5R
O5S
OK1
PGMZT
RNS
RPM
7X8
ITC
5PM
ID FETCH-LOGICAL-c442t-185922266b8ee8525dae09edc2614cf0ba1efa004d132888301eed9e5d9ace613
IEDL.DBID RPM
ISSN 1664-042X
IngestDate Fri Oct 04 13:10:26 EDT 2024
Tue Sep 17 21:28:40 EDT 2024
Fri Aug 16 21:29:31 EDT 2024
Thu Sep 26 17:26:39 EDT 2024
IsDoiOpenAccess true
IsOpenAccess true
IsPeerReviewed true
IsScholarly true
Language English
License This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
LinkModel DirectLink
MergedId FETCHMERGED-LOGICAL-c442t-185922266b8ee8525dae09edc2614cf0ba1efa004d132888301eed9e5d9ace613
Notes ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
Reviewed by: Lu Qin, Penn State Milton S. Hershey Medical Center, United States; Robin Ketteler, University College London, United Kingdom; Junbao Du, Peking University First Hospital, China
This article was submitted to Exercise Physiology, a section of the journal Frontiers in Physiology
Edited by: Jianhua Li, Pennsylvania State University College of Medicine, United States
OpenAccessLink https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8131968/
PMID 34025444
PQID 2531537032
PQPubID 23479
PageCount 1
ParticipantIDs doaj_primary_oai_doaj_org_article_4ca1f4c0c70f4131b2cd783089e6a28c
pubmedcentral_primary_oai_pubmedcentral_nih_gov_8131968
proquest_miscellaneous_2531537032
crossref_primary_10_3389_fphys_2021_599892
PublicationCentury 2000
PublicationDate 2021-05-05
PublicationDateYYYYMMDD 2021-05-05
PublicationDate_xml – month: 05
  year: 2021
  text: 2021-05-05
  day: 05
PublicationDecade 2020
PublicationTitle Frontiers in physiology
PublicationYear 2021
Publisher Frontiers Media S.A
Publisher_xml – name: Frontiers Media S.A
References Minamino (ref20) 2012; 76
Agrotis (ref1) 2019; 15
Parra (ref22) 2015; 65
Brosnan (ref3) 2014; 113
Li (ref16) 2018; 9
Yuan (ref31) 2018; 2018
Gottlieb (ref8) 2013; 18
Klionsky (ref13) 2016; 12
Pattison (ref23) 2011; 109
Penna (ref24) 2020; 32
Lee (ref15) 2017; 67
Powers (ref25) 2017; 123
Gottlieb (ref7) 2009; 104
Zhang (ref33) 2019; 10
Borges (ref2) 2015; 105
Domenech (ref5) 2002; 55
Halling (ref9) 2017; 7
Li (ref17) 2019; 60
Lee (ref14) 2016; 48
He (ref10) 2012; 481
Yuan (ref30) 2018; 71
Tung (ref29) 2019; 12
Kavazis (ref12) 2009; 39
Lu (ref19) 2018; 59
Shepherd (ref26) 1976; 362
Noda (ref21) 2015; 44
Gottlieb (ref6) 2015; 116
Liu (ref18) 2019; 2019
Thijssen (ref28) 2018; 3
Yuan (ref32) 2020; 70
Smuder (ref27) 2011; 111
Jiang (ref11) 2015; 75
Chang (ref4) 2014; 36
References_xml – volume: 2018
  start-page: 1916841
  year: 2018
  ident: ref31
  article-title: H2O2 signaling-triggered PI3K mediates mitochondrial protection to participate in early cardioprotection by exercise preconditioning
  publication-title: Oxidative Med. Cell. Longev.
  doi: 10.1155/2018/1916841
  contributor:
    fullname: Yuan
– volume: 113
  start-page: 1567
  year: 2014
  ident: ref3
  article-title: Comparison of frequency of significant electrocardiographic abnormalities in endurance versus nonendurance athletes
  publication-title: Am. J. Cardiol.
  doi: 10.1016/j.amjcard.2014.01.438
  contributor:
    fullname: Brosnan
– volume: 65
  start-page: 276
  year: 2015
  ident: ref22
  article-title: Exercise preconditioning of myocardial infarct size in dogs is triggered by calcium
  publication-title: J. Cardiovasc. Pharmacol.
  doi: 10.1097/FJC.0000000000000191
  contributor:
    fullname: Parra
– volume: 105
  start-page: 71
  year: 2015
  ident: ref2
  article-title: Mechanisms involved in exercise-induced cardioprotection: a systematic review
  publication-title: Arq. Bras. Cardiol.
  doi: 10.5935/abc.20150024
  contributor:
    fullname: Borges
– volume: 15
  start-page: 976
  year: 2019
  ident: ref1
  article-title: Redundancy of human ATG4 protease isoforms in autophagy and LC3/GABARAP processing revealed in cells
  publication-title: Autophagy
  doi: 10.1080/15548627.2019.1569925
  contributor:
    fullname: Agrotis
– volume: 104
  start-page: 169
  year: 2009
  ident: ref7
  article-title: Cardioprotection requires taking out the trash
  publication-title: Basic Res. Cardiol.
  doi: 10.1007/s00395-009-0011-9
  contributor:
    fullname: Gottlieb
– volume: 2019
  start-page: 1
  year: 2019
  ident: ref18
  article-title: Late exercise preconditioning promotes autophagy against exhaustive exercise-induced myocardial injury through the activation of the AMPK-mTOR-ULK1 pathway
  publication-title: Biomed. Res. Int.
  doi: 10.1155/2019/5697380
  contributor:
    fullname: Liu
– volume: 32
  start-page: 1115
  year: 2020
  ident: ref24
  article-title: Mechanisms involved in cardioprotection induced by physical exercise
  publication-title: Antioxid. Redox Signal.
  doi: 10.1089/ars.2019.8009
  contributor:
    fullname: Penna
– volume: 9
  start-page: 571
  year: 2018
  ident: ref16
  article-title: Beneficial autophagic activities, mitochondrial function, and metabolic phenotype adaptations promoted by high-intensity interval training in a rat model
  publication-title: Front. Physiol.
  doi: 10.3389/fphys.2018.00571
  contributor:
    fullname: Li
– volume: 116
  start-page: 504
  year: 2015
  ident: ref6
  article-title: Untangling autophagy measurements: all fluxed up
  publication-title: Circ. Res.
  doi: 10.1161/CIRCRESAHA.116.303787
  contributor:
    fullname: Gottlieb
– volume: 67
  start-page: 639
  year: 2017
  ident: ref15
  article-title: Potential signaling pathways of acute endurance exercise-induced cardiac autophagy and mitophagy and its possible role in cardioprotection
  publication-title: J. Physiol. Sci.
  doi: 10.1007/s12576-017-0555-7
  contributor:
    fullname: Lee
– volume: 10
  start-page: 175
  year: 2019
  ident: ref33
  article-title: Trimetazidine attenuates exhaustive exercise-induced myocardial injury in rats via regulation of the Nrf2/NF-kappaB signaling pathway
  publication-title: Front. Pharmacol.
  doi: 10.3389/fphar.2019.00175
  contributor:
    fullname: Zhang
– volume: 59
  start-page: 1106
  year: 2018
  ident: ref19
  article-title: Alterations of cardiac KATP channels and autophagy contribute in the late cardioprotective phase of exercise preconditioning
  publication-title: Int. Heart J.
  doi: 10.1536/ihj.17-003
  contributor:
    fullname: Lu
– volume: 109
  start-page: 151
  year: 2011
  ident: ref23
  article-title: Atg7 induces basal autophagy and rescues autophagic deficiency in CryABR120G cardiomyocytes
  publication-title: Circ. Res.
  doi: 10.1161/CIRCRESAHA.110.237339
  contributor:
    fullname: Pattison
– volume: 39
  start-page: 923
  year: 2009
  ident: ref12
  article-title: Exercise preconditioning of the myocardium
  publication-title: Sports Med.
  doi: 10.2165/11317870-000000000-00000
  contributor:
    fullname: Kavazis
– volume: 123
  start-page: 460
  year: 2017
  ident: ref25
  article-title: Exercise: teaching myocytes new tricks
  publication-title: J. Appl. Physiol.
  doi: 10.1152/japplphysiol.00418.2017
  contributor:
    fullname: Powers
– volume: 55
  start-page: 561
  year: 2002
  ident: ref5
  article-title: Exercise induces early and late myocardial preconditioning in dogs
  publication-title: Cardiovasc. Res.
  doi: 10.1016/S0008-6363(02)00334-6
  contributor:
    fullname: Domenech
– volume: 18
  start-page: 575
  year: 2013
  ident: ref8
  article-title: Autophagy: an affair of the heart
  publication-title: Heart Fail. Rev.
  doi: 10.1007/s10741-012-9367-2
  contributor:
    fullname: Gottlieb
– volume: 48
  start-page: 219
  year: 2016
  ident: ref14
  article-title: Cardiac kinetophagy coincides with activation of anabolic signaling
  publication-title: Med. Sci. Sports Exerc.
  doi: 10.1249/MSS.0000000000000774
  contributor:
    fullname: Lee
– volume: 12
  start-page: 80
  year: 2019
  ident: ref29
  article-title: Significance of new, isolated T-wave inversion in multiple electrocardiogram leads with regadenoson injection in patients with normal myocardial perfusion imaging an observational report of 5 consecutive cases
  publication-title: Kans. J. Med.
  doi: 10.17161/kjm.v12i3.11797
  contributor:
    fullname: Tung
– volume: 70
  start-page: 1
  year: 2020
  ident: ref32
  article-title: Altered expression levels of autophagy-associated proteins during exercise preconditioning indicate the involvement of autophagy in cardioprotection against exercise-induced myocardial injury
  publication-title: J. Physiol. Sci.
  doi: 10.1186/s12576-020-00738-1
  contributor:
    fullname: Yuan
– volume: 44
  start-page: 101
  year: 2015
  ident: ref21
  article-title: Mechanisms of autophagy
  publication-title: Annu. Rev. Biophys.
  doi: 10.1146/annurev-biophys-060414-034248
  contributor:
    fullname: Noda
– volume: 111
  start-page: 1190
  year: 2011
  ident: ref27
  article-title: Exercise protects against doxorubicin-induced markers of autophagy signaling in skeletal muscle
  publication-title: J. Appl. Physiol.
  doi: 10.1152/japplphysiol.00429.2011
  contributor:
    fullname: Smuder
– volume: 362
  start-page: 219
  year: 1976
  ident: ref26
  article-title: Oxygen uptake of rats at different work intensities
  publication-title: Pflugers Arch.
  doi: 10.1007/BF00581173
  contributor:
    fullname: Shepherd
– volume: 12
  start-page: 1
  year: 2016
  ident: ref13
  article-title: Guidelines for the use and interpretation of assays for monitoring autophagy (3rd Edn.)
  publication-title: Autophagy
  doi: 10.1080/15548627.2015.1100356
  contributor:
    fullname: Klionsky
– volume: 481
  start-page: 511
  year: 2012
  ident: ref10
  article-title: Exercise-induced BCL2-regulated autophagy is required for muscle glucose homeostasis
  publication-title: Nature
  doi: 10.1038/nature10758
  contributor:
    fullname: He
– volume: 60
  start-page: 419
  year: 2019
  ident: ref17
  article-title: Changes in autophagy levels in rat myocardium during exercise preconditioning-initiated cardioprotective effects
  publication-title: Int. Heart J.
  doi: 10.1536/ihj.18-310
  contributor:
    fullname: Li
– volume: 36
  start-page: 1
  year: 2014
  ident: ref4
  article-title: Exhaustive exercise-induced cardiac conduction system injury and changes of cTnT and Cx43
  publication-title: Int. J. Sports Med.
  doi: 10.1055/s-0034-1384545
  contributor:
    fullname: Chang
– volume: 3
  start-page: 169
  year: 2018
  ident: ref28
  article-title: Association of exercise Preconditioning with immediate cardioprotection: a review
  publication-title: JAMA Cardiol.
  doi: 10.1001/jamacardio.2017.4495
  contributor:
    fullname: Thijssen
– volume: 76
  start-page: 1074
  year: 2012
  ident: ref20
  article-title: Cardioprotection from ischemia/reperfusion injury: basic and translational research
  publication-title: Circ. J.
  doi: 10.1253/circj.CJ-12-0132
  contributor:
    fullname: Minamino
– volume: 7
  start-page: a029777
  year: 2017
  ident: ref9
  article-title: Autophagy-dependent beneficial effects of exercise
  publication-title: Cold Spring Harb. Perspect. Med.
  doi: 10.1101/cshperspect.a029777
  contributor:
    fullname: Halling
– volume: 75
  start-page: 13
  year: 2015
  ident: ref11
  article-title: LC3‐ and p62-based biochemical methods for the analysis of autophagy progression in mammalian cells
  publication-title: Methods
  doi: 10.1016/j.ymeth.2014.11.021
  contributor:
    fullname: Jiang
– volume: 71
  start-page: 303
  year: 2018
  ident: ref30
  article-title: Parkin mediates mitophagy to participate in cardioprotection induced by late exercise preconditioning but Bnip3 does not
  publication-title: J. Cardiovasc. Pharmacol.
  doi: 10.1097/FJC.0000000000000572
  contributor:
    fullname: Yuan
SSID ssj0000402001
Score 2.3729596
Snippet The cardioprotection of exercise preconditioning (EP) has been well documented. EP can be divided into two phases that are the induction of exercise...
SourceID doaj
pubmedcentral
proquest
crossref
SourceType Open Website
Open Access Repository
Aggregation Database
StartPage 599892
SubjectTerms autophagy-related gene 3
autophagy-related gene 4B
autophagy-related gene 7
cardioprotection
exercise preconditioning
LC3
Physiology
SummonAdditionalLinks – databaseName: DOAJ : Directory of Open Access Journals
  dbid: DOA
  link: http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwrV1LS8QwEA7iyYsoKq4vIngSqmmadpvjuigiKh4UvJU0D_XSiu4evPjb_SbtyvbkxWNfecw038yXDDOMnRQK3F-5AG4Crqq0FQm8jJCEzEkvdC2KQFsDd_fF9ZO6ec6fl0p9UUxYlx64E9y5siYNygo7FgGAm9bSunGZiVL7wsjSRvRN8yUyFTGYaJFIu2NMsDB9HminAHxQpmc5KIaWA0MU8_UPnMxhiOSSzbnaYOu9s8gn3SA32Ypvttj3ZV8liT9ENuve-j1VXFNonf_kkzmlCzAvX3zW8mnbvlPmZM_hn_JpjD_tszPgO15_cWAEhaZTE7fTjFM5667SUrJQnnfUOBXG_NxmT1eXj9PrpK-ikFil5CyBQdZwAoqiLr0vc5k7AyVgZuBOygZRm9QHA4k5EFPwYax42E3tc6eN9bD2O2y1aRu_y7gTIYOHaAFKIDrOaJnW4HAyeJOFwmUjdroQafXeJcuoQDJI_lWUf0Xyrzr5j9gFCf33RcpzHW9A-1Wv_eov7Y_Y8UJlFdYFHXaYxrdz9ARwyTPgGToaD3Q56HH4pHl7jRm2y5SQqdz7jyHuszWadQySzA_Y6uxj7g_hyMzqo_jP_gDTOvVc
  priority: 102
  providerName: Directory of Open Access Journals
– databaseName: Scholars Portal Open Access Journals
  dbid: M48
  link: http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwjV1La9wwEBYhveQSUtqQTdqiQE8BJ7Ysa-1DKNslYSndkEMW9mZkPZJAsJN9QPeS395vZG-pIYcc_ZKsGWnm-6RhhrHvSoL7S-vBTcBVZWHiCCjDRz61wsVFFStPWwPTGzWZyV_zbL7DtuWtOgEu36R2VE9qtng6__Oy-YEFf0mME_72wtMmAKieSM4zsIcCFvmDkKmkCT_t0H4wzMSVQkHkRCkKvxDz9pzz7VZ6niok9O-h0H4M5X9O6fqA7Xdoko9a9X9kO67-xF6vujJK_DbQXfvYbbrimmLv3JKP1pRPQN9v-Krh4wZDpowRHACWj0OAape-Ad_xasNhRCh2nZr4PU451btuSzFFW-06S41T5czlZza7vrobT6KuzEJkpBSrCB67AEpQqsqdyzORWQ0tYWQgV9L4uNKJ8xrSs2CuIMwwCXCshctsoY0DHDhku3VTuyPGbexTQEgDqwUmZHUhkgokT3inU69sOmBnW5GWz202jRIshORfBvmXJP-ylf-A_SSh_3uREmGHG83ivuzWVSmNTrw0sRnGHv44qYSxQ_xiXjilRW4G7HSrshILh05DdO2aNXqC9clSGDx0NOzpstdj_0n9-BBScOcJma78-B2tn7A9GlQIksy-sN3VYu2-Asisqm9hev4FL0b03A
  priority: 102
  providerName: Scholars Portal
Title Exercise Preconditioning Promotes Autophagy to Cooperate for Cardioprotection by Increasing LC3 Lipidation-Associated Proteins
URI https://search.proquest.com/docview/2531537032
https://pubmed.ncbi.nlm.nih.gov/PMC8131968
https://doaj.org/article/4ca1f4c0c70f4131b2cd783089e6a28c
Volume 12
hasFullText 1
inHoldings 1
isFullTextHit
isPrint
link http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1LT9wwELZgT70gEK26hSJX6qlSdpPYycZHiECo6lYcisQtcvyAlUqyWnYPXPjt_cZJ0ObaS6Q8HD8-Z2Y-ezLD2PdcgvtL68FNwFWlMnEEK8NHXtjUxaqOc09LA8vf-e29_PmQPRywbPgXJjjtm3o1a_4-z5rVU_CtXD-b-eAnNr9blkVCE6eYH7LDhRB7FD2IX2JEcdLtYIKAqbmnRQJQwTSZZWAXijLYCBmCc8mROgpR-0em5thRck_z3Byzo95k5Jdd007YgWtO2dt1nyuJ3wVOa1f9yirOycHOvfDLHQUN0I-vfNvysm3XFD_ZcVipvAxeqH2MBpTj9SuHpCAHdXrFr1JwSmrd5VuKBgidpZdTesyXj-z-5vpPeRv1uRQiI2W6jaCWFUyBPK8L54oszawGFOgZGJQ0Pq514rzG4FnQU7BifPfQnsplVmnjoPM_sUnTNu4z4zb2AnaigWgC3bFapUkNJpd6p4XPrZiyH8OQVusuZEYFqkFQVAGKiqCoOiim7IoG_f1BinYdLrSbx6rHvJJGJ16a2CxiD6Wb1KmxCzSxUC7XaWGm7NsAWYWvg7Y8dOPaHWqCiMkEpBoqWoywHNU4voNpF-Js99Psy3-XPGMfqKvBPzI7Z5PtZue-wobZ1heB--O4lMVFmL__AMjS96Q
link.rule.ids 230,315,733,786,790,870,891,2115,24346,27957,27958,53827,53829
linkProvider National Library of Medicine
linkToHtml http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV3JbtRAEG2FcIALiwAxrI3ECckeL22PfQxWogFmohwSlJvVaxhB7FHiOYQD386rto1ibnD02m2_7qp67ecqxt7nAtxfGAduAq4qSh0FiDJc4FKT2KhUUe5oaWB9nC_PxOfz7HyPZeO_MF60r9UmbH5chs3mm9dWbi_1fNSJzU_WVRHTwCnmd9hdzNdkcYukewNMnCiK-2-YoGDl3NEyAchgEocZ-EVJNWxS4dNziYlD8nn7J8HmVCp5y_ccPWRfx173kpPv4a5Tof75V0LHf36sR-zBEI3yg_7wY7Znmyfs1-FQhomfeLpsNsOiLbZJu2ev-cGO8hHIixvetbxq2y2lZrYcATCvvMB1SP-A67i64TBCpH2nW6yqlFO97L6UUzCODmvo5lR58_opOzs6PK2WwVCmIdBCJF0Aj18iyshzVVhbZElmJFDGKwM5E9pFSsbWSaBiwHxBuGFS4JhLm5lSaotw4hnbb9rGPmfcRC5FCKph9cCkjCyTWIEkJs7K1OUmnbEPI1b1ts_GUYPFEMa1x7gmjOse4xn7SGj-OZESafsd7dVFPbz3WmgZO6EjvYgc_HmsEm0W6GJR2lwmhZ6xd-NYqDHx6GuKbGy7Q0uwXlkKg4mGFpNBMmlxegTQ-xTeA9Qv_vvKt-ze8nS9qlefjr-8ZPfpsb0MM3vF9rurnX2NUKlTb_zE-A0G3xfg
linkToPdf http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1Lb9QwELagSIgLDwFieRqJE1KyeTjZ-FhCVwXaag9UqrhEjh_tCpqs2uyhHPjtfOMkaMOxxyROHOezZ-ZzRt8w9iEX4P7COHATcFUhdRQgynCBS01iI1lHuaOtgeOT_PBUfD3LznZKffmkfV2vw-bXZdisL3xu5eZSz8c8sfnquCximjjFfGPc_C67hzWbyB2i7o0w8aIo7v9jgobJuaOtAhDCJA4zcAxJdWxS4SW6xMQpee3-ScA5TZfc8T_LR-zH-OZ92snPcNvVof79n6jjrYb2mD0colK-3zd5wu7Y5in7czCUY-IrT5vNeti8xTHl8Nlrvr8lXQJ1fsO7lpdtuyGJZssRCPPSJ7oOMhC4j9c3HMaIcuDpEUdlyqludl_SKRhniTX0cKrAef2MnS4PvpeHwVCuIdBCJF0Azy8RbeR5XVhbZElmFNDGZwNJE9pFtYqtU0DGgAGDeMO0wEFLmxmptEVY8ZztNW1jXzBuIpciFNWwfmBURskkrkEWE2dV6nKTztjHEa9q06tyVGAzhHPlca4I56rHecY-EaL_GpKgtj_RXp1Xw7evhFaxEzrSi8jBr8d1os0Cr1hIm6uk0DP2fpwPFRYg_VVRjW236AlWLEthONHRYjJRJj1OrwB-L-U9wP3y1ne-Y_dXn5fV0ZeTb6_YAxq1z8bMXrO97mpr3yBi6uq3fm38BaTWGmA
openUrl ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=Exercise+Preconditioning+Promotes+Autophagy+to+Cooperate+for+Cardioprotection+by+Increasing+LC3+Lipidation-Associated+Proteins&rft.jtitle=Frontiers+in+physiology&rft.au=Wan%2C+Dong-Feng&rft.au=Pan%2C+Shan-Shan&rft.au=Tong%2C+Yi-Shan&rft.au=Huang%2C+Yue&rft.date=2021-05-05&rft.issn=1664-042X&rft.eissn=1664-042X&rft.volume=12&rft.spage=599892&rft.epage=599892&rft_id=info:doi/10.3389%2Ffphys.2021.599892&rft.externalDBID=NO_FULL_TEXT
thumbnail_l http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=1664-042X&client=summon
thumbnail_m http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=1664-042X&client=summon
thumbnail_s http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=1664-042X&client=summon