Primers Used in This Study.

<div><p>The growing prevalence of methicillin-resistant <i>Staphylococcus aureus</i> (MRSA) infections, coupled with the increasing resistance to existing antibiotics, underscores the critical need for novel therapeutic approaches to combat this pathogen. In this study, the r...

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1. Verfasser:	Jianhua Liao (1393228) (author)
Weitere Verfasser:	Jun Cheng (194158) (author), Baoqing Liu (1508821) (author), Yuzhi Shao (22683349) (author), Chunyan Meng (5993228) (author)
Veröffentlicht:	2025
Schlagworte:	Medicine Microbiology Cell Biology Biotechnology Evolutionary Biology Ecology Science Policy Infectious Diseases Virology Environmental Sciences not elsewhere classified Biological Sciences not elsewhere classified therapeutic strategies aimed novel therapeutic approaches murine infection model div >< p defense mechanisms employed conserved gene encoding compromising membrane stability affect biofilm formation staphylococcus aureus </ reduced bacterial burden improved host survival maintaining mrsa ’ oxidative stress resistance yqhg </ withstand host reduced motility oxidative stress increasing resistance stress adaptation potential target periplasmic protein mrsa virulence mrsa pathogenesis key determinant infected organs increased sensitivity imposed stresses growing prevalence findings highlight existing antibiotics critical need attenuates virulence
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author	Jianhua Liao (1393228)
author2	Jun Cheng (194158) Baoqing Liu (1508821) Yuzhi Shao (22683349) Chunyan Meng (5993228)
author2_role	author author author author
author_facet	Jianhua Liao (1393228) Jun Cheng (194158) Baoqing Liu (1508821) Yuzhi Shao (22683349) Chunyan Meng (5993228)
author_role	author
dc.creator.none.fl_str_mv	Jianhua Liao (1393228) Jun Cheng (194158) Baoqing Liu (1508821) Yuzhi Shao (22683349) Chunyan Meng (5993228)
dc.date.none.fl_str_mv	2025-11-25T18:28:11Z
dc.identifier.none.fl_str_mv	10.1371/journal.pone.0337292.t002
dc.relation.none.fl_str_mv	https://figshare.com/articles/dataset/Primers_Used_in_This_Study_/30713770
dc.rights.none.fl_str_mv	CC BY 4.0 info:eu-repo/semantics/openAccess
dc.subject.none.fl_str_mv	Medicine Microbiology Cell Biology Biotechnology Evolutionary Biology Ecology Science Policy Infectious Diseases Virology Environmental Sciences not elsewhere classified Biological Sciences not elsewhere classified therapeutic strategies aimed novel therapeutic approaches murine infection model div >< p defense mechanisms employed conserved gene encoding compromising membrane stability affect biofilm formation staphylococcus aureus </ reduced bacterial burden improved host survival maintaining mrsa ’ oxidative stress resistance yqhg </ withstand host reduced motility oxidative stress increasing resistance stress adaptation potential target periplasmic protein mrsa virulence mrsa pathogenesis key determinant infected organs increased sensitivity imposed stresses growing prevalence findings highlight existing antibiotics critical need attenuates virulence
dc.title.none.fl_str_mv	Primers Used in This Study.
dc.type.none.fl_str_mv	Dataset info:eu-repo/semantics/publishedVersion dataset
description	<div><p>The growing prevalence of methicillin-resistant <i>Staphylococcus aureus</i> (MRSA) infections, coupled with the increasing resistance to existing antibiotics, underscores the critical need for novel therapeutic approaches to combat this pathogen. In this study, the role of <i>yqhG</i>, a conserved gene encoding a periplasmic protein, in MRSA virulence and stress adaptation was investigated. <i>yqhG</i> deletion in MRSA significantly attenuated virulence in a murine infection model, leading to reduced bacterial burden in infected organs and improved host survival. In vitro, the <i>yqhG</i> mutant exhibited impaired membrane integrity, reduced motility, and increased sensitivity to oxidative stress, but did not affect biofilm formation. These defects were fully restored upon genetic complementation. These findings highlight the critical role of <i>yqhG</i> in maintaining MRSA’s ability to withstand host-imposed stresses, suggesting that <i>yqhG</i> is a key determinant of MRSA pathogenesis. The study provides new insights into the stress-defense mechanisms employed by MRSA and underscores <i>yqhG</i> as a potential target for therapeutic strategies aimed at combating MRSA infections.</p></div>
eu_rights_str_mv	openAccess
id	Manara_24e380d73c7e5b358754c53b4e5cd8e5
identifier_str_mv	10.1371/journal.pone.0337292.t002
network_acronym_str	Manara
network_name_str	ManaraRepo
oai_identifier_str	oai:figshare.com:article/30713770
publishDate	2025
repository.mail.fl_str_mv
repository.name.fl_str_mv
repository_id_str
rights_invalid_str_mv	CC BY 4.0
spelling	Primers Used in This Study.Jianhua Liao (1393228)Jun Cheng (194158)Baoqing Liu (1508821)Yuzhi Shao (22683349)Chunyan Meng (5993228)MedicineMicrobiologyCell BiologyBiotechnologyEvolutionary BiologyEcologyScience PolicyInfectious DiseasesVirologyEnvironmental Sciences not elsewhere classifiedBiological Sciences not elsewhere classifiedtherapeutic strategies aimednovel therapeutic approachesmurine infection modeldiv >< pdefense mechanisms employedconserved gene encodingcompromising membrane stabilityaffect biofilm formationstaphylococcus aureus </reduced bacterial burdenimproved host survivalmaintaining mrsa ’oxidative stress resistanceyqhg </withstand hostreduced motilityoxidative stressincreasing resistancestress adaptationpotential targetperiplasmic proteinmrsa virulencemrsa pathogenesiskey determinantinfected organsincreased sensitivityimposed stressesgrowing prevalencefindings highlightexisting antibioticscritical needattenuates virulence<div><p>The growing prevalence of methicillin-resistant <i>Staphylococcus aureus</i> (MRSA) infections, coupled with the increasing resistance to existing antibiotics, underscores the critical need for novel therapeutic approaches to combat this pathogen. In this study, the role of <i>yqhG</i>, a conserved gene encoding a periplasmic protein, in MRSA virulence and stress adaptation was investigated. <i>yqhG</i> deletion in MRSA significantly attenuated virulence in a murine infection model, leading to reduced bacterial burden in infected organs and improved host survival. In vitro, the <i>yqhG</i> mutant exhibited impaired membrane integrity, reduced motility, and increased sensitivity to oxidative stress, but did not affect biofilm formation. These defects were fully restored upon genetic complementation. These findings highlight the critical role of <i>yqhG</i> in maintaining MRSA’s ability to withstand host-imposed stresses, suggesting that <i>yqhG</i> is a key determinant of MRSA pathogenesis. The study provides new insights into the stress-defense mechanisms employed by MRSA and underscores <i>yqhG</i> as a potential target for therapeutic strategies aimed at combating MRSA infections.</p></div>2025-11-25T18:28:11ZDatasetinfo:eu-repo/semantics/publishedVersiondataset10.1371/journal.pone.0337292.t002https://figshare.com/articles/dataset/Primers_Used_in_This_Study_/30713770CC BY 4.0info:eu-repo/semantics/openAccessoai:figshare.com:article/307137702025-11-25T18:28:11Z
spellingShingle	Primers Used in This Study. Jianhua Liao (1393228) Medicine Microbiology Cell Biology Biotechnology Evolutionary Biology Ecology Science Policy Infectious Diseases Virology Environmental Sciences not elsewhere classified Biological Sciences not elsewhere classified therapeutic strategies aimed novel therapeutic approaches murine infection model div >< p defense mechanisms employed conserved gene encoding compromising membrane stability affect biofilm formation staphylococcus aureus </ reduced bacterial burden improved host survival maintaining mrsa ’ oxidative stress resistance yqhg </ withstand host reduced motility oxidative stress increasing resistance stress adaptation potential target periplasmic protein mrsa virulence mrsa pathogenesis key determinant infected organs increased sensitivity imposed stresses growing prevalence findings highlight existing antibiotics critical need attenuates virulence
status_str	publishedVersion
title	Primers Used in This Study.
title_full	Primers Used in This Study.
title_fullStr	Primers Used in This Study.
title_full_unstemmed	Primers Used in This Study.
title_short	Primers Used in This Study.
title_sort	Primers Used in This Study.
topic	Medicine Microbiology Cell Biology Biotechnology Evolutionary Biology Ecology Science Policy Infectious Diseases Virology Environmental Sciences not elsewhere classified Biological Sciences not elsewhere classified therapeutic strategies aimed novel therapeutic approaches murine infection model div >< p defense mechanisms employed conserved gene encoding compromising membrane stability affect biofilm formation staphylococcus aureus </ reduced bacterial burden improved host survival maintaining mrsa ’ oxidative stress resistance yqhg </ withstand host reduced motility oxidative stress increasing resistance stress adaptation potential target periplasmic protein mrsa virulence mrsa pathogenesis key determinant infected organs increased sensitivity imposed stresses growing prevalence findings highlight existing antibiotics critical need attenuates virulence

Primers Used in This Study.

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