Integrity of genome and polarity in bacteria
Publications
3888256
EQYY
chicago-author-date
50
date
desc
year
14240
https://www.i2bc.paris-saclay.fr/wp-content/plugins/zotpress/
%7B%22status%22%3A%22success%22%2C%22updateneeded%22%3Afalse%2C%22instance%22%3A%22zotpress-cb24e5b1b9ba1d1cd4eaaa57950ac22f%22%2C%22meta%22%3A%7B%22request_last%22%3A0%2C%22request_next%22%3A0%2C%22used_cache%22%3Atrue%7D%2C%22data%22%3A%5B%7B%22key%22%3A%22FEUWQFVI%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Shen%20et%20al.%22%2C%22parsedDate%22%3A%222023-02-11%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EShen%2C%20Minjia%2C%20Kelly%20Goldlust%2C%20Sandra%20Daniel%2C%20Christian%20Lesterlin%2C%20and%20Yoshiharu%20Yamaichi.%202023.%20%26%23x201C%3BRecipient%20UvrD%20Helicase%20Is%20Involved%20in%20Single-%20to%20Double-Stranded%20DNA%20Conversion%20during%20Conjugative%20Plasmid%20Transfer.%26%23x201D%3B%20%3Ci%3ENucleic%20Acids%20Research%3C%5C%2Fi%3E%2C%20February%2C%20gkad075.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgkad075%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgkad075%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Recipient%20UvrD%20helicase%20is%20involved%20in%20single-%20to%20double-stranded%20DNA%20conversion%20during%20conjugative%20plasmid%20transfer%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Minjia%22%2C%22lastName%22%3A%22Shen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Kelly%22%2C%22lastName%22%3A%22Goldlust%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sandra%22%2C%22lastName%22%3A%22Daniel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Christian%22%2C%22lastName%22%3A%22Lesterlin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%5D%2C%22abstractNote%22%3A%22Dissemination%20of%20antibiotic%20resistance%2C%20a%20current%20societal%20challenge%2C%20is%20often%20driven%20by%20horizontal%20gene%20transfer%20through%20bacterial%20conjugation.%20During%20conjugative%20plasmid%20transfer%2C%20single-stranded%20%28ss%29%20DNA%20is%20transferred%20from%20the%20donor%20to%20the%20recipient%20cell.%20Subsequently%2C%20a%20complete%20double-stranded%20%28ds%29%20plasmid%20molecule%20is%20generated%20and%20plasmid-encoded%20genes%20are%20expressed%2C%20allowing%20successful%20establishment%20of%20the%20transconjugant%20cell.%20Such%20dynamics%20of%20transmission%20can%20be%20modulated%20by%20host-%20or%20plasmid-encoded%20factors%2C%20either%20in%20the%20donor%20or%20in%20the%20recipient%20cell.%20We%20applied%20transposon%20insertion%20sequencing%20to%20identify%20host-encoded%20factors%20that%20affect%20conjugative%20transfer%20frequency%20in%20Escherichia%20coli.%20Disruption%20of%20the%20recipient%20uvrD%20gene%20decreased%20the%20acquisition%20frequency%20of%20conjugative%20plasmids%20belonging%20to%20different%20incompatibility%20groups.%20Results%20from%20various%20UvrD%20mutants%20suggested%20that%20dsDNA%20binding%20activity%20and%20interaction%20with%20RNA%20polymerase%20are%20dispensable%2C%20but%20ATPase%20activity%20is%20required%20for%20successful%20plasmid%20establishment%20of%20transconjugant%20cells.%20Live-cell%20microscopic%20imaging%20showed%20that%20the%20newly%20transferred%20ssDNA%20within%20a%20uvrD-%20recipient%20often%20failed%20to%20be%20converted%20to%20dsDNA.%20Our%20work%20suggested%20that%20in%20addition%20to%20its%20role%20in%20maintaining%20genome%20integrity%2C%20UvrD%20is%20also%20key%20for%20the%20establishment%20of%20horizontally%20acquired%20plasmid%20DNA%20that%20drives%20genome%20diversity%20and%20evolution.%22%2C%22date%22%3A%222023-02-11%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.1093%5C%2Fnar%5C%2Fgkad075%22%2C%22ISSN%22%3A%221362-4962%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%5D%2C%22dateModified%22%3A%222023-02-13T09%3A39%3A01Z%22%7D%7D%2C%7B%22key%22%3A%22W7DFUJEL%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Couturier%20et%20al.%22%2C%22parsedDate%22%3A%222023-01-18%22%2C%22numChildren%22%3A2%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3ECouturier%2C%20Agathe%2C%20Chlo%26%23xE9%3B%20Virolle%2C%20Kelly%20Goldlust%2C%20Annick%20Berne-Dedieu%2C%20Audrey%20Reuter%2C%20Sophie%20Nolivos%2C%20Yoshiharu%20Yamaichi%2C%20Sarah%20Bigot%2C%20and%20Christian%20Lesterlin.%202023.%20%26%23x201C%3BReal-Time%20Visualisation%20of%20the%20Intracellular%20Dynamics%20of%20Conjugative%20Plasmid%20Transfer.%26%23x201D%3B%20%3Ci%3ENature%20Communications%3C%5C%2Fi%3E%2014%20%281%29%3A%20294.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fs41467-023-35978-3%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fs41467-023-35978-3%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Real-time%20visualisation%20of%20the%20intracellular%20dynamics%20of%20conjugative%20plasmid%20transfer%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Agathe%22%2C%22lastName%22%3A%22Couturier%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Chlo%5Cu00e9%22%2C%22lastName%22%3A%22Virolle%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Kelly%22%2C%22lastName%22%3A%22Goldlust%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Annick%22%2C%22lastName%22%3A%22Berne-Dedieu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Audrey%22%2C%22lastName%22%3A%22Reuter%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sophie%22%2C%22lastName%22%3A%22Nolivos%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sarah%22%2C%22lastName%22%3A%22Bigot%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Christian%22%2C%22lastName%22%3A%22Lesterlin%22%7D%5D%2C%22abstractNote%22%3A%22Conjugation%20is%20a%20contact-dependent%20mechanism%20for%20the%20transfer%20of%20plasmid%20DNA%20between%20bacterial%20cells%2C%20which%20contributes%20to%20the%20dissemination%20of%20antibiotic%20resistance.%20Here%2C%20we%20use%20live-cell%20microscopy%20to%20visualise%20the%20intracellular%20dynamics%20of%20conjugative%20transfer%20of%20F-plasmid%20in%20E.%20coli%2C%20in%20real%20time.%20We%20show%20that%20the%20transfer%20of%20plasmid%20in%20single-stranded%20form%20%28ssDNA%29%20and%20its%20subsequent%20conversion%20into%20double-stranded%20DNA%20%28dsDNA%29%20are%20fast%20and%20efficient%20processes%20that%20occur%20with%20specific%20timing%20and%20subcellular%20localisation.%20Notably%2C%20the%20ssDNA-to-dsDNA%20conversion%20determines%20the%20timing%20of%20plasmid-encoded%20protein%20production.%20The%20leading%20region%20that%20first%20enters%20the%20recipient%20cell%20carries%20single-stranded%20promoters%20that%20allow%20the%20early%20and%20transient%20synthesis%20of%20leading%20proteins%20immediately%20upon%20entry%20of%20the%20ssDNA%20plasmid.%20The%20subsequent%20conversion%20into%20dsDNA%20turns%20off%20leading%20gene%20expression%2C%20and%20activates%20the%20expression%20of%20other%20plasmid%20genes%20under%20the%20control%20of%20conventional%20double-stranded%20promoters.%20This%20molecular%20strategy%20allows%20for%20the%20timely%20production%20of%20factors%20sequentially%20involved%20in%20establishing%2C%20maintaining%20and%20disseminating%20the%20plasmid.%22%2C%22date%22%3A%222023-01-18%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.1038%5C%2Fs41467-023-35978-3%22%2C%22ISSN%22%3A%222041-1723%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%5D%2C%22dateModified%22%3A%222024-07-26T07%3A48%3A45Z%22%7D%7D%2C%7B%22key%22%3A%22GB67QYY9%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Possoz%20et%20al.%22%2C%22parsedDate%22%3A%222022-05%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EPossoz%2C%20Christophe%2C%20Yoshiharu%20Yamaichi%2C%20Elisa%20Galli%2C%20Jean-Luc%20Ferat%2C%20and%20Francois-Xavier%20Barre.%202022.%20%26%23x201C%3BVibrio%20Cholerae%20Chromosome%20Partitioning%20without%20Polar%20Anchoring%20by%20HubP.%26%23x201D%3B%20%3Ci%3EGenes%3C%5C%2Fi%3E%2013%20%285%29%3A%20877.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3390%5C%2Fgenes13050877%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3390%5C%2Fgenes13050877%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Vibrio%20cholerae%20Chromosome%20Partitioning%20without%20Polar%20Anchoring%20by%20HubP%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Christophe%22%2C%22lastName%22%3A%22Possoz%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Elisa%22%2C%22lastName%22%3A%22Galli%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Luc%22%2C%22lastName%22%3A%22Ferat%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Francois-Xavier%22%2C%22lastName%22%3A%22Barre%22%7D%5D%2C%22abstractNote%22%3A%22Partition%20systems%20are%20widespread%20among%20bacterial%20chromosomes.%20They%20are%20composed%20of%20two%20effectors%2C%20ParA%20and%20ParB%2C%20and%20cis%20acting%20sites%2C%20parS%2C%20located%20close%20to%20the%20replication%20origin%20of%20the%20chromosome%20%28oriC%29.%20ParABS%20participate%20in%20chromosome%20segregation%2C%20at%20least%20in%20part%20because%20they%20serve%20to%20properly%20position%20sister%20copies%20of%20oriC.%20A%20fourth%20element%2C%20located%20at%20cell%20poles%2C%20is%20also%20involved%20in%20some%20cases%2C%20such%20as%20HubP%20for%20the%20ParABS1%20system%20of%20Vibrio%20cholerae%20chromosome%201%20%28ch1%29.%20The%20polar%20anchoring%20of%20oriC%20of%20ch1%20%28oriC1%29%20is%20lost%20when%20HubP%20or%20ParABS1%20are%20inactivated.%20Here%2C%20we%20report%20that%20in%20the%20absence%20of%20HubP%2C%20ParABS1%20actively%20maintains%20oriC1%20at%20mid-cell%2C%20leading%20to%20the%20subcellular%20separation%20of%20the%20two%20ch1%20replication%20arms.%20We%20further%20show%20that%20parS1%20sites%20ectopically%20inserted%20in%20chromosome%202%20%28ch2%29%20stabilize%20the%20inheritance%20of%20this%20replicon%20in%20the%20absence%20of%20its%20endogenous%20partition%20system%2C%20even%20without%20HubP.%20We%20also%20observe%20the%20positioning%20interference%20between%20oriC1%20and%20oriC%20of%20ch2%20regions%20when%20their%20positionings%20are%20both%20driven%20by%20ParABS1.%20Altogether%2C%20these%20data%20indicate%20that%20ParABS1%20remains%20functional%20in%20the%20absence%20of%20HubP%2C%20which%20raises%20questions%20about%20the%20role%20of%20the%20polar%20anchoring%20of%20oriC1%20in%20the%20cell%20cycle.%22%2C%22date%22%3A%222022%5C%2F5%22%2C%22language%22%3A%22en%22%2C%22DOI%22%3A%2210.3390%5C%2Fgenes13050877%22%2C%22ISSN%22%3A%222073-4425%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fwww.mdpi.com%5C%2F2073-4425%5C%2F13%5C%2F5%5C%2F877%22%2C%22collections%22%3A%5B%5D%2C%22dateModified%22%3A%222024-07-26T07%3A48%3A12Z%22%7D%7D%2C%7B%22key%22%3A%22CDY25UNP%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Altinoglu%20et%20al.%22%2C%22parsedDate%22%3A%222022-01-12%22%2C%22numChildren%22%3A1%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EAltinoglu%2C%20Ipek%2C%20Guillaume%20Abriat%2C%20Alexis%20Carreaux%2C%20Luc%26%23xED%3Ba%20Torres-S%26%23xE1%3Bnchez%2C%20Micka%26%23xEB%3Bl%20Poidevin%2C%20Petya%20Violinova%20Krasteva%2C%20and%20Yoshiharu%20Yamaichi.%202022.%20%26%23x201C%3BAnalysis%20of%20HubP-Dependent%20Cell%20Pole%20Protein%20Targeting%20in%20Vibrio%20Cholerae%20Uncovers%20Novel%20Motility%20Regulators.%26%23x201D%3B%20%3Ci%3EPLOS%20Genetics%3C%5C%2Fi%3E%2018%20%281%29%3A%20e1009991.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1371%5C%2Fjournal.pgen.1009991%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1371%5C%2Fjournal.pgen.1009991%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Analysis%20of%20HubP-dependent%20cell%20pole%20protein%20targeting%20in%20Vibrio%20cholerae%20uncovers%20novel%20motility%20regulators%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ipek%22%2C%22lastName%22%3A%22Altinoglu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Guillaume%22%2C%22lastName%22%3A%22Abriat%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Alexis%22%2C%22lastName%22%3A%22Carreaux%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Luc%5Cu00eda%22%2C%22lastName%22%3A%22Torres-S%5Cu00e1nchez%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Micka%5Cu00ebl%22%2C%22lastName%22%3A%22Poidevin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Petya%20Violinova%22%2C%22lastName%22%3A%22Krasteva%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%5D%2C%22abstractNote%22%3A%22In%20rod-shaped%20bacteria%2C%20the%20emergence%20and%20maintenance%20of%20long-axis%20cell%20polarity%20is%20involved%20in%20key%20cellular%20processes%20such%20as%20cell%20cycle%2C%20division%2C%20environmental%20sensing%20and%20flagellar%20motility%20among%20others.%20Many%20bacteria%20achieve%20cell%20pole%20differentiation%20through%20the%20use%20of%20polar%20landmark%20proteins%20acting%20as%20scaffolds%20for%20the%20recruitment%20of%20functional%20macromolecular%20assemblies.%20In%20Vibrio%20cholerae%20a%20large%20membrane-tethered%20protein%2C%20HubP%2C%20specifically%20interacts%20with%20proteins%20involved%20in%20chromosome%20segregation%2C%20chemotaxis%20and%20flagellar%20biosynthesis.%20Here%20we%20used%20comparative%20proteomics%2C%20genetic%20and%20imaging%20approaches%20to%20identify%20additional%20HubP%20partners%20and%20demonstrate%20that%20at%20least%20six%20more%20proteins%20are%20subject%20to%20HubP-dependent%20polar%20localization.%20These%20include%20a%20cell-wall%20remodeling%20enzyme%20%28DacB%29%2C%20a%20likely%20chemotaxis%20sensory%20protein%20%28HlyB%29%2C%20two%20presumably%20cytosolic%20proteins%20of%20unknown%20function%20%28VC1210%20and%20VC1380%29%20and%20two%20membrane-bound%20proteins%2C%20named%20here%20MotV%20and%20MotW%2C%20that%20exhibit%20distinct%20effects%20on%20chemotactic%20motility.%20We%20show%20that%20while%20both%20%5Cu0394motW%20and%20%5Cu0394motV%20mutants%20retain%20monotrichous%20flagellation%2C%20they%20present%20significant%20to%20severe%20motility%20defects%20when%20grown%20in%20soft%20agar.%20Video-tracking%20experiments%20further%20reveal%20that%20%5Cu0394motV%20cells%20can%20swim%20in%20liquid%20environments%20but%20are%20unable%20to%20tumble%20or%20penetrate%20a%20semisolid%20matrix%2C%20whereas%20a%20motW%20deletion%20affects%20both%20tumbling%20frequency%20and%20swimming%20speed.%20Motility%20suppressors%20and%20gene%20co-occurrence%20analyses%20reveal%20co-evolutionary%20linkages%20between%20MotV%2C%20a%20subset%20of%20non-canonical%20CheV%20proteins%20and%20flagellar%20C-ring%20components%20FliG%20and%20FliM%2C%20whereas%20MotW%20regulatory%20inputs%20appear%20to%20intersect%20with%20specific%20c-di-GMP%20signaling%20pathways.%20Together%2C%20these%20results%20reveal%20an%20ever%20more%20versatile%20role%20for%20the%20landmark%20cell%20pole%20organizer%20HubP%20and%20identify%20novel%20mechanisms%20of%20motility%20regulation.%22%2C%22date%22%3A%2212%20janv.%202022%22%2C%22language%22%3A%22en%22%2C%22DOI%22%3A%2210.1371%5C%2Fjournal.pgen.1009991%22%2C%22ISSN%22%3A%221553-7404%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fjournals.plos.org%5C%2Fplosgenetics%5C%2Farticle%3Fid%3D10.1371%5C%2Fjournal.pgen.1009991%22%2C%22collections%22%3A%5B%5D%2C%22dateModified%22%3A%222024-07-26T07%3A47%3A35Z%22%7D%7D%2C%7B%22key%22%3A%22AQ5R89QD%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Chen%20et%20al.%22%2C%22parsedDate%22%3A%222021%22%2C%22numChildren%22%3A2%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EChen%2C%20Ziyan%2C%20Minjia%20Shen%2C%20Chengyao%20Mao%2C%20Chenyu%20Wang%2C%20Panhong%20Yuan%2C%20Tingzhang%20Wang%2C%20and%20Dongchang%20Sun.%202021.%20%26%23x201C%3BA%20Type%20I%20Restriction%20Modification%20System%20Influences%20Genomic%20Evolution%20Driven%20by%20Horizontal%20Gene%20Transfer%20in%20Paenibacillus%20Polymyxa.%26%23x201D%3B%20%3Ci%3EFrontiers%20in%20Microbiology%3C%5C%2Fi%3E%2012%3A%20709571.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3389%5C%2Ffmicb.2021.709571%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3389%5C%2Ffmicb.2021.709571%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22A%20Type%20I%20Restriction%20Modification%20System%20Influences%20Genomic%20Evolution%20Driven%20by%20Horizontal%20Gene%20Transfer%20in%20Paenibacillus%20polymyxa%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ziyan%22%2C%22lastName%22%3A%22Chen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Minjia%22%2C%22lastName%22%3A%22Shen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Chengyao%22%2C%22lastName%22%3A%22Mao%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Chenyu%22%2C%22lastName%22%3A%22Wang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Panhong%22%2C%22lastName%22%3A%22Yuan%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tingzhang%22%2C%22lastName%22%3A%22Wang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Dongchang%22%2C%22lastName%22%3A%22Sun%22%7D%5D%2C%22abstractNote%22%3A%22Considered%20a%20%5C%22Generally%20Recognized%20As%20Safe%5C%22%20%28GRAS%29%20bacterium%2C%20the%20plant%20growth-promoting%20rhizobacterium%20Paenibacillus%20polymyxa%20has%20been%20widely%20applied%20in%20agriculture%20and%20animal%20husbandry.%20It%20also%20produces%20valuable%20compounds%20that%20are%20used%20in%20medicine%20and%20industry.%20Our%20previous%20work%20showed%20the%20presence%20of%20restriction%20modification%20%28RM%29%20system%20in%20P.%20polymyxa%20ATCC%20842.%20Here%2C%20we%20further%20analyzed%20its%20genome%20and%20methylome%20by%20using%20SMRT%20sequencing%2C%20which%20revealed%20the%20presence%20of%20a%20larger%20number%20of%20genes%2C%20as%20well%20as%20a%20plasmid%20documented%20as%20a%20genomic%20region%20in%20a%20previous%20report.%20A%20number%20of%20mobile%20genetic%20elements%20%28MGEs%29%2C%20including%2078%20insertion%20sequences%2C%20six%20genomic%20islands%2C%20and%20six%20prophages%2C%20were%20identified%20in%20the%20genome.%20A%20putative%20lysozyme-encoding%20gene%20from%20prophage%20P6%20was%20shown%20to%20express%20lysin%20which%20caused%20cell%20lysis.%20Analysis%20of%20the%20methylome%20and%20genome%20uncovered%20a%20pair%20of%20reverse-complementary%20DNA%20methylation%20motifs%20which%20were%20widespread%20in%20the%20genome%2C%20as%20well%20as%20genes%20potentially%20encoding%20their%20cognate%20type%20I%20restriction-modification%20system%20PpoAI.%20Further%20genetic%20analysis%20confirmed%20the%20function%20of%20PpoAI%20as%20a%20RM%20system%20in%20modifying%20and%20restricting%20DNA.%20The%20average%20frequency%20of%20the%20DNA%20methylation%20motifs%20in%20MGEs%20was%20lower%20than%20that%20in%20the%20genome%2C%20implicating%20a%20role%20of%20PpoAI%20in%20restricting%20MGEs%20during%20genomic%20evolution%20of%20P.%20polymyxa.%20Finally%2C%20comparative%20analysis%20of%20R%2C%20M%2C%20and%20S%20subunits%20of%20PpoAI%20showed%20that%20homologs%20of%20the%20PpoAI%20system%20were%20widely%20distributed%20in%20species%20belonging%20to%20other%20classes%20of%20Firmicute%2C%20implicating%20a%20role%20of%20the%20ancestor%20of%20PpoAI%20in%20the%20genomic%20evolution%20of%20species%20beyond%20Paenibacillus.%22%2C%22date%22%3A%222021%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.3389%5C%2Ffmicb.2021.709571%22%2C%22ISSN%22%3A%221664-302X%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%222FBUFWW8%22%5D%2C%22dateModified%22%3A%222021-09-02T11%3A41%3A25Z%22%7D%7D%2C%7B%22key%22%3A%2222W2FGVR%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Espinosa%20et%20al.%22%2C%22parsedDate%22%3A%222020-12-18%22%2C%22numChildren%22%3A2%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EEspinosa%2C%20Elena%2C%20Yoshiharu%20Yamaichi%2C%20and%20Fran%26%23xE7%3Bois-Xavier%20Barre.%202020.%20%26%23x201C%3BProtocol%20for%20High-Throughput%20Analysis%20of%20Sister-Chromatids%20Contacts.%26%23x201D%3B%20%3Ci%3ESTAR%20Protocols%3C%5C%2Fi%3E%201%20%283%29%3A%20100202.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.xpro.2020.100202%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1016%5C%2Fj.xpro.2020.100202%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Protocol%20for%20High-Throughput%20Analysis%20of%20Sister-Chromatids%20Contacts%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Elena%22%2C%22lastName%22%3A%22Espinosa%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Fran%5Cu00e7ois-Xavier%22%2C%22lastName%22%3A%22Barre%22%7D%5D%2C%22abstractNote%22%3A%22Sister%20chromatid%20interactions%20are%20a%20key%20step%20to%20ensure%20the%20successful%20segregation%20of%20sister%20chromatids%20after%20replication.%20Our%20knowledge%20about%20this%20phenomenon%20is%20mostly%20based%20on%20microscopy%20approaches%2C%20which%20have%20some%20constraints%20such%20as%20resolution%20limit%20and%20the%20impossibility%20of%20studying%20several%20genomic%20positions%20at%20the%20same%20time.%20Here%2C%20we%20present%20a%20protocol%20for%20Hi-SC2%2C%20a%20high-throughput%20sequencing-based%20method%2C%20to%20monitor%20sister%20chromatid%20contacts%20after%20replication%20at%20high%20resolution%20throughout%20the%20genome%2C%20which%20we%20applied%20to%20study%20cohesion%20in%20Vibrio%20cholerae.%20For%20complete%20details%20on%20the%20use%20and%20execution%20of%20this%20protocol%2C%20please%20refer%20to%20Espinosa%20et%5Cu00a0al.%20%282020%29.%22%2C%22date%22%3A%222020-12-18%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1016%5C%2Fj.xpro.2020.100202%22%2C%22ISSN%22%3A%222666-1667%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fwww.sciencedirect.com%5C%2Fscience%5C%2Farticle%5C%2Fpii%5C%2FS2666166720301891%22%2C%22collections%22%3A%5B%5D%2C%22dateModified%22%3A%222024-07-26T07%3A46%3A36Z%22%7D%7D%2C%7B%22key%22%3A%223QMTYJBU%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Fomenkov%20et%20al.%22%2C%22parsedDate%22%3A%222020-12-16%22%2C%22numChildren%22%3A4%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EFomenkov%2C%20Alexey%2C%20Zhiyi%20Sun%2C%20Iain%20A%20Murray%2C%20Cristian%20Ruse%2C%20Colleen%20McClung%2C%20Yoshiharu%20Yamaichi%2C%20Elisabeth%20A%20Raleigh%2C%20and%20Richard%20J%20Roberts.%202020.%20%26%23x201C%3BPlasmid%20Replication-Associated%20Single-Strand-Specific%20Methyltransferases.%26%23x201D%3B%20%3Ci%3ENucleic%20Acids%20Research%3C%5C%2Fi%3E%2048%20%2822%29%3A%2012858%26%23x2013%3B73.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgkaa1163%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgkaa1163%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Plasmid%20replication-associated%20single-strand-specific%20methyltransferases%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Alexey%22%2C%22lastName%22%3A%22Fomenkov%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Zhiyi%22%2C%22lastName%22%3A%22Sun%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Iain%20A%22%2C%22lastName%22%3A%22Murray%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Cristian%22%2C%22lastName%22%3A%22Ruse%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Colleen%22%2C%22lastName%22%3A%22McClung%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Elisabeth%20A%22%2C%22lastName%22%3A%22Raleigh%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Richard%20J%22%2C%22lastName%22%3A%22Roberts%22%7D%5D%2C%22abstractNote%22%3A%22Analysis%20of%20genomic%20DNA%20from%20pathogenic%20strains%20of%20Burkholderia%20cenocepacia%20J2315%20and%20Escherichia%20coli%20O104%3AH4%20revealed%20the%20presence%20of%20two%20unusual%20MTase%20genes.%20Both%20are%20plasmid-borne%20ORFs%2C%20carried%20by%20pBCA072%20for%20B.%20cenocepacia%20J2315%20and%20pESBL%20for%20E.%20coli%20O104%3AH4.%20Pacific%20Biosciences%20SMRT%20sequencing%20was%20used%20to%20investigate%20DNA%20methyltransferases%20M.BceJIII%20and%20M.EcoGIX%2C%20using%20artificial%20constructs.%20Mating%20properties%20of%20engineered%20pESBL%20derivatives%20were%20also%20investigated.%20Both%20MTases%20yield%20promiscuous%20m6A%20modification%20of%20single%20strands%2C%20in%20the%20context%20SAY%20%28where%20S%20%3D%20C%20or%20G%20and%20Y%20%3D%20C%20or%20T%29.%20Strikingly%2C%20this%20methylation%20is%20asymmetric%20in%20vivo%2C%20detected%20almost%20exclusively%20on%20one%20DNA%20strand%2C%20and%20is%20incomplete%3A%20typically%2C%20around%2040%25%20of%20susceptible%20motifs%20are%20modified.%20Genetic%20and%20biochemical%20studies%20suggest%20that%20enzyme%20action%20depends%20on%20replication%20mode%3A%20DNA%20Polymerase%20I%20%28PolI%29-dependent%20ColE1%5Cu00a0and%20p15A%20origins%20support%20asymmetric%20modification%2C%20while%20the%20PolI-independent%20pSC101%20origin%20does%20not.%20An%20MTase-PolI%20complex%20may%20enable%20discrimination%20of%20PolI-dependent%20and%20independent%20plasmid%20origins.%20M.EcoGIX%20helps%20to%20establish%20pESBL%20in%20new%20hosts%20by%20blocking%20the%20action%20of%20restriction%20enzymes%2C%20in%20an%20orientation-dependent%20fashion.%20Expression%20and%20action%20appear%20to%20occur%20on%20the%20entering%20single%20strand%20in%20the%20recipient%2C%20early%20in%20conjugal%20transfer%2C%20until%20lagging-strand%20replication%20creates%20the%20double-stranded%20form.%22%2C%22date%22%3A%22December%2016%2C%202020%22%2C%22language%22%3A%22en%22%2C%22DOI%22%3A%2210.1093%5C%2Fnar%5C%2Fgkaa1163%22%2C%22ISSN%22%3A%220305-1048%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgkaa1163%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%222FBUFWW8%22%2C%22D373TGAV%22%5D%2C%22dateModified%22%3A%222021-02-02T09%3A52%3A17Z%22%7D%7D%2C%7B%22key%22%3A%22S28A8GIL%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Daniel%20et%20al.%22%2C%22parsedDate%22%3A%222020-10-16%22%2C%22numChildren%22%3A2%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EDaniel%2C%20Sandra%2C%20Kelly%20Goldlust%2C%20Valentin%20Quebre%2C%20Minjia%20Shen%2C%20Christian%20Lesterlin%2C%20Jean-Yves%20Bouet%2C%20and%20Yoshiharu%20Yamaichi.%202020.%20%26%23x201C%3BVertical%20and%20Horizontal%20Transmission%20of%20ESBL%20Plasmid%20from%20Escherichia%20Coli%20O104%3AH4.%26%23x201D%3B%20%3Ci%3EGenes%3C%5C%2Fi%3E%2011%20%2810%29%3A%201207.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3390%5C%2Fgenes11101207%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3390%5C%2Fgenes11101207%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Vertical%20and%20Horizontal%20Transmission%20of%20ESBL%20Plasmid%20from%20Escherichia%20coli%20O104%3AH4%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sandra%22%2C%22lastName%22%3A%22Daniel%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Kelly%22%2C%22lastName%22%3A%22Goldlust%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Valentin%22%2C%22lastName%22%3A%22Quebre%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Minjia%22%2C%22lastName%22%3A%22Shen%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Christian%22%2C%22lastName%22%3A%22Lesterlin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Yves%22%2C%22lastName%22%3A%22Bouet%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%5D%2C%22abstractNote%22%3A%22Multidrug%20resistance%20%28MDR%29%20often%20results%20from%20the%20acquisition%20of%20mobile%20genetic%20elements%20%28MGEs%29%20that%20encode%20MDR%20gene%28s%29%2C%20such%20as%20conjugative%20plasmids.%20The%20spread%20of%20MDR%20plasmids%20is%20founded%20on%20their%20ability%20of%20horizontal%20transference%2C%20as%20well%20as%20their%20faithful%20inheritance%20in%20progeny%20cells.%20Here%2C%20we%20investigated%20the%20genetic%20factors%20involved%20in%20the%20prevalence%20of%20the%20IncI%20conjugative%20plasmid%20pESBL%2C%20which%20was%20isolated%20from%20the%20Escherichia%20coli%20O104%3AH4%20outbreak%20strain%20in%20Germany%20in%202011.%20Using%20transposon-insertion%20sequencing%2C%20we%20identified%20the%20pESBL%20partitioning%20locus%20%28par%29.%20Genetic%2C%20biochemical%20and%20microscopic%20approaches%20allowed%20pESBL%20to%20be%20characterized%20as%20a%20new%20member%20of%20the%20Type%20Ib%20partitioning%20system.%20Inactivation%20of%20par%20caused%20mis-segregation%20of%20pESBL%20followed%20by%20post-segregational%20killing%20%28PSK%29%2C%20resulting%20in%20a%20great%20fitness%20disadvantage%20but%20apparent%20plasmid%20stability%20in%20the%20population%20of%20viable%20cells.%20We%20constructed%20a%20variety%20of%20pESBL%20derivatives%20with%20different%20combinations%20of%20mutations%20in%20par%2C%20conjugational%20transfer%20%28oriT%29%20and%20pnd%20toxin-antitoxin%20%28TA%29%20genes.%20Only%20the%20triple%20mutant%20exhibited%20plasmid-free%20cells%20in%20viable%20cell%20populations.%20Time-lapse%20tracking%20of%20plasmid%20dynamics%20in%20microfluidics%20indicated%20that%20inactivation%20of%20pnd%20improved%20the%20survival%20of%20plasmid-free%20cells%20and%20allowed%20oriT-dependent%20re-acquisition%20of%20the%20plasmid.%20Altogether%2C%20the%20three%20factors-active%20partitioning%2C%20toxin-antitoxin%20and%20conjugational%20transfer-are%20all%20involved%20in%20the%20prevalence%20of%20pESBL%20in%20the%20E.%20coli%20population.%22%2C%22date%22%3A%22Oct%2016%2C%202020%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.3390%5C%2Fgenes11101207%22%2C%22ISSN%22%3A%222073-4425%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%222FBUFWW8%22%5D%2C%22dateModified%22%3A%222020-11-19T09%3A05%3A42Z%22%7D%7D%2C%7B%22key%22%3A%22X7TY949E%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Yano%20et%20al.%22%2C%22parsedDate%22%3A%222020-09-22%22%2C%22numChildren%22%3A7%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EYano%2C%20Hirokazu%2C%20Md%20Zobaidul%20Alam%2C%20Emiko%20Rimbara%2C%20Tomoko%20F.%20Shibata%2C%20Masaki%20Fukuyo%2C%20Yoshikazu%20Furuta%2C%20Tomoaki%20Nishiyama%2C%20et%20al.%202020.%20%26%23x201C%3BCorrigendum%3A%20Networking%20and%20Specificity-Changing%20DNA%20Methyltransferases%20in%20Helicobacter%20Pylori.%26%23x201D%3B%20%3Ci%3EFrontiers%20in%20Microbiology%3C%5C%2Fi%3E%2011%20%28September%29%3A%20596598.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3389%5C%2Ffmicb.2020.596598%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3389%5C%2Ffmicb.2020.596598%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Corrigendum%3A%20Networking%20and%20Specificity-Changing%20DNA%20Methyltransferases%20in%20Helicobacter%20pylori%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Hirokazu%22%2C%22lastName%22%3A%22Yano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Md%20Zobaidul%22%2C%22lastName%22%3A%22Alam%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Emiko%22%2C%22lastName%22%3A%22Rimbara%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tomoko%20F.%22%2C%22lastName%22%3A%22Shibata%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Masaki%22%2C%22lastName%22%3A%22Fukuyo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshikazu%22%2C%22lastName%22%3A%22Furuta%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tomoaki%22%2C%22lastName%22%3A%22Nishiyama%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Shuji%22%2C%22lastName%22%3A%22Shigenobu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mitsuyasu%22%2C%22lastName%22%3A%22Hasebe%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Atsushi%22%2C%22lastName%22%3A%22Toyoda%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yutaka%22%2C%22lastName%22%3A%22Suzuki%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sumio%22%2C%22lastName%22%3A%22Sugano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Keigo%22%2C%22lastName%22%3A%22Shibayama%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ichizo%22%2C%22lastName%22%3A%22Kobayashi%22%7D%5D%2C%22abstractNote%22%3A%22Corrigendum%3A%20Networking%20and%20Specificity-Changing%20DNA%20Methyltransferases%20in%20Helicobacter%20pylori%22%2C%22date%22%3A%222020-09-22%22%2C%22language%22%3A%22English%22%2C%22DOI%22%3A%2210.3389%5C%2Ffmicb.2020.596598%22%2C%22ISSN%22%3A%221664-302X%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fwww.frontiersin.org%5C%2Farticles%5C%2F10.3389%5C%2Ffmicb.2020.596598%5C%2Ffull%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%222FBUFWW8%22%5D%2C%22dateModified%22%3A%222023-12-14T15%3A34%3A54Z%22%7D%7D%2C%7B%22key%22%3A%22BIYZ5LUA%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Yano%20et%20al.%22%2C%22parsedDate%22%3A%222020-07-17%22%2C%22numChildren%22%3A3%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EYano%2C%20Hirokazu%2C%20Md%20Zobaidul%20Alam%2C%20Emiko%20Rimbara%2C%20Tomoko%20F.%20Shibata%2C%20Masaki%20Fukuyo%2C%20Yoshikazu%20Furuta%2C%20Tomoaki%20Nishiyama%2C%20et%20al.%202020.%20%26%23x201C%3BNetworking%20and%20Specificity-Changing%20DNA%20Methyltransferases%20in%20Helicobacter%20Pylori.%26%23x201D%3B%20%3Ci%3EFrontiers%20in%20Microbiology%3C%5C%2Fi%3E%2011%20%28July%29%3A%201628.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3389%5C%2Ffmicb.2020.01628%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3389%5C%2Ffmicb.2020.01628%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Networking%20and%20Specificity-Changing%20DNA%20Methyltransferases%20in%20Helicobacter%20pylori%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Hirokazu%22%2C%22lastName%22%3A%22Yano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Md%20Zobaidul%22%2C%22lastName%22%3A%22Alam%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Emiko%22%2C%22lastName%22%3A%22Rimbara%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tomoko%20F.%22%2C%22lastName%22%3A%22Shibata%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Masaki%22%2C%22lastName%22%3A%22Fukuyo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshikazu%22%2C%22lastName%22%3A%22Furuta%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tomoaki%22%2C%22lastName%22%3A%22Nishiyama%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Shuji%22%2C%22lastName%22%3A%22Shigenobu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mitsuyasu%22%2C%22lastName%22%3A%22Hasebe%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Atsushi%22%2C%22lastName%22%3A%22Toyoda%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yutaka%22%2C%22lastName%22%3A%22Suzuki%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sumio%22%2C%22lastName%22%3A%22Sugano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Keigo%22%2C%22lastName%22%3A%22Shibayama%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ichizo%22%2C%22lastName%22%3A%22Kobayashi%22%7D%5D%2C%22abstractNote%22%3A%22Epigenetic%20DNA%20base%20methylation%20plays%20important%20roles%20in%20gene%20expression%20regulation.%20We%20here%20describe%20a%20gene%20expression%20regulation%20network%20consisting%20of%20many%20DNA%20methyltransferases%20each%20frequently%20changing%20its%20target%20sequence-specificity.%20Our%20object%20Helicobacter%20pylori%2C%20a%20bacterium%20responsible%20for%20most%20incidence%20of%20stomach%20cancer%2C%20carries%20a%20large%20and%20variable%20repertoire%20of%20sequence-specific%20DNA%20methyltransferases.%20By%20creating%20a%20dozen%20of%20single-gene%20knockout%20strains%20for%20the%20methyltransferases%2C%20we%20revealed%20that%20they%20form%20a%20network%20controlling%20methylome%2C%20transcriptome%20and%20adaptive%20phenotype%20sets.%20The%20methyltransferases%20interact%20with%20each%20other%20in%20a%20hierarchical%20way%2C%20sometimes%20regulated%20positively%20by%20one%20methyltransferase%20but%20negatively%20with%20another.%20Motility%2C%20oxidative%20stress%20tolerance%20and%20DNA%20damage%20repair%20are%20likewise%20regulated%20by%20multiple%20methyltransferases.%20Their%20regulation%20sometimes%20involves%20translation%20start%20and%20stop%20codons%20suggesting%20coupling%20of%20methylation%2C%20transcription%20and%20translation.%20The%20methyltransferases%20frequently%20change%20their%20sequence-specificity%20through%20gene%20conversion%20of%20their%20target%20recognition%20domain%20and%20switch%20their%20target%20sets%20to%20remodel%20the%20network.%20The%20emerging%20picture%20of%20a%20metamorphosing%20gene%20regulation%20network%2C%20or%20firework%2C%20consisting%20of%20epigenetic%20systems%20ever-changing%20their%20specificity%20in%20search%20for%20adaptation%2C%20provides%20a%20new%20paradigm%20in%20understanding%20global%20gene%20regulation%20and%20adaptive%20evolution.%22%2C%22date%22%3A%222020-07-17%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.3389%5C%2Ffmicb.2020.01628%22%2C%22ISSN%22%3A%221664-302X%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%222FBUFWW8%22%5D%2C%22dateModified%22%3A%222023-12-14T15%3A42%3A39Z%22%7D%7D%2C%7B%22key%22%3A%22H8MDVJTF%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Steunou%20et%20al.%22%2C%22parsedDate%22%3A%222020%22%2C%22numChildren%22%3A3%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3ESteunou%2C%20Anne%20Soisig%2C%20Marion%20Babot%2C%20Marie-Line%20Bourbon%2C%20Reem%20Tambosi%2C%20Anne%20Durand%2C%20Sylviane%20Liotenberg%2C%20Anja%20Krieger%26%23x2010%3BLiszkay%2C%20Yoshiharu%20Yamaichi%2C%20and%20Soufian%20Ouchane.%202020.%20%26%23x201C%3BAdditive%20Effects%20of%20Metal%20Excess%20and%20Superoxide%2C%20a%20Highly%20Toxic%20Mixture%20in%20Bacteria.%26%23x201D%3B%20%3Ci%3EMicrobial%20Biotechnology%3C%5C%2Fi%3E%2013%20%285%29%3A%201515%26%23x2013%3B29.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2Fhttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1111%5C%2F1751-7915.13589%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2Fhttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1111%5C%2F1751-7915.13589%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Additive%20effects%20of%20metal%20excess%20and%20superoxide%2C%20a%20highly%20toxic%20mixture%20in%20bacteria%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anne%20Soisig%22%2C%22lastName%22%3A%22Steunou%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Marion%22%2C%22lastName%22%3A%22Babot%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Marie-Line%22%2C%22lastName%22%3A%22Bourbon%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Reem%22%2C%22lastName%22%3A%22Tambosi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anne%22%2C%22lastName%22%3A%22Durand%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sylviane%22%2C%22lastName%22%3A%22Liotenberg%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anja%22%2C%22lastName%22%3A%22Krieger%5Cu2010Liszkay%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Soufian%22%2C%22lastName%22%3A%22Ouchane%22%7D%5D%2C%22abstractNote%22%3A%22Heavy%20metal%20contamination%20is%20a%20serious%20environmental%20problem.%20Understanding%20the%20toxicity%20mechanisms%20may%20allow%20to%20lower%20concentration%20of%20metals%20in%20the%20metal-based%20antimicrobial%20treatments%20of%20crops%2C%20and%20reduce%20metal%20content%20in%20soil%20and%20groundwater.%20Here%2C%20we%20investigate%20the%20interplay%20between%20metal%20efflux%20systems%20and%20the%20superoxide%20dismutase%20%28SOD%29%20in%20the%20purple%20bacterium%20Rubrivivax%20gelatinosus%20and%20other%20bacteria%20through%20analysis%20of%20the%20impact%20of%20metal%20accumulation.%20Exposure%20of%20the%20Cd2%2B-efflux%20mutant%20%5Cu0394cadA%20to%20Cd2%2B%20caused%20an%20increase%20in%20the%20amount%20and%20activity%20of%20the%20cytosolic%20Fe-Sod%20SodB%2C%20thereby%20suggesting%20a%20role%20of%20SodB%20in%20the%20protection%20against%20Cd2%2B.%20In%20support%20of%20this%20conclusion%2C%20inactivation%20of%20sodB%20gene%20in%20the%20%5Cu0394cadA%20cells%20alleviated%20detoxification%20of%20superoxide%20and%20enhanced%20Cd2%2B%20toxicity.%20Similar%20findings%20were%20described%20in%20the%20Cu%2B-efflux%20mutant%20with%20Cu%2B.%20Induction%20of%20the%20Mn-Sod%20or%20Fe-Sod%20in%20response%20to%20metals%20in%20other%20bacteria%2C%20including%20Escherichia%20coli%2C%20Pseudomonas%20aeruginosa%2C%20Pseudomonas%20putida%2C%20Vibrio%20cholera%20and%20Bacillus%20subtilis%2C%20was%20also%20shown.%20Both%20excess%20Cd2%2B%20or%20Cu%2B%20and%20superoxide%20can%20damage%20%5B4Fe-4S%5D%20clusters.%20The%20additive%20effect%20of%20metal%20and%20superoxide%20on%20the%20%5B4Fe-4S%5D%20could%20therefore%20explain%20the%20hypersensitive%20phenotype%20in%20mutants%20lacking%20SOD%20and%20the%20efflux%20ATPase.%20These%20findings%20underscore%20that%20ROS%20defence%20system%20becomes%20decisive%20for%20bacterial%20survival%20under%20metal%20excess.%22%2C%22date%22%3A%222020%22%2C%22language%22%3A%22en%22%2C%22DOI%22%3A%22https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1111%5C%2F1751-7915.13589%22%2C%22ISSN%22%3A%221751-7915%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fsfamjournals.onlinelibrary.wiley.com%5C%2Fdoi%5C%2Fabs%5C%2F10.1111%5C%2F1751-7915.13589%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%227EGDQ8LV%22%2C%222FBUFWW8%22%2C%2254WS7MX2%22%5D%2C%22dateModified%22%3A%222021-09-30T08%3A28%3A20Z%22%7D%7D%2C%7B%22key%22%3A%22Z2GHUYNQ%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Steunou%20et%20al.%22%2C%22parsedDate%22%3A%222020%22%2C%22numChildren%22%3A3%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3ESteunou%2C%20Anne%20Soisig%2C%20Marie-Line%20Bourbon%2C%20Marion%20Babot%2C%20Anne%20Durand%2C%20Sylviane%20Liotenberg%2C%20Yoshiharu%20Yamaichi%2C%20and%20Soufian%20Ouchane.%202020.%20%26%23x201C%3BIncreasing%20the%20Copper%20Sensitivity%20of%20Microorganisms%20by%20Restricting%20Iron%20Supply%2C%20a%20Strategy%20for%20Bio-Management%20Practices.%26%23x201D%3B%20%3Ci%3EMicrobial%20Biotechnology%3C%5C%2Fi%3E%2013%20%285%29%3A%201530%26%23x2013%3B45.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2Fhttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1111%5C%2F1751-7915.13590%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2Fhttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1111%5C%2F1751-7915.13590%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Increasing%20the%20copper%20sensitivity%20of%20microorganisms%20by%20restricting%20iron%20supply%2C%20a%20strategy%20for%20bio-management%20practices%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anne%20Soisig%22%2C%22lastName%22%3A%22Steunou%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Marie-Line%22%2C%22lastName%22%3A%22Bourbon%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Marion%22%2C%22lastName%22%3A%22Babot%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anne%22%2C%22lastName%22%3A%22Durand%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sylviane%22%2C%22lastName%22%3A%22Liotenberg%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Soufian%22%2C%22lastName%22%3A%22Ouchane%22%7D%5D%2C%22abstractNote%22%3A%22Pollution%20by%20copper%20%28Cu2%2B%29%20extensively%20used%20as%20antimicrobial%20in%20agriculture%20and%20farming%20represents%20a%20threat%20to%20the%20environment%20and%20human%20health.%20Finding%20ways%20to%20make%20microorganisms%20sensitive%20to%20lower%20metal%20concentrations%20could%20help%20decreasing%20the%20use%20of%20Cu2%2B%20in%20agriculture.%20In%20this%20respect%2C%20we%20showed%20that%20limiting%20iron%20%28Fe%29%20uptake%20makes%20bacteria%20much%20more%20susceptible%20to%20Cu2%2B%20or%20Cd2%2B%20poisoning.%20Using%20efflux%20mutants%20of%20the%20purple%20bacterium%20Rubrivivax%20gelatinosus%2C%20we%20showed%20that%20Cu%2B%20and%20Cd2%2B%20resistance%20relies%20on%20the%20expression%20of%20the%20Fur-regulated%20FbpABC%20and%20Ftr%20iron%20transporters.%20To%20support%20this%20conclusion%2C%20inactivation%20of%20these%20Fe-importers%20in%20the%20Cu%2B%20or%20Cd2%2B-ATPase%20efflux%20mutants%20gave%20rise%20to%20hypersensitivity%20towards%20these%20ions.%20Moreover%2C%20in%20metal%20overloaded%20cells%20the%20expression%20of%20FbpA%2C%20the%20periplasmic%20iron-binding%20component%20of%20the%20ferric%20ion%20transport%20FbpABC%20system%20was%20induced%2C%20suggesting%20that%20cells%20perceived%20an%20%5Cu2018iron-starvation%5Cu2019%20situation%20and%20responded%20to%20it%20by%20inducing%20Fe-importers.%20In%20this%20context%2C%20the%20Fe-Sod%20activity%20increased%20in%20response%20to%20Fe%20homoeostasis%20dysregulation.%20Similar%20results%20were%20obtained%20for%20Vibrio%20cholerae%20and%20Escherichia%20coli%2C%20suggesting%20that%20perturbation%20of%20Fe-homoeostasis%20by%20metal%20excess%20appeared%20as%20an%20adaptive%20response%20commonly%20used%20by%20a%20variety%20of%20bacteria.%20The%20presented%20data%20support%20a%20model%20in%20which%20metal%20excess%20induces%20Fe-uptake%20to%20support%20%5B4Fe-4S%5D%20synthesis%20and%20thereby%20induce%20ROS%20detoxification%20system.%22%2C%22date%22%3A%222020%22%2C%22language%22%3A%22en%22%2C%22DOI%22%3A%22https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1111%5C%2F1751-7915.13590%22%2C%22ISSN%22%3A%221751-7915%22%2C%22url%22%3A%22https%3A%5C%2F%5C%2Fsfamjournals.onlinelibrary.wiley.com%5C%2Fdoi%5C%2Fabs%5C%2F10.1111%5C%2F1751-7915.13590%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%222FBUFWW8%22%2C%2254WS7MX2%22%5D%2C%22dateModified%22%3A%222021-03-02T09%3A56%3A29Z%22%7D%7D%2C%7B%22key%22%3A%22VBYNIMI4%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Altinoglu%20et%20al.%22%2C%22parsedDate%22%3A%222019-04-30%22%2C%22numChildren%22%3A2%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EAltinoglu%2C%20Ipek%2C%20Christien%20J.%20Merrifield%2C%20and%20Yoshiharu%20Yamaichi.%202019.%20%26%23x201C%3BSingle%20Molecule%20Super-Resolution%20Imaging%20of%20Bacterial%20Cell%20Pole%20Proteins%20with%20High-Throughput%20Quantitative%20Analysis%20Pipeline.%26%23x201D%3B%20%3Ci%3EScientific%20Reports%3C%5C%2Fi%3E%209%20%281%29%3A%206680.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fs41598-019-43051-7%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fs41598-019-43051-7%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Single%20molecule%20super-resolution%20imaging%20of%20bacterial%20cell%20pole%20proteins%20with%20high-throughput%20quantitative%20analysis%20pipeline%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ipek%22%2C%22lastName%22%3A%22Altinoglu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Christien%20J.%22%2C%22lastName%22%3A%22Merrifield%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%5D%2C%22abstractNote%22%3A%22Bacteria%20show%20sophisticated%20control%20of%20their%20cellular%20organization%2C%20and%20many%20bacteria%20deploy%20different%20polar%20landmark%20proteins%20to%20organize%20the%20cell%20pole.%20Super-resolution%20microscopy%2C%20such%20as%20Photo-Activated%20Localization%20Microscopy%20%28PALM%29%2C%20provides%20the%20nanoscale%20localization%20of%20molecules%20and%20is%20crucial%20for%20better%20understanding%20of%20organization%20and%20dynamics%20in%20single-molecule.%20However%2C%20analytical%20tools%20are%20not%20fully%20available%20yet%2C%20in%20particular%20for%20bacterial%20cell%20biology.%20For%20example%2C%20quantitative%20and%20statistical%20analyses%20of%20subcellular%20localization%20with%20multiple%20cells%20from%20multiple%20fields%20of%20view%20are%20lacking.%20Furthermore%2C%20brightfield%20images%20are%20not%20sufficient%20to%20get%20accurate%20contours%20of%20small%20and%20low%20contrast%20bacterial%20cells%2C%20compared%20to%20subpixel%20presentation%20of%20target%20molecules.%20Here%20we%20describe%20a%20novel%20analytic%20tool%20for%20PALM%20which%20integrates%20precisely%20drawn%20cell%20outlines%2C%20of%20either%20inner%20membrane%20or%20periplasm%2C%20labelled%20by%20PALM-compatible%20fluorescent%20protein%20fusions%2C%20with%20molecule%20data%20for%20%3E10%2C000%20molecules%20from%20%3E100%20cells%20by%20fitting%20each%20cell%20into%20an%20oval%20arc.%20In%20the%20vibrioid%20bacterium%20Vibrio%20cholerae%2C%20the%20polar%20anchor%20HubP%20constitutes%20a%20big%20polar%20complex%20which%20includes%20multiple%20proteins%20involved%20in%20chemotaxis%20and%20the%20flagellum.%20With%20this%20pipeline%2C%20HubP%20is%20shown%20to%20be%20slightly%20skewed%20towards%20the%20inner%20curvature%20side%20of%20the%20cell%2C%20while%20its%20interaction%20partners%20showed%20rather%20loose%20polar%20localization.%22%2C%22date%22%3A%22Apr%2030%2C%202019%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.1038%5C%2Fs41598-019-43051-7%22%2C%22ISSN%22%3A%222045-2322%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%2283ZRAMIC%22%2C%222FBUFWW8%22%5D%2C%22dateModified%22%3A%222020-04-24T10%3A35%3A16Z%22%7D%7D%2C%7B%22key%22%3A%22CHFFNKJJ%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Poidevin%20et%20al.%22%2C%22parsedDate%22%3A%222018%22%2C%22numChildren%22%3A0%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EPoidevin%2C%20Micka%26%23xEB%3Bl%2C%20Mari%20Sato%2C%20Ipek%20Altinoglu%2C%20Manon%20Delaplace%2C%20Chikara%20Sato%2C%20and%20Yoshiharu%20Yamaichi.%202018.%20%26%23x201C%3BMutation%20in%20ESBL%20Plasmid%20FromEscherichia%20ColiO104%3AH4%20Leads%20Autoagglutination%20and%20Enhanced%20Plasmid%20Dissemination.%26%23x201D%3B%20%3Ci%3EFront%20Microbiol%3C%5C%2Fi%3E%209%3A%20130.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3389%5C%2Ffmicb.2018.00130%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.3389%5C%2Ffmicb.2018.00130%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Mutation%20in%20ESBL%20Plasmid%20fromEscherichia%20coliO104%3AH4%20Leads%20Autoagglutination%20and%20Enhanced%20Plasmid%20Dissemination.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Micka%5Cu00ebl%22%2C%22lastName%22%3A%22Poidevin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mari%22%2C%22lastName%22%3A%22Sato%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ipek%22%2C%22lastName%22%3A%22Altinoglu%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Manon%22%2C%22lastName%22%3A%22Delaplace%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Chikara%22%2C%22lastName%22%3A%22Sato%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%5D%2C%22abstractNote%22%3A%22Conjugative%20plasmids%20are%20one%20of%20the%20main%20driving%20force%20of%20wide-spreading%20of%20multidrug%20resistance%20%28MDR%29%20bacteria.%20They%20are%20self-transmittable%20via%20conjugation%20as%20carrying%20the%20required%20set%20of%20genes%20andcis-acting%20DNA%20locus%20for%20direct%20cell-to-cell%20transfer.%20IncI%20incompatibility%20plasmids%20are%20nowadays%20often%20associated%20with%20extended-spectrum%20beta-lactamases%20producing%20Enterobacteria%20in%20clinic%20and%20environment.%20pESBL-EA11%20was%20isolated%20fromEscherichia%20coliO104%3AH4%20outbreak%20strain%20in%20Germany%20in%202011.%20During%20the%20previous%20study%20identifying%20transfer%20genes%20of%20pESBL-EA11%2C%20it%20was%20shown%20that%20transposon%20insertion%20at%20certain%20DNA%20region%20of%20the%20plasmid%2C%20referred%20to%20as%20Hft%2C%20resulted%20in%20great%20enhancement%20of%20transfer%20ability.%20This%20suggested%20that%20genetic%20modifications%20can%20enhance%20dissemination%20of%20MDR%20plasmids.%20Such%20%27superspreader%27%20mutations%20have%20attracted%20little%20attention%20so%20far%20despite%20their%20high%20potential%20to%20worsen%20MDR%20spreading.%20Present%20study%20aimed%20to%20gain%20our%20understanding%20on%20regulatory%20elements%20that%20involved%20pESBL%20transfer.%20While%20previous%20studies%20of%20IncI%20plasmids%20indicated%20that%20immediate%20downstream%20gene%20of%20Hft%2CtraA%2C%20is%20not%20essential%20for%20conjugative%20transfer%2C%20here%20we%20showed%20that%20overexpression%20of%20TraA%20in%20host%20cell%20elevated%20transfer%20rate%20of%20pESBL-EA11.%20Transposon%20insertion%20or%20certain%20nucleotide%20substitutions%20in%20Hft%20led%20strong%20TraA%20overexpression%20which%20resulted%20in%20activation%20of%20essential%20regulator%20TraB%20and%20likely%20overexpression%20of%20conjugative%20pili.%20Atmospheric%20Scanning%20Electron%20Microscopy%20observation%20suggested%20that%20IncI%20pili%20are%20distinct%20from%20other%20types%20of%20conjugative%20pili%20%28such%20as%20long%20filamentous%20F-type%20pili%29%20and%20rather%20expressed%20throughout%20the%20cell%20surface.%20High%20transfer%20efficiency%20in%20the%20mutant%20pESBL-EA11%20was%20involved%20with%20hyperpiliation%20which%20facilitates%20cell-to-cell%20adhesion%2C%20including%20autoagglutination.%20The%20capability%20of%20plasmids%20to%20evolve%20to%20highly%20transmissible%20mutant%20is%20alarming%2C%20particularly%20it%20might%20also%20have%20adverse%20effect%20on%20host%20pathogenicity%22%2C%22date%22%3A%222018%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.3389%5C%2Ffmicb.2018.00130%22%2C%22ISSN%22%3A%221664-302X%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%2C%222FBUFWW8%22%5D%2C%22dateModified%22%3A%222018-03-22T11%3A01%3A50Z%22%7D%7D%2C%7B%22key%22%3A%22EKZG69FT%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Dost%5Cu00e1lov%5Cu00e1%20et%20al.%22%2C%22parsedDate%22%3A%222017-09-05%22%2C%22numChildren%22%3A2%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EDost%26%23xE1%3Blov%26%23xE1%3B%2C%20Anna%2C%20Samuel%20Rommelaere%2C%20Mickael%20Poidevin%2C%20and%20Bruno%20Lemaitre.%202017.%20%26%23x201C%3BThioester-Containing%20Proteins%20Regulate%20the%20Toll%20Pathway%20and%20Play%20a%20Role%20in%20Drosophila%20Defence%20against%20Microbial%20Pathogens%20and%20Parasitoid%20Wasps.%26%23x201D%3B%20%3Ci%3EBMC%20Biology%3C%5C%2Fi%3E%2015%20%281%29%3A%2079.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1186%5C%2Fs12915-017-0408-0%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1186%5C%2Fs12915-017-0408-0%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Thioester-containing%20proteins%20regulate%20the%20Toll%20pathway%20and%20play%20a%20role%20in%20Drosophila%20defence%20against%20microbial%20pathogens%20and%20parasitoid%20wasps%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Anna%22%2C%22lastName%22%3A%22Dost%5Cu00e1lov%5Cu00e1%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Samuel%22%2C%22lastName%22%3A%22Rommelaere%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Mickael%22%2C%22lastName%22%3A%22Poidevin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Bruno%22%2C%22lastName%22%3A%22Lemaitre%22%7D%5D%2C%22abstractNote%22%3A%22BACKGROUND%3A%20Members%20of%20the%20thioester-containing%20protein%20%28TEP%29%20family%20contribute%20to%20host%20defence%20in%20both%20insects%20and%20mammals.%20However%2C%20their%20role%20in%20the%20immune%20response%20of%20Drosophila%20is%20elusive.%20In%20this%20study%2C%20we%20address%20the%20role%20of%20TEPs%20in%20Drosophila%20immunity%20by%20generating%20a%20mutant%20fly%20line%2C%20referred%20to%20as%20TEPq%20%28%5Cu0394%29%20%2C%20lacking%20the%20four%20immune-inducible%20TEPs%2C%20TEP1%2C%202%2C%203%20and%204.%5CnRESULTS%3A%20Survival%20analyses%20with%20TEPq%20%28%5Cu0394%29%20flies%20reveal%20the%20importance%20of%20these%20proteins%20in%20defence%20against%20entomopathogenic%20fungi%2C%20Gram-positive%20bacteria%20and%20parasitoid%20wasps.%20Our%20results%20confirm%20that%20TEPs%20are%20required%20for%20efficient%20phagocytosis%20of%20bacteria%2C%20notably%20for%20the%20two%20Gram-positive%20species%20tested%2C%20Staphylococcus%20aureus%20and%20Enterococcus%20faecalis.%20Furthermore%2C%20we%20show%20that%20TEPq%20%28%5Cu0394%29%20flies%20have%20reduced%20Toll%20pathway%20activation%20upon%20microbial%20infection%2C%20resulting%20in%20lower%20expression%20of%20antimicrobial%20peptide%20genes.%20Epistatic%20analyses%20suggest%20that%20TEPs%20function%20upstream%20or%20independently%20of%20the%20serine%20protease%20ModSP%20at%20an%20initial%20stage%20of%20Toll%20pathway%20activation.%5CnCONCLUSIONS%3A%20Collectively%2C%20our%20study%20brings%20new%20insights%20into%20the%20role%20of%20TEPs%20in%20insect%20immunity.%20It%20reveals%20that%20TEPs%20participate%20in%20both%20humoral%20and%20cellular%20arms%20of%20immune%20response%20in%20Drosophila.%20In%20particular%2C%20it%20shows%20the%20importance%20of%20TEPs%20in%20defence%20against%20Gram-positive%20bacteria%20and%20entomopathogenic%20fungi%2C%20notably%20by%20promoting%20Toll%20pathway%20activation.%22%2C%22date%22%3A%22Sep%2005%2C%202017%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.1186%5C%2Fs12915-017-0408-0%22%2C%22ISSN%22%3A%221741-7007%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%5D%2C%22dateModified%22%3A%222018-03-22T11%3A46%3A30Z%22%7D%7D%2C%7B%22key%22%3A%225B4Q79PJ%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Yamaichi%20and%20D%5Cu00f6rr%22%2C%22parsedDate%22%3A%222017%22%2C%22numChildren%22%3A0%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EYamaichi%2C%20Yoshiharu%2C%20and%20Tobias%20D%26%23xF6%3Brr.%202017.%20%26%23x201C%3BTransposon%20Insertion%20Site%20Sequencing%20for%20Synthetic%20Lethal%20Screening.%26%23x201D%3B%20In%20%3Ci%3EThe%20Bacterial%20Nucleoid%3C%5C%2Fi%3E%2C%20edited%20by%20Olivier%20Esp%26%23xE9%3Bli%2C%201624%3A39%26%23x2013%3B49.%20Methods%20in%20Molecular%20Biology.%20New%20York%2C%20NY%3A%20Springer%20New%20York.%20https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1007%5C%2F978-1-4939-7098-8_4.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22bookSection%22%2C%22title%22%3A%22Transposon%20Insertion%20Site%20Sequencing%20for%20Synthetic%20Lethal%20Screening%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22editor%22%2C%22firstName%22%3A%22Olivier%22%2C%22lastName%22%3A%22Esp%5Cu00e9li%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tobias%22%2C%22lastName%22%3A%22D%5Cu00f6rr%22%7D%5D%2C%22abstractNote%22%3A%22%22%2C%22bookTitle%22%3A%22The%20Bacterial%20Nucleoid%22%2C%22date%22%3A%222017%22%2C%22language%22%3A%22%22%2C%22ISBN%22%3A%22978-1-4939-7097-1%20978-1-4939-7098-8%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Flink.springer.com%5C%2F10.1007%5C%2F978-1-4939-7098-8_4%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%5D%2C%22dateModified%22%3A%222019-04-17T13%3A25%3A43Z%22%7D%7D%2C%7B%22key%22%3A%22PZK62RGQ%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Poidevin%20et%20al.%22%2C%22parsedDate%22%3A%222017%22%2C%22numChildren%22%3A0%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EPoidevin%2C%20Micka%26%23xEB%3Bl%2C%20Elisa%20Galli%2C%20Yoshiharu%20Yamaichi%2C%20and%20Fran%26%23xE7%3Bois-Xavier%20Barre.%202017.%20%26%23x201C%3BWGADseq%3A%20Whole%20Genome%20Affinity%20Determination%20of%20Protein-DNA%20Binding%20Sites.%26%23x201D%3B%20In%20%3Ci%3EThe%20Bacterial%20Nucleoid%3C%5C%2Fi%3E%2C%20edited%20by%20Olivier%20Esp%26%23xE9%3Bli%2C%201624%3A53%26%23x2013%3B60.%20Methods%20in%20Molecular%20Biology.%20New%20York%2C%20NY%3A%20Springer%20New%20York.%20https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1007%5C%2F978-1-4939-7098-8_5.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22bookSection%22%2C%22title%22%3A%22WGADseq%3A%20Whole%20Genome%20Affinity%20Determination%20of%20Protein-DNA%20Binding%20Sites%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22editor%22%2C%22firstName%22%3A%22Olivier%22%2C%22lastName%22%3A%22Esp%5Cu00e9li%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Micka%5Cu00ebl%22%2C%22lastName%22%3A%22Poidevin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Elisa%22%2C%22lastName%22%3A%22Galli%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Fran%5Cu00e7ois-Xavier%22%2C%22lastName%22%3A%22Barre%22%7D%5D%2C%22abstractNote%22%3A%22%22%2C%22bookTitle%22%3A%22The%20Bacterial%20Nucleoid%22%2C%22date%22%3A%222017%22%2C%22language%22%3A%22%22%2C%22ISBN%22%3A%22978-1-4939-7097-1%20978-1-4939-7098-8%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Flink.springer.com%5C%2F10.1007%5C%2F978-1-4939-7098-8_5%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%5D%2C%22dateModified%22%3A%222019-04-17T13%3A26%3A07Z%22%7D%7D%2C%7B%22key%22%3A%227BMXSZPD%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Zhang%20et%20al.%22%2C%22parsedDate%22%3A%222017%22%2C%22numChildren%22%3A0%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EZhang%2C%20Yingbiao%2C%20Tomoyuki%20Matsuzaka%2C%20Hirokazu%20Yano%2C%20Yoshikazu%20Furuta%2C%20Toshiaki%20Nakano%2C%20Ken%20Ishikawa%2C%20Masaki%20Fukuyo%2C%20et%20al.%202017.%20%26%23x201C%3BRestriction%20Glycosylases%3A%20Involvement%20of%20Endonuclease%20Activities%20in%20the%20Restriction%20Process.%26%23x201D%3B%20%3Ci%3ENucleic%20Acids%20Res%3C%5C%2Fi%3E%2045%3A%201392%26%23x2013%3B1403.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgkw1250%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgkw1250%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Restriction%20glycosylases%3A%20involvement%20of%20endonuclease%20activities%20in%20the%20restriction%20process.%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yingbiao%22%2C%22lastName%22%3A%22Zhang%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Tomoyuki%22%2C%22lastName%22%3A%22Matsuzaka%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Hirokazu%22%2C%22lastName%22%3A%22Yano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshikazu%22%2C%22lastName%22%3A%22Furuta%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Toshiaki%22%2C%22lastName%22%3A%22Nakano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ken%22%2C%22lastName%22%3A%22Ishikawa%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Masaki%22%2C%22lastName%22%3A%22Fukuyo%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Noriko%22%2C%22lastName%22%3A%22Takahashi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yutaka%22%2C%22lastName%22%3A%22Suzuki%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Sumio%22%2C%22lastName%22%3A%22Sugano%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Hiroshi%22%2C%22lastName%22%3A%22Ide%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ichizo%22%2C%22lastName%22%3A%22Kobayashi%22%7D%5D%2C%22abstractNote%22%3A%22All%20restriction%20enzymes%20examined%20are%20phosphodiesterases%20generating%203%5Cu0384-OH%20and%205%5Cu0384-P%20ends%2C%20but%20one%20restriction%20enzyme%20%28restriction%20glycosylase%29%20excises%20unmethylated%20bases%20from%20its%20recognition%20sequence.%20Whether%20its%20restriction%20activity%20involves%20endonucleolytic%20cleavage%20remains%20unclear.%20One%20report%20on%20this%20enzyme%2C%20R.PabI%20from%20a%20hyperthermophile%2C%20ascribed%20the%20breakage%20to%20high%20temperature%20while%20another%20showed%20its%20weak%20AP%20lyase%20activity%20generates%20atypical%20ends.%20Here%2C%20we%20addressed%20this%20issue%20in%20mesophiles.%20We%20purified%20R.PabI%20homologs%20from%20Campylobacter%20coli%20%28R.CcoLI%29%20and%20Helicobacter%20pylori%20%28R.HpyAXII%29%20and%20demonstrated%20their%20DNA%20cleavage%2C%20DNA%20glycosylase%20and%20AP%20lyase%20activities%20in%20vitro%20at%2037%5Cu00b0C.%20The%20AP%20lyase%20activity%20is%20more%20coupled%20with%20glycosylase%20activity%20in%20R.CcoLI%20than%20in%20R.PabI.%20R.CcoLI%5C%2FR.PabI%20expression%20caused%20restriction%20of%20incoming%20bacteriophage%5C%2Fplasmid%20DNA%20and%20endogenous%20chromosomal%20DNA%20within%20Escherichia%20coli%20at%2037%5Cu00b0C.%20The%20R.PabI-mediated%20restriction%20was%20promoted%20by%20AP%20endonuclease%20action%20in%20vivo%20or%20in%20vitro.%20These%20results%20reveal%20the%20role%20of%20endonucleolytic%20DNA%20cleavage%20in%20restriction%20and%20yet%20point%20to%20diversity%20among%20the%20endonucleases.%20The%20cleaved%20ends%20are%20difficult%20to%20repair%20in%20vivo%2C%20which%20may%20indicate%20their%20biological%20significance.%20These%20results%20support%20generalization%20of%20the%20concept%20of%20restriction%5Cu2013modification%20system%20to%20the%20concept%20of%20self-recognizing%20epigenetic%20system%2C%20which%20combines%20any%20epigenetic%20labeling%20and%20any%20DNA%20damaging%22%2C%22date%22%3A%222017%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.1093%5C%2Fnar%5C%2Fgkw1250%22%2C%22ISSN%22%3A%221362-4962%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%5D%2C%22dateModified%22%3A%222019-12-04T09%3A30%3A13Z%22%7D%7D%2C%7B%22key%22%3A%22ERMHTRD5%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Galli%20et%20al.%22%2C%22parsedDate%22%3A%222016-06-27%22%2C%22numChildren%22%3A2%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EGalli%2C%20Elisa%2C%20Micka%26%23xEB%3Bl%20Poidevin%2C%20Romain%20Le%20Bars%2C%20Jean-Michel%20Desfontaines%2C%20Leila%20Muresan%2C%20Evelyne%20Paly%2C%20Yoshiharu%20Yamaichi%2C%20and%20Fran%26%23xE7%3Bois-Xavier%20Barre.%202016.%20%26%23x201C%3BCell%20Division%20Licensing%20in%20the%20Multi-Chromosomal%20Vibrio%20Cholerae%20Bacterium.%26%23x201D%3B%20%3Ci%3ENature%20Microbiology%3C%5C%2Fi%3E%201%20%289%29%3A%2016094.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fnmicrobiol.2016.94%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1038%5C%2Fnmicrobiol.2016.94%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22Cell%20division%20licensing%20in%20the%20multi-chromosomal%20Vibrio%20cholerae%20bacterium%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Elisa%22%2C%22lastName%22%3A%22Galli%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Micka%5Cu00ebl%22%2C%22lastName%22%3A%22Poidevin%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Romain%22%2C%22lastName%22%3A%22Le%20Bars%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jean-Michel%22%2C%22lastName%22%3A%22Desfontaines%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Leila%22%2C%22lastName%22%3A%22Muresan%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Evelyne%22%2C%22lastName%22%3A%22Paly%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Fran%5Cu00e7ois-Xavier%22%2C%22lastName%22%3A%22Barre%22%7D%5D%2C%22abstractNote%22%3A%22%22%2C%22date%22%3A%222016-6-27%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1038%5C%2Fnmicrobiol.2016.94%22%2C%22ISSN%22%3A%222058-5276%22%2C%22url%22%3A%22http%3A%5C%2F%5C%2Fwww.nature.com%5C%2Farticles%5C%2Fnmicrobiol201694%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%5D%2C%22dateModified%22%3A%222019-04-17T13%3A28%3A54Z%22%7D%7D%2C%7B%22key%22%3A%22SBMTPJHV%22%2C%22library%22%3A%7B%22id%22%3A3888256%7D%2C%22meta%22%3A%7B%22creatorSummary%22%3A%22Yamaichi%20et%20al.%22%2C%22parsedDate%22%3A%222015-01%22%2C%22numChildren%22%3A2%7D%2C%22bib%22%3A%22%3Cdiv%20class%3D%5C%22csl-bib-body%5C%22%20style%3D%5C%22line-height%3A%201.35%3B%20padding-left%3A%201em%3B%20text-indent%3A-1em%3B%5C%22%3E%5Cn%20%20%3Cdiv%20class%3D%5C%22csl-entry%5C%22%3EYamaichi%2C%20Yoshiharu%2C%20Michael%20C.%20Chao%2C%20Jumpei%20Sasabe%2C%20Lars%20Clark%2C%20Brigid%20M.%20Davis%2C%20Nozomi%20Yamamoto%2C%20Hiroshi%20Mori%2C%20Ken%20Kurokawa%2C%20and%20Matthew%20K.%20Waldor.%202015.%20%26%23x201C%3BHigh-Resolution%20Genetic%20Analysis%20of%20the%20Requirements%20for%20Horizontal%20Transmission%20of%20the%20ESBL%20Plasmid%20from%20Escherichia%20Coli%20O104%3AH4.%26%23x201D%3B%20%3Ci%3ENucleic%20Acids%20Research%3C%5C%2Fi%3E%2043%20%281%29%3A%20348%26%23x2013%3B60.%20%3Ca%20href%3D%27https%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgku1262%27%3Ehttps%3A%5C%2F%5C%2Fdoi.org%5C%2F10.1093%5C%2Fnar%5C%2Fgku1262%3C%5C%2Fa%3E.%3C%5C%2Fdiv%3E%5Cn%3C%5C%2Fdiv%3E%22%2C%22data%22%3A%7B%22itemType%22%3A%22journalArticle%22%2C%22title%22%3A%22High-resolution%20genetic%20analysis%20of%20the%20requirements%20for%20horizontal%20transmission%20of%20the%20ESBL%20plasmid%20from%20Escherichia%20coli%20O104%3AH4%22%2C%22creators%22%3A%5B%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Yoshiharu%22%2C%22lastName%22%3A%22Yamaichi%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Michael%20C.%22%2C%22lastName%22%3A%22Chao%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Jumpei%22%2C%22lastName%22%3A%22Sasabe%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Lars%22%2C%22lastName%22%3A%22Clark%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Brigid%20M.%22%2C%22lastName%22%3A%22Davis%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Nozomi%22%2C%22lastName%22%3A%22Yamamoto%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Hiroshi%22%2C%22lastName%22%3A%22Mori%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Ken%22%2C%22lastName%22%3A%22Kurokawa%22%7D%2C%7B%22creatorType%22%3A%22author%22%2C%22firstName%22%3A%22Matthew%20K.%22%2C%22lastName%22%3A%22Waldor%22%7D%5D%2C%22abstractNote%22%3A%22Horizontal%20dissemination%20of%20the%20genes%20encoding%20extended%20spectrum%20beta-lactamases%20%28ESBLs%29%20via%20conjugative%20plasmids%20is%20facilitating%20the%20increasingly%20widespread%20resistance%20of%20pathogens%20to%20beta-lactam%20antibiotics.%20However%2C%20there%20is%20relatively%20little%20known%20about%20the%20regulatory%20factors%20and%20mechanisms%20that%20govern%20the%20spread%20of%20these%20plasmids.%20Here%2C%20we%20carried%20out%20a%20high-throughput%2C%20transposon%20insertion%20site%20sequencing%20analysis%20%28TnSeq%29%20to%20identify%20genes%20that%20enable%20the%20maintenance%20and%20transmission%20of%20pESBL%2C%20an%20R64%20%28IncI1%29-related%20resistance%20plasmid%20that%20was%20isolated%20from%20Escherichia%20coli%20O104%3AH4%20linked%20to%20a%20recent%20large%20outbreak%20of%20gastroenteritis.%20With%20a%20few%20exceptions%2C%20the%20majority%20of%20the%20genes%20identified%20as%20required%20for%20maintenance%20and%20transmission%20of%20pESBL%20matched%20those%20of%20their%20previously%20defined%20R64%20counterparts.%20However%2C%20our%20analyses%20of%20the%20high-density%20transposon%20insertion%20library%20in%20pESBL%20also%20revealed%20two%20very%20short%20and%20linked%20regions%20that%20constitute%20a%20previously%20unrecognized%20regulatory%20system%20controlling%20spread%20of%20IncI1%20plasmids.%20In%20addition%2C%20we%20investigated%20the%20function%20of%20the%20pESBL-encoded%20M.EcoGIX%20methyltransferase%2C%20which%20is%20also%20encoded%20by%20many%20other%20IncI1%20and%20IncF%20plasmids.%20This%20enzyme%20proved%20to%20protect%20pESBL%20from%20restriction%20in%20new%20hosts%2C%20suggesting%20it%20aids%20in%20expanding%20the%20plasmid%27s%20host%20range.%20Collectively%2C%20our%20work%20illustrates%20the%20power%20of%20the%20TnSeq%20approach%20to%20enable%20rapid%20and%20comprehensive%20analyses%20of%20plasmid%20genes%20and%20sequences%20that%20facilitate%20the%20dissemination%20of%20determinants%20of%20antibiotic%20resistance.%22%2C%22date%22%3A%22Jan%202015%22%2C%22language%22%3A%22eng%22%2C%22DOI%22%3A%2210.1093%5C%2Fnar%5C%2Fgku1262%22%2C%22ISSN%22%3A%221362-4962%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22R7I3GKDL%22%5D%2C%22dateModified%22%3A%222018-03-22T10%3A09%3A41Z%22%7D%7D%5D%7D
Shen, Minjia, Kelly Goldlust, Sandra Daniel, Christian Lesterlin, and Yoshiharu Yamaichi. 2023. “Recipient UvrD Helicase Is Involved in Single- to Double-Stranded DNA Conversion during Conjugative Plasmid Transfer.” Nucleic Acids Research, February, gkad075. https://doi.org/10.1093/nar/gkad075.
Couturier, Agathe, Chloé Virolle, Kelly Goldlust, Annick Berne-Dedieu, Audrey Reuter, Sophie Nolivos, Yoshiharu Yamaichi, Sarah Bigot, and Christian Lesterlin. 2023. “Real-Time Visualisation of the Intracellular Dynamics of Conjugative Plasmid Transfer.” Nature Communications 14 (1): 294. https://doi.org/10.1038/s41467-023-35978-3.
Possoz, Christophe, Yoshiharu Yamaichi, Elisa Galli, Jean-Luc Ferat, and Francois-Xavier Barre. 2022. “Vibrio Cholerae Chromosome Partitioning without Polar Anchoring by HubP.” Genes 13 (5): 877. https://doi.org/10.3390/genes13050877.
Altinoglu, Ipek, Guillaume Abriat, Alexis Carreaux, Lucía Torres-Sánchez, Mickaël Poidevin, Petya Violinova Krasteva, and Yoshiharu Yamaichi. 2022. “Analysis of HubP-Dependent Cell Pole Protein Targeting in Vibrio Cholerae Uncovers Novel Motility Regulators.” PLOS Genetics 18 (1): e1009991. https://doi.org/10.1371/journal.pgen.1009991.
Chen, Ziyan, Minjia Shen, Chengyao Mao, Chenyu Wang, Panhong Yuan, Tingzhang Wang, and Dongchang Sun. 2021. “A Type I Restriction Modification System Influences Genomic Evolution Driven by Horizontal Gene Transfer in Paenibacillus Polymyxa.” Frontiers in Microbiology 12: 709571. https://doi.org/10.3389/fmicb.2021.709571.
Espinosa, Elena, Yoshiharu Yamaichi, and François-Xavier Barre. 2020. “Protocol for High-Throughput Analysis of Sister-Chromatids Contacts.” STAR Protocols 1 (3): 100202. https://doi.org/10.1016/j.xpro.2020.100202.
Fomenkov, Alexey, Zhiyi Sun, Iain A Murray, Cristian Ruse, Colleen McClung, Yoshiharu Yamaichi, Elisabeth A Raleigh, and Richard J Roberts. 2020. “Plasmid Replication-Associated Single-Strand-Specific Methyltransferases.” Nucleic Acids Research 48 (22): 12858–73. https://doi.org/10.1093/nar/gkaa1163.
Daniel, Sandra, Kelly Goldlust, Valentin Quebre, Minjia Shen, Christian Lesterlin, Jean-Yves Bouet, and Yoshiharu Yamaichi. 2020. “Vertical and Horizontal Transmission of ESBL Plasmid from Escherichia Coli O104:H4.” Genes 11 (10): 1207. https://doi.org/10.3390/genes11101207.
Yano, Hirokazu, Md Zobaidul Alam, Emiko Rimbara, Tomoko F. Shibata, Masaki Fukuyo, Yoshikazu Furuta, Tomoaki Nishiyama, et al. 2020. “Corrigendum: Networking and Specificity-Changing DNA Methyltransferases in Helicobacter Pylori.” Frontiers in Microbiology 11 (September): 596598. https://doi.org/10.3389/fmicb.2020.596598.
Yano, Hirokazu, Md Zobaidul Alam, Emiko Rimbara, Tomoko F. Shibata, Masaki Fukuyo, Yoshikazu Furuta, Tomoaki Nishiyama, et al. 2020. “Networking and Specificity-Changing DNA Methyltransferases in Helicobacter Pylori.” Frontiers in Microbiology 11 (July): 1628. https://doi.org/10.3389/fmicb.2020.01628.
Steunou, Anne Soisig, Marion Babot, Marie-Line Bourbon, Reem Tambosi, Anne Durand, Sylviane Liotenberg, Anja Krieger‐Liszkay, Yoshiharu Yamaichi, and Soufian Ouchane. 2020. “Additive Effects of Metal Excess and Superoxide, a Highly Toxic Mixture in Bacteria.” Microbial Biotechnology 13 (5): 1515–29. https://doi.org/https://doi.org/10.1111/1751-7915.13589.
Steunou, Anne Soisig, Marie-Line Bourbon, Marion Babot, Anne Durand, Sylviane Liotenberg, Yoshiharu Yamaichi, and Soufian Ouchane. 2020. “Increasing the Copper Sensitivity of Microorganisms by Restricting Iron Supply, a Strategy for Bio-Management Practices.” Microbial Biotechnology 13 (5): 1530–45. https://doi.org/https://doi.org/10.1111/1751-7915.13590.
Altinoglu, Ipek, Christien J. Merrifield, and Yoshiharu Yamaichi. 2019. “Single Molecule Super-Resolution Imaging of Bacterial Cell Pole Proteins with High-Throughput Quantitative Analysis Pipeline.” Scientific Reports 9 (1): 6680. https://doi.org/10.1038/s41598-019-43051-7.
Poidevin, Mickaël, Mari Sato, Ipek Altinoglu, Manon Delaplace, Chikara Sato, and Yoshiharu Yamaichi. 2018. “Mutation in ESBL Plasmid FromEscherichia ColiO104:H4 Leads Autoagglutination and Enhanced Plasmid Dissemination.” Front Microbiol 9: 130. https://doi.org/10.3389/fmicb.2018.00130.
Dostálová, Anna, Samuel Rommelaere, Mickael Poidevin, and Bruno Lemaitre. 2017. “Thioester-Containing Proteins Regulate the Toll Pathway and Play a Role in Drosophila Defence against Microbial Pathogens and Parasitoid Wasps.” BMC Biology 15 (1): 79. https://doi.org/10.1186/s12915-017-0408-0.
Yamaichi, Yoshiharu, and Tobias Dörr. 2017. “Transposon Insertion Site Sequencing for Synthetic Lethal Screening.” In The Bacterial Nucleoid, edited by Olivier Espéli, 1624:39–49. Methods in Molecular Biology. New York, NY: Springer New York. https://doi.org/10.1007/978-1-4939-7098-8_4.
Poidevin, Mickaël, Elisa Galli, Yoshiharu Yamaichi, and François-Xavier Barre. 2017. “WGADseq: Whole Genome Affinity Determination of Protein-DNA Binding Sites.” In The Bacterial Nucleoid, edited by Olivier Espéli, 1624:53–60. Methods in Molecular Biology. New York, NY: Springer New York. https://doi.org/10.1007/978-1-4939-7098-8_5.
Zhang, Yingbiao, Tomoyuki Matsuzaka, Hirokazu Yano, Yoshikazu Furuta, Toshiaki Nakano, Ken Ishikawa, Masaki Fukuyo, et al. 2017. “Restriction Glycosylases: Involvement of Endonuclease Activities in the Restriction Process.” Nucleic Acids Res 45: 1392–1403. https://doi.org/10.1093/nar/gkw1250.
Galli, Elisa, Mickaël Poidevin, Romain Le Bars, Jean-Michel Desfontaines, Leila Muresan, Evelyne Paly, Yoshiharu Yamaichi, and François-Xavier Barre. 2016. “Cell Division Licensing in the Multi-Chromosomal Vibrio Cholerae Bacterium.” Nature Microbiology 1 (9): 16094. https://doi.org/10.1038/nmicrobiol.2016.94.
Yamaichi, Yoshiharu, Michael C. Chao, Jumpei Sasabe, Lars Clark, Brigid M. Davis, Nozomi Yamamoto, Hiroshi Mori, Ken Kurokawa, and Matthew K. Waldor. 2015. “High-Resolution Genetic Analysis of the Requirements for Horizontal Transmission of the ESBL Plasmid from Escherichia Coli O104:H4.” Nucleic Acids Research 43 (1): 348–60. https://doi.org/10.1093/nar/gku1262.