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Lipopolysaccharide (LPS) is an essential component of the outer membrane (OM) of many Gram-negative bacteria, providing a barrier against the entry of toxic molecules. In Escherichia coli, LPS is exported to the cell surface by seven essential proteins (LptA-G) that form a transenvelope complex. At the inner membrane, the ATP-binding cassette (ABC) transporter LptB 2 FG associates with LptC to power LPS extraction from the membrane and transfer to the periplasmic LptA protein, which is in complex with the OM translocon LptDE. LptC interacts both with LptB 2 FG and LptADE to mediate the formation of the transenvelope bridge and regulates the ATPase activity of LptB 2 FG. A genetic screen has previously identified suppressor mutants at a residue (R212) of LptF that are viable in the absence of LptC. Here, we present in vivo evidence that the LptF R212G mutant assembles a six-protein transenvelope complex in which LptA mediates interactions with LptF and LptD in the absence of LptC. Furthermore, we present in vitro evidence that the mutant LptB 2 FG complexes restore the regulation of ATP hydrolysis as it occurs in the LptB 2 FGC complex to achieve wild-type efficient coupling of ATP hydrolysis and LPS movement. We also show the suppressor mutations restore the wild-type levels of LPS transport both in vivo and in vitro , but remarkably, without restoring the affinity of the inner membrane complex for LptA. Based on the sensitivity of lptF suppressor mutants to selected stress conditions relative to wild-type cells, we show that there are additional regulatory functions of LptF and LptC that had not been identified. IMPORTANCE The presence of an external LPS layer in the outer membrane makes Gram-negative bacteria intrinsically resistant to many antibiotics. Millions of LPS molecules are transported to the cell surface per generation by the Lpt molecular machine made, in E. coli, by seven essential proteins. LptC is the unconventional regulatory subunit of the LptB 2 FGC ABC transporter, involved in coordinating energy production and LPS transport. Surprisingly, despite being essential for bacterial growth, LptC can be deleted, provided that a specific residue in the periplasmic domain of LptF is mutated and LptA is overexpressed. Here, we apply biochemical techniques to investigate the suppression mechanism. The data produced in this work disclose an unknown regulatory function of LptF in the transporter that not only expands the knowledge about the Lpt complex but can also be targeted by novel LPS biogenesis inhibitors.

Titel:	Suppressor Mutations in LptF Bypass Essentiality of LptC by Forming a Six-Protein Transenvelope Bridge That Efficiently Transports Lipopolysaccharide.
Autor/in / Beteiligte Person:	Falchi, FA ; Taylor, RJ ; Rowe, SJ ; Moura, ECCM ; Baeta, T ; Laguri, C ; Simorre, JP ; Kahne, DE ; Polissi, A ; Sperandeo, P
Link:	Full Text Finder (Volltext)
Zeitschrift:	MBio, Jg. 14 (2023-02-28), Heft 1, S. e0220222
Veröffentlichung:	Washington, D.C. : American Society for Microbiology, 2023
Medientyp:	academicJournal
ISSN:	2150-7511 (electronic)
DOI:	10.1128/mbio.02202-22
Schlagwort:	Lipopolysaccharides metabolism Suppression, Genetic Membrane Proteins metabolism Biological Transport physiology ATP-Binding Cassette Transporters metabolism Adenosine Triphosphate metabolism Carrier Proteins metabolism Escherichia coli metabolism Escherichia coli Proteins metabolism
Sonstiges:	Nachgewiesen in: MEDLINE Sprachen: English Publication Type: Journal Article; Research Support, N.I.H., Extramural; Research Support, Non-U.S. Gov't Language: English [mBio] 2023 Feb 28; Vol. 14 (1), pp. e0220222. <i>Date of Electronic Publication: </i>2022 Dec 21. MeSH Terms: Escherichia coli* / metabolism ; Escherichia coli Proteins* / metabolism ; Lipopolysaccharides / metabolism ; Suppression, Genetic ; Membrane Proteins / metabolism ; Biological Transport / physiology ; ATP-Binding Cassette Transporters / metabolism ; Adenosine Triphosphate / metabolism ; Carrier Proteins / metabolism References: J Bacteriol. 1951 Sep;62(3):293-300. (PMID: 14888646) ; Proc Natl Acad Sci U S A. 2008 Apr 8;105(14):5537-42. (PMID: 18375759) ; Biochemistry. 2012 Jun 19;51(24):4800-6. (PMID: 22668317) ; J Bacteriol. 2007 Jan;189(1):244-53. (PMID: 17056748) ; FEBS Lett. 2020 Dec;594(23):3767-3775. (PMID: 32978974) ; J Bacteriol. 2013 Mar;195(5):1100-8. (PMID: 23292770) ; Nature. 2014 Jul 3;511(7507):108-11. (PMID: 24990751) ; Science. 2018 Feb 16;359(6377):798-801. (PMID: 29449493) ; J Lipid Res. 2009 Apr;50 Suppl:S103-8. (PMID: 18974037) ; J Mol Biol. 1970 Jan 14;47(1):69-85. (PMID: 5413343) ; PLoS One. 2016 Aug 16;11(8):e0161354. (PMID: 27529623) ; Science. 2012 Nov 30;338(6111):1214-7. (PMID: 23138981) ; Proc Natl Acad Sci U S A. 2010 Mar 23;107(12):5363-8. (PMID: 20203010) ; Nat Cell Biol. 2000 Apr;2(4):212-8. (PMID: 10783239) ; Cell. 1990 Aug 24;62(4):649-57. (PMID: 2167176) ; Front Mol Biosci. 2021 Dec 22;8:758228. (PMID: 35004843) ; J Bacteriol. 2011 Mar;193(5):1042-53. (PMID: 21169485) ; Mol Microbiol. 2022 Jul;118(1-2):61-76. (PMID: 35678757) ; J Biol Chem. 2010 Oct 22;285(43):33529-33539. (PMID: 20720015) ; Cold Spring Harb Perspect Biol. 2010 May;2(5):a000414. (PMID: 20452953) ; Anal Biochem. 1988 Jan;168(1):1-4. (PMID: 2834977) ; Proc Natl Acad Sci U S A. 2011 Feb 8;108(6):2486-91. (PMID: 21257904) ; Nature. 2019 Mar;567(7749):550-553. (PMID: 30894747) ; J Mol Biol. 2008 Jul 11;380(3):476-88. (PMID: 18534617) ; Proc Natl Acad Sci U S A. 2014 Apr 1;111(13):4982-7. (PMID: 24639492) ; Curr Opin Microbiol. 2013 Dec;16(6):779-85. (PMID: 24148302) ; J Biol Chem. 2021 Dec;297(6):101313. (PMID: 34673027) ; J Bacteriol. 2008 Jul;190(13):4460-9. (PMID: 18424520) ; Sci Rep. 2017 Aug 29;7(1):9715. (PMID: 28852068) ; J Biol Chem. 2008 Jul 18;283(29):20342-9. (PMID: 18480051) ; Microbiol Mol Biol Rev. 2003 Dec;67(4):593-656. (PMID: 14665678) ; Biochemistry. 2010 Jun 8;49(22):4565-7. (PMID: 20446753) ; FEBS Lett. 2009 Jul 7;583(13):2160-4. (PMID: 19500581) ; J Bacteriol. 2016 Jul 28;198(16):2192-203. (PMID: 27246575) ; J Bacteriol. 2017 Dec 20;200(2):. (PMID: 29109183) ; Structure. 2016 Jun 7;24(6):965-976. (PMID: 27161977) ; Nat Methods. 2006 Apr;3(4):263-5. (PMID: 16554830) ; Nat Commun. 2019 Sep 13;10(1):4175. (PMID: 31519889) ; FEMS Microbiol Rev. 2015 Nov;39(6):985-1002. (PMID: 26038291) ; Nature. 2019 Mar;567(7749):486-490. (PMID: 30894744) ; J Biol Chem. 1972 Jun 25;247(12):3962-72. (PMID: 4555955) Grant Information: R01 AI081059 United States AI NIAID NIH HHS; R01 AI149778 United States AI NIAID NIH HHS Contributed Indexing: Keywords: ABC transporter; ATPase; cell envelope; lipopolysaccharide transport; outer membrane biogenesis; proteoliposomes Substance Nomenclature: 0 (Lipopolysaccharides) ; 0 (Escherichia coli Proteins) ; 0 (Membrane Proteins) ; 0 (ATP-Binding Cassette Transporters) ; 8L70Q75FXE (Adenosine Triphosphate) ; 0 (LptF protein, E coli) ; 0 (LptA protein, E coli) ; 0 (Carrier Proteins) ; 0 (LptB protein, E coli) ; 0 (LptC protein, E coli) Entry Date(s): Date Created: 20221221 Date Completed: 20230302 Latest Revision: 20230314 Update Code: 20240513 PubMed Central ID: PMC9972910

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Suppressor Mutations in LptF Bypass Essentiality of LptC by Forming a Six-Protein Transenvelope Bridge That Efficiently Transports Lipopolysaccharide.