6w6e Citations

Structural basis for aggregate dissolution and refolding by the Mycobacterium tuberculosis ClpB-DnaK bi-chaperone system.

<div class='caption-title'>(A) The domain architecture of ClpB (upper) and DnaK.</div>
<div class='caption-title'>(A) Cartoon view of a ClpB protomer in conf T. The last helix (Helix 4) of helical domain HD1 of NDB1 (HD1-Helix 4) connects M domain and the TGIP loop.</div>
<div class='caption-title'>(A) Top and side views of the NTD density of protomer P3 docked with the atomic model. The arrow points to the density connecting NTD to the main body of P3 protomer.</div>
Yin Y, Feng X, Yu H, Fay A, Kovach A, Glickman MS, Li H
OpenAccess logo Cell Rep 35 109166 (2021)
Related entries: 6w6g, 6w6h, 6w6i, 6w6j, 7l6n

Cited: 9 times
EuropePMC logo PMID: 34038719

Abstract

The M.Ā tuberculosis (Mtb) ClpB is a protein disaggregase that helps to rejuvenate the bacterial cell. DnaK is a protein foldase that can function alone, but it can also bind to the ClpB hexamer to physically couple protein disaggregation with protein refolding, although the molecular mechanism is not well understood. Here, we report the cryo-EM analysis of the Mtb ClpB-DnaK bi-chaperone in the presence of ATPĪ³S and a protein substrate. We observe three ClpB conformations in the presence of DnaK, identify a conserved TGIP loop linking the oligonucleotide/oligosaccharide-binding domain and the nucleotide-binding domain that is important for ClpB function, derive the interface between the regulatory middle domain of the ClpB and the DnaK nucleotide-binding domain, and find that DnaK binding stabilizes, but does not bend or tilt, the ClpB middle domain. We propose a model for the synergistic actions of aggregate dissolution and refolding by the Mtb ClpB-DnaK bi-chaperone system.

Reviews - 6w6e mentioned but not cited (1)

  1. HtpG-A Major Virulence Factor and a Promising Vaccine Antigen against Mycobacterium tuberculosis. Berisio R, Barra G, Napolitano V, Privitera M, Romano M, Squeglia F, Ruggiero A. Biomolecules 14 471 (2024)

Articles - 6w6e mentioned but not cited (2)

  1. Structural basis for aggregate dissolution and refolding by the Mycobacterium tuberculosis ClpB-DnaK bi-chaperone system. Yin Y, Feng X, Yu H, Fay A, Kovach A, Glickman MS, Li H. Cell Rep 35 109166 (2021)
  2. Automatic and accurate ligand structure determination guided by cryo-electron microscopy maps. Muenks A, Zepeda S, Zhou G, Veesler D, DiMaio F. Nat Commun 14 1164 (2023)


Reviews citing this publication (2)

  1. Electron microscopy holdings of the Protein Data Bank: the impact of the resolution revolution, new validation tools, and implications for the future. Burley SK, Berman HM, Chiu W, Dai W, Flatt JW, Hudson BP, Kaelber JT, Khare SD, Kulczyk AW, Lawson CL, Pintilie GD, Sali A, Vallat B, Westbrook JD, Young JY, Zardecki C. Biophys Rev 14 1281-1301 (2022)
  2. AAA+ proteins: one motor, multiple ways to work. Lin J, Shorter J, Lucius AL. Biochem Soc Trans 50 895-906 (2022)

Articles citing this publication (4)

  1. CLPB3 is required for the removal of chloroplast protein aggregates and thermotolerance in Chlamydomonas. Kreis E, Niemeyer J, Merz M, Scheuring D, Schroda M. J Exp Bot 74 3714-3728 (2023)
  2. The Saccharomyces cerevisiae Yta7 ATPase hexamer contains a unique bromodomain tier that functions in nucleosome disassembly. Wang F, Feng X, He Q, Li H, Li H. J Biol Chem 299 102852 (2023)
  3. Multi-Omics Profiling Specifies Involvement of Alternative Ribosomal Proteins in Response to Zinc Limitation in Mycobacterium smegmatis. Dow A, Burger A, Marcantonio E, Prisic S. Front Microbiol 13 811774 (2022)
  4. Structure of the M. tuberculosis DnaK-GrpE complex reveals how key DnaK roles are controlled. Xiao X, Fay A, Molina PS, Kovach A, Glickman MS, Li H. Nat Commun 15 660 (2024)


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