3j3t Citations

Structural dynamics of the MecA-ClpC complex: a type II AAA+ protein unfolding machine.

Liu J, Mei Z, Li N, Qi Y, Xu Y, Shi Y, Wang F, Lei J, Gao N
J Biol Chem 288 17597-608 (2013)
Related entries: 3j3r, 3j3s, 3j3u

Cited: 15 times
EuropePMC logo PMID: 23595989

Abstract

The MecA-ClpC complex is a bacterial type II AAA(+) molecular machine responsible for regulated unfolding of substrates, such as transcription factors ComK and ComS, and targeting them to ClpP for degradation. The six subunits of the MecA-ClpC complex form a closed barrel-like structure, featured with three stacked rings and a hollow passage, where substrates are threaded and translocated through successive pores. Although the general concepts of how polypeptides are unfolded and translocated by internal pore loops of AAA(+) proteins have long been conceived, the detailed mechanistic model remains elusive. With cryoelectron microscopy, we captured four different structures of the MecA-ClpC complexes. These complexes differ in the nucleotide binding states of the two AAA(+) rings and therefore might presumably reflect distinctive, representative snapshots from a dynamic unfolding cycle of this hexameric complex. Structural analysis reveals that nucleotide binding and hydrolysis modulate the hexameric complex in a number of ways, including the opening of the N-terminal ring, the axial and radial positions of pore loops, the compactness of the C-terminal ring, as well as the relative rotation between the two nucleotide-binding domain rings. More importantly, our structural and biochemical data indicate there is an active allosteric communication between the two AAA(+) rings and suggest that concerted actions of the two AAA(+) rings are required for the efficiency of the substrate unfolding and translocation. These findings provide important mechanistic insights into the dynamic cycle of the MecA-ClpC unfoldase and especially lay a foundation toward the complete understanding of the structural dynamics of the general type II AAA(+) hexamers.

Articles - 3j3t mentioned but not cited (2)

  1. Structural dynamics of the MecA-ClpC complex: a type II AAA+ protein unfolding machine. Liu J, Mei Z, Li N, Qi Y, Xu Y, Shi Y, Wang F, Lei J, Gao N. J Biol Chem 288 17597-17608 (2013)
  2. Variability of Protein Structure Models from Electron Microscopy. Monroe L, Terashi G, Kihara D. Structure 25 592-602.e2 (2017)


Reviews citing this publication (3)

  1. Protein rescue from aggregates by powerful molecular chaperone machines. Doyle SM, Genest O, Wickner S. Nat Rev Mol Cell Biol 14 617-629 (2013)
  2. Applications of Bacterial Degrons and Degraders - Toward Targeted Protein Degradation in Bacteria. Izert MA, Klimecka MM, Górna MW. Front Mol Biosci 8 669762 (2021)
  3. Endogenous and Borrowed Proteolytic Activity in the Borrelia. Coleman JL, Benach JL, Karzai AW. Microbiol Mol Biol Rev 85 e00217-20 (2021)

Articles citing this publication (10)

  1. Mechanochemical basis of protein degradation by a double-ring AAA+ machine. Olivares AO, Nager AR, Iosefson O, Sauer RT, Baker TA. Nat Struct Mol Biol 21 871-875 (2014)
  2. BacPROTACs mediate targeted protein degradation in bacteria. Morreale FE, Kleine S, Leodolter J, Junker S, Hoi DM, Ovchinnikov S, Okun A, Kley J, Kurzbauer R, Junk L, Guha S, Podlesainski D, Kazmaier U, Boehmelt G, Weinstabl H, Rumpel K, Schmiedel VM, Hartl M, Haselbach D, Meinhart A, Kaiser M, Clausen T. Cell 185 2338-2353.e18 (2022)
  3. High-Resolution Structure of ClpC1-Rufomycin and Ligand Binding Studies Provide a Framework to Design and Optimize Anti-Tuberculosis Leads. Wolf NM, Lee H, Choules MP, Pauli GF, Phansalkar R, Anderson JR, Gao W, Ren J, Santarsiero BD, Lee H, Cheng J, Jin YY, Ho NA, Duc NM, Suh JW, Abad-Zapatero C, Cho S. ACS Infect Dis 5 829-840 (2019)
  4. Regulatory coiled-coil domains promote head-to-head assemblies of AAA+ chaperones essential for tunable activity control. Carroni M, Franke KB, Maurer M, Jäger J, Hantke I, Gloge F, Linder D, Gremer S, Turgay K, Bukau B, Mogk A. Elife 6 e30120 (2017)
  5. Structure of the N-terminal domain of ClpC1 in complex with the antituberculosis natural product ecumicin reveals unique binding interactions. Wolf NM, Lee H, Zagal D, Nam JW, Oh DC, Lee H, Suh JW, Pauli GF, Cho S, Abad-Zapatero C. Acta Crystallogr D Struct Biol 76 458-471 (2020)
  6. Deficiency of MecA in Streptococcus mutans Causes Major Defects in Cell Envelope Biogenesis, Cell Division, and Biofilm Formation. De A, Jorgensen AN, Beatty WL, Lemos J, Wen ZT. Front Microbiol 9 2130 (2018)
  7. Threshold regulation and stochasticity from the MecA/ClpCP proteolytic system in Streptococcus mutans competence. Son M, Kaspar J, Ahn SJ, Burne RA, Hagen SJ. Mol Microbiol 110 914-930 (2018)
  8. ClpC and MecA, components of a proteolytic machine, prevent Spo0A-P-dependent transcription without degradation. Tanner AW, Carabetta VJ, Dubnau D. Mol Microbiol 108 178-186 (2018)
  9. Molecular Characterization of the ClpC AAA+ ATPase in the Biology of Chlamydia trachomatis. Pan S, Jensen AA, Wood NA, Henrichfreise B, Brötz-Oesterhelt H, Fisher DJ, Sass P, Ouellette SP. mBio 14 e0007523 (2023)
  10. Division of labor between the pore-1 loops of the D1 and D2 AAA+ rings coordinates substrate selectivity of the ClpAP protease. Zuromski KL, Kim S, Sauer RT, Baker TA. J Biol Chem 297 101407 (2021)


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