3lgw Citations

Allostery is an intrinsic property of the protease domain of DegS: implications for enzyme function and evolution.

Sohn J, Grant RA, Sauer RT
J Biol Chem 285 34039-47 (2010)
Related entries: 3lgi, 3lgt, 3lgu, 3lgv, 3lgy, 3lh1, 3lh3

Cited: 24 times
EuropePMC logo PMID: 20739286

Abstract

DegS is a periplasmic Escherichia coli protease, which functions as a trimer to catalyze the initial rate-limiting step in a proteolytic cascade that ultimately activates transcription of stress response genes in the cytoplasm. Each DegS subunit consists of a protease domain and a PDZ domain. During protein folding stress, DegS is allosterically activated by peptides exposed in misfolded outer membrane porins, which bind to the PDZ domain and stabilize the active protease. It is not known whether allostery is conferred by the PDZ domains or is an intrinsic feature of the trimeric protease domain. Here, we demonstrate that free DegS(ΔPDZ) equilibrates between active and inactive trimers with the latter species predominating. Substrate binding stabilizes active DegS(ΔPDZ) in a positively cooperative fashion. Mutations can also stabilize active DegS(ΔPDZ) and produce an enzyme that displays hyperbolic kinetics and degrades substrate with a maximal velocity within error of that for fully activated, intact DegS. Crystal structures of multiple DegS(ΔPDZ) variants, in functional and non-functional conformations, support a two-state model in which allosteric switching is mediated by changes in specific elements of tertiary structure in the context of an invariant trimeric base. Overall, our results indicate that protein substrates must bind sufficiently tightly and specifically to the functional conformation of DegS(ΔPDZ) to assist their own degradation. Thus, substrate binding alone may have regulated the activities of ancestral DegS trimers with subsequent fusion of the protease domain to a PDZ domain, resulting in ligand-mediated regulation.

Articles - 3lgw mentioned but not cited (1)

  1. Allostery is an intrinsic property of the protease domain of DegS: implications for enzyme function and evolution. Sohn J, Grant RA, Sauer RT. J Biol Chem 285 34039-34047 (2010)


Reviews citing this publication (2)

  1. Membrane proteases in the bacterial protein secretion and quality control pathway. Dalbey RE, Wang P, van Dijl JM. Microbiol Mol Biol Rev 76 311-330 (2012)
  2. Architecture and regulation of HtrA-family proteins involved in protein quality control and stress response. Hansen G, Hilgenfeld R. Cell Mol Life Sci 70 761-775 (2013)

Articles citing this publication (21)

  1. Signal integration by DegS and RseB governs the σ E-mediated envelope stress response in Escherichia coli. Chaba R, Alba BM, Guo MS, Sohn J, Ahuja N, Sauer RT, Gross CA. Proc Natl Acad Sci U S A 108 2106-2111 (2011)
  2. Evolving specificity from variability for protein interaction domains. Kaneko T, Sidhu SS, Li SS. Trends Biochem Sci 36 183-190 (2011)
  3. Allosteric regulation of DegS protease subunits through a shared energy landscape. Mauldin RV, Sauer RT. Nat Chem Biol 9 90-96 (2013)
  4. A conserved activation cluster is required for allosteric communication in HtrA-family proteases. de Regt AK, Kim S, Sohn J, Grant RA, Baker TA, Sauer RT. Structure 23 517-526 (2015)
  5. MamO Is a Repurposed Serine Protease that Promotes Magnetite Biomineralization through Direct Transition Metal Binding in Magnetotactic Bacteria. Hershey DM, Ren X, Melnyk RA, Browne PJ, Ozyamak E, Jones SR, Chang MC, Hurley JH, Komeili A. PLoS Biol 14 e1002402 (2016)
  6. Temperature-induced changes of HtrA2(Omi) protease activity and structure. Zurawa-Janicka D, Jarzab M, Polit A, Skorko-Glonek J, Lesner A, Gitlin A, Gieldon A, Ciarkowski J, Glaza P, Lubomska A, Lipinska B. Cell Stress Chaperones 18 35-51 (2013)
  7. Structural and Functional Analysis of Human HtrA3 Protease and Its Subdomains. Glaza P, Osipiuk J, Wenta T, Zurawa-Janicka D, Jarzab M, Lesner A, Banecki B, Skorko-Glonek J, Joachimiak A, Lipinska B. PLoS One 10 e0131142 (2015)
  8. Allosteric regulation of serine protease HtrA2 through novel non-canonical substrate binding pocket. Bejugam PR, Kuppili RR, Singh N, Gadewal N, Chaganti LK, Sastry GM, Bose K. PLoS One 8 e55416 (2013)
  9. Distinct regulatory mechanisms balance DegP proteolysis to maintain cellular fitness during heat stress. Kim S, Sauer RT. Genes Dev 28 902-911 (2014)
  10. HtrA1 activation is driven by an allosteric mechanism of inter-monomer communication. Cabrera AC, Melo E, Roth D, Topp A, Delobel F, Stucki C, Chen CY, Jakob P, Banfai B, Dunkley T, Schilling O, Huber S, Iacone R, Petrone P. Sci Rep 7 14804 (2017)
  11. Dual regulatory switch confers tighter control on HtrA2 proteolytic activity. Singh N, D'Souza A, Cholleti A, Sastry GM, Bose K. FEBS J 281 2456-2470 (2014)
  12. Magnetite Biomineralization in Magnetospirillum magneticum Is Regulated by a Switch-like Behavior in the HtrA Protease MamE. Hershey DM, Browne PJ, Iavarone AT, Teyra J, Lee EH, Sidhu SS, Komeili A. J Biol Chem 291 17941-17952 (2016)
  13. Peptide binding to the PDZ3 domain by conformational selection. Steiner S, Caflisch A. Proteins 80 2562-2572 (2012)
  14. Allosteric coupling between Mn2+ and dsDNA controls the catalytic efficiency and fidelity of cGAS. Hooy RM, Massaccesi G, Rousseau KE, Chattergoon MA, Sohn J. Nucleic Acids Res 48 4435-4447 (2020)
  15. Distinct 3D Architecture and Dynamics of the Human HtrA2(Omi) Protease and Its Mutated Variants. Gieldon A, Zurawa-Janicka D, Jarzab M, Wenta T, Golik P, Dubin G, Lipinska B, Ciarkowski J. PLoS One 11 e0161526 (2016)
  16. Steric clashes with bound OMP peptides activate the DegS stress-response protease. de Regt AK, Baker TA, Sauer RT. Proc Natl Acad Sci U S A 112 3326-3331 (2015)
  17. Analytical expressions for the homotropic binding of ligand to protein dimers and trimers. Lefurgy ST, Leyh TS. Anal Biochem 421 433-438 (2012)
  18. Molecular motion regulates the activity of the Mitochondrial Serine Protease HtrA2. Merski M, Moreira C, Abreu RM, Ramos MJ, Fernandes PA, Martins LM, Pereira PJB, Macedo-Ribeiro S. Cell Death Dis 8 e3119 (2017)
  19. A distinct concerted mechanism of structural dynamism defines activity of human serine protease HtrA3. Acharya S, Dutta S, Bose K. Biochem J 477 407-429 (2020)
  20. Genome-wide association study of gastric cancer- and duodenal ulcer-derived Helicobacter pylori strains reveals discriminatory genetic variations and novel oncoprotein candidates. Tuan VP, Yahara K, Dung HDQ, Binh TT, Huu Tung P, Tri TD, Thuan NPM, Khien VV, Trang TTH, Phuc BH, Tshibangu-Kabamba E, Matsumoto T, Akada J, Suzuki R, Okimoto T, Kodama M, Murakami K, Yano H, Fukuyo M, Takahashi N, Kato M, Nishiumi S, Azuma T, Ogura Y, Hayashi T, Toyoda A, Kobayashi I, Yamaoka Y. Microb Genom 7 (2021)
  21. The Repeating, Modular Architecture of the HtrA Proteases. Merski M, Macedo-Ribeiro S, Wieczorek RM, Górna MW. Biomolecules 12 793 (2022)


Quick links