Literature DB >> 22806565

Architecture and regulation of HtrA-family proteins involved in protein quality control and stress response.

Guido Hansen1, Rolf Hilgenfeld.   

Abstract

Protein quality control is vital for all living cells and sophisticated molecular mechanisms have evolved to prevent the excessive accumulation of unfolded proteins. High-temperature requirement A (HtrA) proteases have been identified as important ATP-independent quality-control factors in most species. HtrA proteins harbor a serine-protease domain and at least one peptide-binding PDZ domain to ensure efficient removal of misfolded or damaged proteins. One distinctive property of HtrAs is their ability to assemble into complex oligomers. Whereas all examined HtrAs are capable of forming pyramidal 3-mers, higher-order complexes consisting of up to 24 molecules have been reported. Tight control of chaperone and protease function is of pivotal importance in preventing deleterious HtrA-protease activity. In recent years, structural biology provided detailed insights into the molecular basis of the regulatory mechanisms, which include unique intramolecular allosteric signaling cascades and the dynamic switching of oligomeric states of HtrA proteins. Based on these results, functional models for many family members have been developed. The HtrA protein family represents a remarkable example of how structural and functional diversity is attained from the assembly of simple molecular building blocks.

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Year:  2012        PMID: 22806565     DOI: 10.1007/s00018-012-1076-4

Source DB:  PubMed          Journal:  Cell Mol Life Sci        ISSN: 1420-682X            Impact factor:   9.261


  88 in total

1.  HtrA proteases have a conserved activation mechanism that can be triggered by distinct molecular cues.

Authors:  Tobias Krojer; Justyna Sawa; Robert Huber; Tim Clausen
Journal:  Nat Struct Mol Biol       Date:  2010-06-27       Impact factor: 15.369

2.  Listeria monocytogenes 10403S HtrA is necessary for resistance to cellular stress and virulence.

Authors:  Rebecca L Wilson; Lindsay L Brown; Dana Kirkwood-Watts; Travis K Warren; S Amanda Lund; David S King; Kevin F Jones; Dennis E Hruby
Journal:  Infect Immun       Date:  2006-01       Impact factor: 3.441

3.  Regulation of the sigmaE stress response by DegS: how the PDZ domain keeps the protease inactive in the resting state and allows integration of different OMP-derived stress signals upon folding stress.

Authors:  Hanna Hasselblatt; Robert Kurzbauer; Corinna Wilken; Tobias Krojer; Justyna Sawa; Juliane Kurt; Rebecca Kirk; Sonja Hasenbein; Michael Ehrmann; Tim Clausen
Journal:  Genes Dev       Date:  2007-10-15       Impact factor: 11.361

4.  Role of DegP for two-partner secretion in Bordetella.

Authors:  C Baud; H Hodak; E Willery; H Drobecq; C Locht; M Jamin; F Jacob-Dubuisson
Journal:  Mol Microbiol       Date:  2009-08-24       Impact factor: 3.501

Review 5.  The structural basis of mode of activation and functional diversity: a case study with HtrA family of serine proteases.

Authors:  Nitu Singh; Raja R Kuppili; Kakoli Bose
Journal:  Arch Biochem Biophys       Date:  2011-10-18       Impact factor: 4.013

6.  Implications of the serine protease HtrA1 in amyloid precursor protein processing.

Authors:  Sandra Grau; Alfonso Baldi; Rossana Bussani; Xiaodan Tian; Raluca Stefanescu; Michael Przybylski; Peter Richards; Simon A Jones; Viji Shridhar; Tim Clausen; Michael Ehrmann
Journal:  Proc Natl Acad Sci U S A       Date:  2005-04-26       Impact factor: 11.205

7.  Activation of DegP chaperone-protease via formation of large cage-like oligomers upon binding to substrate proteins.

Authors:  Jiansen Jiang; Xuefeng Zhang; Yong Chen; Yi Wu; Z Hong Zhou; Zengyi Chang; Sen-Fang Sui
Journal:  Proc Natl Acad Sci U S A       Date:  2008-08-12       Impact factor: 11.205

8.  Overproduction or absence of the periplasmic protease DegP severely compromises bacterial growth in the absence of the dithiol: disulfide oxidoreductase DsbA.

Authors:  Ozlem Onder; Serdar Turkarslan; David Sun; Fevzi Daldal
Journal:  Mol Cell Proteomics       Date:  2008-01-02       Impact factor: 5.911

9.  Age-related macular degeneration.

Authors:  Hanna R Coleman; Chi-Chao Chan; Frederick L Ferris; Emily Y Chew
Journal:  Lancet       Date:  2008-11-22       Impact factor: 79.321

10.  Newly folded substrates inside the molecular cage of the HtrA chaperone DegQ.

Authors:  Hélène Malet; Flavia Canellas; Justyna Sawa; Jun Yan; Konstantinos Thalassinos; Michael Ehrmann; Tim Clausen; Helen R Saibil
Journal:  Nat Struct Mol Biol       Date:  2012-01-15       Impact factor: 15.369
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  43 in total

1.  The LA loop as an important regulatory element of the HtrA (DegP) protease from Escherichia coli: structural and functional studies.

Authors:  Donata Figaj; Artur Gieldon; Agnieszka Polit; Anna Sobiecka-Szkatula; Tomasz Koper; Milena Denkiewicz; Bogdan Banecki; Adam Lesner; Jerzy Ciarkowski; Barbara Lipinska; Joanna Skorko-Glonek
Journal:  J Biol Chem       Date:  2014-04-15       Impact factor: 5.157

2.  Structural basis of the proteolytic and chaperone activity of Chlamydia trachomatis CT441.

Authors:  Friedrich Kohlmann; Kensuke Shima; Rolf Hilgenfeld; Werner Solbach; Jan Rupp; Guido Hansen
Journal:  J Bacteriol       Date:  2014-10-27       Impact factor: 3.490

3.  The membrane protein PrsS mimics σS in protecting Staphylococcus aureus against cell wall-targeting antibiotics and DNA-damaging agents.

Authors:  Christina N Krute; Harris Bell-Temin; Halie K Miller; Frances E Rivera; Andy Weiss; Stanley M Stevens; Lindsey N Shaw
Journal:  Microbiology       Date:  2015-03-04       Impact factor: 2.777

4.  Regulation of Proteolysis in the Gram-Negative Bacterial Envelope.

Authors:  Tracy L Raivio
Journal:  J Bacteriol       Date:  2018-01-10       Impact factor: 3.490

5.  The Chlamydomonas deg1c Mutant Accumulates Proteins Involved in High Light Acclimation.

Authors:  Jasmine Theis; Julia Lang; Benjamin Spaniol; Suzanne Ferté; Justus Niemeyer; Frederik Sommer; David Zimmer; Benedikt Venn; Shima Farazandeh Mehr; Timo Mühlhaus; Francis-André Wollman; Michael Schroda
Journal:  Plant Physiol       Date:  2019-10-11       Impact factor: 8.340

6.  The HtrA-like protease CD3284 modulates virulence of Clostridium difficile.

Authors:  Dennis Bakker; Anthony M Buckley; Anne de Jong; Vincent J C van Winden; Joost P A Verhoeks; Oscar P Kuipers; Gillian R Douce; Ed J Kuijper; Wiep Klaas Smits; Jeroen Corver
Journal:  Infect Immun       Date:  2014-07-21       Impact factor: 3.441

7.  Arabidopsis AtPARK13, which confers thermotolerance, targets misfolded proteins.

Authors:  Indranil Basak; Ramavati Pal; Ketan S Patil; Aisling Dunne; Hsin-Pin Ho; Sungsu Lee; Diluka Peiris; Jodi Maple-Grødem; Mark Odell; Emmanuel J Chang; Jan Petter Larsen; Simon G Møller
Journal:  J Biol Chem       Date:  2014-04-09       Impact factor: 5.157

8.  HTRA1 (high temperature requirement A serine peptidase 1) gene is transcriptionally regulated by insertion/deletion nucleotides located at the 3' end of the ARMS2 (age-related maculopathy susceptibility 2) gene in patients with age-related macular degeneration.

Authors:  Daisuke Iejima; Takeshi Itabashi; Yuich Kawamura; Toru Noda; Shinsuke Yuasa; Keiichi Fukuda; Chio Oka; Takeshi Iwata
Journal:  J Biol Chem       Date:  2014-12-17       Impact factor: 5.157

9.  Proteolytic systems of archaea: slicing, dicing, and mincing in the extreme.

Authors:  Julie A Maupin-Furlow
Journal:  Emerg Top Life Sci       Date:  2018-11-14

Review 10.  Molecular engineering of secretory machinery components for high-level secretion of proteins in Bacillus species.

Authors:  Zhen Kang; Sen Yang; Guocheng Du; Jian Chen
Journal:  J Ind Microbiol Biotechnol       Date:  2014-09-12       Impact factor: 3.346
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