Literature DB >> 19450606

Crystal structure of histidine phosphotransfer protein ShpA, an essential regulator of stalk biogenesis in Caulobacter crescentus.

Qingping Xu1, Dennis Carlton, Mitchell D Miller, Marc-André Elsliger, S Sri Krishna, Polat Abdubek, Tamara Astakhova, Prasad Burra, Hsiu-Ju Chiu, Thomas Clayton, Marc C Deller, Lian Duan, Ylva Elias, Julie Feuerhelm, Joanna C Grant, Anna Grzechnik, Slawomir K Grzechnik, Gye Won Han, Lukasz Jaroszewski, Kevin K Jin, Heath E Klock, Mark W Knuth, Piotr Kozbial, Abhinav Kumar, David Marciano, Daniel McMullan, Andrew T Morse, Edward Nigoghossian, Linda Okach, Silvya Oommachen, Jessica Paulsen, Ron Reyes, Christopher L Rife, Natasha Sefcovic, Christine Trame, Christina V Trout, Henry van den Bedem, Dana Weekes, Keith O Hodgson, John Wooley, Ashley M Deacon, Adam Godzik, Scott A Lesley, Ian A Wilson.   

Abstract

Cell-cycle-regulated stalk biogenesis in Caulobacter crescentus is controlled by a multistep phosphorelay system consisting of the hybrid histidine kinase ShkA, the histidine phosphotransfer (HPt) protein ShpA, and the response regulator TacA. ShpA shuttles phosphoryl groups between ShkA and TacA. When phosphorylated, TacA triggers a downstream transcription cascade for stalk synthesis in an RpoN-dependent manner. The crystal structure of ShpA was determined to 1.52 A resolution. ShpA belongs to a family of monomeric HPt proteins that feature a highly conserved four-helix bundle. The phosphorylatable histidine His56 is located on the surface of the helix bundle and is fully solvent exposed. One end of the four-helix bundle in ShpA is shorter compared with other characterized HPt proteins, whereas the face that potentially interacts with the response regulators is structurally conserved. Similarities of the interaction surface around the phosphorylation site suggest that ShpA is likely to share a common mechanism for molecular recognition and phosphotransfer with yeast phosphotransfer protein YPD1 despite their low overall sequence similarity.

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Year:  2009        PMID: 19450606      PMCID: PMC2726009          DOI: 10.1016/j.jmb.2009.05.023

Source DB:  PubMed          Journal:  J Mol Biol        ISSN: 0022-2836            Impact factor:   5.469


  61 in total

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Authors:  Thomas R Schneider; George M Sheldrick
Journal:  Acta Crystallogr D Biol Crystallogr       Date:  2002-09-28

Review 5.  Cell-cycle progression and the generation of asymmetry in Caulobacter crescentus.

Authors:  Jeffrey M Skerker; Michael T Laub
Journal:  Nat Rev Microbiol       Date:  2004-04       Impact factor: 60.633

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8.  Cell cycle control by an essential bacterial two-component signal transduction protein.

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9.  Kinetic analysis of YPD1-dependent phosphotransfer reactions in the yeast osmoregulatory phosphorelay system.

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  10 in total

Review 1.  Getting in the loop: regulation of development in Caulobacter crescentus.

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5.  Structural insights into ChpT, an essential dimeric histidine phosphotransferase regulating the cell cycle in Caulobacter crescentus.

Authors:  Antonella Fioravanti; Bernard Clantin; Frédérique Dewitte; Zoé Lens; Alexis Verger; Emanuele G Biondi; Vincent Villeret
Journal:  Acta Crystallogr Sect F Struct Biol Cryst Commun       Date:  2012-08-29

6.  Stalk formation of Brevundimonas and how it compares to Caulobacter crescentus.

Authors:  Patrick D Curtis
Journal:  PLoS One       Date:  2017-09-08       Impact factor: 3.240

7.  Extended N-terminal region of the essential phosphorelay signaling protein Ypd1 from Cryptococcus neoformans contributes to structural stability, phosphostability and binding of calcium ions.

Authors:  Emily N Kennedy; Smita K Menon; Ann H West
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8.  Role of the highly conserved G68 residue in the yeast phosphorelay protein Ypd1: implications for interactions between histidine phosphotransfer (HPt) and response regulator proteins.

Authors:  Emily N Kennedy; Skyler D Hebdon; Smita K Menon; Clay A Foster; Daniel M Copeland; Qingping Xu; Fabiola Janiak-Spens; Ann H West
Journal:  BMC Biochem       Date:  2019-01-21       Impact factor: 4.059

9.  Comparative Genomic Analysis of Rhodococcus equi: An Insight into Genomic Diversity and Genome Evolution.

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Journal:  IUCrJ       Date:  2020-08-25       Impact factor: 4.769
  10 in total

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