Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Monomer-monomer interactions propagate structural transitions necessary for pore formation by the cholesterol-dependent cytolysins.

Literature DB >> 22645132

Monomer-monomer interactions propagate structural transitions necessary for pore formation by the cholesterol-dependent cytolysins.

Eileen M Hotze¹, Elizabeth Wilson-Kubalek, Allison J Farrand, Lori Bentsen, Michael W Parker, Arthur E Johnson, Rodney K Tweten.

Abstract

The assembly of the cholesterol-dependent cytolysin (CDC) oligomeric pore complex requires a complex choreography of secondary and tertiary structural changes in domain 3 (D3) of the CDC monomer structure. A point mutation was identified in the archetype CDC, perfringolysin O, that blocks detectable D3 structural changes and traps the membrane-bound monomers in an early and reversible stage of oligomer assembly. Using this and other mutants we show that specific D3 structural changes are propagated from one membrane-bound monomer to another. Propagation of these structural changes results in the exposure of a β-strand in D3 that allows it to pair and form edge-on interactions with a second β-strand of a free membrane-bound monomer. Pairing of these strands establishes the final geometry of the pore complex and is necessary to drive the formation of the β-barrel pore. These studies provide new insights into how structural information is propagated between membrane-bound monomers of a self-assembling system and the interactions that establish the geometry of the final pore complex.

Entities: Chemical

Mesh：

Substances：
Perforin
Cholesterol

Year: 2012 PMID： 22645132 PMCID： PMC3397878 DOI： 10.1074/jbc.M112.380139

Source DB: PubMed Journal: J Biol Chem ISSN： 0021-9258 Impact factor: 5.157

28 in total

Review 1. Membrane assembly of the cholesterol-dependent cytolysin pore complex.

Authors: Eileen M Hotze; Rodney K Tweten
Journal: Biochim Biophys Acta Date: 2011-07-31

2. Molecular basis of listeriolysin O pH dependence.

Authors: Daniel W Schuerch; Elizabeth M Wilson-Kubalek; Rodney K Tweten
Journal: Proc Natl Acad Sci U S A Date: 2005-08-16 Impact factor: 11.205

Review 3. Protein misfolding, functional amyloid, and human disease.

Authors: Fabrizio Chiti; Christopher M Dobson
Journal: Annu Rev Biochem Date: 2006 Impact factor: 23.643

Review 4. Amyloid formation by globular proteins under native conditions.

Authors: Fabrizio Chiti; Christopher M Dobson
Journal: Nat Chem Biol Date: 2009-01 Impact factor: 15.040

5. Structure of human C8 protein provides mechanistic insight into membrane pore formation by complement.

Authors: Leslie L Lovelace; Christopher L Cooper; James M Sodetz; Lukasz Lebioda
Journal: J Biol Chem Date: 2011-03-25 Impact factor: 5.157

6. Structure of a cholesterol-binding, thiol-activated cytolysin and a model of its membrane form.

Authors: J Rossjohn; S C Feil; W J McKinstry; R K Tweten; M W Parker
Journal: Cell Date: 1997-05-30 Impact factor: 41.582

7. Crystallization and preliminary X-ray analysis of a thiol-activated cytolysin.

Authors: S C Feil; J Rossjohn; K Rohde; R K Tweten; M W Parker
Journal: FEBS Lett Date: 1996-11-18 Impact factor: 4.124

8. Identification of a membrane-spanning domain of the thiol-activated pore-forming toxin Clostridium perfringens perfringolysin O: an alpha-helical to beta-sheet transition identified by fluorescence spectroscopy.

Authors: L A Shepard; A P Heuck; B D Hamman; J Rossjohn; M W Parker; K R Ryan; A E Johnson; R K Tweten
Journal: Biochemistry Date: 1998-10-13 Impact factor: 3.162

9. Structural basis of pore formation by the bacterial toxin pneumolysin.

Authors: Sarah J Tilley; Elena V Orlova; Robert J C Gilbert; Peter W Andrew; Helen R Saibil
Journal: Cell Date: 2005-04-22 Impact factor: 41.582

Review 10. The MACPF/CDC family of pore-forming toxins.

Authors: Carlos J Rosado; Stephanie Kondos; Tara E Bull; Michael J Kuiper; Ruby H P Law; Ashley M Buckle; Ilia Voskoboinik; Phillip I Bird; Joseph A Trapani; James C Whisstock; Michelle A Dunstone
Journal: Cell Microbiol Date: 2008-06-28 Impact factor: 3.715

28 in total

1. An intermolecular electrostatic interaction controls the prepore-to-pore transition in a cholesterol-dependent cytolysin.

Authors: Kristin R Wade; Eileen M Hotze; Michael J Kuiper; Craig J Morton; Michael W Parker; Rodney K Tweten
Journal: Proc Natl Acad Sci U S A Date: 2015-02-02 Impact factor: 11.205

2. Real-time visualization of perforin nanopore assembly.

Authors: Carl Leung; Adrian W Hodel; Amelia J Brennan; Natalya Lukoyanova; Sharon Tran; Colin M House; Stephanie C Kondos; James C Whisstock; Michelle A Dunstone; Joseph A Trapani; Ilia Voskoboinik; Helen R Saibil; Bart W Hoogenboom
Journal: Nat Nanotechnol Date: 2017-02-06 Impact factor: 39.213

3. The Cholesterol-dependent Cytolysin Membrane-binding Interface Discriminates Lipid Environments of Cholesterol to Support β-Barrel Pore Insertion.

Authors: Allison J Farrand; Eileen M Hotze; Takehiro K Sato; Kristin R Wade; William C Wimley; Arthur E Johnson; Rodney K Tweten
Journal: J Biol Chem Date: 2015-06-01 Impact factor: 5.157

4. Crucial role of perfringolysin O D1 domain in orchestrating structural transitions leading to membrane-perforating pores: a hydrogen-deuterium exchange study.

Authors: Aleksandra Kacprzyk-Stokowiec; Magdalena Kulma; Gabriela Traczyk; Katarzyna Kwiatkowska; Andrzej Sobota; Michał Dadlez
Journal: J Biol Chem Date: 2014-08-27 Impact factor: 5.157

5. Stonefish toxin defines an ancient branch of the perforin-like superfamily.

Authors: Andrew M Ellisdon; Cyril F Reboul; Santosh Panjikar; Kitmun Huynh; Christine A Oellig; Kelly L Winter; Michelle A Dunstone; Wayne C Hodgson; Jamie Seymour; Peter K Dearden; Rodney K Tweten; James C Whisstock; Sheena McGowan
Journal: Proc Natl Acad Sci U S A Date: 2015-12-01 Impact factor: 11.205