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Literature DB >> 22509487

FoldEco: a model for proteostasis in E. coli.

Evan T Powers¹, David L Powers, Lila M Gierasch.

Abstract

To gain insight into the interplay of processes and species that maintain a correctly folded, functional proteome, we have developed a computational model called FoldEco. FoldEco models the cellular proteostasis network of the E. coli cytoplasm, including protein synthesis, degradation, aggregation, chaperone systems, and the folding characteristics of protein clients. We focused on E. coli because much of the needed input information--including mechanisms, rate parameters, and equilibrium coefficients--is available, largely from in vitro experiments; however, FoldEco will shed light on proteostasis in other organisms. FoldEco can generate hypotheses to guide the design of new experiments. Hypothesis generation leads to system-wide questions and shows how to convert these questions to experimentally measurable quantities, such as changes in protein concentrations with chaperone or protease levels, which can then be used to improve our current understanding of proteostasis and refine the model. A web version of FoldEco is available at http://foldeco.scripps.edu.

Entities: Chemical Disease Gene Species

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Year: 2012 PMID： 22509487 PMCID： PMC3324317 DOI： 10.1016/j.celrep.2012.02.011

Source DB: PubMed Journal: Cell Rep Impact factor: 9.423

46 in total

1. Multistep mechanism of substrate binding determines chaperone activity of Hsp70.

Authors: M P Mayer; H Schröder; S Rüdiger; K Paal; T Laufen; B Bukau
Journal: Nat Struct Biol Date: 2000-07

2. Small heat shock proteins, ClpB and the DnaK system form a functional triade in reversing protein aggregation.

Authors: Axel Mogk; Elke Deuerling; Sonja Vorderwülbecke; Elizabeth Vierling; Bernd Bukau
Journal: Mol Microbiol Date: 2003-10 Impact factor: 3.501

3. An adaptable standard for protein export from the endoplasmic reticulum.

Authors: R Luke Wiseman; Evan T Powers; Joel N Buxbaum; Jeffery W Kelly; William E Balch
Journal: Cell Date: 2007-11-16 Impact factor: 41.582

4. GroEL stimulates protein folding through forced unfolding.

Authors: Zong Lin; Damian Madan; Hays S Rye
Journal: Nat Struct Mol Biol Date: 2008-03-02 Impact factor: 15.369

5. DnaK-mediated association of ClpB to protein aggregates. A bichaperone network at the aggregate surface.

Authors: Sergio P Acebrón; Ianire Martín; Urko del Castillo; Fernando Moro; Arturo Muga
Journal: FEBS Lett Date: 2009-08-19 Impact factor: 4.124

6. GroEL/GroES cycling: ATP binds to an open ring before substrate protein favoring protein binding and production of the native state.

Authors: Navneet K Tyagi; Wayne A Fenton; Arthur L Horwich
Journal: Proc Natl Acad Sci U S A Date: 2009-11-13 Impact factor: 11.205

7. Site-specific modification of Alzheimer's peptides by cholesterol oxidation products enhances aggregation energetics and neurotoxicity.

Authors: Kenji Usui; John D Hulleman; Johan F Paulsson; Sarah J Siegel; Evan T Powers; Jeffery W Kelly
Journal: Proc Natl Acad Sci U S A Date: 2009-10-19 Impact factor: 11.205

8. Catapult mechanism renders the chaperone action of Hsp70 unidirectional.

Authors: S M Gisler; E V Pierpaoli; P Christen
Journal: J Mol Biol Date: 1998-06-19 Impact factor: 5.469

Review 9. Molecular chaperones in protein folding and proteostasis.

Authors: F Ulrich Hartl; Andreas Bracher; Manajit Hayer-Hartl
Journal: Nature Date: 2011-07-20 Impact factor: 49.962

10. The global transcriptional response of Escherichia coli to induced sigma 32 protein involves sigma 32 regulon activation followed by inactivation and degradation of sigma 32 in vivo.

Authors: Kai Zhao; Mingzhu Liu; Richard R Burgess
Journal: J Biol Chem Date: 2005-03-09 Impact factor: 5.157

37 in total

1. Protein folding in the cell, from atom to organism.

Authors: Jeffrey L Brodsky; Patricia L Clark
Journal: FASEB J Date: 2014-12 Impact factor: 5.191

Review 2. Viewing protein fitness landscapes through a next-gen lens.

Authors: Jeffrey I Boucher; Pamela Cote; Julia Flynn; Li Jiang; Aneth Laban; Parul Mishra; Benjamin P Roscoe; Daniel N A Bolon
Journal: Genetics Date: 2014-10 Impact factor: 4.562

3. Individual and collective contributions of chaperoning and degradation to protein homeostasis in E. coli.

Authors: Younhee Cho; Xin Zhang; Kristine Faye R Pobre; Yu Liu; David L Powers; Jeffery W Kelly; Lila M Gierasch; Evan T Powers
Journal: Cell Rep Date: 2015-04-02 Impact factor: 9.423

4. Kinetic versus thermodynamic control of mutational effects on protein homeostasis: A perspective from computational modeling and experiment.

Authors: Kristine Faye R Pobre; David L Powers; Kingshuk Ghosh; Lila M Gierasch; Evan T Powers
Journal: Protein Sci Date: 2019-05-24 Impact factor: 6.725

10. Folding and Misfolding of Human Membrane Proteins in Health and Disease: From Single Molecules to Cellular Proteostasis.

Authors: Justin T Marinko; Hui Huang; Wesley D Penn; John A Capra; Jonathan P Schlebach; Charles R Sanders
Journal: Chem Rev Date: 2019-01-04 Impact factor: 60.622