We model the evolution of simple lattice proteins as a random walk in a fitness landscape, where the fitness represents the ability of the protein to fold. At higher selective pressure, the evolutionary trajectories are confined to neutral networks where the native structure is conserved and the dynamics are non self-averaging and nonexponential. The optimizability of the corresponding native structure has a strong effect on the size of these neutral networks and thus on the nature of the evolutionary process. Proteins 29:461–466, 1997. © 1997 Wiley-Liss, Inc.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/38527/1/6_ftp.pd

Allaart

Arevalo

Azzi

Baker

Bally

Beauchamp

Beck

Bernstein

Bertina

Bocchinfuso

Borgel

Branden

Castaman

Chang

Comp

Dahlbäck

Dayhoff

DiScipio

Duchemin

Dunkel

Ehrig

Faioni

Fair

Fernández

Formstone

Fortunati

Fujiwara

Gandrille

García de Frutos

Garrison

Gershagen

Ghosh

Girolami

Goruppi

Gray

Greengard

Griffin

Gómez

Hammond

Heeb

Hennessey

Higgins

Hildebrand

Hillarp

Härdig

Jackson

Joseph

Kabsch

Kahn

Koppelman

Kusche-Gullberg

Levitt

Lijnzaad

Linse

Lundwall

Malm

Manfioletti

Martin

Matthews

Mustafa

Nakano

Needleman

Nelson

Nisker

Nomizu

Ohashi

Olsen

Patthy

Petra

Poch

Power

Rost

Sasaki

Proteins Structure Function and Bioinformatics

Walker

Schwarz

Zöller

Stitt

Varnum

Yamazaki

Simmonds

Vrielink

Yurchenco

Thompson

Yang

Sreerama

Scholtz

Schmidel

Crossref

SHBG region of the anticoagulant cofactor protein S: Secondary structure prediction, circular dichroism spectroscopy, and analysis of naturally occurring mutations

A partly folded state of hen egg-white lysozyme has been characterized in 50% DMSO. Low concentrations of DMSO (&lt;10%) have little effect on the overall folded conformation of lysozyme as seen from 1H NMR chemical shift dispersion. At increasing DMSO concentrations (&gt;10%) a cooperative transition of the structure to a new, partially folded state is observed. This transition is essentially complete by ~50% DMSO. NMR studies show an overall decrease in chemical shift dispersion with marked broadening of many resonances. A substantial number of backbone and side chain-side chain NOEs suggests the presence of secondary and tertiary interactions in the intermediate state. Tertiary organization of the aromatic residues is also demonstrated by enhanced near-UV circular dichroism and limited exposure of tryptophans as monitored by iodide quenching of fluorescence. The intermediate state exhibits enhanced binding to hydrophobic dyes. Further, the structural transition from this state to a largely unfolded conformation is cooperative. H/D exchange rates of several amide protons and four indole protons of tryptophans (W28, W108, W111, and W123), measured by refolding from 50% DMSO at different time intervals reveal that protection factors are high for the helical domain, whereas NH groups in the triple stranded antiparallel &#946;-sheet domain are largely solvent-exposed. An ordered hydrophobic core in the intermediate state comprising of helix A, helix B, and helix D is consistent with the high protection factors observed. The structured intermediate in 50% DMSO resembles the early kinetic intermediate observed in the refolding of hen egg white lysozyme, as well as a molten globule state of equine lysozyme at low pH. The results demonstrate the potential use of nonaqueous structure perturbing solvents like DMSO to stabilize partially folded conformations of proteins

Bhattacharjya, Surajit

Balaram, P.

Publications of the IAS Fellows

English

Effects of organic solvents on protein structures: observation of a structured helical core in hen egg-white lysozyme in aqueous dimethylsulfoxide

Govindarajan, Sridhar

Goldstein, Richard A.

Deep Blue Documents at the University of Michigan

Evolution of model proteins on a foldability landscape

Interleukin-6 (IL-6) is a multifunctional cytokine that regulates cell growth, differentiation, and cellular functions in many cell lineages, Recently, evidences for the formation of an active hexameric complex with an IL-6:IL-6R alpha:gp130 stoichiometry of 2:2:2 have been obtained by different experimental approaches, Analysis of the electrostatic potential complementarity between IL-6 and its receptors has been used, in this study to guide the assembly of homology-based 3D models of the components, The results strongly support a mechanism whereby the active cytokine (IL-6: IL-6R alpha) associates with the signal transducing gp130 protein, and the trimeric complex formed further dimerizes to form the hexameric species. Furthermore, computational simulations of the multiprotein complexes provide a rationalization of data from mutation experiments and highlight some key protein-protein interactions which have not yet been the subject of mutagenesis studies

Evolution of model proteins on a foldability landscape

Abstract

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Publications of the IAS Fellows

Deep Blue Documents at the University of Michigan

Archivio istituzionale della ricerca - Università di Modena e Reggio Emilia

Indian Academy of Sciences