Design rules for the self-assembly of a protein crystal

Asherie; Babu; Berman; Caspar; Chung; Costa; Doye; Fejer; Fejer; Fortini; Galkin; Galkin; Gast; George; Gibaud; Gorti; Hagan; Hedges; Hu; Kern; Kulkarni; Liu; Liu; Liu; McManus; Muschol; Norville; Pagan; Pan; Panagiotopoulos; Rapaport; Romano; Romano; Rosenbaum; Rosenbaum; Rosenbaum; Sleytr; Sleytr; Sleytr; Soga; Stephen Whitelam; Talanquer; ten Wolde; Thomas K. Haxton; van Workum; Vekilov; Vekilov; Whitelam; Whitelam; Wilber; Wilson; Zhang

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Design rules for the self-assembly of a protein crystal

Authors: Asherie
Babu
Berman
Caspar
Chung
Costa
Doye
Fejer
Fejer
Fortini
Galkin
Galkin
Gast
George
Gibaud
Gorti
Hagan
Hedges
Hu
Kern
Kulkarni
Liu
Liu
Liu
McManus
Muschol
Norville
Pagan
Pan
Panagiotopoulos
Rapaport
Romano
Romano
Rosenbaum
Rosenbaum
Rosenbaum
Sleytr
Sleytr
Sleytr
Soga
Stephen Whitelam
Talanquer
ten Wolde
Thomas K. Haxton
van Workum
Vekilov
Vekilov
Whitelam
Whitelam
Wilber
Wilson
Zhang
Publication date: 25 October 2011
Publisher: 'Royal Society of Chemistry (RSC)'
Doi

Abstract

Theories of protein crystallization based on spheres that form close-packed crystals predict optimal assembly within a `slot' of second virial coefficients and enhanced assembly near the metastable liquid-vapor critical point. However, most protein crystals are open structures stabilized by anisotropic interactions. Here, we use theory and simulation to show that assembly of one such structure is not predicted by the second virial coefficient or enhanced by the critical point. Instead, good assembly requires that the thermodynamic driving force be on the order of the thermal energy and that interactions be made as nonspecific as possible without promoting liquid-vapor phase separation.Comment: 5 pages, 4 figure

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info:doi/10.1039%2Fc2sm07436b

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