Principles for Designing Ideal Protein Structures

Overview

Journal Nature

Specialty Science

Date 2012 Nov 9

PMID 23135467

Citations 268

Authors

Nobuyasu Koga

Rie Tatsumi-Koga

Gaohua Liu

Rong Xiao

Thomas B Acton

Gaetano T Montelione

David Baker

Affiliations

Soon will be listed here.

Abstract

Unlike random heteropolymers, natural proteins fold into unique ordered structures. Understanding how these are encoded in amino-acid sequences is complicated by energetically unfavourable non-ideal features--for example kinked α-helices, bulged β-strands, strained loops and buried polar groups--that arise in proteins from evolutionary selection for biological function or from neutral drift. Here we describe an approach to designing ideal protein structures stabilized by completely consistent local and non-local interactions. The approach is based on a set of rules relating secondary structure patterns to protein tertiary motifs, which make possible the design of funnel-shaped protein folding energy landscapes leading into the target folded state. Guided by these rules, we designed sequences predicted to fold into ideal protein structures consisting of α-helices, β-strands and minimal loops. Designs for five different topologies were found to be monomeric and very stable and to adopt structures in solution nearly identical to the computational models. These results illuminate how the folding funnels of natural proteins arise and provide the foundation for engineering a new generation of functional proteins free from natural evolution.

Citing Articles

Protein superfolds are characterised as frustration-free topologies: A case study of pure parallel β-sheet topologies.

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Validation of de novo designed water-soluble and transmembrane β-barrels by in silico folding and melting.

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