AI Article Synopsis
- Computational protein design (CPD) enhances protein engineering by creating proteins with desirable traits like increased thermostability, better binding, and new enzymatic functions.
- The traditional single-state design (SSD) method limits design to a single protein backbone, which can be insufficient for achieving more complex protein functions that require multiple states.
- The emerging multistate design (MSD) approach allows for the incorporation of multiple conformational and chemical states, offering advantages for tasks such as designing protein flexibility and specificity in binding, while also highlighting challenges like scoring competing states in the design process.
Article Abstract
Computational protein design (CPD) is a useful tool for protein engineers. It has been successfully applied towards the creation of proteins with increased thermostability, improved binding affinity, novel enzymatic activity, and altered ligand specificity. Traditionally, CPD calculations search and rank sequences using a single fixed protein backbone template in an approach referred to as single-state design (SSD). While SSD has enjoyed considerable success, certain design objectives require the explicit consideration of multiple conformational and/or chemical states. Cases where a "multistate" approach may be advantageous over the SSD approach include designing conformational changes into proteins, using native ensembles to mimic backbone flexibility, and designing ligand or oligomeric association specificities. These design objectives can be efficiently tackled using multistate design (MSD), an emerging methodology in CPD that considers any number of protein conformational or chemical states as inputs instead of a single protein backbone template, as in SSD. In this review article, recent examples of the successful design of a desired property into proteins using MSD are described. These studies employing MSD are divided into two categories--those that utilized multiple conformational states, and those that utilized multiple chemical states. In addition, the scoring of competing states during negative design is discussed as a current challenge for MSD.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3631354 | PMC |
| http://dx.doi.org/10.1002/pro.2128 | DOI Listing |
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