Biophysical Models of Protein Evolution: Understanding the Patterns of Evolutionary Sequence Divergence
For decades, rates of protein evolution have been interpreted in terms of the vague concept of functional importance. Slowly evolving proteins or sites within proteins were assumed to be more functionally important and thus subject to stronger selection pressure. More recently, biophysical models of...
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| Published in | Annual review of biophysics Vol. 46; p. 85 |
|---|---|
| Main Authors | , |
| Format | Journal Article |
| Language | English |
| Published |
United States
22.05.2017
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| Online Access | Get more information |
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| Abstract | For decades, rates of protein evolution have been interpreted in terms of the vague concept of functional importance. Slowly evolving proteins or sites within proteins were assumed to be more functionally important and thus subject to stronger selection pressure. More recently, biophysical models of protein evolution, which combine evolutionary theory with protein biophysics, have completely revolutionized our view of the forces that shape sequence divergence. Slowly evolving proteins have been found to evolve slowly because of selection against toxic misfolding and misinteractions, linking their rate of evolution primarily to their abundance. Similarly, most slowly evolving sites in proteins are not directly involved in function, but mutating these sites has a large impact on protein structure and stability. In this article, we review the studies in the emerging field of biophysical protein evolution that have shaped our current understanding of sequence divergence patterns. We also propose future research directions to develop this nascent field. |
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| AbstractList | For decades, rates of protein evolution have been interpreted in terms of the vague concept of functional importance. Slowly evolving proteins or sites within proteins were assumed to be more functionally important and thus subject to stronger selection pressure. More recently, biophysical models of protein evolution, which combine evolutionary theory with protein biophysics, have completely revolutionized our view of the forces that shape sequence divergence. Slowly evolving proteins have been found to evolve slowly because of selection against toxic misfolding and misinteractions, linking their rate of evolution primarily to their abundance. Similarly, most slowly evolving sites in proteins are not directly involved in function, but mutating these sites has a large impact on protein structure and stability. In this article, we review the studies in the emerging field of biophysical protein evolution that have shaped our current understanding of sequence divergence patterns. We also propose future research directions to develop this nascent field. |
| Author | Echave, Julian Wilke, Claus O |
| Author_xml | – sequence: 1 givenname: Julian surname: Echave fullname: Echave, Julian email: julian.echave@unsam.edu.ar organization: Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), Argentina – sequence: 2 givenname: Claus O surname: Wilke fullname: Wilke, Claus O email: wilke@austin.utexas.edu organization: Department of Integrative Biology, The University of Texas at Austin, Texas 78712; email: wilke@austin.utexas.edu |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/28301766$$D View this record in MEDLINE/PubMed |
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| SubjectTerms | Biophysical Phenomena Biophysics Evolution, Molecular Genetic Fitness Humans Mutation Protein Folding Protein Stability Proteins - chemistry Proteins - genetics Thermodynamics |
| Title | Biophysical Models of Protein Evolution: Understanding the Patterns of Evolutionary Sequence Divergence |
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