The interface of protein structure, protein biophysics, and molecular evolution

Liberles, David A.; Teichmann, Sarah A.; Bahar, İvet; Bastolla, Ugo; Bloom, Jesse D.; Bornberg‐Bauer, Erich; Colwell, Lucy; Koning, A. P. Jason de; Dokholyan, Nikolay V.; Echave, Julián; Elofsson, Arne; Gerloff, Dietlind L.; Goldstein, Richard A.; Grahnen, Johan A.; Holder, Mark T.; Lakner, Clemens; Lartillot, Nicholas; Lovell, Simon C.; Naylor, Gavin J. P.; Perica, Tina; Pollock, David D.; Pupko, Tal; Regan, Lynne; Roger, Andrew J.; Rubinstein, Nimrod D.; Shakhnovich, Eugene I.; Sjölander, Kimmen; Sunyaev, Shamil; Teufel, Ashley I.; Thorne, Jeffrey L.; Thornton, Joseph W.; Weinreich, Daniel; Whelan, Simon

doi:10.1002/pro.2071

Cited by 201 publications

(182 citation statements)

References 150 publications

Supporting

Mentioning

175

Contrasting

Order By: Relevance

“…Its apparent helpfulness in contributing to prediction of the locations of the common amino acids in folded proteins agrees with the well-established closepacking of amino acid side-chains in proteins, in which large and small amino acids differ in their structural requirements (35). The finding that the core/surface distributions of the 20 amino acids can be better approximated using two complementary types of solvent transfer free energies seems likely to be useful in protein design and phylogenetics (36), by identifying suitable amino acid substitutions.…”

Section: Relationship Between Side-chain Transfer Equilibria and Proteinsupporting

confidence: 71%

Temperature dependence of amino acid hydrophobicities

Wolfenden

Lewis

Yuan

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

The hydrophobicities of the 20 common amino acids are reflected in their tendencies to appear in interior positions in globular proteins and in deeply buried positions of membrane proteins. To determine whether these relationships might also have been valid in the warm surroundings where life may have originated, we examined the effect of temperature on the hydrophobicities of the amino acids as measured by the equilibrium constants for transfer of their side-chains from neutral solution to cyclohexane (K w>c ). The hydrophobicities of most amino acids were found to increase with increasing temperature. Because that effect is more pronounced for the more polar amino acids, the numerical range of K w>c values decreases with increasing temperature. There are also modest changes in the ordering of the more polar amino acids. However, those changes are such that they would have tended to minimize the otherwise disruptive effects of a changing thermal environment on the evolution of protein structure. Earlier, the genetic code was found to be organized in such a way that-with a single exception (threonine)-the side-chain dichotomy polar/ nonpolar matches the nucleic acid base dichotomy purine/pyrimidine at the second position of each coding triplet at 25°C. That dichotomy is preserved at 100°C. The accessible surface areas of amino acid side-chains in folded proteins are moderately correlated with hydrophobicity, but when free energies of vapor-tocyclohexane transfer (corresponding to size) are taken into consideration, a closer relationship becomes apparent.T he equilibrium conformations of proteins in neutral solution are strongly influenced by interactions between their constituent amino acids and solvent water. Early work on the crystal structure of hemoglobin and related proteins showed that the side-chains of the more polar amino acid residues tend to be exposed to solvent, whereas less polar side-chains tend to be buried within the interior of globular proteins (1). Later, those tendencies were put to a quantitative test by measuring equilibria of transfer of amino acid side-chains from neutral aqueous solution into less polar environments, such as the vapor phase (2, 3) or a nonpolar solvent such as cyclohexane (4), which dissolves only ∼2 × 10 −3 M water at saturation (5) and appears to be devoid of specific interactions with solutes. The water-to-cyclohexane distribution coefficients (K w>c ) of the 20 common sidechains [here termed "hydrophobicities" (6, 7) and expressed in concentration units of mol/L in each phase; SI Appendix] were found to span a range of 15 orders of magnitude at pH 7 and 25°C. Values of K w>c have been shown to be related to their outside-to-inside distributions in globular proteins (4,8) and to their tendencies to appear within the buried sequences of transmembrane proteins (9-11).Those solvent distribution experiments were conducted at what we would consider ordinary temperatures. However, there is widespread (12, 13)-if not universal (14)-agreement that life originated when the ea...

show abstract

Section: Relationship Between Side-chain Transfer Equilibria and Proteinsupporting

confidence: 71%

Temperature dependence of amino acid hydrophobicities

Wolfenden

Lewis

Yuan

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

View full text Add to dashboard Cite

show abstract

“…Particularly in the case of TEM-1, the stabilizing mutation M182T has been shown to be beneficial in the hydrolysis spectrum extension of the enzyme, only when some destabilizing mutations in the active site were present (25,26). However, the in vitro stability of these enzymes with modified active site is lower than -4 kcal/mol, suggesting that the effect of M182T should be marginal, and "challenging the notion that evolution is a balance between structure and function" (36). Our estimation of a much lower in vitro stability appears to be more compatible with the apparent selective pressures for stabilizing mutations, and may therefore suggest some limitations of the in vitro estimation of stability, at least in the case of TEM-1.…”

Section: A Simple Model Of Protein Stability Accounts For Changes In Thementioning

confidence: 99%

Capturing the mutational landscape of the beta-lactamase TEM-1

Jacquier

Birgy

Nagard

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

236

279

View full text Add to dashboard Cite

Adaptation proceeds through the selection of mutations. The distribution of mutant fitness effect and the forces shaping this distribution are therefore keys to predict the evolutionary fate of organisms and their constituents such as enzymes. Here, by producing and sequencing a comprehensive collection of 10,000 mutants, we explore the mutational landscape of one enzyme involved in the spread of antibiotic resistance, the beta-lactamase TEM-1. We measured mutation impact on the enzyme activity through the estimation of amoxicillin minimum inhibitory concentration on a subset of 990 mutants carrying a unique missense mutation, representing 64% of possible amino acid changes in that protein reachable by point mutation. We established that mutation type, solvent accessibility of residues, and the predicted effect of mutations on protein stability primarily determined alone or in combination changes in minimum inhibitory concentration of mutants. Moreover, we were able to capture the drastic modification of the mutational landscape induced by a single stabilizing point mutation (M182T) by a simple model of protein stability. This work thereby provides an integrated framework to study mutation effects and a tool to understand/define better the epistatic interactions.epistasis | adaptive landscape | distribution of fitness effects T he distribution of fitness effects (DFE) of mutations is central in evolutionary biology. It captures the intensity of the selective constraints acting on an organism and therefore how the interplay between mutation, genetic drift, and selection will shape the evolutionary fate of populations (1). For instance, the DFE determines the size of the population required to see fitness increase or decrease (2

show abstract

“…Therefore, in recent years, there has been a drive to integrate the fields of protein biophysics and molecular evolution in order to better understand protein evolution (Harms and Thornton 2013;Liberles et al 2012;Serohijos and Shakhnovich 2014;Soskine and Tawfik 2010). One technique that has proved particularly useful in this pursuit is ancestral sequence reconstruction (ASR).…”

Section: Introductionmentioning

confidence: 99%

Reconstructed Ancestral Enzymes Impose a Fitness Cost upon Modern Bacteria Despite Exhibiting Favourable Biochemical Properties

et al. 2015

View full text Add to dashboard Cite

Ancestral sequence reconstruction has been widely used to study historical enzyme evolution, both from biochemical and cellular perspectives. Two properties of reconstructed ancestral proteins/enzymes are commonly reported-high thermostability and high catalytic activity-compared with their contemporaries. Increased protein stability is associated with lower aggregation rates, higher soluble protein abundance and a greater capacity to evolve, and therefore, these proteins could be considered ''superior'' to their contemporary counterparts. In this study, we investigate the relationship between the favourable in vitro biochemical properties of reconstructed ancestral enzymes and the organismal fitness they confer in vivo. We have previously reconstructed several ancestors of the enzyme LeuB, which is essential for leucine biosynthesis. Our initial fitness experiments revealed that overexpression of ANC4, a reconstructed LeuB that exhibits high stability and activity, was only able to partially rescue the growth of a DleuB strain, and that a strain complemented with this enzyme was outcompeted by strains carrying one of its descendants. When we expanded our study to include five reconstructed LeuBs and one contemporary, we found that neither in vitro protein stability nor the catalytic rate was correlated with fitness. Instead, fitness showed a strong, negative correlation with estimated evolutionary age (based on phylogenetic relationships). Our findings suggest that, for reconstructed ancestral enzymes, superior in vitro properties do not translate into organismal fitness in vivo. The molecular basis of the relationship between fitness and the inferred age of ancestral LeuB enzymes is unknown, but may be related to the reconstruction process. We also hypothesise that the ancestral enzymes may be incompatible with the other, contemporary enzymes of the metabolic network.

show abstract

The interface of protein structure, protein biophysics, and molecular evolution

Cited by 201 publications

References 150 publications

Temperature dependence of amino acid hydrophobicities

Temperature dependence of amino acid hydrophobicities

Capturing the mutational landscape of the beta-lactamase TEM-1

Reconstructed Ancestral Enzymes Impose a Fitness Cost upon Modern Bacteria Despite Exhibiting Favourable Biochemical Properties

Contact Info

Product

Resources

About