Impact of in vivo protein folding probability on local fitness landscapes

Faber, Matthew S.; Wrenbeck, Emily E.; Azouz, Laura R.; Steiner, Paul J; Whitehead, Timothy A.

doi:10.1101/590398

Cited by 4 publications

(4 citation statements)

References 47 publications

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“…The analogous behavior observed for these mutants in E. coli and correlation of misfolding effects with phylogenetic conservation is consistent with a selective pressure to avoid misfolding in vivo and with growing evidence that kinetic factors affect stable protein expression in cells (Fig. 3K) ( 20, 26, 60, 61 ). The strong dependence of activity on temperature and Zn 2+ concentration present during expression suggests that mutations promoting formation of the inactive state may disrupt co-translational folding ( 20, 62 ).…”

Section: Discussionsupporting

confidence: 81%

Revealing enzyme functional architecture via high-throughput microfluidic enzyme kinetics

Markin¹,

Mokhtari²,

Sunden³

et al. 2020

Preprint

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Systematic and extensive investigation of enzymes is needed to understand their extraordinary efficiency and meet current challenges in medicine and engineering. We present HT-MEK, a microfluidic platform for high-throughput expression, purification, and characterization of >1500 enzyme variants per experiment. For 1036 mutants of the alkaline phosphatase PafA, we performed >670,000 reactions to determine >5000 kinetic and physical constants for multiple substrates and inhibitors. These constants allowed us to uncover extensive kinetic partitioning to a misfolded state and isolate catalytic effects, revealing spatially contiguous “regions” of residues linked to particular aspects of function. These regions included active-site proximal residues but also extended to the enzyme surface, providing a map of underlying architecture that could not be derived from existing approaches. HT-MEK, using direct and coupled fluorescent assays, has future applications to a wide variety of problems ranging from understanding molecular mechanisms to medicine to engineering and design.One Sentence SummaryHT-MEK, a microfluidic platform for high-throughput, quantitative biochemistry, reveals enzyme architectures shaping function.

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Section: Discussionsupporting

confidence: 81%

Revealing enzyme functional architecture via high-throughput microfluidic enzyme kinetics

Markin¹,

Mokhtari²,

Sunden³

et al. 2020

Preprint

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“…At least two factors might hamper the success of sequence alignments for predicting substitution outcomes. First, most extant homologs differ at multiple positions, and non-additivity among some subsets of substitutions ("epistasis") can confound detection of signals associated with single amino acid changes (e.g., [34][35][36][37][38][39][40][41] ). Second, the rheostat/toggle/neutral character of a position could change during evolution (i.e., differ among homologs).…”

Section: Discussionmentioning

confidence: 99%

Rheostat functional outcomes occur when substitutions are introduced at nonconserved positions that diverge with speciation

et al. 2021

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When amino acids vary during evolution, the outcome can be functionally neutral or biologically‐important. We previously found that substituting a subset of nonconserved positions, “rheostat” positions, can have surprising effects on protein function. Since changes at rheostat positions can facilitate functional evolution or cause disease, more examples are needed to understand their unique biophysical characteristics. Here, we explored whether “phylogenetic” patterns of change in multiple sequence alignments (such as positions with subfamily specific conservation) predict the locations of functional rheostat positions. To that end, we experimentally tested eight phylogenetic positions in human liver pyruvate kinase (hLPYK), using 10–15 substitutions per position and biochemical assays that yielded five functional parameters. Five positions were strongly rheostatic and three were non‐neutral. To test the corollary that positions with low phylogenetic scores were not rheostat positions, we combined these phylogenetic positions with previously‐identified hLPYK rheostat, “toggle” (most substitution abolished function), and “neutral” (all substitutions were like wild‐type) positions. Despite representing 428 variants, this set of 33 positions was poorly statistically powered. Thus, we turned to the in vivo phenotypic dataset for E. coli lactose repressor protein (LacI), which comprised 12–13 substitutions at 329 positions and could be used to identify rheostat, toggle, and neutral positions. Combined hLPYK and LacI results show that positions with strong phylogenetic patterns of change are more likely to exhibit rheostat substitution outcomes than neutral or toggle outcomes. Furthermore, phylogenetic patterns were more successful at identifying rheostat positions than were co‐evolutionary or eigenvector centrality measures of evolutionary change.

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“…It is clear that epistasis is pervasive in real proteins, but its effect on evolution and the extent of higher-order interactions remains murky. Studies of single-site mutant libraries (32)(33)(34)(35)(36)(37)(38)(39)(40)(41)(42) and case studies of historical substitutions (43)(44)(45)(46)(47)(48)(49) have shown that mutations' effects often depend on the sequence background in which they occur. Studies that measure the effects of many pairs of mutations on a single function have shown that pairwise interactions reduce the accessibility of some two-step paths from a designated wildtype protein (50)(51)(52)(53).…”

Section: Introductionmentioning

confidence: 99%

“…Epistasis is clearly present in the genetic architecture of proteins (32)(33)(34)(35)(36)(37)(38)(39)(40)(41)(42)(43)(44)(45)(46)(47)(48)(49), but its overall character and effects on evolutionary trajectories remain murky. Studies of pairs of mutations show that pairwise interactions can block some twostep paths around a designated wild-type protein (50)(51)(52)(53) and experiments on higher-order combinations have found that epistasis can reduce the number of functional intermediates that connect a designated pair of starting and ending proteins (54)(55)(56)(57)(58)(59)(60)(61)(62).…”

Section: Introductionmentioning

confidence: 99%

Epistasis facilitates functional evolution in an ancient transcription factor

Metzger

Park

Starr

2023

Preprint

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A protein's genetic architecture - the set of causal rules by which its sequence determines its specific functions - also determines the functional impacts of mutations and the protein's possible evolutionary trajectories. Prior research has proposed that proteins' genetic architecture is very complex, with pervasive epistatic interactions that constrain evolution and make function difficult to predict from sequence. Most of this work has considered only the amino acid states present in two sequences of interest and the direct paths between them, but real proteins evolve in a multidimensional space of 20 possible amino acids per site. Moreover, almost all prior work has assayed the effect of sequence variation on a single protein function, leaving unaddressed the genetic architecture of functional specificity and its impacts on the evolution of new functions. Here we develop a new logistic regression-based method to directly characterize the global genetic determinants of multiple protein functions from 20-state combinatorial deep mutational scanning (DMS) experiments. We apply it to dissect the genetic architecture and evolution of a transcription factor's specificity for DNA, using data from a combinatorial DMS of an ancient steroid hormone receptor's capacity to activate transcription from two biologically relevant DNA elements. We show that the genetic architecture of DNA recognition and specificity consists of a dense set of main and pairwise effects that involve virtually every possible amino acid state in the protein-DNA interface, but higher-order epistasis plays only a tiny role. Pairwise interactions enlarge the set of functional sequences and are the primary determinants of specificity for different DNA elements. Epistasis also massively expands the number of opportunities for single-residue mutations to switch specificity from one DNA target to another. By bringing variants with different functions close together in sequence space, pairwise epistasis therefore facilitates rather than constrains the evolution of new functions.

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Impact of in vivo protein folding probability on local fitness landscapes

Cited by 4 publications

References 47 publications

Revealing enzyme functional architecture via high-throughput microfluidic enzyme kinetics

Revealing enzyme functional architecture via high-throughput microfluidic enzyme kinetics

Rheostat functional outcomes occur when substitutions are introduced at nonconserved positions that diverge with speciation

Epistasis facilitates functional evolution in an ancient transcription factor

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