Inferring the shape of global epistasis

Otwinowski, Jakub; McCandlish, David M.; Plotkin, Joshua B.

doi:10.1073/pnas.1804015115

Cited by 215 publications

(313 citation statements)

References 75 publications

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“…in partial factorial designs where they are purposefully confounded with main effects and lower-order interactions, [63]). However, there is a growing consensus that such higher-order interactions are not only common in genotype-phenotype maps [10,18,29,32,38] but are expected even for very simple, smooth genotype-phenotype relationships such as where the observed phenotype is just an additive trait that has been run through a nonlinear transformation [31,32,40,[64][65][66]. Our results contribute to this view by showing that the incorporation of higher-order interactions in fact allows substantially less epistatic fits than standard pairwise models.…”

Section: Discussionmentioning

confidence: 59%

“…In principle, these "higher-order" interactions can be captured by adding interactions between three or more sites to standard regression models, but this leads to problems in interpretability and overfitting because the number of such terms grows rapidly with increasing interaction order [26]. Another strategy has been to assume that the observed phenotype is a simple non-linear function of some underlying nonepistatic trait [32,40], a pattern of epistasis known as univariate [8,24], non-specific [31] or global [40,41] epistasis, which appears to be well suited-primarily to sequence-function relationships that are essentially noised versions of single-peaked landscapes. Finally, a variety of machine-learning techniques [8,12,[42][43][44][45] have been employed that can fit more complex forms of epistasis than global epistasis or pairwise interaction models.…”

Section: Introductionmentioning

confidence: 99%

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Minimum epistasis interpolation for sequence-function relationships

Zhou

McCandlish

2019

Preprint

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AbstractMassively parallel phenotyping assays have provided unprecedented insight into how multiple mutations combine to determine biological function. While these assays can measure phenotypes for thousands to millions of genotypes in a single experiment, in practice these measurements are not exhaustive, so that there is a need for techniques to impute values for genotypes whose phenotypes are not directly assayed. Here we present a method based on the idea of inferring the least epistatic possible sequence-function relationship compatible with the data. In particular, we infer the reconstruction in which mutational effects change as little as possible across adjacent genetic backgrounds. Although this method is highly conservative and has no tunable parameters, it also makes no assumptions about the form that genetic interactions take, resulting in predictions that can behave in a very complicated manner where the data require it but which are nearly additive where data is sparse or absent. We apply this method to analyze a fitness landscape for protein G, showing that our technique can provide a substantially less epistatic fit to the landscape than standard methods with little loss in predictive power. Moreover, our analysis reveals that the complex structure of epistasis observed in this dataset can be well-understood in terms of a simple qualitative model consisting of three fitness peaks where the landscape is locally additive in the vicinity of each peak.

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Section: Discussionmentioning

confidence: 59%

Section: Introductionmentioning

confidence: 99%

Minimum epistasis interpolation for sequence-function relationships

Zhou

McCandlish

2019

Preprint

Self Cite

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“…Of course, as for the DME, many specific cases will deviate from these general expectations and vary across proteins. For example, specific structural interactions could generate sign epistasis when mutations do not act additively on the level of folding energy (ΔG) (Otwinowski, McCandlish, & Plotkin, 2018;Starr & Thornton, 2016 F I G U R E 5 Expression-fitness functions for a diverse set of protein-coding yeast genes. Red lines mark wild-type expression levels.…”

Section: Intragenic Epistasis Within Single Proteinsmentioning

confidence: 99%

Recent insights into the genotype–phenotype relationship from massively parallel genetic assays

Kemble

Nghe

Tenaillon

2019

Evolutionary Applications

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With the molecular revolution in Biology, a mechanistic understanding of the genotype–phenotype relationship became possible. Recently, advances in DNA synthesis and sequencing have enabled the development of deep mutational scanning assays, capable of scoring comprehensive libraries of genotypes for fitness and a variety of phenotypes in massively parallel fashion. The resulting empirical genotype–fitness maps pave the way to predictive models, potentially accelerating our ability to anticipate the behaviour of pathogen and cancerous cell populations from sequencing data. Besides from cellular fitness, phenotypes of direct application in industry (e.g. enzyme activity) and medicine (e.g. antibody binding) can be quantified and even selected directly by these assays. This review discusses the technological basis of and recent developments in massively parallel genetics, along with the trends it is uncovering in the genotype–phenotype relationship (distribution of mutation effects, epistasis), their possible mechanistic bases and future directions for advancing towards the goal of predictive genetics.

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“…Epistasis remains a cutting-edge topic in evolutionary biology that continues to be the object of study for a variety of reasons, and measured using diverse methods [10,[19][20][21]. For our purposes, we use a Walsh-Hadamard transformation of the fitness values, scaled by an additional diagonal matrix, as presented in Poelwijk et al [19].…”

Section: Calculating Higher-order Epistasismentioning

confidence: 99%

Lexical landscapes as largein silicodata for examining advanced properties of fitness landscapes

Meszaros

Miller-Dickson

Ogbunugafor

2019

Preprint

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In silico approaches have served a central role in the development of evolutionary theory for generations. This especially applies to the concept of the fitness landscape, one of the most important abstractions in evolutionary genetics, and one which has benefited from the presence of large empirical data sets only in the last decade or so. In this study, we propose a method that allows us to generate enormous data sets that walk the line between in silico and empirical: word usage frequencies as catalogued by the Google ngram corpora. These data can be codified or analogized in terms of a multidimensional empirical fitness landscape towards the examination of advanced concepts-adaptive landscape by environment interactions, clonal competition, higher-order epistasis and countless others. We argue that the greater Lexical Landscapes approach can serve as a platform that offers an astronomical number of fitness landscapes for exploration (at least) or theoretical formalism (potentially) in evolutionary biology.

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Inferring the shape of global epistasis

Cited by 215 publications

References 75 publications

Minimum epistasis interpolation for sequence-function relationships

Minimum epistasis interpolation for sequence-function relationships

Recent insights into the genotype–phenotype relationship from massively parallel genetic assays

Lexical landscapes as largein silicodata for examining advanced properties of fitness landscapes

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