Many Options, Few Solutions: Over 60 My Snakes Converged on a Few Optimal Venom Formulations
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Barua, Agneesh
Mikheyev, Alexander
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Society for Molecular Biology Evolution
Abstract
Gene expression changes contribute to complex trait variations in both individuals and populations. However, the
evolution of gene expression underlying complex traits over macroevolutionary timescales remains poorly understood.
Snake venoms are proteinaceous cocktails where the expression of each toxin can be quantified and mapped to a distinct
genomic locus and traced for millions of years. Using a phylogenetic generalized linear mixed model, we analyzed
expression data of toxin genes from 52 snake species spanning the 3 venomous snake families and estimated phylogenetic
covariance, which acts as a measure of evolutionary constraint. We find that evolution of toxin combinations is not
constrained. However, although all combinations are in principle possible, the actual dimensionality of phylomorphic
space is low, with envenomation strategies focused around only four major toxin families: metalloproteases, three-finger
toxins, serine proteases, and phospholipases A2. Although most extant snakes prioritize either a single or a combination
of major toxin families, they are repeatedly recruited and lost. We find that over macroevolutionary timescales, the
venom phenotypes were not shaped by phylogenetic constraints, which include important microevolutionary constraints
such as epistasis and pleiotropy, but more likely by ecological filtering that permits a small number of optimal solutions.
As a result, phenotypic optima were repeatedly attained by distantly related species. These results indicate that venoms
evolve by selection on biochemistry of prey envenomation, which permit diversity through parallelism, and impose
strong limits, since only a few of the theoretically possible strategies seem to work well and are observed in extant snakes.
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Molecular Biology and Evolution
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Creative Commons Attribution License