Abstract
Roles of constraints in shaping evolutionary outcomes are often considered in the contexts of developmental biology and population genetics, in terms of capacities to generate new variants and how selection limits or promotes consequent phenotypic changes. Comparative genomics also recognizes the role of constraints, in terms of shaping evolution of gene and genome architectures, sequence evolutionary rates, and gene gains or losses, as well as on molecular phenotypes. Characterizing patterns of genomic change where putative functions and interactions of system components are relatively well described offers opportunities to explore whether genes with similar roles exhibit similar evolutionary trajectories. Using insect immunity as our test case system, we hypothesize that characterizing gene evolutionary histories can define distinct dynamics associated with different functional roles. We develop metrics that quantify gene evolutionary histories, employ these to characterize evolutionary features of immune gene repertoires, and explore relationships between gene family evolutionary profiles and their roles in immunity to understand how different constraints may relate to distinct dynamics. We identified three main axes of evolutionary trajectories characterized by gene duplication and synteny, maintenance/stability and sequence conservation, and loss and sequence divergence, highlighting similar and contrasting patterns across these axes amongst subsets of immune genes. Our results suggest that where and how genes participate in immune responses limit the range of possible evolutionary scenarios they exhibit. The test case study system of insect immunity highlights the potential of applying comparative genomics approaches to characterize how functional constraints on different components of biological systems govern their evolutionary trajectories.
Highlights
The concept of constraints in evolutionary biology encompasses a diverse array of interpretations and terminologies shaped by the approaches of different research fields (Antonovics and van Tienderen 1991)
Comparative genomics recognizes the role of constraints, in shaping the evolution of gene and genome architectures, sequence evolutionary rates, and gene gains and losses, as well as on the molecular phenotypes governed by their functional products (Koonin and Wolf 2010)
Functional constraints impact the evolution of gene families, for example, families of paralogs with or without essential genes exhibit dramatically different evolutionary regimes in terms of sequence divergence and duplication rates (Shakhnovich and Koonin 2006)
Summary
The concept of constraints in evolutionary biology encompasses a diverse array of interpretations and terminologies shaped by the approaches of different research fields (Antonovics and van Tienderen 1991). Integrative analyses of evolutionary and functional constraints point to emergent properties such as a gene family’s “importance” or “status” characterized by low sequence divergence and propensity for gene loss with high expression levels, protein interactions, and essentiality; or a family’s “adaptability” manifested by high duplication levels, many genetic interaction partners, and a tendency of genes to be nonessential; or a family’s “reactivity” with high gain/loss and expression levels but low sequence divergence, a paucity of essential genes, and few physical or genetic interactions (Wolf et al 2006) If such constraints limit the realm of possibilities in terms of allowed gene evolutionary trajectories recurring patterns should be observable for genes evolving under similar constraints.
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