Gene Gain and Loss Push Prokaryotes Beyond the Homologous Recombination Barrier and Accelerate Genome Sequence Divergence

Overview

Journal Nat Commun

Specialty Biology

Date 2019 Nov 28

PMID 31772262

Citations 40

Authors

Jaime Iranzo

Yuri I Wolf

Eugene V Koonin

Itamar Sela

Affiliations

Soon will be listed here.

Abstract

Bacterial and archaeal evolution involve extensive gene gain and loss. Thus, phylogenetic trees of prokaryotes can be constructed both by traditional sequence-based methods (gene trees) and by comparison of gene compositions (genome trees). Comparing the branch lengths in gene and genome trees with identical topologies for 34 clusters of closely related bacterial and archaeal genomes, we show here that terminal branches of gene trees are systematically compressed compared to those of genome trees. Thus, sequence evolution is delayed compared to genome evolution by gene gain and loss. The extent of this delay differs widely among bacteria and archaea. Mathematical modeling shows that the divergence delay can result from sequence homogenization by homologous recombination. The model explains how homologous recombination maintains the cohesiveness of the core genome of a species while allowing extensive gene gain and loss within the accessory genome. Once evolving genomes become isolated by barriers impeding homologous recombination, gene and genome evolution processes settle into parallel trajectories, and genomes diverge, resulting in speciation.

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