Amplicon Remodeling and Genomic Mutations Drive Population Dynamics after Segmental Amplification

Abstract New enzymes often evolve by duplication and divergence of genes encoding enzymes with promiscuous activities that have become important in the face of environmental opportunities or challenges. Amplifications that increase the copy number of the gene under selection commonly amplify many su...

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Veröffentlicht in:	Molecular biology and evolution 2022-01, Vol.39 (1)
Hauptverfasser:	Morgenthaler, Andrew B, Fritts, Ryan K, Copley, Shelley D
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Sprache:	eng
Schlagworte:	Discoveries Enzymes Gene Amplification Genes Genetic aspects Genomes Genomics Mutation Population biology Population Dynamics
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creator	Morgenthaler, Andrew B Fritts, Ryan K Copley, Shelley D
description	Abstract New enzymes often evolve by duplication and divergence of genes encoding enzymes with promiscuous activities that have become important in the face of environmental opportunities or challenges. Amplifications that increase the copy number of the gene under selection commonly amplify many surrounding genes. Extra copies of these coamplified genes must be removed, either during or after evolution of a new enzyme. Here we report that amplicon remodeling can begin even before mutations occur in the gene under selection. Amplicon remodeling and mutations elsewhere in the genome that indirectly increase fitness result in complex population dynamics, leading to emergence of clones that have improved fitness by different mechanisms. In this work, one of the two most successful clones had undergone two episodes of amplicon remodeling, leaving only four coamplified genes surrounding the gene under selection. Amplicon remodeling in the other clone resulted in removal of 111 genes from the genome, an acceptable solution under these selection conditions, but one that would certainly impair fitness under other environmental conditions.
doi_str_mv	10.1093/molbev/msab289
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subjects	Discoveries Enzymes Gene Amplification Genes Genetic aspects Genomes Genomics Mutation Population biology Population Dynamics
title	Amplicon Remodeling and Genomic Mutations Drive Population Dynamics after Segmental Amplification
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