The Genomic Landscape and Evolutionary Resolution of Antagonistic Pleiotropy in Yeast

Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other common phenomena. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear....

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Bibliographic Details
Published inCell reports (Cambridge) Vol. 2; no. 5; pp. 1399 - 1410
Main Authors Qian, Wenfeng, Ma, Di, Xiao, Che, Wang, Zhi, Zhang, Jianzhi
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 29.11.2012
Elsevier
Subjects
Alleles
Biological Evolution
Gene Deletion
Gene Expression Regulation, Fungal
Genetic Pleiotropy - genetics
Genetics, Population
Genome
Models, Genetic
Saccharomyces cerevisiae - genetics
Online AccessGet full text
ISSN2211-1247
2211-1247
DOI10.1016/j.celrep.2012.09.017

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Abstract Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other common phenomena. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. By measuring the fitness difference between the wild-type and null alleles of ∼5,000 nonessential genes in yeast, we found that in any given environment, yeast expresses hundreds of genes that harm rather than benefit the organism, demonstrating widespread AP. Nonetheless, under sufficient selection, AP is often resolvable through regulatory evolution, primarily by trans-acting changes, although in one case we also detected a cis-acting change and localized its causal mutation. However, AP is resolved more slowly in smaller populations, predicting more unresolved AP in multicellular organisms than in yeast. These findings provide an empirical foundation for AP-dependent theories and have broad biomedical and evolutionary implications. [Display omitted] ► Under any conditions, yeast expresses many genes that are harmful to the cell ► Such problems can often be resolved by regulatory evolution under selection ► Such regulatory evolution tends to occur via trans-acting genetic changes ► Antagonistic pleiotropy is predicted to be more abundant in multicellular organisms Antagonistic pleiotropy (AP) refers to the situation in which the relative advantage of two alleles of a gene is reversed in different components of fitness, such as different sexes or external environments. AP is frequently invoked in theories of aging, cancer, genetic disease, and adaptation. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. Zhang and colleagues address these questions by a combination of genomics, genetics, and modeling in yeast.
AbstractList Antagonistic pleiotropy (AP) or genetic tradeoff is an important concept invoked frequently in theories of aging, cancer, genetic disease, and other common phenomena. But, it is unclear how prevalent AP is, which genes are subject to AP, and to what extent and how AP may be resolved. By measuring the fitness difference between the wild-type and null alleles of ~5000 nonessential genes in yeast, we find that, in any given environment, yeast expresses hundreds of genes that harm rather than benefit the organism, demonstrating widespread AP. Nonetheless, under sufficient selection, AP is often resolvable through regulatory evolution, primarily by trans -acting changes, although in one case we also detect a cis -acting change and localize its causal mutation. AP resolution, however, is slower in smaller populations, predicting more unresolved AP in multicellular organisms than in yeast. These findings provide the empirical foundation for AP-dependent theories and have broad biomedical and evolutionary implications.
Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other common phenomena. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. By measuring the fitness difference between the wild-type and null alleles of ~5,000 nonessential genes in yeast, we found that in any given environment, yeast expresses hundreds of genes that harm rather than benefit the organism, demonstrating widespread AP. Nonetheless, under sufficient selection, AP is often resolvable through regulatory evolution, primarily by trans-acting changes, although in one case we also detected a cis-acting change and localized its causal mutation. However, AP is resolved more slowly in smaller populations, predicting more unresolved AP in multicellular organisms than in yeast. These findings provide an empirical foundation for AP-dependent theories and have broad biomedical and evolutionary implications.
Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other common phenomena. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. By measuring the fitness difference between the wild-type and null alleles of similar to 5,000 nonessential genes in yeast, we found that in any given environment, yeast expresses hundreds of genes that harm rather than benefit the organism, demonstrating widespread AP. Nonetheless, under sufficient selection, AP is often resolvable through regulatory evolution, primarily by trans-acting changes, although in one case we also detected a cis-acting change and localized its causal mutation. However, AP is resolved more slowly in smaller populations, predicting more unresolved AP in multicellular organisms than in yeast. These findings provide an empirical foundation for AP-dependent theories and have broad biomedical and evolutionary implications.
Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other common phenomena. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. By measuring the fitness difference between the wild-type and null alleles of ∼5,000 nonessential genes in yeast, we found that in any given environment, yeast expresses hundreds of genes that harm rather than benefit the organism, demonstrating widespread AP. Nonetheless, under sufficient selection, AP is often resolvable through regulatory evolution, primarily by trans-acting changes, although in one case we also detected a cis-acting change and localized its causal mutation. However, AP is resolved more slowly in smaller populations, predicting more unresolved AP in multicellular organisms than in yeast. These findings provide an empirical foundation for AP-dependent theories and have broad biomedical and evolutionary implications. [Display omitted] ► Under any conditions, yeast expresses many genes that are harmful to the cell ► Such problems can often be resolved by regulatory evolution under selection ► Such regulatory evolution tends to occur via trans-acting genetic changes ► Antagonistic pleiotropy is predicted to be more abundant in multicellular organisms Antagonistic pleiotropy (AP) refers to the situation in which the relative advantage of two alleles of a gene is reversed in different components of fitness, such as different sexes or external environments. AP is frequently invoked in theories of aging, cancer, genetic disease, and adaptation. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. Zhang and colleagues address these questions by a combination of genomics, genetics, and modeling in yeast.
Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other common phenomena. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. By measuring the fitness difference between the wild-type and null alleles of ∼5,000 nonessential genes in yeast, we found that in any given environment, yeast expresses hundreds of genes that harm rather than benefit the organism, demonstrating widespread AP. Nonetheless, under sufficient selection, AP is often resolvable through regulatory evolution, primarily by trans-acting changes, although in one case we also detected a cis-acting change and localized its causal mutation. However, AP is resolved more slowly in smaller populations, predicting more unresolved AP in multicellular organisms than in yeast. These findings provide an empirical foundation for AP-dependent theories and have broad biomedical and evolutionary implications.
Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other common phenomena. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. By measuring the fitness difference between the wild-type and null alleles of ~5,000 nonessential genes in yeast, we found that in any given environment, yeast expresses hundreds of genes that harm rather than benefit the organism, demonstrating widespread AP. Nonetheless, under sufficient selection, AP is often resolvable through regulatory evolution, primarily by trans-acting changes, although in one case we also detected a cis-acting change and localized its causal mutation. However, AP is resolved more slowly in smaller populations, predicting more unresolved AP in multicellular organisms than in yeast. These findings provide an empirical foundation for AP-dependent theories and have broad biomedical and evolutionary implications.Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other common phenomena. However, the prevalence of AP, which genes are subject to AP, and to what extent and how AP may be resolved remain unclear. By measuring the fitness difference between the wild-type and null alleles of ~5,000 nonessential genes in yeast, we found that in any given environment, yeast expresses hundreds of genes that harm rather than benefit the organism, demonstrating widespread AP. Nonetheless, under sufficient selection, AP is often resolvable through regulatory evolution, primarily by trans-acting changes, although in one case we also detected a cis-acting change and localized its causal mutation. However, AP is resolved more slowly in smaller populations, predicting more unresolved AP in multicellular organisms than in yeast. These findings provide an empirical foundation for AP-dependent theories and have broad biomedical and evolutionary implications.
Author Qian, Wenfeng
Wang, Zhi
Ma, Di
Xiao, Che
Zhang, Jianzhi
AuthorAffiliation 2 Department of Cell and Developmental Biology, University of Michigan, Ann Arbor, MI 48109, USA
4 School of Life Sciences, Peking University, Beijing 100871, China
3 Life Sciences Institute, University of Michigan, Ann Arbor, MI 48109, USA
1 Department of Ecology and Evolutionary Biology, University of Michigan, Ann Arbor, MI 48109, USA
AuthorAffiliation_xml – name: 2 Department of Cell and Developmental Biology, University of Michigan, Ann Arbor, MI 48109, USA
– name: 4 School of Life Sciences, Peking University, Beijing 100871, China
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– name: 3 Life Sciences Institute, University of Michigan, Ann Arbor, MI 48109, USA
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  fullname: Wang, Zhi
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  surname: Zhang
  fullname: Zhang, Jianzhi
  email: jianzhi@umich.edu
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BackLink https://www.ncbi.nlm.nih.gov/pubmed/23103169$$D View this record in MEDLINE/PubMed
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Issue 5
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Present address: Graduate Program in Genetics, Stony Brook University, Stony Brook, NY 11794, USA
Present address: Arizona State University, Tempe, AZ 85287, USA.
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Snippet Antagonistic pleiotropy (AP), or genetic tradeoff, is an important concept that is frequently invoked in theories of aging, cancer, genetic disease, and other...
Antagonistic pleiotropy (AP) or genetic tradeoff is an important concept invoked frequently in theories of aging, cancer, genetic disease, and other common...
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SubjectTerms Alleles
Biological Evolution
Gene Deletion
Gene Expression Regulation, Fungal
Genetic Pleiotropy - genetics
Genetics, Population
Genome
Models, Genetic
Saccharomyces cerevisiae - genetics
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Title The Genomic Landscape and Evolutionary Resolution of Antagonistic Pleiotropy in Yeast
URI https://dx.doi.org/10.1016/j.celrep.2012.09.017
https://www.ncbi.nlm.nih.gov/pubmed/23103169
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