Biological Processes Modulating Longevity across Primates: A Phylogenetic Genome-Phenome Analysis

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Biological Processes Modulating Longevity across Primates : A Phylogenetic Genome-Phenome Analysis. / Muntané, Gerard; Farré, Xavier; Rodriguez, Juan Antonio; Pegueroles, Cinta; Hughes, David A.; de Magalhães, João Pedro; Gabaldón, Toni; Navarro, Arcadi.

In: Molecular Biology and Evolution, Vol. 35, No. 8, 2018, p. 1990-2004.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Muntané, G, Farré, X, Rodriguez, JA, Pegueroles, C, Hughes, DA, de Magalhães, JP, Gabaldón, T & Navarro, A 2018, 'Biological Processes Modulating Longevity across Primates: A Phylogenetic Genome-Phenome Analysis', Molecular Biology and Evolution, vol. 35, no. 8, pp. 1990-2004. https://doi.org/10.1093/molbev/msy105

APA

Muntané, G., Farré, X., Rodriguez, J. A., Pegueroles, C., Hughes, D. A., de Magalhães, J. P., Gabaldón, T., & Navarro, A. (2018). Biological Processes Modulating Longevity across Primates: A Phylogenetic Genome-Phenome Analysis. Molecular Biology and Evolution, 35(8), 1990-2004. https://doi.org/10.1093/molbev/msy105

Vancouver

Muntané G, Farré X, Rodriguez JA, Pegueroles C, Hughes DA, de Magalhães JP et al. Biological Processes Modulating Longevity across Primates: A Phylogenetic Genome-Phenome Analysis. Molecular Biology and Evolution. 2018;35(8):1990-2004. https://doi.org/10.1093/molbev/msy105

Author

Muntané, Gerard ; Farré, Xavier ; Rodriguez, Juan Antonio ; Pegueroles, Cinta ; Hughes, David A. ; de Magalhães, João Pedro ; Gabaldón, Toni ; Navarro, Arcadi. / Biological Processes Modulating Longevity across Primates : A Phylogenetic Genome-Phenome Analysis. In: Molecular Biology and Evolution. 2018 ; Vol. 35, No. 8. pp. 1990-2004.

Bibtex

@article{3ed4d2ae5dd24603bebbf0f4dd10d321,
title = "Biological Processes Modulating Longevity across Primates: A Phylogenetic Genome-Phenome Analysis",
abstract = "Aging is a complex process affecting different species and individuals in different ways. Comparing genetic variation across species with their aging phenotypes will help understanding the molecular basis of aging and longevity. Although most studies on aging have so far focused on short-lived model organisms, recent comparisons of genomic, transcriptomic, and metabolomic data across lineages with different lifespans are unveiling molecular signatures associated with longevity. Here, we examine the relationship between genomic variation and maximum lifespan across primate species. We used two different approaches. First, we searched for parallel amino-acid mutations that co-occur with increases in longevity across the primate linage. Twenty-five such amino-acid variants were identified, several of which have been previously reported by studies with different experimental setups and in different model organisms. The genes harboring these mutations are mainly enriched in functional categories such as wound healing, blood coagulation, and cardiovascular disorders. We demonstrate that these pathways are highly enriched for pleiotropic effects, as predicted by the antagonistic pleiotropy theory of aging. A second approach was focused on changes in rates of protein evolution across the primate phylogeny. Using the phylogenetic generalized least squares, we show that some genes exhibit strong correlations between their evolutionary rates and longevity-associated traits. These include genes in the Sphingosine 1-phosphate pathway, PI3K signaling, and the Thrombin/protease-activated receptor pathway, among other cardiovascular processes. Together, these results shed light into human senescence patterns and underscore the power of comparative genomics to identify pathways related to aging and longevity.",
keywords = "Aging, Evolution, Genotype-phenotype, Longevity, Primates",
author = "Gerard Muntan{\'e} and Xavier Farr{\'e} and Rodriguez, {Juan Antonio} and Cinta Pegueroles and Hughes, {David A.} and {de Magalh{\~a}es}, {Jo{\~a}o Pedro} and Toni Gabald{\'o}n and Arcadi Navarro",
note = "Publisher Copyright: {\textcopyright} 2018 The Author(s).",
year = "2018",
doi = "10.1093/molbev/msy105",
language = "English",
volume = "35",
pages = "1990--2004",
journal = "Molecular Biology and Evolution",
issn = "0737-4038",
publisher = "Oxford University Press",
number = "8",

}

RIS

TY - JOUR

T1 - Biological Processes Modulating Longevity across Primates

T2 - A Phylogenetic Genome-Phenome Analysis

AU - Muntané, Gerard

AU - Farré, Xavier

AU - Rodriguez, Juan Antonio

AU - Pegueroles, Cinta

AU - Hughes, David A.

AU - de Magalhães, João Pedro

AU - Gabaldón, Toni

AU - Navarro, Arcadi

N1 - Publisher Copyright: © 2018 The Author(s).

PY - 2018

Y1 - 2018

N2 - Aging is a complex process affecting different species and individuals in different ways. Comparing genetic variation across species with their aging phenotypes will help understanding the molecular basis of aging and longevity. Although most studies on aging have so far focused on short-lived model organisms, recent comparisons of genomic, transcriptomic, and metabolomic data across lineages with different lifespans are unveiling molecular signatures associated with longevity. Here, we examine the relationship between genomic variation and maximum lifespan across primate species. We used two different approaches. First, we searched for parallel amino-acid mutations that co-occur with increases in longevity across the primate linage. Twenty-five such amino-acid variants were identified, several of which have been previously reported by studies with different experimental setups and in different model organisms. The genes harboring these mutations are mainly enriched in functional categories such as wound healing, blood coagulation, and cardiovascular disorders. We demonstrate that these pathways are highly enriched for pleiotropic effects, as predicted by the antagonistic pleiotropy theory of aging. A second approach was focused on changes in rates of protein evolution across the primate phylogeny. Using the phylogenetic generalized least squares, we show that some genes exhibit strong correlations between their evolutionary rates and longevity-associated traits. These include genes in the Sphingosine 1-phosphate pathway, PI3K signaling, and the Thrombin/protease-activated receptor pathway, among other cardiovascular processes. Together, these results shed light into human senescence patterns and underscore the power of comparative genomics to identify pathways related to aging and longevity.

AB - Aging is a complex process affecting different species and individuals in different ways. Comparing genetic variation across species with their aging phenotypes will help understanding the molecular basis of aging and longevity. Although most studies on aging have so far focused on short-lived model organisms, recent comparisons of genomic, transcriptomic, and metabolomic data across lineages with different lifespans are unveiling molecular signatures associated with longevity. Here, we examine the relationship between genomic variation and maximum lifespan across primate species. We used two different approaches. First, we searched for parallel amino-acid mutations that co-occur with increases in longevity across the primate linage. Twenty-five such amino-acid variants were identified, several of which have been previously reported by studies with different experimental setups and in different model organisms. The genes harboring these mutations are mainly enriched in functional categories such as wound healing, blood coagulation, and cardiovascular disorders. We demonstrate that these pathways are highly enriched for pleiotropic effects, as predicted by the antagonistic pleiotropy theory of aging. A second approach was focused on changes in rates of protein evolution across the primate phylogeny. Using the phylogenetic generalized least squares, we show that some genes exhibit strong correlations between their evolutionary rates and longevity-associated traits. These include genes in the Sphingosine 1-phosphate pathway, PI3K signaling, and the Thrombin/protease-activated receptor pathway, among other cardiovascular processes. Together, these results shed light into human senescence patterns and underscore the power of comparative genomics to identify pathways related to aging and longevity.

KW - Aging

KW - Evolution

KW - Genotype-phenotype

KW - Longevity

KW - Primates

U2 - 10.1093/molbev/msy105

DO - 10.1093/molbev/msy105

M3 - Journal article

C2 - 29788292

AN - SCOPUS:85055004129

VL - 35

SP - 1990

EP - 2004

JO - Molecular Biology and Evolution

JF - Molecular Biology and Evolution

SN - 0737-4038

IS - 8

ER -

ID: 327321946