The long‐standing significance of genetic diversity in conservation

Since allozymes were first used to assess genetic diversity in the 1960s and 1970s, biologists have attempted to characterize gene pools and conserve the diversity observed in domestic crops, livestock, zoos and (more recently) natural populations. Recently, some authors have claimed that the import...

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Vydané v:Molecular ecology Ročník 30; číslo 17; s. 4147 - 4154
Hlavní autori: DeWoody, J. Andrew, Harder, Avril M., Mathur, Samarth, Willoughby, Janna R.
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Oxford Blackwell Publishing Ltd 01.09.2021
Predmet:
allozymes
Anthropocene
Anthropocene epoch
Biodiversity
Conservation
Conservation biology
conservation genetics
Ecosystem conservation
Evolution
genes
Genetic diversity
genetic variation
Isoenzymes
Livestock
Natural populations
population genetics – empirical
population genetics – theoretical
Populations
Strategic management
wildlife management
ISSN:0962-1083, 1365-294X, 1365-294X
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Abstract Since allozymes were first used to assess genetic diversity in the 1960s and 1970s, biologists have attempted to characterize gene pools and conserve the diversity observed in domestic crops, livestock, zoos and (more recently) natural populations. Recently, some authors have claimed that the importance of genetic diversity in conservation biology has been greatly overstated. Here, we argue that a voluminous literature indicates otherwise. We address four main points made by detractors of genetic diversity's role in conservation by using published literature to firmly establish that genetic diversity is intimately tied to evolutionary fitness, and that the associated demographic consequences are of paramount importance to many conservation efforts. We think that responsible management in the Anthropocene should, whenever possible, include the conservation of ecosystems, communities, populations and individuals, and their underlying genetic diversity.
AbstractList Since allozymes were first used to assess genetic diversity in the 1960s and 1970s, biologists have attempted to characterize gene pools and conserve the diversity observed in domestic crops, livestock, zoos and (more recently) natural populations. Recently, some authors have claimed that the importance of genetic diversity in conservation biology has been greatly overstated. Here, we argue that a voluminous literature indicates otherwise. We address four main points made by detractors of genetic diversity's role in conservation by using published literature to firmly establish that genetic diversity is intimately tied to evolutionary fitness, and that the associated demographic consequences are of paramount importance to many conservation efforts. We think that responsible management in the Anthropocene should, whenever possible, include the conservation of ecosystems, communities, populations and individuals, and their underlying genetic diversity.
Since allozymes were first used to assess genetic diversity in the 1960s and 1970s, biologists have attempted to characterize gene pools and conserve the diversity observed in domestic crops, livestock, zoos and (more recently) natural populations. Recently, some authors have claimed that the importance of genetic diversity in conservation biology has been greatly overstated. Here, we argue that a voluminous literature indicates otherwise. We address four main points made by detractors of genetic diversity's role in conservation by using published literature to firmly establish that genetic diversity is intimately tied to evolutionary fitness, and that the associated demographic consequences are of paramount importance to many conservation efforts. We think that responsible management in the Anthropocene should, whenever possible, include the conservation of ecosystems, communities, populations and individuals, and their underlying genetic diversity.Since allozymes were first used to assess genetic diversity in the 1960s and 1970s, biologists have attempted to characterize gene pools and conserve the diversity observed in domestic crops, livestock, zoos and (more recently) natural populations. Recently, some authors have claimed that the importance of genetic diversity in conservation biology has been greatly overstated. Here, we argue that a voluminous literature indicates otherwise. We address four main points made by detractors of genetic diversity's role in conservation by using published literature to firmly establish that genetic diversity is intimately tied to evolutionary fitness, and that the associated demographic consequences are of paramount importance to many conservation efforts. We think that responsible management in the Anthropocene should, whenever possible, include the conservation of ecosystems, communities, populations and individuals, and their underlying genetic diversity.
Author Willoughby, Janna R.
Harder, Avril M.
Mathur, Samarth
DeWoody, J. Andrew
Author_xml – sequence: 1
  givenname: J. Andrew
  orcidid: 0000-0002-7315-5631
  surname: DeWoody
  fullname: DeWoody, J. Andrew
  email: dewoody@purdue.edu
  organization: Purdue University
– sequence: 2
  givenname: Avril M.
  orcidid: 0000-0001-7371-4002
  surname: Harder
  fullname: Harder, Avril M.
  organization: Auburn University
– sequence: 3
  givenname: Samarth
  orcidid: 0000-0002-6446-5718
  surname: Mathur
  fullname: Mathur, Samarth
  organization: The Ohio State University
– sequence: 4
  givenname: Janna R.
  orcidid: 0000-0002-0176-1878
  surname: Willoughby
  fullname: Willoughby, Janna R.
  organization: Auburn University
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Snippet Since allozymes were first used to assess genetic diversity in the 1960s and 1970s, biologists have attempted to characterize gene pools and conserve the...
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SubjectTerms allozymes
Anthropocene
Anthropocene epoch
Biodiversity
Conservation
Conservation biology
conservation genetics
Ecosystem conservation
Evolution
genes
Genetic diversity
genetic variation
Isoenzymes
Livestock
Natural populations
population genetics – empirical
population genetics – theoretical
Populations
Strategic management
wildlife management
Title The long‐standing significance of genetic diversity in conservation
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Volume 30
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