Diversification in vipers: Phylogenetic relationships, time of divergence and shifts in speciation rates

[Display omitted] •We generated a molecular phylogeny for 79% species of vipers.•We provide divergence time estimates between lineages.•Vipers are characterized by two distinct diversification regimes.•Speciation rates rapidly increased in a sub-clade of pit vipers. Snakes of the cosmopolitan family...

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Bibliographic Details
Published inMolecular phylogenetics and evolution Vol. 105; pp. 50 - 62
Main Authors Alencar, Laura R.V., Quental, Tiago B., Grazziotin, Felipe G., Alfaro, Michael L., Martins, Marcio, Venzon, Mericien, Zaher, Hussam
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 01.12.2016
Subjects
Animals
Asia
BAMM
Calibration
Explosive radiation
Extinction, Biological
Fossils
genes
Genetic Speciation
Genetic Variation
Loreal pits
mitochondria
monophyly
New World
Phylogeny
Snakes
species diversity
Species Specificity
Time Factors
Trimeresurus
Viperidae - classification
Asia
BAMM
Loreal pits
Phylogeny
Explosive radiation
New World
Snakes
Online AccessGet full text

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Abstract [Display omitted] •We generated a molecular phylogeny for 79% species of vipers.•We provide divergence time estimates between lineages.•Vipers are characterized by two distinct diversification regimes.•Speciation rates rapidly increased in a sub-clade of pit vipers. Snakes of the cosmopolitan family Viperidae comprise around 329 venomous species showing a striking heterogeneity in species richness among lineages. While the subfamily Azemiopinae comprises only two species, 70% of all viper species are arranged in the subfamily Crotalinae or the “pit vipers”. The radiation of the pit vipers was marked by the evolution of the heat-sensing pits, which has been suggested to be a key innovation for the successful diversification of the group. Additionally, only crotalines were able to successfully colonize the New World. Here, we present the most complete molecular phylogeny for the family to date that comprises sequences from nuclear and mitochondrial genes representing 79% of all living vipers. We also investigated the time of divergence between lineages, using six fossils to calibrate the tree, and explored the hypothesis that crotalines have undergone an explosive radiation. Our phylogenetic analyses retrieved high support values for the monophyly of the family Viperidae, subfamilies Viperinae and Crotalinae, and 22 out of 27 genera, as well as well-supported intergeneric relationships throughout the family. We were able to recover a strongly supported sister clade to the New World pit vipers that comprises Gloydius, Ovophis, Protobothrops and Trimeresurus gracilis. Our results agree in many aspects with other studies focusing on the phylogenetics of vipers, but we recover new relationships as well. Despite the addition of new sequences we were not able to resolve some of the poor supported relationships previously suggested. Time of divergence estimates suggested that vipers started to radiate around the late Paleocene to middle Eocene with subfamilies most likely dating back to the Eocene. The invasion of the New World might have taken place sometime close to the Oligocene/Miocene boundary. Diversification analyses suggested a shift in speciation rates during the radiation of a sub-clade of pit vipers where speciation rates rapidly increased but slowed down toward the present. Thus, the evolution of the loreal pits alone does not seem to explain their explosive speciation rates. We suggest that climatic and geological changes in Asia and the invasion of the New World may have also contributed to the speciation shift found in vipers.
AbstractList Snakes of the cosmopolitan family Viperidae comprise around 329 venomous species showing a striking heterogeneity in species richness among lineages. While the subfamily Azemiopinae comprises only two species, 70% of all viper species are arranged in the subfamily Crotalinae or the “pit vipers”. The radiation of the pit vipers was marked by the evolution of the heat-sensing pits, which has been suggested to be a key innovation for the successful diversification of the group. Additionally, only crotalines were able to successfully colonize the New World. Here, we present the most complete molecular phylogeny for the family to date that comprises sequences from nuclear and mitochondrial genes representing 79% of all living vipers. We also investigated the time of divergence between lineages, using six fossils to calibrate the tree, and explored the hypothesis that crotalines have undergone an explosive radiation. Our phylogenetic analyses retrieved high support values for the monophyly of the family Viperidae, subfamilies Viperinae and Crotalinae, and 22 out of 27 genera, as well as well-supported intergeneric relationships throughout the family. We were able to recover a strongly supported sister clade to the New World pit vipers that comprises Gloydius, Ovophis, Protobothrops and Trimeresurus gracilis. Our results agree in many aspects with other studies focusing on the phylogenetics of vipers, but we recover new relationships as well. Despite the addition of new sequences we were not able to resolve some of the poor supported relationships previously suggested. Time of divergence estimates suggested that vipers started to radiate around the late Paleocene to middle Eocene with subfamilies most likely dating back to the Eocene. The invasion of the New World might have taken place sometime close to the Oligocene/Miocene boundary. Diversification analyses suggested a shift in speciation rates during the radiation of a sub-clade of pit vipers where speciation rates rapidly increased but slowed down toward the present. Thus, the evolution of the loreal pits alone does not seem to explain their explosive speciation rates. We suggest that climatic and geological changes in Asia and the invasion of the New World may have also contributed to the speciation shift found in vipers.
[Display omitted] •We generated a molecular phylogeny for 79% species of vipers.•We provide divergence time estimates between lineages.•Vipers are characterized by two distinct diversification regimes.•Speciation rates rapidly increased in a sub-clade of pit vipers. Snakes of the cosmopolitan family Viperidae comprise around 329 venomous species showing a striking heterogeneity in species richness among lineages. While the subfamily Azemiopinae comprises only two species, 70% of all viper species are arranged in the subfamily Crotalinae or the “pit vipers”. The radiation of the pit vipers was marked by the evolution of the heat-sensing pits, which has been suggested to be a key innovation for the successful diversification of the group. Additionally, only crotalines were able to successfully colonize the New World. Here, we present the most complete molecular phylogeny for the family to date that comprises sequences from nuclear and mitochondrial genes representing 79% of all living vipers. We also investigated the time of divergence between lineages, using six fossils to calibrate the tree, and explored the hypothesis that crotalines have undergone an explosive radiation. Our phylogenetic analyses retrieved high support values for the monophyly of the family Viperidae, subfamilies Viperinae and Crotalinae, and 22 out of 27 genera, as well as well-supported intergeneric relationships throughout the family. We were able to recover a strongly supported sister clade to the New World pit vipers that comprises Gloydius, Ovophis, Protobothrops and Trimeresurus gracilis. Our results agree in many aspects with other studies focusing on the phylogenetics of vipers, but we recover new relationships as well. Despite the addition of new sequences we were not able to resolve some of the poor supported relationships previously suggested. Time of divergence estimates suggested that vipers started to radiate around the late Paleocene to middle Eocene with subfamilies most likely dating back to the Eocene. The invasion of the New World might have taken place sometime close to the Oligocene/Miocene boundary. Diversification analyses suggested a shift in speciation rates during the radiation of a sub-clade of pit vipers where speciation rates rapidly increased but slowed down toward the present. Thus, the evolution of the loreal pits alone does not seem to explain their explosive speciation rates. We suggest that climatic and geological changes in Asia and the invasion of the New World may have also contributed to the speciation shift found in vipers.
Snakes of the cosmopolitan family Viperidae comprise around 329 venomous species showing a striking heterogeneity in species richness among lineages. While the subfamily Azemiopinae comprises only two species, 70% of all viper species are arranged in the subfamily Crotalinae or the "pit vipers". The radiation of the pit vipers was marked by the evolution of the heat-sensing pits, which has been suggested to be a key innovation for the successful diversification of the group. Additionally, only crotalines were able to successfully colonize the New World. Here, we present the most complete molecular phylogeny for the family to date that comprises sequences from nuclear and mitochondrial genes representing 79% of all living vipers. We also investigated the time of divergence between lineages, using six fossils to calibrate the tree, and explored the hypothesis that crotalines have undergone an explosive radiation. Our phylogenetic analyses retrieved high support values for the monophyly of the family Viperidae, subfamilies Viperinae and Crotalinae, and 22 out of 27 genera, as well as well-supported intergeneric relationships throughout the family. We were able to recover a strongly supported sister clade to the New World pit vipers that comprises Gloydius, Ovophis, Protobothrops and Trimeresurus gracilis. Our results agree in many aspects with other studies focusing on the phylogenetics of vipers, but we recover new relationships as well. Despite the addition of new sequences we were not able to resolve some of the poor supported relationships previously suggested. Time of divergence estimates suggested that vipers started to radiate around the late Paleocene to middle Eocene with subfamilies most likely dating back to the Eocene. The invasion of the New World might have taken place sometime close to the Oligocene/Miocene boundary. Diversification analyses suggested a shift in speciation rates during the radiation of a sub-clade of pit vipers where speciation rates rapidly increased but slowed down toward the present. Thus, the evolution of the loreal pits alone does not seem to explain their explosive speciation rates. We suggest that climatic and geological changes in Asia and the invasion of the New World may have also contributed to the speciation shift found in vipers.Snakes of the cosmopolitan family Viperidae comprise around 329 venomous species showing a striking heterogeneity in species richness among lineages. While the subfamily Azemiopinae comprises only two species, 70% of all viper species are arranged in the subfamily Crotalinae or the "pit vipers". The radiation of the pit vipers was marked by the evolution of the heat-sensing pits, which has been suggested to be a key innovation for the successful diversification of the group. Additionally, only crotalines were able to successfully colonize the New World. Here, we present the most complete molecular phylogeny for the family to date that comprises sequences from nuclear and mitochondrial genes representing 79% of all living vipers. We also investigated the time of divergence between lineages, using six fossils to calibrate the tree, and explored the hypothesis that crotalines have undergone an explosive radiation. Our phylogenetic analyses retrieved high support values for the monophyly of the family Viperidae, subfamilies Viperinae and Crotalinae, and 22 out of 27 genera, as well as well-supported intergeneric relationships throughout the family. We were able to recover a strongly supported sister clade to the New World pit vipers that comprises Gloydius, Ovophis, Protobothrops and Trimeresurus gracilis. Our results agree in many aspects with other studies focusing on the phylogenetics of vipers, but we recover new relationships as well. Despite the addition of new sequences we were not able to resolve some of the poor supported relationships previously suggested. Time of divergence estimates suggested that vipers started to radiate around the late Paleocene to middle Eocene with subfamilies most likely dating back to the Eocene. The invasion of the New World might have taken place sometime close to the Oligocene/Miocene boundary. Diversification analyses suggested a shift in speciation rates during the radiation of a sub-clade of pit vipers where speciation rates rapidly increased but slowed down toward the present. Thus, the evolution of the loreal pits alone does not seem to explain their explosive speciation rates. We suggest that climatic and geological changes in Asia and the invasion of the New World may have also contributed to the speciation shift found in vipers.
Author Martins, Marcio
Zaher, Hussam
Alfaro, Michael L.
Quental, Tiago B.
Grazziotin, Felipe G.
Venzon, Mericien
Alencar, Laura R.V.
Author_xml – sequence: 1
  givenname: Laura R.V.
  surname: Alencar
  fullname: Alencar, Laura R.V.
  email: alencarlrv@gmail.com
  organization: University of São Paulo, Department of Ecology, Rua do Matão, Travessa 14, São Paulo, SP CEP 05508-900, Brazil
– sequence: 2
  givenname: Tiago B.
  surname: Quental
  fullname: Quental, Tiago B.
  email: tbquental@usp.br
  organization: University of São Paulo, Department of Ecology, Rua do Matão, Travessa 14, São Paulo, SP CEP 05508-900, Brazil
– sequence: 3
  givenname: Felipe G.
  surname: Grazziotin
  fullname: Grazziotin, Felipe G.
  email: fgrazziotin@gmail.com
  organization: University of São Paulo, Museum of Zoology, Avenida Nazaré 481, São Paulo, SP CEP 04263-000, Brazil
– sequence: 4
  givenname: Michael L.
  surname: Alfaro
  fullname: Alfaro, Michael L.
  email: michaelalfaro@ucla.edu
  organization: University of California, Department of Ecology and Evolutionary Biology, 610 Young Drive South, Los Angeles, CA 90095, United States
– sequence: 5
  givenname: Marcio
  surname: Martins
  fullname: Martins, Marcio
  email: martinsmrc@usp.br
  organization: University of São Paulo, Department of Ecology, Rua do Matão, Travessa 14, São Paulo, SP CEP 05508-900, Brazil
– sequence: 6
  givenname: Mericien
  surname: Venzon
  fullname: Venzon, Mericien
  email: mvenzon@ucla.edu
  organization: University of California, Department of Ecology and Evolutionary Biology, 610 Young Drive South, Los Angeles, CA 90095, United States
– sequence: 7
  givenname: Hussam
  surname: Zaher
  fullname: Zaher, Hussam
  email: hzaher@usp.br
  organization: University of São Paulo, Museum of Zoology, Avenida Nazaré 481, São Paulo, SP CEP 04263-000, Brazil
BackLink https://www.ncbi.nlm.nih.gov/pubmed/27480810$$D View this record in MEDLINE/PubMed
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Loreal pits
Phylogeny
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New World
Snakes
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Snippet [Display omitted] •We generated a molecular phylogeny for 79% species of vipers.•We provide divergence time estimates between lineages.•Vipers are...
Snakes of the cosmopolitan family Viperidae comprise around 329 venomous species showing a striking heterogeneity in species richness among lineages. While the...
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SubjectTerms Animals
Asia
BAMM
Calibration
Explosive radiation
Extinction, Biological
Fossils
genes
Genetic Speciation
Genetic Variation
Loreal pits
mitochondria
monophyly
New World
Phylogeny
Snakes
species diversity
Species Specificity
Time Factors
Trimeresurus
Viperidae - classification
Title Diversification in vipers: Phylogenetic relationships, time of divergence and shifts in speciation rates
URI https://dx.doi.org/10.1016/j.ympev.2016.07.029
https://www.ncbi.nlm.nih.gov/pubmed/27480810
https://www.proquest.com/docview/1824226973
https://www.proquest.com/docview/2000274916
Volume 105
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