Viruses of the family Bunyaviridae: Are all available isolates reassortants?

Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large, medium, and small). Dual infections of arthropod and perhaps vertebrate and plant hosts provide substantial opportunity for segment reassortment and...

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Published inVirology (New York, N.Y.) Vol. 446; no. 1-2; pp. 207 - 216
Main Authors Briese, Thomas, Calisher, Charles H., Higgs, Stephen
Format Journal Article
LanguageEnglish
Published United States Elsevier Inc 01.11.2013
Subjects
Animals
Arthropoda
arthropods
Bunyaviridae
Bunyaviridae - classification
Bunyaviridae - genetics
Bunyaviridae - isolation & purification
Bunyaviridae Infections - veterinary
Bunyaviridae Infections - virology
Bunyavirus
Bunyaviruses
evolution
Evolution, Molecular
Genetic Drift
Genome segment reassortment
hosts
Humans
Infectious Disease
Orthobunyavirus
Phylogenetics
Phylogeny
Plant Diseases - virology
Plants
point mutation
Reassortant Viruses - classification
Reassortant Viruses - genetics
Reassortant Viruses - isolation & purification
RNA
RNA, Viral - genetics
Tripartite genome
vertebrates
viruses
Phylogenetics
Genome segment reassortment
Tripartite genome
Bunyaviridae
Bunyaviruses
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Abstract Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large, medium, and small). Dual infections of arthropod and perhaps vertebrate and plant hosts provide substantial opportunity for segment reassortment and an increasingly recognized number of the nearly 300 viruses in this family have been shown to be reassortants. Reassortment of RNA segments (genetic shift) complements genetic drift (accumulation of point mutations) as a powerful mechanism underlying bunyavirus evolution. Here we consider the possibility, if not likelihood, that most if not all bunyaviruses currently recognized may represent reassortants, some of which may be reassortants of existing viruses, and some of which may be reassortants of extinct viruses. If this hypothesis is correct, then the roots of the family and genus trees of bunyaviruses as currently described (or ignored) are incomplete or incorrect. •Dual infections provide bunyaviruses the opportunity for segment reassortment•It is possible that most or all currently recognized bunyaviruses are reassortants.•It is unknown whether contemporary bunyaviruses contain segments of extinct viruses.•Currently described bunyavirus phylogeny may be incorrect or incomplete.
AbstractList Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large, medium, and small). Dual infections of arthropod and perhaps vertebrate and plant hosts provide substantial opportunity for segment reassortment and an increasingly recognized number of the nearly 300 viruses in this family have been shown to be reassortants. Reassortment of RNA segments (genetic shift) complements genetic drift (accumulation of point mutations) as a powerful mechanism underlying bunyavirus evolution.Here we consider the possibility, if not likelihood, that most if not all bunyaviruses currently recognized may represent reassortants, some of which may be reassortants of existing viruses, and some of which may be reassortants of extinct viruses. If this hypothesis is correct, then the roots of the family and genus trees of bunyaviruses as currently described (or ignored) are incomplete or incorrect.
Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large, medium, and small). Dual infections of arthropod and perhaps vertebrate and plant hosts provide substantial opportunity for segment reassortment and an increasingly recognized number of the nearly 300 viruses in this family have been shown to be reassortants. Reassortment of RNA segments (genetic shift) complements genetic drift (accumulation of point mutations) as a powerful mechanism underlying bunyavirus evolution. Here we consider the possibility, if not likelihood, that most if not all bunyaviruses currently recognized may represent reassortants, some of which may be reassortants of existing viruses, and some of which may be reassortants of extinct viruses. If this hypothesis is correct, then the roots of the family and genus trees of bunyaviruses as currently described (or ignored) are incomplete or incorrect.Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large, medium, and small). Dual infections of arthropod and perhaps vertebrate and plant hosts provide substantial opportunity for segment reassortment and an increasingly recognized number of the nearly 300 viruses in this family have been shown to be reassortants. Reassortment of RNA segments (genetic shift) complements genetic drift (accumulation of point mutations) as a powerful mechanism underlying bunyavirus evolution. Here we consider the possibility, if not likelihood, that most if not all bunyaviruses currently recognized may represent reassortants, some of which may be reassortants of existing viruses, and some of which may be reassortants of extinct viruses. If this hypothesis is correct, then the roots of the family and genus trees of bunyaviruses as currently described (or ignored) are incomplete or incorrect.
Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large, medium, and small). Dual infections of arthropod and perhaps vertebrate and plant hosts provide substantial opportunity for segment reassortment and an increasingly recognized number of the nearly 300 viruses in this family have been shown to be reassortants. Reassortment of RNA segments (genetic shift) complements genetic drift (accumulation of point mutations) as a powerful mechanism underlying bunyavirus evolution. Here we consider the possibility, if not likelihood, that most if not all bunyaviruses currently recognized may represent reassortants, some of which may be reassortants of existing viruses, and some of which may be reassortants of extinct viruses. If this hypothesis is correct, then the roots of the family and genus trees of bunyaviruses as currently described (or ignored) are incomplete or incorrect. •Dual infections provide bunyaviruses the opportunity for segment reassortment•It is possible that most or all currently recognized bunyaviruses are reassortants.•It is unknown whether contemporary bunyaviruses contain segments of extinct viruses.•Currently described bunyavirus phylogeny may be incorrect or incomplete.
Abstract Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large, medium, and small). Dual infections of arthropod and perhaps vertebrate and plant hosts provide substantial opportunity for segment reassortment and an increasingly recognized number of the nearly 300 viruses in this family have been shown to be reassortants. Reassortment of RNA segments (genetic shift) complements genetic drift (accumulation of point mutations) as a powerful mechanism underlying bunyavirus evolution. Here we consider the possibility, if not likelihood, that most if not all bunyaviruses currently recognized may represent reassortants, some of which may be reassortants of existing viruses, and some of which may be reassortants of extinct viruses. If this hypothesis is correct, then the roots of the family and genus trees of bunyaviruses as currently described (or ignored) are incomplete or incorrect.
Author Briese, Thomas
Calisher, Charles H.
Higgs, Stephen
Author_xml – sequence: 1
  givenname: Thomas
  surname: Briese
  fullname: Briese, Thomas
  email: thomas.briese@columbia.edu
  organization: Center for Infection and Immunity and Department of Epidemiology, Mailman School of Public Health, Columbia University, 722 West 168th Street, New York, NY 10032, USA
– sequence: 2
  givenname: Charles H.
  surname: Calisher
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  organization: Arthropod-Borne and Infectious Diseases Laboratory, Department of Microbiology, Immunology and Pathology, College of Veterinary Medicine and Biomedical Sciences, Colorado State University, 3195 Rampart Rd., Delivery Code 1690, Foothills Campus, Fort Collins, CO 80523-1690, USA
– sequence: 3
  givenname: Stephen
  surname: Higgs
  fullname: Higgs, Stephen
  email: shiggs@k-state.edu
  organization: Biosecurity Research Institute, Kansas State University, 1041 Pat Roberts Hall, Manhattan, KS 66506, USA
BackLink https://www.ncbi.nlm.nih.gov/pubmed/24074583$$D View this record in MEDLINE/PubMed
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Issue 1-2
Keywords Phylogenetics
Genome segment reassortment
Tripartite genome
Bunyaviridae
Bunyaviruses
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2013 Elsevier Inc. All rights reserved.
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  year: 2013
  text: 2013-11-01
  day: 01
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PublicationTitle Virology (New York, N.Y.)
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Snippet Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large, medium,...
Abstract Viruses of the family Bunyaviridae (the bunyaviruses) possess three distinct linear, single-stranded, negative sense or ambisense RNA segments (large,...
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SubjectTerms Animals
Arthropoda
arthropods
Bunyaviridae
Bunyaviridae - classification
Bunyaviridae - genetics
Bunyaviridae - isolation & purification
Bunyaviridae Infections - veterinary
Bunyaviridae Infections - virology
Bunyavirus
Bunyaviruses
evolution
Evolution, Molecular
Genetic Drift
Genome segment reassortment
hosts
Humans
Infectious Disease
Orthobunyavirus
Phylogenetics
Phylogeny
Plant Diseases - virology
Plants
point mutation
Reassortant Viruses - classification
Reassortant Viruses - genetics
Reassortant Viruses - isolation & purification
RNA
RNA, Viral - genetics
Tripartite genome
vertebrates
viruses
Title Viruses of the family Bunyaviridae: Are all available isolates reassortants?
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