Mitogenomic analysis of the Australian lungfish (Neoceratodus forsteri) reveals structuring of indigenous riverine populations and late Pleistocene movement between drainage basins

Neoceratodus forsteri : is a freshwater species of Dipnoan currently listed as ‘vulnerable to extinction’ under Australian legislation. The species is restricted to at least two indigenous riverine populations in southeastern Queensland, and several other putatively translocated populations. Current...

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Bibliographic Details
Published in:Conservation genetics 2018-06, Vol.19 (3), p.587-597
Main Authors: Bishop, Cameron R., Hughes, Jane M., Schmidt, Daniel J.
Format: Article
Language:English
Subjects:
Animal Genetics and Genomics
Basins
Bayesian analysis
Biodiversity
Biomedical and Life Sciences
Catchments
Conservation Biology/Ecology
Continental shelves
Demographics
Deoxyribonucleic acid
Divergence
DNA
Drainage basins
Ecology
Endangered & extinct species
Evolutionary Biology
Fragments
Genetic diversity
Genetic structure
Genetic variability
Haplotypes
Isoenzymes
Legislation
Life Sciences
Microsatellites
Mitochondrial DNA
Molecular structure
Neoceratodus forsteri
Plant Genetics and Genomics
Pleistocene
Population genetics
Population number
Population structure
Population studies
Populations
Positive selection
Research Article
Species diversity
Species extinction
Surveying
Threatened species
Translocation
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Summary:Neoceratodus forsteri : is a freshwater species of Dipnoan currently listed as ‘vulnerable to extinction’ under Australian legislation. The species is restricted to at least two indigenous riverine populations in southeastern Queensland, and several other putatively translocated populations. Current understanding of genetic relationships among populations is based on studies of allozymes, microsatellites and mitochondrial DNA (mtDNA) fragments. A notable feature of all these datasets was low genetic variability. Here we sequence the complete mitogenome of 71 N. forsteri individuals from five populations to improve resolution of mtDNA diversity, examine relationships among populations, and evaluate recent demographic history. We recorded 137 variable positions forming 41 haplotypes in the 16,573 bp mitogenome alignment. Strong genetic structure was observed among riverine samples (global Φ ST  = 0.342) in a pattern consistent with translocation history. Tinana Creek was confirmed as an isolated and genetically unique subpopulation that should be recognized as a distinct management unit. Two previously unreported mtDNA clades (0.46% mean divergence) were found and suggest that genetic exchange among coastal catchments may have been facilitated by riverine connections on the exposed continental shelf during the late Pleistocene. Extended Bayesian skyline analysis showed no evidence for recent historical change in female effective population size, and codon-based selection tests found no evidence for positive selection in coding genes. Overall, our results emphasise the utility of the full mtDNA molecule for capturing population structure in taxa with low genetic diversity. In such cases, informative variation may be scattered across disparate parts of the mitogenome. Surveying relatively short fragments of mtDNA may lead to significant underestimates of population structure when applied to threatened species with low genetic diversity.
ISSN:1566-0621
1572-9737
DOI:10.1007/s10592-017-1034-7