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Ecology and evolution
Jan, 2021;11 (1): 664-678.

Divergent lineages in a semi-arid mallee species, , correspond to a major geographic break in southeastern Australia.

Patrick S Fahey, Rachael M Fowler, Todd G B McLay, Frank Udovicic, David J Cantrill, Michael J Bayly
Author Information
  1. Patrick S Fahey: School of BioSciences The University of Melbourne Parkville Vic. Australia. ORCID
  2. Rachael M Fowler: School of BioSciences The University of Melbourne Parkville Vic. Australia. ORCID
  3. Todd G B McLay: School of BioSciences The University of Melbourne Parkville Vic. Australia. ORCID
  4. Frank Udovicic: Royal Botanic Gardens Victoria South Yarra Vic. Australia. ORCID
  5. David J Cantrill: Royal Botanic Gardens Victoria South Yarra Vic. Australia. ORCID
  6. Michael J Bayly: School of BioSciences The University of Melbourne Parkville Vic. Australia. ORCID
PMID: 33437459 DOI: 10.1002/ece3.7099

Abstract

AIM: To infer relationships between populations of the semi-arid, mallee eucalypt, , to build hypotheses regarding evolution of major disjunctions in the species' distribution and to expand understanding of the biogeographical history of southeastern Australia.
LOCATION: Southeastern Australia.
TAXON: (Myrtaceae, Angiospermae).
METHODS: We developed a large dataset of anonymous genomic loci for 97 samples from 11 populations of using double digest restriction site-associated DNA sequencing (ddRAD-seq), to determine genetic relationships between the populations. These relationships, along with species distribution models, were used to construct hypotheses regarding environmental processes that have driven fragmentation of the species' distribution.
RESULTS: Greatest genetic divergence was between populations on either side of the Lower Murray Basin. Populations west of the Basin showed greater genetic divergence between one another than the eastern populations. The most genetically distinct population in the east (Long Forest) was separated from others by the Great Dividing Range. A close relationship was found between the outlying northernmost population (near West Wyalong) and those in the Victorian Goldfields despite a large disjunction between them.
CONCLUSIONS: Patterns of genetic variation are consistent with a history of vicariant differentiation of disjunct populations. We infer that an early disjunction to develop in the species distribution was that across the Lower Murray Basin, an important biogeographical barrier separating many dry sclerophyll plant taxa in southeastern Australia. Additionally, our results suggest that the western populations fragmented earlier than the eastern ones. Fragmentation, both west and east of the Murray Basin, is likely tied to climatic changes associated with glacial-interglacial cycles although it remains possible that major geological events including uplift of the Mount Lofty Ranges and basalt flows in the Newer Volcanics Province also played a role.

Keywords

Eucalyptus climatic cycles ddRAD‐seq phylogeography population fragmentation species distribution model vicariance

Associated Data

Dryad | 10.5061/dryad.v9s4mw6sm

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Journal Article

Word Cloud

Created with Highcharts 10.0.0populationsdistributionAustraliageneticspeciesBasinrelationshipsmajorsoutheasternMurraypopulationinfersemi-aridmalleehypothesesregardingspecies'biogeographicalhistorylargefragmentationdivergenceLowerwesteasterneastdisjunctionclimaticcyclesAIM:eucalyptbuildevolutiondisjunctionsexpandunderstandingLOCATION:SoutheasternTAXON:MyrtaceaeAngiospermaeMETHODS:developeddatasetanonymousgenomicloci97samples11usingdoubledigestrestrictionsite-associatedDNAsequencingddRAD-seqdeterminealongmodelsusedconstructenvironmentalprocessesdrivenRESULTS:GreatesteithersidePopulationsshowedgreateroneanothergeneticallydistinctLongForestseparatedothersGreatDividingRangecloserelationshipfoundoutlyingnorthernmostnearWestWyalongVictorianGoldfieldsdespitethemCONCLUSIONS:PatternsvariationconsistentvicariantdifferentiationdisjunctearlydevelopacrossimportantbarrierseparatingmanydrysclerophyllplanttaxaAdditionallyresultssuggestwesternfragmentedearlieronesFragmentationlikelytiedchangesassociatedglacial-interglacialalthoughremainspossiblegeologicaleventsincludingupliftMountLoftyRangesbasaltflowsNewerVolcanicsProvincealsoplayedroleDivergentlineagescorrespondgeographicbreakEucalyptusddRAD‐seqphylogeographymodelvicariance

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