Molecular phylogeny and biogeography of the spider ants, genus Leptomyrmex Mayr (Hymenoptera: Formicidae)

[Display omitted] ► Leptomyrmex is monophyletic; ‘Macro-’ and ‘micro-’ Leptomyrmex are sister clades. ► NG species nested within NE Australia; NC species sister to central-E Australia. ► Genus arose in the Eocene; crown group diversification occurred in the Miocene. ► NG and NC lineages diverged fro...

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Bibliographic Details
Published in:Molecular phylogenetics and evolution 2011-05, Vol.59 (2), p.281-292
Main Author: Lucky, Andrea
Format: Article
Language:English
Subjects:
Animals
Ants - classification
Ants - genetics
Araneae
arginine kinase
Arginine Kinase - genetics
Australia
Base Sequence
Bayes Theorem
biogeography
cytochrome-c oxidase
Demography
Divergence dating
DNA Primers - genetics
DNA, Mitochondrial - genetics
Evolution, Molecular
Formicidae
genes
Genetic Variation
Hymenoptera
Leptomyrmex
Likelihood Functions
mitochondrial DNA
Models, Genetic
Molecular Sequence Data
monophyly
New Caledonia
New Guinea
Phylogeny
rain forests
rhodopsin
Rhodopsin - genetics
sclerophyll forests
Sequence Analysis, DNA
topology
wavelengths
Wnt1 Protein - genetics
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Summary:[Display omitted] ► Leptomyrmex is monophyletic; ‘Macro-’ and ‘micro-’ Leptomyrmex are sister clades. ► NG species nested within NE Australia; NC species sister to central-E Australia. ► Genus arose in the Eocene; crown group diversification occurred in the Miocene. ► NG and NC lineages diverged from Australian lineages 4.7 ma and 10.3 ma. ► Leptomyrmex is inferred to have reached NC via long distance dispersal. This study provides the first phylogenetic reconstruction of the ant genus Leptomyrmex Mayr, a prominent endemic component of rain forest and wet sclerophyll forest in Australia, New Guinea and New Caledonia. Five genes are used to reconstruct phylogeny and estimate of ages of diversification in order to test congruence of the history of nuclear and mitochondrial genes: three protein-coding nuclear genes: arginine kinase (argK, 897 bp), long wavelength rhodopsin (LW Rh, 546 bp) and wingless (Wg, 409 bp), as well as the large subunit ribosomal gene 28S (482 bp) and the mitochondrial gene cytochrome oxidase I (COI, 658 bp). Four different partitioning schemes were tested for optimal resolving power; results show that partitioning by gene, translational pattern and codon position were uniformly favoured over less complex partitions. Nuclear markers showed relatively minor sequence divergence and provided strongly supported topology; phylogeny based solely on mtDNA produced somewhat conflicting topology but offered little power to resolve species complexes. Monophyly of the genus Leptomyrmex was recovered, as was the sister-group relationship of ‘micro-’ and ‘macro-’ Leptomyrmex species. Divergence dating analyses estimate that Leptomyrmex arose in the Eocene (stem age ∼44 million years ago (ma)), and that the ‘macro-’ species diverged from the ‘micro-’ species in the early Oligocene (∼31 ma). Diversification of the crown group ‘macro-’ and ‘micro-’ Leptomyrmex occurred in the Miocene (∼15 ma and 7.9 ma, respectively). New Guinean and New Caledonian lineages appear to have diverged from Australian lineages only recently (∼4.7 ma and 10.3 ma, respectively), and the latter clade is inferred to have reached New Caledonia from Australia via long distance dispersal. These results challenge previous hypotheses of Leptomyrmex classification and assumptions about their historical dispersal, but are in agreement with the current knowledge of the geological history of Melanesia.
ISSN:1055-7903
1095-9513
DOI:10.1016/j.ympev.2011.03.004