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Introgression of mt DNA in Urosaurus lizards: historical and ecological processes
Author(s) -
Haenel Gregory J.
Publication year - 2017
Publication title -
molecular ecology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.619
H-Index - 225
eISSN - 1365-294X
pISSN - 0962-1083
DOI - 10.1111/mec.13930
Subject(s) - biology , introgression , ecology , evolutionary biology , zoology , genetics , gene
Introgression of mt DNA appears common in animals, but the implications of acquiring a novel mitochondrial genome are not well known. This study investigates mito‐genome introgression between the lizard species Urosaurus graciosus , a thermal specialist, and U. ornatus, a species that occupies a wider range of thermal environments. As ectotherms, their metabolic rate is strongly influenced by the thermal environment; with mitochondria being linked to metabolic rates, overall energy budgets could be impacted by introgression. I use mitochondrial gene trees, inferred from Bayesian analyses of Cyt‐B and ND 1 gene sequences, along with morphology and microsatellites from nineteen populations of these two species to address if the direction and location of mito‐nuclear discordance match predictions of introgression resulting from past population expansions. Mt DNA is expected to move from resident species into expanding or invading species. Second, does having a heterospecific form of mitochondria impact body size, a trait strongly associated with fitness? Multiple independent introgression events of historic origin were detected. All introgression was unidirectional with U. ornatus ‐type mt DNA found in U. graciosus parental type individuals. This result was consistent with population expansions detected in U. graciosus but not U. ornatus . Females with heterospecific mt DNA were significantly smaller than homospecific forms, and heterospecific males had a different relationship of body mass to body length than those with homospecific mt DNA . These changes indicate a potential selective disadvantage for individuals with heterospecific mitochondria and are consistent with the theoretical expectation that deleterious alleles are more likely to persist in expanding populations.