Coexistence of minicircular and a highly rearranged mtDNA molecule suggests that recombination shapes mitochondrial genome organization.

Citation data:

Molecular biology and evolution, ISSN: 1537-1719, Vol: 31, Issue: 3, Page: 636-44

Publication Year:
Usage 18
Abstract Views 16
Link-outs 2
Captures 27
Readers 27
Social Media 4
Tweets 4
Citations 18
Citation Indexes 18
Repository URL:
Mao, Meng; Austin, Andrew D.; Johnson, Norman F.; Dowton, Mark
Oxford University Press (OUP)
Agricultural and Biological Sciences; Biochemistry, Genetics and Molecular Biology; mtDNA; recombination; minicircle; maxicircle; gene rearrangement; PCR artifact; numts; CMMB; Medicine and Health Sciences; Social and Behavioral Sciences
Most Recent Tweet View All Tweets
article description
Recombination has been proposed as a possible mechanism to explain mitochondrial (mt) gene rearrangements, although the issue of whether mtDNA recombination occurs in animals has been controversial. In this study, we sequenced the entire mt genome of the megaspilid wasp Conostigmus sp., which possessed a highly rearranged mt genome. The sequence of the A+T-rich region contained a number of different types of repeats, similar to those reported previously in the nematode Meloidogyne javanica, in which recombination was discovered. In Conostigmus, we detected the end products of recombination: a range of minicircles. However, using isolated (cloned) fragments of the A+T-rich region, we established that some of these minicircles were found to be polymerase chain reaction (PCR) artifacts. It appears that regions with repeats are prone to PCR template switching or PCR jumping. Nevertheless, there is strong evidence that one minicircle is real, as amplification primers that straddle the putative breakpoint junction produce a single strong amplicon from genomic DNA but not from the cloned A+T-rich region. The results provide support for the direct link between recombination and mt gene rearrangement. Furthermore, we developed a model of recombination which is important for our understanding of mtDNA evolution.