AI Article Synopsis
- The microsporidian Nosema ceranae is a growing threat to honeybees and other pollinators globally, showcasing a surprising ability to adapt despite not having a typical sexual reproduction process.
- Recent studies using advanced techniques revealed that there may be some genetic recombination occurring among the Nosema ceranae strains infecting honeybees, which contradicts previous beliefs about its life cycle.
- The findings indicate potential genetic variation within the parasite population and suggest the possibility of a diploid stage, shedding light on the dynamics of its spread among honeybee colonies.
Article Abstract
The microsporidian Nosema ceranae is an emergent pathogen that threatens the health of honeybees and other pollinators all over the world. Its recent rapid spread across a wide variety of host species and environments demonstrated an enhanced ability of adaptation, which seems to contradict the lack of evidence for genetic recombination and the absence of a sexual stage in its life cycle. Here we retrieved fresh data of the patterns of genetic variation at the PTP2 locus in naturally infected Apis mellifera colonies, by means of single genome amplification. This technique, designed to prevent the formation of chimeric haplotypes during polymerase chain reaction (PCR), provides more reliable estimates of the diversity levels and haplotype structure than standard PCR-cloning methods. Our results are consistent with low but significant rates of recombination in the history of the haplotypes detected: estimates of the population recombination rate are of the order of 30 and support recent evidence for unexpectedly high levels of variation of the parasites within honeybee colonies. These observations suggest the existence of a diploid stage at some point in the life cycle of this parasite and are relevant for our understanding of the dynamics of its expanding population.
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| http://dx.doi.org/10.1111/1462-2920.12574 | DOI Listing |
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