August 10, 2015 by Krishna Ramanujan
Some honeybee colonies adapt in wake of deadly mites
A new
genetics study of wild honeybees offers clues to how a population has adapted
to a mite that has devastated bee colonies worldwide. The findings may aid
beekeepers and bee bre
he
researchers genetically analyzed museum samples collected from wild honeybee
colonies in 1977 and 2010; the bees came from Cornell University's Arnot
Forest. In comparing genomes from the two time periods, the results – published
Aug. 6 in Nature Communications – show clear evidence that the wild
honeybee colonies experienced a genetic bottleneck - a loss of genetic
diversity - when the Varroa destructor mites killed most of the honeybee
colonies. But some colonies survived, allowing the population to
rebound.
"The
study is a unique and powerful contribution to understanding how honeybees have
been impacted by the introduction of Varroa destructor, and how, if left alone,
they can evolve resistance to this deadly parasite," said Thomas Seeley,
the Horace White Professor in Biology at Cornell and the paper's senior author.
Sasha Mikheyev '00, an assistant professor of ecology and evolution at Okinawa
Institute of Science and Technology (OIST) in Japan, is the paper's first
author.
"The
paper is also a clear demonstration of the importance of museum collections, in
this case the Cornell University Insect Collection, and the importance of wild
places, such as Cornell's Arnot Forest," Seeley added.
In the 1970s, Seeley surveyed the population of wild colonies of honeybees (Apis
mellifera) in Arnot Forest, and found 2.5 colonies per square mile. By the
early 1990s, V. destructor mites had spread across the U.S. to New York state
and were devastating bee colonies. The mites infest nursery cells in
honeybee nests and feed on developing bees while also transferring virulent
viruses.
A 2002
survey of Arnot Forest by Seeley revealed the same abundance of bee colonies as
in the late 1970s, suggesting that either new colonies from beekeepers' hives
had repopulated the area, or that the existing population had undergone strong
natural selection and came out with good resistance.
By 2010,
advances in DNA technology, used previously to stitch together fragmented DNA
from Neanderthal samples, gave Mikheyev, Seeley and colleagues the tools for
whole-genome sequencing and comparing museum and modern specimens.
The results revealed a huge loss in diversity of mitochondrial genes, which are passed from one generation to the next only through the female lineage. This shows that the wild population of honeybees experienced a genetic bottleneck. Such bottlenecks arise when few individuals reproduce, reducing the gene pool. "Maybe only four or five queens survived and repopulated the forest," Seeley said.
At the same
time, the surviving bees show high genetic diversity in their nuclear genes,
passed on by dying colonies that still managed to produce male bees. The
nuclear DNA showed widespread genetic changes, a signature of adaptation.
"Even when a colony is not doing well, it can still produce a batch of
males, so nuclear genes were not lost," Seeley said.
The data
also show a lack of genes coming from outside populations, such as beekeepers'
bees.
The
surviving bees evolved to be smaller, suggesting these bees might require less
time to develop. Since the mites infest nursery cells in hives, the shorter
development time may allow young bees to develop into adulthood before the
mites can finish their development. Mite-resistant honeybees in Africa are also
small and have short development times, Seeley said.
Next, the
researchers will study which genes and traits confer resistance to Varroa
mites. The findings may help beekeepers to avoid pesticides for controlling
mites and to trust the process of natural selection, and bee breeders to
develop bees with the traits that have enabled bees to
survive in the wild.
A new genetics study of
wild honeybees offers clues to how a population has adapted to a mite
that has devastated bee colonies worldwide. The findings may aid
beekeepers and bee breeders to prevent future honeybee declines.
Read more at: http://phys.org/news/2015-08-honeybee-colonies-deadly-mites.html#jCp
Read more at: http://phys.org/news/2015-08-honeybee-colonies-deadly-mites.html#jCp
A new genetics study of
wild honeybees offers clues to how a population has adapted to a mite
that has devastated bee colonies worldwide. The findings may aid
beekeepers and bee breeders to prevent future honeybee declines.
Read more at: http://phys.org/news/2015-08-honeybee-colonies-deadly-mites.html#jCp
Read more at: http://phys.org/news/2015-08-honeybee-colonies-deadly-mites.html#jCp
A new genetics study of
wild honeybees offers clues to how a population has adapted to a mite
that has devastated bee colonies worldwide. The findings may aid
beekeepers and bee breeders to prevent future honeybee declines.
Read more at: http://phys.org/news/2015-08-honeybee-colonies-deadly-mites.html#jCp
Read more at: http://phys.org/news/2015-08-honeybee-colonies-deadly-mites.html#jCp
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