Bees Bounce Back From Disease

By comparing museum samples with modern bees, scientists have witnessed natural selection in action.

AsianScientist (Aug. 26, 2015) – Research published in Nature Communications suggests that honeybee populations have rapidly evolved resistance to predatory mites while maintaining their genetic diversity.

“They took a hit, but they recovered,” said Alexander Mikheyev, a professor at the Okinawa Institute of Science and Technology Graduate University (OIST) in Japan and lead paper author. “The population appears to have developed genetic resistance.”

Mikheyev and his collaborators at OIST and Cornell University studied the population genetics of the wild colony by comparing the DNA of specimens collected in 1977 with bees collected from the same forest in 2010. To conduct the study, they developed a new DNA analysis tool that works especially well for degraded DNA stored in museum samples.

Such a study is extremely rare, especially with bees. Few people collect them, and even fewer collect in a way that is good enough for a population level study. Luckily, Cornell Professor Tom Seeley worked in this area during his Ph.D., and deposited his samples in the Cornell University Insect Collection. This is the first time scientists have been able to observe genome-wide changes after a specific event like the mite invasion.

“By using museum specimens, we see how evolution happens as compared to how we think it happens,” said Mikheyev, who runs OIST’s Ecology and Evolution Unit.

Museum bees (blue bars) are more closely related to modern bees from the same population (red bars), which is represented by the grey lines connecting the groups. A US domestic population (black bars) is more closely related to modern bees than museum specimens, which is represented by the orange lines connecting the three groups. This pattern confirms that modern bees experience gene flow from the wild bees in past, and from other domestic populations. Credit: OIST.
Museum bees (blue bars) are more closely related to modern bees from the same population (red bars), which is represented by the grey lines connecting the groups. A US domestic population (black bars) is more closely related to modern bees than museum specimens, which is represented by the orange lines connecting the three groups. This pattern confirms that modern bees experience gene flow from the wild bees in past, and from other domestic populations. Credit: OIST.

Many people think of evolution happening over thousands or millions of years, but in fact, it is happening from generation to generation. External forces cause certain traits to be selected and passed on to offspring to enhance their chance of survival and reproduction. By comparing bees from the same colony only a few decades a part, the team was able to see this natural selection in action.

The bees changed in several different ways.

First, mitochondrial DNA, the genetic material stored in cells’ power plants, changed significantly from the older generation to the newer generation. That genetic material is only passed on from the mothers, so a major change indicates the old queen bees were wiped out and there were large-scale population losses. Even so, the population still maintained a high level of genetic diversity throughout the rest of genome, which is stored in the cell nucleus.

One of the most interesting changes in the bee population was in a gene related to a dopamine receptor known to control aversion learning. Another study has suggested this receptor is involved with bees grooming themselves to get rid of the mites by chewing them up.

The researchers also found many changes in genes associated with development. Mites reproduce and feed on the bee during the bees’ larval stage, so the researchers hypothesize that bees evolved to disrupt that process. Also, there were physical changes: today’s bees are smaller than the older bees and their wing shape is different.

The researchers note changes observed cannot be prescribed to any one factor, such as the mites, because the timeframe is too long. However, many of the changes are too large to be due to random genetic fluctuations, or the introduction of genes from other sources, like Africanized bees, and found the strongest driver of the observed changes was still natural selection.

“These findings identify candidate genes that could be used for breeding more resistant bees, such as the dopamine receptor gene,” Mikheyev said. “More importantly, it suggests the importance of maintaining high levels of genetic diversity in domestic bee stocks, which may help overcome future diseases.”

The article can be found at: Mikheyev et al. (2015) Museum Samples Reveal Rapid Evolution by Wild Honey Bees Exposed to a Novel Parasite.

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Source: OIST.
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