What is in this article?:
- How bees decide what to be
- Nurses and foragers
- Scientists report what is believed to be the first evidence that complex, reversible behavioral patterns in bees — and presumably other animals — are linked to reversible chemical tags on genes in the brain
Scientists at Arizona State University, the Norwegian University of Life Sciences, and Johns Hopkins University report what is believed to be the first evidence that complex, reversible behavioral patterns in bees — and presumably other animals — are linked to reversible chemical tags on genes in the brain.
The scientists say what is most significant about the new study, described online in Nature Neuroscience, is that for the first time, DNA methylation “tagging” has been linked to something at the behavioral level of a whole organism. On top of that, they say, the behavior in question, and its corresponding molecular brain changes, are reversible, which has important implications for human health.
“Bees are famous models used in research related to the brain and behavior,” said Gro Amdam, associate professor at ASU’s School of Life Sciences, and Pew Scholar in Biomedical Sciences. “The molecular principles of bees help us understand the brain machineries of other animals.”
According to Andy Feinberg, professor of molecular medicine and director of the Center for Epigenetics at Hopkins’ Institute for Basic Biomedical Sciences, the addition of DNA methylation to genes has long been shown to play an important role in regulating gene activity in changing biological systems, such as fate determination in stem cells or the creation of cancer cells. Curious about how epigenetics might contribute to behavior, researchers studied a tried-and-true model of animal behavior: bees.
Scientists discovered significant differences in DNA methylation patterns in bees that have equal genetic sequences, but vastly different behavioral patterns.
Employing a method that allows the researchers to analyze the whole genome at once, dubbed CHARM (comprehensive high-throughput arrays for relative methylation), the team analyzed the location of DNA methylations in the brains of worker bees of two different “professions.” All worker bees are female and, within a given hive, are all siblings. However, they don’t all do the same thing; some nurse and some forage.
Nurses are generally younger and remain in the hive to take care of the queen and her larvae. When nurses mature, they become foragers that leave the hive to gather pollen and other supplies for the hive.
“Genes themselves weren’t going to tell us what is responsible for the two types of behavior,” Feinberg said. “But epigenetics – and how it controls genes – could.”
Amdam and Feinberg started their experiment with new hives populated by bees of the same age. That removed the possibility that any differences they might find could be attributed to differences of age.
“When young, age-matched bees enter a new hive, they divvy up their tasks so that the right proportion becomes nurses and foragers,” explained Amdam. It is these two groups that were tested after painstakingly characterizing and marking each bee with its “professional,” or behavioral category.
Analyzing the patterns of DNA methylation in the brains of 21 nurses and 21 foragers, the team found 155 regions of DNA that had different tag patterns in the two types of bees. The genes associated with the methylation differences were mostly regulatory genes known to affect the status of other genes.
“Methylation tags are like fingers playing on a piano,” Amdam said. “The piano is the DNA, and nurses and foragers are two different tunes. The fingers and the brain DNA are the same in both types of bees; it is just that the fingers are in different places.”
Once the researchers knew differences existed, they could take the next step to determine if the differences were permanent.