Summary: A new study reports that social time cues override influences of light and darkness in regulating the circadian rhythm of honeybees.
Source: Hebrew University of Jerusalem.
Hebrew University field study shows for the first time that social time cues override influence of light and darkness in regulating the natural body clock of honeybees, highlighting the complexity of clock regulation in natural habitat.
Circadian rhythms are internal clocks that determine many of an organism’s daily rhythms, for example sleep-wake, feeding, urinary output and hormone production. Aligned with the environment by external forces such as sunlight and ambient temperature, circadian rhythms are important for animal health and survival. Disturbances of the circadian clock are associated with a variety of diseases in humans and animals, including cancer, mental illnesses and metabolic disorders, such as diabetes and obesity.
The dominant role of light in adjusting the circadian rhythm to the local environment has consistently been emphasized in studies on individually-isolated animals in laboratories. Interactions with others of the same species, while very important for animal survival and fitness in nature, are not considered important external stimuli that affect the animal circadian clock.
Now, a study conducted by researchers from the Hebrew University of Jerusalem and published in the journal Nature Communications challenges this view.
The researchers performed a set of large scale experiments in which they manipulated social interactions and light exposure for more than 1,000 honeybees in cages, or in freely foraging colonies housed in observation hives, allowing research in an ecologically relevant context. Every experiment was repeated two to four times, each with bees from a different source colony (which were genetically different).
“We show for the first time that social time cues stably adjust the clock, even in animals experiencing conflicting light exposure and social cycles,” said Prof. Guy Bloch from the Department of Ecology, Evolution & Behavior at The Hebrew University’s Alexander Silberman Institute of Life Sciences, who led the study.
The researchers collected a massive data set which demonstrated that in honeybees, social interactions can override potent light exposure as external cues that influence the biological clock.
The data showed that resetting the circadian rhythm by manipulating the social environment had a robust and stable effect for several days even for 2-day-old bees, which are typically active around the clock with no overt circadian rhythms. Remarkably, young bees that experienced conflicting light and social cycles showed a phase that was more similar to the social cycle. When removed from the hive and monitored individually in constant laboratory conditions, they maintained the phase of the social cycle, meaning this potent social factor does not depend on physical contact with other bees in the colony.
“This study provides the strongest available evidence for the power of social entrainment, and emphasizes the importance of studying circadian rhythms in a species-specific, ecologically-relevant context,” said Prof. Bloch.
Social insects are ecologically important and offer attractive model systems for studies on the interplay between social behavior and circadian rhythms. The best evidence for the influence of social activity on the internal clock is found in dark cavity-dwelling social animals, such as bees and bats. These species may be especially responsive to social influence, because individuals may not experience ambient conditions directly, but rather rely on information received from group mates that forage outside their domicile.
This study adds to recent research showing the circadian rhythms in complex natural environments may profoundly differ from those in controlled laboratory conditions. “Studies in the real world will provide a better understanding of the function and regulation of biological clocks,” said Prof. Bloch.
The study also indicates that social signals may be important time-givers for the clocks of other animals, including mammals, and could contribute to the research on sleep and behavioral disorders, as well as for the understanding of the complex life of bee societies.
About this neuroscience research article
Funding: Israel Science Foundation, JapanSociety for the Promotion of Science funded the study.
Source: Avivit Delgoshen – Hebrew University of Jerusalem Image Source: This NeuroscienceNews.com image is credited to Muki Nagari. Original Research: Full open access research for “Potent social synchronization can override photic entrainment of circadian rhythms” by Taro Fuchikawa, Ada Eban-Rothschild, Moshe Nagari, Yair Shemesh and Guy Bloch in Nature Communications. Published online May 23 2016 doi:10.1038/ncomms11662
Cite This NeuroscienceNews.com Article
[cbtabs][cbtab title=”MLA”]Hebrew University of Jerusalem. “Honeybee Circadian Rhythms are Affected More by Social Interactions.” NeuroscienceNews. NeuroscienceNews, 28 June 2016. <https://neurosciencenews.com/circadian-rhythm-bee-social-interaction-4587/>.[/cbtab][cbtab title=”APA”]Hebrew University of Jerusalem. (2016, June 28). Honeybee Circadian Rhythms are Affected More by Social Interactions. NeuroscienceNews. Retrieved June 28, 2016 from https://neurosciencenews.com/circadian-rhythm-bee-social-interaction-4587/[/cbtab][cbtab title=”Chicago”]Hebrew University of Jerusalem. “Honeybee Circadian Rhythms are Affected More by Social Interactions.” https://neurosciencenews.com/circadian-rhythm-bee-social-interaction-4587/ (accessed June 28, 2016).[/cbtab][/cbtabs]
Potent social synchronization can override photic entrainment of circadian rhythms
Circadian rhythms in behaviour and physiology are important for animal health and survival. Studies with individually isolated animals in the laboratory have consistently emphasized the dominant role of light for the entrainment of circadian rhythms to relevant environmental cycles. Although in nature interactions with conspecifics are functionally significant, social signals are typically not considered important time-givers for the animal circadian clock. Our results challenge this view. By studying honeybees in an ecologically relevant context and using a massive data set, we demonstrate that social entrainment can be potent, may act without direct contact with other individuals and does not rely on gating the exposure to light. We show for the first time that social time cues stably entrain the clock, even in animals experiencing conflicting photic and social environmental cycles. These findings add to the growing appreciation for the importance of studying circadian rhythms in ecologically relevant contexts.
“Potent social synchronization can override photic entrainment of circadian rhythms” by Taro Fuchikawa, Ada Eban-Rothschild, Moshe Nagari, Yair Shemesh and Guy Bloch in Nature Communications. Published online May 23 2016 doi:10.1038/ncomms11662