Aligning biological clock with day-night cycles
Bacterial model shows DNA incorporation depends on the peaks and valleys of circadian rhythms
- Date:
- April 8, 2020
- Source:
- University of California - San Diego
- Summary:
- Scientists studying bacteria have identified the roots of a behavior that is regulated by the circadian clock. The research provides a striking example of the importance of keeping the internal biological clock aligned with the external environment so that key processes occur at the right time of day.
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Timing is everything. A fresh example supporting the old saying has been found in connection with the systems regulated by biological clocks.
Research on circadian rhythms, our internal 24-hour patterns that affect sleep-wake and metabolic cycles, has shown that timing is key for human health. When our activities and internal circadian clocks are out of step with the natural day-night cycle -- for example, in cases of irregular shift work, jet lag and poor sleep-wake habits -- we increase our risk of disease because of the mistiming of important biological processes. But the genetics behind these mechanisms haven't been well established.
Now scientists at the University of California San Diego studying photosynthetic bacteria called cyanobacteria, or "blue-green algae," have identified the roots of a behavior that is regulated by the circadian clock.
The findings, led by Division of Biological Sciences Associate Project Scientist Arnaud Taton and senior authors James and Susan Golden, are published in Nature Communications.
"I think this paper demonstrates the importance of having internal biological time coincide with environmental time," said UC San Diego Distinguished Professor Susan Golden, director of the Center for Circadian Biology and senior author of the paper. "There are lots of human illnesses in which people are poorly aligned to their environment. This can result from habits such as getting too much light at night, eating at odd times of the day and not sleeping regularly. In the cyanobacterium it makes a very big difference for biological time and external environment time to be aligned."
Scientists know that in the hunt for new genes, bacteria incorporate DNA from the environment. Such processes ensure that there is raw material to generate genetic variation, which is how species evolve. Yet the details of this puzzling process is understood in only a few organisms. The ability to take up DNA is typically tightly regulated, suggesting to scientists that it would be detrimental to the organism to indiscriminately take up foreign genes.
In the new study, the researchers identified the DNA uptake machinery in the cyanobacterium Synechococcus elongatus and discovered that the internal circadian clocks within their cells prevent DNA uptake early in the day and enhance the process early at night. They had predicted that clock-mediated expression of certain dusk-peaking, dark-induced genes is central for taking up DNA from the environment. They found that when darkness occurs at the time the cells' internal clock tells them it's dusk, DNA uptake and incorporation increase dramatically. In contrast, darkness at times that do not match the internal clock time fails to provide a boost in DNA uptake and incorporation.
As for why early DNA uptake is discouraged and late is enhanced, scientists aren't quite sure. They are testing hypotheses such as whether it may be helpful to avoid taking up potentially dangerous DNA when viruses are more prevalent, which in some environments is during the day.
"This study provides a striking example of the importance of keeping the internal biological clock aligned with the external environment so that processes occur at the right time of day," the researchers say.
The full author list includes Arnaud Taton, Christian Erikson, Yiling Yang, Benjamin Rubin (former graduate student supported by a Cellular and Molecular Genetics Training Grant), Scott Rifkin, James Golden and Susan Golden.
Funding for the study was provided by the National Institute of General Medical Sciences of the National Institutes of Health (R35GM118290 and R01GM118815) and the National Science Foundation (IOS-1754894).
Story Source:
Materials provided by University of California - San Diego. Original written by Mario Aguilera. Note: Content may be edited for style and length.
Journal Reference:
- Arnaud Taton, Christian Erikson, Yiling Yang, Benjamin E. Rubin, Scott A. Rifkin, James W. Golden, Susan S. Golden. The circadian clock and darkness control natural competence in cyanobacteria. Nature Communications, 2020; 11 (1) DOI: 10.1038/s41467-020-15384-9
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