Controlling the internal clock in darkness
How do people subjected to the endless dark days of winter in the far northern latitudes maintain normal daily rhythms? Though many might feel like hibernating, a highly regulated internal system keeps such impractical yearnings in check. From fruit flies to humans, nearly every living organism depends on an internal clock to regulate basic biological cycles such as sleep patterns, metabolism, and body temperature. And that clock runs on similar molecular mechanisms.
Specific clusters of neurons in the brain are known to control the biological clock. Scientists believed these brain “clock cells” function as independent units. But new research described in this issue show that the neurons do not act in isolation; rather they collaborate with other neurons in a cell-communication network to sustain the repeating circadian rhythm cycles.
Clock cells within the brain maintain an organisms circadian rhythms, even in the absence of cyclical environmental signals like light, in a state scientists call “free running.” Though it has long been clear that the circadian rhythms of an organism persist under such free-running conditions (for example, constant darkness), it was thought that the gene-expression patterns within the cells governing these biorhythms did not require any external, or extracellular, signals to continue ticking. In experiments described here, Michael Rosbash and his colleagues show that the key brain clock cells in fruit flies, called ventral lateral neurons, do indeed support the flys circadian rhythms during periods of constant darkness, and that the molecular expression patterns associated with these rhythms continue to cycle as well within other clock cells. These sustained expression patterns, however, require intercellular communication between different groups of brain clock cells.
In other words, the ventral lateral neurons do not act alone. When the molecular clock machinery was manipulated so that only the ventral lateral neurons were active, the flys circadian rhythms were not sustained, suggesting the rhythms depend on other neuronal groups as well. The researchers also demonstrate that the persistence of normal cycling during constant darkness depends on a protein (called PDF) secreted by the ventral lateral cells.
The PDF neuropeptide protein was thought to connect the molecular expression pattern of the ventral lateral neurons with the manifestation of circadian rhythms, but the researchers found evidence of a larger influence. When mutant flies lacking a functional PDF gene were exposed to constant darkness, the molecular expression patterns gradually stopped. The scientists say this suggests that the ventral lateral neurons and the PDF protein it produces help coordinate the entire neural network that underlies circadian rhythms.
CONTACT:
Ying Peng (Corresponding Author)
Dept. of Biology
Brandeis University
Waltham, MA 02454
United States of America
Phone: 781-736-3161
E-mail: pengying@brandeis.edu
Michael Rosbash (Author)
Dept. of Biology
Brandeis University
Waltham, MA 02454
USA
Phone: 781-736-3160
Fax: 781-736-3164
E-mail: rosbash@brandeis.edu
Peng Y, Stoleru D, Levine JD, Hall JC, Rosbash M (2003): Drosophila Free-Running Rhythms Require Intercellular Communication. DOI: 10.1371/journal.pbio.0000013. Download article PDF at:
http://www.plos.org/downloads/peng.pdf.
The article is published online as a sneak preview to PLoS Biology, the first open-access journal from the Public Library of Science (PLoS). The article will be part of the inaugural issue of the new journal, which will appear online and in print in October 2003. PLoS is a non-profit organization of scientists and physicians committed to making the worlds scientific and medical literature a freely available public resource (http://www.plos.org).
Media Contact
All latest news from the category: Life Sciences and Chemistry
Articles and reports from the Life Sciences and chemistry area deal with applied and basic research into modern biology, chemistry and human medicine.
Valuable information can be found on a range of life sciences fields including bacteriology, biochemistry, bionics, bioinformatics, biophysics, biotechnology, genetics, geobotany, human biology, marine biology, microbiology, molecular biology, cellular biology, zoology, bioinorganic chemistry, microchemistry and environmental chemistry.
Newest articles
Long-sought structure of powerful anticancer natural product
…solved by integrated approach. A collaborative effort by the research groups of Professor Haruhiko Fuwa from Chuo University and Professor Masashi Tsuda from Kochi University has culminated in the structure…
Making a difference: Efficient water harvesting from air possible
Copolymer solution uses water-loving differential to induce desorption at lower temperatures. Harvesting water from the air and decreasing humidity are crucial to realizing a more comfortable life for humanity. Water-adsorption…
In major materials breakthrough
UVA team solves a nearly 200-year-old challenge in polymers. UVA researchers defy materials science rules with molecules that release stored length to decouple stiffness and stretchability. Researchers at the University…