University of Michigan mathematicians and their British colleagues say they have identified the signal that the brain sends to the rest of the body to control biological rhythms, a finding that overturns a long-held theory about our internal clock.
Understanding how the human biological clock works is an essential step toward correcting sleep problems like insomnia and jet lag. New insights about the body’s central pacemaker might also, someday, advance efforts to treat diseases influenced by the internal clock, including cancer, Alzheimer’s disease and mood disorders, said University of Michigan mathematician Daniel Forger.
“Knowing what the signal is will help us learn how to adjust it, in order to help people,” said Forger, an associate professor of mathematics and a member of the U-M’s Center for Computational Medicine and Bioinformatics. “We have cracked the code, and the information could have a tremendous impact on all sorts of diseases that are affected by the clock.”
The body’s main time-keeper resides in a region of the central brain called the suprachiasmatic nuclei, or SCN. For decades, researchers have believed that it is the rate at which SCN cells fire electrical pulses—fast during the day and slow at night—that controls time-keeping throughout the body.
Imagine a metronome in the brain that ticks quickly throughout the day, then slows its pace at night. The rest of the body hears the ticking and adjusts its daily rhythms, also known as circadian rhythms, accordingly.
That’s the idea that has prevailed for more than two decades. But new evidence compiled by Forger and his colleagues shows that “the old model is, frankly, wrong,” Forger said.
The true signaling mechanism is very different: The timing signal sent from the SCN is encoded in a complex firing pattern that had previously been overlooked, the researchers concluded. Forger and U-M graduate student Casey Diekman, along with Dr. Mino Belle and Hugh Piggins of the University of Manchester in England, report their findings in the Oct. 9 edition of Science. …
Awesome! Just send the signal in reverse and, if we want, we can get younger instead of older. 😉