Researchers in Japan have offered new insights into how the brain’s circadian rhythm control centre regulates behaviour.
Circadian rhythms are a force in the background that shapes many human behaviours such feeling tired and falling asleep, as well as influencing our health. Michihiro Mieda and his team at Kanazawa University in Japan are researching just how the brain’s circadian rhythm control centre regulates behaviour.
The control centre, known as the superchiasmatic nucleus, or SCN, contains many types of neurons that transmit signals using the molecule GABA, but little is known about how each type contributes to our bodily rhythms. In this most recent study, the researchers focused on GABA neurons that produce arginine vasopressin, a hormone that regulates kidney function and blood pressure in the body, and which the team recently showed is also involved in the regulation of the interval of rhythms produced by the SCN.
To examine the function of these neurons separate to all others, the researchers first deleted a gene in mice which was needed for GABA signaling between neurons, but only in vasopressin-producing SCN neurons. “We removed a gene that codes for a protein that allows GABA to be packaged before it is sent to other neurons,” explained Mieda. “Without packaging, none of the vasopressin neurons could send out any GABA signals.”
Thus, these neurons could not use GABA to communicate with the rest of the SCN anymore. The mice showed longer periods of activity, beginning activity earlier and ending activity later than control mice, a simple enough result. It might seem that losing the packaging gene in the neurons disrupted the molecular clock signal but the result was not so simple. Closer examination deepened the mystery as the molecular clock seemed to progress unhindered.
Using calcium imaging, the researchers examined the clock rhythms within the vasopressin neurons. They found that while the rhythm of activity matched the timing of behaviour in control mice, this relationship was disturbed in the mice with missing GABA transmission in the vasopressin neurons. The rhythm of SCN output, ie SCN neuronal electrical activity, in the modified mice had the same irregular rhythm as their behaviour.
“Our study shows that GABA signaling from vasopressin neurons in the suprachiasmatic nucleus help fix behavioral timing within the constraints of the molecular clock,” concluded Mieda.
Source: News-Medical.Net
Journal reference: Maejima, T., et al. (2021) GABA from vasopressin neurons regulates the time at which suprachiasmatic nucleus molecular clocks enable circadian behavior. PNAS. doi.org/10.1073/pnas.2010168118.
