It suggests avenues for novel treatments
From: Harvard Medical School
April 29, 2022 -- Scientists pinpoint the molecular
epicenter of deep-sleep regulation. The findings, based on research in mice,
identify a gene that makes a protein that regulates delta waves -- electrical
signals between neurons that occur during the deepest phases of relaxation and
are a hallmark of restorative sleep.
Healthy sleep is a basic physiologic need. In its
absence, a myriad of processes in the body can go terribly awry. Chronic sleep
problems have been linked to mental health disorders, cardiovascular disease,
type 2 diabetes, and obesity, among other conditions.
Yet, consistently achieving the deep, restorative
sleep necessary for optimal physiologic health and peak cognitive performance
can be difficult due to lifestyle, environmental, and biologic factors.
One of the most confounding questions in sleep
biology has been how deep sleep is regulated by the brain. The answer could
help illuminate new ways to mitigate sleep problems.
Now, a newly published study led by Harvard Medical
School researchers at VA Boston Healthcare System offers critical clues into
this longstanding mystery.
The work, conducted in mice and published April 26
in Nature Communications, identifies an area in the brain that
regulates the oscillations of delta waves -- electrical signals transmitted
across neurons that arise during the deepest phases of relaxation. They are a
hallmark of restorative sleep.
The research team homed in on neurons in the
thalamus, a region of the brain that regulates sleep and wakefulness, among
other functions. Using CRISPR-Cas9 gene editing, the researchers disrupted a
gene that codes for a protein that binds the inhibitory neurotransmitter GABA.
The protein is a target of drugs that promote sleep. Disruption of this gene in
mouse models boosted the activity of delta waves and enhanced deep sleep in the
animals.
If replicated in further animal models, the findings
could lay the groundwork for designing therapies that precision-target this
protein to induce deep sleep.
"Our findings represent an important step
forward in pinpointing the molecular basis of sleep regulation and point to an
alternative pharmacologic strategy for promoting natural, restorative
sleep," said study senior investigator Radhika Basheer, associate
professor of psychiatry at HMS and VA Boston.
New therapies are sorely needed. Commonly used
insomnia medicines, while an important tool for treatment of persistent
insomnia, have well-known drawbacks. Many of these medications work by getting
people to fall asleep fast, but they also tend to dampen the activity of
restorative delta waves. Thus, while such medications promote falling asleep,
the slumber they induce is not necessarily restorative.
"We believe our findings set the stage for
developing a new class of sleep medicines that can achieve this all-important
maintenance of deep sleep by boosting delta wave oscillations," added
Basheer, who co-led the study with colleague Ritchie Brown, associate professor
of psychiatry at HMS.
HMS co-authors include David Uygun, Chun Yang, Fumi
Katsuki, Erik Hodges, James McKenna, and James McNally. Elena Tilli of
Stonehill College was also a co-author on the study.
https://www.sciencedaily.com/releases/2022/04/220429145059.htm
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