A
new study in mice concludes that light-sensitive proteins on fat cells can
detect sunlight. It also finds that too little natural light can alter how fat
cells behave and may increase the risk of metabolic syndrome.
Throughout
the evolution of life on Earth, much has changed. One notable constant,
however, is the light from our sun. We cannot overstate our reliance on this
huge ball of plasma 93 million miles away.
Because
life in all its forms evolved under the glow of our nearest star, animals have
evolved to utilize its emissions. Most obviously, the eyes contain
photoreceptors that detect light and share the information with the brain,
which then generates an image of a person’s surroundings.
The
light from the sun also trains us into a roughly 24 hour circadian sleep–wake
cycle. Virtually every land animal on Earth uses the sun to maintain their
daily rhythms.
A
new study that now appears in the journal Cell Reports describes
a new way that sunlight might influence the lives of mammals.
Animals
can detect light using proteins called opsins. Two of the most well-known in
humans are melanopsin and neuropsin, which are expressed in some retinal cells.
In
other animals, light-detecting compounds are present outside of the visual
system. For example, frogs can detect light through cells in their skin called
chromatophores.
Until
quite recently, scientists believed that mammals only detected light through
their eyes. However, several studies have now overturned this notion.
For instance, one study from 2019 found that neuropsin in the
skin of rats can detect light and help them maintain their circadian rhythms.
Still, evidence of so-called extraocular photoreception in mammals is scarce.
For
the first time, a new study has investigated whether or not certain proteins on
fat cells that lie beneath the skin might also detect light.
Senior
study author Richard Lang, Ph.D. — from Cincinnati Children’s Hospital Medical
Center in Ohio — explains, “This idea of light penetration into deep tissue is
very new, even to many of my scientific colleagues. But we and others have been
finding opsins located in a variety of tissue types. This is still just the
beginning of this work.”
The
researchers focused on opsin 3 (OPN3). This protein is present throughout the
body, including in the brain, testis, liver, and kidneys.
They
demonstrated that OPN3 is also present in both human and mouse fat cells, or
adipocytes. Also, importantly, they showed that light can travel deep enough
through a rat’s skin to trigger OPN3 in adipocytes.
A
specific wavelength of blue light (480 nanometers) stimulates OPN3. This occurs
in sunlight but not artificial light.
In
their experiments, the scientists used genetically engineered mice that lack
the gene coding for OPN3, called Opn3, in their adipocytes.
When
mammals, including humans, are in a cold environment, the body adapts. Aside
from shivering, the body burns fat to create heat. White adipose tissue is the
primary energy store, and brown adipose tissue is mainly responsible for
generating heat (without shivering) when we are cold.
In
a process called lipolysis, white adipose tissue releases free fatty acids and
glycerol into the bloodstream. Brown adipose fat then takes these fatty acids
and uses them to generate heat.
There
is a growing body of evidence supporting the idea that activating brown adipose
fat might protect against metabolic syndrome. Metabolic syndrome is a
collection of conditions, including hypertension, high blood sugar, abnormal
blood lipids, and excess body fat around the waist.
When
the researchers exposed mice lacking Opn3 in their adipocytes
to cold temperatures of 39.2ºF (4ºC), their response to the cold was impaired.
Their core body temperatures were lower than those of control mice with
intact Opn3 genes.
Brown
fat in the modified mice did not generate as much heat. Interestingly, when the
researchers deprived these mice of food, they did not burn off as much fat
under cold conditions as normal mice.
In
another experiment, the researchers placed normal adult mice in a cold
environment with full-spectrum lighting and monitored their core body
temperatures.
After
3 hours, they switched off the blue light of the wavelength that triggers OPN3
but left the rest of the spectrum. Without the blue wavelength, the animals’
core temperatures dropped, providing further evidence that natural,
full-spectrum light influences metabolism.
In
another set of experiments, the researchers raised mice with intact Opn3 genes
under lights that lacked the specific blue light wavelengths that normally
stimulate OPN3. The study authors refer to this as “minus blue” lighting
conditions.
Like
the mice that lacked Opn3, the mice raised in minus blue lighting
conditions did not respond efficiently to cold temperatures and had lower core
temperatures when in cold conditions. They also had larger adipocytes and did
not lose weight when fasting.
Overall, animals without Opn3 used
less energy and consumed less food and water. Despite being just as active as
normal mice, they expended less energy and carried higher levels of fat.
In
short, the study authors conclude that sunlight is essential for healthy energy
metabolism.
Although
the scientists conducted this study in mice, they believe that a similar
mechanism probably exists in humans. Of course, they will need to carry out
more research to explore whether or not this is the case. They write:
“If
the light-OPN3 adipocyte pathway exists in humans, there are potentially broad
implications for human health. Our modern lifestyle subjects us to unnatural
lighting spectra, exposure to light at night, shift work, and jet lag, all of
which result in metabolic disruption.”
Although
scientists are at the very start of this line of investigation, the study
authors theorize that “insufficient stimulation of the light-OPN3 adipocyte
pathway is part of an explanation for the prevalence of metabolic deregulation
in industrialized nations where unnatural lighting has become the norm.”
Looking
even further into the future — and assuming that other researchers can
replicate these findings — doctors might one day prescribe “light therapy” to
people at risk of developing metabolic syndrome.
Source: Medical News Today
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