The 24-hour internal clock controls many
aspects of human behavior and physiology, including sleep, blood pressure, and
metabolism. Disruption in circadian rhythms leads to increased incidence of
many diseases, including metabolic disease and cancer.
Each
cell of the body has its own internal timing mechanism, which is controlled by
proteins that keep one another in check. One of these proteins, called Rev-erb
alpha, was thought to have a subordinate role because the clock runs fairly
normally in its absence.
New
work, published in Genes and Development this month, from the lab of Mitchell
Lazar, MD, PhD, director of the Institute for Diabetes, Obesity, and Metabolism
at the Perelman School of Medicine, University of Pennsylvania, found that a
closely related protein called Rev-erb beta serves as a back-up for Rev-erb
alpha. When both are not functioning, the cellular clock loses its time-keeping
function.
The two
Rev-erbs work together to control fat metabolism, and in their absence, the
liver fills with fat. These findings establish the Rev-erbs as major regulators
of both clock function and metabolism.
Lazar,
postdoctoral fellow Anne Bugge, PhD, and the team knocked out Rev-erb alpha in
mice and didn't see a large effect on the liver. When they knocked out both
Rev-erb alpha and Rev-erb beta, they saw a loss of the rhythmic cycling of the
clock protein Bmal 1's messenger RNA. They concluded that the Rev-erb system is
an integral part of the human clock, not ancillary.
Prior
to this paper, the Lazar team discovered molecules that act as "shift
workers" to maintain the daily rhythm of fat metabolism. When those
molecules do not do their jobs, the liver also dramatically fills with fat.
In
normal mice, the team of molecules migrates to the genome of liver cells during
the daytime. Rev-erb, one of the team members, delivers the molecular workers
to thousands of specific locations in the liver genome, many of which are near
genes involved in the production of fat. Another team member, histone
deacetylase 3 (HDAC3), does construction work on the protein scaffold (the
epigenome) surrounding the genome to dampen the activity of the fat-related
genes.
During
the night, the day shift molecules depart the liver genome, and fat production
increases due to other regulatory molecules. The fat production is kept in
check when the Rev-erb construction team returns to the genome the next day.
However, if HDAC3 is absent, the cycles do not occur, and the liver fills with
fat.
The absence
of both Rev-erbs prevents HDAC3 from doing its job, since Rev-erbs serve as the
shuttle delivering HDAC3 to target genes. Sure enough, fat accumulates in the
liver to a much great extent when both Rev-erbs are missing compared to when
one is still available.
"This
work shows that if we want to manipulate the human clock we would likely need
to affect both Rev-erb alpha and Rev-erb beta," explains Lazar.
"Circadian rhythm of metabolism is important because disruption of this
rhythm leads to a fatty liver. This may explain, in part, why altered circadian
rhythms in people who do shift work is associated with metabolic
disorders."
Source:
University of Pennsylvania School of Medicine
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