OBESITY BREAKTHROUGH -- METABOLIC MASTER SWITCH PROMPTS FAT CELLS TO STORE OR BURN FAT
Obesity is one of the biggest public health
challenges of the 21st century. Affecting more than 500 million people
worldwide, obesity costs at least $200 billion each year in the United States
alone, and contributes to potentially fatal disorders such as cardiovascular
disease, type 2 diabetes, and cancer.
But there may now be a
new approach to prevent and even cure obesity, thanks to a study led by
researchers at MIT and Harvard Medical School and published today in the New
England Journal of Medicine. By analyzing the cellular circuitry underlying
the strongest genetic association with obesity, the researchers have unveiled a
new pathway that controls human metabolism by prompting our adipocytes, or fat
cells, to store fat or burn it away.
"Obesity has
traditionally been seen as the result of an imbalance between the amount of
food we eat and how much we exercise, but this view ignores the contribution of
genetics to each individual's metabolism," says senior author Manolis
Kellis, a professor of computer science and a member of MIT's Computer Science
and Artificial Intelligence Laboratory (CSAIL) and of the Broad Institute.
New mechanism found
The strongest
association with obesity resides in a gene region known as "FTO,"
which has been the focus of intense scrutiny since its discovery in 2007.
However, previous studies have failed to find a mechanism to explain how
genetic differences in the region lead to obesity.
"Many studies
attempted to link the FTO region with brain circuits that control appetite or
propensity to exercise," says first author Melina Claussnitzer, a visiting
professor at CSAIL and instructor in medicine at Beth Israel Deaconess Medical
Center and Harvard Medical School. "Our results indicate that the
obesity-associated region acts primarily in adipocyte progenitor cells in a
brain-independent way."
To recognize the cell
types where the obesity-associated region may act, the researchers used
annotations of genomic control switches across more than 100 tissues and cell
types. They found evidence of a major control switchboard in human adipocyte
progenitor cells, suggesting that genetic differences may affect the
functioning of human fat stores.
To study the effects
of genetic differences in adipocytes, the researchers gathered adipose samples
from healthy Europeans carrying either the risk or the non-risk version of the
region. They found that the risk version activated a major control region in
adipocyte progenitor cells, which turned on two distant genes, IRX3 and IRX5.
Control of
thermogenesis
Follow-up experiments
showed that IRX3 and IRX5 act as master controllers of a process known as
thermogenesis, whereby adipocytes dissipate energy as heat, instead of storing
it as fat. Thermogenesis can be triggered by exercise, diet, or exposure to
cold, and occurs both in mitochondria-rich brown adipocytes that are
developmentally related to muscle, and in beige adipocytes that are instead
related to energy-storing white adipocytes.
"Early studies of
thermogenesis focused primarily on brown fat, which plays a major role in mice,
but is virtually nonexistent in human adults," Claussnitzer says.
"This new pathway controls thermogenesis in the more abundant white fat
stores instead, and its genetic association with obesity indicates it affects
global energy balance in humans."
The researchers
predicted that a genetic difference of only one nucleotide is responsible for
the obesity association. In risk individuals, a thymine (T) is replaced by a
cytosine (C) nucleobase, which disrupts repression of the control region and
turns on IRX3 and IRX5. This then turns off thermogenesis, leading to lipid
accumulation and ultimately obesity.
By editing a single
nucleotide position using the CRISPR/Cas9 system -- a technology that allows
researchers to make precise changes to a DNA sequence -- the researchers could
switch between lean and obese signatures in human pre-adipocytes. Switching the
C to a T in risk individuals turned off IRX3 and IRX5, restored thermogenesis
to non-risk levels, and switched off lipid storage genes.
"Knowing the
causal variant underlying the obesity association may allow somatic genome
editing as a therapeutic avenue for individuals carrying the risk allele,"
Kellis says. "But more importantly, the uncovered cellular circuits may
allow us to dial a metabolic master switch for both risk and non-risk
individuals, as a means to counter environmental, lifestyle, or genetic
contributors to obesity."
Success in human and
mouse cells
The researchers showed
that they could indeed manipulate this new pathway to reverse the signatures of
obesity in both human cells and mice.
In primary adipose
cells from either risk or non-risk individuals, altering the expression of
either IRX3 or IRX5 switched between energy-storing white adipocyte functions
and energy-burning beige adipocyte functions.
Similarly, repression
of IRX3 in mouse adipocytes led to dramatic changes in whole-body energy
balance, resulting in a reduction of body weight and all major fat stores, and
complete resistance to a high-fat diet.
"By manipulating
this new pathway, we could switch between energy storage and energy dissipation
programs at both the cellular and the organismal level, providing new hope for
a cure against obesity," Kellis says.
The researchers are
currently establishing collaborations in academia and industry to translate
their findings into obesity therapeutics. They are also using their approach as
a model to understand the circuitry of other disease-associated regions in the
human genome.
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