PROTEIN REGULATES BURNING OF BODY FAT
Muscle movements
generate body heat. However, body heat can also be generated in another way:
body fat contains a small number of brown adipose cells -- special fat cells
that can generate heat without muscle activity. They do this using a protein
known as UCP1 that enables babies or hibernating animals to keep warm without
shivering. A research team at the University of Veterinary Medicine (Vetmeduni
Vienna) has found that a specific chemical compound, an aldehyde, can activate
UCP1 under certain conditions, and that could also trigger fat burning. The
data were published in the journal PLoS One
The uncoupling Protein
1 (UCP1) is found exclusively in brown adipose tissue. Until some years ago it
was thought that only babies and hibernating animals had brown adipose tissue,
but since then it also has been found in adults, so UCP1 could be useful in the
fight against obesity. "If we can find out how to regulate this protein,
we might also find a way to trigger fat burning in the body," explains biophysicist
Elena Pohl from the Unit of Physiology and Biophysics at the Vetmeduni Vienna.
UCP1 burns energy
UCP1 is located in the
membrane of mitochondria, the power plants that fuel every single cell in the
body. Cells that require a lot of energy, such as muscle cells, contain many
mitochondria. But brown adipose tissue contains even more mitochondria than
muscle tissue. In fact, it is the mitochondria that are responsible for the
brown colour of this form of adipose tissue. Regular adipose tissue, which is
the majority, is white. UCP1 in mitochondria uses the cell's energy to produce
heat. If UCP1 is 'turned off' in mice, the animals will freeze. Hibernating
animals would not survive the winter if they did not have this protein.
Researchers aim to
regulate UCP1
Elena Pohl and her
research group are trying to find a way to regulate UCP1. In a project funded
by the FWF, they have tested different substances reported to activate UCP1,
under them also reactive aldehyde 4-hydroxy-2-nonenal (HNE).Using an artificial
cell membrane containing UCP1, the researchers were able to detect the activity
of the protein by measuring the electrical conductivity on the membrane. The
researchers dripped HNE onto the membrane and found that UCP1 can be activated
by HNE only if combined with fatty acids. "In this model, all the
'players' are known so we could determine clearly whether the substance
influences the protein directly or not. The discovery helps to improve our
understanding of the mechanisms that regulate UCP1 and may even lead us to a
way to burn body fat," explains co-author Olga Jovanovic.
Reducing free radicals
Free radicals play an
important role in many biological processes, but they also cause cellular
damage and play a crucial role in the pathogenesis of various diseases such as
cancer, atherosclerosis and Alzheimer's disease. The research team has also
shown that HNE, combined with fatty acids, also has the potential to minimize
these damaging free radicals by reducing the membrane potential. "We want
to elucidate the molecular mechanisms of UCP. We are still examining various
aldehydes and other UCPs. There are five different UCPs and all their functions
are not yet fully understood. We hope that our work will contribute to the
development of therapies for various diseases."
Drugs in the battle
against obesity
In the 1930s, a
substance similar to UCP1 was developed that seemed to promise an easy way of
losing weight. The substance was called 2,4-dinitrophenol and, like UCP1, it
worked as an uncoupler in the mitochondria of cells. Taken in the right
amounts, the drug accelerates the human metabolism by up to 50 percent.
However, in some cases it caused serious or even lethal side effects and had to
be withdrawn from the market. "If we are able to regulate UCP1 in a controlled
way, it might be different story," says Pohl.
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