Scientists have discovered a protein that regulates body weight in mice, an insight that could lead to new treatments for metabolic disorders.
The research team decided to take a closer look at the protein, called augmentor-alpha, because of its connection to cancer. The protein is known to bind to and activate the anaplastic lymphoma kinase receptor (ALK), a molecule that, when mutated, drives a variety of human cancers, including pediatric neuroblastoma, B-cell lymphomas, and certain lung cancers.
To better understand this protein and the role it plays in the body, the researchers first wanted to pinpoint where it is commonly located. Looking in mice, they found that augmentor-alpha was most strongly expressed in the hypothalamus region of the brain.
“AgRP neurons are so important for feeling hunger that without them, you wouldn’t eat. You’d die.”
In particular, they found it was expressed within cells called agouti-related peptide (AgRP) neurons, which are known to promote hunger.
“AgRP neurons are so important for feeling hunger that without them, you wouldn’t eat. You’d die,” says Tamas Horvath, professor of comparative medicine at Yale University and an author of the study in the Proceedings of the National Academy of Sciences.
“So when it became clear that augmentor-alpha was dominantly expressed in these neurons, it immediately suggested that augmentor-alpha was involved in metabolism.”
The team found further evidence of a link between augmentor-alpha and metabolism when they observed that fasting increased the expression of augmentor-alpha in these neurons.
“Fasting appeared to be a signal to make more of this protein,” says senior author Joseph Schlessinger, professor of pharmacology and co-director of the Yale Cancer Biology Institute.
The researchers then studied mice that lacked the protein altogether. Compared to typical mice, those without augmentor-alpha were thinner, whether they ate a normal or a high-fat diet. They were also more physically active than typical mice but did not eat significantly more food, which likely contributed to their thinness.
When faced with a lack of food, mice will typically conserve energy and reduce their physical activity, the researchers say. But during fasting, mice without augmentor-alpha were still very active, which suggests the protein is an important signal for energy conservation.
“From what we observed in this study, we think one of augmentor-alpha’s roles in the body is to slow down metabolism when there’s a lack of food,” says Schlessinger. “It’s like it is saying, ‘You don’t have food, don’t expend so much energy.'”
This link to metabolism suggests inhibiting or enhancing augmentor-alpha’s effect could be useful for a number of diseases, the researchers say. Drugs that inhibit augmentor-alpha—which certain cancer drugs that target ALK do—could be repurposed for metabolic disorders where excess weight can exacerbate disease.
And the enhancement of augmentor-alpha’s effect might offer a treatment option for people experiencing harmful weight loss, such as those with anorexia, cachexia, or persistent loss of appetite due to drug side effects or injury.
Recently, Yale researchers uncovered the structure of ALK and how it interacts with augmentor-alpha. Schlessinger says the new findings support and add to what they observed in this earlier research. He compared augmentor-alpha to insulin, which is produced in the pancreas but has effects throughout the body. Conversely, augmentor-alpha is produced in AgRP neurons in the hypothalamus and affects other nearby neurons.
“It acts very locally within the hypothalamus,” says Schlessinger.
And that, say the researchers, provides another clue about augmentor-alpha’s role. The hypothalamus controls many essential functions, including reproduction, temperature regulation, and stress response. Augmentor-alpha’s effect within the hypothalamus means it could be involved in some of these other processes as well, notes Horvath.
“I think we’re just scratching the surface of augmentor-alpha’s role,” Schlessinger says.
Source: Yale University