Before we delve into the details of the study, itâ€™s worth explaining what gray hair signifies on a biological level.
Our hair is naturally white, but it is colored by a pigment called melanin, which is produced by cells called melanocytes.
These are positioned in hair follicles. As each hair grows, it is infused with melanin.
As we age, melanocytes slow down and slowly disappear, reducing the amount of pigment produced, leaving us with gray hair.
Why some people go gray at a relatively young age is down to genetic factors, at least in part, but why it happens after illness or stress is still unclear.
So, recently, researchers at the National Institutes of Health (NIH) and the University of Alabama in Birmingham found some clues in an unexpected place: the immune system. Interferons seemed particularly key.
Interferons and going gray
When the body is invaded by a pathogen, the innate immune system is the first responder. This arm of the immune system â€” also called the non-specific immune system â€” fights all-comers with a swift attack.
All cells have the ability to recognize invaders, and, when they do, they release interferons. These proteins inform other cells to take action, too, by increasing the activity of genes that block viral replication.
Interferons also activate other immune cells, such as natural killer cells and macrophages.
â€œGenomic tools,â€ she says, â€œallow us to assess how all of the genes within our genome change their expression under different conditions, and sometimes they change in ways that we donâ€™t anticipate. We are interested in genes that affect how our stem cells are maintained over time.â€
â€œWe like to study gray hair,â€ adds Harris, â€œbecause itâ€™s an easy read-out of melanocyte stem cell dysfunction.â€
The compound that joined the dots between gray hair and the immune system was transcription factor MITF, which is a protein that regulates much of the cellular activity within melanocytes.
The scientists found that MITF is vital for keeping melanocytesâ€™ interferon response under wraps. Without MITFâ€™s control of the response in melanocyte stem cells, the miceâ€™s hair turns gray.
Also, in mice predisposed to turning gray, if immune signaling is activated, gray hairs grow more rapidly.
The results might give us more information about why people turn gray early in life or following disease and stress. However, there are other, perhaps more important, applications:
â€œ[D]iscovering this connection will help us understand pigmentation diseases with innate immune system involvement, like vitiligo.â€
Vitiligo â€” characterized by the loss of pigmentation in patches of skin â€” affects 0.5â€“1 percent of people worldwide. The light regions of discoloration are due to a reduction in the number of melanocytes.
Although no one is too sure why melanocytes stop working, non-segmental vitiligo â€” the most common kind â€” is thought to be an autoimmune disease.
As is often the case in science, serendipity has led researchers down an unexpected and fascinating path. Only plenty more hours of research will see where that path leads.
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