Partnering with scientists at Harvard, a group of Brazilians affiliated with the Center for Research on Inflammatory Diseases (CRID), supported by FAPESP, described the mechanisms that cause hair color loss in extreme situations (image: Pixabay)

Scientific evidence found for role of stress in hair whitening
2020-01-23
PT ES

Partnering with scientists at Harvard, a group of Brazilians affiliated with the Center for Research on Inflammatory Diseases (CRID), supported by FAPESP, described the mechanisms that cause hair color loss in extreme situations.

Scientific evidence found for role of stress in hair whitening

Partnering with scientists at Harvard, a group of Brazilians affiliated with the Center for Research on Inflammatory Diseases (CRID), supported by FAPESP, described the mechanisms that cause hair color loss in extreme situations.

2020-01-23
PT ES

Partnering with scientists at Harvard, a group of Brazilians affiliated with the Center for Research on Inflammatory Diseases (CRID), supported by FAPESP, described the mechanisms that cause hair color loss in extreme situations (image: Pixabay)

 

By Karina Toledo  |  Agência FAPESP – People usually start gradually graying in their thirties. Once crossing the age of 50, one will be hard-pressed to successfully disguise one’s white hair crown without paying monthly visits to a hairdresser. 

However, medical reports suggest the process of hair color loss, which scientists call canities or achromotrichia, can be greatly accelerated by persistent acute stress or severe trauma. Some historians have speculated that Marie Antoinette’s hair turned white when she heard she was to be guillotined, at the height of the French Revolution (1793).

“For the longest time it’s been said that stress makes the hair turn white but until now there was no scientific basis for this belief. Our study proved that the phenomenon does indeed occur, and we identified the mechanisms involved. In addition, we discovered a way of interrupting the process of hair color loss due to stress,” said Thiago Mattar Cunha, a researcher affiliated with the Center for Research on Inflammatory Diseases (CRID), a Research, Innovation and Dissemination Center (RIDC) funded by FAPESP and hosted by the University of São Paulo’s Ribeirão Preto Medical School (FMRP-USP) in São Paulo State, Brazil. 

The study was conducted in partnership with a group led by Ya-Chieh Hsu, a professor of regenerative biology at Harvard University (USA). According to Cunha, the results, published January 22, 2020 in the journal Nature, were partly serendipitous.

“We were conducting a study on pain using black C57 mice, a dark-furred laboratory strain,” he said. “In this model, we administered a substance called resiniferatoxin to activate a receptor expressed by sensory nerve fibers and induce intense pain. Some four weeks after systemic injection of the toxin, a PhD student observed that the animals’ fur had turned completely white.”

The experiment was repeated several times until the CRID researchers concluded that the phenomenon was indeed due to the application of resiniferatoxin, a naturally occurring chemical found in resin spurge (Euphorbia resinifera), a cactus-like plant native to Morocco.

“We set out to check the hypothesis that the loss of fur color resulted from pain-induced stress,” Cunha said. “We designed a very simple experiment to see if the phenomenon was dependent on activation of sympathetic nerve fibers.”

He explained that the sympathetic nervous system is directly affected by stress. This division of the autonomic nervous system consists of nerves that branch from the spine and run throughout the body. It controls the organism’s “fight or flight” response to imminent danger, triggering the release of adrenaline and cortisol to make the heart beat faster, blood pressure rise, respiration accelerate and the pupils dilate, among other systemic effects. 

“After injecting resiniferatoxin into the mice, we treated them with guanethidine, an anti-hypertensive capable of inhibiting neurotransmission via sympathetic fibers. We observed that the process of fur color loss was blocked by the treatment,” Cunha said.

In another experiment, neurotransmission was interrupted by the surgical removal of sympathetic fibers. In this case, too, fur color was not lost in the weeks following pain induction.

“These and other experiments conducted by our group demonstrated the participation of sympathetic innervation in achromotrichia and confirmed that pain is a powerful stressor in this model. But it remained to detail the mechanisms involved,” Cunha noted.

Synchronicity

Cunha spent a period at Harvard as a visiting professor in 2018-19 with a scholarship from the joint program Harvard University holds with CAPES, the Brazilian Ministry of Education’s Office for Faculty Development. In conversations with colleagues, he heard that a local group had made similar discoveries to those of his group at the University of São Paulo, and that their findings were also partly accidental.

“Professor Ya-Chieh Hsu invited me to join a project in which the phenomenon was being investigated in more detail. She’s a leading researcher on processes that control skin stem cell differentiation,” Cunha told Agência FAPESP.

His group already knew by then that pain-related stress was somehow making the melanocyte stem cells in the hair follicle bulb “mature” too soon. These cells are responsible for yielding melanin-producing cells. Melanin is the pigment primarily responsible for skin and hair color. 

“In a young individual the cells are undifferentiated, like all stem cells, but with aging, they gradually differentiate. Once the process is complete they stop producing the melanocytes which produce melanin,” Cunha said. “We used various methodologies to show that intense sympathetic activity speeds up differentiation significantly. In our model, therefore, pain accelerated the aging of melanocyte stem cells.”

“When we started to study this, I expected that stress was bad for the body – but the detrimental impact of stress that we discovered was beyond what I imagined,” Hsu said. “After just a few days, all of the pigment-regenerating stem cells were lost. Once they’re gone, you can’t regenerate pigment anymore. The damage is permanent.”

“Acute stress, particularly the fight-or-flight response, has been traditionally viewed to be beneficial for an animal’s survival. But in this case, acute stress causes permanent depletion of stem cells,” said postdoctoral fellow Bing Zhang, the lead author of the study.

Other systems in the organism are probably affected by intense stress in a similar manner to the hair follicle bulb. “We don’t know for sure what the implications are,” Cunha said. “I’m currently working with other researchers on an investigation of the effects of sympathetic activity in other stem cell subpopulations.”

Altered gene expression

RNA sequencing was one of the methodologies used to explore the mechanisms that promote melanocyte stem cell differentiation. The researchers used this technology to compare the gene expression profiles of mice that received the injection of resiniferatoxin, developing pain, stress and fur color loss, with those of mice injected with a placebo.

“We looked for genes whose expression was most altered after stress induction, and one caught our attention: the gene that encodes a protein called CDK [cyclin-dependent kinase]. This is an enzyme that participates in cell cycle regulation,” Cunha said.

When the researchers repeated the pain induction procedure and treated the mice with a CDK inhibitor, they found that melanocyte stem cell differentiation was prevented, as was fur color loss.

“This finding shows that CDK participates in the process and could, therefore, be a therapeutic target,” Cunha said. “It’s too soon to know whether it will actually become a target someday in clinical practice, but it’s worth exploring further.”

In another experiment, the researchers demonstrated that when the sympathetic system is robustly activated, the fibers that innervate hair follicle bulbs release noradrenaline very near the melanocyte stem cells. 

“We showed that melanocyte stem cells express the protein ADRB2 [beta-2 adrenergic receptor], which is activated by noradrenaline, and we discovered that the stem cells differentiate when this receptor is activated by noradrenaline,” Cunha said.

To confirm the finding, the researchers repeated the experiment using mice that had been genetically modified so as not to express ADRB2. As suspected, their fur did not turn white after they were injected with resiniferatoxin.

“In another test, we injected noradrenaline directly into the skin of the mouse. As a result, the fur around the site of the injection turned white,” Cunha said.

Finally, the group treated a primary culture of human melanocytes (melanin-producing cells obtained directly from the skin of a volunteer) with noradrenaline, which as noted earlier is released by the sympathetic nerve fibers in hair follicles. The result was an increase in expression of CDK similar to that observed in mice.

According to Cunha, the researchers do not yet know if there will be future aesthetic applications for their findings, such as the development of a drug that prevents the hair color loss associated with aging. “It would be necessary to see if a CDK inhibitor has side-effects, and if so whether they would be outweighed by the aesthetic benefit,” he said.

The article “Hyperactivation of Sympathetic Nerves Drives Melanocyte Stem Cell Depletion. Nature” (DOI: 10.1038/s41586-020-1935-3) by Zhang, B. et al. can be retrieved from https://www.nature.com/articles/s41586-020-1935-3.

 

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