Health British Columbia

The Surprising Cellular Benefit of the Pigment Behind Red Hair

Orange pigment may help protect cells by turning excess cysteine into inert pigment. The same pigment that gives red hair and orange feathers their color may also help cells manage a chemical problem. Pheomelanin, an or…

The Surprising Cellular Benefit of the Pigment Behind Red Hair
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Orange pigment may help protect cells by turning excess cysteine into inert pigment. The same pigment that gives red hair and orange feathers their color may also help cells manage a chemical problem. Pheomelanin, an orange to red pigment found in human red hair, fair skin, and some bird feathers, is made using the amino [...]

Orange pigment may help protect cells by turning excess cysteine into inert pigment. The same pigment that gives red hair and orange feathers their color may also help cells manage a chemical problem. Pheomelanin, an orange to red pigment found in human red hair, fair skin, and some bird feathers, is made using the amino acid cysteine.

New research suggests that producing this pigment may help protect cells by drawing down excess cysteine before it contributes to cellular damage. Pheomelanin has long presented an evolutionary puzzle. Earlier studies have linked the pigment to a higher risk of melanoma, raising the question of why genetic variants that encourage pheomelanin production have persisted over time.

To investigate a possible benefit, Ismael Galván and colleagues studied 65 adult zebra finches divided into treatment and control groups. In the treatment group, male zebra finches were given dietary cysteine along with ML349, a drug that blocks pheomelanin synthesis. Pigment helps manage cysteine

The results suggest that pheomelanin production may help cells keep cysteine levels in balance. Male birds that received both cysteine and ML349 showed more serious oxidative damage in blood plasma than males that received cysteine alone, after the

Source and reference

authors accounted for the overall expression of the antioxidant regulator produced by melanocytes. The pattern was also seen in females, which do not produce pheomelanin. Female birds given cysteine alone tended to show more oxidative damage than female controls. According to the authors, pheomelanin synthesis may help maintain cysteine homeostasis by converting excess cysteine into inert pigment. That protective role could help explain why pheomelanin-promoting genetic variants remain in populations, even though they are also associated with increased melanoma risk. Reference: “MC1R depalmitoylation inhibition reveals a physiological role for pheomelanin” by Ismael Galván, Marina García-Guerra and Marta Araujo-Roque, 6 January 2026, PNAS Nexus. DOI: 10.1093/pnasnexus/pgaf391 This study received funding by Ministerio de Ciencia e Innovación (MCIN/AEI/10.13039/501100011033) grant...

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Published
Jul 12, 2026
Updated
Jul 12, 2026
Source
Scitechdaily
Category
Health
Read time
2 min
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SourceScitechdaily
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PublishedJul 12, 2026
UpdatedJul 12, 2026

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PublishedJul 12, 2026, 4:59 AMThis story was published by BC Post.
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Scitechdaily Published Jul 12, 2026 Imported Jul 12, 2026
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Scitechdaily Jul 12, 2026
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