New findings
explain how UV rays trigger skin cancer
By Krishna Ramanujan, Cornell
University
Melanoma, a cancer of skin pigment cells called melanocytes, will strike an estimated 87,110 people in the U.S. in 2017, according to the Centers for Disease Control and Prevention.
A fraction of those melanomas come
from pre-existing moles, but the majority of them come from sources unknown –
until now.
Cornell researchers have discovered
that when melanocyte stem cells accumulate a sufficient number of genetic
mutations, they can become the cells where these cancers originate.
Under normal conditions, ultraviolet
(UV) radiation from the sun activates melanocytes to release melanin, a pigment
that protects the skin from the sun’s rays. But if melanocyte stem cells have
surpassed a threshold of genetic mutations, a tumor can start to grow when
those skin stem cells are activated by sun exposure.
“If you had mutations that were sufficient for melanoma, everything would be fine until you went out and got a sunburn,” said Andrew White, assistant professor of biomedical sciences at Cornell’s College of Veterinary Medicine, and senior author of a study published Oct. 12 in the journal Cell Stem Cell. Hyeongsun Moon, a postdoctoral researcher in White’s lab, is the paper’s lead author.
“The stimuli that would normally just give you a tanning response could in fact start a melanoma instead,” White said.
The researchers also may have
discovered a way to prevent melanomas caused by mutated stem cells.
A gene called Hgma2 was suspected to become expressed in the skin under UV radiation. When expressed, Hgma2 facilitates melanocyte stem cells to move from the base of skin hair follicles to the skin’s surface (the epidermis), where the cells release melanin.
Moon, White and colleagues used mice engineered with melanocyte stem cell mutations. One set of mice had the mutations, while another set with the mutations had the Hgma2 gene deleted. They then gave the mice a very low dose of UV radiation, just enough to trigger a tanning response. Mice with tumor-causing mutations and the Hgma2 gene intact developed melanomas, but the mice with mutations and the deleted gene remained healthy.
A gene called Hgma2 was suspected to become expressed in the skin under UV radiation. When expressed, Hgma2 facilitates melanocyte stem cells to move from the base of skin hair follicles to the skin’s surface (the epidermis), where the cells release melanin.
Moon, White and colleagues used mice engineered with melanocyte stem cell mutations. One set of mice had the mutations, while another set with the mutations had the Hgma2 gene deleted. They then gave the mice a very low dose of UV radiation, just enough to trigger a tanning response. Mice with tumor-causing mutations and the Hgma2 gene intact developed melanomas, but the mice with mutations and the deleted gene remained healthy.
More study is needed to better
understand the Hgma2 gene’s function.
“We have an actual mechanism, with
Hgma2, that can be explored in the future and could be a way we can prevent
melanomas from happening,” White said.
The study was supported by the
Office of the Assistant Secretary of Defense for Health Affairs through the
Peer Reviewed Cancer Research Program, the Cornell Center for Vertebrate
Genomics, the Cornell Stem Cell Program and the National Institutes of Health.
