Melanoma is a type of skin cancer that develops in the cells (melanocytes) that produce pigment in the skin. It is a more aggressive form of skin cancer and can spread (metastasize) to other parts of the body if not detected and treated early.
A team of scientists from the University of Pittsburgh School of Medicine has found the missing puzzle piece in the mystery of how melanoma tumors control their mortality.
In a paper published in Science, they describe how they identified the specific genetic changes that allow tumors to grow rapidly while also preventing their own death. This discovery could have significant implications for the way melanoma is understood and treated by oncologists.
Jonathan Alder, Ph.D., assistant professor in the Division of Pulmonary, Allergy and Critical Care Medicine at the University of Pittsburgh School of Medicine. Credit: University of Pittsburgh
“We did something that was, in essence, obvious based on previous basic research and connected back to something that is happening in patients,” said Alder, assistant professor in the Division of Pulmonary, Allergy, and Critical Care Medicine at Pitt’s School of Medicine.
Telomeres, protective caps at the end of the chromosome, are required to prevent DNADNA, or deoxyribonucleic acid, is a molecule composed of two long strands of nucleotides that coil around each other to form a double helix. It is the hereditary material in humans and almost all other organisms that carries genetic instructions for development, functioning, growth, and reproduction. Nearly every cell in a person’s body has the same DNA. Most DNA is located in the cell nucleus (where it is called nuclear DNA), but a small amount of DNA can also be found in the mitochondria (where it is called mitochondrial DNA or mtDNA).” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>DNA from degrading. In healthy cells, telomeres become shorter with each cycle of replication until they become so short that the cell can no longer divide. Disruptions in maintenance of the length of the telomeres can lead to severe disease. Short telomere syndromes lead to premature aging and death, but extra-long telomeres are associated with cancer.
For years, scientists have observed strikingly long telomeres in melanoma tumors, especially in comparison with other cancer types.
“There’s some special link between melanoma and telomere maintenance,” said Alder. “For a melanocyte to transform into cancer, one of the biggest hurdles is to immortalize itself. Once it can do that, it’s well on its way to cancer.”
The telomerase protein is responsible for elongating telomeres, protecting them from damage, and preventing cell death. Telomerase is inactive in most cells, but many types of cancers use mutations in the telomerase gene, TERT, that activate this protein and allow cells to continue growing. Melanoma is particularly well-known for doing just this.
About 75% of melanoma tumors contain mutations in the TERT gene that stimulate protein production and increase telomerase activity. Yet, when scientists mutated TERT in melanocytes, they weren’t able to produce the same long telomeres seen in their patient’s tumors. It turned out that TERT promoter mutations were just half of the story.
With a background in cancer biology and a new interest in telomeres, Pattra Chun-on, M.D., an internist earning her Ph.D. in Alder’s lab, was determined to find the missing link between melanoma, TERT promoter mutations, and long telomeres.
Pattra Chun-On, M.D., a Ph.D. student at the University of Pittsburgh School of Public Health Department of Environmental and Occupational Health. Credit: Pattra Chun-On
“The fun part of this story is when Pattra joined my lab,” Alder said. “She contacted me and told me that she was interested in studying cancer. I told her that I study short telomeres and not long telomeres. This went on until I realized that Pattra would never take ‘no’ for an answer.”
While combing through cancer mutation databases, Alder’s lab team had previously discovered a region in a telomere-binding protein called TPP1, which was often mutated in melanoma tumors.
Chun-on’s determination in the lab shone when she found that the mutations in TPP1 were strikingly similar to those of TERT; they were located in the newly annotated promoter region of TPP1 and stimulated the production of the protein. This was exciting to Alder because TPP1 has long been known to stimulate telomerase activity.
“Biochemists more than a decade before us showed that TPP1 increases the activity of telomerase in a test tube, but we never knew that this actually happened clinically,” he said.
When Chun-on – who is also part of a Ph.D. program in the Department of Environmental and Occupational Health at Pitt’s School of Public Health – added mutated TERT and TPP1 back to cells, the two proteins synergized to create the distinctively long telomeres seen in melanoma tumors. TPP1 was the missing factor scientists had been searching for, and it was hiding in plain sight all along.
This discovery has changed the way scientists understand the onset of melanoma, but it also has the potential to improve treatment. By identifying a telomere maintenance system that is unique to cancer, scientists have a new target for treatments.
Reference: “TPP1 promoter mutations cooperate with TERT promoter mutations to lengthen telomeres in melanoma” by Pattra Chun-on, Angela M. Hinchie, Holly C. Beale, Agustin A Gil Silva, Elizabeth Rush, Cindy Sander, Carla J. Connelly, Brittani K.N. Seynnaeve, John M. Kirkwood, Olena M. Vaske, Carol W. Greider and Jonathan K. Alder, 10 November 2022, Science.
DOI: 10.1126/science.abq0607
The study was funded by the National Institutes of Health.
Source: SciTechDaily
