Friday, July 3, 2026

Melanoma's secret to cheating death has finally been revealed

 

Scientists at the University of Pittsburgh School of Medicine have identified a crucial missing piece in the long standing mystery of how melanoma tumors avoid death and continue growing.

Writing this week in Science, Jonathan Alder, Ph.D., and colleagues describe a combination of genetic changes that allows melanoma cells to dramatically extend their lifespan while fueling rapid tumor growth. The discovery could reshape how researchers understand melanoma and may point to new treatment strategies.

"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 Help Control a Cell's Lifespan

Telomeres are protective caps located at the ends of chromosomes that help keep DNA from breaking down. Every time a healthy cell divides, its telomeres become a little shorter. Eventually, they shrink to the point where the cell can no longer divide.

Keeping telomeres at the proper length is critical for health. Telomeres that become too short can cause disorders linked to premature aging and early death. On the other hand, unusually long telomeres are often associated with cancer.

Scientists have long known that melanoma tumors contain exceptionally long telomeres, especially compared with many other types of cancer.

"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 Missing Genetic Link Behind Melanoma

The enzyme telomerase lengthens telomeres, helping protect chromosomes and preventing cells from dying. In most healthy cells, telomerase remains inactive. Many cancers, however, activate the enzyme through mutations in the telomerase gene known as TERT, allowing cancer cells to keep dividing.

Melanoma is particularly dependent on this strategy. Roughly 75% of melanoma tumors carry TERT mutations that increase telomerase production and activity.

Yet there was a mystery. Even after researchers introduced TERT mutations into melanocytes, they still could not recreate the unusually long telomeres found in melanoma tumors. That suggested another important factor was missing.

Pattra Chun-on, M.D., an internist pursuing her Ph.D. in Alder's lab, set out to uncover that missing link. Drawing on her background in cancer biology and growing interest in telomeres, she investigated why TERT mutations alone were not enough.

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."

TPP1 Completes the Puzzle

Earlier work from Alder's laboratory had identified frequent mutations in a telomere binding protein called TPP1 while analyzing cancer mutation databases.

Chun-on discovered that these TPP1 mutations closely resembled the TERT mutations. They occurred in the newly annotated promoter region of TPP1 and boosted production of the protein. That finding immediately caught Alder's attention because scientists had already shown that TPP1 enhances 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.

Chun-on, who is also enrolled in a Ph.D. program in the Department of Environmental and Occupational Health at Pitt's School of Public Health, then introduced the mutated forms of both TERT and TPP1 into cells. Working together, the two proteins produced the exceptionally long telomeres that characterize melanoma tumors.

The results revealed that TPP1 was the long sought missing factor, one that had been hidden in plain sight.

New Target for Future Melanoma Treatments

The findings offer a new explanation for how melanoma develops and survives. They also identify a cancer specific telomere maintenance system that could become a promising target for future therapies.

Additional authors of the study are Angela M. Hinchie, Agustin A. Gil Silva, Ph.D., Elizabeth Rush, Cindy Sander, Brittani K.N. Seynnaeve, M.D., M.S., John M. Kirkwood, M.D., all of Pitt, UPMC or both; Holly C. Beale, Ph.D., and Olena M. Vaske, Ph.D., both of the University of California, Santa Cruz; Carla J. Connelly, of Johns Hopkins University; and Carol W. Greider, Ph.D., of the University of California, Santa Cruz and Johns Hopkins University.

The research was supported by National Institutes of Health grants R35CA209974 and R01HL135062.

Journal Reference:

  1. 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, Jonathan K. Alder. TPP1 promoter mutations cooperate with TERT promoter mutations to lengthen telomeres in melanoma. Science, 2022; 378 (6620): 664 DOI: 10.1126/science.abq0607

Courtesy:

University of Pittsburgh. "Melanoma's secret to cheating death has finally been revealed." ScienceDaily. ScienceDaily, 30 June 2026. <www.sciencedaily.com/releases/2026/06/260625014833.htm>.  

 

 

Wednesday, June 24, 2026

Scientists finally crack an “undruggable” pancreatic cancer target and nearly double survival

 

For a long time, the likelihood of surviving pancreatic cancer has been extremely low. For patients who were diagnosed with metastatic pancreatic cancer between 2015 and 2021, about 97% died within five years of their diagnosis.

Pancreatic cancer is so deadly in part because there are no effective screening tests, and it rarely causes noticeable symptoms in its earliest stages. By the time a patient experiences signs, such as jaundice – a yellowing of the skin – or abdominal pain, the cancer has often already spread to other organs.

As a gastrointestinal oncologist and researcher specializing in early-phase clinical trials, I have seen the critical need for more effective therapies for patients with pancreatic cancer. For decades, successfully targeting the central mechanism that causes the vast majority of pancreatic cancers was considered impossible.

However, that narrative is rapidly changing with a new drug that can shut down the key protein that drives pancreatic cancer, nearly doubling survival rates for patients with advanced stages of the disease.

‘Undruggable’ tumors

The standard treatment for advanced pancreatic cancer has historically relied on chemotherapy, potent drugs designed to kill rapidly dividing cells. While chemotherapy can slow the progression of the disease, its effectiveness is often limited by the ability of pancreatic cancer cells to develop resistance against these drugs.

Pancreatic cancer’s success lies in its genetics. More than 90% of pancreatic tumors are driven by mutations in a gene called KRAS. This gene codes for proteins that function as switches that turn cell growth on and off. When the KRAS gene is mutated, the switch becomes permanently stuck in the “on” position, commanding cancer cells to multiply endlessly.

For decades, scientists considered KRAS to be “undruggable.” The surface of the protein is exceptionally smooth, lacking the molecular pockets that standard drugs require to bind to and turn the switch off.

Because existing drugs haven’t been able to target this protein, treatment for pancreatic cancer has primarily relied on toxic drugs that act more like blunt instruments than precise tools. Chemotherapy attempts to control the disease through widespread cell destruction, causing significant collateral damage to healthy tissues that lead to side effects.

What is daraxonrasib?

A new drug called daraxonrasib offers a critical advance in treating metastatic pancreatic cancer.

Daraxonrasib is taken daily by mouth. Instead of binding to KRAS directly, it attaches to a molecule called cyclophilin A in cells that helps fold proteins into their final 3D structures. This protein complex is then able to bind to the active KRAS protein and shut down its ability to signal cancer cells to multiply.

The company developing the drug, Revolution Medicines, presented results on May 31, 2026, from its Phase 3 clinical trial of 500 patients with metastatic pancreatic cancer who had received prior treatment. Compared to standard chemotherapy, daraxonrasib nearly doubled overall survival from 6.7 months to 13.2 months after diagnosis. Overall, daraxonrasib reduced the risk of death for metastatic pancreatic cancer patients by 60%.

The most common side effect is a prominent skin rash, which affected more than 86% of patients in the study. Patients also frequently dealt with stomatitis – painful swelling and sores inside the mouth – as well as diarrhea, nausea and vomiting. However, patients taking daraxonrasib were far less likely to stop treatment due to severe side effects compared to chemotherapy, and they had improved quality of life with reduced pain.

Next steps for daraxonrasib

By successfully targeting the specific genetic mutation that drives the vast majority of pancreatic cancers, researchers have demonstrated that this “undruggable” disease is treatable with targeted therapy.

The immediate next step is regulatory review of the drug’s readiness for the clinic. With data now officially published, Revolution Medicines will use these findings to seek formal approval from the Food and Drug Administration and other global regulatory bodies.

Because advanced pancreatic cancer is notoriously difficult to treat, breakthrough therapies that demonstrate this kind of significant survival benefit are often granted expedited or priority review. When daroxonrasib becomes available to patients will depend on the review timeline. Should the drug obtain approval, it could be available in clinics within months.

For the broader landscape of drug development, this milestone represents a likely shift in pancreatic cancer treatment. I expect more clinical trials exploring combination therapies pairing KRAS inhibitors with other drugs to prevent tumors from developing resistance to treatment.

Should daraxonrasib succeed, it could help set the stage for more precise, personalized and effective treatments for pancreatic cancer in the years to come.

Journal Reference:

  1. Eileen M. O’Reilly, Zev A. Wainberg, Andrew E. Hendifar, Mitesh J. Borad, Filippo Pietrantonio, Shubham Pant, Pascal Hammel, Chiara Cremolini, Gulam A. Manji, Paul E. Oberstein, Ignacio Garrido-Laguna, Christoph Springfeld, Nilofer S. Azad, Makoto Ueno, Stephen Y. Chui, Ying Zhang, Hina Patel, Yeonju Lee, Zeena Salman, Brian M. Wolpin. Daraxonrasib or Chemotherapy in Previously Treated Metastatic Pancreatic Cancer. New England Journal of Medicine, 2026; DOI: 10.1056/NEJMoa2605555

Courtesy:

The Conversation. "Scientists finally crack an “undruggable” pancreatic cancer target and nearly double survival." ScienceDaily. ScienceDaily, 4 June 2026. <www.sciencedaily.com/releases/2026/06/260604044247.htm>.The Conversation