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Blocking tumor signals can hinder cancer’s spread

By Katherine Unger Baillie | Kbaillie@Upenn.Edu | 215-898-9194 Published: May 29, 2020
Studying the molecular players that foster cancer’s spread, a team of basic science researchers from Penn have identified a way to halt it. By inhibiting an enzyme, they successfully reduced the spread of lung metastases in a mouse model of melanoma, also significantly prolonging survival.
Studying the molecular players that foster cancer’s spread, a team of basic science researchers from Penn have identified a way to halt it. By inhibiting an enzyme, they successfully reduced the spread of lung metastases in a mouse model of melanoma,
also significantly prolonging survival.

For most people who die of cancer, the spread of the initial tumor is to blame. “Metastasis is what kills most cancer patients,” says Serge Fuchs, a professor in Penn’s School of Veterinary Medicine. “Yet there are not many, if any, drugs that specifically target metastatic processes.”

Dr. Serge Fuchs, Penn Vet
Dr. Serge Fuchs

In a paper in the journal Nature Cancer, Fuchs teamed with researchers from around campus and elsewhere to overcome that lack, studying the molecular players that foster cancer’s spread and identifying a strategy to stop it. Using an inhibitor of the enzyme known as p38α kinase (p38), they successfully reduced the spread of melanoma in a mouse model, significantly prolonging survival time.

“In my opinion, this kind of therapy could be used in conjunction with surgery to remove the primary tumor or perhaps other cancer treatments, such as chemotherapy,” says Fuchs. 

The study emerged from conversations and collaborations that have been ongoing for years among Penn groups, including those of Penn Vet’s Ellen Puré and the Perelman School of Medicine’s Constantinos KoumenisSandra Ryeom, and Ben Stanger, as well as the nearby Wistar Institute’s Dmitry Gabrilovich. All focus on different aspects of cancer biology. 

Many of these conversations revolved around what are known as tumor-derived factors (TDF): the various proteins, lipids, vesicles, genetic material, signaling molecules, and other compounds that tumors secrete and which, in some cases, travel around the body. Scientists believe many of these factors help “prepare the soil,” as it is often described, for the growth of metastases, making areas in the normal tissues more hospitable to tumor cells that are likewise traveling the body and disseminating to these areas. 

“We kept saying how the tumors and the factors are so different and their chemical nature is so different and their receptors are different and how they’re perceived by different types of normal cells,” Fuchs says. “But these areas in the lung that invite disseminated malignant cells and are conducive to their growth as metastases are, generally speaking, all alike.”

Aiming to focus on what united metastases, the researchers initially looked for elements that distinguished melanoma tumor cells that tended to be more metastatic from a melanoma cell line that was less so. When they introduced TDF from the more aggressive disease into normal mice, these animals developed premetastatic niches: areas conducive to the development of cancer metastases. Animals that received TDF from a less aggressive form of melanoma hardly developed these niches.

They also paid attention to the p38, as it is known to be activated in response to certain factors secreted by cancer cells. They observed that its activation correlated with metastasis, becoming more highly activated by the TDF from the highly metastatic melanoma and less activated by the less metastatic melanoma. 

To confirm that this enzyme was important in the metastatic process, the team tried two tactics: either eliminating the enzyme using genetic manipulation or blocking the effect of the kinase’s activity using an inhibitor that stopped the pathway it activates. 

“By doing either of these, we didn’t get a premetastatic niche,” says Fuchs.

To give their findings a clinical context, they looked at white blood cells from patients with melanoma. Those who did not have signs of metastasis had significantly lower p38 activation than those with a diagnosis of metastatic disease.

Next they examined the lungs of mice that were given the TDF from a metastatic cancer to learn more about what p38 was doing to cultivate the premetastatic niche. The team found that activation of p38 by TDF in lung fibroblasts, which are connective tissue cells, increased the fibroblasts’ activity and stimulated production of fibroblast activating protein (FAP), a molecule which Puré has long focused on and which has been shown to influence tumor growth and metastasis. Production of FAP then helped to recruit immune cells called neutrophils, which further acted on the premetastatic niche areas within lung tissue to augment their ability to trap and stimulate the growth of metastatic cells.

Hoping to prevent the formation of this niche and, ideally, metastasis, Fuchs and colleagues treated mice with two different inhibitors of p38, while also surgically removing their primary tumors. Both treatments suppressed the spread of cancer to the lung and prolonged the animals’ survival. 

One of the therapies they tested, ralimetinib, is an experimental cancer drug with somewhat lackluster performance at treating primary tumors. But initial trials have shown it to be relatively safe, suggesting that it could be a specialized component of the cancer-fighting arsenal, tamping down the primary tumor’s ability to spread.

Serge Y. Fuchs is professor of cell biology in the Department of Biomedical Sciences and director of the Mari Lowe Center for Comparative Oncology in the University of Pennsylvania School of Veterinary Medicine.

Fuchs’s coauthors were Penn Vet’s Jun Gui, Farima Zahedi, Angelica Ortiz, Christina Cho, Kanstantsin V. Katlinski, Leslie Todd, Hongru Zhang, Ellen Puré, and Daniel Beiting; Penn’s Perelman School of Medicine’s Jinyang Li, Ben Z. Stanger, Constantinos Koumenis, and Sandra W. Ryeom; the Wistar Institute’s Kevin Alicea-Torres and Dmitry I. Gabrilovich; the University of Pittsburgh’s Cindy Sander and John M. Kirkwood; the Princess Margaret Cancer Centre’s Bryan E. Snow, Andrew C. Wakeham, and Tak W. Mak; and Case Western Reserve University’s J. Alan Diehl.

The work was supported by the Pennsylvania Department of Health 2017 Health Research Formula Fund and the National Cancer Institute (grants CA216936, CA092900, CA229803, CA165997, CA206431, CA009140, and CA121973)

About Penn Vet

Ranked among the top ten veterinary schools worldwide, the University of Pennsylvania School of Veterinary Medicine (Penn Vet) is a global leader in veterinary education, research, and clinical care. Founded in 1884, Penn Vet is the first veterinary school developed in association with a medical school. The school is a proud member of the One Health initiative, linking human, animal, and environmental health.

Penn Vet serves a diverse population of animals at its two campuses, which include extensive diagnostic and research laboratories. Ryan Hospital in Philadelphia provides care for dogs, cats, and other domestic/companion animals, handling more than 34,600 patient visits a year. New Bolton Center, Penn Vet’s large-animal hospital on nearly 700 acres in rural Kennett Square, PA, cares for horses and livestock/farm animals. The hospital handles more than 6,200 patient visits a year, while our Field Services have gone out on more than 5,500 farm service calls, treating some 18,700 patients at local farms. In addition, New Bolton Center’s campus includes a swine center, working dairy, and poultry unit that provide valuable research for the agriculture industry.

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