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New pathway for lung cancer treatment

MIT researchers identify pyrimidine biosynthesis as a target for the treatment of small cell lung cancer.
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Small cell lung cancer (red) metastasizes to the liver in a genetically-engineered mouse model.
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Small cell lung cancer (red) metastasizes to the liver in a genetically-engineered mouse model.
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Image: Leanne Li

MIT cancer biologists have identified a new therapeutic target for small cell lung cancer, an especially aggressive form of lung cancer with limited options for treatment.

Lung cancer is the leading cause of cancer-associated mortality in the United States and worldwide, with a five-year survival rate of less than 20 percent. But of the two major sub-types of lung cancer, small cell and non-small cell, small cell is more aggressive and has a much poorer prognosis. Small cell lung cancer tumors grow quickly and metastasize early, resulting in a five-year survival rate of about 6 percent.

“Unfortunately, we haven’t seen the same kinds of new treatments for small cell lung cancer as we have for other lung tumors,” says Tyler Jacks, director of the Koch Institute for Integrative Cancer Research at MIT. “In fact, patients are treated today more or less the same way they were treated 40 or 50 years ago, so clearly there is a great need for the development of new treatments.”

A study appearing in the Nov. 6 issue of Science Translational Medicine shows that small cell lung cancer cells are especially reliant on the pyrimidine biosynthesis pathway and that an enzyme inhibitor called brequinar is effective against the disease in cell lines and mouse models.

Jacks is the senior author of this study. Other MIT researchers include Associate Professor of Biology and Koch Institute member Matthew Vander Heiden, and co-lead authors postdoc researcher Leanne Li and graduate student Sheng Rong Ng.

Roadblock for cell replication

Researchers in the Jacks lab used CRISPR to screen small cell lung cancer cell lines for genes that already have drugs targeting them, or that are likely to be druggable, in order to find therapeutic targets that can be tested more quickly and easily in a clinical setting.

The group found that small cell lung cancer tumors are particularly sensitive to the loss of a gene encoding dihydroorotate dehydrogenase (DHODH), a key enzyme in the de novo pyrimidine biosynthesis pathway. Upon discovering that the sensitivity involved a metabolic pathway, the researchers sought the collaboration of the Vander Heiden lab, experts in normal and cancer cell metabolism who were already conducting studies on the role of pyrimidine metabolism and DHODH inhibitors in other cancers.

Pyrimidine is one of the major building blocks of DNA and RNA. Unlike healthy cells, cancer cells are constantly dividing and need to synthesize new DNA and RNA to support the production of new cells. The investigators found that small cell lung cancer cells have an unexpected vulnerability: Despite their dependence on the availability of pyrimidine, this synthesis pathway is much less active in small cell lung cancer cells than in other types of cancer cells examined in the study. Through inhibiting DHODH, they found that small cell lung cancer cells were not able to produce enough pyrimidine to keep up with demand.

When researchers treated a genetically engineered mouse model of small cell lung cancer tumors with the DHODH inhibitor brequinar, tumor progression slowed down and the mice survived longer than untreated mice. Similar results were observed for small cell lung cancer tumors in the liver, a frequent site of metastasis in patients.

In addition to mouse model studies, the researchers tested four patient-derived small cell lung cancer tumor models and found that brequinar worked well for two of these models — one of which does not respond to the standard platinum-etoposide regimen for this disease.

“These findings are noteworthy because second-line treatment options are very limited for patients whose cancers no longer respond to the initial treatment, and we think that this could potentially represent a new option for these patients,” says Ng.

Shorter pathway to the clinic

Brequinar has already been approved for use in patients as an immunosuppressant, and there has been some preclinical research showing that brequinar and other DHODH inhibitors may be effective for other types of cancers.

“We’re excited because our findings could provide a new way to help small cell lung cancer patients in the future,” says Li. “While we still have a lot of work to do before brequinar can be tested in the clinic as a therapy for small cell lung cancer, we’re hopeful that this might happen more quickly now that we’re starting with a drug that is known to be safe in humans.”

Next steps for the researchers include optimizing the therapeutic efficacy of DHODH inhibitors and combining them with other currently available treatment options for small cell lung cancer, such as chemotherapy and immunotherapy. To help clinicians tailor treatments to individual patients, researchers will also work to identify biomarkers for tumors that are susceptible to this therapy, and investigate resistance mechanisms in tumors that do not respond to this treatment.

The research was funded, in part, by the MIT Center for Precision Cancer Medicine and the Ludwig Center for Molecular Oncology at MIT.

Press Mentions

NIH

Dr. Francis Collins, director of the NIH, highlights how MIT researchers have identified a metabolic pathway that appears to play a key role in small cell lung cancer. Collins notes that “the new findings show the promise of gene-editing technology as a research tool for uncovering elusive cancer targets.”

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