Drug target identified for chemotherapy-resistant ovarian, breast cancer

Study finds mimic for BRCA genes that could be targeted to improve treatment

Researchers at Washington University School of Medicine in St. Louis may have found a path toward improving the effectiveness of chemotherapy in people with breast or ovarian cancer caused by defects in one of the BRCA genes. The researchers identified a pair of genes that operate in parallel to BRCA and may increase susceptibility to chemotherapy drugs. (Getty Images)

People who inherit a faulty copy of the so-called “breast cancer genes” BRCA1 and BRCA2 are at high risk of cancer. About 10 percent of breast cancer cases and 15 percent of ovarian cancers can be traced back to a flaw in one of these genes.

A class of drugs known as PARP inhibitors was designed to target tumors with defective BRCA genes. Sold under brand names such as Lynparza, Rubraca and Talzenna, the drugs offered new hope to people with ovarian or breast cancer. But in the five years since the first one was approved, PARP inhibitors haven’t lived up to their promise. Tumors typically shrink when first hit with a PARP inhibitor, but they soon become resistant, and the cancer returns.

Now, researchers may have found a path toward improving the effectiveness of chemotherapy in people with breast or ovarian cancer that is caused by BRCA defects. Researchers at Washington University School of Medicine in St. Louis identified a pair of genes that operate in parallel to BRCA. Knocking down the genes increases tumor cells’ susceptibility to a toxic chemical – and potentially to chemotherapy drugs as well.

“Women treated with PARP inhibitors typically go into remission relatively quickly, but a lot of these cancers then become resistant partly because there are other proteins in the cell that can compensate for the lack of BRCA,” said Andrea Byrum, a graduate student and the study’s co-first author. “If we target these other factors, we might be able to make the tumor sensitive to these drugs again.”

The findings are available online in the Journal of Cell Biology.

BRCA helps repair damaged DNA, fending off the errors that threaten to transform normal cells into cancer cells. When a person has a BRCA gene that isn’t working properly, his or her cells struggle to heal injuries to their DNA. PARP inhibitors knock out another arm of the cell’s DNA repair system. Together, a flawed BRCA gene and a PARP inhibitor leave tumor cells with a fatal inability to fix DNA damage, and the cells die.

But the DNA repair system is complex and redundant, and some tumor cells with nonfunctioning BRCA genes are able to effectively restore BRCA function by boosting another aspect of the system. That’s where this latest study comes in. The researchers found a way to make tumor cells that have BRCA act like they don’t so they can be more easily killed. Their findings point the way toward making resistant tumor cells susceptible to PARP inhibitors once again.

Nima Mosammaparast, MD, PhD, an assistant professor of pathology and immunology, Byrum, and colleagues found that a complex of the proteins TPX2 and Aurora A could mimic the effects of the BRCA proteins.

“If you lose this complex, it’s like you lose BRCA,” said Mosammaparast, the study’s senior author. “The nice thing is that there are inhibitors to Aurora A already in clinical trials for other types of cancer such as lymphoma and melanoma. We could combine an Aurora inhibitor and a PARP inhibitor to more effectively target these cancers. I am working on getting funding to do such a study.”

Moreover, the researchers found that cells needed both the complex and BRCA proteins to optimally protect their DNA as the cells are dividing. Co-senior author Alessandro Vindigni, PhD, and co-first author Denisse Carvajal-Maldonado, PhD, both of Saint Louis University, treated human cells with a DNA-damaging chemical and measured the lengths of replicating DNA strands. The strands were short if either the complex or BRCA was missing, and much shorter if both were, indicating that the cell was failing to protect its DNA.

“If you don’t have BRCA and you inhibit this complex, it could be potentially catastrophic for the tumor,” Mosammaparast said.

Defective BRCA genes raise the risk of not just breast and ovarian cancer, but prostate and pancreatic cancers as well. Finding a way to prevent resistance or restore sensitivity to PARP inhibitors could improve therapy options for many people.

“We weren’t looking for a drug when we started this study,” Mosammaparast said. “We were just asking a very basic question about how other genes regulate BRCA, and we stumbled across a potential drug target. My own personal take on it is that sometimes asking very basic questions leads you to discoveries that you weren’t even thinking about.”


Byrum AK, Carvajal‐Maldonado D, Mudge MC, Valle‐Garcia D, Majid MC, Patel R, Sowa ME, Gygi SP, Harper JW, Shi Y, Vindigni A, Mosammaparast N. Mitotic regulators TPX2 and Aurora A protect DNA forks during replication stress by counteracting 53BP1 function. Journal of Cell Biology. Feb. 3, 2019. DOI: 10.1083/jcb.201803003
This work was supported by the National Institutes of Health (NIH), grant numbers R01 CA118487, R01 GM108648, and R01 CA193318; Boston Children’s Hospital; Siteman Cancer Center; the Children’s Discovery Institute of St. Louis Children’s Hospital, grant number MC-II- 2015-453; and the Department of Defense, Breast Cancer Research Program Breakthrough Award number BC151728.
Washington University School of Medicine’s 1,500 faculty physicians also are the medical staff of Barnes-Jewish and St. Louis Children’s hospitals. The School of Medicine is a leader in medical research, teaching and patient care, ranking among the top 10 medical schools in the nation by U.S. News & World Report. Through its affiliations with Barnes-Jewish and St. Louis Children’s hospitals, the School of Medicine is linked to BJC HealthCare.

Originally published by the School of Medicine