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Power of cancer drugs may see boost by targeting newly ID’d pathway

Researchers discover previously unknown way cells protect their genomes during replication

by Tamara BhandariJanuary 24, 2023

Lingzhen Kong

Cells zealously protect the integrity of their genomes, because damage can lead to cancer or cell death. The genome — a cell’s complete set of DNA — is most vulnerable while it is being duplicated before a cell divides. Cancer cells constantly are dividing, so their genomes are constantly in jeopardy.

Researchers at Washington University School of Medicine in St. Louis have identified a previously unknown signaling pathway cells use to protect their DNA while it is being copied. The findings, published Jan. 24 in the journal Molecular Cell, suggest that targeting this pathway potentially could boost the potency of cancer therapeutics.

“A cell that can’t protect its genome is going to die,” said senior author Zhongsheng You, PhD, a professor of cell biology & physiology. “This entire pathway we found exists to protect the genome so the cell can survive in the face of replication stress. By combining inhibitors of this pathway with chemotherapy drugs that target the DNA replication process, we potentially could make such drugs more effective.”

Replication stress occurs when the cell’s DNA duplication machinery runs into problems copying the genome. Certain stretches of DNA are inherently difficult to copy, because they contain many repeated sequences. Factors that damage the DNA, such as radiation and toxic molecules, also cause replication stress, as does the activation of cancer-causing genes. Dozens of cancer drugs, including widely used medications such as cisplatin and doxorubicin, work by damaging the DNA and increasing replication stress.

You studies how cells protect their genomes while they are being duplicated. Early in his career, he worked on the ATR-Chk1 genome-protection pathway — a pathway that controls the cell-division cycle and prevents stalled replication machinery from failing entirely and causing breaks in the DNA. For the past eight years, he and his team painstakingly have been piecing together another previously unknown genome-protection pathway. With this new study, the final piece of the puzzle has clicked into place.

The process they discovered goes like this: When the DNA-duplicating machinery stalls, a protein called Exo1 that normally follows behind the machinery gets a little out of hand. Exo1’s job is to perform quality control by cutting out incorrectly copied pieces of DNA, but when the machinery stops moving forward, Exo1 starts snipping away haphazardly, cleaving off bits of DNA that then make their way out of the nucleus and into the main part of the cell. DNA is not found outside the nucleus under normal conditions, so its presence in the main part of the cell sets off an alarm. Upon encountering a fragment of DNA, a sensor molecule triggers a cascade of molecular events, including the release of the calcium ion from a cellular organelle known as the endoplasmic reticulum, which in turn shuts down Exo1, preventing it from dicing up the genome any further until the problem with the machinery can be fixed.

This newest study describes the discovery of DNA fragments as the warning signal that sets off the whole genome-protection response. The study was led by first author Shan Li, PhD, as a postdoctoral researcher and then a staff scientist in You’s lab. Li is now an assistant professor at Zhejiang University School of Medicine in Hangzhou, China. Co-author Lingzhen Kong, a graduate student, also made important contributions to the study.

Over the years, You and colleagues have identified eight protein factors involved in this genome-protection pathway. Most of them already have inhibitors under development that could be repurposed for cancer studies.

“Now that we have the pathway, we want to know whether it can be targeted for cancer treatment,” You said. “Lung, ovarian and breast cancer are intrinsically under replication stress. Other cancers are put under replication stress by chemotherapy drugs. This pathway protects cells from replication stress, so if we could block the pathway, it might improve patients’ response to cancer therapies.”

Several of the proteins in this pathway also play a role in other critical biological processes, including immunity, metabolism and autophagy, the process by which cells break down their own unwanted materials.

“One of the most exciting things about this pathway is how it intersects with so many other pathways,” You said. “I’ve been focusing on cancer, but much of this could also apply to autoimmune diseases. Two of the proteins we identified have been linked to chronic activation of the immune response and autoimmune disease. We want to understand the relationship between this replication-stress response pathway and the innate immune response pathway. The work we do is very basic, and it is so exciting to connect the dots between these fundamental processes and see how they relate to human health and disease.”

Li S, Kong L, Meng Y, Cheng C, Lemacon DS, Yang Z, Tan K, Cheruiyot A, Lu Z, You Z. Cytosolic DNA sensing by cGAS/STING promotes TRPV2-mediated Ca2+ release to protect stressed replication forks. Molecular Cell. Jan. 24, 2022. DOI: 10.1016/j.molcel.2022.12.034

This work was supported by the National Institutes of Health (NIH), grant number R01GM098535; the American Cancer Society, grant number RSG-13-212-01-DMC; Siteman Investment Program, grant number 5124; the Ministry of Science and Technology of China, grant number 2020YFA0803300; the National Natural Science Foundation of China, grant numbers 82030074 and 82272984; and the Zhejiang Natural Science Foundation-Key Project, grant number LD21H160003.

About Washington University School of Medicine

WashU Medicine is a global leader in academic medicine, including biomedical research, patient care and educational programs with 2,700 faculty. Its National Institutes of Health (NIH) research funding portfolio is the fourth largest among U.S. medical schools, has grown 54% in the last five years, and, together with institutional investment, WashU Medicine commits well over $1 billion annually to basic and clinical research innovation and training. Its faculty practice is consistently within the top five in the country, with more than 1,790 faculty physicians practicing at over 60 locations and who are also the medical staffs of Barnes-Jewish and St. Louis Children’s hospitals of BJC HealthCare. WashU Medicine has a storied history in MD/PhD training, recently dedicated $100 million to scholarships and curriculum renewal for its medical students, and is home to top-notch training programs in every medical subspecialty as well as physical therapy, occupational therapy, and audiology and communications sciences.

Tamara covers infectious diseases, molecular microbiology, neurology, neuroscience, surgery, the Institute for Informatics, the Division of Physician-Scientists and the MSTP program. She holds a double bachelor's degree in molecular biophysics & biochemistry and in sociology from Yale University, a master's in public health from the University of California, Berkeley, and a PhD in biomedical science from the University of California, San Diego. She joined WashU Medicine Marketing & Communications in 2016. She has received three Robert G. Fenley writing awards from the American Association of Medical Colleges: a bronze in 2020 for "Mind’s quality control center found in long-ignored brain area," a silver in 2022 for "Mice with hallucination-like behaviors reveal insight into psychotic illness," and a bronze in 2023 for "Race of people given Alzheimer’s blood tests may affect interpretation of results." Since January of 2024, Tamara has been writing under the name Tamara Schneider.