“Genomic instability is an increased tendency for abnormal changes in DNA, like the addition of extra copies of chromosomes, DNA breaks and mutations,” said Ji-Hye Paik, Ph.D., assistant professor in the Department of Pathology and Laboratory Medicine at Weill Cornell Medical College in New York, N.Y. “Because these genetic abnormalities increase the chances for developing a tumor, it is fundamentally important to understand the molecular basis of genomic instability in cancer for prognosis and therapy.”
Telomeres are segments at the end of the chromosome that protect the chromosome from deterioration. As the length of the telomeres shortens, they activate cell death, mediated by the tumor suppressor gene, p53. This process is critical in the suppression of cancer, and dysfunctional telomeres can cause chromosomal abnormalities and cancer.
Using cells designed to be cancer-prone because of defective telomeres, Paik and colleagues demonstrated that p53 activates ZNF365 to maintain genomic stability. The researchers found that cells deficient in ZNF365 showed signs of incomplete doubling of DNA, causing abnormal cell division and unequally divided chromosomes. They concluded that because ZNF365 promotes the timely resolution of cell division, its loss led to an abnormal number of chromosomes called aneuploidy, which is implicated in many diseases including cancer.
“Our study is the first to demonstrate molecular mechanisms underlying the p53–ZNF365–telomere pathway and to show how alterations in this pathway may lead to increased cancer risk,” said Paik. “Understanding this pathway provides novel therapeutic opportunities for cancers.”
To understand the role of ZNF365 in cancer, Paik and colleagues used data available from The Cancer Genome Atlas (TCGA) and analyzed the expression of ZNF365 in 49 triple-negative breast cancers (TNBCs) — the most aggressive form of breast cancer — and 300 non-TNBCs. They found that expression of ZNF365 was lowest in TNBCs, and it remained high in non-TNBCs.
Using data from a larger cohort of 2,978 women from TCGA, the researchers also found that among women who had a 10-year, relapse-free survival, those with a high expression of ZNF365 had a 26 percent higher survival advantage. Further, when the researchers analyzed for the presence of ZNF365 in a tissue microarray containing 18 normal breast tissues, 141 TNBCs and 145 non-TNBCs, ZNF365 was present in normal breast tissues and non-TNBCs, but its expression declined in TNBCs.
According to Paik, this study is the first to determine the expression of ZNF365 in different types of breast cancers, and because it predicts disease prognosis, ZNF365 may be a potential biomarker for patient stratification.
About the American Association for Cancer Research
Founded in 1907, the American Association for Cancer Research (AACR) is the world’s first and largest professional organization dedicated to advancing cancer research and its mission to prevent and cure cancer. AACR membership includes more than 34,000 laboratory, translational and clinical researchers; population scientists; other health care professionals; and cancer advocates residing in more than 90 countries. The AACR marshals the full spectrum of expertise of the cancer community to accelerate progress in the prevention, biology, diagnosis and treatment of cancer by annually convening more than 20 conferences and educational workshops, the largest of which is the AACR Annual Meeting with more than 18,000 attendees. In addition, the AACR publishes eight peer-reviewed scientific journals and a magazine for cancer survivors, patients and their caregivers. The AACR funds meritorious research directly as well as in cooperation with numerous cancer organizations. As the scientific partner of Stand Up To Cancer, the AACR provides expert peer review, grants administration and scientific oversight of team science and individual grants in cancer research that have the potential for near-term patient benefit. The AACR actively communicates with legislators and policymakers about the value of cancer research and related biomedical science in saving lives from cancer. For more information about the AACR, visit www.AACR.org.