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Synthetic essentiality: a novel approach for locating cancer therapy targets

6 Feb 2017
Synthetic essentiality: a novel approach for locating cancer therapy targets

A new method has been found for identifying therapeutic targets in cancers lacking specific key tumour suppressor genes.

The process, which located a genetic site for the most common form of prostate cancer, has potential for developing precision therapy for other cancers, such as breast, brain and colorectal, say researchers at The University of Texas MD Anderson Cancer Center.

Study results were published in the online issue of Nature.

By searching for gene deletion patterns in cancer through a concept the investigators call "synthetic essentiality," the team identified a synthetic essential gene known as chromatin helicase DNA-binding factor (CHD1) as a therapeutic target for prostate and breast cancers lacking a tumour suppressor gene called phosphatase and tensin homologue (PTEN).

Tumour suppressor genes are deleted in many cancers leading to tumour formation and growth.

"We searched for genes that are occasionally deleted in some cancers but which are retained in cancers caused by specific tumour suppressing genes, such as PTEN," said Di Zhao, Ph.D., Odyssey postdoctoral fellow in Cancer Biology and first author on the Nature paper. "We reasoned that this retained synthetic essential gene might be required for cancer-promoting actions when the cancers lose specific tumour suppressor genes."

Prostate cancer often occurs when it deletes PTEN, commonly associated with advanced prostate cancer.

The Centers for Disease Control cites prostate cancer as the second leading cause of cancer-related death for men in the U.S., with 176,000 new cases and 28,000 deaths reported annually.

Up to 70 percent of primary prostate tumours are PTEN-deficient.

Through analysing prostate cancer genome databases from The Cancer Genome Atlas and other sources, the research team found that CHD1, while occasionally deleted in some prostate cancers, was consistently retained in PTEN-deficient prostate cancer.

Further investigation uncovered CHD1's role as vital to PTEN signalling, and as a potential therapeutic target in prostate and breast cancers with PTEN gene loss.

"Identifying targets essential to cell survival in tumour suppressor genes has long been an investigational goal with the aim of offering cancer-specific vulnerabilities for targeted therapy," said Ronald DePinho, M.D., professor of Cancer Biology, MD Anderson president, and senior author for the Nature paper. "This study provided a conceptual framework for the discovery of 'traceable' targets in cancers harbouring specific tumour suppressor deficiencies."

DePinho added that further analyses are needed to verify additional synthetic essential genes in cancer cells that harbour specific genomic alterations as well as to identify potential regulatory interactions and cell-essential mechanisms.

Source: University of Texas M.D. Anderson Center