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Protein Protects Anti-Cancer Gene from Chemical Shutdown


A protein that is largely absent in one type of skin cancer protects an important gene in a cell’s defense against harmful mutations from being silenced, researchers at The University of Texas M. D. Anderson Cancer Center report in the July 20 edition of Molecular Cell.

The protein IKKa, expressed at reduced levels in aggressive squamous cell carcinomas both in mice and humans, prevents a vital “checkpoint” gene from being chemically shut down, says Yinling Hu, Ph.D., senior author of the paper and assistant professor in M. D. Anderson’s Department of Carcinogenesis at the Science Park - Research Division in Smithville, Texas.

Expression of the checkpoint gene, called 14-3-3o, normally is triggered by the cancer-preventing gene p53 in response to DNA damage in the cell, Hu says. The protein expressed by the checkpoint gene helps to block a defective cell from dividing, allowing its genetic errors to be repaired rather than repeated in a new cell. Cells with damaged genes or genes that are behaving abnormally are the drivers of cancer.

“What we’ve identified is a mechanism that promotes genetic instability in keratinocytes, a critical type of skin cell that makes up 90% of epidermal cells, during the development of human skin cancers,” Hu says. They found that the absence or weak expression of IKKa leaves the checkpoint gene vulnerable to silencing.

In a series of experiments reported in the Molecular Cell paper, Hu and colleagues show how IKKa prevents silencing of the checkpoint gene by a chemical process known as methylation. Methyl groups, consisting of a carbon atom surrounded by three hydrogen atoms, attach to specific locations on a gene and prevent it from expressing its protein without altering the gene. The team restored the checkpoint gene’s activity by first restoring the expression of IKKa in deficient cells by infecting the cells with a virus designed to express IKKa.

“DNA methylation is largely responsible for shutting down the checkpoint gene expression in human cancer cells,” Hu says. “Our finding opens a new avenue for identifying new therapeutic targets for battling cancer. Although IKKa can protect the checkpoint gene 14-3-3 o from silencing, IKKa itself is frequently impaired in cancer cells. So we are going to define specific downstream targets of IKKa involved in regulating DNA methylation of the checkpoint gene. Those targets may be used to prevent silencing of the gene in cancer cells and so allow us to eliminate those cells.”

In addition to understanding a critical component in skin cancer, the team notes that other researchers have shown that the checkpoint gene 14-3-3o is silenced in a variety of other human epithelial cancers. Epithelial cells make up the outer layers of skin and the inner linings of many organs, including the lungs and the gastrointestinal, reproductive and urinary tracts.

The checkpoint gene had been known to be silenced by methylation, but the mechanism had not been understood. DNA methylation is known as an epigenetic process, because it affects a gene’s activity without changing or damaging the gene itself.

Hu’s research group has focused on IKKa, which is an important component of a molecular complex that regulates the development of the lymph and immune systems. Hu and colleagues earlier showed that IKKa is essential for embryonic skin development.

Co-authors with Hu are first author Feng Zhu, Ph.D., Xiaojun Xia, Ph.D., Bigang Liu, Jianjun Shen, Ph.D., and Yuhui Hu, all of M. D. Anderson’s Science Park - Research Division; and Maria Person, Ph.D., of the Division of Pharmacology and Toxicology, College of Pharmacy, The University of Texas at Austin.


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