Scientists Find Surprising New Influence on Cancer Genes
A new study led by scientists at The Scripps Research Institute (TSRI) shows how pseudogenes—small stretches of DNA long thought to be non-coding junk DNA—can regulate the activity of the cancer-related gene called PTEN. The study also shows that pseudogenes can be targeted to control PTEN’s activity.
The team’s findings suggest a much larger role for pseudogenes than previously thought—a discovery that changes our understanding of the internal landscape of living cells, adding a new layer of complexity to an already crowded topography marked by multiple, overlapping, interacting gene networks.
Understanding how pseudogenes interact and control gene networks in the human body may lead to new ways of addressing diseases tied to problems that arise due to disruptions in these gene networks, said TSRI scientist Kevin Morris, PhD, who led the research in collaboration with scientists at the Karolinska Institute in Stockholm, Sweden, and The University of New South Wales in Sydney, Australia. “This has improved our knowledge of how genes in cancer are regulated and how we may now be able to control them,” Morris said in a press release.
Genes and Pseudogenes at Work
The results from the new study contradict that view by showing these bits of genetic material playing a profound role in controlling the activity of human genes. The control or loss of control of genes can make the difference between healthy and diseased tissue. In cancer, for instance, some genes become more active, while other genes that should normally shut down a cancerous growth become suppressed.
In the new work, Morris and his colleagues showed that pseudogenes can influence the activity of a human gene known as the phosphatase and tensin homolog (PTEN). PTEN has long been implicated in cancer and is categorized as a “tumor suppressor” gene, meaning that it has the ability to arrest the growth of a tumor. But in many forms of cancer, PTEN is shut down, allowing the tumor to grow unchecked.
Morris and his colleagues found that pseudogenes sharing sequences in common with PTEN can regulate the gene in two ways—knocking it down by suppressing the “promoter” for the PTEN gene, preventing the gene from being expressed, or soaking up PTEN-targeted regulatory micro-RNAs affecting the PTEN protein after the gene transcripts have been expressed.
Some companies are already looking at pseudogenes such as PTEN as targets of potential new drugs, Morris said, and the new work is a proof of principle that targeting pseudogenes can modulate the growth of cancer cells grown in the laboratory.
The same principle may be applicable to other diseases where the aberrant activity of a normal human gene is in play—or in infectious diseases, as a way of shutting down certain crucial genes belonging to viruses or bacteria. Morris noted, however, there are many practical issues with controlling pseudogenes. Designing a drug targeting pseudogenes directly would be difficult to administer with current technology, as these drugs would need to be delivered into the exact cells where they are needed without spreading to other, healthy tissues where they could be toxic.
The article appears in the February 24, 2013 issue of the journal Nature Structural & Molecular Biology.