How a non-coding RNA encourages cancer growth and metastasis


Philip Howe Ph.D., the senior author on the Nature Cell Biology article, is chair of the Department of Biochemistry Molecular Biology at the Medical University of South Carolina (MUSC) and the Hans and Helen Koebig Endowed Chair in Oncology at the MUSC Hollings Cancer Center Credit: Medical University of South Carolina

A mechanism that pushes a certain gene to produce a non-coding form of RNA instead of its protein-coding alternative can promote the growth of cancer, report researchers at the Medical University of South Carolina (MUSC) in an article published online ahead of print on August 21, 2017 by Nature Cell Biology. The non-coding RNA soaks up a microRNA that prevents epithelial-to-mesenchymal transition, one of the key features of tumor development.

From one gene, cells can often produce different forms of RNA. The exact pre-RNA copy of one strand of DNA in a gene must be cut and assembled into its final RNA form, or several forms, in a process known as alternative splicing. Yet while these alternative forms of RNA can encode different proteins, scientists are discovering that many types of RNA do not, instead performing vastly different functions that regulate cell fate and behavior. MicroRNAs, for example, home in on certain protein-coding RNAs and help degrade them.

It is another class, called long non-coding RNAs (lncRNA), that are of particular interest to Philip H. Howe, Ph.D., chair of the Department of Biochemistry Molecular Biology, and the Hans and Helen Koebig Endowed Chair in Oncology at the MUSC Hollings Cancer Center. Howe and his team found that a pre-RNA for a protein called PNUTS can be alternatively spliced to form a lncRNA that contributes to cancer progression. The PNUTS lncRNA does not encode a protein, but rather soaks up like a sponge a certain microRNA that is usually tasked with preventing epithelial-to-mesenchymal transition, which is a key feature of tumor growth and metastasis.

Howe’s group connected a number of dots to explain how this happens. First, they found that breast cancer cells contained more PNUTS lncRNA than normal breast epithelial cells—a good initial sign that the non-coding RNA was associated with cancer development. Those cells were also more mesenchymal, meaning that they were more likely to form tumors.

They next examined a ribonucleoprotein called hnRNP E1, which binds to pre-RNA and suppresses alternative splicing. Importantly, they knew that TGF-beta, which is released in large amounts by tumor cells, could prevent its binding, potentially allowing alternate forms to be made. Computer models predicted that this ribonucleoprotein could bind to PNUTS pre-RNA on its alternative splicing site. In lung and breast cancer cell lines, specially designed RNA probes confirmed that this exact splicing site was more exposed when the ribonucleoprotein was knocked down and that those cells had more PNUTS lncRNA. When cells were exposed to TGF-beta over time, PNUTS lncRNA was made in increasing amounts. It turns out that the ribonucleoprotein was bound more tightly with the alternative splice site. In normal conditions, this allowed PNUTS protein to be made, but in tumors, the alternative splice site became exposed and more lncRNA was made instead.

Yet the group wanted to confirm exactly how PNUTS lncRNA could encourage tumor formation. Additional computer simulations predicted that, based on its sequence, there were seven potential locations on the PNUTS lncRNA for microRNA-205 to bind. This microRNA binds and destroys a transcriptional regulator called ZEB1 that encourages cells to unstick from one another and spread—a major step that allows epithelial-to-mesenchymal transition to occur. As predicted, without those potential binding locations, the lncRNA and the microRNA were unable to bind together. This helped cells stick together and spread less, even with TGF-beta added to push them to spread.

It appeared that PNUTS lncRNA was soaking up microRNA-205, which freed up ZEB1 to encourage cells to act more like tumors. To be sure that this was true, the group stuck fluorescent molecules to ZEB1 to track it and found that more of it was present when there were more PNUTS lncRNA.

As expected, preclinical models revealed that breast and lung tumors grew faster and larger when their cells contained more PNUTS lncRNA. By connecting all of the dots, Howe’s group had shown that one gene can make either a protein-coding RNA or a long non-coding RNA. With TGF-beta, the lncRNA soaked up microRNA-205 like a sponge, freeing up ZEB to drive epithelial-to-mesenchymal transition, a critical event in the development and spread of cancer.

This is the first study to show exactly how TGF-beta drives cancer through formation of a long non-coding RNA. Howe and his team are conducting experiments to find other such long non-coding RNAs that follow this same mechanism in cancer, with the goal of developing therapies to target them.

“My prediction is that this mechanism didn’t evolve to make just one long non-coding RNA,” says Howe. “There are probably others that are generated in this same fashion.”


Explore further:
Long non-coding RNA modulates colorectal cancer metabolism

More information:
A regulated PNUTS mRNA to lncRNA splice switch mediates EMT and tumour progression, Nature Cell Biology (2017). DOI: 10.1038/ncb3595

Journal reference:
Nature Cell Biology
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Medical University of South Carolina
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