Plant-derived chemical bypasses healthy cells, hits cancer stem cells

Plant-derived chemical bypasses healthy cells, hits cancer stem cells
Credit: Shutterstock.com/ Plufflyman

A plant-derived chemical has been shown to slow head and neck cancer’s ability to make proteins that tell cancer cells to grow and spread.

The chemical bouvardin is derived from the firecracker bush (Bouvardia ternifolia) native to Mexico and the American Southwest. The lab of University of Colorado Cancer Centre and CU Boulder researcher, Tin Tin Su, and others have shown that this chemical can slow a cancer’s ability to make proteins that tell cancer cells to grow and spread.

A paper based on almost five years of work, published in Cancer Research, shows that SVC112 – a molecule based on bouvardin and synthesised by Su’s Colorado-based pharma start-up, SuivCa – acts specifically against head and neck cancer stem cells (CSCs), resulting in better tumour control with less toxicity to health cells than existing FDA-approved protein synthesis inhibitors.

The group hopes that these promising preclinical results will pave the way for human trials of SVC112 in head and neck cancer patients.

CSCs are a subpopulation of cancer cells that, like healthy stem cells, act as factories, manufacturing cells that make up the bulk of a cancer’s tissue. Unfortunately, CSCs often resist treatments like radiation and chemotherapy, and can survive to restart tumour growth once treatment ends.

“Many groups have linked the production of transcription factors to the survival and growth of cancer stem cells, but inhibitors have just been too toxic – they come with too many side effects. Definitely our studies suggest that this drug could be an advantage over existing drugs. It inhibits protein synthesis in a way that no other drug does and that’s why we’re excited,” says Su, who is also co-leader of the CU Cancer Centre Molecular and Cellular Oncology Program.

Importantly, the group’s work showed that SVC112 acts specifically against proteins like Myc and Sox2 needed by cancer stem cells, while leaving healthy cells relatively unharmed. They did this by comparing the effects of the drug in “matched pairs” of cancer cells and healthy cells grown from samples graciously donated by five head and neck cancer patients in Colorado.

For further comparison, the group did the same experiments with the FDA-approved protein synthesis inhibitor known as omacetaxine mepesuccinate (also called homoharringtonin, or HHT).

“Having cancer cells along with matched non-cancer cells from the same patient is pretty unique. When we tested these matched pairs with SVC112 and with HHT, what we saw is the approved drug eliminated both cancer and normal cells, whereas SVC112 had selectivity – it affected cancer cells but not healthy cells – so theoretically the effects on the normal tissue will be less,” Su says.

In fact, healthy cells were between 3.8 and 5.6 times less sensitive to SVC112 than were cancer cells (healthy cells and cancer cells were equally sensitive to the FDA-approved drug HHT).

The next step was using SVC112 to treat head and neck tumours grown in mouse models from samples of human tumours. Earlier work had shown that SVC112 sensitized previously radiation-resistant CSCs to radiation treatment, and so the group tested SVC112 and radiation alone and in combination.

“What we saw is that only when you decrease the population of cancer stem cells to under 1 percent of the total makeup of a tumour did the tumour shrink,” says paper co-senior author, Antonio Jimeno, Director of the Head and Neck Cancer Clinical Research Programme.

“It’s like cancer stem cells are in the control tower, directing the growth of the tumour. If you impair enough of these directors, other cancer cells don’t know what to do and cancer growth slows down or stops.”

Ongoing work continues in two major directions, with Su’s team continuing to propel the drug toward the clinic and Jimeno’s team working to understand of the basic biology driving the drug’s action, how to best combine it with other treatments such as radiation or immunotherapy, and its potential uses in other cancer types.

“This is the first report of the drug, from the drug’s chemical structure, its basic effects on commercial cell lines, to its mechanism of action with patient-derived cell lines and more complex action on CSCs, all the way to animal models from patient samples,” Jimeno says.

Early drug development undertaken outside the funding structure of established pharmaceutical sponsors often requires contributions from many sources, and the current project is no exception, receiving support from subcontracts to SuviCa’s Small Business Innovation Research (SBIR) award, a National Institutes of Health grant to the Su lab, pilot funding from the CU Cancer Centre, and philanthropy support from the Gates Centre and the CU School of Medicine.

Proposals are already underway to take the next important step – testing SVC112 in an early human clinical trial.