Researchers led by Igor Stagljar at the Donnelly Centre for Cellular and Biomolecular Research used a new live cell-based method for identifying small molecules that target mutations in cancer cells.
Two leukemia drugs could be used against treatment-resistant lung cancer, with a clinical trial expected to launch in Toronto and Zagreb, Croatia, later this year to evaluate one of them. The journal Nature Chemical Biology published the findings. "Drug resistance is a big problem for lung cancer patients," says Stagljar. "Our new technology allows us to find molecules that could be used against cancers for which no other treatment options are available."
‘Gilteritinib and midostaurin, drugs approved for leukemia patients, hold promise in treating lung cancer patients with triple mutant epidermal growth factor receptor.’
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The researchers identified gilteritinib and midostaurin, two drugs already approved for patients with a particular form of leukemia, as potential treatments for lung cancer patients with triple mutant epidermal growth factor receptor (EGFR). The tumours in these patients are highly resistant to available therapy.Read More..
The Toronto team hopes to demonstrate the efficacy of these drugs in patient trials, with the gilteritinib trial to launch first. If it proves successful, gilteritinib could in a few years become a new standard of care treatment for an estimated 60,000 lung cancer patients worldwide who have triple mutant EGFR.
"We already have a sense of gilteritinib doses that are safe to give to humans," says Dr. Adrian Sacher, an oncologist at Toronto's Princess Margaret Cancer Centre, at University Health Network, who will lead the trial. "We only need to demonstrate efficacy and hopefully make them a novel treatment option for lung cancer patients that have developed resistance to current targeted therapies."
Lung cancer remains a leading cause of death from cancer in Canada and the world. Non-small cell lung cancer is the most common type of the disease with about one fifth of cases in North America caused by EGFR mutations.
EGFR is a cell surface receptor that regulates cell proliferation and belongs to a class of proteins known as receptor tyrosine kinases (RTKs). Oncogenic mutations make the receptor overactive, spurring on cell division.
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In a bid to stay one step ahead of the disease, scientists seek to identify drugs that can target the mutations that arise in response to treatment. Most methods are test tube based and focus on finding new kinase inhibitors, however. Consequently, promising drug candidates are often not suitable as therapeutics either because they don't penetrate the cells or because their effects are altered by other cellular factors.
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"The advantage of our method is that we are doing it in living cells, where we have all the other molecular machineries present that are important for signal transduction," says Stagljar. "Also, the compounds are fished at very low dose, which allows us to test for both permeability and toxicity at the same time."
Furthermore, MaMTH-DS allows identification of drug molecules which target not only the receptor's kinase activity, but also its interactions with other cellular proteins.
In a proof of principle study, the team looked for small molecules that can target the resistance-conferring C797S mutation in the triple mutant EGFR. A screen of almost 3,000 molecules revealed four promising compounds that had no effect on the normal receptor, meaning the drugs would be less likely to harm healthy cells.
In addition to midostaurin and gilteritinib, the latter of which will be tested in a pilot trial of about 20 lung cancer patients whose tumours harbor the C797S mutation, the study also revealed two more promising molecules.
One of these molecules, known as EMI1, acts on the mutant EGFR in a completely new way, not by inhibiting its kinase activity, but by targeting the receptor for degradation with the help of other molecular machineries. The researchers think that EMI1's more complex mechanism of action will make it more difficult for tumours to develop resistance to it.
Stagljar is working with Rima Al-awar, Head of Therapeutic Innovation and Drug Discovery, and her medicinal chemistry team at the Ontario Institute for Cancer Research (OICR), to create an improved version of the EMI1 molecule before its ability to shrink tumours can be evaluated in animal cancer models and eventually patients.
"The unbiased screening approach by the Stagljar's group has the merit of identifying small molecule inhibitors that could act via new mechanisms of action that would otherwise escape detection by conventional drug development strategies, as shown in this proof of principle study, " says Marino Zerial, Managing Director of the Max Planck Institute of Molecular Cell Biology and Genetics in Dresden, Germany and one of Stagljar's collaborators.
Source-Eurekalert