New research out of VCU Massey Comprehensive Cancer Centre provides promising evidence for an innovative combination treatment strategy that uses cells’ waste removal functions to effectively dismantle multiple myeloma.
The findings, published in Cell Death & Disease, show how an experimental targeted protein degrader, developed in-house at the cancer centre, enhances the destruction of a specific cancer cell survival protein and works in tandem with existing drugs in preclinical models, while showing limited toxicity in cardiac models.
“Treatment resistance remains a major challenge in multiple myeloma,” said study senior author Senthil K. Radhakrishnan, Ph.D., member of the Cancer Biology research programme at Massey and professor of pathology at the VCU School of Medicine.
“Our findings point to a new way of using the cancer cell’s own recycling machinery against it, with the goal of making existing treatments more effective.”
The research findings
The research team designed a molecule that uses autophagy to target and degrade an important survival protein—MCL1—on which many multiple myeloma cells depend.
The molecule is an autophagy-targeting chimaera, or AUTAC.
“We’re using the autophagy response and degrading this critical protein and killing the cancer cells,” Radhakrishnan said.
“MCL1 is usually broken down through the proteasome, but we’re forcing MCL1 to be degraded through autophagy.”
Targeted protein degradation is an up-and-coming treatment strategy.
Where many current targeted cancer drugs work by preventing the normal functions of different tumour-driving proteins, targeted protein degradation conversely aims to completely remove the proteins altogether.
When using their molecule in combination with a proteasome inhibitor, the research team observed enhanced activity in preclinical multiple myeloma models.
“After 48 hours, we saw a 50% reduction in multiple myeloma cell viability in preclinical models,” said study lead author Ahmed M. Elshazly, B.Pharm, M.Sc., a Ph.D. candidate in the Department of Pathology at the VCU School of Medicine.
“We confirmed that our drug, as a complete molecule, is able to induce cancer cell death.”
Cardiac safety has been an important concern in the development of therapies targeting MCL1.
In the cardiac models examined in this study, the AUTAC showed limited toxicity while retaining activity against cancer cells.
Additionally, the research team demonstrated that the treatment strategy effectively degraded MCL1 in non-small cell lung cancer.
What’s next?
For multiple myeloma, the research team plans to further optimise the molecule and evaluate improved candidates in additional preclinical studies.
Additionally, these findings could have implications for the development of treatment strategies for other tumours that depend on MCL1, including breast cancer, lung cancer and melanoma, among others.
“We are trying to increase the potency of this molecule using medicinal chemistry. This study is just proof of principle, so we want to continue to improve on it,” Radhakrishnan said.
Source: Virginia Commonwealth University
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