What happens when a cancer treatment stops working?
In many metastatic cancers, drugs that are initially effective lose their potency over time, as malignant cells acquire mutations that enable them to survive and spread. This is one of the most challenging moments in cancer treatments – but fortunately, there is cause for hope.
A recent study out of Prof. Yardena Samuels’s lab proposes a new way to confront cancer resistance: harnessing the very mutations that make tumors resistant in order to fight the cancer.
The study, published in Cancer Discovery, presents a new computational tool called SpotNeoMet, which systematically identifies therapy-resistance mutations common to many patients. These mutations lead to the production of protein fragments known as neo-antigens, which are unique to cancer cells and absent from healthy cells, allowing them to serve as recognition signals for the immune system.
As a test case, the team, led by Drs. Nofar Gumpert and Shira Sagie of Samuels’s lab, focused on metastatic prostate cancer, a disease in which most patients eventually develop resistance to existing therapies. In collaboration with Sheba Medical Center and Hadassah Medical Center in Israel, as well as medical centers and universities in North America and Europe, the researchers identified three neo-antigens that showed promising results in laboratory experiments and in mouse models of cancer.
These findings may pave the way for the development of new immunotherapies for prostate cancer, which remains one of the most common malignancies in men, with 1,466,680 new cases and 396,792 deaths in 2025.
“Our research demonstrates a broad principle that may change the way we think about treatment-resistant cancer,” Samuels says. “The same mutations that allow a tumor to evade a drug can, through precise immunotherapy, become the cancer’s weak point. Unlike ‘boutique’ immunotherapies that must be tailored to each individual patient, these therapies could be suitable for large groups of patients.”