Harvard Stem Cell Institute, June 15, 2022
In a new study, researchers have discovered a method for using engineered donor stem cells to successfully treat glioblastoma in mice. The study revealed the presence of special “death receptors” on circulating tumor cells that could be targeted with proteins derived from healthy donor bone marrow cells. In the mouse study all animals treated with the gel encapsulated stem cell-based therapy lived significantly longer paving the way to future clinical testing.
Glioblastomas (GBMs) are highly aggressive cancerous tumors of the brain and spinal cord. Brain cancers like GBM are challenging to treat because many cancer therapeutics cannot pass through the blood-brain barrier, and more than 90 percent of GBM tumors return after being surgically removed, despite surgery and subsequent chemo- and radiation therapy being the most successful way to treat the disease. In a new study led by Khalid Shah, MS, PhD, principal faculty member of the Harvard Stem Cell Institute, scientists devised a novel therapeutic strategy for treating GBMs post-surgery by using stem cells taken from healthy donors engineered to attack GBM-specific tumor cells. This strategy demonstrated profound efficacy in preclinical models of GBM, with 100 percent of mice living over 90 days after treatment. Results are published in Nature Communications.
“This is the first study to our knowledge that identifies target receptors on tumor cells prior to initiating therapy, and using biodegradable, gel-encapsulated, ‘off-the-shelf’ engineered stem cell-based therapy after GBM tumor surgery,” said Shah, who is director of the Center for Stem Cell and Translational Immunotherapy at Brigham & Women’s Hospital, and professor at Harvard Medical School. “In the future, we will be applying this strategy to promptly identify target receptors after one receives a GBM diagnosis, then administer a gel-encapsulated, off-the-shelf, engineered stem cell therapeutic from a pre-made reservoir.”
Many cell-based therapies for cancer are derived from a patient’s own stem cells or immune cells. However, in a disease like GBM, most patients undergo surgery in the first week after receiving their diagnosis due to the disease’s rapid progression, granting little time to develop therapeutics from their own cell types. Instead, Shah and colleagues developed a novel approach to use allogeneic stem cells, or cells from healthy individuals, so that the remedy is readily available to administer immediately at the time of surgery. They evaluated the efficacy of several capsules that carry the stem-cell therapeutic in the brain and found a biodegradable hydrogel capsule that could successfully transport the treatment without being washed away by cerebrospinal fluid.
The team first identified special receptors coined “death receptors” on circulating tumor cells (CTC’s) — or cancer cells in the bloodstream — using a genetic biomarker commonly expressed on tumor cells. Once identified, they took stem cells from the bone marrow of healthy human donors and engineered the cells to release a protein that binds to the death receptors and initiates cell death. They also built a safety switch into the stem cell system that allows tracking stem cells by PET imaging and, when activated, eradicates stem cells and further enhances cancer cell death. Finally, Shah’s team assessed the efficacy of the therapeutic bifunctional cells (MSCBif) in animal models of primary and recurrent GBM tumors post-surgery.
Notably, all mice that received the gel encapsulated stem cell-based therapeutic after surgery were still alive 90 days post-treatment, compared to mice that solely underwent surgery, which exhibited a mean survival time of 55 days. Investigators additionally assessed the safety of this clinical treatment by conducting several studies using different doses of the MSC therapy on mice. They found no signs of toxicity among mice with or without tumors.
The study’s findings pave a pathway to clinical testing in phase I clinical trials in patients with GBM undergoing brain surgery within next two years. Shah and colleagues note that this therapeutic strategy will be applicable to a wider range of solid tumors and that further investigations of its applications are warranted.
“Beyond this therapy’s significant exhibited success rate, these findings suggest that we can use stem cells from healthy individuals to treat cancer patients,” said Shah. “This work lays down a foundation to begin building an engineered therapeutic stem cell biobank targeting different receptors on tumor cells and the immune cells in the tumor microenvironment that we will one day be able to use to treat a wide range of difficult-to-treat cancers like GBM.”
Source: Harvard Stem Cell Institute