Posted on by Dr. Francis Collins
Researchers continue to make progress with cancer immunotherapy, a type of treatment that harnesses the body’s own immune cells to attack cancer. But Kole Roybal wants to help move the field further ahead by engineering patients’ immune cells to detect an even broader range of cancers and then launch customized attacks against them.
With an eye toward developing the next generation of cell-based immunotherapies, this synthetic biologist at University of California, San Francisco, has already innovatively hacked into how certain cells communicate with each other. Now, he and his research team are using a 2018 NIH Director’s New Innovator Award to build upon that progress.
Roybal’s initial inspiration is CAR-T therapy, one of the most advanced immunotherapies to date. In CAR-T therapy, some of a cancer patient’s key immune cells, called T cells, are removed and engineered in a way that they begin to produce new surface proteins called chimeric antigen receptors (CARs). Those receptors allow the cells to recognize and attack cancer cells more effectively. After expanding the number of these engineered T cells in the lab, doctors infuse them back into patients to enhance their immune systems’s ability to seek-and-destroy their cancer.
As helpful as this approach has been for some people with leukemia, lymphoma, and certain other cancers, it has its limitations. For one, CAR-T therapy relies solely on a T cell’s natural activation program, which can be toxic to patients if the immune cells damage healthy tissues. In other patients, the response simply isn’t strong enough to eradicate a cancer.
Roybal realized that redirecting T cells to attack a broader range of cancers would take more than simply engineering the receptors to bind to cancer cells. It also would require sculpting novel immune cell responses once those receptors were triggered.
Roybal found a solution in a new class of lab-made receptors known as Synthetic Notch, or SynNotch, that he and his colleagues have been developing over the last several years [1, 2]. Notch protein receptors play an essential role in developmental pathways and cell-to-cell communication across a wide range of animal species. What Roybal and his colleagues found especially intriguing is the protein receptors’ mode of action is remarkably direct.
When a protein binds the Notch receptor, a portion of the receptor breaks off and heads for the cell nucleus, where it acts as a switch to turn on other genes. They realized that engineering a cancer patient’s immune cells with synthetic SynNotch receptors could offer extraordinary flexibility in customized sensing and response behaviors. What’s more, the receptors could be tailored to respond to a number of user-specified cues outside of a cell.
In his NIH-supported work, Roybal will devise various versions of SynNotch-engineered cells targeting solid tumors that have proven difficult to treat with current cell therapies. He reports that they are currently developing the tools to engineer cells to sense a broad spectrum of cancers, including melanoma, glioblastoma, and pancreatic cancer.
They’re also engineering cells equipped to respond to a tumor by producing a range of immune factors, including antibodies known to unleash the immune system against cancer. He says he’ll also work on adding engineered SynNotch molecules to other immune cell types, not just T cells.
Given the versatility of the approach, Roybal doesn’t plan to stop there. He’s also interested in regenerative medicine and in engineering therapeutic cells to treat autoimmune conditions. I’m looking forward to see just how far these and other next-gen cell therapies will take us.
 Engineering Customized Cell Sensing and Response Behaviors Using Synthetic Notch Receptors. Morsut L, Roybal KT, Xiong X, Gordley RM, Coyle SM, Thomson M, Lim WA. Cell. 2016 Feb 11;164(4):780-91.
 Engineering T Cells with Customized Therapeutic Response Programs Using Synthetic Notch Receptors. Roybal KT, Williams JZ, Morsut L, Rupp LJ, Kolinko I, Choe JH, Walker WJ, McNally KA, Lim WA. Cell. 2016 Oct 6;167(2):419-432.e16.
Car-T Cells: Engineering Patients’ Immune Cells to Treat Cancers (National Cancer Institute/NIH)
Synthetic Biology for Technology Development (National Institute of Biomedical Imaging and Bioengineering/NIH)
Roybal Lab (University of California, San Francisco)
Roybal Project Information (NIH RePORTER)
NIH Support: Common Fund; National Cancer Institute
Posted on by Dr. Francis Collins
There’s been tremendous excitement in the cancer community recently about the life-saving potential of immunotherapy. In this treatment strategy, a patient’s own immune system is enlisted to control and, in some cases, even cure the cancer. But despite many dramatic stories of response, immunotherapy doesn’t work for everyone. A major challenge has been figuring out how to identify with greater precision which patients are most likely to benefit from this new approach, and how to use that information to develop strategies to expand immunotherapy’s potential.
A couple of years ago, I wrote about early progress on this front, highlighting a small study in which NIH-funded researchers were able to predict which people with colorectal and other types of cancer would benefit from an immunotherapy drug called pembrolizumab (Keytruda®). The key seemed to be that tumors with defects affecting the “mismatch repair” pathway were more likely to benefit. Mismatch repair is involved in fixing small glitches that occur when DNA is copied during cell division. If a tumor is deficient in mismatch repair, it contains many more DNA mutations than other tumors—and, as it turns out, immunotherapy appears to be most effective against tumors with many mutations.
Now, I’m pleased to report more promising news from that clinical trial of pembrolizumab, which was expanded to include 86 adults with 12 different types of mismatch repair-deficient cancers that had been previously treated with at least one type of standard therapy . After a year of biweekly infusions, more than half of the patients had their tumors shrink by at least 30 percent—and, even better, 18 had their tumors completely disappear!