Adoptive cell therapy is a promising cancer treatment that uses our immune system to eliminate cancer cells. These treatments, however, are only effective for a small subset of individuals with specific types of cancer and specific inherited genes. A recent breakthrough by Naoto Hirano, a professor in the Department of Immunology, paves the way for novel immunotherapies to help more patients, regardless of their genetic ancestry, live longer and healthier lives.
In a study published in Nature Biotechnology, Hirano and his collaborators developed a new technology that rigorously and robustly identifies the immune cells that are capable of recognizing and eliminating cancer cells. This technology allows researchers to develop new immunotherapies for cancer patients that are not limited by the differences – or heterogeneity – of tumour cells, thus expanding the potential impact of immunotherapy for patients around the world.
Hirano’s technology applies to an immunotherapy approach called T cell receptor (TCR) gene therapy that is based on genetically-engineered immune cells (T cells) recognizing and binding to specific molecules, called peptide-loaded human leukocyte antigens (HLA), on the surface of cancer cells. Although there has been progress in TCR therapy, there are more than 28,000 different variations of HLA found in humans and current TCR therapies only work for a few of these variations.
“Historically, TCR treatments have been developed for those who had the most common and well-studied HLA alleles, which often meant that these immunotherapies only worked for people from Caucasian ancestry,” says Hirano, who is also a senior scientist at the Princess Margaret Cancer Centre and Ontario Institute for Cancer Research clinician scientist. “It was an important goal for us to develop a technology that could work for a broad range of HLA alleles. We’re proud of what we developed because it could help many more cancer patients in the future.”
The technology presented in this study involves a methodology that can – in a single step at a low expense – form a functional protein structure, called a dimer, that is comprised of any peptide and HLA molecule, regardless of type, and can bind to and identify a variety of T cells. The method improves the binding affinity between T cells and HLA molecules nearly 200-fold relative to prior methods, which could allow researchers to better identify and engineer the T cells for novel immunotherapies.
The technology has been licensed to TCRyption Inc. for further development, translation, and large-scale implementation. In the future, it may be applied to fields other than cancer research and care, including autoimmune diseases such as rheumatoid arthritis and type 1 diabetes.
“I’m grateful for the cancer research community’s support over the years, which has enabled me to focus on important and challenging issues,” says Hirano, who was named the University Health Network’s Inventor of the Year last year for developing these analysis techniques. “Only with the support for rigorous experimentation, deep expertise, and innovative thinking, were we able to make this breakthrough.”
Learn more about the work behind this publication, or read more about Hirano.
Note: N.H. has received research funding from Takara Bio and served as a consultant for Takara. The University Health Network has filed a patent application related to this study on which N.H. is named as a lead inventor. N.H. is cofounder and has equity in TCRyption to which the technologies used in this study have been licensed.
This article was originally published by the Ontario Institute for Cancer Research.