For decades, oncologists have observed mutations that combine two genes, resulting in the creation of a hybrid protein that fuels cancer (fusion oncogenes and fusion oncoproteins). Targeting fusions using drugs has shown some success because cancer cells depend on the fusion proteins to thrive. However, this approach has been plagued with difficulties driven in part by a lack of understanding about how fusions work and the side effects of therapy.
“We’ve made something similar to the periodic table in chemistry for types of oncogenic fusions,” said senior and co-corresponding author Xiaotu Ma, Ph.D., St. Jude Department of Computational Biology. “By cataloguing the underlying mechanisms, we’ve given other scientists the ability to study fusions in better detail.”
“It is now well established that fusion oncoproteins drive many pediatric cancers,” said co-corresponding author Jeffery Klco, M.D., Ph.D., St. Jude Department of Pathology. “The Ma lab has comprehensively characterized the full spectrum of oncogenic fusions in childhood cancer, providing the community which a rich resource that can be mined to develop more predictive clinical tests while also suggesting potential therapeutic strategies for some tumor types. This will be a hugely impactful study.”
A proof-of principle that genome editing can cure oncogenic fusions
The problem for many cancers driven by oncogenic fusions is that they cannot be treated with existing drugs. This is typically because one or both normal proteins created by the hybridized genes are essential in healthy cells. Drugging the fusion protein therefore also harms healthy cells, causing major side effects.
But the new St. Jude tool lays a foundation for using genome editing to cure cancer. The mutations that cause fusion genes are only present in cancer cells. That means a highly specific genetic engineering tool, such as the CRISPR-Cas9 system, could selectively cut out the fusion gene in cancer cells – removing their ability to make the hybrid protein, leading to a cure.
“The fusion gene specific sequence only exists in cancer cells,” said first author Yanling Liu, Ph.D., St. Jude Department of Computational Biology. “It wouldn’t target any normal cells. We used CRISPR-Cas9 to perturb the fusion specific alleles in two cancer cell lines and killed them.”
“We were able to demonstrate the therapeutic potential of genome editing using CRISPR-Cas9 and in vitro cancer cell line models” said co-corresponding author Shondra Pruett-Miller, Ph.D., St. Jude Center for Advanced Genome Engineering director. “We believe this is just the tip of the iceberg in terms of how we might be able to harness the power of genome editing to target these oncofusions.”
Hope on the horizon for genome editing cures
Killing the cell lines provides a proof-of-principle for a genome editing cure for these cancers. It also showed the difficulties that lay ahead of such cures. The cell lines were derived from pediatric cancers that currently have a poor prognosis, even with treatment. One line was simply killed by the genome editing. However, the other cancer cell line unexpectedly compensated by using multiple splice variants. Splice variants are different sequences of RNA derived from the same DNA region. When the St. Jude scientists disrupted all splice variants of oncogenic fusion in the second cell line, they successfully killed the cancer cells.
Pre-emptively identifying splice variants is technically challenging and current genome editing technologies are not yet efficient enough to bring into the clinic for these diseases.
Predicting clinical outcomes and pushing research forward
Even with the challenges facing its use in therapy, the computational tool already predicts some clinical outcomes. The St. Jude authors were able to explain why a small group of pediatric patients with relapsed acute myeloid leukemia (AML) had poor outcomes. They found subtle differences in the oncogenic fusion mutations, which explained survival outcomes better than any existing clinical diagnostics. The result demonstrated that the tool can be used for clinical predictions, which will help physicians choose more personalized and effective treatments for patients in the future.
Authors and funding
The study’s other co-corresponding authors are Soheil Meshinchi, Fred Hutchinson Cancer Research Center and Patrick Brown, Johns Hopkins University. Additional authors are Jonathon Klein, Richa Bajpai, Li Dong, Quang Tran, Pandurang Kolekar, Liqing Tian, Heather Mulder, Jing Ma, Michael Walsh, Guangchun Song, Tamara Westover, Robert Autry, Alexander Gout, David Wheeler, Shibiao Wan, Gang Wu, Jun J. Yang, William Evans, John Easton and Jinghui Zhang of St. Jude; Jenny Smith and Rhonda Ries, Fred Hutchinson Cancer Research Center; Benjamin Huang, University of California San Francisco; Jim Wang, Children’s Oncology Group; Todd Alonzo, University of Southern California; Timothy Shaw, Moffitt Cancer Center; and Mignon Loh, Seattle Children’s Hospital.
The study was supported by grants from the National Cancer Institute (R01CA273326), the Fund for Innovation in Cancer Informatics, the National Institutes of Health Cancer Center Support Grant (P30CA021765) and ALSAC, the fundraising and awareness organization of St. Jude.
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St. Jude Children’s Research Hospital
St. Jude Children’s Research Hospital is leading the way the world understands, treats and cures childhood cancer, sickle cell disease and other life-threatening disorders. It is the only National Cancer Institute-designated Comprehensive Cancer Center devoted solely to children. Treatments developed at St. Jude have helped push the overall childhood cancer survival rate from 20% to 80% since the hospital opened more than 60 years ago. St. Jude shares the breakthroughs it makes to help doctors and researchers at local hospitals and cancer centers around the world improve the quality of treatment and care for even more children. To learn more, visit stjude.org, read St. Jude Progress blog, and follow St. Jude on social media at @stjuderesearch.