Revolutionary CRISPR-based genome editing system treatment destroys cancer cells

Researchers at Tel Aviv University (TAU) have demonstrated that the CRISPR/Cas9 system is very effective in treating metastatic cancers, a significant step on the way to finding a cure for cancer. The researchers developed a novel lipid nanoparticle-based delivery system that specifically targets cancer cells and destroys them by genetic manipulation. The system, called CRISPR-LNPs, carries a genetic messenger (messenger RNA), which encodes for the CRISPR enzyme Cas9 that acts as molecular scissors that cut the cells’ DNA.

The revolutionary work was conducted in the laboratory of Prof. Dan Peer, VP for R&D and Head of the Laboratory of Precision Nanomedicine at the Shmunis School of Biomedicine and Cancer Research at TAU. The research was conducted by Dr. Daniel Rosenblum together with Ph.D. student Anna Gutkin and colleagues at Prof. Peer’s laboratory, in collaboration with Dr. Dinorah Friedmann-Morvinski from the School of Neurobiology, Biochemistry & Biophysics at TAU; Dr. Zvi R. Cohen, Director of the Neurosurgical Oncology Unit and Vice-Chair of the Department of Neurosurgery at the Sheba Medical Center; Dr. Mark A. Behlke, Chief Scientific Officer at IDT Inc. and his team; and Prof. Judy Lieberman of Boston Children’s Hospital and Harvard Medical School.

The results of the groundbreaking study, which was funded by ICRF (Israel Cancer Research Fund), were published in November 2020 in Science Advances.

“This is the first study in the world to prove that the CRISPR genome editing system can be used to treat cancer effectively in a living animal,” said Prof. Peer. “It must be emphasized that this is not chemotherapy. There are no side effects, and a cancer cell treated in this way will never become active again. The molecular scissors of Cas9 cut the cancer cell’s DNA, thereby neutralizing it and permanently preventing replication.”

To examine the feasibility of using the technology to treat cancer, Prof. Peer and his team chose two of the deadliest cancers: glioblastoma and metastatic ovarian cancer. Glioblastoma is the most aggressive type of brain cancer, with a life expectancy of 15 months after diagnosis and a five-year survival rate of only 3%. The researchers demonstrated that a single treatment with CRISPR-LNPs doubled the average life expectancy of mice with glioblastoma tumors, improving their overall survival rate by about 30%.

Ovarian cancer is a major cause of death among women and the most lethal cancer of the female reproductive system. Most patients are diagnosed at an advanced stage of the disease when metastases have already spread throughout the body. Despite progress in recent years, only a third of the patients survive this disease. Treatment with CRISPR-LNPs in a metastatic ovarian cancer mice model increased their overall survival rate by 80%.

“The CRISPR genome editing technology, capable of identifying and altering any genetic segment, has revolutionized our ability to disrupt, repair or even replace genes in a personalized manner,” said Prof. Peer. “Despite its extensive use in research, clinical implementation is still in its infancy because an effective delivery system is needed to safely and accurately deliver the CRISPR to its target cells. The delivery system we developed targets the DNA responsible for the cancer cells’ survival. This is an innovative treatment for aggressive cancers that have no effective treatments today.”

The researchers note that by demonstrating its potential in treating two aggressive cancers, the technology opens numerous new possibilities for treating other types of cancer as well as rare genetic diseases and chronic viral diseases such as AIDS.

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