Researchers at the prestigious Salk Institute are reporting that they have managed to map the molecular structure of a CRISPR enzyme that could allow scientists to more precisely manipulate functions within cells.
Over the past several years, CRISPR-Cas9 has seized the public imagination for its ability to edit genetic code in a way that may correct defects inside individual cells — potentially healing mutations and preventing the advent of many illnesses.
Specifically, Cas9 enzymes act sort of like scissors, snipping away pieces of genetic code and swapping them out with a replacement. But these enzymes target DNA, which is the fundamental building block for the development of an organism, and there are growing concerns that using the enzyme to essentially reprogram the DNA of a cell may cause more harm than good.
As this report in Scientific American illustrates:
Research published on Monday suggests that’s only the tip of a Titanic-sized iceberg: CRISPR-Cas9 can cause significantly greater genetic havoc than experts thought, the study concludes, perhaps enough to threaten the health of patients who would one day receive CRISPR-based therapy.
The results come hard on the heels of two studies that identified a related issue: Some CRISPR’d cells might be missing a key anti-cancer mechanism and therefore be able to initiate tumors.
The new findings from the Salk Institute, published in the journal Cell, provide the detailed molecular structure of CRISPR-Cas13d, an enzyme that can target RNA instead of DNA.
Once thought to just be the delivery mechanism for instructions encoded in DNA for cell operations, RNA is now known to carry out biochemical reactions like enzymes, and serve their own regulatory functions in cells. By identifying an enzyme that can target the mechanisms by which cells operate, rather than the overall plan for cellular function, scientists should be able to come up with even more highly refined treatments with fewer risks.
Put more simply, having editing tools can allow scientists to modify a gene’s activity without making permanent — and potentially dangerous — changes to the gene itself seems like a good option to explore.
“DNA is constant, but what’s always changing are the RNA messages that are copied from the DNA,” says Salk Research Associate Silvana Konermann, a Howard Hughes Medical Institute Hanna Gray Fellow and one of the study’s first authors, in a statement. “Being able to modulate those messages by directly controlling the RNA has important implications for influencing a cell’s fate.”
Researchers at Salk first identified the family of enzymes they’re calling CRISPR-Cas13d earlier this year and suggested that this alternate system could recognize and cut RNA. Their first work was around dementia treatment, and the team showed that the tool could be used to correct protein imbalances in cells of dementia patients.
“In our previous paper, we discovered a new CRISPR family that can be used to engineer RNA directly inside of human cells,” said Helmsley-Salk Fellow Patrick Hsu, who is the other corresponding author of the new work. “Now that we’ve been able to visualize the structure of Cas13d, we can see in more detail how the enzyme is guided to the RNA and how it is able to cut the RNA. These insights are allowing us to improve the system and make the process more effective, paving the way for new strategies to treat RNA-based diseases.”
The paper’s other authors were Nicholas J. Brideau and Peter Lotfy of Salk; Xuebing Wu of the Whitehead Institute for Biomedical Research; and Scott J. Novick, Timothy Strutzenberg and Patrick R. Griffin of The Scripps Research Institute, according to a statement.
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