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Posted: Apr 23, 2015
Improving accuracy in genome editing
(Nanowerk News) Imagine a day when scientists are able to alter the DNA of organisms in the lab in the search for answers to a host of questions. Or imagine a day when doctors treat genetic disorders by administering drugs designed to alter a patient's genome.
It may sound like science fiction, but with the development of genome-editing proteins like Cas9 and CRISPR, it could one day become science fact.
Before that happens, however, scientists must overcome a number of challenges, including how to improve the specificity of these proteins- the rate at which genome-editing proteins modify the target DNA sequence, while ignoring similar, but off-target sequences.
It's a challenge Professor of Chemistry and Chemical Biology David Liu and colleagues have begun to unlock.
Led by Liu, a team of scientists has developed an engineered form of Cas9 that can be turned on with a small drug-like molecule. By using this activatable form of Cas9, the team could modify targets in the human genome with up to 25-fold higher specificity than when using the standard form of Cas9. The study is described in an April 6 paper in Nature Chemical Biology ("Small molecule–triggered Cas9 protein with improved genome-editing specificity").
"This study sought to improve the specificity of genome editing by carefully controlling when Cas9 is active. We engineered a form of Cas9 that is only active in the presence of a harmless, drug-like small molecule which we provide to the cell," Liu explained. "We showed it's possible to achieve efficient genome editing using this system, but because you can stop the production of active Cas9 by withholding the small molecule once it's had enough time to modify the target genes, you limit the opportunity for off-target genome modification."
Liu explained that his lab has taken two approaches to increasing the specificity of genome editing proteins.
The first, and most obvious, has been to engineer proteins that must recognize longer genetic sequences, making it more difficult for them to bind to off-target sites, or that require more perfectly matched DNA sequences before productively editing DNA. The second approach, Liu explained, is based on the understanding that genome editing proteins, unlike traditional biological tools and therapeutics, only need to be active for very limited times.
The idea to use a small molecule to control the activation of Cas9 grew out of the realization by Liu and colleagues, that genome editing - unlike virtually every other drug therapy or tool used in the lab - is not "steady-state" chemistry.
As an example of a steady-state process, Liu pointed to the way most diseases are treated. If someone is infected with a pathogen that needs to make a certain enzyme to reproduce, a conventionl treatment approach would be to administer a drug to interrupt that enzyme.
"What you're doing is pushing on an equilibrium," Liu said. "The bacteria is trying to make the enzyme, you're supplying a drug that's inhibiting the enzyme. If you stop supplying the drug, the enzyme could regain its activity, but if you keep supplying the drug, the bacteria will die off."
Genome-editing proteins, in contrast, are not tasked with perturbing a steady-state process.
"In human cells, there's only one or two molecules of substrate that you want to modify - the copy of the gene you got form your mother and one from your father" Liu said. "Once a genome-editing protein has processed the one or two target molecules, then the only things that genome-editing protein can do in the cell are bad things.
"Our approach arises from the simple appreciation that genome-editing is not a steady state process," he continued. "Therefore what we want to achieve is a short burst of genome editing activity sufficient to modify the one or two target copies of a gene, and then you want to get rid of the genome-editing activity and never allow it to return to the cell."
To achieve that short-burst of activity in Cas9, Liu and colleagues engineered a form of the protein that was only active in the presence of a small, drug-like molecule.
"Virtually all of the published genome-editing studies have used constructs that make lots of genome-editing agents, often without any necessary time limit - they can keep making genome-editing proteins for days or longer," Liu said. "With this system, we can pulse the cell with the small molecule to get the Cas9 to turn on for several hours, and then withhold it and the protein will naturally be degraded. Any new Cas9 proteins made after that pulse of the small molecule has passed will naturally be inactive."
With continued improvement, Liu expects tools like Cas9 and CRISPR will one day be so accurate that they fall below the rate of natural, spontaneous mutation.
"There are a certain number of mutations that occur in your genome everyday," Liu said. It's all about making sure the benefits of the technology outweigh the risks," he continued. "If we can lower the undesired genome modification rates to below the level of spontaneous mutations, then one can take comfort in knowing that a genome-editing agent delivered to a human patient does not significantly increase the risk of that patient developing cancer or other genetic diseases."
While efforts to improve the specificity of Cas9 and other genome-editing agents are important, Liu said he also supports the idea, recently described by Professor Jennifer Doudna of U. C. Berkeley and other scientists, of placing a moratorium on the use of such technology in humans until their risks are better understood, and their safety is evaluated.
"This is a new technology, and it's been widely recognized to be effective in virtually every cell type, including human cells," Liu said. "I think it's very wise to establish a dialog, preemptively, between scientists and other members of society to make sure the development and application of these tools is done thoughtfully."