MIT scientists have developed a technique that could potentially be used one day to treat diseases of the brain, muscles, liver and kidneys by using CRISPR to edit RNA, writes Melissa Healy for The Los Angeles Times. Making edits to the chemical message of RNA, “doesn’t effect a permanent change in a cell’s architectural plan; rather, it essentially alters the implementation of that plan,” explains Healy.
Prof. Feng Zhang and his colleagues have created a CRISPR-based system that can edit RNA in human cells, reports Amy Dockser Marcus for The Wall Street Journal. “The new RNA-editing system, which the scientists have dubbed Repair, allows the editing of individual RNA letters, correcting a common mutation known to play a role in a number of diseases.”
Financial Times reporter Clive Cookson writes that Prof. Feng Zhang and his colleagues have engineered CRISPR so that it can edit single RNA letters in human cells. Cookson explains that the researchers believe that, “RNA editing offers a safer and more flexible way to make corrections than the permanent changes involved in DNA editing.”
Prof. Feng Zhang has been awarded the Lemelson-MIT Prize, reports Sharon Begley for STAT. Zhang was honored for his, “track record of innovations and of coming up with big ideas that change fields,” explains Prof. Michael Cima, faculty director of the award. “Zhang is one of those individuals who move through groups of talented people sparking new ideas.”
Prof. Feng Zhang has been honored as one of the recipients of this year’s Albany Medical Center Prize in Medicine and Biomedical Research for his work contributing to the development of the gene-editing tool CRISPR-Cas9, according to the AP. The AP notes that CRISPR-Cas9, “has sparked a boom in research over the past five years.”
The Economist writes about new research from Prof. Chris Voigt, in which “he and his colleagues demonstrate how to control customised cells with coloured light.”
TIME reporter Alice Park writes that MIT researchers have modified the CRISPR gene-editing system so that it could be used to diagnose disease. Park explains that the researchers, “used CRISPR to recognize specific substances that bacteria and viruses make. Picking up even the slightest whisper of these products can alert doctors that an infection is active.”
MIT researchers have developed a new technique that uses the CRISPR gene-editing system to diagnose diseases, reports Joel Achenbach for The Washington Post. Achenbach explains that the tool could potentially be used to “detect not only viral and bacterial diseases but also potentially for finding cancer-causing mutations.”
Straits Times reporter Nadia Chevroulet writes that researchers from MIT and the Singapore-MIT Alliance for Research and Technology (SMART) have uncovered how certain bacteria evade the body’s defenses. The findings could provide “new ways to counter tuberculosis, and possibly a new generation of drugs to battle antibiotic resistance.”
Boston Globe reporter Priyanka Dayal McCluskey writes that researchers from the Broad Institute and IBM are joining forces to examine why many cancer patients become resistant to drugs. The researchers hope this new effort could “help doctors prescribe more effective combinations of drugs for cancer patients.”
MIT researchers have developed a new system for protecting patient privacy in genomic databases, reports Anna Nowogrodzki for Nature. The system “masks the donor's identity by adding a small amount of noise, or random variation, to the results it returns on a user’s query,” Nowogrodzki explains.
MIT researchers have discovered that a bacterium found in the human mouth can be used to form a new CRISPR gene-editing system that can target RNA, reports Carl Zimmer for The New York Times. The development “may open up a new front in gene engineering, gaining the ability to precisely adjust the proteins in cells, for instance, or to target cancer cells."
New Scientist reporter Colin Barras writes that MIT researchers have found they can program C2c2, an enzyme found in bacteria, to serve as an RNA-editing tool. Barras writes that the tool “promises to transform our understanding of RNA’s role in our growth and development, and provide a new avenue for treating infectious diseases and cancer.”
Michael Le Page writes for New Scientist that MIT researchers have developed a technique that allows cells to log their activities using the CRISPR gene-editing system. Le Page explains that “such CRISPR-based logging could have a huge range of uses, from smart cells that monitor our health from within, to helping us understand exactly how our bodies develop.”
Huffington Post reporter Carolyn Gregoire writes that MIT spinoff Synlogic is working on reprogramming gut bacteria to act as a living therapeutic. “It’s become really clear that the bacteria living in us and on us affect our bodies in a variety of different ways — in ways that we never imagined,” explains Prof. Timothy Lu.