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Researchers at the MRC Weatherall Institute of Molecular Medicine have developed a new platform based on CRISPR/Cas9 technology, to alter the way human cells respond to external signals.

Cells are constantly monitoring the environment around them and are programmed to respond to molecular cues in their surroundings in distinct ways – some cues may prompt cells to grow, some lead to cell movement and others initiate cell death. For a cell to remain healthy, these responses must be finely balanced. It took evolution over two billion years to tune these responses and orchestrate their interplay in each and every human cell. But what if we could alter the way our cells respond to certain aspects of their environment? Or make them react to signals that wouldn’t normally provoke a reaction? New research published by scientists at the MRC WIMM takes cellular engineering to the next level in order to achieve just that.

In a paper published in Cell Reports, graduate student Toni Baeumler and Associate Professor Tudor Fulga (Radcliffe Department of Medicine) have used a derivative of the CRISPR/Cas9 technology to rewire the way cells respond to extracellular signals. CRISPR/Cas9 frequently makes the headlines as it allows medical researchers to accurately manipulate the human genome – opening up new possibilities for treating diseases. These studies often focus on correcting faulty genes in crops, livestock, mammalian embryos or cells in a dish. However, not all diseases are caused by a defined error in the DNA. In more complex disorders like diabetes and cancer, it may be necessary to completely rewire the way in which cells work.

Read more on the Oxford Science Blog.