New biological tool can detect and debug faulty genetic circuits

New biological tool can detect and debug faulty genetic circuits

Biological toolkit will help researchers design new functions in mammalian cells Qi had previously developed Cas tools that could perform multiple tasks, such as switching desired genes on or off. In his latest work, with graduate student Hannah Kempton, he expanded on that concept to develop a CRISPR-Cas tool that performs these different tasks only in the presence of different combinations of biological signals. This is important because complex diseases like cancers can rarely be identified by a single genetic breakdown. More often, they result from a cascade of failures involving several genes - one may be switched on when it should be off, for instance, interfering with the proper operation of other genes. Kempton modified a particular Cas protein, Cas12, to enable it to detect multiple faulty signals and flip the right switches to help eliminate whatever chain of defects had caused the cell to malfunction. "Few works have demonstrated this much control in human cells," said Qi, whose lab has applied for a provisional patent on their Cas12 technology. "Sensing many signals at once means greater precision in identifying a disease state, and greater safety in administering a therapy. We see this kind of circuit control playing a bigger role in treatments in the future." The researchers believe that the applications for this technology extend beyond treating diseases like cancer. For example, rather than eliminating sick cells, the body may need to generate healthy new cells to replace irreparable ones. Our heart, bones, liver and other organs are all made up of specialized cell types that can be generated from stem cells. By programming the engineered Cas12 tool to trigger the right genetic circuits in these stem cells, clinical scientists could direct their rapid transformation into useful cells to repair damaged organs in response to injury. We've created a multi-tasking tool that can probe and control several genetic circuits at once." Hannah Kempton, graduate student Stanford School of Engineering Journal reference: Kempton, H.R., et al. (2020) Multiple Input Sensing and Signal Integration Using a Split Cas12a System. Molecular Cell . doi.org/10.1016/j.molcel.2020.01.016 .



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