PUBLIC RELEASE DATE: <\/p>\n
10-Mar-2014 <\/p>\n
Contact: David Ruth david@rice.edu<\/a> 713-348-6327 Rice University<\/p>\n In a significant advance for the growing field of synthetic biology, Rice University bioengineers have created a toolkit of genes and hardware that uses colored lights and engineered bacteria to bring both mathematical predictability and cut-and-paste simplicity to the world of genetic circuit design. <\/p>\n \"Life is controlled by DNA-based circuits, and these are similar to the circuits found in electronic devices like smartphones and computers,\" said Rice bioengineer Jeffrey Tabor, the lead researcher on the project. \"A major difference is that electrical engineers measure the signals flowing into and out of electronic circuits as voltage, whereas bioengineers measure genetic circuit signals as genes turning on and off.\" <\/p>\n In a new paper appearing online today in the journal Nature Methods, Tabor and colleagues, including graduate student and lead author Evan Olson, describe a new, ultra high-precision method for creating and measuring gene expression signals in bacteria by combining light-sensing proteins from photosynthetic algae with a simple array of red and green LED lights and standard fluorescent reporter genes. By varying the timing and intensity of the lights, the researchers were able to control exactly when and how much different genes were expressed. <\/p>\n \"Light provides us a powerful new method for reliably measuring genetic circuit activity,\" said Tabor, an assistant professor of bioengineering who also teaches in Rice's Ph.D. program in systems, synthetic and physical biology. \"Our work was inspired by the methods that are used to study electronic circuits. Electrical engineers have tools like oscilloscopes and function generators that allow them to measure how voltage signals flow through electrical circuits. Those measurements are essential for making multiple circuits work together properly, so that more complex devices can be built. We have used our light-based tools as a biological function generator and oscilloscope in order to similarly analyze genetic circuits.\" <\/p>\n Electronic circuits -- like those in computers, smartphones and other devices -- are made up of components like transistors, capacitors and diodes that are connected with wires. As information -- in the form of voltage -- flows through the circuit, the components act upon it. By putting the correct components in the correct order, engineers can build circuits that perform computations and carry out complex information processing. <\/p>\n Genetic circuits also process information. Their components are segments of DNA that control whether or not a gene is expressed. Gene expression is the process in which DNA is read and converted to produce a product -- such as a protein -- that serves a particular purpose in the cell. If a gene is not \"expressed,\" it is turned off, and its product is not produced. The bacteria used in Tabor's study have about 4,000 genes, while humans have about 20,000. The processes of life are coordinated by different combinations and timings of genes turning on and off. <\/p>\n Each component of a genetic circuit acts on the input it receives -- which may be one or more gene-expression products from other components -- and produces its own gene-expression product as an output. By linking the right genetic components together, synthetic biologists like Tabor and his students construct genetic circuits that program cells to carry out complex functions, such as counting, having memory, growing into tissues, or diagnosing the signatures of disease in the body. <\/p>\n <\/p>\n Original post: <\/p>\n Rice synthetic biologists shine light on genetic circuit analysis<\/a><\/p>\n","protected":false},"excerpt":{"rendered":" PUBLIC RELEASE DATE: 10-Mar-2014 Contact: David Ruth david@rice.edu<\/a> 713-348-6327 Rice University In a significant advance for the growing field of synthetic biology, Rice University bioengineers have created a toolkit of genes and hardware that uses colored lights and engineered bacteria to bring both mathematical predictability and cut-and-paste simplicity to the world of genetic circuit design. Continue reading