Suppressor tRNA-based Biosensors for Detecting Analytes

Coupled in vitro transcription/translation based on wheat germ extract for efficient expression from PCR-generated templates in short-time batch reactions

We successfully constructed a coupled in vitro transcription/translation (cIVTT) system based on wheat germ extract (WGE) for efficient expression from PCR-generated DNA templates in short-time (∼3-h) batch reactions. The productivity of this system under optimized conditions was 85 μg (2.8 nmol) per 1 mL of reaction solution (corresponding to 425 μg per 1 mL of WGE), which was about 9-fold higher than that by the conventional batch method using mRNA as a template. The DNA template concentration required for efficient cIVTT was as low as 2.5 nM, which is much lower than those required for other eukaryotic cIVTT systems to maximize their productivity (30-50 nM). The productivity of the present system with a 2.5 nM template was 80-fold and 4-fold higher than that of a commercially available WGE-based cIVTT system with a 2.5 nM and a 40 nM template, respectively. In addition, the present system functioned well in a liposome (i.e., in an artificial cell) without a loss of productivity. Given that WGE-based systems have the advantage of being suitable for the expression of a broad range of proteins, the present cIVTT system is expected to be widely used in future cell-free synthetic biology.

Cell-free riboswitches

The emerging community of cell-free synthetic biology aspires to build complex biochemical and genetic systems with functions that mimic or even exceed those in living cells. To achieve such functions, cell-free systems must be able to sense and respond to the complex chemical signals within and outside the system. Cell-free riboswitches can detect chemical signals via RNA-ligand interaction and respond by regulating protein synthesis in cell-free protein synthesis systems. In this article, we review synthetic cell-free riboswitches that function in both prokaryotic and eukaryotic cell-free systems reported to date to provide a current perspective on the state of cell-free riboswitch technologies and their limitations.