In vitro dissection revealed that the kinase domain of wheat RNA ligase is physically isolatable from the flanking domains as a non-overlapping domain enzyme

Cell-free protein synthesis for functional and structural studies

Recent advances in cell-free protein expression systems have made them reliable and practical for functional and structural studies of a wide variety of proteins. In particular, wheat germ cell-free translation can consistently produce target proteins in microgram quantities from relatively inexpensive, small-scale reactions. Here we describe our small-scale protein expression method for rapidly producing proteins for functional assay and techniques for determining if the target is suitable for scale-up to amounts potentially needed for structure determination. The cell-free system is versatile and can be easily customized with the inclusion of additives. We describe simple modifications used for producing membrane proteins.

Use of domain enzymes from wheat RNA ligase for in vitro preparation of RNA molecules

Wheat RNA ligase can be dissected into three isolated domain enzymes that are responsible for its core ligase, 5'-kinase, and 2',3'-cyclic phosphate 3'-phosphodiesterase activities, respectively. In the present study, we pursued a practical strategy using the domain enzymes for in vitro step-by-step ligation of RNA molecules. As a part of it, we demonstrated that a novel side reaction on 5'-tri/diphosphate RNAs is dependent on ATP, a 2'-phosphate-3'-hydroxyl end, and the ligase domain. Mass spectroscopy and RNA cleavage analyses strongly suggested that it is an adenylylation on the 5' terminus. The ligase domain enzyme showed a high productivity for any of the possible 16 combinations of terminal bases and a high selectivity for the 5'-phosphate and 2'-phosphate-3'-hydroxyl ends. Two RNA molecules having 5'-hydroxyl and 2',3'-cyclic monophosphate groups were ligated almost stoichiometrically after separate conversion of respective terminal phosphate states into reactive ones. As the product has the same terminal state as the starting material, the next rounds of ligation are also possible in principle. Thus, we propose a flexible method for in vitro RNA ligation.