Abstract
The extremely radiation resistant bacterium, Deinococcus radiodurans, is a microbe of importance, both, for studying stress tolerance mechanisms and as a chassis for industrial biotechnology. However, the molecular tools available for use in this organism continue to be limiting. In view of this, the CRISPR-Cas tools provide a large repertoire of applications for gene manipulation. We show the utility of the type I-E Cascade system for knocking down gene expression in this organism. A single-vector system was designed for expression of the Cascade components as well as the crRNA. The type I-E Cascade system was better tolerated than the type II-A Cas9 system in D. radiodurans. An assayable acid phosphatase gene, phoN integrated into the genome of this organism could be knocked down to 10% of its activity using the Cascade system. Cascade-based knockdown of ssb, a gene important for radiation resistance resulted in poor recovery post irradiation. Targeting the Radiation and Desiccation Resistance Motif (RDRM), upstream of the ssb, prevented de-repression of its expression upon radiation exposure. In addition to this, multi-locus targeting was demonstrated on the deinococcal genome, by knocking down both phoN and ssb expression simultaneously. The programmable CRISPRi tool developed in this study will facilitate study of essential genes, hypothetical genes, cis-elements involved in radiation response as well as enable metabolic engineering in this organism. Further the tool is amenable for implementing high-throughput approaches for such studies.
Competing Interest Statement
The authors have declared no competing interest.