The influence of the copy number of invader on the fate of bacterial host cells in the antiviral defense by CRISPR-Cas10 DNases

Abstract

Type III CRISPR-Cas10 systems employ multiple immune activities to defend their hosts against invasion from mobile genetic elements (MGEs), including DNase and cyclic oligoadenylates (cOA) synthesis both of which are hosted by the type-specific protein Cas10. Extensive investigations conducted for the activation of Cas accessory proteins by cOAs have revealed their functions in the type III immunity, but the function of the Cas10 DNase in the same process remains elusive. Here, Lactobacillus delbrueckii subsp. Bulgaricus type III-A (Ld) Csm system, a type III CRISPR system that solely relies on its Cas10 DNase for providing immunity, was employed as a model to investigate the DNase function. Interference assay was conducted in Escherichia coli using two plasmids: pCas carrying the LdCsm system and pTarget producing target RNAs. The former functioned as a de facto “CRISPR host element” while the latter, mimicking an invading MGE. We found that, upon induction of immune responses, the fate of each genetic element was determined by their copy numbers: plasmid of a low copy number was selectively eliminated from the E. coli cells regardless whether it represents a de facto CRISPR host or an invader. Together, we reveal, for the first time, that the immune mechanisms of Cas10 DNases are of two folds: the DNase activity is capable of removing low-copy invaders from infected cells, but it also leads to abortive infection when the invader copy number is high.