Isolation and characterization of novel temperate virus Aeropyrum globular virus 1 infecting hyperthermophilic archaeon Aeropyrum

Abstract

ABSTRACTWe isolate a novel archaeal temperate virus named Aeropyrum globular virus 1 (AGV1) from the host Aeropyrum culture. Reproduction of AGV1 was induced by adding 20 mM tris-acetate buffer to exponentially growing host cells. Negatively stained virions showed spherical morphology (60 ±2 nm in diameter) similar to Globuloviridae viruses. The double-stranded circular DNA genome of AGV1 contains 18,222 bp encoding 34 open-reading frames. No ORFs showed significant similarity with Globuloviridae viruses. AGV1 shares three genes, including an integrase gene, with reported spindle-shaped temperate viruses. However we couldn’t detect its integration site in the host genome. Moreover AGV1 seemed not to replicate autonomously because there are no origin recognition boxes in the genome. qPCR results showed that the genome copy number of AGV1 was lower than that of the host genome (10−3 copies per host genome). Upon the addition of tris-acetate buffer, a steep increase in the AGV1 genome copy number (9.5–26 copies per host genome at 2 days post-treatment) was observed although clustered regularly interspaced short palindromic repeat (CRISPR) elements of the host genome showed significant matches with AGV1 protospacers. Our findings suggest that AGV1 is a novel globular virus exhibiting an unstable carrier state in the growing host and in that way AGV1 can escape from the host defense system and propagate under stressful host conditions.ImportanceStudying archaeal viruses yields novel insights into the roles of virospheres and viruses in the evolutionary process of their hosts. Here, we isolated a novel spherical virus named Aeropyrum globular virus 1. AGV1 has integrase gene but its genome is not integrated into the host genome. AGV1 could not replicate autonomously due to the lack of origin recognition boxes and thus its copy number was too low (10−3 copies per host genome) without any inducing stimulus. However, upon the addition of tris-acetate buffer, the AGV1 genome copy number steeply increased instead of a perfect sequence match between the spacer of the host CRISPR/Cas system and the protospacer. Our findings suggest that AGV1 can escape from the host defense system and propagate under stressful conditions for the host by establishing an unstable carrier state. These results reveals a novel aspect of host–virus interactions in extreme environments.