Identification and functional-structural characterization of the enzymes linked with stable genome size increase of (+) RNA viruses

ABSTRACT

Nidovirales is an extraordinary order of complex positive-stranded RNA viruses including some of the largest RNA genomes (12-41 kb) among which notable human health burdens SARS-CoV-1, SARS-CoV-2, MERS-CoV, etc. Recent advance in genome sequencing is slowly filling the gaps between and beyond the classified nidoviral families. Still, the research is lagging behind to understand the evolution of RNA genomes. For example, how are these large genome RNA viruses able to bypass the length and stability constraints of an RNA molecule? Is there any link between increasing length and gaining a functional domain or a special structural feature? To answer these questions, we started with database mining to extract novel nidoviral genomes and annotated different domains in polyproteins of classified and unclassified nidoviruses using HHpred and HHblits tools (Zimmermann L, et al. 2018). We observed a significant variation across the order regarding presence/absence, fold/structure type, co-factor (or enhancer) presence/absence, presence of one motif or the other and genome location of enzymes Exonuclease (ExoN), N-7 Methyltransferase (MTase), 2'-O-MTase and RNA dependent RNA polymerase (RdRp). A trend seen with this bioinformatic analysis directly implies that stable RNA genome increase as well as maintenance is driven by the synergy of modifying enzymes MTases, RNA proofreading by ExoNs and fast & processive RdRps (Ferron F, et al. 2021). Next, after their identification, we are trying to characterize these large RNA genome genetic markers MTase(s) & ExoN, to have a comprehensive understanding of nidoviruses evolution. We have identified, expressed and purified a new nidoviral MTase from a Tobaniviridae family member, White Bream Virus (WBV). This enzyme is unique in terms of its location in ORF1a and not in ORF1b (Ferron F, et al. 2019). Functional and mutational studies show this new MTase to contain N-7 guanine specific, S-adenosyl-methionine (SAM) dependent capping activity (cap-0). Aligning with our predictions, structural characterization confirms that it has a Rossmann fold (RF) SAMdependent RNA-cap N7-guanine MTase. This study answers the missing link of capping activity in these members, which is somewhat only established for coronaviruses in this large genome order. Evaluating such enzymes is a step forward in the direction of fundamental understanding of how these RNA viruses are successfully expanding and maintaining their large genomes as well as coping up to fight against the host innate immunity.