Abstract
Coronaviruses (CoVs) replicate unusually large RNA genomes that necessitate proofreading by the 3'-to-5' exoribonuclease (ExoN) formed by nonstructural proteins 14 (nsp14) and 10 (nsp10). Previous studies suggested that inactivation of the ExoN catalytic site in severe acute respiratory syndrome CoV 2 (SARS-CoV-2) is lethal, leaving unresolved whether the virus can tolerate impaired proofreading activity. Here, we investigated the functional requirement for ExoN in SARS-CoV-2 replication by combining a continuous fluorescence-based biochemical assay with an optimized single-bacmid reverse genetics system. Mutational analysis of residues involved in RNA binding or catalysis revealed graded effects on ExoN activity in vitro. Alanine substitution of Lys9, a residue positioned near the RNA-binding interface, did not reduce ExoN activity, whereas charge reversal at this position (K9E) impaired activity more strongly than alanine substitutions of the catalytic motif I residues D90 and E92 (D90A/E92A). Correspondingly, recombinant SARS-CoV-2 carrying K9A was readily recovered, whereas the D90A/E92A mutant was recovered only after an extended delay and K9E could not be rescued despite repeated attempts. The D90A/E92A mutant exhibited reduced replication while maintaining the engineered ExoN substitutions during serial passage. Deep sequencing of viral populations revealed a marked increase in genome-wide sequence variation in the D90A/E92A mutant, demonstrating a stable mutator phenotype. Together, these findings indicate that SARS-CoV-2 can tolerate substantial impairment of ExoN activity but depends on a minimal activity threshold for viability. This system provides a platform for defining how SARS-CoV-2 proofreading controls genome stability, viral fitness, and sensitivity to antiviral strategies that exploit reduced replication fidelity.