Abstract
2'- O -ribose methylation of the first transcribed base (adenine or A (1) in SARS-CoV-2) of viral RNA mimics the host RNAs and subverts the innate immune response. How nsp16, with its obligate partner nsp10, assembles on the 5'-end of SARS-CoV-2 mRNA to methylate the A (1) has not been fully understood. We present a ∼ 2.4 Å crystal structure of the heterotetrameric complex formed by the cooperative assembly of two nsp16/nsp10 heterodimers with one 10-mer Cap-1 RNA (product) bound to each. An aromatic zipper-like motif in nsp16 and the N-terminal regions of nsp10 and nsp16 orchestrate an oligomeric assembly for efficient methylation. The front catalytic pocket of nsp16 stabilizes the upstream portion of the RNA while the downstream RNA remains unresolved, likely due to its flexibility. An inverted nsp16 dimer extends the positively charged surface area for longer RNA to influence the catalysis. Additionally, a non-specific nucleotide-binding pocket on the backside of nsp16 plays a critical role in catalysis, further contributing to its enzymatic activity.