6',6'-Difluoro-aristeromycin is a potent inhibitor of MERS-coronavirus replication

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic has highlighted the lack of treatments to combat infections with human or (potentially) zoonotic CoVs. Thus, it is critical to develop and evaluate antiviral compounds that either directly target CoV functions or modulate host functions involved in viral replication. Here, we demonstrate that low-micromolar concentrations of 6',6'-difluoro-aristeromycin (DFA), an adenosine nucleoside analogue, strongly inhibit the replication of Middle East respiratory syndrome coronavirus (MERS-CoV) in a cell-based infection assay. DFA was designed to target S-adenosylhomocysteine (SAH) hydrolase and, consequently, may affect intracellular levels of the methyl donor S-adenosylmethionine, which is used by two CoV methyltransferases involved in the capping of the 5 end of the viral mRNAs. Passaging of wild-type MERS-CoV in the presence of DFA selected a virus population with a [~]100-fold decreased DFA sensitivity, which carried various amino acid substitutions in viral nonstructural proteins (nsps). Specifically, mutations were present in the RNA polymerase subunit (nsp12) and in nsp13, the helicase subunit containing a nucleoside triphosphate hydrolase activity that has been implicated in CoV capping. We hypothesize that DFA directly or indirectly affects viral cap methylation, either by inhibiting the viral enzymes involved or by binding to SAH hydrolase. We also evaluated the antiviral activity of DFA against other betacoronaviruses, but found it to have limited impact on their replication, while being quite cytotoxic to the Calu-3 cells used for this comparison. Nevertheless, our results justify the further characterization of DFA derivatives as an inhibitor of MERS-CoV replication. ImportanceCurrently, there is a lack of antiviral drugs with proven efficacy against human CoV infections including the MERS-CoV that is endemic in the Middle East, the pandemic SARS-CoV-2 and potential future zoonotic CoV. This highlights the importance to investigate new drug targets and identify compounds that can be used to inhibit CoV replication. In this study, we characterize the inhibitory effect of DFA on MERS-CoV replication by phenotypic studies, time-of-addition studies, and the generation and genotyping of a DFA-resistant virus population. Our results revealed that DFA needs further improvement to reduce its cytotoxic side-effects and potentially enhance its broad-spectrum activity. Despite this observation, we think that DFA can be used to understand the function and metabolic interactions of the CoV RNA-synthesizing machinery, or as a starting point for the design of new compounds of the same class.