Global surveillance of potential antiviral drug resistance in SARS-CoV-2: proof of concept focussing on the RNA-dependent RNA polymerase (preprint)

Antiviral treatments for COVID-19 have involved many repurposed drugs. Currently, SARS-CoV-2 RNA-dependent RNA polymerase (RdRp, encoded by nsp12-nsp7-nsp8) has been targeted by numerous inhibitors with debated clinical impact. Among these, remdesivir has been conditionally approved for the treatment of COVID-19 patients. Although the emergence of antiviral resistance, an indirect proxy for antiviral efficacy, poses a considerable healthcare threat, an evolutionary perspective on emerging resistant mutants is still lacking. Here we show that SARS-CoV-2 RdRp is under purifying selection, that potential escape mutations are rare, and unlikely to lead to viral fitness loss. In more than 56,000 viral genomes from 105 countries dating from December 2019 to July 2020 we found negative selective pressure affecting nsp12 (Tajimas D = -2.62), with potential antiviral escape mutations in only 0.3% of sequenced genomes. Those affected known key residues, such as Nsp12:Val473 and Nsp12:Arg555. Of the potential escape mutations found globally, in silico structural models show that this rarely implies loss of stability in RdRp. No potential escape mutation were found in our local cohort of remdesivir treated patients from the first wave (n=8). Our results indicate that RdRp is a suitable drug target, and that remdesivir does not seem to exert high selective pressure. Our study could be the starting point of a larger monitoring effort of drug resistance throughout the COVID-19 pandemic. We recommend the application of repetitive genome sequencing of SARS-CoV-2 from patients treated with antivirals to provide early insights into the evolution or antiviral resistance.

Determinants of SARS-CoV-2 transmission to guide vaccination strategy in a city (preprint)

Transmission chains within cities provide an important contribution to case burden and economic impact during the ongoing COVID-19 pandemic, and should be a major focus for preventive measures to achieve containment. Here, at very high spatio-temporal resolution, we analysed determinants of SARS-CoV-2 transmission in a medium-sized European city. We combined detailed epidemiological, mobility, and socioeconomic data-sets with whole genome sequencing during the first SARS-CoV-2 wave. Both phylogenetic clustering and compartmental modelling analysis were performed based on the dominating viral variant (B.1-C15324T; 60% of all cases). Here we show that transmissions on the city population level are driven by the socioeconomically weaker and highly mobile groups. Simulated vaccination scenarios showed that vaccination of a third of the population at 90% efficacy prioritising the latter groups would induce a stronger preventive effect compared to vaccinating exclusively senior population groups first. Our analysis accounts for both social interaction and mobility on the basis of molecularly related cases, thereby providing high confidence estimates of the underlying epidemic dynamics that may readily be translatable to other municipal areas.

SARS-CoV-2 phylogeny during the early outbreak in the Basel area, Switzerland: import and spread dominated by a single B.1 lineage variant (C15324T) (preprint)

Background: The first local case of SARS-CoV-2 in Basel, Switzerland, was detected on February 26th 2020. We present a phylogenetic cross-sectional study and explore viral introduction and evolution during the exponential early phase of the local COVID-19 outbreak from February 26th until March 23rd. Methods: We sequenced SARS-CoV-2 samples from naso-oropharyngeal swabs and generated 468 high quality genomes and called variants with our COVID-19 Genome Analysis Pipeline (COVGAP). We analysed viral genetic diversity using PANGOLIN taxonomic lineages. For identification of introduction and dissemination events across the Basel area a time-calibrated phylogeny was inferred including global SARS-CoV-2 genomes. Findings: Our samples exhibit low lineage diversity compared to neighbouring countries. Lineage B.1 (82.7%), detected from March 2nd, dominated infections in Basel. A large clade within B.1 contains 69.1% of our samples, all of which carry the SNP C15324T, suggesting local transmission in spreading events. We have located the geographic origin of this mutation in our tri-national region. The remaining genomes map broadly over the global phylogenetic tree, evidencing several events of introduction from and/or dissemination to other regions of the world. Further, we have identified several transmission events within families. Interpretation: Molecular surveillance of SARS-CoV-2 by phylogenetic reconstruction in the Basel area provides important insights into local transmission (spreading events and family transmission). This phylogenetic analysis enriches epidemiological and contact tracing data, allowing connection of seemingly unconnected events and drawing conclusions, which can be used to inform public health interventions. Funding: No dedicated funding was used for this work.