Rise and Fall of SARS-CoV-2 Variants in Rotterdam: Comparison of Wastewater and Clinical Surveillance

Overview

Journal Sci Total Environ

Date 2023 Feb 16

PMID 36796689

Authors

Ray W Izquierdo-Lara

Leo Heijnen

Bas B Oude Munnink

Claudia M E Schapendonk

Goffe Elsinga

Jeroen Langeveld

Johan Post

Divyae K Prasad

Christian Carrizosa

Frederic Been

Janko van Beek

Remy Schilperoort

Rianne Vriend

Ewout Fanoy

Evelien I T de Schepper

Reina S Sikkema

Richard Molenkamp

Frank M Aarestrup

Gertjan Medema

Marion P G Koopmans

Miranda de Graaf

Affiliations

Soon will be listed here.

Abstract

Monitoring of SARS-CoV-2 in wastewater (WW) is a promising tool for epidemiological surveillance, correlating not only viral RNA levels with the infection dynamics within the population, but also to viral diversity. However, the complex mixture of viral lineages in WW samples makes tracking of specific variants or lineages circulating in the population a challenging task. We sequenced sewage samples of 9 WW-catchment areas within the city of Rotterdam, used specific signature mutations from individual SARS-CoV-2 lineages to estimate their relative abundances in WW and compared them against those observed in clinical genomic surveillance of infected individuals between September 2020 and December 2021. We showed that especially for dominant lineages, the median of the frequencies of signature mutations coincides with the occurrence of those lineages in Rotterdam's clinical genomic surveillance. This, along with digital droplet RT-PCR targeting signature mutations of specific variants of concern (VOCs), showed that several VOCs emerged, became dominant and were replaced by the next VOC in Rotterdam at different time points during the study. In addition, single nucleotide variant (SNV) analysis provided evidence that spatio-temporal clusters can also be discerned from WW samples. We were able to detect specific SNVs in sewage, including one resulting in the Q183H amino acid change in the Spike gene, that was not captured by clinical genomic surveillance. Our results highlight the potential use of WW samples for genomic surveillance, increasing the set of epidemiological tools to monitor SARS-CoV-2 diversity.

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