2023
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An improved method for determining frequency of multiple variants of SARS-CoV-2 in wastewater using qPCR assays
Meghan Fuzzen,
Nathanael B.J. Harper,
Hadi A. Dhiyebi,
Nivetha Srikanthan,
Samina Hayat,
Leslie M. Bragg,
Shelley Peterson,
Minqing Ivy Yang,
Jianxian Sun,
Elizabeth A. Edwards,
John P. Giesy,
Chand S. Mangat,
Tyson E. Graber,
Robert Delatolla,
Mark R. Servos,
Meghan Fuzzen,
Nathanael B.J. Harper,
Hadi A. Dhiyebi,
Nivetha Srikanthan,
Samina Hayat,
Leslie M. Bragg,
Shelley Peterson,
Minqing Ivy Yang,
Jianxian Sun,
Elizabeth A. Edwards,
John P. Giesy,
Chand S. Mangat,
Tyson E. Graber,
Robert Delatolla,
Mark R. Servos
Science of The Total Environment, Volume 881
Wastewater-based surveillance has become an effective tool around the globe for indirect monitoring of COVID-19 in communities. Variants of Concern (VOCs) have been detected in wastewater by use of reverse transcription polymerase chain reaction (RT-PCR) or whole genome sequencing (WGS). Rapid, reliable RT-PCR assays continue to be needed to determine the relative frequencies of VOCs and sub-lineages in wastewater-based surveillance programs. The presence of multiple mutations in a single region of the N-gene allowed for the design of a single amplicon, multiple probe assay, that can distinguish among several VOCs in wastewater RNA extracts. This approach which multiplexes probes designed to target mutations associated with specific VOC's along with an intra-amplicon universal probe (non-mutated region) was validated in singleplex and multiplex. The prevalence of each mutation (i.e. VOC) is estimated by comparing the abundance of the targeted mutation with a non-mutated and highly conserved region within the same amplicon. This is advantageous for the accurate and rapid estimation of variant frequencies in wastewater. The N200 assay was applied to monitor frequencies of VOCs in wastewater extracts from several communities in Ontario, Canada in near real time from November 28, 2021 to January 4, 2022. This includes the period of the rapid replacement of the Delta variant with the introduction of the Omicron variant in these Ontario communities in early December 2021. The frequency estimates using this assay were highly reflective of clinical WGS estimates for the same communities. This style of qPCR assay, which simultaneously measures signal from a non-mutated comparator probe and multiple mutation-specific probes contained within a single qPCR amplicon, can be applied to future assay development for rapid and accurate estimations of variant frequencies.
DOI
bib
abs
An improved method for determining frequency of multiple variants of SARS-CoV-2 in wastewater using qPCR assays
Meghan Fuzzen,
Nathanael B.J. Harper,
Hadi A. Dhiyebi,
Nivetha Srikanthan,
Samina Hayat,
Leslie M. Bragg,
Shelley Peterson,
Minqing Ivy Yang,
Jianxian Sun,
Elizabeth A. Edwards,
John P. Giesy,
Chand S. Mangat,
Tyson E. Graber,
Robert Delatolla,
Mark R. Servos,
Meghan Fuzzen,
Nathanael B.J. Harper,
Hadi A. Dhiyebi,
Nivetha Srikanthan,
Samina Hayat,
Leslie M. Bragg,
Shelley Peterson,
Minqing Ivy Yang,
Jianxian Sun,
Elizabeth A. Edwards,
John P. Giesy,
Chand S. Mangat,
Tyson E. Graber,
Robert Delatolla,
Mark R. Servos
Science of The Total Environment, Volume 881
Wastewater-based surveillance has become an effective tool around the globe for indirect monitoring of COVID-19 in communities. Variants of Concern (VOCs) have been detected in wastewater by use of reverse transcription polymerase chain reaction (RT-PCR) or whole genome sequencing (WGS). Rapid, reliable RT-PCR assays continue to be needed to determine the relative frequencies of VOCs and sub-lineages in wastewater-based surveillance programs. The presence of multiple mutations in a single region of the N-gene allowed for the design of a single amplicon, multiple probe assay, that can distinguish among several VOCs in wastewater RNA extracts. This approach which multiplexes probes designed to target mutations associated with specific VOC's along with an intra-amplicon universal probe (non-mutated region) was validated in singleplex and multiplex. The prevalence of each mutation (i.e. VOC) is estimated by comparing the abundance of the targeted mutation with a non-mutated and highly conserved region within the same amplicon. This is advantageous for the accurate and rapid estimation of variant frequencies in wastewater. The N200 assay was applied to monitor frequencies of VOCs in wastewater extracts from several communities in Ontario, Canada in near real time from November 28, 2021 to January 4, 2022. This includes the period of the rapid replacement of the Delta variant with the introduction of the Omicron variant in these Ontario communities in early December 2021. The frequency estimates using this assay were highly reflective of clinical WGS estimates for the same communities. This style of qPCR assay, which simultaneously measures signal from a non-mutated comparator probe and multiple mutation-specific probes contained within a single qPCR amplicon, can be applied to future assay development for rapid and accurate estimations of variant frequencies.
2022
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Community Surveillance of Omicron in Ontario: Wastewater-based Epidemiology Comes of Age.
Authors presented in alphabetical order,
Eric J. Arts,
R. Stephen Brown,
David Bulir,
Trevor C. Charles,
Christopher T. DeGroot,
Robert Delatolla,
Jean‐Paul Desaulniers,
Elizabeth A. Edwards,
Meghan Fuzzen,
Kimberley Gilbride,
Jodi Gilchrist,
Lawrence Goodridge,
Tyson E. Graber,
Marc Habash,
Peter Jüni,
Andrea E. Kirkwood,
James Knockleby,
Christopher J. Kyle,
Chrystal Landgraff,
Chand S. Mangat,
Douglas G. Manuel,
R. Michael L. McKay,
Edgard M. Mejia,
Aleksandra Mloszewska,
Banu Örmeci,
Claire Oswald,
Sarah Jane Payne,
Hui Peng,
Shelley Peterson,
Art F. Y. Poon,
Mark R. Servos,
Denina Simmons,
Jianxian Sun,
Minqing Ivy Yang,
Gustavo Ybazeta
Abstract Wastewater-based surveillance of SARS-CoV-2 RNA has been implemented at building, neighbourhood, and city levels throughout the world. Implementation strategies and analysis methods differ, but they all aim to provide rapid and reliable information about community COVID-19 health states. A viable and sustainable SARS-CoV-2 surveillance network must not only provide reliable and timely information about COVID-19 trends, but also provide for scalability as well as accurate detection of known or unknown emerging variants. Emergence of the SARS-CoV-2 variant of concern Omicron in late Fall 2021 presented an excellent opportunity to benchmark individual and aggregated data outputs of the Ontario Wastewater Surveillance Initiative in Canada; this public health-integrated surveillance network monitors wastewaters from over 10 million people across major population centres of the province. We demonstrate that this coordinated approach provides excellent situational awareness, comparing favourably with traditional clinical surveillance measures. Thus, aggregated datasets compiled from multiple wastewater-based surveillance nodes can provide sufficient sensitivity (i.e., early indication of increasing and decreasing incidence of SARS-CoV-2) and specificity (i.e., allele frequency estimation of emerging variants) with which to make informed public health decisions at regional- and state-levels.
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Multiplex RT-qPCR assay (N200) to detect and estimate prevalence of multiple SARS-CoV-2 Variants of Concern in wastewater
Meghan Fuzzen,
Nathanael B.J. Harper,
Hadi A. Dhiyebi,
Nivetha Srikanthan,
Samina Hayat,
Shelley Peterson,
Minqing Ivy Yang,
Jianxian Sun,
Elizabeth A. Edwards,
John P. Giesy,
Chand S. Mangat,
Tyson E. Graber,
Robert Delatolla,
Mark R. Servos
Abstract Wastewater-based surveillance (WBS) has become an effective tool around the globe for indirect monitoring of COVID-19 in communities. Quantities of viral fragments of SARS-CoV-2 in wastewater are related to numbers of clinical cases of COVID-19 reported within the corresponding sewershed. Variants of Concern (VOCs) have been detected in wastewater by use of reverse transcription quantitative polymerase chain reaction (RT-qPCR) or sequencing. A multiplex RT-qPCR assay to detect and estimate the prevalence of multiple VOCs, including Omicron/Alpha, Beta, Gamma, and Delta, in wastewater RNA extracts was developed and validated. The probe-based multiplex assay, named “N200” focuses on amino acids 199-202, a region of the N gene that contains several mutations that are associated with variants of SARS- CoV-2 within a single amplicon. Each of the probes in the N200 assay are specific to the targeted mutations and worked equally well in single- and multi-plex modes. To estimate prevalence of each VOC, the abundance of the targeted mutation was compared with a non- mutated region within the same amplified region. The N200 assay was applied to monitor frequencies of VOCs in wastewater extracts from six sewersheds in Ontario, Canada collected between December 1, 2021, and January 4, 2022. Using the N200 assay, the replacement of the Delta variant along with the introduction and rapid dominance of the Omicron variant were monitored in near real-time, as they occurred nearly simultaneously at all six locations. The N200 assay is robust and efficient for wastewater surveillance can be adopted into VOC monitoring programs or replace more laborious assays currently being used to monitor SARS- CoV-2 and its VOCs.
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Wastewater to clinical case (WC) ratio of COVID-19 identifies insufficient clinical testing, onset of new variants of concern and population immunity in urban communities
Patrick M. D’Aoust,
Xin Tian,
Syeda Tasneem Towhid,
Amy Xiao,
Élisabeth Mercier,
Nada Hegazy,
Jianjun Jia,
Shen Wan,
Md Pervez Kabir,
Wanting Fang,
Meghan Fuzzen,
Maria E. Hasing,
Minqing Ivy Yang,
Jianxian Sun,
Julio Plaza‐Díaz,
Zhihao Zhang,
Aaron Cowan,
Walaa Eid,
Sean Stephenson,
Mark R. Servos,
Matthew J. Wade,
Alex MacKenzie,
Hui Peng,
Elizabeth A. Edwards,
Xiaoli Pang,
Eric J. Alm,
Tyson E. Graber,
Robert Delatolla
Science of The Total Environment, Volume 853
Clinical testing has been the cornerstone of public health monitoring and infection control efforts in communities throughout the COVID-19 pandemic. With the anticipated reduction of clinical testing as the disease moves into an endemic state, SARS-CoV-2 wastewater surveillance (WWS) will have greater value as an important diagnostic tool. An in-depth analysis and understanding of the metrics derived from WWS is required to interpret and utilize WWS-acquired data effectively (McClary-Gutierrez et al., 2021; O'Keeffe, 2021). In this study, the SARS-CoV-2 wastewater signal to clinical cases (WC) ratio was investigated across seven cities in Canada over periods ranging from 8 to 21 months. This work demonstrates that significant increases in the WC ratio occurred when clinical testing eligibility was modified to appointment-only testing, identifying a period of insufficient clinical testing (resulting in a reduction to testing access and a reduction in the number of daily tests) in these communities, despite increases in the wastewater signal. Furthermore, the WC ratio decreased significantly in 6 of the 7 studied locations, serving as a potential signal of the emergence of the Alpha variant of concern (VOC) in a relatively non-immunized community (40-60 % allelic proportion), while a more muted decrease in the WC ratio signaled the emergence of the Delta VOC in a relatively well-immunized community (40-60 % allelic proportion). Finally, a significant decrease in the WC ratio signaled the emergence of the Omicron VOC, likely because of the variant's greater effectiveness at evading immunity, leading to a significant number of new reported clinical cases, even when community immunity was high. The WC ratio, used as an additional monitoring metric, could complement clinical case counts and wastewater signals as individual metrics in its potential ability to identify important epidemiological occurrences, adding value to WWS as a diagnostic technology during the COVID-19 pandemic and likely for future pandemics.
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Metagenomics of Wastewater Influent from Wastewater Treatment Facilities across Ontario in the Era of Emerging SARS-CoV-2 Variants of Concern
Opeyemi U. Lawal,
Linkang Zhang,
Valeria R. Parreira,
R. Stephen Brown,
Charles Chettleburgh,
Nora Dannah,
Robert Delatolla,
Kimberly Gilbride,
Tyson E. Graber,
Golam Islam,
James Knockleby,
Sean Ma,
Hanlan McDougall,
R. Michael L. McKay,
Aleksandra Mloszewska,
Claire Oswald,
Mark R. Servos,
Megan Swinwood-Sky,
Gustavo Ybazeta,
Marc Habash,
Lawrence Goodridge
Microbiology Resource Announcements, Volume 11, Issue 7
We report metagenomic sequencing analyses of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) RNA in composite wastewater influent from 10 regions in Ontario, Canada, during the transition between Delta and Omicron variants of concern. The Delta and Omicron BA.1/BA.1.1 and BA.2-defining mutations occurring in various frequencies were reported in the consensus and subconsensus sequences of the composite samples.
2021
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Near real-time determination of B.1.1.7 in proportion to total SARS-CoV-2 viral load in wastewater using an allele-specific primer extension PCR strategy
Tyson E. Graber,
Élisabeth Mercier,
Kamya Bhatnagar,
Meghan Fuzzen,
Patrick M. D’Aoust,
Huy‐Dung Hoang,
Xin Tian,
Syeda Tasneem Towhid,
Julio Plaza Diaz,
Tommy Alain,
Ainslie J. Butler,
Lawrence Goodridge,
Mark R. Servos,
Robert Delatolla,
Tyson E. Graber,
Élisabeth Mercier,
Kamya Bhatnagar,
Meghan Fuzzen,
Patrick M. D’Aoust,
Huy‐Dung Hoang,
Xin Tian,
Syeda Tasneem Towhid,
Julio Plaza Diaz,
Tommy Alain,
Ainslie J. Butler,
Lawrence Goodridge,
Mark R. Servos,
Robert Delatolla
Abstract The coronavirus disease 2019 (COVID-19) pandemic caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has claimed millions of lives to date. Antigenic drift has resulted in viral variants with putatively greater transmissibility, virulence, or both. Early and near real-time detection of these variants of concern (VOC) and the ability to accurately follow their incidence and prevalence in communities is wanting. Wastewater-based epidemiology (WBE), which uses nucleic acid amplification tests to detect viral fragments, is a faithful proxy of COVID-19 incidence and prevalence, and thus offers the potential to monitor VOC viral load in a given population. Here, we describe and validate a primer extension PCR strategy targeting a signature mutation in the N gene of SARS-CoV-2. This allows quantification of the proportional expression of B.1.1.7 versus non-B.1.1.7 alleles in wastewater without the need to employ quantitative RT-PCR standard curves. We show that the wastewater B.1.1.7 profile correlates with its clinical counterpart and benefits from a near real-time and facile data collection and reporting pipeline. This assay can be quickly implemented within a current SARS-CoV-2 WBE framework with minimal cost; allowing early and contemporaneous estimates of B.1.1.7 community transmission prior to, or in lieu of, clinical screening and identification. Our study demonstrates that this strategy can provide public health units with an additional and much needed tool to rapidly triangulate VOC incidence/prevalence with high sensitivity and lineage specificity.
DOI
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Near real-time determination of B.1.1.7 in proportion to total SARS-CoV-2 viral load in wastewater using an allele-specific primer extension PCR strategy
Tyson E. Graber,
Élisabeth Mercier,
Kamya Bhatnagar,
Meghan Fuzzen,
Patrick M. D’Aoust,
Huy‐Dung Hoang,
Xin Tian,
Syeda Tasneem Towhid,
Julio Plaza Diaz,
Tommy Alain,
Ainslie J. Butler,
Lawrence Goodridge,
Mark R. Servos,
Robert Delatolla,
Tyson E. Graber,
Élisabeth Mercier,
Kamya Bhatnagar,
Meghan Fuzzen,
Patrick M. D’Aoust,
Huy‐Dung Hoang,
Xin Tian,
Syeda Tasneem Towhid,
Julio Plaza Diaz,
Tommy Alain,
Ainslie J. Butler,
Lawrence Goodridge,
Mark R. Servos,
Robert Delatolla
Abstract The coronavirus disease 2019 (COVID-19) pandemic caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has claimed millions of lives to date. Antigenic drift has resulted in viral variants with putatively greater transmissibility, virulence, or both. Early and near real-time detection of these variants of concern (VOC) and the ability to accurately follow their incidence and prevalence in communities is wanting. Wastewater-based epidemiology (WBE), which uses nucleic acid amplification tests to detect viral fragments, is a faithful proxy of COVID-19 incidence and prevalence, and thus offers the potential to monitor VOC viral load in a given population. Here, we describe and validate a primer extension PCR strategy targeting a signature mutation in the N gene of SARS-CoV-2. This allows quantification of the proportional expression of B.1.1.7 versus non-B.1.1.7 alleles in wastewater without the need to employ quantitative RT-PCR standard curves. We show that the wastewater B.1.1.7 profile correlates with its clinical counterpart and benefits from a near real-time and facile data collection and reporting pipeline. This assay can be quickly implemented within a current SARS-CoV-2 WBE framework with minimal cost; allowing early and contemporaneous estimates of B.1.1.7 community transmission prior to, or in lieu of, clinical screening and identification. Our study demonstrates that this strategy can provide public health units with an additional and much needed tool to rapidly triangulate VOC incidence/prevalence with high sensitivity and lineage specificity.
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Quantitative analysis of SARS-CoV-2 RNA from wastewater solids in communities with low COVID-19 incidence and prevalence
Patrick M. D’Aoust,
Élisabeth Mercier,
Danika Montpetit,
Jian-Jun Jia,
I. V. Alexandrov,
Nafisa Neault,
Aiman Tariq Baig,
Janice Mayne,
Xu Zhang,
Tommy Alain,
Marc‐André Langlois,
Mark R. Servos,
Malcolm R. MacKenzie,
Daniel Figeys,
Alex MacKenzie,
Tyson E. Graber,
Robert Delatolla
Water Research, Volume 188
• RT-ddPCR is more sensitive to inhibitors than RT-qPCR for primary clarified sludge. • Primary clarified sludge has elevated frequency of SARS-CoV-2 RNA detection. • Primary clarified sludge allows detection of RNA during low COVID-19 incidence. • PMMoV normalization of RNA data reduces noise and increases precision. • PMMoV normalization of RNA shows strongest correlation to epidemiological metrics. In the absence of an effective vaccine to prevent COVID-19 it is important to be able to track community infections to inform public health interventions aimed at reducing the spread and therefore reduce pressures on health-care, improve health outcomes and reduce economic uncertainty. Wastewater surveillance has rapidly emerged as a potential tool to effectively monitor community infections through measuring trends of RNA signal in wastewater systems. In this study SARS-CoV-2 viral RNA N1 and N2 gene regions are quantified in solids collected from influent post grit solids (PGS) and primary clarified sludge (PCS) in two water resource recovery facilities (WRRF) serving Canada's national capital region, i.e., the City of Ottawa, ON (pop. ≈ 1.1M) and the City of Gatineau, QC (pop. ≈ 280K). PCS samples show signal inhibition using RT-ddPCR compared to RT-qPCR, with PGS samples showing similar quantifiable concentrations of RNA using both assays. RT-qPCR shows higher frequency of detection of N1 and N2 gene regions in PCS (92.7, 90.6%, n = 6) as compared to PGS samples (79.2, 82.3%, n = 5). Sampling of PCS may therefore be an effective approach for SARS-CoV-2 viral quantification, especially during periods of declining and low COVID-19 incidence in the community. The pepper mild mottle virus (PMMoV) is determined to have a less variable RNA signal in PCS over a three month period for two WRRFs, regardless of environmental conditions, compared to Bacteroides 16S rRNA or human 18S rRNA, making PMMoV a potentially useful biomarker for normalization of SARS-CoV-2 signal. PMMoV-normalized PCS RNA signal from WRRFs of two cities correlated with the regional public health epidemiological metrics, identifying PCS normalized to a fecal indicator (PMMoV) as a potentially effective tool for monitoring trends during decreasing and low-incidence of infection of SARS-Cov-2 in communities.
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Catching a resurgence: Increase in SARS-CoV-2 viral RNA identified in wastewater 48 h before COVID-19 clinical tests and 96 h before hospitalizations
Patrick M. D’Aoust,
Tyson E. Graber,
Élisabeth Mercier,
Danika Montpetit,
I. V. Alexandrov,
Nafisa Neault,
Aiman Tariq Baig,
Janice Mayne,
Xu Zhang,
Tommy Alain,
Mark R. Servos,
Nivetha Srikanthan,
Malcolm R. MacKenzie,
Daniel Figeys,
Douglas G. Manuel,
Peter Jüni,
Alex MacKenzie,
Robert Delatolla
Science of The Total Environment, Volume 770
Curtailing the Spring 2020 COVID-19 surge required sweeping and stringent interventions by governments across the world. Wastewater-based COVID-19 epidemiology programs have been initiated in many countries to provide public health agencies with a complementary disease tracking metric and non-discriminating surveillance tool. However, their efficacy in prospectively capturing resurgences following a period of low prevalence is unclear. In this study, the SARS-CoV-2 viral signal was measured in primary clarified sludge harvested every two days at the City of Ottawa's water resource recovery facility during the summer of 2020, when clinical testing recorded daily percent positivity below 1%. In late July, increases of >400% in normalized SARS-CoV-2 RNA signal in wastewater were identified 48 h prior to reported >300% increases in positive cases that were retrospectively attributed to community-acquired infections. During this resurgence period, SARS-CoV-2 RNA signal in wastewater preceded the reported >160% increase in community hospitalizations by approximately 96 h. This study supports wastewater-based COVID-19 surveillance of populations in augmenting the efficacy of diagnostic testing, which can suffer from sampling biases or timely reporting as in the case of hospitalization census.