key: cord-0958269-g0bd3ibf
authors: Cuevas-Ferrando, Enric; Pérez-Cataluña, Alba; Allende, Ana; Guix, Susana; Randazzo, Walter; Sánchez, Gloria
title: Recovering coronavirus from large volumes of water
date: 2020-10-16
journal: Sci Total Environ
DOI: 10.1016/j.scitotenv.2020.143101
sha: 841a7b94f268d7c4d1c96bccdf69d0a8ef4a26a9
doc_id: 958269
cord_uid: g0bd3ibf

The need for monitoring tools to better control the ongoing coronavirus disease (COVID-19) pandemic is extremely urgent and the contamination of water resources by excreted viral particles poses alarming questions to be answered. As a first step to overcome technical limitations in monitoring SARS-CoV-2 along the water cycle, we assessed the analytical performance of a dead end hollow fiber ultrafiltration coupled to different options for secondary concentrations to concentrate viral particles from large volume of spiked tap water, seawater and surface water together with two quantitative RT-qPCR detection kits. Spiking the porcine epidemic diarrhea virus (PEDV), an enveloped virus surrogate for SARS-CoV-2, together with the mengovirus, we demonstrated that PEG-precipitation and SENS-kit better recovered PEDV (13.10 ± 0.66%) from tap water, while centrifugal filtration resulted the best option to recover mengovirus regardless of the detection kit used. No statistical significant differences were found when comparing high (10,000 ×g) and low (3500 ×g) centrifugation speeds for the secondary PEG- based concentration of spiked seawater, while considerable inhibition was observed for both viruses detected by NoInh-kit assay. Similarly, the co-concentration of PCR inhibitors and viral particles was observed in surface waters detected with either SENS-kit or NoInh-kit and RNA dilution was needed to achieve acceptable recoveries at the expenses of the overall sensitivity of the method. These methodologies represent suitable options to investigate SARS-CoV-2 occurrence in different water resources and allow to conduct on site sampling of large volume of water.

The access to safe and clean water is a universal human right (United Nations, 2010) , that has been further questioned by the ongoing coronavirus disease pandemic.

While severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the etiological agent of COVID-19, is mainly a respiratory pathogen, the detection of virus particles in stool supports the hypothesis that fecal-oral transmission may occur (Yeo, Kaushal, & Yeo, 2020) .

Despite this conjecture has not been elucidated yet, wastewater-based epidemiology (WBE) has been implemented worldwide for tracking the pandemic within a given community and for gaining preparedness for future SARS-CoV-2 local outbreaks Farkas, Hillary, Malham, McDonald, & Jones, 2020; Haramoto, Malla, Thakali, & Kitajima, 2020; La Rosa, Bonadonna, Lucentini, Kenmoe, & Suffredini, 2020; Medema, Heijnen, Elsinga, Italiaander, & Brouwer, 2020; Randazzo, Cuevas-Ferrando, Sanjuán, Domingo-Calap, & Sánchez, 2020; Westhaus et al., 2021; WHO, 2020a) . Special interests have been also given to the presence of SARS-CoV-2 in effluent wastewater and recreational waters such as river water and seawater to assess public health risks (Cahill & Morris, 2020; Guerrero-Latorre et al., 2020; Liu, Thompson, Carducci, & Bi, 2020) . A colossal number of laboratories have been involved in wastewater monitoring programs worldwide, being the lack of standard methods the main bottleneck for implementing WBE nation-and world-wide. In this sense, it has been imperative to assess the analytical performances of concentration methods for SARS-CoV-2 in different types of water, as protocols validated for common viral human pathogens such as enteric viruses may not succeed in well-recovering enveloped viruses Randazzo, Truchado, et al., 2020) . To a larger extent, the controversial debate on the fate of SARS-CoV-2 along the water cycle brought to light the need for the development of robust methods for concentrating enveloped viruses from large volume of J o u r n a l P r e -p r o o f Journal Pre-proof water in order to investigate natural water resources such as tap, reclaimed, surface, drinking and sea-waters. In fact, current methods used to concentrate viruses from wastewater are not feasible for larger volumes because of (i) the low viral titers; (ii) the coconcentration of PCR inhibitors (e.g., salt); (iii) the presence of suspended solids, and (iv) the logistics and costs of delivering water samples to laboratories. However, whether the existing methods already validated for concentrating enteric viruses from large volumes are also suitable for enveloped viruses, and therefore used to investigate SARS-CoV-2 contamination in water resources, is unknown.

We assessed the analytical performance of a Dead End Hollow Fiber Ultrafiltration (DEUF) concentration and two quantitative RT-qPCR detection kits with the final aim of developing a tool of interest for studying the potential SARS-CoV-2 contamination of different types of water.

To this end, we concentrated tap, surface and seawaters spiked with porcine epidemic diarrhea virus (PEDV, strain CV777), an enveloped virus member of the Coronaviridae family, and mengovirus (CECT 100000, strain vMC0), a non-enveloped member of the Picornaviridae, used as process controls to evaluate the procedures for concentrating large volume of water. PEDV and mengovirus viral stocks were obtained from Vero and HeLa cells culture infected suspensions, respectively (Puente, Randazzo, Falcó, Carvajal, & Sánchez, 2020) .

All water samples used in this study were of blinded origin and collected in April-May 2020. Specifically, a large volume (20L) of tap water (n=2), seawater (n=2) and surface water (n=2) was collected as a simple grab sample and transferred to the laboratory within 6 hours J o u r n a l P r e -p r o o f Journal Pre-proof to be subsequently processed. All water samples were spiked with 10 7 PEDV genomic copies (gc) and 10 8 mengovirus gc and primary concentrated by DEUF as detailed by Cuevas-Ferrando et al., (2020) . Different options were evaluated for secondary concentrations depending on the type of water: (i) a polyethylene glycol (PEG) precipitation and a centrifuge filtration with Centricon Plus-70 devices with a 30 kDa cutoff NMWL membrane (Merck Millipore Ltd.) for tap water; (ii) a PEG precipitation at 10,000 × g or 3,500 × g for seawater; (iii) a PEG precipitation at 3,500 × g for secondary concentrating surface waters.

RNA extraction from concentrates was carried out using the NucleoSpin RNA virus kit (Macherey-Nagel GmbH & Co.), including a purification step with Plant RNA Isolation Aid (Ambion). For RNA detection, two commercially available kits were compared. Specifically,

Step PrimeScript™ RT-PCR Kit (Perfect Real Time) (Takara Bio, USA) (referred as SENSkit) and One Step PrimeScript™ III RT-PCR Kit (Takara Bio, USA) (referred as NoInh-kit) were used. The first kit is claimed to provide a sensitive detection of very small amounts of RNA, while the latter is highly resistant to a wide variety of inhibitory substances. For all assays, undiluted, 10-and 50-fold diluted RNA were tested to check for RT-qPCR inhibitors. Details on RT-qPCR and quantification have been reported by . The percent virus recovery (r) was calculated as follows:

= 100

The effects of the variables considered in this study (concentration method, RT-qPCR kit, virus, dilution) were separately tested for each type of water sample (tap water, seawater, surface water) by the analysis of variance (ANOVA) followed by the Tukey's HSD as post hoc test to obtain homogenous groups. A P value < 0.05 was deemed significant.

Journal Pre-proof

We defined PEDV and mengovirus recovery yields as the performance characteristic for the viral concentration of spiked tap water, seawater and surface water (Figures 1-3) .

Different modifications for the concentration method specific for each type of water were assessed along with two RT-qPCR quantification assays.

In tap water, significant differences were observed between centrifugal filtration and PEG precipitation, but not between the SENS-kit and the NoInh-kit. PEDV showed higher recoveries when secondary concentrated by PEG-precipitation and detected by SENS-kit (13.10 ± 0.66%), while lower recoveries of 3.94 ± 0.28% were yielded by NoInh-kit. On the contrary, mengovirus was better recovered with centrifugal filtration regardless of the detection kit used, being the recovery rates of 17.95 ± 2.50% for SENS-kit and 17.76 ± 1.52

for NoInh-kit ( Figure 1 ). As it could be expected, no significant PCR inhibitions were detected for both PEDV and mengovirus by using either SENS-kit or NoInh-kit in concentrated tap water.

The options evaluated for the secondary concentration of spiked seawater samples showed no statistical significant differences between the centrifugation speeds (10,000 × g and 3,500 × g), while considerable inhibition was observed for both viruses detected by NoInh-kit assay. Specifically, centrifugation at high (10,000 × g) and low (3,500 × g) speed recovered 3.36 ± 0.10% and 2.98 ± 0.05% of PEDV, and 10.19 ± 0.19% and 9.45 ± 0.12% of mengovirus, respectively, detecting undiluted RNA with SENS-kit ( Figure 2 ). On the contrary, when viral detection was carried out by NoInh-kit on undiluted RNAs, recoveries of 0.76 ± 0.00% and 0.84 ± 0.03% for PEDV, and 0.81 ± 0.07% and 1.52 ± 0.17% for mengovirus were yielded at high and low speed, respectively. This indicates the presence of PCR inhibitions

Journal Pre-proof that was confirmed by the higher recovery rates achieved by diluting the RNAs by 10-fold and 50-fold (Figure 2) .

Similarly, the co-concentration of inhibitors and viral particles was observed in surface waters detected either with SENS-kit or NoInh-kit. The recovery rates of undiluted RNA resulted as low as 0.82 ± 0.06% and 0.51 ± 0.12% for PEDV and 0.29 ± 0.05% and 0.22 ± 0.02% for mengovirus with SENS-kit or NoInh-kit, respectively. Again, by diluting viral RNA by 10-fold and 50-fold, the recoveries rates resulted higher than 2.89% in all cases ( Figure   3 ).

plants (Randazzo, Truchado, et al., 2020) , and in surface water polluted with wastewater The present study reports the analytical performances of several modifications of a DEUF method to concentrate viruses from large volumes of tap water, seawater and surface waters of interest for studying the potential contamination of water resources by SARS-CoV-2. Until recently, studies to assess the efficiency of concentration methods in water matrices mostly involved nonenveloped virus, such as human enteric viruses (reviewed by Bofill-Mas developed for the former would not fit for concentrating the latter. Interestingly, PEG precipitation has been applied as a secondary concentration step to recover enveloped viruses from large volume of water (reviewed by Bofill-Mas & Rusiñol, 2020) , and an optimized procedure based on glass wool primary concentration detected naturally occurring alphacoronavirus in surface water in Saudi Arabia (Blanco et al., 2019) .

Moreover, to assess the sensitivity of RT-qPCR assays to inhibitors, we compared two quantitative detection kits: one claimed to be optimized for low RNA amounts (SENS-kit) and a second specified to be highly resistant to a wide variety of inhibitory substances (NoInh-kit). Despite the use of a contaminants/inhibitors removal product before RNA extraction (Plant RNA Isolation Aid), we observed a different sensitivity of RT-qPCR assays to co-concentrated inhibitory substances, being the SENS-kit less prone to such limiting factor.

Nucleic acid dilution is a well-known approach to evaluate the presence of inhibitors in complex matrices (ISO 15216-1, 2017; McKee et al., 2015) , however, the sensitivity of the assay decreases according to the dilution factor applied. In our study, we had to dilute up to 50-fold the RNA concentrated from surface water and seawater samples to overcome PCR inhibition effects. This resulted in exceeding the detection limit of the assay in some cases In general, data on water reservoirs contaminated by human enteric viruses are limited (Haramoto et al., 2018) , and to date, no evidences of SARS-CoV-2 occurrence in natural water resources have been reported. In line, WHO and CDC agree in defining the risk associated with contracting SARS-CoV-2 via water sources as low (CDC, 2020; WHO, 2020b).

However, in the midst of the current pandemic, chances of SARS-CoV-2 transmission routes cannot be excluded, especially in densely populated areas with poor sanitization systems or when overflows occur (Bhowmick et al., 2020; Heller, Mota, & Greco, 2020) .

Further research is required for monitoring the potential SARS-CoV-2 contamination of downstream waters used for irrigation or recreational purposes, as well drinking water resources in settings with limited availability of water, sanitation and hygiene (Street, Malema, Mahlangeni, & Mathee, 2020) .

To this end, large volume of water has to be sampled and concentration methods need to be validated by either using SARS-CoV-2 spiked or naturally contaminated waters, along with the determination of the limit of detection. Meanwhile, the assessed methodologies represent suitable options to investigate SARS-CoV-2 occurrence in different water resources and allow to conduct on site sampling of large volume of water.

diarrhea virus (PEDV) and mengovirus (MgV) in tap water primary concentrated by dead end hollow fiber ultrafiltration followed by a secondary concentration procedure based on a centrifuge filtration or, alternatively, on a polyethylene glycol (PEG) precipitation.

Letters denote homogeneous groups according to the analysis of variance (ANOVA) and

Tukey's HSD post hoc test (p < 0.05).

J o u r n a l P r e -p r o o f diarrhea virus (PEDV) and mengovirus (MgV) in seawater primary concentrated by dead end hollow fiber ultrafiltration followed by a secondary concentration procedure based on polyethylene glycol (PEG) precipitation using a high-(10,000 x g) or low-(3,500 x g) speed centrifugation.

Letters denote homogeneous groups according to the analysis of variance (ANOVA) and

Tukey's HSD post hoc test (p < 0.05).

J o u r n a l P r e -p r o o f diarrhea virus (PEDV) and mengovirus (MgV) in surface water primary concentrated by dead end hollow fiber ultrafiltration followed by a secondary concentration procedure based on polyethylene glycol (PEG) precipitation using a low-(3,500 x g) speed centrifugation.

#, negative.

Letters denote homogeneous groups according to the analysis of variance (ANOVA) and

Tukey's HSD post hoc test (p < 0.05).

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The authors thank Prof. A. Carvajal from University of Leon for kindly providing PEDV CV777 strain and Agustin Garrido Fernandez for his support in the concentration procedures.We acknowledge the GAMASER, Global Omnium S.L. and SEPRONA for arranging water sampling.

The study was funded by grants from CSIC (202070E101), Generalitat Valenciana (Covid_19-SCI), and MICIU co-founded by AEI/FEDER, UE (AGL2017-82909). EC-F is recipient of a

ECF and APC: Investigation, Editing and Reviewing; WR: data analyses and first draft writing; AA, SG, WR and GS: Conceptualization, Supervision, Writing, Editing and Reviewing.J o u r n a l P r e -p r o o f