Blue mussels (Mytilus spp) are filter-feeders and are widespread in European coastal waters, which are often in close proximity to urban sewage treatment units.1,2 Filter-feeders may retain particles at 4μm with 100% efficiency.3 Faecal contamination of water (via sewage discharge) poses a serious threat to human health as bivalves (mussels and oysters) which filter large volumes of water through their gills as part of their feeding activities, bio-accumulate pathogenic microbes, including enteric bacteria and viruses. In situ studies with bio-accumulation of a virus indicator in oysters have shown that they can effectively concentrate viruses (up to 99-fold) compared to the surrounding water.4 An adult blue mussel may filter ∼72L of water on an average per day5 and have been proposed as bio-samplers for assessment of faecal contamination in recreational waters.6 Consumption of bivalves as food is often reported to be the cause of disease outbreaks by enteric viruses. Though primary infection results from ingestion of faecal contaminated food or water, unintentional ingestion of contaminated recreational waters can also lead to gastrointestinal illness.7 Norovirus outbreaks have a distinct seasonality linked to winter months.8,9 NoV infections are called “gastric flu” for its similar seasonality & lack of effective therapeutics like influenza viruses, and also for its high infectivity and rapid evolution.10,11

Noroviruses (NoVs) are a non-enveloped positive sense single-stranded RNA virus of the Caliciviridae family. NoVs have a significant impact on human health as they are highly infectious and cause acute gastroenteritis in all age groups accounting for >200,000 deaths worldwide each year, especially in children.12 The organism is highly contagious and problematic as a hospital-acquired infection. According to WHO, <10 virions are sufficient to cause infection in adults and NoV outbreaks often lead to closure of entire hospital wards every year affecting both patients and staff. Despite attempts to control via ‘deep cleaning’ and implementing hygiene measures outbreaks can cause considerable inconvenience and economic losses.13–15 NoVs cannot be cultured on cells and detection and diagnosis increasingly relies solely on molecular methods such as reverse transcriptase-PCR (RT-PCR).16 Diversity of NoVs both genetically and antigenically were demonstrated through RT-PCR and genomic sequencing.17 NoVs are divided into six genogroups (GI-GVI) and genogroups are further subdivided into around forty genetic clusters or genotypes.18 NoV genogroups which infect humans are I (NoV GI), II (NoV GII) and rarely IV (NoV GIV). NoV GII.4 is responsible for 80% of the disease outbreaks19 and is currently the most virulent strain circulating in the UK.20 Since it has a faster mutation rate than other NoVs21 new variants emerge every 2–3 years and is also responsible for 60–80% of outbreaks worldwide.22 The GII.4 variant named Sydney 2012 has progressively replaced the predecessor GII.4 New Orleans 2009 variant globally.23,24

GII.4 outbreaks occurred preferentially during winter months25 and most works have been conducted with samples collected during winter months.26 Thus the aim of the present study was to screen for NoV contamination/retention in bivalves during the summer months in the UK coastal seawaters. This work contributes to the development of a working methodology for the routine surveillance of mussels round the year for identification and genetic characterization of enteric pathogenic viruses accumulated within them.

NoVs are most common cause of outbreaks of food-borne illnesses and pose serious health risks to humans. In the present small-scale study, mussel samples obtained from seawater near Swansea were found to contain two GII.4 variants. In February 2012, four wards were closed in a nearby public hospital due to NoV outbreak (http://www.bbc.com/news/uk-wales-south-west-wales-17110220 accessed on 14.10.2015). However, if the GII.4 virus strains identified in the mussels were genetically identical to the NoV strains responsible for the Swansea outbreaks, it would demonstrate that these viruses probably survive the sewage treatment process and concentrate in mussels. This could not be analyzed in the present study as no sequence data on the outbreak of NoV strains from Swansea in 2012 were available in the public domain. In this context, it is worth mentioning that the most commonly detected GII.4 strain in the healthcare settings in UK in the season (2013–2015) was Sydney 2012 (PHE Monthly National Norovirus and Rotavirus Report, 14 April, 2016).33 NoV capsid PCRs were negative which could have resulted from primer mismatch as capsid proteins are exposed to higher level of immune pressure and therefore, immune selection compared to more conserved non-structural proteins like virus RNA-dependent RNA polymerase. Consequently, the capsid genes are more prone to higher rates of mutation. As humans are mostly infected by the GII strains, the present work indicates the need for a larger study of surveillance of enteric viruses (e.g. NoV, HAV virus and HEV, rotaviruses and others) that contaminate coastal waters of the UK and become bio-accumulated in mussels, clams and oysters34 confirming their role as a food chain source of infection.

NoV GI and GII have been detected in oyster samples harvested from bays and estuaries worldwide35,36 and also from human samples.25 However, this is the first report, to the best of our knowledge, on NoV GII.4 Sydney 2012 variant detected in blue mussels collected from UK coastal waters. It suggests that choosing noroviruses as a parameter would be worthy enough if viral testing of mussels is introduced on a routine basis. It was also interesting to note that norovirus is highly detectable even in a small scale sampling of mussels during summer months, suggesting the possible prevalence of pathogenic NoV strains contaminating UK coastal waters throughout the year.

It had been reported earlier that NoV outbreaks are more likely to occur during winter4 as cold water temperatures and reduced ultraviolet light increase their survival.37 The present work detected NoVs to a great extent even in summer months, so it may be proposed that mussels act as reservoirs to retain and shelter the viruses round the year so that they can contribute to the flux of viable NoVs contamination of sea waters during winter and potentiate greater spread to cause severe outbreaks of NoV infections during the winter months.

One limitation of the present work was that the sample size was not large but still comparable to that reported earlier.28 Despite pilot level sample size, the interesting and important observation was that different pathogenic NOV GII, including GII.4 Sydney variants (as evident from sequence variations in the RdRp gene) could be detected from potentially all the blue mussels collected. This suggests substantial environmental contamination which perhaps explains why Sydney 2012 variant was isolated from most UK outbreaks during 2013–15. One possible explanation for the clustering of the GII.4 Sydney variants of NoVs from mussels with NoVs of Chinese and Taiwanese origin could be that the mussel collection sites in the present study were places where year-round maritime activities take place and coastal water contamination from ships and vessels from faraway places could not be ruled out. Surveillance and control of NoV outbreaks related to mussel and other shellfish consumption is therefore crucial to prevent spread of infection in the population. We believe that this work will be an important addendum to the ongoing research in NoV epidemiology in the UK.38–40

The authors declare that they have no conflict of interest. All authors have agreed to the final version of the manuscript.