Abstract
Levels of Escherichia coli and male-specific bacteriophages (MSBs) were determined in the filter feeders obtained from retail markets, commercial farms, and wild beds in Korea. The accumulation and elimination of E. coli and MSBs were compared between ascidians and bivalves (oysters and mussels) during relaying and depuration. E. coli concentrations in ascidians from retail markets ranged between < 20 and 460 most probable number/100 g while MSBs were not detected. E. coli levels in bivalves from commercial farms and wild beds were not significantly different but bacterial levels in ascidians were consistently lower. Ascidians exhibited much lower ability than bivalves to accumulate E. coli and MSBs during relaying in a polluted coastal area. This study also shows that an equilibrium was developed between levels of microbes in water and ascidians and shellfish during relaying. E. coli and MSBs in ascidians decreased quickly during depuration in a clean seawater tank. However, after 1 day, E. coli in bivalves decreased by only 1.1–1.6 logs, and the elimination of MSBs was negligible. Therefore, depuration is an effective means to reduce the health risk of contaminated ascidians.
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Introduction
The edible ascidian Halocynthia roretzi is a commercially important seafood species in Korea, Japan, and other Asian countries. Ascidians are cultured extensively in coastal regions of eastern and southern Korea and northeastern Japan (Mizuta et al. 2002). Similar to other tunicates, ascidians are suspension feeders that filter phytoplankton and other suspended particulate matter from the surrounding water (Bone et al. 2003; Petersen 2007; Riisgård and Larsen 2010). Besides ingesting phytoplankton and other food particles, filter-feeding animals (e.g., tunicates and bivalves) may also concentrate pathogenic bacteria and viruses in their guts, so that consumption of filter feeders from polluted waters presents a risk to human health.
For many decades, the consumption of raw or undercooked bivalves, such as oysters and clams, has been implicated in numerous food-poisoning outbreaks caused by pathogenic microorganisms (Rippey 1994; Potasman et al. 2002; Lees et al. 2010; Sair et al. 2002; Iwamoto et al. 2010; Yang et al. 2017). Fecal coliforms, including Escherichia coli, are used as fecal contamination indicators to assess the quality of bivalves and to determine whether bivalves are safe for raw consumption (Mok et al. 2016a). Many countries have established regulatory limits using fecal indicators for bivalves and their growing areas (European Commission (EC) 2005; New Zealand Food Safety Authority (NZFSA) 2006; US Food and Drug Administration (US FDA) 2015; Korea Ministry of Food and Drug Safety (KMFDS) 2016). Male-specific bacteriophages (MSBs) have been also used for tracking pollution in marine estuaries and determining the risk of illness associated with the consumption of raw bivalves (Burkhardt et al. 1992b). Furthermore, in Korea, peeled whole ascidians are commonly consumed raw, including the hepatopancreas. For this reason, as for bivalves, careful attention must be paid to the food safety of ascidians.
Several experiments have been conducted to determine the kinetics of uptake and elimination of fecal indicator bacteria and pathogens by shellfish. The accumulation and elimination kinetics of enteric bacteria and viruses vary among bivalve species (Cabelli and Heffernan 1970) and depend on the type of microorganism (Burkhardt et al. 1992a; Burkhardt and Calci 2000; Mok et al. 2016b) and environmental conditions (Burkhardt et al. 1992a). Although ascidians and bivalves are both filter feeders, they differ in size and in their particle capture mechanisms (Riisgård and Larsen 2010). It is well established that the filtration rates of ascidians vary with the species and environmental conditions (Randløv and Riisgård 1979; Ribes et al. 1998; Petersen and Svane 2002). Feed particle size and capture mechanisms have been studied extensively in ascidians (Bone et al. 2003; Petersen 2007; Riisgård and Larsen 2010). However, few studies have been conducted to evaluate the microbiological quality of live ascidians destined for raw consumption. Although bacterial contamination of ascidians can occur at any step from pre-harvest through to final preparation, prevention of initial contamination at the harvesting area is important because, as noted, the animal is commonly consumed raw in Asian countries.
In the present study, microbiological quality was evaluated based on the levels of indicators of fecal contamination, including total coliforms, fecal coliforms, E. coli, and MSBs in live bivalves (oysters and mussels) and ascidians collected from retail markets or fields. The characteristics of bioaccumulation and elimination of E. coli and MSBs by H. roretzi and by oysters and mussels were compared by relaying them at a polluted area and then depuration in seawater tanks to investigate the importance of ascidians as vectors in the transmission of pathogenic microorganisms. While levels of these microorganisms in bivalves (oysters and mussels) at retail markets have been studied as well as bioaccumulation and depuration, this is the first work that we are aware of that evaluates the levels of fecal indicators within ascidians as a vector in the transmission of pathogenic microorganisms.
Materials and methods
Sample collection
Live ascidians (H. roretzi) were obtained from local retail markets in Tongyeong and Busan, Korea, during 2009–2010. Samples of H. roretzi, oysters (Crassostrea gigas), and mussels (Mytilus galloprovincialis) were also collected from a commercial aquaculture farm and from wild beds. The commercial farm was located in an area designated for shellfish growing for export that met water quality standards of the National Shellfish Sanitation Program (NSSP) for approved areas (US FDA 2015). The wild bed was located in a shallow water coastal region near Busan City, which is susceptible to land-based pollutants. Samples of animals were collected monthly from the commercial farm and from the wild bed. All collected samples for microbiological analysis were maintained below 10 °C during transport to the laboratory. Ascidians, oysters, and mussels for accumulation and elimination experiments were taken from the designated shellfish-growing area.
Analysis of fecal indicator bacteria
The levels of total coliforms, fecal coliforms, and E. coli in the samples were enumerated by the most probable number (MPN) method. The MPN method used was a five-tube test using three tenfold serial dilutions; referring the numbers of tubes yielding positive results to published standard tables gave the concentrations of bacteria in the samples. The recommended procedures for the examination of seawater and shellfish according to the American Public Health Association (APHA) were applied for total coliform and fecal coliform enumeration (APHA 1970). The presumptive test was performed using lauryl tryptose broth (Difco, Detroit, MI, USA) at 35 ± 0.5 °C. The confirmative test used brilliant green-lactose broth (Difco) at 35 ± 0.5 °C for total coliforms, and EC medium (Difco) at 44.5 ± 0.2 °C for fecal coliforms. In addition, the ISO/TS 16649-3 method (ISO 2015) was used for E. coli enumeration. Tubes of Minerals-modified Glutamate Broth (Oxoid, Basingstoke, UK) were incubated at 37 ± 1 °C for 24 ± 2 h for the presumptive test. Each positive culture tube showing yellow color was subsequently confirmed by subculture onto a Tryptone Bile X-glucuronide Agar (Oxoid) plate at 44 ± 1 °C for 22 ± 2 h. Results are expressed as MPN/100 mL for seawater and MPN/100 g for ascidian and bivalve meat samples. The limits of detection (LODs) of these methods were the following: 18 MPN/100 g of meat and 1.8 MPN/100 mL of seawater for total and fecal coliforms, and 20 MPN/100 g of meat and 2.0 MPN/100 mL of seawater for E. coli.
MSB analysis
The MSB levels in ascidians and bivalves meat were assayed using the double-layer agar method described by Burkhardt et al. (1992b). The E. coli culture HS[pFamp]R (ATCC 700891) was obtained from the American Type Culture Collection through their Korean distributor and used as the bacterial host strain for the MSBs. The bacterial host culture was prepared as described in the US EPA method 1601 (US EPA 2001). The assays used the antibiotics, streptomycin sulfate, and ampicillin to prevent competing bacterial growth. The MSBs were quantified by plaque formation on the host E. coli on the agar medium. The results are expressed as the numbers of plaque-forming units (PFU) per 100 g or per 100 mL of sample. The LODs were 17 PFU/100 g of meat and 10 PFU/100 mL of seawater.
Bioaccumulation experiments
Live ascidians, oysters, and mussels collected from the designated shellfish-growing area were transferred to water near the outflow of a sewage treatment plant to compare the accumulation rates and final levels of E. coli and MSBs by ascidians and bivalves. Ascidians, oysters, and mussels harvested from the designated shellfish-growing area were used for relaying, after confirming that they were free from E. coli and MSBs. After scrubbing with a stiff brush to remove adhering detritus and fouling organisms, 37 animals (7 ascidians, 15 oysters, and 15 mussels) were placed together into each of mesh bags (mesh size 10 mm). The bags were hung from buoys and allowed to sink approximately 50 cm below the surface at the relaying site. Duplicate samples of five ascidians and 12 mussels and oysters were taken from each bag and assayed for the levels of E. coli and MSB.
Depuration experiments
The depuration tank (100 × 100 × 70 cm high) had a working volume of 400 L. Sand-filtered (Negatron Water Filter, Busan, Korea), UV-irradiated (four 39-W lamps, Sungchang, Anyang, Korea) seawater was used for the depuration experiments. Prior to the depuration experiments, no detection of indicators in the seawater was confirmed. The water temperature was maintained at 12 ± 8 °C. Contaminated ascidians and bivalves relayed for 5 days were washed thoroughly, and damaged and moribund individuals were rejected. The contaminated animals were loaded into baskets without overlapping and the baskets were placed on the bottom of the depuration tank at a depth of approximately 8 cm. Seawater was supplied to the tank at a rate of 10 L/min. Duplicate samples of five ascidians, 10 oysters, or 10 mussels were retrieved for microbiological analysis.
Water purification by filter feeders
Twenty similarly sized ascidians, oysters, or mussels were shucked (or peeled) and weighed for calculation of average net weight. Sewage containing bacteria and MSBs was filtered with a paper pre-filter (Advantec No. 5A, Toyo Roshi, Japan) for the removal of particles. Filtered sewage (2 L) was added to sand-filtered seawater (120 L), the mixture was stirred with an electronic stirrer for 1 h, and the mixture was then subdivided into 30-L volumes. Prior to subdividing, the levels of E. coli and MSBs in the mixture were enumerated. Groups of 22 ascidians, 25 oysters, or 74 mussels providing similar total net meat weights (ca. 400 g) were each placed in 30 L of the seawater mixture and aerated (air filtered with a cotton plug). Seawater was sampled daily for analysis of E. coli and MSB concentration to investigate the water purification activities of the ascidians and bivalves. Water temperature and salinity were measured using an YSI 556 Multiprobe system (YSI Inc., Yellow Springs, OH).
Results and discussion
Levels of fecal indicator bacteria and MSBs in ascidians from retail markets
Levels of total coliforms, fecal coliforms, E. coli, and MSBs in live ascidians obtained from retail markets in Busan (Gijang market) and Tongyeong (Seoho market and Jungang market), Korea, are summarized in Table 1.
Levels of fecal indicator bacteria in ascidians differed among the markets and sample batches. The maximum levels recorded among the 30 samples taken from the three retail markets were 1100 MPN/100 g total coliforms, 230 MPN/100 g fecal coliforms, and 460 MPN/100 g E. coli. The estimated geometric means were 24 MPN/100 g for fecal coliforms and 22 MPN/100 g for E. coli. The MSBs were not detected in any of the retailed ascidians.
The levels of E. coli in most of the ascidians (n = 30) purchased from the three markets complied with the European standard for live and raw seafood (bivalves, echinoderms, tunicates, and gastropods) for human consumption (fewer than 230 E. coli per 100 g) (EC 2005), and no MSBs were found. However, the level of E. coli (460 MPN/100 g) in one sample obtained from Seoho market, Tongyeong, exceeded the European standard. The geometric mean value of E. coli concentration in ascidians from the 30 retail samples (24 MPN/100 g) was higher than that in retailed oysters from the North Atlantic and Pacific coasts but similar to that of Gulf and Mid-Atlantic coast oysters in the USA (DePaola et al. 2010). Even in the ascidian sample that exceeded the European E. coli standard of 230 MPN/100 g, the MSB concentration was below the detection limit of 17 PFU/100 mL. Although the ratios of MSBs and E. coli change during the sewage treatment process, E. coli are generally present in greater concentrations than MSBs in raw sewage (Doré et al. 2003). The sample that exceeded the European standard may have been contaminated by untreated sewage at any stage of growing, harvesting, and handling.
Levels of fecal indicator bacteria and MSBs in ascidians and bivalves collected from commercial farms and wild beds
The levels of fecal indicator bacteria and MSBs in the seawater, ascidians, oysters, and mussels collected from commercial farms and wild beds are summarized in Table 2.
Levels of fecal indicator bacteria in the seawater and in the three filter feeders were significantly different among the sample collection sites. Marked differences in bacterial levels were also observed among the ascidians, oysters, and mussels at the same sampling site. Maximum and geometric mean concentrations of total coliforms in ascidians from the commercial farm were lowest among the three filter feeders. However, there were no significant differences in fecal coliforms and E. coli levels among ascidians, oysters, and mussels because the levels of fecal indicator bacteria in most of the samples were below the detection limit. In the samples from wild beds, the maximum and geometric mean concentrations of three categories of indicative bacteria in ascidians were lower than those in oysters and mussels. The maximum concentrations of total coliforms in ascidians, oysters, and mussels from wild beds were 230, 4900, and 2400 MPN/100 g, respectively, and the geometric mean concentrations were 43, 221, and 102 MPN/100 g, respectively. The MSBs were not detected in any of the samples. No significant differences were observed in the levels of the indicative bacteria between oysters and mussels. The levels of the indicator bacteria in ascidians were consistently lower than those observed in bivalves. The levels of MSBs could not be compared among filter feeders because the MSBs were not detected in any of the tested samples.
Korea is the world’s fourth largest producer of bivalves, contributing almost 2.8% of the global harvest (Pawiro 2010). Some of the shellfish-growing areas meet the approved area criteria of the National Shellfish Sanitation Program Guide for the Control of Molluscan Shellfish (US FDA 2015) for which the median, or geometric mean, of fecal coliforms in seawater should not exceed 14 MPN/100 mL, and the estimated 90th percentile should not exceed 43 MPN/100 mL. Other shellfish-growing areas located close to pollution sources are affected by the land-based fecal contaminants during wet weather (Ha et al. 2011).
Most bivalve and ascidian farms are located in shallow coastal waters, which may be affected by the land pollution sources. Our data showed that bivalves concentrated fecal indicator bacteria to a slightly higher degree than ascidians did. Unfortunately, levels of MSBs in ascidians could not be compared with those in bivalves. Nevertheless, ascidians produced from coastal waters were apparently much safer for raw consumption than oysters harvested from the same areas. The bioaccumulation and elimination characteristics of these filter feeders for E. coli and MSBs were compared in relaying and depuration experiments to investigate possible reasons for the differences in the levels of indicator bacteria in filter feeders from the same growing water.
Bioaccumulation and elimination of E. coli and MSBs by filter feeders
Bioaccumulation of E. coli and MSBs in filter feeders that were relayed from designated shellfish-growing areas to an area contaminated by sewage is shown in Fig. 1. E. coli was selected as the only test indicator because this bacterium was recommended as the best biological indicator for contamination of bivalve flesh by fecal pollutants for public health protection (Edberg et al. 2000). Levels of E. coli and MSBs in relaying waters fluctuated during the experiment in the ranges 33–170 MPN/100 mL and 10–110 PFU/100 mL, respectively. The concentrations of E. coli in the filter feeders reached maximum levels after 1 or 2 days of relaying and fluctuated within 920–4900 MPN/100 g in mussels, 630–1400 MPN/100 g in oysters, and 140–490 MPN/100 g in ascidians. Mussels were consistently contaminated with higher levels of E. coli than were oysters collected at the same time, and concentrations of the bacteria in ascidians were much lower than those in oysters. In contrast to the relatively rapid accumulation of E. coli in filter feeders (1–2 days), MSB concentrations reached the highest levels in each filter feeder after 4 days of relaying. Figure 1 also shows that an equilibrium was developed between levels of microbes in water and ascidians and shellfish within 4 days for oysters and mussels.
Patterns of MSB accumulation differed among the three species. MSBs were accumulated faster and to higher levels in oysters than in mussels or ascidians. A high level of MSBs accumulated in both bivalves but low levels were observed in ascidians. The MSBs in bivalve meat reached ca. 103 PFU/100 g within 2 days after relaying in oysters, and within 4 days in mussels, and remained at 103 PFU/100 g. In contrast, the highest level of MSBs recorded in ascidians was only 120 PFU/100 g. Thus, ascidians showed much poorer ability to accumulate E. coli and MSBs compared with both bivalves. In most cases, the MSB concentration in the flesh of ascidians was lower than that in seawater.
The accumulation levels of bacteria and MSBs varied among the three species. Accumulation factors for bacteria and MSBs in the ascidians, oysters, and mussels were calculated from the geometric mean concentrations of E. coli and MSBs and are presented in Fig. 1. The accumulation factors for E. coli were 3.3 for ascidians, 11.4 for oysters, and 23.6 for mussels. Accumulation factors for MSBs were 0.7, 60.9, and 11.2, respectively. E. coli were most efficiently accumulated in mussels and MSBs were most efficiently accumulated in oysters. The lowest accumulation factors for both E. coli and MSBs were observed in ascidians, especially for MSBs where the concentration was lower than in the surrounding water.
Many studies have been carried out on the accumulation of enteric bacteria and viruses in various bivalve species (Bedford et al. 1978; Timoney and Abston 1984; Doré and Lees 1995; Burkhardt and Calci 2000). Although bacteria and viruses are usually accumulated in bivalve tissue to levels much higher than in the surrounding water, interspecific differences among filter feeders in their ability to accumulate microorganisms have been reported, with accumulation factors varying from a fewfold to more than a hundredfold (Kershaw et al. 2013; Burkhardt and Calci 2000). These differences are probably associated with the morphology of the gills in bivalves and the branchial basket in ascidians (Kryger and Riisgard 1988; Doré and Lees 1995; Galbraith et al. 2009; Petersen and Svane 2002). Other biological factors may be involved; for example, norovirus binds specifically to oyster digestive tissues (Le Guyader et al. 2006), and Burkhardt and Calci (2000) showed that F-specific coliphage was selectively accumulated up to 99-fold in oysters (C. virginica). A number of studies have shown that mussels accumulate enteric bacteria, such as E. coli, faster and to higher levels than in oysters (C. gigas). The average E. coli accumulation ratios in mussels (Mytilus spp.) were from 1.3 to 3.4 times greater than those in oysters (C. gigas) (Berry and Younger 2009; Younger and Reese 2013; Kershaw et al. 2013). In the present study, the geometric mean accumulation factor of E. coli in mussels was 2.1 times higher than that in oyster, which is consistent with previous reports. However, accumulation factors of E. coli and MSBs in tissues of the ascidian H. roretzi were lower than those in mussels or oysters.
To investigate the cause of the lower accumulation factors in ascidians, change patterns of E. coli and MSBs in a mixture of filtered seawater and sewage for the three filter feeders were assessed (Fig. 2). Species and animal size, water temperature, and the size and concentration of particles are all known to affect filtration activity by filter feeders (Vaughn and Hakenkamp 2001; Petersen 2007). Thus, in the present study, change patterns of E. coli and MSBs in ascidians and bivalves were compared under the same environmental conditions. Species-specific differences were observed in decrease rates of E. coli and MSBs. The level of E. coli in the water holding the ascidians declined more rapidly than that in the water holding oysters and mussels. In contrast, MSBs were most slowly removed from the water holding ascidians. Although E. coli was rapidly removed from the water by the ascidians, the bacterium was accumulated to a lower concentration in ascidian tissues than in bivalves (Fig. 1). However, MSBs in ascidians in the surrounding water decreased slower than those in bivalves (Fig. 2) and accumulation of MSBs in ascidians was also lower than that in bivalves (Fig. 1). Bacteria are an important food source for bivalves and tunicates. Stuart and Klumpp (1984) observed that ascidians retained all particles larger than 0.6 μm with ca. 100% efficiency but the retention efficiency of the same-sized particles was only 20% in bivalves. Thus, it was suggested that the bacteria were more easily digested or inactivated by ascidians than by bivalves. It was unclear whether MSBs were passed through the branchial basket of ascidians or were not inactivated in hepatopancreas after uptake by animals.
Other experiments on the elimination of E. coli and MSBs during depuration in a clean seawater tank from the contaminated filter feeders are shown in Fig. 3. Different microbial reduction patterns were observed between ascidians and bivalves. In the ascidians, the levels of microorganisms declined quickly from high starting concentrations of E. coli (2200 MPN/100 g) and MSBs (310 PFU/100 g) to undetectable levels (< 20 MPN/100 g for E. coli, < 17 PFU/100 g for MSB) within 1 day of depuration. However, E. coli levels in bivalves, oysters, and mussels decreased by only 1.1 logs and 1.6 logs, respectively, and the elimination of MSBs was negligible after 1 day of depuration. Bivalves were of class C (4600 to 46,000 E. coli MPN/100 g flesh) according to microbiological standards of EU legislation (EC 2005) before depuration and improved to better than class Al (< 230 E. coli MPN/100 g flesh) for raw consumption within 2 days of treatment. In contrast, the MSB concentrations in bivalves dropped by only 0.14–0.31 logs in the same period.
Several studies have revealed that viruses are retained by bivalves for significantly longer periods than indicator bacteria such as E. coli and fecal coliforms (Power and Collins 1989; Doré and Lees 1995; Burkhardt and Calci 2000; Oliveira et al. 2011). In particular, human norovirus has been shown to persist longer than feline calicivirus or poliovirus in oysters under depuration (Ueki et al. 2007; Mcleod et al. 2009). Thus, although depuration is an efficient purification procedure for bacterial contaminants in bivalves, the process has a limited effect on reducing viral levels. Our observations are consistent with these earlier studies. Many studies on accumulation and elimination of enteric bacteria and bacteriophages for disease prevention have focused on bivalves for economic reasons. Unlike bivalves, there have been few reports on the kinetics of accumulation and elimination of bacteria and viruses by ascidians. In this study, we compared microbiological quality and bioaccumulation and elimination properties between ascidians and bivalves. We conclude that the depuration process is an effective way to reduce the health risk of contaminated ascidians but, similar to bivalves, ascidians can be a vector of human disease when they are grown in polluted coastal areas for raw consumption.
Conclusions
In the present study, microbiological quality was evaluated on the basis of bacterial fecal contamination indicators and MSBs in live ascidians collected from the growing areas and the retail markets. In addition, the accumulation and elimination characteristics of E. coli and MSBs by ascidian and bivalves were compared during bioaccumulation by relaying them at a polluted area and depuration in seawater tanks. The E. coli concentrations of ascidians purchased from three retail markets ranged from < 20 MPN/100 g to 460 MPN/100 g, meeting the European standard for live and raw seafood, with exception of one sample, and MSBs were not detected. No significant differences were observed in the indicator levels for bacteria in oysters and mussels; the indicator levels in ascidians were consistently lower than those in bivalves collected from commercial farms or wild beds.
E. coli was quickly accumulated in the filter feeders but MSB accumulation was delayed during relaying in a polluted coastal area. Mussels were consistently contaminated with higher levels of E. coli than were oysters collected at the same time, and the bacterial levels in ascidians were even lower than those in oysters. High levels of MSBs were accumulated in bivalves but low levels of MSBs were found in ascidians. These observations suggest that ability of ascidians to accumulate E. coli and MSBs is lower than that of mussels and oysters.
Species-specific differences were also observed in the elimination rates of E. coli and MSBs by these filter feeders during depuration in a clean seawater tank. The levels of microorganisms in ascidians decreased quickly from starting concentrations of 2200 MPN/100 g of E. coli and 310 PFU/100 g of MSBs to undetectable levels (< 20 MPN/100 g for E. coli, < 17 PFU/100 g for MSB) within 1 day of depuration. However, E. coli levels in oysters and mussels decreased by only 1.1 logs and 1.6 logs, respectively, and elimination of MSBs was negligible after 1 day of depuration. Therefore, we conclude that depuration is an effective means of reducing the health risk of contaminated ascidians.
References
APHA (American Public Health Association) (1970) Recommended procedures for the examination of seawater and shellfish. American Public Health Association, Washington DC
Bedford AJ, Williams G, Bellamy AR (1978) Virus accumulation by the rock oyster Crassostrea glomerata. Appl Environ Microbiol 35(6):1012–1018
Berry R, Younger A (2009) Interspecies comparison of E. coli accumulation in bivalve shellfish using data obtained from official control monitoring under EU Regulation 854/2004. Presented at the 7th International Conference on Molluscan Shellfish Safety (ICMSS09 Nantes, France
Bone Q, Carré C, Chang P (2003) Tunicate feeding filters. J Mar Biol Ass U K 83:907–919
Burkhardt W, Calci KR (2000) Selective accumulation may account for shellfish-associated viral illness. Appl Environ Microbiol 66(4):1375–1378. https://doi.org/10.1128/AEM.66.4.1375-1378.2000
Burkhardt W, Rippey SR, Watkins WD (1992a) Depuration rates of northern quahogs Mercenaria mercenaria and eastern oysters Crassostrea virginica in ozone- and ultraviolet light-disinfected seawater systems. J Shellfish Res 11:105–109
Burkhardt W, Watkins WD, Rippey SR (1992b) Survival and replication of male-specific bacteriophages in molluscan shellfish. Appl Environ Microbiol 58(4):1371–1373
Cabelli VJ, Heffernan WP (1970) Elimination of bacteria by the soft shell clam Mya arenaria. J Fish Res Board Canada 27(9):1579–1587. https://doi.org/10.1139/f70-179
DePaola A, Jones JL, Woods J, Burkhardt W, Calci KR, Krantz JA, Bowers JC, Kasturi K, Byars RH, Jacobs E, Williams-Hill D, Nabe K (2010) Bacterial and viral pathogens in live oysters: 2007 United States market survey. Appl Environ Microbiol 76(9):2754–2768. https://doi.org/10.1128/AEM.02590-09
Doré WJ, Lees DN (1995) Behavior of Escherichia coli and male-specific bacteriophage in environmentally contaminated bivalve molluscs before and after depuration. Appl Environ Microbiol 61(8):2830–2834
Doré WJ, Mackie M, Lees DN (2003) Levels of male-specific RNA bacteriophage and Escherichia coli in molluscan bivalve shellfish from commercial harvesting areas. Lett Appl Microbiol 36(2):92–96. https://doi.org/10.1046/j.1472-765X.2003.01268.x
EC (European Commission) (2005) Commission Regulation (EC) No. 2073/2005 of 15 November 2005 on microbiological criteria for foodstuffs. http://eur-lex.europa.eu/LexUriServ/LexUriServ.do?uri=CONSLEG:2005R2073:20071227:EN:PDF. Accessed 22 June 2016
Edberg SC, Rice EW, Karlin RJ, Allen MJ (2000) Escherichia coli: the best biological drinking water indicator for public health protection. J Appl Microbiol 88(S1):106S–116S. https://doi.org/10.1111/j.1365-2672.2000.tb05338.x
Galbraith HS, Frazier SE, Allison B, Vaughn CC (2009) Comparison of gill surface morphology across a guild of suspension-feeding unionid bivalves. J Molluscan Stud 75(2):103–107. https://doi.org/10.1093/mollus/eyn045
Ha KS, Yoo HD, Shim KB, Kim JH, Lee TS, Kim PH, Ju JY, Lee HJ (2011) Evaluation of the influence of inland pollution sources on shellfish growing areas after rainfall events in Geoje Bay, Korea. Korean J Fish Aquat Sci 44:612–621
ISO (International Organization for Standardization) (2015) ISO 16649-3:2015, Microbiology of the food chain—horizontal method for the enumeration of beta-glucuronidase-positive Escherichia coli—part 3: detection and most probable number technique using 5-bromo-4-chloro-3-indolyl-beta-D-glucuronide. International Organization for Standardization, Geneva
Iwamoto M, Ayers T, Mahon BE, Swerdlow DL (2010) Epidemiology of seafood-associated infections in the United States. Clin Microbiol Rev 23(2):399–411. https://doi.org/10.1128/CMR.00059-09
Kershaw S, Campos CJA, Reese A, Mitchard N, Kay D, Wyer M (2013) Impact of chronic microbial pollution on shellfish. Cefas, Lowestoft, UK
KMFDS (Korea Ministry of Food and Drug Safety) (2016) Korea food code http://fse.foodnara.go.kr/residue/RS/jsp/menu_02_01_01.jsp. Accessed 22 June 2016
Kryger J, Riisgard HU (1988) Filtration rate capacities in 6 species of European freshwater bivalves. Oecologia 77(1):34–38. https://doi.org/10.1007/BF00380921
Le Guyader FS, Loisy F, Atmar RL, Hutson AM, Estes MK, Ruvoën-Clouet N, Pommepuy M, Le Pendu J (2006) Norwalk virus-specific binding to oyster digestive tissues. Emerg Infect Dis 12(6):931–936. https://doi.org/10.3201/eid1206.051519
Lees D, Younger A, Doré B (2010) Depuration and relaying. In: Rees G, Pond K, Kay D, Bartram J, Santo Domingo J (eds) Safe management of shellfish and harvest waters. World Health Organization, IWA Publishing, London, pp 145–181
Mcleod C, Hay B, Grant C, Greening G, Day D (2009) Inactivation and elimination of human enteric viruses by Pacific oysters. J Appl Microbiol 107(6):1809–1818. https://doi.org/10.1111/j.1365-2672.2009.04373.x
Mizuta S, Isobe S, Yoshinaka R (2002) Existence of two molecular species of collagen in the muscle layer of the ascidian (Halocynthia roretzi). Food Chem 79(1):9–13. https://doi.org/10.1016/S0308-8146(02)00167-X
Mok JS, Lee KJ, Kim PH, Lee TS, Lee HJ, Jung YJ, Kim JH (2016a) Bacteriological quality evaluation of seawater and oysters from the Jaranman-Saryangdo area, a designated shellfish growing area in Korea: impact of inland pollution sources. Mar Pollut Bull 108(1–2):147–154. https://doi.org/10.1016/j.marpolbul.2016.04.036
Mok JS, Lee TS, Kim PH, Lee HJ, Ha KS, Shim KB, Lee KJ, Jung YJ, Kim JH (2016b) Bacteriological quality evaluation of seawater and oysters from the Hansan-Geojeman area in Korea, 2011–2013: impact of inland pollution sources. SpringerPlus 5(1):1412. https://doi.org/10.1186/s40064-016-3049-9
NZFSA (New Zealand Food Safety Authority) (2006) Animal products (Specifications for bivalve molluscan shellfish). http://www.foodsafety.govt.nz/elibrary/industry/Animal_Products-Applies_Anyone.pdf. Accessed 22 June 2016
Oliveira J, Cunha A, Castilho F, Romalde JL, Pereira MJ (2011) Microbial contamination and purification of bivalve shellfish: crucial aspects in monitoring and future perspectives—a mini-review. Food Control 22(6):805–816. https://doi.org/10.1016/j.foodcont.2010.11.032
Pawiro S (2010) Bivalves: global production and trade trends. In: Rees G, Pond K, Kay D, Bartram J, Santo Domingo J (eds) Safe management of shellfish and harvest waters. World Health Organization, IWA Publishing, London, pp 11–19
Petersen JK (2007) Ascidian suspension feeding. J Exp Mar Biol Ecol 342(1):127–137. https://doi.org/10.1016/j.jembe.2006.10.023
Petersen JK, Svane I (2002) Filtration rate in seven Scandinavian ascidians: implications of the morphology of the gill sac. Mar Biol 140:397–402
Potasman I, Paz A, Odeh M (2002) Infectious outbreaks associated with bivalve shellfish consumption: a worldwide perspective. Clin Infect Dis 35(8):921–928. https://doi.org/10.1086/342330
Power UF, Collins JK (1989) Differential depuration of poliovirus, Escherichia coli, and a coliphage by the common mussel, Mytilus edulis. Appl Environ Microbiol 55(6):1386–1390
Randløv A, Riisgård HU (1979) Efficiency of particle retention and filtration rate in four species of ascidians. Mar Ecol Prog Ser 1:55–59. https://doi.org/10.3354/meps001055
Ribes M, Coma R, Gili JM (1998) Seasonal variation of in situ feeding rates by the temperate ascidian Halocynthia papillosa. Mar Ecol Prog Ser 175:201–213. https://doi.org/10.3354/meps175201
Riisgård HU, Larsen PS (2010) Particle capture mechanisms in suspension-feeding invertebrates. Mar Ecol Prog Ser 418:255–293. https://doi.org/10.3354/meps08755
Rippey SR (1994) Infectious diseases associated with molluscan shellfish consumption. Clin Microbiol Rev 7(4):419–425. https://doi.org/10.1128/CMR.7.4.419
Sair AI, D'Souza DH, Jaykus LA (2002) Human enteric viruses as causes of foodborne disease. Compr Rev Food Sci Food Saf 1:72–89
Stuart V, Klumpp DW (1984) Evidence for food-resource partitioning by kelp-bed filter feeders. Mar Ecol Prog Ser 16:27–37. https://doi.org/10.3354/meps016027
Timoney JF, Abston A (1984) Accumulation and elimination of Escherichia coli and Salmonella typhimurium by hard clams in an in vitro system. Appl Environ Microbiol 47(5):986–988
U.S. EPA (Environmental Protection Agency) (2001) Method 1601: Male-specific (F+) and Somatic Coliphage in Water by Two-step Enrichment Procedure. EPA 821-R-01-030, US EPA, Washington DC
U.S. FDA (Food and Drug Administration) (2015) National Shellfish Sanitation Program (NSSP), NSSP Guide for the Control of Molluscan Shellfish. http://www.fda.gov/Food/GuidanceRegulation/FederalStateFoodPrograms/ucm2006754.htm. Accessed 20 April 2017
Ueki Y, Shoji M, Suto A, Tanabe T, Okimura Y, Kikuchi Y, Saito N, Sano D, Omura T (2007) Persistence of caliciviruses in artificially contaminated oysters during depuration. Appl Environ Microbiol 73(17):5698–5701. https://doi.org/10.1128/AEM.00290-07
Vaughn CC, Hakenkamp CC (2001) The functional role of burrowing bivalves in freshwater ecosystems. Freshw Biol 46(11):1431–1446. https://doi.org/10.1046/j.1365-2427.2001.00771.x
Yang JH, Mok JS, Jung YJ, Lee KJ, Kwon JY, Park K, Moon SY, Kwon SJ, Ryu AR, Lee TS (2017) Distribution and antimicrobial susceptibility of Vibrio species associated with zooplankton in coastal area of Korea. Mar Pollut Bull. https://doi.org/10.1016/j.marpolbul.2017.07.054
Younger AD, Reese RA (2013) Comparison of Escherichia coli levels between bivalve mollusc species across harvesting sites in England and Wales. J Shellfish Res 32(2):527–532. https://doi.org/10.2983/035.032.0232
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This work was supported by a grant from the National Institute of Fisheries Science in Korea (R2017057).
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Kim, J.H., Shim, K.B., Shin, S.B. et al. Comparison of bioaccumulation and elimination of Escherichia coli and male-specific bacteriophages by ascidians and bivalves. Environ Sci Pollut Res 24, 28268–28276 (2017). https://doi.org/10.1007/s11356-017-0736-1
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DOI: https://doi.org/10.1007/s11356-017-0736-1