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Riverbed Sediments as Reservoirs of Multiple Vibrio cholerae Virulence-Associated Genes: A Potential Trigger for Cholera Outbreaks in Developing Countries.

1. Introduction

Pathogenic strains of Vibrio cholerae, a Gram-negative bacterium, are the causative agents of the dreadful waterborne diarrhoeal disease called cholera [1]. Cholera outbreaks continue to be reported around the world, affecting over 5 million people [2] and killing over 100000 people per year [3]. Africa remains the most cholera stricken continent in the world [4], with the majority of cases and associated mortality being attributed to the lack of sanitary infrastructures and poor economic development [5]. This acute diarrhoeal disease in humans may rapidly lead to grave dehydration and even death if proper medical care, usually through oral rehydration, is not given [6,7].

Vibrio cholerae has been found to survive in numerous aquatic ecosystems like rivers, lakes, streams, and oceans [8-11]. Toxigenic strains of V. cholerae have been found in both the water column and sediments in some of these environments [12,13]. Monitoring of V. cholerae in aquatic environments usually focuses on the isolation of strains carrying the cholera toxin (CT) and toxin coregulated pilus (TCP) genes. Such strains are classified as typical O1 and O139 strains [14]. However, reports on sporadic cholera-like outbreaks have caused increased interest in non-O1 and non-O139 V. cholerae strains [1,12,15-17]. Apart from the CT and TCP genes, several other genes have been reported to synergistically contribute to virulence in O1, O139, and non-O1/O139 V. cholerae. Some of these virulence genes include the outer membrane protein (ompW) gene, toxR regulon, Zonula occludens toxin (zot) gene, pore-forming toxin haemolysin (hlyA), and the heat-stable enterotoxin (stn/sto) gene.

Although found to be species-specific for all V. cholerae [18] including nonpathogenic environmental strains, the ompW gene aids in increasing the adaptability of virulent strains of the organism to different environmental conditions, such as survival against bile salts in the human body [19]. The toxR regulon activates the transcription of the toxT gene, which in turn stimulates the production of proteins that activate several genes involved in virulence of V. cholerae [20]. This gene (toxR) also modulates the expression of the outer membrane proteins OmpU and OmpT [21]. During a cholera infection in mammals, the Zonula occludens toxin (zot) gene helps in increasing the permeability of the small intestine to V. cholerae [22]. It has been reported that V. cholerae uses the pore-forming toxin, haemolysin (hlyA) gene to form devices that punch holes in target eukaryotic cells, causing them to lyse during infection [23]. The stn/sto gene codes for the production of a heat-stable enterotoxin which disrupts fluid intake and causes the accumulation of fluid in the intestine during infection [24].

Between 1973 and 2013, South Africa reported a total of 186463 cholera cases to the World Health Organisation [25]. Over 100000 of the reported cases were in the 2001 epidemics alone, the highest number of cholera infections and deaths the country has ever experienced. Most of the cholera outbreaks in the country have been reported in rural areas without access to adequate water supplies and have been linked to polluted rivers in these areas [26]. Several studies in South Africa have reported on the presence of V. cholerae, including the O1 and O139 strains, in the aquatic environment [27-29]. However, these studies focused on the water column with no attention being paid to sediments. Furthermore, the investigations have focused on the detection of the CT gene and there is little or no information on the presence of other virulence genes, especially in environmental strains. The present study was conducted to investigate the presence of V. cholerae VAGs in water and riverbed sediment samples collected from the Apies River, Gauteng, South Africa. Like in many developing countries where access to safe pipe-borne water remains a challenge, the Apies River is the main source of water, for personal and household hygiene, for many communities in Gauteng. Also, many countries, including South Africa, do not include sediments quality during the monitoring of their water bodies for microbial quality. A recent study in the Apies River demonstrated that the risk of infection associated with exposure to the river could increase under conditions of sediment resuspension [30]. Identification of these virulence genes in the environment, especially in the sediments, could improve the understanding of the possible sources of the V. cholerae strains involved in the cholera epidemics that have affected the country for many years. Also, the detection of the VAGs in the sediments would highlight the need for many countries to include microbial sediment quality monitoring within their national water quality guidelines.

2. Materials and Methods

2.1. Study Site. Water and sediment samples were collected from the Apies River situated in the Province of Gauteng in South Africa. A full description of the river, its tributaries, the sampling sites, and the main land uses have earlier been published [31] (Figure 1).

Briefly, the river has its source in the south of the Gauteng Province and flows northward into the Northwest Province. The portions of the river around the Pretoria CBD (Central Business District) have been canalised due to the development of the area. The portions towards the northern end of the river, as it joins the Pienaars River in the Northwest Province, have not been canalised and thus give easy access to the communities around whose inhabitants use the water for different purposes. As the river flows through rural, urban, and informal settlements around the City of Tshwane, it is used for agricultural (irrigation and animal farms), domestic, and recreational purposes [32]. A major characteristic of the land uses around the river is the presence of four main wastewater treatment works (WWTWs) (Daspoort, Rooiwal, Temba, and Babelegi) that discharge their effluents directly into the river. These WWTWs account for the greatest proportion (over 80%) of the river's total water discharge, especially during the dry winter periods [33].

2.2. Sample Collection. A total of 120 samples (60 water and 60 sediment samples) were collected weekly for six weeks between January and February 2014 from ten sites along the Apies River. Water samples were collected in sterile plastic bottles following standard procedures [34]. Grab sediment samples were scooped from the top 5 cm of the riverbed directly below the point at which water samples were collected and transferred into sterile plastic cups with lids. All samples were transported to the laboratory at 4[degrees]C in a cooler box with ice and analysed within 6 hours from the time of collection. All samples were collected in duplicate.

2.3. Sample Processing and DNA Extraction. Sediment samples were processed as previously described [35]. Fifty millilitres (50 mL) of the supernatant from resuspended sediment samples was added to an equal volume of double strength alkaline peptone water (APW) (Merck, SA). For the water samples, 50 mL of the sample from the sampling bottle was directly mixed with equal volume of the APW [36]. The enrichment step was to promote the growth of V. cholerae (in case where the concentration might be low) [37], thus enhancing the detection of the VAGs. The inoculated APW bottles were then incubated overnight at 37[degrees]C. After incubation, 1 mL of overnight culture was collected from the culture bottles and DNA extracted from the culture using the Instagene[TM] matrix (Bio-Rad, SA) following the manufacturer's instructions. Extracted DNA was stored at -20[degrees] C for use in PCR reactions the following day.

2.4. Identification of Virulence-Associated Genes. The identification ofVAGs from the samples was done on a Corbett Life Science Rotor-Gene 6000 Cycler (Qiagen, Hilden, Germany) using three different PCR sets. Set 1 was for identification of the ompW, ctxAB, zot, and tcpA genes. Set 2 was for the tcpI, hlyA, and toxR genes. The last set was for the stn/sto genes (including the ompW gene as an internal control). The two multiplex PCR sets (1 and 2) were run conventionally while the last set (stn/sto) was run in real-time. This was because the various primers for the multiplex reactions had overlapping melting temperatures and as such could not be separated in a multiplex real-time PCR reaction. The primers used in each reaction and the size of the amplicons are given in Table 1.

A confirmed Vibrio cholerae strain O139 isolated from wastewater in Pretoria was used as positive control for every reaction while a reaction mixture void of template DNA was used as a No Template Control (NTC). The positive control was obtained from the microbiology laboratory of the NRE (Natural Resources and the Environment) at the Council for Scientific and Industrial Research (CSIR), Pretoria, South Africa, after being confirmed to possess the various genes of interest.

The reaction mixture for PCR Set 1 was as follows: 10 [micro]L (final concentration 1x) of 2x SensiFAST[TM] HRM (SF) mix; 0.5 [micro]L (F and R; 0.5 [micro]M final concentration) of each primer for ompW, ctxAB, zot, and tcpA; 1 [micro]L of nuclease free water (NF [H.sub.2]O); and 5 [micro]L of template DNA giving a total reaction volume of 25 [micro]L. For PCR Set 2, the reaction was carried out in a total volume of 25 [micro]L consisting of 2x SF mix: 10 [micro]L (final concentration 1x) and 1 [micro]L (F and R; 1 [micro]M final concentration) of each primer for toxR and hlyA; 2 [micro]L (F and R; 2 [micro]M final concentration) of each primer for tcpI; 2 [micro]L of NF [H.sub.2]O; and 5 [micro]L of template DNA. PCR reaction mixture for Set 3 was made up of 2x SF mix: 10 [micro]L (final concentration 1x) and 1 [micro]L (F and R; 1 [micro]M final concentration) of each primer for stn/sto and ompW; 1 [micro]L of NF [H.sub.2]O; and 5 [micro]L of template DNA for a total reaction volume of 25 [micro]L. The PCR reactions were run under optimised conditions consisting of an initial incubation step at 95[degrees]C for 50 s, followed by a 40-cycle amplification program consisting of 95[degrees] C for 10 s, 55[degrees] C for 15 s, 72[degrees]C for 25 s, and a final extension step at 72[degrees]C for 5 minutes. For PCR Set 3, the final extension was followed by preparation of a melt curve by ramping up the melting temperature from 72[degrees]C to 90[degrees]C at a ramp rate of 0.1[degrees]C at each step, holding for 90 s for premelt on the 1st step, and then holding for 2 s on each of the next steps.

2.5. Gel Electrophoresis. The PCR products from PCR Set 1 and Set 2 were separated by a 2.0% agarose gel electrophoresis supplemented with ethidium bromide as stain and run in a Tris-acetate-EDTA buffer. A GeneRuler[TM] 100 bp (Thermo Fisher Scientific, South Africa) was used as the DNA ladder. Gels were visualised under UV light and images were captured either using a digital camera or using an INGenius Syngene Bio Imaging System (Vacutec, South Africa). Once captured, the gel images were analysed using the GelAnalyzer 2010 software (http://www.gelanalyzer.com/download.html) and stored for subsequent printing.

2.6. Determination of Physicochemical Parameters. All physicochemical parameters were directly measured on-site during sample collection. The dissolved oxygen (DO; mg/L), electrical conductivity (EC; [micro]s/cm), pH, and temperature of the water samples were measured using an HQ40d portable Hach Multiparameter Meter (Hach, USA). Water turbidity was measured in nephelometric turbidity units (NTU) using a Eutech portable T100 turbidity meter (Eutech Instruments, Germany). Prior to being used, each instrument was calibrated using known standards from the respective suppliers.

2.7. Statistical Analysis. For a site to be considered positive for the gene of interest, the duplicate water or sediment samples had to be positive for the PCR assay. The occurrence of VAGs in water and sediments were compared for any statistical difference using a Kruskal Wallis test. The nonparametric Spearman's rank correlation analysis was performed to investigate any relationship between the various VAGs and the physicochemical parameters in both matrices. All tests were performed using SPSS version 20 (Statistical Package for the Social Sciences; IBM Corporation, Armonk, New York, USA) and were considered significant at [alpha] = 0.05.

3. Results

3.1. Distribution of Vibrio cholerae VAGs in Water and Sediments. A total of 60 sediment and 60 water samples were analysed for the presence of Vibrio cholerae VAGs using PCR following enrichment in APW. Optimised conditions for the conventional PCR reactions were verified by running the PCR product on a gel (Figure 1, in Supplementary Material available online at https://doi.org/10.1155/2017/5646480). Figure 2 is a high resolution melt (HRM) curve analysis for real-time PCR Set 3 (Supplementary Material).

Of the 120 samples analysed, 68 (37 sediment and 31 water) samples were positive for the species-specific ompW gene of V. cholerae. Table 2 shows the distribution of the various genes investigated in this study. Overall, the VAGs were more detected in the sediments than in the water column, although this difference was not statistically significant (p = 0.831; p > 0.05). When considered individually, the percentage detection of the ompW gene in the sediment samples was statistically significantly higher (p = 0.000; p < 0.05) than that in the water samples. Contrary to the ompW, the hlyA gene was statistically significantly higher in the water samples (p = 0.012; p < 0.05) compared to the sediment samples. No statistically significant difference was observed between the water and the sediment samples for the detection of the tcpA, toxR, zot, and tcpI genes.

None of the samples analysed, both water and sediments, was positive for the ctx gene typical of O1 and O139 V. cholerae strains. All samples analysed were also negative for the non-O1 heat-stable enterotoxin (stn/sto) genes. The zot gene was only detected in the water column at very low rates (2 out of the 120 samples analysed). The most frequently isolated VAG was the haemolysin gene (31.7% of sediment samples and 50% of water samples).

The VAGs investigated in this study were not evenly distributed amongst the sampling sites. Some genes like the zot gene were only detected in water samples collected at sites DAS and AP2 (Table 3). Sites AP3, AP4, and AP5 recorded the lowest prevalence of the seven virulence genes studied.

3.2. Distribution of Possible Virulent Genotypes in Water and Sediments. Results of the molecular profiling of the 68 V. cholerae positive samples revealed 14 different profiles with one sample being positive for up to five of the seven VAGs investigated (Table 4).

The majority of the samples (30 of the 68 positive samples) revealed a single virulence gene. Of the 30 samples with a unique profile, the most detected genotype was the hlyA (23/30) genotype. The tcpI-tcpA, tcpI-toxR-hlyA, toxR-hlyA-tcpA, and tcpI-toxR-hlyA-zot-tcpA genotypes were only detected once in the entire study. Nine samples were positive for the ompW gene only.

3.3. Water Physicochemical Parameters. The water temperature during the entire sampling period ranged between 20.2[degrees]C and 28.1[degrees]C with mean temperature being 23.7[degrees]C. The DO, pH, EC, and turbidity ranged between 3.4 mg/L and 7 mg/L (mean = 5.5 mg/L), 6.6 and 8.2 (mean = 7.6), 187.8 [micro]s/cm and 654 [micro]s/cm (mean = 406.8 [micro] s/cm), and 7.1 NTU and 213 NTU (mean = 187.8 NTU), respectively.

3.4. Relationships between Occurrence of V. cholerae VAGs and Physicochemical Parameters. Within the water column, none of the genes studied showed a significant correlation with any of the physicochemical parameters measured. However, in the sediments, there was a significant positive correlation between the occurrence of the hlyA gene and temperature (p = 0.002; p < 0.05), the tcpA gene and EC (p = 0.013; p < 0.05), and the toxR gene and EC (p = 0.011; p < 0.05).

4. Discussion

4.1. Distribution of Vibrio cholerae VAGs in Water and Sediments. The main aim of the present study was to investigate the presence of V. cholerae VAGs in environmental samples collected from riverbed sediments of the Apies River. Several studies have shown that V. cholerae is present in many aquatic environments, but only a few have reported on the presence of V. cholerae VAGs within riverbed sediments [41-43]. In many developing countries and Sub-Saharan African countries in particular, information on the presence of V. cholerae strains carrying virulence gene in riverbed sediments is virtually nonexistent. These virulence genes were, however, detected in the sediments of the Apies River, South Africa. The prevalence of virulence-associated V. cholerae genes obtained from the environmental samples in the current study is tied with findings of previous research studies in other parts of the world [12,42,44]. In a study conducted on surface water in different parts of China, Li et al. [12] reported that 95.3% of the 295 non-O1/O139 environmental isolates investigated were positive for the hlyA gene. Ceccarelli and colleagues reported the presence of non-O1/O139 V. cholerae isolates carrying multiple virulence genes in the sediments of the Chesapeake Bay, Maryland, USA [42]. Similarly, Bag et al. investigated 21 isolates from natural surface waters in India and found out that none of the isolates harboured the ctx gene but were all positive for the hly gene [44]. The detection of these VAGs in the absence of the ctx gene in various parts of the world calls for the need to further investigate the dynamics of these non-O1/O139 isolates globally, especially in countries where access to safe drinking water is still a challenge.

The detection of V. cholerae genes in the sediments (and water) of the Apies River could indicate the possibility of faecal pollution within this river catchment. It has previously been demonstrated that the Apies River harboured high numbers of Escherichia coli and Clostridium perfringens, good indicators of recent and long-term faecal pollution [31,32]. The possibility of faecal pollution in the Apies River is further strengthened by the fact that V. cholerae VAGs were not evenly distributed between the sampling sites (Table 4). There are four wastewater treatment works (WWTWs) that discharge directly into the Apies River and their effluent is not usually of good microbial quality [32]. These WWTWs are situated upstream of sampling sites DAS (Daspoort WWTW), AP2 (Rooiwal WWTW), and AP8 (Babelegi and Temba WWTWs). The zot gene, for example, was only detected in the water column of sites DAS and AP2, all characterised by the presence of WWTWs. Other sites are characterised by informal settlements (AP1), agriculture (AP9), or a combination of both (AP7). Open defecation has been demonstrated to contribute to the poor microbial quality of surface water bodies [45-48]. At site AP1, there is a complete lack of sanitary facilities and the river banks and water are the only points for defecation and waste disposal. These sites (AP1, AP2, and AP8) showed the highest prevalence of the various VAGs investigated in this study. Sites that had less human influence (AP3, AP4, and AP5) showed less detection of the VAGs. Considering the fact that this study was conducted between the months of January and February, which are rainy months in South Africa, it could also be possible that the few positive samples for the V. cholerae VAGs identified at sites AP3, AP4, and AP5 were a result of runoff from surrounding areas (neighbouring villages without proper sanitary facilities).

The high detection of V. cholerae VAGs in the sediments of the Apies River also supports the fact that sediments serve as a reservoir of microorganisms where they could be resuspended, thus negatively affecting the microbial quality of the water column [49-52]. Sediments are said to provide a conducive environment for the extended survival of microorganisms, including pathogens in the aquatic ecosystem.

Although it is generally accepted that most environmental strains of V. cholerae are not pathogenic and thus pose no threat to human health, nonpathogenic environmental strains have been shown to evolve and have developed disease-causing potentials once within the human intestine [39]. In the present study, all the samples analysed were negative for the cholera toxin gene (ctxAB), but the presence of other virulence factors indicates the possibility of infection under appropriate conditions. The high prevalence of the haemolysin gene (hlyA) in these environmental samples is tied with findings of Rahman et al. [53] and Ceccarelli et al. [42]. The hlyA gene is responsible for the production of an extracellular protein that causes extensive damage to eukaryotic cells through a hole-punching mechanism that destroys the plasma membrane of these cells [23]. The TCP genes responsible for mediating the production of the toxin coagulated pilus were also identified within the sediment samples in the present study. It has been shown that TCP, the main colonisation determinant in V. cholerae, is the point of attachment of the lysogenic phage CTXip, the genome of which carries genetic information for the production of the cholera toxin [54]. It has been reported that TCP positive but non-O1/non-O139 V. cholerae strains could be intermediates with the potential of conversion to the toxigenic forms through infection by the CTX[phi] phage [55]. This therefore means that, in the presence of this filamentous bacteriophage (CTX[phi]), nontoxigenic but TCP positive environmental stains of V. cholerae could acquire the genes for ctx production. Also, Faruque et al. [55] demonstrated that nontoxigenic strains of V. cholerae with virulence potential caused fluid accumulation within rabbit intestines suggesting that these strains were selectively enriched in the mammalian system. The detection of different possible V. cholerae genotypes with varying virulence genes combinations in this study (Table 4) suggests that sediments of the Apies River could be harbouring V. cholerae strains that may pose a potential threat to those using the waters of the Apies River for diverse purposes.

It should however be noted that the results presented in the current study are on the presence or absence of the VAGs. The enrichment step probably increased sensitivity with respect to the detection of the VAGs. Although the enrichment could have also probably ensured that the VAGs found were most likely carried in viable cells, the actual quantification of the number of cells carrying the genes could not done. This is because the APW would have favoured the multiplication of the organisms and quantitative information derived in this case would give a false impression of a high concentration of the pathogens in the samples, thus affecting the actual risk. Nevertheless, the detection of the VAGs calls for the need to further investigate the actual concentration of V. cholerae within the Apies River in order to determine the actual risk that the populations could be exposed to when they use untreated water from the river.

4.2. Correlation between Environmental Factors and the Occurrence of V. cholerae VAGs. Environmental factors have been found to influence the growth and survival of microorganisms in the aquatic environment. In the present study, only the hlyA, tcpA, and toxR genes were observed to have a significant correlation with at least one of the environmental factors. It has been shown that gene expression in V. cholerae is highly enhanced at temperatures of 25[degrees]C, higher pH of 8.5, high salt, and nutrient contents [56]. In the present study, however, the mean temperature and pH were 23[degrees]C and 7, respectively, which were all lower than those required for optimal expression of virulence genes in V. cholerae as indicated by Bhowmick and colleagues. Sediments are known to contain higher amounts of nutrients than the water column [57]. The higher nutrient concentration may favour longer survival of microorganisms in the sediments compared to the water column. This could explain the higher occurrence of the virulence genes in the sediments than in the water column and their correlation with some of the environmental factors within this matrix. The lack of correlation between most of the VAGs and the environmental parameters in this study could be due to the low variability of the physicochemical parameters as the study was conducted only during a single season. It would therefore be necessary to further study the effect of seasonal variations on the presence of these V. cholerae VAGs in order to better understand the relationship between the physicochemical parameters and the VAGs.

5. Conclusion

Based on the results obtained from the present study, we conclude that sediments of the Apies River harbour many V. cholerae VAGs but not the ctx gene. This could indicate the presence of nontoxigenic V. cholerae strains carrying virulence genes and hence pathogenic potentials. The presence of such strains could represent a hidden public health threat to users of the river, especially in areas where access to safe water for household uses is limited or completely absent. Also, the presence of other VAGs in the absence of the ctx gene of V. cholerae as detected in this study could stimulate further research on the possible triggers of cholera epidemics in most developing countries where toxigenic strains of the bacterium are not endemic. However, given that the present results are based on molecular detection of these VAG, it would not be possible to differentiate between V. cholerae and closely related species like Vibrio mimicus. There is therefore a need for further studies to isolate through culture and fully characterise the various V. cholerae strains present in sediments within South African water bodies. Also, methods such as multilocus sequence analysis (MLSA) would be necessary to obtain high resolution phenotypic differentiation between isolated Vibrio species.

Disclosure

Opinions expressed and conclusions arrived at are those of the authors and are not necessarily attributed to the NRF, the WRC, or TUT.

https://doi.org/10.1155/2017/5646480

Conflicts of Interest

The authors declare that there are no conflicts of interest regarding the publication of this paper.

Acknowledgments

The authors thank the Water Research Commission (WRC), South Africa (WRC Projects K5/2169 and K5/2147), the National Research Foundation (NRF) of South Africa, and the Tshwane University of Technology (TUT) for their generous financial support.

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Akebe Luther King Abia, (1) Eunice Ubomba-Jaswa, (2) and Maggy Ndombo Benteke Momba (3)

(1) AMBIO Environmental Management, Department of Biotechnology, Faculty of Applied and Computer Sciences, Vaal University of Technology, Vanderbijlpark 1900, South Africa

(2) Natural Resources and the Environment, CSIR, P.O. Box 395, Pretoria 0001, South Africa

(3) Department of Environmental, Water and Earth Science, Tshwane University of Technology, Arcadia Campus, 175 Nelson Mandela Drive, Private Bag X 680, Pretoria 0001, South Africa

Correspondence should be addressed to Akebe Luther King Abia; lutherkinga@yahoo.fr

Received 12 December 2016; Accepted 11 May 2017; Published 31 May 2017

Academic Editor: Pam R. Factor-Litvak

Caption: Figure 1: Map of the Apies River showing sampling points and wastewater treatment works (WWTW). Sites AP3, AP4, and AP5 are tributaries to the main river.
Table 1: Primers used for the identification of VAGs of V. cholerae in
water and riverbed sediment samples collected from the Apies River.

Target                                        Amplicon
gene          Primer sequence (5'-3')       size (bp) (a)   Reference

ompW        F: CACCAAGAAGGTGACTTTATTGTG          304          [18]
               R: GAACTTATAACCACCCGCG
ctxAB       F: GCCGGGTTGTGGGAATGCTCCAAG          536          [38]
           R: GCCATACTAATTGCGGCAATCGCATG
Zot          F: TCGCTTAACGATGGCGCGTTTT           947          [39]
             R: AACCCCGTTTCACTTCTACCCA
tcpA        F: CACGATAAGAAAACCGGTCAAGAG          451          [39]
(El Tor)     R: CGAAAGCACCTTCTTTCACGTTG
tcpI         F: TAGCCTTAGTTCTCAGCAGGCA           862          [39]
             R: GGCAATAGTGTCGAGCTCGTTA
hlyA          F: GTGCGTATCAGCCTAGATGA            216          [40]
               R: CCAAGCTCAAAACCTGAAA
toxR         F: CCTTCGATCCCCTAAGCAATAC           779          [39]
             R: AGGGTTAGCAACGATGCGTAAG
Stn/sto     F: TCGCATTTAGCCAAACAGTAGAAA          179          [39]
             R: GCTGGATTGCAACATATTTCGC

(a) bp = base pair.

Table 2: Distribution of V. cholerae virulence genes in the sediments
and water column of the Apies River.

                    Number of positive samples per gene (%)

Sample type           ompW      ctx    tcpA (a)      zot

Sediment (n = 60)   37 (61.7)   0(0)   11 (18.3)    0(0)
Water (n = 60)      31 (51.7)   0(0)   12 (20.0)   2 (3.3)
Total (n = 120)        68        0        23          2

                      Number of positive samples per gene (%)

Sample type           toxR        hlyA        tcpI      stn/sto

Sediment (n = 60)   13 (21.7)   19 (31.7)   13 (21.7)    0(0)
Water (n = 60)      8 (13.3)    30 (50.0)   9 (15.0)     0 (0)
Total (n = 120)        21          49          22          0

(a) Only the El Tor variant of the gene was investigated in this study.

Table 3: Presence/absence of the virulence genes at each of the
sampling sites.

Sample    Sample
type       site   ompW   ctx   tcpA   zot   toxR   hlyA   tcpI   stn/sto

Sediment   DAS     +      -     +      -     +      +      +        -
           AP1     +      -     +      -     +      +      +        -
           AP2     +      -     +      -     +      +      +        -
           AP3     +      -     -      -     -      +      -        -
           AP4     +      -     +      -     -      +      -        -
           AP5     +      -     -      -     -      -      -        -
           AP6     +      -     +      -     +      +      +        -
           AP7     +      -     +      -     -      +      +        -
           AP8     +      -     +      -     +      +      +        -
           AP9     +      -     +      -     +      +      -        -

Water      DAS     +      -     +      +     -      +      +        -
           AP1     +      -     +      -     +      +      +        -
           AP2     +      -     +      +     +      +      +        -
           AP3     +      -     -      -     -      +      -        -
           AP4     +      -     +      -     -      +      +        -
           AP5     +      -     -      -     -      +      -        -
           AP6     +      -     +      -     +      +      +        -
           AP7     +      -     +      -     +      +      +        -
           AP8     +      -     +      -     +      +      +        -
           AP9     +      -     +      -     +      +      +        -

Table 4: Distribution of the possible V. cholerae virulence
genotypes present in water and sediments of the Apies River.

Genotype                        Number of samples

ompW                                    9
ompW-hlyA                              23
ompW-tcpA                               4
ompW-toxR                               3
ompW-tcpI-hlyA                          2
ompW-toxR-hlyA                          6
ompW-hlyA-tcpA                          8
ompW-tcpI-tcpA                          1
ompW-tcpI-toxR-hlyA                     1
ompW-tcpI-hlyA-tcpA                     2
ompW-toxR-hlyA-tcpA                     1
ompW-tcpI-toxR-tcpA                     3
ompW-tcpI-toxR-hlyA-tcpA                4
ompW-tcpI-toxR-hlyA-zot-tcpA            1
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Title Annotation:Research Article
Author:Abia, Akebe Luther King; Ubomba-Jaswa, Eunice; Momba, Maggy Ndombo Benteke
Publication:Journal of Environmental and Public Health
Geographic Code:0DEVE
Date:Jan 1, 2017
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