Comparison of the Tecra VIA kit, Oxoid BCET-RPLA kit and CHO cell culture assay for the detection of Bacillus cereus diarrhoeal enterotoxin

Two commercial serological kits (Oxoid BCET-RPLA and Tecra VIA) and a Chinese hamster ovary (CHO) cell cytotonicity assay for the detection of Bacillus cereus diarrhoeal enterotoxin were compared. Eleven B. cereus strains and one enterotoxigenic B. thuringiensis strain were evaluated. Both kits and the CHO cell assay yielded positive toxin responses for cell-free culture filtrates from eight out of 11 diarrhoeal enterotoxigenic strains. An emetic enterotoxin producing strain was negative with all three assays. Two B. cereus strains were negative using the BCET-RPLA kit, but positive with the Tecra VIA kit and CHO cell assay. The BCET-RPLA indicated significant levels of enterotoxin after samples were boiled, whereas the CHO cell and Tecra assays were negative. Overall, the cell culture assay was the most sensitive. However, the Tecra VIA kit provided similar results and was better suited for the rapid detection of B. cereus diarrhoeal enterotoxin.     

A comparison of ELISA and RPLA for detection of Bacillus cereus diarrhoeal enterotoxin

Fourteen strains of Bacillus cereus isolated from different sources were examined for their ability to produce diarrhoeal enterotoxin by two commercial immunoassay kits (Oxoid BCET-RPLA and Tecra ELISA) and the microslide immunodiffusion assay. One strain that was positive in monkey feedings, as well as a number of other strains isolated from diarrhoeal outbreaks, gave positive results in the ELISA and negative results in the RPLA test systems. When tested in the microslide assay, these strains produced only one antigen which formed a line of identity with the reference toxin. The results of the control toxins provided with the kits substantiated that the two commercial assays did not detect the same antigen. Cultures positive with both assay kits were shown to produce diarrhoeal enterotoxin (by a line of identity) and other antigens in the microslide immunodiffusion assay.     

Diarrhoeal enterotoxin production by strains of Bacillus thuringiensis isolated from commercial Bacillus thuringiensis-based insecticides

Abstract Strains of Bacillus cereus and B. thuringiensis were tested by the Tecra VIA kit for the ability to produce a diarrhoeal enterotoxin. The strains of B. thuringiensis were isolated from commercial B. thuringiensis -based insecticides (Bactimos^TM, DiPel^TM, Florbac^TM FC, Foray^TM 48B, Novodor^TM FC, Turex^TM, VecTobac^TM, XenTari^TM). The production of diarrhoeal enterotoxin varied by a factor of more than 100 among the different strains tested. B. cereus (F4433/73) produced the highest amount of enterotoxin and the B. thuringiensis strain isolated from DiPel^TM the lowest. The products were tested for their content of diarrhoeal enterotoxin and all products, except MVP^TM which does not contain viable B. thuringiensis spores, contained diarrhoeal enterotoxins. The results indicates an potential risk for gastroenteritis outbreak caused by B. thuringiensis .     

Identification and analysis of the antigens detected by two commercial Bacillus cereus diarrheal enterotoxin immunoassay kits.

The usefulness of two commercial immunoassays for the detection of diarrheal enterotoxin of Bacillus cereus is unclear because the identity of the enterotoxin(s) has not been proven and the kits detect different proteins. We found that the Bacillus cereus Enterotoxin-Reversed Passive Latex Agglutination kit (Oxoid) detects the L2 component from hemolysin BL, and the Bacillus Diarrhoeal Enterotoxin Visual Immunoassay (Tecra) detects two apparently nontoxic proteins.     

Cereulide, the emetic toxin of Bacillus cereus, is putatively a product of nonribosomal peptide synthesis

AIMS: To determine if cereulide, the emetic toxin produced by Bacillus cereus, is produced by a nonribosomal peptide synthetase (NRPS). METHODS AND RESULTS: NC Y, an emetic strain of Bacillus cereus, was examined for a NRPS gene using PCR with primers recognizing a fragment of a NRPS gene from the cyanobacterium Microcystis. The amplicon was sequenced and compared with other gene sequences using BLAST analysis, which showed that the amplicon from strain NC Y was similar in sequence to peptide synthetase genes in other micro-organisms, including Bacillus subtilis and B. brevis, while no such sequence was found in the complete genome sequence of a nonemetic strain of B. cereus. Specific PCR primers were then designed and used to screen 40 B. cereus isolates previously implicated in outbreaks of foodborne illness. The isolates were also screened for toxin production using the MTT cell cytotoxicity assay. PCR and MTT assay screening of the B. cereus isolates revealed a high correlation between the presence of the NRPS gene and cereulide production. CONCLUSIONS: The results indicate that cereulide is produced by a NRPS complex. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first study to provide evidence identifying the mechanism of production of cereulide, the emetic toxin of B. cereus. The PCR primers developed in the study allow determination of the potential for cereulide production among isolates of B. cereus.     

The use of Bacillus diarrhoeal enterotoxin (BDE) detection using an ELISA technique in the confirmation of the aetiology of Bacillus-mediated diarrhoea

A commercially available ELISA kit was used for the detection of Bacillus diarrhoeal enterotoxin (BDE) in a variety of foods and faeces. The ability of isolates of Bacillus spp., including Bacillus cereus , to produce BDE in Brain Heart Infusion broth containing 0·1% glucose was also checked by use of the kit. Results show that 29 out of 31 B. cereus isolates were enterotoxigenic. Foods positive for preformed BDE were always contaminated with >10⁵ B. cereus cfu g⁻¹, but not all foods contaminated with large numbers of B. cereus were positive for BDE. Bacillus spp., other than one isolate which closely resembled B. subtilis , were negative for BDE production. Criteria for the confirmation of Bacillus -mediated diarrhoea should now include reports of symptoms and incubation periods consistent with the diarrhoeal form of food-poisoning by Bacillus spp., together with the results of tests for enterotoxigenicity of the Bacillus isolate, and detection of BDE in either the food and/or faeces.     

Toxin gene profiling of enterotoxic and emetic Bacillus cereus

Very different toxins are responsible for the two types of gastrointestinal diseases caused by Bacillus cereus: the diarrhoeal syndrome is linked to nonhemolytic enterotoxin NHE, hemolytic enterotoxin HBL, and cytotoxin K, whereas emesis is caused by the action of the depsipeptide toxin cereulide. The recently identified cereulide synthetase genes permitted development of a molecular assay that targets all toxins known to be involved in food poisoning in a single reaction, using only four different sets of primers. The enterotoxin genes of 49 strains, belonging to different phylogenetic branches of the B. cereus group, were partially sequenced to encompass the molecular diversity of these genes. The sequence alignments illustrated the high molecular polymorphism of B. cereus enterotoxin genes, which is necessary to consider when establishing PCR systems. Primers directed towards the enterotoxin complex genes were located in different CDSs of the corresponding operons to target two toxin genes with one single set of primers. The specificity of the assay was assessed using a panel of B. cereus strains with known toxin profiles and was successfully applied to characterize strains from food and clinical diagnostic labs as well as for the toxin gene profiling of B. cereus isolated from silo tank populations.     

Development of a PCR assay for identification of the Bacillus cereus group species

Aims:  A PCR technique was developed as a reliable and rapid identification method for the Bacillus cereus group species, based on a unique conserved sequence of the motB gene (encoding flagellar motor protein) from B. cereus , Bacillus thuringiensis and Bacillus anthracis .
Methods and Results:  Primer locations were identified against eight strains of the B. cereus group spp. from nucleotide sequences available in the National Centre for Biotechnology Information database. The PCR assay was applied for the identification of 117 strains of the B. cereus group spp. and 19 strains from other microbial species, with special emphasis on foodborne pathogens.
Conclusion:  The designed cross-species primers are group specific and did not react with DNA from other Bacillus and non- Bacillus species either motile or not. The primers system enabled us to detect 10³ CFU of B. cereus cells per millilitre of sample.
Significance and Impact of the Study:  Bacillus cereus group spp. belongs to one of the most prevalent foodborne pathogens. Bacterial growth results in production of different toxins; therefore, consumption of food containing >10⁶ bacteria per gram may result in emetic and diarrhoeal syndromes. A rapid and sensitive bacterial detection method is significant for food safety.     

Identification of emetic toxin producing Bacillus cereus strains by a novel molecular assay

Bacillus cereus causes two types of gastrointestinal diseases: emesis and diarrhea. The emetic type of the disease is attributed to the heat-stable depsipeptide cereulide and symptoms resemble Staphylococcus aureus intoxication, but there is no rapid method available to detect B. cereus strains causing this type of disease. In this study, a polymerase chain reaction (PCR) fragment of unknown function was identified, which was shown to be specific for emetic toxin producing strains of B. cereus. The sequence of this amplicon was determined and a PCR assay was developed on this basis. One hundred B. cereus isolates obtained from different food poisoning outbreaks and diverse food sources from various geographical locations and 29 strains from other species belonging to the B. cereus group were tested by this assay. In addition, 49 non-B. cereus group strains, with special emphasis on food pathogens, were used to show that the assay is specific for emetic toxin producing B. cereus strains. The presented PCR assay is the first molecular tool for the rapid detection of emetic toxin producing B. cereus strains.     

Potential application of a HEp-2 cell assay in the investigation of Bacillus cereus emetic-syndrome food poisoning

Abstract When grown for 15 h in rice culture, 13 out of 15 Bacillus cereus strains associated with emetic-syndrome food poisoning (87%) caused vacuoles to appear in HEp-2 cells, compared with 5 out of 11 B. cereus strains from other sources (45%). No other Bacillus species tested gave rise to this response under these conditions. Six out of eight rice samples involved in incidents of B. cereus emetic illness produced vacuoles in HEp-2 cells, whereas control rice samples and foods from vomiting episodes caused by other Bacillus spp. failed to do so. This vacuole response may have application as a simple in vitro assay for organisms and foods implicated in B. cereus emetic-syndrome food poisoning.     

Production of diarrheal enterotoxins and other potential virulence factors by veterinary isolates of bacillus species associated with nongastrointestinal infections

With the exceptions of Bacillus cereus and Bacillus anthracis, Bacillus species are generally perceived to be inconsequential. However, the relevance of other Bacillus species as food poisoning organisms and etiological agents in nongastrointestinal infections is being increasingly recognized. Eleven Bacillus species isolated from veterinary samples associated with severe nongastrointestinal infections were assessed for the presence and expression of diarrheagenic enterotoxins and other potential virulence factors. PCR studies revealed the presence of DNA sequences encoding hemolysin BL (HBL) enterotoxin complex and B. cereus enterotoxin T (BceT) in five B. cereus strains and in Bacillus coagulans NB11. Enterotoxin HBL was also harbored by Bacillus polymyxa NB6. After 18 h of growth in brain heart infusion broth, all seven Bacillus isolates carrying genes encoding enterotoxin HBL produced this toxin. Cell-free supernatant fluids from all 11 Bacillus isolates demonstrated cytotoxicity toward human HEp-2 cells; only one Bacillus licheniformis strain adhered to this test cell line, and none of the Bacillus isolates were invasive. This study constitutes the first demonstration that Bacillus spp. associated with serious nongastrointestinal infections in animals may harbor and express diarrheagenic enterotoxins traditionally linked to toxigenic B. cereus.     

From soil to gut: Bacillus cereus and its food poisoning toxins

Bacillus cereus is widespread in nature and frequently isolated from soil and growing plants, but it is also well adapted for growth in the intestinal tract of insects and mammals. From these habitats it is easily spread to foods, where it may cause an emetic or a diarrhoeal type of food-associated illness that is becoming increasingly important in the industrialized world. The emetic disease is a food intoxication caused by cereulide, a small ring-formed dodecadepsipeptide. Similar to the virulence determinants that distinguish Bacillus thuringiensis and Bacillus anthracis from B. cereus, the genetic determinants of cereulide are plasmid-borne. The diarrhoeal syndrome of B. cereus is an infection caused by vegetative cells, ingested as viable cells or spores, thought to produce protein enterotoxins in the small intestine. Three pore-forming cytotoxins have been associated with diarrhoeal disease: haemolysin BL (Hbl), nonhaemolytic enterotoxin (Nhe) and cytotoxin K. Hbl and Nhe are homologous three-component toxins, which appear to be related to the monooligomeric toxin cytolysin A found in Escherichia coli. This review will focus on the toxins associated with foodborne diseases frequently caused by B. cereus. The disease characteristics are described, and recent findings regarding the associated toxins are discussed, as well as the present knowledge on virulence regulation.     

Psychrotolerant species from the Bacillus cereus group are not necessarily Bacillus weihenstephanensis

Twenty-six strains of Bacillus cereus from different sources were determined to be either mesophilic or psychrotrophic by growth at 6 and 42 degrees C. The strains were also screened by two polymerase chain reaction (PCR) methods designed to discriminate between mesophilic and psychrotrophic types. Seventeen of the 26 strains were able to grow at 6 degrees C, but only four conformed to the new psychrotolerant species Bacillus weihenstephanensis. Among the 26 strains were two which caused outbreaks of food poisoning in Norway, and three others that were isolated from food suspected of causing illness. The presence of the gene components encoding production of enterotoxins Nhe, Hbl, EntT and a recently described cytotoxin K was determined by PCR. All the strains possessed genes for at least one of these toxins, and 19 of the 26 strains were cytotoxic in a Vero cell assay. We conclude that there are psychrotrophic B. cereus strains which cannot be classified as B. weihenstephanensis, and that intermediate forms between the two species exist. No correlation between cytotoxicity and the growth temperature of the strains was found.     

Putative virulence factor expression by clinical and food isolates of Bacillus spp. after growth in reconstituted infant milk formulae

Forty-seven strains representing 14 different Bacillus species isolated from clinical and food samples were grown in reconstituted infant milk formulae (IMF) and subsequently assessed for adherence to, invasion of, and cytotoxicity toward HEp-2 and Caco-2 cells. Cell-free supernatant fluids from 38 strains (81%) were shown to be cytotoxic, 43 strains (91%) adhered to the test cell lines, and 23 strains (49%) demonstrated various levels of invasion. Of the 21 Bacillus cereus strains examined, 5 (24%) were invasive. A larger percentage of clinically derived Bacillus species (20%) than of similar species tested from the food environment were invasive. Increased invasion occurred after growth of selected Bacillus species in reconstituted IMF containing glucose. While PCR primer studies revealed that many different Bacillus species contained DNA sequences encoding the hemolysin BL (HBL) enterotoxin complex and B. cereus enterotoxin T, not all of these isolates expressed these diarrheagenic genes after growth in reconstituted IMF. Of the 47 Bacillus isolates examined, 3 isolates of B. cereus and 1 isolate of B. subtilis produced the HBL enterotoxin after 18 h of growth in brain heart infusion broth. However, eight isolates belonging to the species B. cereus, B. licheniformis, B. circulans, and B. megaterium were found to produce this enterotoxin after growth in reconstituted IMF when assessed with the B. cereus enterotoxin (diarrheal type) reversed passive latex agglutination (RPLA) kit. It is concluded that several Bacillus species occurring occasionally in clinical specimens and food samples are of potential medical significance due to the expression of putative virulence factors.     

Detection of toxigenic strains of Bacillus cereus and other Bacillus spp. with an improved cytotoxicity assay

An improved qualitative cell cytotoxicity assay for the detection of Bacillus cereus emetic and enterotoxin is described. The presence of toxin in culture supernatant fluids was detected by measurement with the tetrazolium salt MTT, as it adversely affects the metabolic status of cultured CHO cells. Psychrotrophic B. cereus isolates (65) were assessed for toxin production using the cytotoxicity assay, and 91% of culture supernatant fluids were cytotoxic. Toxin assessment using BCET-RPLA and ELISA immunoassays indicated that 51% and 85% of the cultures, respectively, were toxigenic. There were pronounced strain differences in the amount of toxin produced by the B. cereus isolates. Some isolates of B. circulans, B. laterosporus/cereus, B. lentus, B. licheniformis, B. mycoides, B. subtilis and B. thuringiensis were also toxigenic.     

Using an insect model to assess correlation between temperature and virulence in Bacillus weihenstephanensis and Bacillus cereus

The closely related bacterial species Bacillus cereus and Bacillus weihenstephanensis are adapted to the mesophilic and the psychrotrophic temperature range, respectively. While B. cereus strains are associated with foodborne diseases, B. weihenstephanensis strains are so far not, although similar virulence genes are found in both species. Our investigations show that both species were virulent in the insect model, Galleria mellonella, following infection via oral and haemocoel routes. However, virulence of B. weihenstephanensis was much higher at 15°C than at 37°C. Furthermore, a temperature-dependent difference between the species was seen in a cell culture cytotoxicity assay. In summary, our results demonstrate for the first time virulence of B. weihenstephanensis strains in an in vivo model. In addition, we found that G. mellonella is a useful model for studies of the psychrotolerant species of the B. cereus group, suggesting that insects might be an ecological growth niche for several members of this bacterial group.     

An improved method for detecting cytostatic toxin (emetic toxin) of Bacillus cereus and its application to food samples

Abstract We developed an improved HEp-2 cell assay method for the detection of Bacillus cereus toxin, which affects the proliferation of HEp-2 cells. The cytostatic toxin was stable upon exposure to heat, pH 2, pH 11 and trypsin, which suggests it is an emetic. Using the HEp-2 cell assay, we examined the distribution and contamination of B. cereus strains that produced an emetic toxin in various foods. Although there were 228 enterotoxin producers among 310 B. cereus strains obtained from foods, 16 of them produced the cytostatic type (emetic toxin). All of the strains that produced the cytostatic toxin were of the H.1 serotype.     

Development of real-time PCR assays for detection and quantification of Bacillus cereus group species: differentiation of B. weihenstephanensis and rhizoid B. pseudomycoides isolates from milk

Quantitative real-time PCR (qRT-PCR) offers an alternative method for the detection of bacterial contamination in food. This method provides the quantitation and determination of the number of gene copies. In our study, we established an RT-PCR assay using the LightCycler system to detect and quantify the Bacillus cereus group species, which includes B. cereus, B. anthracis, B. thuringiensis, B. weihenstephanensis, B. mycoides, and B. pseudomycoides. A TaqMan assay was designed to detect a 285-bp fragment of the motB gene encoding the flagellar motor protein, which was specific for the detection of the B. cereus group species, excluding B. pseudomycoides, and the detection of a 217-bp gene fragment of a hypothetical protein specific only for B. pseudomycoides strains. Based on three hydrolysis probes (MotB-FAM-1, MotB-FAM-2, and Bpm-FAM-1), it was possible to differentiate B. weihenstephanensis from the B. cereus group species with nonrhizoid growth and B. pseudomycoides from the whole B. cereus group. The specificity of the assay was confirmed with 119 strains belonging to the Bacillus cereus group species and was performed against 27 other Bacillus and non-Bacillus bacteria. A detection limit was determined for each assay. The assays performed well not only with purified DNA but also with DNA extracted from milk samples artificially contaminated with bacteria that belong to the B. cereus group species. This technique represents an alternative approach to traditional culture methods for the differentiation of B. cereus group species and differentiates B. weihenstephanensis and B. pseudomycoides in one reaction.     

普洱茶中微生物的筛选及其安全性初步评价

目的在对普洱茶中微生物筛选和鉴定基础上对蜡样芽胞杆菌毒素基因的分布、普洱茶下调毒素基因的表达和改善肠上皮细胞的损伤进行研究。方法分别采用无菌水和沸水泡制普洱茶,获得分离株,通过16SrDNA测序以及生理生化试验确定其归属;对所筛选的菌株进行耐模拟胃肠液能力评价和毒力基因的检测;采用细胞实验和荧光定量PCR技术,研究普洱茶对蜡样芽胞杆菌毒素的抑制作用。结果无菌水浸泡普洱茶获得的45株菌中44株为芽胞杆菌属,沸水浸泡获得的7株菌均为蜡样芽胞杆菌(FBCE01、FBCE06、FBCE10、FBCE14、FBCE20、FBCE26和FBCE29),多重PCR技术结果表明其分别含有毒力基因cytK、nheA和hblD的2种或3种。耐模拟胃肠液实验表明,7株菌均具有很强的耐模拟胃肠液消化能力;细胞实验结果发现,普洱茶汤能显著降低蜡样芽胞杆菌对Caco-2细胞的粘附(P0.05);MTT实验结果显示,普洱茶能有效降低蜡样芽胞杆菌对细胞的损伤;荧光定量PCR技术结果进一步说明,普洱茶使蜡样芽胞杆菌肠毒素的mRNA表达水平下调。结论普洱茶具有抑制蜡样芽胞杆菌毒素的作用。