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Screening for enterotoxigenic Bacteroides fragilis in stool samples
Accepted Manuscript Screening for enterotoxigenic Bacteroides fragilis in stool samples Jacqueline I. Keenan, Alan Aitchison, Rachel V. Purcell, Rosie Greenlees, John F. Pearson, Frank A. Frizelle PII:
S1075-9964(16)30057-9
DOI:
10.1016/j.anaerobe.2016.05.004
Reference:
YANAE 1576
To appear in:
Anaerobe
Received Date: 3 March 2016 Revised Date:
21 April 2016
Accepted Date: 6 May 2016
Please cite this article as: Keenan JI, Aitchison A, Purcell RV, Greenlees R, Pearson JF, Frizelle FA, Screening for enterotoxigenic Bacteroides fragilis in stool samples, Anaerobe (2016), doi: 10.1016/ j.anaerobe.2016.05.004. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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Screening for enterotoxigenic Bacteroides fragilis in stool samples
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Jacqueline I Keenana,#, Alan Aitchisona, Rachel V Purcella, Rosie Greenleesb, John F
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Pearsonc, & Frank A Frizellea.
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Microbiology Department , Canterbury Health Laboratories, Christchurch, New Zealand
Biostatistics and Computational Biology Unit, University of Otago Christchurch,
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Department of Surgery, University of Otago Christchurch, Christchurch, New Zealand
Christchurch, New Zealand
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Dr Jacqui Keenan, [email protected], Tel +64 3 3640 570; Fax +64 3 3641 427
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Key words: enterotoxigenic Bacteroides fragilis, colorectal cancer, bft gene, PCR, stool
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samples
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Abstract
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Bacteroides fragilis is a commensal bacterium found in the gut of most humans, however
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enterotoxigenic B.fragilis strains (ETBF) have been associated with diarrhoea and colorectal
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cancer (CRC). The purpose of this study was to establish a method of screening for the
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Bacteroides fragilis toxin (bft) gene in stool samples, as a means of determining if carriage of
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ETBF is detected more often in CRC patients than in age-matched healthy controls. Stool
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samples from 71 patients recently diagnosed with CRC, and 71 age-matched controls, were
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screened by standard and quantitative PCR using primers specific for the detection of the bft
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gene. Bacterial template DNA from stool samples was prepared by two methods: a sweep,
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where all colonies growing on Bacteroides Bile Esculin agar following stool culture for 48 h
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at 37°C in an anaerobic environment were swept into sterile water and heat treated; and a
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direct DNA extraction from each stool sample. The bft gene was detected more frequently
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from DNA isolated from bacterial sweeps than from matched direct DNA extractions. qPCR
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was found to be more sensitive than standard PCR in detecting bft. The cumulative total of
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positive qPCR assays from both sample types revealed that 19 of the CRC patients had
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evidence of the toxin gene in their stool sample (27%), compared to seven of the age-matched
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controls (10%). This difference was significant (P = 0.016). Overall, ETBF carriage was
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detected more often in CRC patient stool samples compared to controls, but disparate
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findings from the different DNA preparations and testing methods suggests that poor
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sensitivity may limit molecular detection of ETBF in stool samples.
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Introduction
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Bacteroides fragilis are anaerobic gram negative bacteria commonly found as part of the
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human faecal microbiota. Infection most likely occurs in early childhood, and the inherent
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ability of B. fragilis to evade the host immune response suggests that colonisation may persist
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for life [1]. Whereas carriage of non-enterotoxigenic strains of B. fragilis may promote
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mucosal health [2], some strains produce a toxin that is identified as causative agent of human
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diarrhoea [3]. Colonic carriage of toxin-producing strains is also reportedly more prevalent in
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people presenting with colorectal cancer (CRC) compared to healthy controls [4-6], fuelling
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speculation that persistent carriage of these bacteria may “drive” colon carcinogenesis [7].
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CRC rates of 37.3 per 100,000 New Zealanders are amongst the highest in the world [8]. Our
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aim was to establish a method for screening stool samples for evidence of the B. fragilis toxin
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(bft) gene, as a first step in determining if this potential marker of colon carcinogenesis is
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detected more frequently in stool of CRC patients than in age-matched healthy controls. This
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approach involved the processing of stool samples by two different methods: culture-based
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amplification [9, 10] and direction extraction [11, 12], and testing each of these samples by
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standard and quantitative PCR (qPCR).
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Materials & Methods
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Study Participants. Seventy-one individuals, diagnosed with CRC between 2012 and 2014,
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using standard endoscopic, histological or radiological criteria, provided a stool sample prior
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to chemo-radiation and/or surgery. Patients found to have had pre-operative chemo-radiation
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therapy or those with adenomas were not included in the study. Seventy-one stool samples
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from a cohort of 125 collected from healthy volunteers who self-reported no evidence of
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bowel problems at the time of sampling were age-matched to the 71 patients (Table 1). The
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study was approved by the Upper South A Regional Ethics Committee of New Zealand, and
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all participants provided written informed consent.
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Sample preparation. Each stool was processed by two different methods. The first was
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culture-based amplification, where a loopful of sample was plated onto Bacteroides Bile
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Esculin (BBE) agar (Fort Richard Laboratories, Auckland, NZ), a selective medium for
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Bacteroides [13]. After 48 h anaerobic incubation at 37°C, all colonies were swept off the
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plate into 500 µl of sterile water and heated for 10 min at 99°C. These “sweeps” were kept
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frozen at -20°C until PCR was performed. The second method involved extraction of DNA
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directly from 100 mg of each stool sample using a commercially available kit (Dynabeads
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DNA DIRECTTM Universal extraction kit, Life Technologie AS, Oslo, Norway). This
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“extract” was diluted 100-fold to reduce any inhibitory factors [9]. Extracts were also kept
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frozen at -20°C.
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Standard PCR analysis of bacterial DNA. Each sample was screened for evidence of the bft
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gene using a previously published primer set [14]. Briefly, each 10 µl PCR reaction mixture
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contained 5 pmol of each primer, 200 nM dNTPs, 2 mM MgCl2, 1x enzyme buffer, 0.5 U 4
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HotFire Polymerase (Solis Biodyne, Tartu, Estonia), and 0.5 µl DNA template. The PCR
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amplification program consisted of a 15 minute incubation at 95°C, followed by 35 cycles of
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30 sec denaturation at 95°C, 30 sec annealing at 66°C, and 30 sec extension at 72°C, followed
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by a final extension step of 2 min at 72°C. DNA from ETBF strain VPI 13784 was used as a
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positive bft control. We have previously shown that the primer set used will detect all three bft
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subtypes [15]. Products were visualised on a 1.5% agarose gel containing SYBRSafe
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(Invitrogen, Carlsbad, CA, USA).
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Quantitative PCR. Quantitative real-time polymerase chain reaction (qPCR) was carried out
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to quantify levels of ETBF in stool samples using the LightCycler®480 thermocycler (Roche
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Diagnostics, Indianapolis, IN, USA) using SYBR-green chemistry. Each 10 µl reaction
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consisted of 25–35 ng of genomic DNA, 0.5 µM of each primer pair (Odamaki primers, Table
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1), 5 µl of SYBR Green Master Mix (Roche Diagnostics), and 1.5 µl of water. Thermal
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cycling conditions were as follows: 1 cycle of 95°C for 5 mins, followed by 60 cycles of 95°C
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for 10 secs, 66°C for 10 secs and 72°C for 20 secs. Melting curves were obtained by heating
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samples from 65°C to 97°C in increments of 0.11 °C/s with 5 acquisitions per °C. It was
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assumed that each ETBF contained a single copy of the bft gene. The concentration of ETBF
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was expressed as genome copy numbers by calculating the weight of one ETBF genome, as
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described by Dolezel et al [16]. ETBF has an estimated genome size of 5.2 Mb, and a single
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ETBF genome weighs approximately 5.32 fg (5.2 Mb/978Mb [one picogram of double
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stranded DNA] = 0.00532 pg). Therefore, 1 ng of ETBF DNA contains approximately 187,970
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copies of the genome (1000 pg/0.00532 pg). A standard curve was constructed by serially
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diluting DNA of known concentration, extracted from purified ETBF (strain VPI 13784).
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Concentrations of ETBF in stool samples were calculated using the standard curve following
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amplification of bft.
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Reference strains. Three ETBF reference strains containing the three Bft subtypes (VPI
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13784 [Bft-1] [17], 86-5443-2-2 [Bft-2] [18], and Korea 570 [Bft-3] [19] were generously
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supplied by Professor Cynthia Sears, Baltimore, USA. DNA was extracted from colonies
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following anaerobic culture of each strain on sheep blood agar (Fort Richard Laboratories).
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Preparation of spiked faecal samples for PCR analysis. Serial ten-fold dilutions of a
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suspension of toxigenic B. fragilis strain 86-5443-2-2, containing approximately 1 x 109
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CFU/ml, were added to pre-weighed stool samples from two healthy volunteers negative for
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carriage of ETBF. Standard and quantitative PCR was performed on DNA (sweeps and
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extracts) from each spiked sample to assess the sensitivity of the assays.
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Statistical analysis. Sample counts were compared with Fisher’s exact test with odds-ratio
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and 95% confidence intervals estimated by unconditional maximum likelihood. Logistic
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regression including covariates for age (continuous in years) and gender (dichotomous) was
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used to produce age and gender adjusted P-values for sample counts. All tests were two-sided
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with a type II error rate of 0.05. Analysis was performed in R version 3.2.1 (Vienna, Austria).
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Results
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Incidence of bft gene in stool samples analysed by standard PCR. Stool samples from 71
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patients recently diagnosed with CRC, and 71 age-matched controls were screened using
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primers specific for the detection of the B. fragilis toxin (bft) gene in both bacterial sweeps and
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direct DNA extractions. Standard PCR revealed that sweeps yielded more positive PCR results
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(16/142 (11%)) than DNA extracted from stool samples (11/142 (8%)), indicating that the
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sweep method is more sensitive (Table 2). This was confirmed by assaying serial dilutions of
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stool samples spiked with ETBF. The threshold of detection was approximately 1 x 105 CFUs
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per gram of stool when DNA was directly extracted from the stool. In contrast, the threshold
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for DNA extracted from cultures grown from spiked stool was 1 x 104 CFUs per gram of stool.
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More positive PCR results (11/71) were detected from bacterial sweeps of CRC patient
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samples than from sweeps of age-matched controls (5/71) (16% vs 7%; P > 0.05). Ten CRC
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patients were also found to be positive for the bft gene when the stool DNA extract was tested.
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However, notably fewer positive samples were detected in the control group using this method
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(1/71), which resulted in a significant difference between the number of positive patient and
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control samples using this method of sample preparation (P = 0.046) (Table 2).
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Only seven patient samples tested positive by both methods of sample preparation. Bacterial
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sweeps from four patients were found to be positive while the corresponding extract was
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negative, while three stool samples had evidence of the bft gene in DNA extract only, as
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illustrated by Figure 1. The cumulative total of positive PCR assays from both sample types
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was used to determine the presence of the bft gene in the two patient cohorts. We found that 14
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of the individuals in the CRC group had evidence of the toxin gene in their stool sample
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(20%), compared to five of the age-matched controls (7%). This difference was significant (P
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= 0.046). Logistic regression analysis showed that age and gender did not materially affect the
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results.
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Incidence of bft gene in stool samples analysed by qPCR. Both DNA samples from each
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individual’s stool (bacterial sweep and Dynabead extraction) were then screened for evidence
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of bft using qPCR. The bacterial sweeps yielded a total of 22 positives compared to the 16
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positive samples detected by standard PCR, whereas 19 and 11 of the 142 extracts were
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positive by quantitative and standard PCR, respectively. The increased sensitivity of qPCR
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was confirmed by analysis of DNA extracted directly from serial dilutions of spiked stool
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samples. The threshold for detecting bft from DNA extracted from cultures grown from spiked
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stool was approximately 1 x 101 CFUs per gram of stool; a higher detection threshold was
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observed when DNA was extracted directly from the same samples using Dynabead
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technology (approximately 1 x 102 CFUs per gram of stool). However, despite the increased
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sensitivity of qPCR, this assay did not detect the bft gene significantly more often in individual
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samples when compared to standard PCR (P > 0.05).
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All of the patients that tested positive for bft in either sample by standard PCR also tested
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positive using qPCR. A further seven samples, negative by standard PCR, were additionally
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detected using qPCR. Five of the seven samples were from CRC patients; the other two were
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from age-matched controls (Table 2). Of note, all of these seven samples were detected
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between 35 cycles and the 45 cycle cut-off, which was set to minimise the detection of non-
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specific products; this is consistent with low abundance of bft in these samples. Interestingly,
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six of the seven samples that tested positive by quantitative but not standard PCR were
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bacterial sweeps generated following stool culture on selective media. These additional seven
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samples were confirmed as true positives by sequencing of the qPCR product.
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However, while qPCR detected bft in all the patients/controls positive for bft by standard PCR,
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a comparison of standard and qPCR findings on individual samples rather than per patient
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revealed again the results were not consistent. Of the 11 CRC patient samples where bft was
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detected in the sweeps by standard PCR, only ten were positive by qPCR. Likewise, qPCR
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failed to detect bft in an extracted patient sample that was positive by standard PCR. These
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results suggest sampling error due to low abundance of the target DNA in the samples.
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Accordingly, the cumulative total of positive qPCR assays from both sample types was used to
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determine the presence of the bft gene in patient and age-matched control cohorts. Nineteen of
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the individuals in the CRC group had evidence of the toxin gene in their stool sample (27%),
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compared to seven of the age-matched controls (10%). This difference was significant (P =
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0.016). Logistic regression analysis showed that age and gender did not materially affect the
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results (Table 2).
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ETBF genome copy number in stool samples analysed by qPCR. The generation of a
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standard curve using DNA from a reference strain of ETBF allowed us to determine the copy
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number of ETBF genomes in DNA samples using qPCR. The copy number ranged from
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0.0005 to 32000 among bft-positive samples. There was no difference in relative abundance
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between CRC samples (1955 ± 977) and controls (1706 ± 1193), or between sweep samples
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and DNA extracts (2121 ± 1681 and 1305 ± 384, respectively).
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Discussion
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There is a growing awareness that certain species of gut bacteria may drive toxin- and/or
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inflammation-mediated colorectal carcinogenesis [20]. We have been collecting evidence of a
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significant association between long-term colonic carriage of ETBF and risk of low-grade
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colonic dysplasia in our community. This led us to evaluate two methods for use as faecal
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diagnostic tests for ETBF in individuals considered at risk of developing CRC.
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Culture-based amplification was shown to provide greater sensitivity for ETBF detection than
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DNA extracted directly from stool by using spiked stool samples, as reported elsewhere [9,
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10]. Accordingly, selective enrichment of stool samples resulted in a slight increase in the
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number of bft-positive samples compared to screening of DNA extracted directly from the
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stool, suggesting an increase in the relative abundance of ETBF, if present. In this study solid
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media was used to enrich for Bacteroides spp in the stool samples whereas a recent study
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described the use of a defined broth culture medium [10]; either approach would likely serve
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the same purpose.
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Screening of stool DNA for bft using standard PCR methods showed a significant difference
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between patient and control groups (P = 0.046). However, the detection rates of bft found in
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the New Zealand patients were notably lower than those in the only other study to describe
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increased incidence of ETBF in CRC patient stool samples [4]. To investigate whether the use
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of standard PCR was responsible for under-reporting of bft-positivity in our study, the samples
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were re-screened using a SYBR green qPCR assay with the same primers. This method was
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shown to detect a signal at higher dilutions of spiked samples when compared to standard
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PCR, similar to the TaqMan assay for ETBF recently described by Chen et al. [10]. Culture-
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based amplification of ETBF served to further increase qPCR sensitivity: the number of CRC
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samples with evidence of ETBF carriage increased from 14 (20%) to 19 (27%), and two
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further age-matched controls were found to be positive (from five (7%) to seven patients
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(10%). The difference in detection rates between the groups was significantly different (P =
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0.016) but still notably lower than that reported in Turkish patients [4].
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Toprak and colleagues also used a culture-based system but instead used PCR to analyse
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single colonies that were identified as B. fragilis by conventional methods [4]. Thus, the
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differences between the two studies may reflect methodological as well as geographical
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variation, particularly if the relative abundance of ETBF in samples is low. This is highlighted
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by the finding that six of the seven stool samples in our study, positive for bft only by qPCR,
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were sweep samples. This suggests a very low abundance of ETBF that was undetectable in
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DNA extracted directly from stool samples. The viable cell number of B. fragilis in faecal
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samples is reportedly 10- to 100-fold lower than other intestinal Bacteroides [21] and these
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bacteria account for a very small proportion of the normal colonic microflora (0.1%-0.5%)
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[22]; culturing of samples on selective media may have allowed ETBF to grow to numbers
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detectable in subsequent qPCR.
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In conclusion, this study aimed to determine if molecular screening of stool samples using bft
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as a marker would detect ETBF more often in stool of CRC patients than in age-matched
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healthy controls. Our results support the concept that ETBF may act to promote colon
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carcinogenesis [20]. However, we stress that care needs to be taken with assay design and
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interpretation following the observation of disparate findings in some stool samples where
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DNA was prepared by different processes and/or tested by different methods. We conclude
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that using qPCR with a combination of culture-based amplification and direct extraction is
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likely to increase sensitivity.
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Conflict of interest declaration
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The authors declare that they have no conflict of interest.
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Acknowledgements
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This study was funded by grants from Genesis Oncology Trust NZ and the Rotary Club of
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Christchurch Sunrise.
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Figure legend
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Figure 1. B. fragilis toxin PCR amplification from patient stool samples using both DNA
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extracted directly from stool (top row) and sweeps of bacteria cultured on BBE agar (bottom
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row). Discrepancies between the two DNA preparations can be seen for samples 203 and 277.
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DNA from ETBF strain VPI 13784 and water were used as positive and negative PCR controls
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respectively.
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Tables
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Table 1. Characteristics of CRC patients and controls
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Age median (10%, 90%)
CRC
Control
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71
72 (53,81)
64 (53, 80)
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Female
29 (41%)
39 (55%)
Male
42 (59%)
32 (45%)
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CRC, colorectal cancer; n, number of patients
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Table 2. Patient and control bft status by standard and qPCR
353 Extract (%)
11 (16)
10 (14)
Controls
5 (7)
1 (1)
P-value
0.183
0.005*
0.046*
P-value (adj)
0.112
0.023*
0.030*
bft qPCR CRC patients
15 (21)
Controls
7 (10)
P-value
0.103
P-value (adj)
0.098
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bft standard PCR
Total (%)
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Sweep (%)
14 (20) 5 (7)
14 (20)
19 (27)
5 (7)
7 (10)
0.046*
0.016*
0.024*
0.015*
CRC, colorectal cancer; BFT, Bacteroides fragilis toxin; PCR, polymerase chain reaction; qPCR,
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quantitative PCR; P-value (adj) adjusted for age and gender; * P-value < 0.05.
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ACCEPTED MANUSCRIPT Highlights Molecular identification of enterotoxigenic B. fragilis (ETBF) in stool samples.
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Comparison of different methods of DNA preparation and ETBF amplification.
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Selective enrichment of Bacteroides increases identification of ETBF.
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Quantitative PCR increases sensitivity over conventional PCR.
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Use of multiple methods offers greatest detection rates.
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S1075-9964(16)30057-9
DOI:
10.1016/j.anaerobe.2016.05.004
Reference:
YANAE 1576
To appear in:
Anaerobe
Received Date: 3 March 2016 Revised Date:
21 April 2016
Accepted Date: 6 May 2016
Please cite this article as: Keenan JI, Aitchison A, Purcell RV, Greenlees R, Pearson JF, Frizelle FA, Screening for enterotoxigenic Bacteroides fragilis in stool samples, Anaerobe (2016), doi: 10.1016/ j.anaerobe.2016.05.004. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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Screening for enterotoxigenic Bacteroides fragilis in stool samples
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Jacqueline I Keenana,#, Alan Aitchisona, Rachel V Purcella, Rosie Greenleesb, John F
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Pearsonc, & Frank A Frizellea.
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Microbiology Department , Canterbury Health Laboratories, Christchurch, New Zealand
Biostatistics and Computational Biology Unit, University of Otago Christchurch,
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Department of Surgery, University of Otago Christchurch, Christchurch, New Zealand
Christchurch, New Zealand
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Dr Jacqui Keenan, [email protected], Tel +64 3 3640 570; Fax +64 3 3641 427
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Key words: enterotoxigenic Bacteroides fragilis, colorectal cancer, bft gene, PCR, stool
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samples
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Abstract
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Bacteroides fragilis is a commensal bacterium found in the gut of most humans, however
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enterotoxigenic B.fragilis strains (ETBF) have been associated with diarrhoea and colorectal
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cancer (CRC). The purpose of this study was to establish a method of screening for the
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Bacteroides fragilis toxin (bft) gene in stool samples, as a means of determining if carriage of
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ETBF is detected more often in CRC patients than in age-matched healthy controls. Stool
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samples from 71 patients recently diagnosed with CRC, and 71 age-matched controls, were
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screened by standard and quantitative PCR using primers specific for the detection of the bft
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gene. Bacterial template DNA from stool samples was prepared by two methods: a sweep,
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where all colonies growing on Bacteroides Bile Esculin agar following stool culture for 48 h
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at 37°C in an anaerobic environment were swept into sterile water and heat treated; and a
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direct DNA extraction from each stool sample. The bft gene was detected more frequently
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from DNA isolated from bacterial sweeps than from matched direct DNA extractions. qPCR
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was found to be more sensitive than standard PCR in detecting bft. The cumulative total of
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positive qPCR assays from both sample types revealed that 19 of the CRC patients had
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evidence of the toxin gene in their stool sample (27%), compared to seven of the age-matched
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controls (10%). This difference was significant (P = 0.016). Overall, ETBF carriage was
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detected more often in CRC patient stool samples compared to controls, but disparate
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findings from the different DNA preparations and testing methods suggests that poor
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sensitivity may limit molecular detection of ETBF in stool samples.
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Introduction
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Bacteroides fragilis are anaerobic gram negative bacteria commonly found as part of the
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human faecal microbiota. Infection most likely occurs in early childhood, and the inherent
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ability of B. fragilis to evade the host immune response suggests that colonisation may persist
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for life [1]. Whereas carriage of non-enterotoxigenic strains of B. fragilis may promote
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mucosal health [2], some strains produce a toxin that is identified as causative agent of human
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diarrhoea [3]. Colonic carriage of toxin-producing strains is also reportedly more prevalent in
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people presenting with colorectal cancer (CRC) compared to healthy controls [4-6], fuelling
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speculation that persistent carriage of these bacteria may “drive” colon carcinogenesis [7].
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CRC rates of 37.3 per 100,000 New Zealanders are amongst the highest in the world [8]. Our
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aim was to establish a method for screening stool samples for evidence of the B. fragilis toxin
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(bft) gene, as a first step in determining if this potential marker of colon carcinogenesis is
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detected more frequently in stool of CRC patients than in age-matched healthy controls. This
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approach involved the processing of stool samples by two different methods: culture-based
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amplification [9, 10] and direction extraction [11, 12], and testing each of these samples by
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standard and quantitative PCR (qPCR).
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Materials & Methods
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Study Participants. Seventy-one individuals, diagnosed with CRC between 2012 and 2014,
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using standard endoscopic, histological or radiological criteria, provided a stool sample prior
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to chemo-radiation and/or surgery. Patients found to have had pre-operative chemo-radiation
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therapy or those with adenomas were not included in the study. Seventy-one stool samples
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from a cohort of 125 collected from healthy volunteers who self-reported no evidence of
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bowel problems at the time of sampling were age-matched to the 71 patients (Table 1). The
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study was approved by the Upper South A Regional Ethics Committee of New Zealand, and
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all participants provided written informed consent.
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Sample preparation. Each stool was processed by two different methods. The first was
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culture-based amplification, where a loopful of sample was plated onto Bacteroides Bile
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Esculin (BBE) agar (Fort Richard Laboratories, Auckland, NZ), a selective medium for
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Bacteroides [13]. After 48 h anaerobic incubation at 37°C, all colonies were swept off the
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plate into 500 µl of sterile water and heated for 10 min at 99°C. These “sweeps” were kept
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frozen at -20°C until PCR was performed. The second method involved extraction of DNA
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directly from 100 mg of each stool sample using a commercially available kit (Dynabeads
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DNA DIRECTTM Universal extraction kit, Life Technologie AS, Oslo, Norway). This
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“extract” was diluted 100-fold to reduce any inhibitory factors [9]. Extracts were also kept
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frozen at -20°C.
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Standard PCR analysis of bacterial DNA. Each sample was screened for evidence of the bft
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gene using a previously published primer set [14]. Briefly, each 10 µl PCR reaction mixture
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contained 5 pmol of each primer, 200 nM dNTPs, 2 mM MgCl2, 1x enzyme buffer, 0.5 U 4
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HotFire Polymerase (Solis Biodyne, Tartu, Estonia), and 0.5 µl DNA template. The PCR
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amplification program consisted of a 15 minute incubation at 95°C, followed by 35 cycles of
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30 sec denaturation at 95°C, 30 sec annealing at 66°C, and 30 sec extension at 72°C, followed
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by a final extension step of 2 min at 72°C. DNA from ETBF strain VPI 13784 was used as a
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positive bft control. We have previously shown that the primer set used will detect all three bft
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subtypes [15]. Products were visualised on a 1.5% agarose gel containing SYBRSafe
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(Invitrogen, Carlsbad, CA, USA).
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Quantitative PCR. Quantitative real-time polymerase chain reaction (qPCR) was carried out
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to quantify levels of ETBF in stool samples using the LightCycler®480 thermocycler (Roche
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Diagnostics, Indianapolis, IN, USA) using SYBR-green chemistry. Each 10 µl reaction
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consisted of 25–35 ng of genomic DNA, 0.5 µM of each primer pair (Odamaki primers, Table
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1), 5 µl of SYBR Green Master Mix (Roche Diagnostics), and 1.5 µl of water. Thermal
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cycling conditions were as follows: 1 cycle of 95°C for 5 mins, followed by 60 cycles of 95°C
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for 10 secs, 66°C for 10 secs and 72°C for 20 secs. Melting curves were obtained by heating
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samples from 65°C to 97°C in increments of 0.11 °C/s with 5 acquisitions per °C. It was
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assumed that each ETBF contained a single copy of the bft gene. The concentration of ETBF
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was expressed as genome copy numbers by calculating the weight of one ETBF genome, as
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described by Dolezel et al [16]. ETBF has an estimated genome size of 5.2 Mb, and a single
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ETBF genome weighs approximately 5.32 fg (5.2 Mb/978Mb [one picogram of double
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stranded DNA] = 0.00532 pg). Therefore, 1 ng of ETBF DNA contains approximately 187,970
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copies of the genome (1000 pg/0.00532 pg). A standard curve was constructed by serially
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diluting DNA of known concentration, extracted from purified ETBF (strain VPI 13784).
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Concentrations of ETBF in stool samples were calculated using the standard curve following
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amplification of bft.
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Reference strains. Three ETBF reference strains containing the three Bft subtypes (VPI
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13784 [Bft-1] [17], 86-5443-2-2 [Bft-2] [18], and Korea 570 [Bft-3] [19] were generously
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supplied by Professor Cynthia Sears, Baltimore, USA. DNA was extracted from colonies
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following anaerobic culture of each strain on sheep blood agar (Fort Richard Laboratories).
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Preparation of spiked faecal samples for PCR analysis. Serial ten-fold dilutions of a
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suspension of toxigenic B. fragilis strain 86-5443-2-2, containing approximately 1 x 109
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CFU/ml, were added to pre-weighed stool samples from two healthy volunteers negative for
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carriage of ETBF. Standard and quantitative PCR was performed on DNA (sweeps and
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extracts) from each spiked sample to assess the sensitivity of the assays.
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Statistical analysis. Sample counts were compared with Fisher’s exact test with odds-ratio
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and 95% confidence intervals estimated by unconditional maximum likelihood. Logistic
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regression including covariates for age (continuous in years) and gender (dichotomous) was
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used to produce age and gender adjusted P-values for sample counts. All tests were two-sided
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with a type II error rate of 0.05. Analysis was performed in R version 3.2.1 (Vienna, Austria).
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Results
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Incidence of bft gene in stool samples analysed by standard PCR. Stool samples from 71
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patients recently diagnosed with CRC, and 71 age-matched controls were screened using
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primers specific for the detection of the B. fragilis toxin (bft) gene in both bacterial sweeps and
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direct DNA extractions. Standard PCR revealed that sweeps yielded more positive PCR results
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(16/142 (11%)) than DNA extracted from stool samples (11/142 (8%)), indicating that the
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sweep method is more sensitive (Table 2). This was confirmed by assaying serial dilutions of
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stool samples spiked with ETBF. The threshold of detection was approximately 1 x 105 CFUs
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per gram of stool when DNA was directly extracted from the stool. In contrast, the threshold
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for DNA extracted from cultures grown from spiked stool was 1 x 104 CFUs per gram of stool.
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More positive PCR results (11/71) were detected from bacterial sweeps of CRC patient
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samples than from sweeps of age-matched controls (5/71) (16% vs 7%; P > 0.05). Ten CRC
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patients were also found to be positive for the bft gene when the stool DNA extract was tested.
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However, notably fewer positive samples were detected in the control group using this method
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(1/71), which resulted in a significant difference between the number of positive patient and
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control samples using this method of sample preparation (P = 0.046) (Table 2).
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Only seven patient samples tested positive by both methods of sample preparation. Bacterial
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sweeps from four patients were found to be positive while the corresponding extract was
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negative, while three stool samples had evidence of the bft gene in DNA extract only, as
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illustrated by Figure 1. The cumulative total of positive PCR assays from both sample types
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was used to determine the presence of the bft gene in the two patient cohorts. We found that 14
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of the individuals in the CRC group had evidence of the toxin gene in their stool sample
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(20%), compared to five of the age-matched controls (7%). This difference was significant (P
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= 0.046). Logistic regression analysis showed that age and gender did not materially affect the
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results.
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Incidence of bft gene in stool samples analysed by qPCR. Both DNA samples from each
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individual’s stool (bacterial sweep and Dynabead extraction) were then screened for evidence
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of bft using qPCR. The bacterial sweeps yielded a total of 22 positives compared to the 16
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positive samples detected by standard PCR, whereas 19 and 11 of the 142 extracts were
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positive by quantitative and standard PCR, respectively. The increased sensitivity of qPCR
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was confirmed by analysis of DNA extracted directly from serial dilutions of spiked stool
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samples. The threshold for detecting bft from DNA extracted from cultures grown from spiked
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stool was approximately 1 x 101 CFUs per gram of stool; a higher detection threshold was
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observed when DNA was extracted directly from the same samples using Dynabead
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technology (approximately 1 x 102 CFUs per gram of stool). However, despite the increased
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sensitivity of qPCR, this assay did not detect the bft gene significantly more often in individual
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samples when compared to standard PCR (P > 0.05).
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All of the patients that tested positive for bft in either sample by standard PCR also tested
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positive using qPCR. A further seven samples, negative by standard PCR, were additionally
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detected using qPCR. Five of the seven samples were from CRC patients; the other two were
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from age-matched controls (Table 2). Of note, all of these seven samples were detected
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between 35 cycles and the 45 cycle cut-off, which was set to minimise the detection of non-
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specific products; this is consistent with low abundance of bft in these samples. Interestingly,
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six of the seven samples that tested positive by quantitative but not standard PCR were
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bacterial sweeps generated following stool culture on selective media. These additional seven
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samples were confirmed as true positives by sequencing of the qPCR product.
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However, while qPCR detected bft in all the patients/controls positive for bft by standard PCR,
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a comparison of standard and qPCR findings on individual samples rather than per patient
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revealed again the results were not consistent. Of the 11 CRC patient samples where bft was
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detected in the sweeps by standard PCR, only ten were positive by qPCR. Likewise, qPCR
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failed to detect bft in an extracted patient sample that was positive by standard PCR. These
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results suggest sampling error due to low abundance of the target DNA in the samples.
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Accordingly, the cumulative total of positive qPCR assays from both sample types was used to
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determine the presence of the bft gene in patient and age-matched control cohorts. Nineteen of
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the individuals in the CRC group had evidence of the toxin gene in their stool sample (27%),
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compared to seven of the age-matched controls (10%). This difference was significant (P =
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0.016). Logistic regression analysis showed that age and gender did not materially affect the
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results (Table 2).
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ETBF genome copy number in stool samples analysed by qPCR. The generation of a
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standard curve using DNA from a reference strain of ETBF allowed us to determine the copy
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number of ETBF genomes in DNA samples using qPCR. The copy number ranged from
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0.0005 to 32000 among bft-positive samples. There was no difference in relative abundance
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between CRC samples (1955 ± 977) and controls (1706 ± 1193), or between sweep samples
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and DNA extracts (2121 ± 1681 and 1305 ± 384, respectively).
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Discussion
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There is a growing awareness that certain species of gut bacteria may drive toxin- and/or
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inflammation-mediated colorectal carcinogenesis [20]. We have been collecting evidence of a
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significant association between long-term colonic carriage of ETBF and risk of low-grade
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colonic dysplasia in our community. This led us to evaluate two methods for use as faecal
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diagnostic tests for ETBF in individuals considered at risk of developing CRC.
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Culture-based amplification was shown to provide greater sensitivity for ETBF detection than
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DNA extracted directly from stool by using spiked stool samples, as reported elsewhere [9,
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10]. Accordingly, selective enrichment of stool samples resulted in a slight increase in the
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number of bft-positive samples compared to screening of DNA extracted directly from the
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stool, suggesting an increase in the relative abundance of ETBF, if present. In this study solid
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media was used to enrich for Bacteroides spp in the stool samples whereas a recent study
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described the use of a defined broth culture medium [10]; either approach would likely serve
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the same purpose.
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Screening of stool DNA for bft using standard PCR methods showed a significant difference
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between patient and control groups (P = 0.046). However, the detection rates of bft found in
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the New Zealand patients were notably lower than those in the only other study to describe
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increased incidence of ETBF in CRC patient stool samples [4]. To investigate whether the use
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of standard PCR was responsible for under-reporting of bft-positivity in our study, the samples
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were re-screened using a SYBR green qPCR assay with the same primers. This method was
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shown to detect a signal at higher dilutions of spiked samples when compared to standard
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PCR, similar to the TaqMan assay for ETBF recently described by Chen et al. [10]. Culture-
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based amplification of ETBF served to further increase qPCR sensitivity: the number of CRC
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samples with evidence of ETBF carriage increased from 14 (20%) to 19 (27%), and two
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further age-matched controls were found to be positive (from five (7%) to seven patients
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(10%). The difference in detection rates between the groups was significantly different (P =
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0.016) but still notably lower than that reported in Turkish patients [4].
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Toprak and colleagues also used a culture-based system but instead used PCR to analyse
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single colonies that were identified as B. fragilis by conventional methods [4]. Thus, the
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differences between the two studies may reflect methodological as well as geographical
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variation, particularly if the relative abundance of ETBF in samples is low. This is highlighted
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by the finding that six of the seven stool samples in our study, positive for bft only by qPCR,
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were sweep samples. This suggests a very low abundance of ETBF that was undetectable in
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DNA extracted directly from stool samples. The viable cell number of B. fragilis in faecal
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samples is reportedly 10- to 100-fold lower than other intestinal Bacteroides [21] and these
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bacteria account for a very small proportion of the normal colonic microflora (0.1%-0.5%)
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[22]; culturing of samples on selective media may have allowed ETBF to grow to numbers
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detectable in subsequent qPCR.
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In conclusion, this study aimed to determine if molecular screening of stool samples using bft
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as a marker would detect ETBF more often in stool of CRC patients than in age-matched
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healthy controls. Our results support the concept that ETBF may act to promote colon
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carcinogenesis [20]. However, we stress that care needs to be taken with assay design and
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interpretation following the observation of disparate findings in some stool samples where
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DNA was prepared by different processes and/or tested by different methods. We conclude
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that using qPCR with a combination of culture-based amplification and direct extraction is
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likely to increase sensitivity.
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Conflict of interest declaration
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The authors declare that they have no conflict of interest.
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Acknowledgements
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This study was funded by grants from Genesis Oncology Trust NZ and the Rotary Club of
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Christchurch Sunrise.
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Figure legend
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Figure 1. B. fragilis toxin PCR amplification from patient stool samples using both DNA
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extracted directly from stool (top row) and sweeps of bacteria cultured on BBE agar (bottom
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row). Discrepancies between the two DNA preparations can be seen for samples 203 and 277.
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DNA from ETBF strain VPI 13784 and water were used as positive and negative PCR controls
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respectively.
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Tables
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Table 1. Characteristics of CRC patients and controls
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Age median (10%, 90%)
CRC
Control
71
71
72 (53,81)
64 (53, 80)
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Female
29 (41%)
39 (55%)
Male
42 (59%)
32 (45%)
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CRC, colorectal cancer; n, number of patients
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Table 2. Patient and control bft status by standard and qPCR
353 Extract (%)
11 (16)
10 (14)
Controls
5 (7)
1 (1)
P-value
0.183
0.005*
0.046*
P-value (adj)
0.112
0.023*
0.030*
bft qPCR CRC patients
15 (21)
Controls
7 (10)
P-value
0.103
P-value (adj)
0.098
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bft standard PCR
Total (%)
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Sweep (%)
14 (20) 5 (7)
14 (20)
19 (27)
5 (7)
7 (10)
0.046*
0.016*
0.024*
0.015*
CRC, colorectal cancer; BFT, Bacteroides fragilis toxin; PCR, polymerase chain reaction; qPCR,
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quantitative PCR; P-value (adj) adjusted for age and gender; * P-value < 0.05.
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ACCEPTED MANUSCRIPT
ACCEPTED MANUSCRIPT Highlights Molecular identification of enterotoxigenic B. fragilis (ETBF) in stool samples.
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Comparison of different methods of DNA preparation and ETBF amplification.
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Selective enrichment of Bacteroides increases identification of ETBF.
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Quantitative PCR increases sensitivity over conventional PCR.
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Use of multiple methods offers greatest detection rates.
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