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Journal of Clinical Microbiology, March 2001, p. 1057-1066, Vol. 39, No. 3
Nemuro Livestock Hygiene Service Center,
Betsukaimidorimachi, Betsukai, Notsukegun,
086-0214,1 Kamikawa Livestock
Hygiene Service Center, 4-15 Higashitakasu, Asahikawa
071-8154,2 Hokkaido Research Station,
National Institute of Animal Health, 4 Hitsujigaoka,3 and Ishikari Livestock
Hygiene Service Center, 3 Hitsujigaoka,5
Toyohira, Sapporo 062-0045, Kushiro Livestock Hygiene
Service Center, 127-1 Otanoshike, Kushiro,
084-0917,4 Soya Livestock Hygiene
Service Center, Hamatonbetu, Esashigun
098-5736,6 Obihiro University of
Agriculture and Veterinary Medicine, Inada, Obihiro
080-8555,7 National Institute of
Animal Health, Tsukuba Science City
305-0856,8 and Kyushu Research Station,
National Institute of Animal Health, 2702 Chuzan, Kagoshima
891-0105,9 Japan
Received 14 September 2000/Returned for modification 16 December
2000/Accepted 6 January 2001
One hundred twenty Salmonella enterica
serotype Typhimurium strains, including 103 isolates from cattle
gathered between 1977 and 1999 in the prefecture located on the
northern-most island of Japan, were analyzed by using fluorescent
amplified-fragment length polymorphism (FAFLP) and pulsed-field gel
electrophoresis (PFGE) to examine the genotypic basis of the epidemic.
Among these strains, there were 17 FAFLP profiles that formed four
distinct clusters (A, B, C, and D). Isolates that belonged to cluster A have become increasingly common since 1992 with the increase of bovine
salmonellosis caused by serotype Typhimurium. PFGE resolved 25 banding
patterns that formed three distinct clusters (I, II, and III). All the
isolates that belonged to FAFLP cluster A, in which all the strains of
definitive phage type 104 examined were included, were grouped into
PFGE cluster I. Taken together, these results indicate that clonal
exchange of serotype Typhimurium has taken place since 1992, and they
show a remarkable degree of homogeneity at a molecular level among
contemporary isolates from cattle in this region. Moreover, we have
sequenced two kinds of FAFLP markers, 142-bp and 132-bp fragments,
which were identified as a polymorphic marker of strains that belonged
to clusters A and C, respectively. The sequence of the 142-bp fragment
shows homology with a segment of P22 phage, and that of the 132-bp
fragment shows homology with a segment of traG, which is an
F plasmid conjugation gene. FAFLP is apparently as well suited for
epidemiological typing of serotype Typhimurium as is PFGE, and FAFLP
can provide a source of molecular markers useful for studies of genetic
variation in natural populations of serotype Typhimurium.
Salmonella infections in
livestock have been a concern for both animal and human health. In
particular, a common serotype causing salmonellosis in humans is
Salmonella enterica serotype Typhimurium, a globally
distributed zoonotic serotype that is common in both cattle and
poultry. In order to study the epidemiology of its outbreaks and
determine the source of contamination so that a recurrence can be
avoided, detailed characterization is necessary. Although the majority
of outbreaks in livestock are caused by a select number of serotypes,
serotyping is not an adequate method for determination of the source of
contamination during an outbreak. One subtyping method for
epidemiological investigations of human and animal salmonellosis
outbreaks is phage typing (3), which discriminates
phenotypically at the intraserotype level. However, phage typing
requires access to special reagents and a specialized laboratory and
fails to reflect evolutionary relationships of bacterial strains. In
the last decade, with the development of new techniques in molecular
biology techniques, new approaches have become available. Widely used
are plasmid analysis (29, 39), chromosomal fingerprinting
by Southern hybridization (12, 16, 31, 36, 37), and
macrorestriction analysis of chromosomal DNA by pulsed-field gel
electrophoresis (PFGE) (4). PFGE is currently the method
of choice to discriminate between strains on the DNA level
(4, 31, 38). However, this technique is difficult to
standardize among laboratories.
Recently, a novel high-resolution technique has been introduced for
whole-genome analysis: amplified-fragment length polymorphism (AFLP) (21, 34). This technique is based on the selective amplification of genomic restriction fragments by PCR in order to
generate fingerprinting patterns consisting of large numbers of bands.
As originally proposed, AFLP used radioactively labeled primers for the
PCR amplification of small genomic fragments defined by known
restriction sites and adapters. Several bacterial genera have been
studied by using radioactive AFLP (18, 23, 25). In the
case of Salmonella, in 1998 Aarts and colleagues analyzed 78 Salmonella strains comprising 62 different serotypes by
using AFLP analysis and showed that the patterns were specific for
serotypes and in some cases even for strains (1).
Recently, AFLP analyses with fluorescently labeled primer (FAFLP) have
been reported for the molecular epidemiological investigation of
Streptococcus pyogenes (7, 8),
Escherichia coli (5, 6, 19), Listeria
monocytogenes (2), Mycoplasma species
(24), Staphylococcus aureus (15, 17), and Mycobacterium tuberculosis
(14). An automated sequencer using a genetic analysis
system along with in-lane size standards can automatically analyze the
fragments generated by FAFLP. This enables the standardization of
fragment sizes and facilitates the identification of polymorphic bands.
In 2000, Lindstedt and coworkers performed FAFLP with
Salmonella comprising seven different serotypes and reported
that the FAFLP method showed a discriminatory power equal to that of
PFGE (26).
In the present study, we have used FAFLP analysis for the molecular
epidemiological investigation of serotype Typhimurium isolated from
cattle and compared the results with those obtained using PFGE.
Surveillance program data show that the incidence of salmonellosis in
cattle in the prefecture located on the northernmost island of Japan
has increased continuously since 1992, with cases stabilizing and
declining after 1995. Both FAFLP and PFGE analyses in this study showed
clonal propagation of serotype Typhimurium isolates from cattle after
the epidemic of 1992. Furthermore, we determined the nucleotide
sequence of the polymorphic fragment that is an FAFLP marker specific
for the epidemic strain.
Bacterial strains.
The 120 serotype Typhimurium strains used
in this study are listed in Table 1.
The majority of the collected strains
reported here were isolated from diseased cattle at local livestock
Animal Hygiene Centers by local public employees in the period 1977 to 1999 in the prefecture located in the northern-most island of Japan.
This study also included 12 serotype Typhimurium definitive phage type
104 (DT104) strains (33) of animal origin (9 from cattle,
1 from pigeon, 1 from chicken, and 1 from crow) and five laboratory
strains (NCTC73, NCTC9324, LT2, L719, and L767).
0095-1137/01/$04.00+0 DOI: 10.1128/JCM.39.3.1057-1066.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Molecular Typing and Epidemiological Study of Salmonella
enterica Serotype Typhimurium Isolates from Cattle by
Fluorescent Amplified-Fragment Length Polymorphism
Fingerprinting and Pulsed-Field Gel Electrophoresis
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
TABLE 1.
Origin and characterization of serotype Typhimurium
strains used in this study
DNA isolation. Strains were grown aerobically at 37°C in 5 ml of LB broth with shaking for 18 h. The genomic DNAs of the Salmonella strains were extracted from these cultures using an ISOPLANT kit (Nippon Gene Corp., Tokyo, Japan) according to the method recommended by the manufacturer. Plasmid DNA was isolated by the method described by Kado and Liu (22). The approximate molecular weight of the plasmid was determined in terms of mobility to plasmid, using known-molecular-weight plasmids from E. coli V517 (27).
Antimicrobial susceptibility testing. The susceptibility of the isolates to antimicrobial agents was determined by disk diffusion tests on Mueller-Hinton agar (Difco, Detroit, Mich.). The following antibiotics were used: ampicillin (AMP), 10 µg/disk; chloramphenicol (CHL), 30 µg/disk; tetracycline (TET), 30 µg/disk; streptomycin (STR), 10 µg/disk; and sulfisoxazole (SUL), 250 µg/disk.
FAFLP. FAFLP was carried out using an AFLP kit (PE Biosystems, Foster City, Calif.) according to the manufacturer's instructions. The enzymes EcoRI (New England Biolabs, Hertfordshire, United Kingdom [NEB]) and MseI (NEB) were used to digest approximately 10 ng of genomic DNA from each isolate and were ligated with EcoRI and MseI adapter using T4 DNA ligase (NEB). The ligated fragments were then diluted 20-fold and amplified by preselective primers, EcoRI primer (5'-GACTGCGTACCAATTC-3') and MseI primer (5'-GATGAGTCCTGAGTAA-3'). Preselective PCR was performed as follows: 2 min at 72°C, followed by 20 cycles of denaturation at 94°C for 18 s, a 27-s annealing step at 56°C, and a 108-s extension step at 72°C. PCR was performed in a PE-2400 thermocycler (Perkin-Elmer Corp., Norwalk, Conn.).
The resulting preselective mixture was again diluted 20-fold and used as a template for selective amplification with EcoRI primer (EcoRI plus A) labeled with a blue fluorescent dye, 5-carboxyfluorescein and MseI primer (MseI plus A). Touchdown PCR cycling was used for amplifying the fragment with the following conditions: a 2-min denaturation step at 94°C (one cycle), followed by 30 cycles of denaturation at 94°C for 18 s, a 27-s annealing step, and a 108-s extension step at 72°C. The annealing temperature for the first cycle was 66°C; for the next nine cycles, the temperature was decreased by one degree at each cycle. The annealing temperature for the remaining 20 cycles was 56°C. This was followed by a final extension at 60°C. The amplification products were stored at
20°C.
FAFLP fragments were separated in 5% denaturing polyacrylamide
gels (LongRanger; FMC Bioproducts, Rockland, Maine) on an ABI Prism 377 automated DNA sequencer (Perkin-Elmer Corp.). The sample (1.0 µl) was added to 2.0 µl of loading dye, which was a mixture containing 1.25 µl of formamide, 0.25 µl of loading solution
(dextran blue in 50 mM EDTA), and 0.5 µl of the internal lane
standard, GeneScan 500, labeled with the red fluorescent dye
6-carboxy-
-rhodamine (PE Biosystems). The sample mixture was
heated at 95°C for 2 min, cooled on ice, and immediately loaded onto
the gel. Running buffer was 1× TBE (89 mM Tris, 89 mM boric acid, 2 mM
EDTA), and electrophoresis conditions were 1.68 kV and 51°C for
8 h.
GeneScan collection software (PE Biosystems) was used to automatically
size and quantify individual fragments by using the internal lane
standards. Results were viewed in the form of gel image,
electrophorogram, and tabular data, or a combination of all three. For
the purpose of numerical analysis, background level was subtracted from
the GeneScan-derived data using Genotyper software (PE Biosystems). The
presence or absence of precisely sized fragments was ascertained, and
these digital data were transferred to spreadsheets for further
analysis. Pairwise comparisons were made between all strains in terms
of the Dice coefficient (30) using in-house software. The
distance matrix thus generated was used as input for the UPGMA
(NEIGHBOR program of PHYLIP [9]).
PFGE. PFGE was performed by clamped homogeneous electric field electrophoresis using a CHEFF DRII apparatus (Bio-Rad Laboratories, Hercules, Calif.). Genomic DNA was prepared as previously described elsewhere (31). Each strain was grown overnight at 37°C in LB broth. Cells were harvested by centrifugation for 10 min at 3,600 × g and resuspended in 0.5 ml of NT buffer (10 mM Tris-HCl [pH 7.5], 1 M NaCl). An aliquot (0.3 ml) of the suspension was transferred to a microcentrifuge tube, and cells were pelleted at 12,000 × g and washed twice in NT buffer. The cell suspension was mixed with an equal volume of 1.5% low-melting-point agarose (FMC Bioproducts) and allowed to solidify in a 100-µl plug mold (Bio-Rad Laboratories). The agarose plugs were incubated overnight at 55°C in 1 ml of lysis buffer (60 mM Tris-HCl [pH 7.5], 50 mM EDTA, 1.0% sodium-lauryl sarcosine, lysozyme [1 mg/ml], RNase [1 µg/ml], proteinase K [1 mg/ml]), washed twice for 30 min with TE buffer (10 mM Tris-HCl [pH 7.5], 0.1 mM EDTA) containing phenylmethylsulfonyl fluoride (1 mM), and then washed four times for 30 min in 1 ml of TE buffer. A slice of each plug was cut and incubated in 400 µl of restriction buffer containing 50 U of XbaI at 37°C for 2 h. The restricted DNA fragments were separated on pulsed-field-certified agarose (Bio-Rad Laboratories). Electrophoresis was done for 25 h at 14°C at 6V/cm in twofold-diluted TBE buffer with pulse times of 5 to 80 s. Lambda PFG DNA markers (NEB) were used as DNA size markers. The PFGE profiles were scanned and analyzed using the Taxotron package according to the instructions of the user's manual (Patrick A. D. Grimont, Institute Pasteur, Paris, France). This package is composed of the RestrictoScan, RestrictoTyper, Anderson, and Dendrograph programs. Lines and bands were detected with the RestrictoScan program. Fragment lengths were interpolated using the Spline algorithm (implemented with the RestrictoTyper software). The similarity index was calculated using the RestrictoTyper program with the fragment length error tolerance set at 4%. The single linkage was computed with the Anderson program, and a dendrogram was drawn using the Dendrograf program.
Sequencing. FAFLP products of the 132-bp and 142-bp fragments yielded by the strains NET30 and H6, respectively, were eluted from a 5% acrylamide gel using the method described elsewhere (28). Eluted fragments were amplified again by PCR, using the selective primer pair as described above. The resulting PCR product was cloned to pCRII to give pCR132 and pCR142, respectively, using a TA cloning kit (Invitrogen Corp., San Diego, Calif.) by the method recommended by the manufacturer. The cloned PCR product was sequenced on an ABI 377 automatic sequencer using a BigDye Terminator kit (PE Biosystems) according to the manufacturer's instruction.
Hybridization experiments. FAFLP products of the 132- and 142-bp fragments were amplified by PCR as described above and purified using a PCR product purification kit (Qiagen, Hilden, Germany). The purified fragments were labeled with digoxigenin (DIG)-11-dUTP by random priming using a DIG High Prime Labelling Kit (Boehringer GmbH, Mannheim, Germany) as described by the manufacturer. For Southern hybridization, plasmid DNA or cleaved genomic DNA was separated on a 0.8% agarose gel and transferred to a positive membrane (Boehringer) with a vacuum blotter (LKB Vac Gene; Pharmacia LKB Biotechnology, Uppsala, Sweden). Prehybridizations (>30 min) and hybridizations (>16 h) using Easy Hyb solution (Boehringer) under high-stringent conditions and detection of hybrids by means of enhanced chemiluminescence with anti-DIG-alkaline phosphatase and CSPD were carried out using a DIG Luminescent Detection kit (Boehringer), following the manufacturer's instructions. DIG-labeled marker III (Boehringer) was used as a DNA size marker. Hyper MP (Amersham International, Little Chalfont, United Kingdom) was exposed to membranes for 1 to 10 min at room temperature and developed in a Kodak X-Omat processor.
Nucleotide sequence accession numbers. The nucleotide sequences of the 132- and 142-bp fragments determined in this study (see Fig. 4) are deposited with DDBJ under accession numbers AB047311 and AB047310, respectively.
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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FAFLP analysis of serotype Typhimurium strains.
A total of 120 serotype Typhimurium strains were analyzed by the EcoRI plus
A and MseI plus A FAFLP primer combination. FAFLP analysis
generated 45 to 50 amplified fragments ranging in size from 80 to 430 bp and exhibited 12 polymorphic amplified fragments among them (Table
2). Seventeen profiles were
detected among the 120 strains (Fig.
1). At a cutoff value of 96.5%,
cluster analysis identified four clusters: cluster A (73 isolates),
cluster B (28 isolates), cluster C (17 isolates), and cluster D
(2 isolates). Within these clusters, four (A1 to A4), six
(B1 to B6), five (C1 to C5) and two (D1 and D2) different profiles were
detected (Fig. 1). Eight strains had unique FAFLP profiles (Fig. 1).
The other 112 strains were assigned to nine profiles: 55 were
assigned to profile A2, 16 were assigned to profile A1, 12 were
assigned to profile B2, 8 were assigned profile B5, 7 were assigned to
profile C1, 6 were assigned to profile C4, 4 were assigned to profile B3, and 2 each were assigned to profiles B1 and C2 (Fig. 1). Examples of the areas of polymorphism within FAFLP profiles derived by GeneScan
analysis for four EcoRI plus A and MseI plus A
amplifications are shown in Fig. 2. All
four profiles in FAFLP cluster A contained a characteristic fragment of
142 bp and lacked the 80-bp fragment found in other FAFLP profiles
(Table 2; Fig. 2). A fragment of 142 bp was also found in the profile
B1 that contained a fragment of 80 bp, whereas the 142-bp fragment was
absent in the other profiles in cluster B (Table 2; Fig. 2). Five
profiles in cluster C contained the 132-bp fragment, which was absent
from the profiles in the other clusters (Table 2; Fig. 2). Four
fragments of 172, 235, 278, and 324 bp in profiles D1 and D2 are absent
from the other profiles (Table 2; Fig. 2).
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Genetic diversity of serotype Typhimurium strains as defined by
PFGE.
All the strains were analyzed by PFGE, and the results
obtained were compared with those of FAFLP. Digestion of serotype
Typhimurium with XbaI gave 13 to 17 fragments with sizes
between 40 and 800 kbp (Fig. 3).
Twenty-five PFGE profiles after digestion of DNA with XbaI
were observed among the 120 strains and with a 72% level of
similarity; three clusters (I, II, and III) were found (Fig. 3).
Comparative data for PFGE and FAFLP analyses for the 120 strains are
presented in Table 1. All of the 73 strains which belonged to FAFLP
cluster A could be grouped into PFGE cluster I. Except for four strains
(N49, N60, N61, and N62) yielding FAFLP profile B3, all the strains
belonging to FAFLP cluster B fell into PFGE cluster II. Four strains
yielding FAFLP B3 profile, together with all 17 strains grouped into
FAFLP cluster C, were classified into PFGE cluster III. The four
strains yielding FAFLP B3 profile lacked plasmid, while the other
isolates belonging to PFGE cluster III had a large plasmid (data
not shown). Two strains belonging to FAFLP cluster D had PFGE profiles
IId and IIe.
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Antimicrobial resistance. The antibiotic resistance profiles of 120 serotype Typhimurium strains are listed in Table 1. Overall, 91.7% of 120 strains were resistant to at least one antibiotic. The antibiotic to which resistance was most frequently detected was TET (85.8%), followed by SUL (84.2%), AMP (82.5%), CHL (80.0%), and STR (75.8%). Most of the strains belonging to FAFLP cluster A, including DT104 strains, showed antibiotic resistance to AMP, SUL, STR, TET, and CHL, except for KT10 (SUL and STR) and KT43 (STR).
Comparison of isolates associated with an epidemic. The incidence of bovine salmonellosis caused by serotype Typhimurium increased since 1992 in the prefecture located in the northernmost island of Japan, and a prolonged epidemic continued until 1996. To compare the isolates associated with the epidemic, the FAFLP profiles of 103 strains isolated from cattle between 1977 and 1999 in this area were examined. The FAFLP results are summarized in Table 1. Although before 1992, with one exception (NET39), all the isolates were grouped into cluster B, C, or D, the number of isolates that belong to cluster A has increased dramatically since 1992. This genotype has become common since 1994. Furthermore, all the DT104 strains examined belonged to FAFLP cluster A, which corresponds to PFGE cluster I (Table 1).
Sequence analysis of 132- and 142-bp fragments.
In order to
analyze cluster-specific FAFLP fragments of 132 and 142 bp, we decided
to clone them from strain NET30 and H6, respectively, and sequence the
cloned fragments. A search for homologies to the sequence of the 132-bp
fragment in the database revealed that this sequence was 97% identical
to a 107-bp segment of traG that is an F plasmid conjugation
gene (10) (Fig. 4A). The
sequence of the 142-bp fragment was 86% identical to the 117-bp segment of the P22 phage (42) (Fig. 4B).
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DISCUSSION |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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In 1992, we observed an apparent increase in the incidence of bovine salmonellosis caused by serotype Typhimurium in the prefecture located in the northernmost island of Japan, where dairy farming is one of the main agroindustries. Surveillance program data showed that the incidence was stable until 1991 but that the number increased during the next 3 years, with cases stabilizing and even declining after 1995. The reason for this increment is unclear, and further epidemiological investigation is needed in order to examine the genotypic basis of the epidemic.
In this study, we used a recently developed genotyping method, FAFLP, which is based on selective amplification of restriction fragments of chromosomal DNA, for the genetic typing of serotype Typhimurium strains isolated from cattle. Among 120 strains including 114 isolates from cattle, 17 FAFLP profiles and four clusters (A, B, C, and D) were identified. Before 1992, only one isolate was grouped into FAFLP cluster A, and the other strains were grouped into cluster B, C, or D. The number of strains which belonged to cluster A has increased since 1992, and all the isolates fell into a single cluster, A, since 1994. These results show that the isolates that belonged to clusters B, C, and D had been circulating in this area until at least 1993, whereas isolates that belonged to cluster A seem to have spread since 1992. Thus, isolates belonging to FAFLP cluster A seem to be responsible for prolonging the epidemic in this area. With respect to the XbaI macrorestriction profiles detected by PFGE, 25 distinct profiles were observed among the 120 strains. Three groups were identified with a similarity of 72%. Strains that were grouped into FAFLP clusters A and C belonged to PFGE clusters I and III, respectively, and with the exception of strains showing FAFLP profile B3, strains that were grouped into FAFLP cluster B or D belonged to PFGE cluster II. Therefore, overall, the data generated by FAFLP analysis gave results almost consistent with those of PFGE, and both methods were able to distinguish between a preepidemic lineage of serotype Typhimurium and the lineage of isolates which caused the epidemic.
An increase in the occurrence of antibiotic resistance in Salmonella isolated from food animals has been observed in several countries, and in some cases the emergence of resistance has been caused by the clonal spread of multiresistant strains (11, 32). Recently, multiresistant serotype Typhimurium DT104 has been reported with increasing frequency in several countries worldwide (13, 40, 41). Sameshima et al. (33) reported that DT104 strains have existed in Japanese livestock since 1990 and that 36 of 68 isolates which exhibited resistance to five or more antimicrobials were identified as DT104. These isolates are resistant to AMP, CHL, STR, SUL, and TET but have also shown a tendency to acquire resistance to additional antimicrobial agents. In this study, we showed that 76 of 78 strains belonging to FAFLP cluster A, in which most of the contemporary isolates were included, have the same antibiotic resistance pattern (AMP, SUL, STR, TET, and CHL). Furthermore, all the DT104 strains examined belonged to FAFLP cluster A. Although we did not determine the phage type of the isolates from cattle, these results indicated that clones genetically similar to DT104 have been widely spread in this area. In Japan, only four DT104-related outbreaks in humans were reported (20); however, fortunately, a human case caused by DT104 has not been reported in the northernmost island of Japan. Further surveillance of serotype Typhimurium is required to examine the relationship between human and animal origin. The FAFLP method might be a useful tool for this surveillance.
Using FAFLP, we identified a 142-bp fragment which was one of the polymorphic markers of the strains belonging to FAFLP cluster A. A Southern hybridization study revealed that the 142-bp fragment originated from a chromosome and hybridized to a common band of the 7.0-kb HindIII fragment present in all isolates which belonged to FAFLP cluster A. The sequence of the 142-bp fragment was highly similar to the segment of P22 phage (42). Recent reports have demonstrated that antimicrobial resistance genes are clustered in the genome of serotype Typhimurium DT104 and that these genes can be efficiently transduced by P22-like phages (35). The DT104 strain may carry a P22-like prophage in its genome, and such a prophage may confer horizontal transfer and further spread of resistance genes. The usefulness of the 142-bp fragment as a marker to detect DT104 strains needs to be confirmed in prospective studies. However, on the contrary, a 132-bp fragment originated from plasmid. Although the fragment of 132 bp is specific for FAFLP cluster C, the hybridization study showed that the 132-bp fragment hybridized with a plasmid not only from isolates that are grouped into FAFLP cluster C but also from isolates that are grouped into the other clusters, suggesting that a homologous sequence with that of the 132-bp fragment is conserved among plasmids in serotype Typhimurium strains. All the strains belonging to FAFLP cluster C are multidrug resistant, and plasmids of these strains were conjugative with R plasmid (data not shown). Since the sequence of the 132-bp fragment showed similarity with traG, which is an F plasmid conjugation gene (10), this fragment might be a marker of R plasmid.
In the present study, we examined whether FAFLP is applicable to the epidemiological study of serotype Typhimurium. Our results indicated that FAFLP has almost the same discriminatory ability as that of PFGE, which is now considered to be one of the more powerful tools for molecular subtyping of serotype Typhimurium. Moreover, when used with another pair of primers the combination of these results might increase the discrimination power of FAFLP. The sizing of the fragments by FAFLP with the use of an internal standard was precise, having a resolution of ±1 bp (data not shown). The internal standard also allows us to directly compare fingerprint patterns from different runs, and FAFLP profiles are suitable for rapid electronic transmission for interlaboratory comparisons. Therefore, FAFLP profiles are well suited for constructing a database for later comparisons and epidemiological analyses. Furthermore, as we were able to characterize cluster-specific fragments of 132 and 142 bp in this study, FAFLP may provide a rich source of molecular markers which are useful for studies of the epidemiology, pathogenicity, and genetic variation in natural populations of serotype Typhimurium.
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ACKNOWLEDGMENTS |
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We thank the staff of the Hokkaido local government for kindly providing serotype Typhimurium strains isolated from cattle.
This project was funded by the Ministry of Agriculture, Forestry, and Fisheries of Japan.
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FOOTNOTES |
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* Corresponding author. Mailing address: Hokkaido Research Station, National Institute of Animal Health, 4 Hitsujigaoka, Toyohira, Sapporo, Hokkaido 062-0045, Japan. Phone: (81) 11-851-5226. Fax: (81) 11-853-0767. E-mail: ikuouchi{at}affrc.go.jp.
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Introduction
Materials and Methods
Results
Discussion
References
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Journal of Clinical Microbiology, March 2001, p. 1057-1066, Vol. 39, No. 3
0095-1137/01/$04.00+0 DOI: 10.1128/JCM.39.3.1057-1066.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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