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Antimicrobial Agents and Chemotherapy, October 2000, p. 2858-2860, Vol. 44, No. 10
Station de Pathologie Aviaire et
Parasitologie, Institut National de la Recherche Agronomique, 37380 Nouzilly,1 and Agence Française de
Sécurité Sanitaire des Aliments, 69007 Lyon,3 France and Institut für
Tierzucht und Tierverhalten, Bundesforschungsanstalt für
Landwirtschaft Braunschweig (FAL), 29223 Celle,
Germany2
Received 24 February 2000/Returned for modification 30 May
2000/Accepted 5 July 2000
A florfenicol resistance gene almost identical to floR
of Salmonella enterica serovar Typhimurium DT104 was
detected on 110- to 125-kb plasmids in Escherichia coli
isolates of animal origin. Analysis of the floR gene
flanking regions of one of the plasmids showed that they were different
from those encountered in S. enterica serovar Typhimurium DT104.
Florfenicol (FFC) is a fluorinated
derivative of chloramphenicol (CM) approved for use in cattle in Europe
since 1995. Ffc is active against CM-resistant isolates coding for
either CM acetyltransferases (6) or CM exporters, such as
CmlA (3). The first Ffc resistance gene, pp-flo,
was detected in 1996 on a plasmid in the fish pathogen Photobacterium damselae subsp. piscicida
(formerly known as Pasteurella piscicida) (9).
Ffc resistance has gained interest with its description in the
multidrug-resistant Salmonella enterica serovar Typhimurium phage-type DT104 worldwide epidemic strains
(1, 2, 4, 5). Serovar Typhimurium DT104 strains harbor a chromosomal locus in which the floR gene (1) and
the tetracycline resistance operon tetR-tet(G) are bracketed
by two integron structures. This antibiotic resistance gene cluster
including the floR gene has recently been found in serovar
Agona isolates from poultry, suggesting the mobility of this locus
(7). In this study, we investigated FFC-resistant
Escherichia coli isolates from France and Germany for the
presence of the floR gene and its transferability. Analysis
of the floR flanking areas was performed to obtain
information on whether the floR gene area in E. coli might have originated from Photobacterium or
Salmonella.
All 31 French E. coli isolates included in this study
were from cattle, while the 13 German isolates included 11 isolates from cattle and single isolates from a sheep and a cat living on the
same farm as one of the diseased cattle. All isolates were multidrug
resistant, and the FFC MICs varied between 64 and 256 µg/ml.
Conjugation experiments with the E. coli strain BM14
(pro met azi) as the recipient confirmed the FFC resistance
genes to be located on conjugative plasmids. The plasmids of the
original E. coli isolates as well as those of all
FFC-resistant transconjugants were subjected to PCR with internal
primers of the floR gene (1, 2, 7). The
floR-specific internal 496-bp amplicon was seen in all
cases. Two PCR products were sequenced and showed only one 1-bp
difference as compared to the respective part of the serovar
Typhimurium DT104 floR sequence (1). Southern
blot hybridization of the plasmids extracted from the transconjugants with a floR probe (1, 2, 7) confirmed the
location of the floR gene on plasmids ranging in size from
110 to 125 kb (data not shown). Four transconjugant strains from the
French isolates were selected for further study on the basis of their
antibiotic resistance profiles and their FFC MICs (Table
1). They showed four different types of
FFC resistance plasmids which varied in their sizes and their
additional resistances but also in their EcoRI restriction
patterns and the corresponding floR hybridization (Table 1;
Fig. 1). A fifth type of FFC resistance
plasmid was detected in all 13 German E. coli isolates
(Table 1; Fig. 1). A recent report (D. G. White, L. Bolton, J. Maurer, T. Foley, and J. Sherwood, Abstr. 99th Gen. Meet. Am. Soc.
Microbiol., abstr. A-80, p. 17, 1999) described a possible chromosomal
location of the floR gene in bovine E. coli.
Their FFC-resistant strains did not share common plasmids, and FFC
resistance was not transferable by conjugation. Recently, Keyes et al.
(8) also reported FFC resistance due to the floR
gene in avian E. coli isolates. The FFC MICs were 32 to 64 µg/ml, and the floR gene was located on larger plasmids of
186 to 204 kb.
0066-4804/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Plasmid-Mediated Florfenicol Resistance Encoded by
the floR Gene in Escherichia coli Isolated
from Cattle
ABSTRACT
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TABLE 1.
Characteristics of the E. coli strains used in
this study
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FIG. 1.
(A) EcoRI restriction profiles of plasmids
extracted from the transconjugants BN10337-1 (lane 2), BN10507-1 (lane
3), BN10660-1 (lane 4), BN10870-1 (lane 5), and EC-23-99-1 (lane 6).
Lanes 1 and 7, DNA ladder. (B) Southern blot hybridization with the
floR probe of the EcoRI-digested plasmids
extracted from the transconjugants BN10337-1 (lane 2), BN10507-1 (lane
3), BN10660-1 (lane 4), BN10870-1 (lane 5), and EC-23-99-1 (lane 6).
Lanes 1 and 7, DNA ladder.
To assess the genetic environment of the floR gene,
several PCR assays which amplified segments flanking the
floR gene in strains of the serovar Typhimurium DT104 and
serovar Agona (2, 7) were used. The absence of amplification
products indicated that the genetic environment of the floR
gene in the E. coli plasmids was different. Therefore, the
floR-carrying EcoRI fragment of the plasmid from
transconjugant BN10660-1 was cloned in plasmid pGEM-7Zf and sequenced
(Fig. 2). Comparative sequence analysis confirmed that the E. coli floR gene was almost identical to
the pp-flo gene of P. damselae subsp.
piscicida and the floR gene of serovar
Typhimurium DT104 (>98% identity). A database search for homologies
confirmed that the flanking regions of the E. coli floR gene
matched almost exactly (98% identity) with that of the 3.7-kb fragment
of plasmid pSP92088 of P. damselae subsp.
piscicida containing the pp-flo gene
(10) (Fig. 2). The floR locus also revealed
homology to a sulII gene carrying a fragment of plasmid pSP9351 from P. damselae subsp. piscicida
(11) (Fig. 2). Part of the sequences which exhibited
homology to the two plasmids from P. damselae were found to
be repeated in the floR upstream region (Fig. 2). The
1,978-bp segment that showed homology to the serovar Typhimurium DT104
antibiotic resistance gene cluster included only the floR
gene, the upstream region of floR with its putative promoter
region, and a stretch of 99 bp which is repeated in serovar
Typhimurium DT104 downstream of the floR gene and
connects floR with the tetR-tet(G) region of the
antibiotic resistance gene cluster (1, 5). The
floR gene was bracketed by two closely related open reading
frames, orfA' and orfA (Fig. 2). Comparative
analysis of the deduced amino acid sequence of orfA revealed
homology to putative transposases (GenBank database accession no.
AB020531, AF028594, and AF109307). In comparison to orfA,
the 5' end of orfA' appeared to be deleted. Thus, the floR gene might be part of a transposable element. This
would explain its mobility and its location on structurally different plasmids but also might have played a role in the formation of the
DT104 antibiotic resistance gene cluster.
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In conclusion, the occurrence of the floR gene on conjugative plasmids could explain its distribution in several bacterial species from different animal hosts. Analysis of the floR flanking regions suggested that the occurrence of the floR gene in E. coli plasmids is more likely to derive from P. damselae subsp. piscicida plasmids than from the antibiotic resistance gene cluster detected in serovar Typhimurium DT104 (1, 2) and serovar Agona (7). The observation that the floR gene was located on plasmids which usually carry other resistance genes also implicates that the spread of the floR gene might be the result of coselection in the presence of antimicrobials other than FFC. Moreover, the proposal that presumptive identification of serovar Typhimurium DT104 could be rapidly made based on the presence of the floR gene or its resulting phenotype (4) appears to be a questionable approach in light of the occurrence of floR genes in bacteria other than serovar Typhimurium DT104.
Nucleotide sequence accession number. The sequence of the EcoRI floR containing fragment from plasmid of transconjugant BN10660-1 has been deposited in GenBank under accession no. AF231986.
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ACKNOWLEDGMENTS |
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We thank C. Mouline and V. Nöding for expert technical assistance.
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FOOTNOTES |
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* Corresponding author. Mailing address: Station de Pathologie Aviaire et Parasitologie, Institut National de la Recherche Agronomique, 37380 Nouzilly, France. Phone: (33) 2 47427750. Fax: (33) 2 47427774. E-mail: cloeckae{at}tours.inra.fr.
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REFERENCES |
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Antimicrobial Agents and Chemotherapy, October 2000, p. 2858-2860, Vol. 44, No. 10
0066-4804/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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