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Antimicrobial Agents and Chemotherapy, October 2001, p. 2856-2861, Vol. 45, No. 10
Department of
Pharmacology1 and Department of
Microbiology,2 Municipal Institute of
Medical Investigation, 08003 Barcelona, and Laboratori de
Rèferencia de Catalunya (Microbiology), Autovia de
Castelldefels, 08907 L'Hospitalet de Llobregrat,
Barcelona,3 Spain
Received 1 February 2001/Returned for modification 12 May
2001/Accepted 10 July 2001
The nature of the SHV-1 The SHV-1 SHV-1 has been identified in several species of enterobacteria and is
generally considered a plasmid-encoded enzyme (5). Nevertheless, this To obtain a better understanding of the structure and function of the
SHV-1 family of Bacterial strain characterization.
Ninety-seven
K. pneumoniae strains were studied. All were isolated
from pathological human products between 1979 and 1984 and were
provided by five laboratories (laboratories L1 to L5). The strains were
not epidemiologically related. Most of the strains were from laboratory
L1 (49.5%). The other laboratories provided 18.5% (laboratory L2),
18.6% (laboratory L3), 7.2% (laboratory L4), and 6.2% (laboratory
L5) of the strains. Urine was the most frequent type of sample
(79.2%), followed by blood (4.1%), exudates (7.2%), respiratory
specimens (1%), and other types of specimens (9.3%). Biotype
characterization was performed by standard biochemical analyses. The
reference strain used to extract the SHV-1 DNA probe was
Escherichia coli HB101 (F
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.10.2856-2861.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
SHV-1
-Lactamase Is Mainly a Chromosomally
Encoded Species-Specific Enzyme in Klebsiella
pneumoniae
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-lactamase gene was analyzed in
97 epidemiologically unrelated Klebsiella
pneumoniae strains isolated from clinical samples.
-Lactamase bands that focused at a pI of 7.6 (SHV-1-type) in 74 strains, at a pI of 7.1 (LEN-1-type) in 13 strains, and at a pI of 5.4 (TEM-1-type) in 10 strains were detected by analytical isoelectric
focusing (IEF). Among the 74 SHV-1-producing strains, 40 had, in
addition to the pI 7.6 band, an additional band on IEF: 20 had a
band with a pI of 7.1 and 20 had a band with a pI of 5.4. Most
of the 74 SHV-1-producing strains (76.7%) carried plasmids. Transfer
of -lactam resistance by conjugation was possible in only 9.3% of
the strains tested. SHV-1 gene-specific PCR-restriction fragment length
polymorphism (PCR-RFLP) analysis of the chromosomal DNA was positive
for 93 of the 97 strains and negative for only 4 of the 10 samples with K. pneumoniae TEM-1 producers. In an attempt to
approximate the location of the SHV gene locus by endonuclease
restriction analysis, RFLP analysis with Southern blotting of
chromosomal DNA with a labeled SHV-1 fragment as a probe was used to
study the 97 strains. A trial with EcoRI showed at least
one positive hybridization band for 96 strains; two bands were detected
for 8 strains. The hybridization was negative for only one TEM-1
-lactamase-producing strain. DNA sequence analysis showed no
differences in promoter regions or extra stop-triplet sequences;
only point mutations determined different allelic variants. The
novel SHV-type variants are designated SHV-32 and SHV-33. As a result
of the RFLP and sequencing analyses, it can be postulated that the loci
for SHV-1 and LEN-1 genes are arranged in tandem. Our results
strongly support the hypothesis that the ancestor of the SHV-1
-lactamase originated from the K. pneumoniae chromosome.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-lactamase,
first described by Pitton in 1972 as Pit-2 (19), is a
class A, group 2b -lactamase (according to the Bush-Jacoby-Medeiros
classification [5]). Its hydrolytic spectrum of activity
is similar to that of the TEM-1 -lactamase, but it achieves better
activity against ampicillin (5).
-lactamase is found at a higher frequency (up to
80 to 90%) in Klebsiella pneumoniae (3, 9-12,
19). Thus, SHV-1 has putatively been considered chromosomally
borne. In 1979, Matthew et al. (14) and Nugent and Hedges
(17) demonstrated the extrachromosomal location of the
blaSHV-1 gene in some K. pneumoniae strains. Other -lactamases of putative chromosomal origin were occasionally found in K. pneumoniae
strains, which were unable to transfer ampicillin resistance
(18). Among them, LEN-1, a class A, group 2a
-lactamase, is the most frequently occurring and is clearly
chromosomally encoded (2).
-lactamases, several groups of investigators have sought to detect differences among -lactamases of the SHV-1 family in K. pneumoniae mainly by comparing the
sequences of SHV-1 (4, 15), LEN-1 (2), and
OHIO-1 (22). In the study described here we attempted
to clarify the nature of the SHV-1 -lactamase gene by analyzing 97 unrelated K. pneumoniae strains isolated from clinical samples.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
hsdS20 recA13 ara-14 proA2 leu lacY1 galK2 rpsL20 xyl-55 mtl-1 supE44) carrying plasmid pMON38.
-lactamases was studied by previously
described analytical isoelectric focusing (IEF) procedures (13) performed with samples of crude cell-free sonic
extracts in Multiphor equipment (Pharmacia Biotech, Uppsala, Sweden).
The pH gradients (pH 3.5 to 9.5, 4 to 6.5, and 5.5 to 8.5) were
measured with a surface pH electrode device (LKB Multiphor electrode); enzyme bands were detected by nitrocefin staining (0.5 mmol of nitrocefin per liter in 0.1 mol of phosphate buffer per liter [pH
7.0]).
Antibiotic susceptibility and transfer of resistance. Testing of the MICs of ampicillin, mezlocillin, carbenicillin, cephalothin, cefotaxime, ceftazidime, and aztreonam was performed by the agar dilution method. In addition, the MICs of ampicillin (2:1) and mezlocillin (4:1) in combination with clavulanic acid were also determined.
Conjugation experiments were performed by a two-step procedure with E. coli K-12 (C600; F without the
lac, thia, leu, and threo
genes but with Nalr) as the recipient
strain. From an overnight broth, culture recipient and donor strains
were mixed at a proportion of 2:1 and were incubated at 37°C for
4 h. A sample of 0.1 ml was incubated overnight at 37°C on
Mueller-Hinton agar; E. coli transconjugants were
selected on agar plates (Diagnostics Pasteur, Marnes La
Coquette, France) with nalidixic acid (40 µg/ml)
containing ampicillin (60 µg/ml).
SHV-1 genetic analysis. Plasmid DNA was isolated by a commercial method (Magic Miniprep DNA purification system; Promega Corporation, Madison, Wis.) based on the alkaline lysis method, followed by DNA purification with ion-exchange resins. Chromosomal DNA was isolated by the cetyltrimethylammonium bromide (CTAB) method (23). The size of the chromosomal DNA was estimated to be over 80 kb, and the 260/280 purity ratio was 1.8. Recombinant plasmid pMON38 carrying the SHV-1pMON38 gene was kindly provided by George A. Jacoby. Plasmid pMON38 was used as a template to obtain the 178-bp PCR product as a probe for Southern blot analysis and as a template to set up a specific PCR-restriction fragment length polymorphism (PCR-RFLP) analysis method. The probe was labeled with digoxigenin-dUTP with a PCR digoxigenin DNA labeling system (Boehringer Mannheim, Mannheim, Germany) according to the manufacturer's instructions.
A specific PCR-RFLP test was developed after the designation of primer sequences from the SHV-1 sequence (GenBank accession number AF148850) (4) by selecting the most specific coding area that distinguished SHV-1 from other-lactamases, particularly LEN-1.
The primer sequences were located at SHV-1 gene (GenBank accession
number AF148850) (4) sequences
5'-T97AAGCGAAAGCCAGCTGTCG116-3'-OH (forward primer) and
5'-T274TTCGCTCCAGCTGTTCGTC255-3'-OH
(backward primer); both primers detected a 178-bp
fragment. The PCR amplification reaction mixture consisted of a 50-µl
volume containing 50 mM Tris buffer (pH 8.0), 1.3 mM
MgCl2, 5% dimethyl sulfoxide, 0.2 mM
deoxynucleoside triphosphates, each primer at a concentration of 125 nM, and 1.25 U of Taq DNA polymerase (Amplitaq; Roche, Basel, Switzerland). The reaction was performed in a
Perkin-Elmer 9600 thermocycler. The amplification method was as
follows: the reaction was initiated by a denaturing step at 94°C for
1 min, followed by 30 cycles of denaturation at 92°C for 10 s,
annealing at 55°C for 10 s, and extension at 72°C for 10 s; the reaction was terminated with an extension step at 72°C for 1 min. The amplified fragment was electrophoresed in 1.2% agarose gels
with TBE (Tris-borate-EDTA buffer, which consisted of 45 mM
Trizma base, 45 mM boric acid, and 1 mM EDTA [pH 8.0]), yielding a
fragment of 178 bp, which was a positive reaction. The PCR
product was further digested with 3 U of NotI restriction
endonuclease to test for specificity for SHV-1 and yielded specific
fragments of 56 and 122 bp.
RFLP analysis with Southern blotting was performed with chromosomal DNA
samples. Several endonucleases were tested at 3 U/µg of DNA overnight
at the appropriate temperature for each endonuclease. Electrophoresis
was done on a 0.5% agarose gel (20 by 20 cm) at 20 V for 24 h.
Transfer to a positively charged nylon membrane (Boehringer Mannheim)
was performed with a vacuum transfer system (Vacu-Gene XL;
Pharmacia Biotech, Uppsala, Sweden). Conditions of stringency
were taken into account as follows: the hybridization temperature was
68°C and the hybridization solution was 250 mM Na2HPO4, 1 mM EDTA, 20%
sodium dodecyl sulfate, and 0.5% blocking reagent (Boehringer
Mannheim). Detection of specific fragments was performed by
chemiluminescence with the CSPD reagent (Boehringer Mannheim) at
a dilution of 1:100 for 5 min. The sizes of the fragments obtained by
RFLP analysis were determined with a digoxigenin-labeled bacteriophage lambda-HindIII DNA ladder marker
that was also detected by chemiluminescence.
DNA sequencing analyses were performed with a Perkin-Elmer sequencing
kit (ABI PRISM dye terminator cycle sequencing kit) adapted for an ABI
PRISM 377 sequencer (Perkin-Elmer). The reactions were performed in a
Perkin-Elmer 9600 thermocycler with 100 ng of chromosomal DNA from the
tested strain as the template and according to the manufacturer's
instructions; purified PCR products were electrophoresed and analyzed
with an ABI PRISM 377 sequencer. Sequencing primers were defined
to identify the whole sequence of the SHV-1 gene (a total of 1,120 bp;
EMBL accession number M59181) (15) in two steps: both
strands of the gene were sequenced, including 864 bp of the coding
region, 117 bp upstream, and 139 bp downstream. The first pair of
primers used was
5'-G8ATGAAAAATGATGAAGGAA27-3'-OH (forward primer set 1) and
5'-A576TCTGGCGCAAAAAGGCAGT557-3'-OH (backward primer set 1); the second pair of primers was
5'-C514GCCAATCTGCTACTGGCCA533-3'-OH (forward primer set 2) and
5'-G1127GAGGCCACGTTTATGGCGT1108-3'-OH (backward primer set 2). Sequencing data for 16 strains and
pMON38, which was used as a probe, were compared to reported
data for the blaSHV-1 gene listed in
GenBank under accession number AF148850 (4). The sequences
of the strains were translated and the amino acids were numbered as
described by Ambler et al. (1).
Nucleotide sequence accession numbers. The novel allelic variants reported in this study were designated SHV-32 and SHV-33 (http://www.lahey.org/studies/webt.html), and the nucleotide sequence data reported for the strains producing those variant enzymes and for K263 (designated as LEN-2) will appear in the GenBank nucleotide sequence database under accession numbers AY037778, AY037779, and AY037780, respectively.
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Analytical IEF of sonic extracts yielded different -lactamase
bands that focused at a pI of 7.6 (SHV-1) in 74 strains, at a
pI of 7.1 (LEN-1) in 13 strains, and at a pI of 5.4 (TEM-1) in 10 strains. Additionally, among the 74 SHV-1-type strains, 34 had a
single band and 40 had, in addition to the pI 7.6 band, an additional
band on IEF: 20 with a band at a pI of 7.1 and 20 with a band
at a pI of 5.4. Antibiotic susceptibility assessed according to
the MICs for the 97 K. pneumoniae strains tested indicated that the strains had broad-spectrum activities, showing both
penicillinase and cephalosporinase activities, but the percentage of strains resistant to the different antibiotics studied tended to
correlate with the enzyme produced (Table
1). Resistance to broad-spectrum
cephalosporins or aztreonam was not observed. Nevertheless, for 33 strains that were not considered to have
extended-spectrum -lactamases, ceftazidime MICs ranged from 
0.5 to
4 µg/ml.
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Plasmid analysis was performed with the 74 SHV-producing strains to
study the frequency and distribution of plasmids. Most of the strains
(76.7%) carried from one to five plasmids. The group of strains most
frequently encountered was that with only one plasmid (37%), and 23%
of the strains had no detectable plasmids. Plasmids were mainly
distributed into two groups according to size: 54% were large
(>30-kb) plasmids and 37% were very small (<7-kb) plasmids. Strains
frequently had different combinations of plasmids by size and were
compiled into different categories, as shown in Fig.
1. Among the 74 strains, 59 were studied
in conjugation experiments; the strains excluded were the SHV-1 and
TEM-1 producers because of their plasmid-encoded TEM-1 -lactamase.
Transfer of -lactam resistance to the recipient strain, E. coli K-12 C600 F, was positive for only 5 of the 59 (9.3%) strains tested. The five parental strains were
mezlocillin resistant. The sizes of the plasmids detected in the
transconjugant strains were >60 kb in three strains and 3.5 kb in two
strains.
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SHV-1 gene-specific PCR-RFLP analysis of the chromosomal DNA was
positive for 93 of the 97 strains. PCR was negative for negative control strains (several E. coli clinical isolates that were
nonproducers of the SHV-1 -lactamase) and for only 4 of the 10 K. pneumoniae strains that produced the TEM-1 enzyme. A
specific control analysis was performed with the restriction enzyme
NotI, which has an SHV-1-specific restriction site.
The NotI site is absent from the LEN-1 and OHIO genes, which
have 90 and 95% nucleotide gene sequence homologies, respectively,
with the SHV-1 sequence analyzed.
The 97 strains were studied by RFLP analysis with Southern blotting of
chromosomal DNA. In an attempt to approximate the gene locus by
endonuclease restriction analysis, several enzymes were tested (Fig.
2). The strategy used was to test the
enzymes that did not cut the genes (EcoRI,
HindIII) or that were specific for the SHV-1 gene
(NotI) and/or the LEN-1 gene (BamHI,
KpnI) (Table 2). In the trial
with EcoRI, at least one positive hybridization band was
found for 96 strains. The hybridization was negative for only one TEM-1
-lactamase-producing strain (strain K534; Fig. 2, lane 3); PCR was
also negative for this strain. Curiously, strains K251 and K273
(Fig. 2, lanes 1 and 2, respectively), which were also PCR negative
(Table 2), were positive for a fragment; thus, further sequence
analysis was suggested. Among the 96 positive strains, 88 had one
EcoRI-specific hybridization band and two bands were
detected for 8 strains. The fragments found were 8.5 kb (88.5%),
8 kb (6.7%), 7 kb (2.9%), and >23 kb (1.9%). The 8-kb fragment was
always found together with the 8.5-kb fragment; the 7-kb fragment was
always found alone; the >23-kb fragment was found alone in one strain
and was combined with the 8.5-kb fragment in another strain. Among all
strains that produced LEN-1, as determined by IEF, PCR analysis
detected the SHV-1 gene and RFLP analysis detected one fragment of 8.5 kb (83% of strains) and two fragments of 8 and 8.5 kb (7% of
strains). In addition, in the six strains that produced TEM-1 and in
which the SHV-1 gene was detected by PCR, the fragment obtained by RFLP
analysis was 8.5 kb.
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): 1, K251 
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DNA sequence analysis was performed with 17 DNA samples: pMON38 DNA;
plasmid DNAs of the 5 transconjugant strains (strains TK75, TK136,
TK167, TK175, and TK198); chromosomal DNAs of 3 SHV-1-type K. pneumoniae strains (strains K280, K48, and K237),
with strain K280 being sensitive to mezlocillin and the other two
strains being resistant to mezlocillin; and chromosomal DNAs of 3 LEN-1-producing K. pneumoniae strains (strains K103,
K218, and K299) and 5 TEM-1-producing K. pneumoniae
strains (strains K8, K39, K117, K154, and K263), as determined by IEF.
Table 3 shows the results for both
alignments for 16 different DNA sequences and their respective deduced
amino acid sequences. For comparison purposes, the published sequences of the SHV-1 (GenBank accession number AF148850), LEN-1 (EMBL accession
number X04515), and OHIO-1 (EMBL accession number M33655) genes
were also considered. All matches were expressed relative to our
SHV-1pMON38 sequence or its deduced amino acid sequence. As expected, the DNA and amino acid sequences of
SHV-1pMON38 showed high degrees of homology
(99.20 and 100%, respectively) with those of the SHV-1 enzyme from
GenBank (accession number AF148850). Only 7 nucleotides were found to
be different, and all of them were out of the coding region. The other
sequences were also very homologous, with homologies varying between
98.8 and 100% for DNA sequence homology and 99.3 and 100% for amino acid sequence homology. Seven of the 15 strains that were sequenced and
that were PCR positive for the SHV-1 gene showed amino acid changes
(strains K48, K103, K218, K299, K8, K39, and K154) (Table 3). The amino
acid sequences of isolates K48 and K39 were consistent with that
of SHV-11 (a non-extended-spectrum -lactamase)
(16), and both showed a 7-kb fragment by RFLP
analysis with EcoRI and Southern blotting.
According to the -lactamase nomenclature described on the World
Wide Web (http://www.lahey.org/studies/webt.html), strains K48 and
K39, strains K103 and K218, and strain K154 have already been
designated producers of SHV-31, SHV-27 (6), and SHV-28,
respectively. The remaining two strains (strains K299 and K8)
produce new SHV variants designated SHV-32 and SHV-33, respectively,
and their sequence data are included in the GenBank database under
accession numbers AY037778 and AY037779, respectively.
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The enzyme from one of the TEM-1-type producer strains (strain K263) showed lower levels of DNA (90.9%) and amino acid (90.9%) sequence homology with the DNA and amino acid sequences of SHV-1pMON38 but had higher levels of DNA (98.7%) and amino acid (97.5%) sequence homology with the DNA and amino acid sequences of LEN-1. This strain can also be considered to produce a new variant, in this case, a LEN enzyme (EMBL accession number X04515). Strain K263 was PCR negative and showed an 8.5-kb fragment by RFLP analysis with Southern blotting. In view of these results, the sonic extracts were concentrated by lyophilization and further analyzed by IEF; a clear band with a pI of 7.1, similar to that for LEN-1, was detected. This LEN-1 and SHV-1 allelic variant (strain K263) may indicate that the chromosomal loci for SHV-1 and LEN-1 have a common ancestor; the sequence data for the enzyme from K263, designated LEN-2, will be reported in the GenBank database under accession number AY037780.
Neither differences in promoter regions nor extra triplet stop sequences were observed. Point mutations, which in some cases implied an amino acid change, were the only finding. These point mutations, when found, determined different allelic variants which, in an important number of cases, were the same for different strains (data not shown).
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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IEF clearly showed the high frequency of expression of the pI 7.6 -lactamase in K. pneumoniae. Two -lactamases
combined, usually SHV-1 plus LEN-1 or TEM-1, were also frequently
detected in this and other (7, 10, 20) studies. However,
using a more highly sensitive method (PCR analysis), we demonstrated
the chromosomal location of the SHV-1 gene in K. pneumoniae by detecting the gene in chromosomal DNA. The PCR
method not only permits confirmation of IEF data but also improves the
IEF technique by detecting those strains in which the gene was not
expressed and, subsequently, in which the enzyme could not be detected.
In some strains, poor enzyme expression can result in underestimation
of the presence of the unaltered gene. However, PCR would not
necessarily imply a functional expression of the gene. PCR analyses had
high degrees of specificity for the detection of the SHV-1 gene and
could be useful in studies that test the horizontal propagation of
SHV-1.
Plasmids are frequently found in K. pneumoniae, and
these are mainly self-transferable (>30 kb); however, SHV-1 is
poorly transferred from K. pneumoniae to other
strains, possibly because of its chromosomal location (8).
In conjugation experiments we found that a plasmid-borne SHV-1 gene was
transferred in a few cases, which confirmed our PCR results. The five
donor strains (K75, K167, K136, K175, and K198) had MIC profiles
indicating that they were highly resistant to mezlocillin, probably due
to an extra copy of the gene carried on plasmids. Nevertheless, only two of these transconjugants
those carrying the smaller
multicopy plasmidswere resistant to mezlocillin (TK75, TK167).
The large plasmids were not identified in these particular
transconjugant strains; this fact can probably be explained by the very
small copy number of the large plasmids in the new recipient
host. Moreover, three of the parental strains (strains K75, K167, and
K136) had two large fragments, as determined by RFLP analysis with
Southern blotting, indicating, in addition to the fact that the enzyme is plasmid borne, chromosomal gene duplication (8.5- and 8-kb EcoRI-specific fragments).
RFLP analysis with Southern blotting showed that the SHV-1
-lactamase gene resides in a very conservative 8.5-kb
EcoRI-EcoRI fragment. This region may include the
LEN-1 -lactamase gene in tandem, as deduced from the RFLP profile
found in the TEM-1-producing strains, which were PCR negative, and
sequencing analyses confirmed the presence of an allelic variant of the
LEN-2 gene (Table 3). Additionally, on most occasions, only one
hybridization fragment was found even in samples with strains
expressing both enzymes. In eight strains, the genetic driving force of
this particular region must have evolved to carry a double copy of the
gene, as shown by the presence of two hybridization fragments by RFLP
analysis with Southern blotting. As described above for the strains to which SHV-1 was transferable by plasmids, these strains with a double
copy of the gene were also highly mezlocillin resistant.
DNA sequence analysis showed no differences in the promoter regions
that would have explained the high or the low level of expression of
the SHV-1 gene and the relationship to antibiotic resistance. Recently,
a single A
C mutation at the second position of the 
10 region has
been reported; this mutation confers a high level of expression of the
chromosomally encoded SHV-1 gene and, consequently, resistance to
ceftazidime and piperacillin-tazobactam (21). No
stop-codon sequences or other structures were observed that would have
indicated why in some cases the enzyme is not detected by IEF. Only
dispersed mutations were seen, indicative of an evolution in
clusters (repetitive or conservative point mutations); in some cases,
these mutations were translated into conservative amino acid changes
(Table 3). Some of these allelic variants were also observed in other
studies (6, 8, 16; http://www.lahey.org/studies/webt.html), but some others were new
(those that produce the SHV-32, SHV-33, and LEN-2 enzymes).
In conclusion, our results strongly support the hypothesis that the
ancestor of the SHV-1 -lactamase originated from the K. pneumoniae chromosome. As a result of the RFLP and sequencing analyses, it can be postulated that the loci for the SHV-1 and LEN-1
genes are arranged in tandem (Fig. 3).
However, to clearly confirm this finding, a specific analysis to test
for the LEN-1 gene would clarify the occurrence of the gene and
how close its locus is to that for the SHV-1 gene. It is possible that
environmental antibiotic pressure selected some clustered point
mutations and strains with a duplication of the gene inside the
chromosome. This phenomenon was probably the first step toward transfer
of the gene into a mobile element (a plasmid or transposon), where it
acquired the potential for horizontal distribution to other species, in
which it is plasmid encoded. In this new environment and with
subsequent adaptations, the gene may confer high levels of resistance
under antibiotic pressure.
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ACKNOWLEDGMENTS |
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This work was supported by grants from the Spanish Fondo de Investigación Sanitaria (grants FIS 94/1829 and 92/170).
George A. Jacoby is acknowledged for kindly providing the pMON38 clone. We are also grateful to C. O'Hara for English revision of the manuscript.
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FOOTNOTES |
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* Corresponding author. Mailing address: CID-CSIC, C/Jordi Girona, 18-26, 08034 Barcelona, Spain. Phone: 34-93-400 61 00. Fax: 34-93-204 59 04. E-mail: mglqob{at}cid.csic.es.
Through this study, we wish to posthumously pay our last respects
to Clara Roy, who was the head of the Microbiology Department for many years.
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Antimicrobial Agents and Chemotherapy, October 2001, p. 2856-2861, Vol. 45, No. 10
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.10.2856-2861.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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