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Antimicrobial Agents and Chemotherapy, January 2001, p. 88-95, Vol. 45, No. 1
Department of Pharmacy and Pharmacology,
University of Durban-Westville, Durban, 4000,1
and Department of Medical Microbiology, University of Natal,
Congella, 4013,3 South Africa, and
Department of Medical Microbiology, St. Bartholomew's and
the Royal London School of Medicine and Dentistry, London E1
2AD,2 and Antibiotic Resistance
Monitoring and Reference Laboratory, Central Public Health
Laboratory, London NW9 5HT,4 United Kingdom
Received 10 January 2000/Returned for modification 25 April
2000/Accepted 10 October 2000
Most ESBLs are variants of the classical TEM and SHV Although the primary purpose of the study was identification of the
types of enzymes produced in South African isolates, the major finding
was the remarkable diversity and complexity of Bacterial cultures.
The 25 K. pneumoniae isolates
investigated were from clinical material collected at the King Edward
VIII Hospital in Durban (Table 1). This government-run institution is
one of the largest tertiary-care hospitals in southern Africa, with
2,000 beds. Twelve isolates were collected during September and October
1994, and 13 were collected during June and July 1996. These organisms
were selected solely because they were reported to be resistant to one
or more oxyimino-aminothiazolyl cephalosporins by the diagnostic laboratory. The species of the organisms were verified by tests with
the API 20E system (bioMerieux, Lyons, France). Isolates 117, 118, 122, and 202 were collected from a single patient (patient I) within 7 days
in 1994; isolates 4183, 4265, 4744, and 8143 were collected from
patient II within 1 month in 1996, and isolates 4175 and 4291 were
collected from patient III within 6 days in 1996. Reference producers
of SHV and TEM enzymes were described previously (18).
Escherichia coli NCTC 50192 served as a source of plasmid
markers (16).
Susceptibility testing.
Susceptibility tests and ESBL
detection were performed on Mueller-Hinton agar by Etests, which were
used according to the manufacturer's directions (AB Biodisk, Solna, Sweden).
Strain typing.
Total DNA was extracted from the isolates,
restricted with XbaI (Promega, Madison, Wis.), and
fingerprinted by pulsed-field gel electrophoresis (PFGE). Methods were
as described previously (6).
Sequencing of TEM and SHV genes.
DNA fragments corresponding
in size to those carrying Plasmid profiles and transfers.
Plasmids were extracted and
electrophoresed by the method of Kado and Liu (14), with
E. coli NCTC 50192 (16) used as a source of
molecular weight markers.
Nucleotide sequence accession numbers.
The nucleotide
sequence accession numbers for novel Strain structure and ESBL production.
Table
1
summarizes the strain types, plasmid
profiles, and
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.1.88-95.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Complexity and Diversity of Klebsiella
pneumoniae Strains with Extended-Spectrum
-Lactamases Isolated
in 1994 and 1996 at a Teaching Hospital in Durban, South
Africa
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-Lactamase production was investigated in cultures of 25 Klebsiella pneumoniae isolates isolated at a hospital in
Durban, South Africa, in 1994 and 1996. Twenty of these isolates gave ceftazidime MIC/ceftazidime plus clavulanate MIC ratios of 
8, implying production of extended-spectrum -lactamases (ESBLs), and
DNA sequencing identified an ESBL gene
(blaTEM-53) in a further two isolates.
Pulsed-field gel electrophoresis (PFGE) defined 4 distinct strains
among the 12 isolates collected in 1994 and 9 distinct strains among
the 13 isolates collected in 1996. In three cases, multiple isolates
from single patients varied in their PFGE profiles and antibiograms,
implying mixed colonization or infection. Isoelectric focusing and DNA
hybridization found both TEM and SHV enzymes and their genes in all 25 isolates. Many isolates had multiple identical or different
-lactamase gene variants, with at least 84 blaSHV and blaTEM gene
copies among the 25 organisms. Sequencing identified the genes for the
SHV-1, -2, and -5 enzymes and for four new SHV types (SHV-19, -20, -21, and -22). These new SHV variants had novel mutations remote from sites
known to affect catalytic activity. Sequencing also found the genes for
TEM-1, TEM-53, and one novel type, TEM-63. All the isolates had
multiple and diverse plasmids. These complex and diverse patterns of
ESBL production and strain epidemiology are far removed from the
concept of an ESBL outbreak and suggest a situation in which ESBL
production has become endemic and in which evolution is generating a
wide range of enzyme combinations. This complexity and diversity
complicates patient management and the design of antibiotic use policies.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-Lactams are prescribed more
often than any other antibiotics. This heavy usage has selected for
resistance, which is most often caused by -lactamases
(17). Recent concerns have centered on extended-spectrum
-lactamases (ESBLs), which are an increasing problem in members of
the family Enterobacteriaceae in general and especially in
Klebsiella spp.
-lactamases,
but with one or more amino acid substitutions (22, 25; G. A. Jacoby and K. Bush, Amino acid sequences for TEM, SHV, and OXA extended-spectrum and inhibitor-resistant -lactamases
[http://www.lahey.org/studies/webt.htm]). These changes alter the
catalytic center, permitting hydrolysis of oxyimino-aminothiazolyl
cephalosporins. ESBLs have been reported worldwide, but most studies
have examined producers collected in Europe, North America, and
Southeast Asia (17, 25), and only a few (2)
have examined bacteria collected in Africa (20). To
redress this situation, we investigated -lactamase types, including
ESBLs, in nosocomial Klebsiella pneumoniae isolates collected at a major teaching hospital in Durban, Kwazulu-Natal, South Africa.
-lactamase and strain
types among the small number of isolates examined.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-Lactamase typing.
Isoelectric focusing was performed on
ultrasonic extracts by a protocol described elsewhere
(19). Genes for TEM and SHV -lactamases were detected
by hybridization. Briefly, total DNA was extracted from the isolates as
described previously (11) and was restricted with
SalI for detection of blaSHV and
variously (see Results) with BamHI, HindIII,
or HincII for detection of blaTEM.
Restriction conditions were those suggested by the enzyme supplier
(Promega). The restricted DNA was electrophoresed on 0.9% agarose
gels, which were Southern blotted (24) and then hybridized
with gene probes for blaSHV or
blaTEM. These probes were generated from
reference strains by PCR with primers 5'-ATGAGTATTCAACATTTCCGTG (positions 1 to 22, as numbered from the start of the
enzyme-coding region) and 5'-TTACCAATGCTTAATCAGTGAG
(positions 861 to 840) for blaTEM and with
5'-ATGCGTTATATTCGCCTGTG (positions 1 to 20) and 5'-GTTAGCGTTGCCAGTGCTCG (positions 865 to 846) for
blaSHV. PCR conditions for
blaTEM comprised a thermal ramp to 95°C for 3 min, followed by 30 cycles of 95°C for 1 min, 55°C for 1 min, and
72°C for 1 min; those for blaSHV comprised
95°C for 3 min and then 30 cycles of 94°C for 15 s, 60°C for
30 s, and 72°C for 1 min, followed by 5 min at 72°C.
Hybridization was performed at 65°C under the conditions described by
Sambrook et al. (24) with blaSHV
and blaTEM gene probes generated from reference
strains by PCR with the primers described above and labeled with
digoxygenin (DIG DNA Labeling and Detection Kit; Boehringer Mannheim,
Mannheim, Germany). The sizes of the restriction fragments were
estimated by comparison with a 1-kb DNA ladder (Gibco BRL, Paisley, Scotland).
-lactamase genes were excised from 0.9%
agarose gels that had been electrophoresed overnight at 46 V. The TEM
and SHV genes were then amplified by PCR as described above. Only
BamHI-restricted DNA was used as a source of
blaTEM genes. The products were cleaned with
either a QIAquick Gel Extraction or a PCR Purification kit (Qiagen,
Crawley, West Sussex, United Kingdom) and were then sequenced with an
ABI Prism Dye Terminator Cycle Sequencing Ready Reaction kit with
AmpliTaq DNA Polymerase FS (Perkin-Elmer, Branchburg, N.J.). A GeneAmp
PCR System 2400 (Perkin-Elmer) was used and was operated in accordance
with the manufacturer's protocols. The extension products were
purified by Ethanol Precipitation Protocol 1 (Perkin-Elmer) and were
then loaded onto an ABI Prism 377 sequencer (Perkin-Elmer). The primers
for sequencing blaTEM were
5'-TTCTGTGACTGGTGAGTACT (positions 324 to 305),
5'-GAGTAAGTAGTTCGCCAGTT (positions 595 to 576), and
5'-TTACCAATGCTTAATCAGTGAG (positions 861 to 840); those for
blaSHV were 5'-ATGCGTTATATTCGCCTGTG
(positions 1 to 20), 5'-CGTTTCCCAGCGGTCAAGG (positions
489 to 471), and 5'-GTTAGCGTTGCCAGTGCTCG (positions 865 to
846). All sequences were confirmed by two independent determinations
and were analyzed with Sequence Navigator software (Perkin-Elmer). All
the sequences were confirmed by two independent PCR experiments.
-lactamase genes in GenBank
were as follows: blaTEM-63, AF045475; blaSHV-19, AF117743;
blaSHV-20, AF117744;
blaSHV-21, AF117745; and
blaSHV-22, AF117746.
RESULTS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-lactamase characteristics for the isolates, and Table
2 shows the MIC data. Isolates were
categorized as putatively ESBL positive on the basis of ratios of the
MIC of ceftazidime to the MIC of ceftazidime plus clavulanate of 8 or
more. Twenty isolates were ESBL positive on the basis of this
criterion, with MIC ratios ranging from 8 to >128. For five isolates
MIC ratios were less than 8, and it was inferred that the isolates
lacked ESBLs, although two of these (isolates 117 and 118) later proved
to have blaTEM-53, which may not have been
expressed (see below). Among the organisms collected in 1994, isolates
79, 113, 114, and 122 gave PFGE restriction patterns identical to each
other and it was inferred that they belong to an outbreak strain type,
designated the type A strain. Isolates with PFGE patterns that differed
from that of the type A strain by two or three fragments were
categorized as subtypes of this strain. Thus, isolates 10 and 202 were
designated subtype A1, isolate 73 was designated subtype A2, and
isolates 91 and 117 were designated subtype A3. The other isolates
collected in 1994 differed from outbreak strain type A and each other
by 10 or more PFGE bands and were designated strain types B to D. Of the organisms collected in 1996, isolate 4291 belonged to type A, and
isolate 4495 gave a similar profile and was designated subtype A4,
whereas all the other organisms gave profiles unrelated to those seen
among isolates collected in 1994. Isolates 4120 and 4448 differed by
three fragments by PFGE and were designated types F and F1,
respectively; the other isolates collected in 1996 differed from types
A to F and from each other by 10 bands and were designated types G to
L. In 1994, patient I yielded isolates 122 (type A), 202 (subtype A1),
117 (subtype A3), and 118 (type C). Isolates 4175 (type G) and 4291 (type A) were both collected from patient II in 1996 but were
unrelated. Isolates 4265, 4744, and 8143 were collected from patient
III in 1996, and all belonged to type E; isolate 4183 was from the same
patient but belonged to type H.
TABLE 1.
Epidemiology, phenotypes, and -lactamase genes of
K. pneumoniae isolates collected in 1994 and 1996
TABLE 2.
MICs for isolates collected in 1994 and 1996
-Lactamase identification.
Five electrofocusing profiles
were found among the isolates collected in 1994 and eight were found
among those collected in 1996. The isolates expressed one to five
-lactamases each. Most isolates appeared to produce both TEM and SHV
enzymes, as evidenced by isoelectric focusing bands in the regions
typical of both enzyme families (pI 5.4 to 6.3 and pI 7.0 to 8.2, respectively). DNA hybridization confirmed this inference, detecting
both blaTEM and blaSHV
genes in all 25 isolates, including those for which the ceftazidime
MIC/ceftazidime plus clavulanate MIC ratios were less than 8. Many
isolates carried multiple blaTEM and
blaSHV copies, as demonstrated by the
hybridization of probes with multiple restriction fragments (Table 1).
Among the ESBL producers collected in 1994, 3 had two
blaTEM copies and 1 had two
blaSHV copies; among 12 ESBL producers collected
in 1996, 6 had two blaTEM copies and 5 had three
copies; all 12 had two blaSHV copies. In 13 isolates, the multiple gene copies encoded the same -lactamase; in 7 isolates different enzyme variants were encoded within an isolate. To
identify some of the enzymes, DNAs corresponding to individual
restriction fragments were excised and sequenced. In the case of
the blaTEM variants, sequencing was
undertaken only with fragments from BamHI-restricted DNA,
not for additional TEM-encoding fragments revealed after digestion with
HindIII or HincII. The latter fragments may
have encoded additional enzyme variants.
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-lactamases corresponded with the
detection of blaSHV. Isolates 4175, 4265, 4291, 4495, 4700, and 4824 had classical SHV-1, whereas isolates 10, 73, 79, 91, 97, 113, 114, 117, 118, 122, 202, and 4448 had a novel variant, SHV-19, with Leu173Phe (Table 3). Isolates 571, 4120, 4291, 4634, and
4699 had the SHV-2 enzyme, whereas isolates 4183, 4699, and 4824 had a
novel SHV-2 variant, SHV-20, with the Leu173Phe substitution (which is
also seen in SHV-19) as well as the Gly238Ser mutation that
distinguishes SHV-2 from SHV-1. Isolate 571 had SHV-21, which was
identical to SHV-20 except for Leu122Phe. The SHV-5 -lactamase was
found in isolates 4183, 4265, 4448, 4495, 4744, and 8143. Isolate 8143 additionally had SHV-22, an SHV-5 variant with Asn158Lys. The presence
of a pI 8.2 band in extracts of isolate 4634 implied that it, too,
might have the SHV-5 enzyme, but this was not confirmed by sequencing.
The novel substitutions in SHV-19, -20, -21, and -22 were remote from
those positions (positions 35, 39, 43, 69, 104, 164, 179, 205, 237, 238, 240, 244, 245, 265, and 276) normally associated with ESBL
activity in the SHV family (2), and the kinetics of these
enzymes were not studied. Several isolates had -lactamase activities
with pIs of 6.3 and 6.8 (Tables 1 and 2). These may have been distinct
non-TEM, non-SHV types, but they were not pursued.
-Lactamases and resistance.
The 20 isolates that were
phenotypically ESBL positive were resistant to piperacillin (MICs,
>256 µg/ml). Eighteen were susceptible to piperacillin-tazobactam
(MICs, 
16 and 4 µg/ml, respectively), 16 were susceptible to
amoxicillin-clavulanate (MICs, 8 and 4 µg/ml, respectively), and 7 were susceptible to ampicillin-sulbactam (MICs, 8 and 4 µg/ml,
respectively). The MICs of oxyimino-aminothiazolyl cephalosporins were
very variable among these 20 ESBL producers; those of ceftazidime were
1 µg/ml for all the isolates and 4 µg/ml for 19 of 20 isolates;
the MICs of cefepime were consistently 4 µg/ml but were two- to
sixfold higher than those for ESBL nonproducers. Four of the five
isolates for which ceftazidime MIC/ceftazidime plus clavulanate MIC
ratios were below 8, including those with blaTEM-53 (isolates 117 and 118), were fully
susceptible to oxyimino-aminothiazolyl cephalosporins (MICs, <1
µg/ml). The exception was isolate 4175, which had low-level
resistance to these cephalosporins (MICs 1 to 4 µg/ml) (Table 2).
Susceptibility to piperacillin, amoxicillin-clavulanate, and
ampicillin-sulbactam was variable among these five isolates (Table 2),
but all were susceptible to piperacillin-tazobactam (MICs, 4 plus 4 µg/ml, respectively), aztreonam (MICs, 1 µg/ml), and cefoxitin
(MICs, 2 µg/ml).
Plasmid profiles. Nine different plasmid profiles were observed among the 12 isolates collected in 1994 and 11 different plasmid profiles were observed among the 13 isolates collected in 1996 (Table 1). Isolates had one to seven plasmid bands ranging in size from 5 to 186 kb. Some isolates belonging to the same strain had similar plasmid profiles (e.g., isolates 10 and 73, isolates 113 and 114, and isolates 4265, 4744, and 8143), but there was also much variation in the profiles within the strains defined by PFGE.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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We examined small numbers of K. pneumoniae isolates
reported to be resistant to one or more oxyimino-aminothiazolyl
cephalosporins at King Edward VIII Hospital in Durban, South Africa, in
2-month periods in 1994 and 1996. These organisms proved to be
remarkably complex and diverse in their resistance patterns,
-lactamase combinations, and plasmid profiles. Twenty of the
isolates had an ESBL phenotype, defined as a ceftazidime
MIC-ceftazidime plus clavulanate MIC ratio of 8 or more. Two further
isolates gave ceftazidime MIC/ceftazidime plus clavulanate MIC ratios
below 8 but carried blaTEM-53, which should give
a mature product identical to TEM-12 (7; Jacoby and Bush,
http://www.lahey.org/studies/webt./htm). The susceptibilities of
the latter two isolates was perhaps explicable by the low level of
expression of the TEM-53 gene, a view supported by the absence of
electrofocusing bands with the characteristically low pI (pI 5.2) of
TEM-12 (Table 1) (7). However, TEM-12 is among the weakest
ESBLs (17, 19), and the susceptibilities of these
producers may reflect the low level of activity of this enzyme against
oxyimino-aminothiazolyl cephalosporins.
The ESBL producers included multiple subvariants of one strain (PFGE
type A), smaller clusters of representatives of other strains (e.g.,
types E and F), and a diverse scatter of single isolates (types B to D
and G to L). Even within strains of types A and E, there was scatter in
their antibiogram, plasmid profile, and -lactamase types. Previous
work on a multicenter collection of K. pneumoniae isolates
with ESBLs from European intensive care units (ICUs) likewise revealed
mixtures of epidemic and nonepidemic strains in many hospitals and
found considerable microdiversity within epidemic strains in terms of
their antibiogram, plasmid profile, and, to a lesser extent,
-lactamase subtypes (29). Others, likewise, have
described heterogeneity within outbreak strains of ESBL-producing
K. pneumoniae strains (3, 10, 27). The
diversity of ESBL producers and the variations within the ESBL-positive
strains were not, therefore, surprising. What was remarkable was the
complexity of the present isolates. Specifically (i) three individual
patients (patients I, II, and III) each yielded two different strains
of klebsiellae over brief periods, (ii) many isolates carried multiple
identical or different blaTEM and blaSHV gene variants, and (iii) one new TEM
variant and four new SHV variants were found among only 25 isolates.
Patient I yielded isolates 117, 118, 122, and 202 over 7 days in 1994. Among these, isolates 117, 122, and 202 belonged to type A, whereas
isolate 118 was of a distinct type. All four isolates had the SHV-19
enzyme but differed in their TEM variants, with TEM-53 (maybe not
expressed) detected in isolates 117 and 118, TEM-1 detected in isolate
122, and TEM-63 detected in isolate 202. In 1 week in 1996, patient II
yielded isolates 4175 and 4291, which belonged to different strain
types. Also in 1996, patient III yielded isolates 4183, 4265, 4744, and
8143 over a period of 1 month: isolate 4183 belonged to a unique PFGE
type (type H), whereas the other three isolates were of PFGE type E. The type E isolates from patient III consistently had the SHV-5
-lactamase but varied in the other SHV-type enzymes present
(variously none, SHV-1, and SHV-22) and in whether or not multiple
copies of blaTEM and
blaSHV-5 were present. Most of the multiple
isolates from patients II and III were from endotracheal aspirates, and
it is not difficult to envisage colonization of the airways with
multiple Klebsiella strains. The results for patient I were
rather more surprising, insofar as three of the four isolates,
including the unique isolate (isolate 118) were from peritoneal fluid
or abdominal pus, suggesting a mixed infective population. Sequential
or simultaneous isolation of unrelated strains of E. coli
and K. pneumoniae from individual patients has been reported
by others (4, 6, 13, 26), and Weller et al.
(27) reported that multiple subvariants of a strain could
persist in an infective population without any one becoming dominant.
All the isolates had both the blaTEM and
blaSHV genes, and 20 isolates had multiple
copies of one or both of these genes. Carriage of multiple copies was
more frequent among the isolates collected in 1996 (29 blaTEM copies and 26 blaSHV copies among 13 isolates) than among
those collected in 1994 (16 blaTEM copies and 13 blaSHV copies among 12 isolates). The greater
proportion of isolates with three or more enzymes in 1996 may imply
that complexity was increasing with time, but comparison is confounded by the small numbers of isolates, because an epidemic strain (strain A)
was more prevalent in 1994, and because we cannot discount ESBL loss
during storage. It should also be reemphasized that the present results
almost certainly underestimated the prevalences of the
blaSHV and blaTEM genes,
as the use of different restriction endonucleases increased the number
of blaTEM-bearing fragments identified, and the
same effect might be anticipated if multiple endonucleases had been
used before probing for blaSHV. Moreover, one
route to -lactamase hyperproduction is gene amplification (20), and with restriction enzymes lacking internal sites
in the TEM and SHV genes (i.e., BamHI,
HindIII, and SalI), only one hybridizing
fragment would be generated regardless of whether a TEM or SHV gene
existed alone or was flanked by copies of itself. With
HincII (which has a site internal to
blaTEM), each blaTEM copy
would yield two hybridizing fragments, whereas two or more linked
copies would still yield only three different sizes of hybridizing
fragments. The presence of multiple gene copies increases the
likelihood of enzyme hyperproduction, potentially increasing resistance
to weak substrates and -lactamase inhibitor combinations (17). Nevertheless, most of the present isolates were
susceptible to piperacillin-tazobactam (23 of 25 isolates) and
amoxicillin-clavulanate (17 of 25 isolates). Multiple TEM
-lactamases have previously been found in single isolates (5,
21), as have combinations of TEM and SHV enzymes (8, 12,
28). Simultaneous production of multiple SHV ESBLs by single
isolates has rarely been reported previously, and we believe that the
present study is the first to record definitively isolates with
multiple ESBLs of both the TEM and SHV families, although a similar
situation was inferred from electrofocusing data by Yang et al.
(28).
A novel TEM -lactamase, TEM-63, was found in five isolates.
It had four substitutions compared with the sequence of
TEM-1: Leu21Phe, which lies in the signal peptide (9);
Glu104Lys, which occurs in many TEM ESBLs (15);
Arg164Ser, which widens the binding cavity to accommodate the
bulky side chains of oxyimino-aminothiazolyl cephalosporins
(15); and Met182Thr. Met182Thr also occurs in several
inhibitor-resistant TEM -lactamases (15) and in the TEM-43 ESBL (28); it augments rather than causes inhibitor
resistance (15), and the present TEM-63 producers were
susceptible to the inhibitor combinations tested (Table 2). TEM-63 has
also been described from K. pneumoniae, E. coli,
and Proteus mirabilis strains isolated in Durban,
Johannesburg, and Cape Town, South Africa (13), and this
enzyme, which has not been found elsewhere, may be locally prevalent in
South Africa.
Besides TEM-63, four new blaSHV variants were
found and numbered SHV-19 to SHV-22. SHV-19 was found in 12 isolates,
including 9 of 11 representatives of type A; it was distinguished from
SHV-1 by Leu173Phe, a conservative substitution remote from any site associated with ESBL activity but lying within the omega loop. This
mutation site and the lack of resistance to oxyimino-aminothiazolyl cephalosporins in organisms with SHV-19 plus TEM-1 (isolates 97 and
122) argue against the SHV-19 enzyme being an ESBL. SHV-20 likewise had
Leu173Phe but also had the Gly238Ser substitution, which is almost
universal in SHV ESBLs and which is the sole feature that distinguishes
the SHV-2 -lactamase from SHV-1 (15). SHV-20 therefore
has the same relationship to SHV-2 that SHV-19 has to SHV-1. SHV-21 had
both the substitutions present in SHV-20 and Leu122Phe, another
conservative substitution remote from any site known to be associated
with ESBL activity. The remaining mutant, SHV-22, resembled SHV-5 in
having both Gly238Ser and Glu240Lys, but additionally, it had
Asn158Lys, which affected another site not known to be associated with
ESBL activity.
SHV-19 was predominantly found in isolates of type A but was not exclusive to this lineage, being found also in isolates of types B, C, and F1. Other enzymes with Leu173Phe, specifically, isolates with SHV-20 and SHV-21, were found in non-type A strains, and this mutation is also present in SHV-23, which was found in a K. pneumoniae isolate collected at the same hospital in 1990 (unpublished data). It seems that SHV variants with Leu173Phe are something of a local feature at King Edward VIII Hospital; whether they occur elsewhere in South Africa remains unknown.
In summary, the present study showed that ESBL dissemination at King
Edward VIII Hospital reflected the evolution and spread of multiple
different enzymes and strains. Even klebsiellae (ESBL producing or not)
from single patients varied, belonging to different strain types and
having different -lactamases. Many of the ESBL producers had
multiple identical or different blaTEM and
blaSHV copy numbers. Some of these gene copies
encoded TEM-63, a novel ESBL, and others encoded SHV-19 to SHV-22. In
this situation of complexity and diversity, the concept of an ESBL
outbreak is redundant; such complexity complicates the design of
reliable antibiotic use policies, as well as the molecular
biology-based investigations of resistance.
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ACKNOWLEDGMENTS |
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Sabiha Y. Essack is grateful to the Wellcome Trust for a Travelling Fellowship (no. 048863/Z/96/Z) and to the Medical Research Council of South Africa. We are indebted to Brigid Duke for technical support.
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FOOTNOTES |
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* Corresponding author. Mailing address: Antibiotic Resistance Monitoring and Reference Laboratory, Central Public Health Laboratory, 61 Colindale Ave., London NW9 5HT, United Kingdom. Phone: 0208-200-4400. Fax: 0208-200-7449. E-mail: DLivermore{at}phls.nhs.uk.
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Antimicrobial Agents and Chemotherapy, January 2001, p. 88-95, Vol. 45, No. 1
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.1.88-95.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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