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Molecular analysis of high-level ciprofloxacin resistance in Salmonella enterica serovar Typhi and S. Paratyphi A: need to expand the QRDR region?

Published online by Cambridge University Press:  08 August 2008

M. R. CAPOOR
Affiliation:
Department of Microbiology, Vardhman Mahaveer Medical College and Safdarjung Hospital, New Delhi, India
D. NAIR*
Affiliation:
Department of Microbiology, Vardhman Mahaveer Medical College and Safdarjung Hospital, New Delhi, India
N. S. WALIA
Affiliation:
Department of Microbiology, Vardhman Mahaveer Medical College and Safdarjung Hospital, New Delhi, India
R. S. ROUTELA
Affiliation:
Department of Biotechnology, National Institute of Communicable Diseases, New Delhi, India
S. S. GROVER
Affiliation:
Department of Biotechnology, National Institute of Communicable Diseases, New Delhi, India
M. DEB
Affiliation:
Department of Microbiology, Vardhman Mahaveer Medical College and Safdarjung Hospital, New Delhi, India
P. AGGARWAL
Affiliation:
Department of Microbiology, Vardhman Mahaveer Medical College and Safdarjung Hospital, New Delhi, India
P. K. PILLAI
Affiliation:
Department of Microbiology, Majeedia Hospital, New Delhi, India
P. J. BIFANI
Affiliation:
Department of Molecular Biology, Pasteur Institute, Brussels, Belgium
*
*Author for correspondence: Dr D. Nair, D-2/2201, Vasant Kunj, New Delhi-110070, India. (Email: deepthinair2@gmail.com)
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Summary

Fourteen strains of S. Typhi (n=13) and S. Paratyphi A (n=1) resistant to ciprofloxacin were compared with 30 ciprofloxacin decreased-susceptibility strains on the basis of qnr plasmid analysis, and nucleotide substitutions at gyrA, gyrB, parC and parE. In ciprofloxacin-resistant strains, five S. Typhi and a single S. Paratyphi A showed triple mutations in gyrA (Ser83→Phe, Asp87→Asn, Glu133→Gly) and a novel mutation outside the quinolone resistance determining region (QRDR) (Met52→Leu). Novel mutations were also discovered in an isolate (minimum inhibitory concentration 8 μg/ml) in gyrA gene Asp76→Asn and outside the QRDR Leu44→Ile. Out of 30 isolates with reduced susceptibility, single mutation was found in 12 strains only. Genes encoding qnr plasmid (qnr A, qnr B, AAC1-F) were not detected in ciprofloxacin-resistant or decreased-susceptibility strains. Antimicrobial surveillance coupled with molecular analysis of fluoroquinolone resistance is warranted for reconfirming novel and established molecular patterns of resistance, which is quintessential for reappraisal of enteric fever therapeutics.

Type
Original Papers
Copyright
Copyright © 2008 Cambridge University Press

INTRODUCTION

The emergence of multidrug-resistant enteric fever led to use of fluoroquinolones as the first-line of therapy. Unfortunately, broad-spectrum antibacterial activity, affordability and easy availability led to their indiscriminate use in human medicine. Furthermore, nalidixic acid- resistant S. Typhi (NARST) with reduced susceptibility to ciprofloxacin (0·125–1 μg/ml) causing clinical failure emerged worldwide and became endemic in the Indian subcontinent [Reference Threlfall1, Reference Capoor2].

At the molecular level, this was mediated by a single-nucleotide polymorphism (SNP) in the quinolone resistance-determining region (QRDR) of gyrA at Ser83 or Asp87. Resistant isolates harbour ⩾2 mutations in gyrA, gyrB, and topoisomerase (parC and parE). Other mechanisms demonstrated are multi-antibiotic resistance associated efflux pumps (MAR locus, outer membrane proteins), qnr plasmid and up-/down-regulation of operon genes [Reference Levy, Sharma and Cebula3Reference Hirose5]. Experimental evidence from in vitro selection studies suggests that single mutations are associated with low-level flouroquinolone resistance and high-level resistance is built-up by sequential accumulation or perhaps a mixture of target and efflux-related mutations [Reference Lindgren, Karlsson and Hughes6]. These are well documented in non-enteric fever salmonellae and other organisms [Reference Eaves7Reference Ling9], as each target gene mutation reduces the susceptibility by four- to eightfold [Reference Sanders10]. Nonetheless, a recent report observed that for S. Typhi nalidixic acid resistance does not completely predict decreased ciprofloxacin susceptibility [Reference Crump11]. Moreover, the emergence of plasmid-mediated quinolone resistance (PMQR) mediated by QNR, aminoglycoside acetyltransferase (AAC) and Qep A in family Enterobacteriaceae has complicated the understanding of molecular mechanisms of quinolone resistance [Reference Yamane12]. Recent literature cites isolated reports of high-level ciprofloxacin resistance in enteric fever, from India and elsewhere [Reference Renuka13Reference Gaind18]. Studies on molecular analysis of fluoroquinolone resistance in clinical isolates of Salmonella enterica serotype Typhi and Paratyphi A from India are limited [Reference Capoor2, Reference Nair4, Reference Renuka13, Reference Gaind18].

Keeping in mind the prime therapeutic role of ciprofloxacin in enteric fever, an understanding of the mechanisms involved is crucial. Therefore the current study was undertaken to characterize the molecular basis of ciprofloxacin resistance in enteric fever.

METHODS

The present study was conducted in Vardhman Mahaveer Medical College and Safdarjung Hospital, a 1700-bed tertiary-care hospital, and Majeedia Hospital, a referral centre in New Delhi over a period of 1 year and 10 months (December 2004–September 2006). One hundred ninety-eight isolates of S. Typhi and S. Paratyphi A from suspected enteric fever patients were identified by standard biochemical reactions [Reference Old, Collee, Fraser, Marmion and Simmons19] and serotyping with specific antisera (Central Research Institute, Kasauli, India). Socio-demographic (age, gender) and clinical information (antimicrobial management and in-hospital mortality) of the patients in study were noted. The antimicrobial susceptibility of the isolates was determined by disk diffusion method according to CLSI guidelines [20] using: ampicillin (10 μg), chloramphenicol (30 μg), trimethoprim/sulfamethoxazole (cotrimoxazole) (1·25/23·75 μg), nalidixic acid (30 μg), ciprofloxacin (5 μg), ceftriaxone (30 μg), cefixime (5 μg) and cefepime (30 μg). Multidrug resistance (MDR) was defined as simultaneous resistance to ampicillin, chloramphenicol and cotrimoxazole (ACCo). The minimum inhibitory concentration (MIC) for ciprofloxacin, ofloxacin and ceftriaxone was determined by the agar dilution method and for nalidixic acid breakpoint MIC (256 μg/ml and 32 μg/ml) was determined by the agar dilution method according to CLSI guidelines [20]. The agar dilution method to determine MICs was repeated three times and the mean was taken as the final value. Interpretive criteria for sensitive, intermediate and resistant strains for ciprofloxacin were ⩽1 μg/ml, =2 μg/ml and ⩾4 μg/ml and for nalidixic acid ⩽1 μg/ml, =2 μg/ml and ⩾4 μg/ml, respectively, in accordance with CLSI guidelines [20]. Decreased susceptibility to ciprofloxacin was defined as isolates having a MIC of ⩾0·125 μg/ml but ⩽1 μg/ml. The control strain used was E. coli ATCC 25922. Antimicrobial disks and powders used in the study were obtained from Hi Media, Sigma Laboratories (India).

Representative isolates resistant to ciprofloxacin were compared by molecular methods [plasmid analysis (qnr allele), nucleotide substitutions at gyrA, gyrB, parC and parE] with decreased- susceptibility strains at Pasteur Institute, Brussels, Belgium and the National Institute of Communicable Diseases, New Delhi. DNA was extracted according to the protocol for the isolation of genomic DNA from Gram-negative bacteria (Qiagen: Qiamp DNA mini kit) under sterile conditions. Samples (200 μl) were processed in parallel. The species identification of a few strains was carried out by sequencing the 16S rRNA. DNA amplification was performed by polymerase chain reaction (PCR). PCR mixture consisted of 5 μl of extracted DNA in 45 μl PCR mixture composed of 1x buffer (Ozyme, New England Biolabs, Beverly, MA, USA), 0·5 mm MgCl2, 0·24 mm dNTP, 25 pmol of each primer and 1 U Taq polymerase (Ozyme, New England Biolabs). Internal controls were included in all PCR assays consisting of PCR inhibition control as performed for biological extract, positive controls to validate the amplification conditions and negative controls to ensure that there was no PCR/sample cross-contamination. The thermal cycling DNA amplification conditions consisted of 15 min at 95°C for activation of the polymerase, 2 min at 92°C followed by 35 cycles of denaturation at 93°C for 30 s, annealing at 53°C for 30 s, extension at 72°C for 1 min and elongation at 72°C for 8 min. Sequencing was performed on PCR-amplified amplicons by the dideoxy chain-termination method with the Big Dye Terminator Cycle sequencing kit (PerkinElmer, Applied Biosystems, Foster City, CA, USA) and run on a DNA analysis system model 373 (PerkinElmer, Applied Biosystems). PCR amplification and direct DNA sequencing of QRDR regions (gyrA, gyrB, parC, parE genes) was performed according to Giraud et al. [Reference Giraud21], with an ABI prism dye terminator (PerkinElmer, Applied Biosystems) on an ABI 3730 automated sequencer.

The known sequence genes were used for designing primers. Oligonucleotide primers used for PCR assay were:

  • gyrA (F): 5′-CCAGATGT(A/C/T)CG(A/C/T)GATGG-3′(F)

  • gyrA (R): 5′-ACGAAATCAAC(G/C)GT(C/T)TCTTTTTC-3′

  • gyrB5 (F): 5′-AAGCGCGATGGCAAAGAAG-3′

  • gyrB6 (R): 5′-AACGGTCTGCTCATCAGAAAGG-3′

  • parC3 (F): 5′-CGATTTTCCGGTCTTCTTCCAG-3′

  • parC10 (R): 5′-GCAATGCACGAATAAACAACGG-3′

  • parE3 (F): 5′-CCTGATCTGGCTACTGCAACAG-3′

  • parE8 (R): 5′-ATGCGCAAGTGTCGCCATCAG-3′

Nucleotide and deduced amino acids were analysed, using Sequence Navigator Software followed by BLAST at the National Center for Biotechnology Information (NCBI) website (http://www.ncbi.nlm.nih.gov/blast).

The primers used to detect qnr plasmids (5) were: 5′-GGG TAT GGA TAT TAT TGA TAAG-3′ for qnr A and 5′-CTA ATC CGGG CAG CAC TAT TAT-3′ for qnr B and 5′- GTGAATTATTGCGGAATCCAGC for AAC1-F as described by Wang et al. [Reference Wang22] and Nair et al. [Reference Nair4]. PCR and sequencing using the aforementioned primers was performed according to Mammeri et al. [Reference Mammarei23]. After PCR amplification, the DNA was purified with a Quiaquick PCR purification kit (Qiagen, Courtaboeuf, France). Both strands of the amplification products obtained were sequenced with an Applied Biosystems sequencer (ABI 377). The nucleotide and deduced protein sequences were analysed using Sequence Navigator Software followed by BLAST at the NCBI website (http://www.ncbi.nlm.nih.gov/blast).

RESULTS

The most common age group in the study was 20–30 years. The majority were males (64%). Twenty-nine percent of patients were hospitalized and 71% were from the out-patient department. Ciprofloxacin was the drug of choice in out-patients and the therapy was changed to ceftriaxone on therapeutic failure (ciprofloxacin resistance or decreased susceptibility). None of the patients died in hospital. A total of 198 isolates, comprising of 158 (79·8%) S. Typhi and 40 (20·2%) S. Paratyphi A were analysed. Of the 198 isolates studied 25 S. Typhi and five S. Paratyphi A were observed to be resistant to ciprofloxacin. The disk diffusion antimicrobial testing of these 30 isolates revealed the following resistance pattern: ampicillin, 2 (6·7%); chloramphenicol, 5 (16·7%); trimethoprim/sulfamethoxazole, 18 (60%); tetracycline, 18 (60%); nalidixic acid, 30 (100%); ceftriaxone, 1 (3·3%); cefixime, 0 (0%); and cefepime, 1 (3·3%). Multidrug resistance (ACCo) was seen in two (6·7%) of the isolates.

Table 1. Presence of mutations in DNA gyrase, topoisomerase IV and qnrA, qnrB, AAC in S. Typhi (n=13) and S. Paratyphi A (n=1) isolates with resistance to ciprofloxacin

CP, Ciprofloxacin; NP, not present; PUO, pyrexia of unknown origin; QRDR, quinolone resistance determining region; SNO, serial no.; h/o, history of.

Out of a total of 198 isolates reduced susceptibility (0·125–1 μg/ml) was seen in 168 isolates. High-level ciprofloxacin resistance was seen in 25 S. Typhi and five S. Paratyphi A (MICs 8 to ⩾512 μg/ml). MIC 90 for ciprofloxacin and ceftriaxone was 1 μg/ml and 0·25 μg/ml, respectively and MIC 50 for ciprofloxacin and ceftriaxone was 0·5 μg/ml and 0·125 μg/ml, respectively. The MIC 50 and MIC 90 for ofloxacin was identical to that of ciprofloxacin. All ciprofloxacin-resistant and decreased-susceptibility strains had a nalidixic acid MIC breakpoint of ⩾256 μg/ml, with the exception of a single outlier [a nalidixic acid-sensitive S. Typhi (NASST) isolate with decreased susceptibility at 0·25 μg/ml].

Thirteen S. Typhi isolates and a single S. Paratyphi A isolate resistant to ciprofloxacin were selected randomly and compared by molecular methods with 30 decreased-susceptibility strains. Relevant clinical, microbiological (MICs), molecular data of these patients with ciprofloxacin resistance is depicted in Table 1. Eight (57%) patients had history of incomplete fluroquinolone therapy and six (43%) presented fever with no prior antimicrobial therapy on days 2–4.

Table 2. Studies reporting molecular analysis of ciprofloxacin-resistant S. Typhi and S. Paratyphi A from enteric fever patients

MIC, Minimum inhibitory concentration; NP, not present; QRDR, quinolone resistance determining region.

Amongst the ciprofloxacin-resistant isolates, five S. Typhi and a single S. Paratyphi A showed triple mutations in gyrA (Ser83→Phe, Asp87→Asn, Glu133→Gly) and a novel mutation outside the QRDR region (Met52→Leu). Novel mutations were also discovered in an isolate (8 μg/ml) in the gyrA gene Asp76→Asn and outside the QRDR Leu44→Ile. Of note are single replacements at Asp76→Asn (four isolates) and Phe72→Tyr (three isolates) of S. Typhi. Out of 30 isolates with reduced susceptibility, single mutation was seen in 15 strains, six had mutations in gyrA at Asp87→Asn, five at Phe72→Tyr, two at Ser83→Phe and one each at Asp76→Asn and Phe31→Tyr (outside QRDR), substitutions, respectively. No mutations could be detected in 15 isolates. Genes encoding qnr plasmid (qnr A, QNR B, AAC1-F) were not detected in ciprofloxacin-resistant or decreased-susceptibility strains.

DISCUSSION

In the present study, multi-drug resistance (ACCo) was observed in 6·6% of ciprofloxacin strains. A re-emergence of sensitivity to the classical first-line agents has been observed due to their restricted use in the 1990s. The use of quinolone led to a concomitant decrease in susceptibility to ciprofloxacin and nalidixic acid from this region [Reference Capoor2]. All of the NARST isolates had a decreased susceptibility to ciprofloxacin (MIC ⩾0·125 μg/ml). Several workers have corroborated this finding abroad [Reference Capoor2, Reference Renuka13, Reference Wang22]. The MIC 50 and MIC 90 for ofloxacin was identical to that of ciprofloxacin. A single outlier isolate was observed (a NASST isolate with decreased susceptibility to ciprofloxacin at 0·25 μg/ml). This observation has been reported in a recent study [Reference Crump11].

Single Ser83→Phe, Asp87→Asn, Phe72→Tyr substitutions are commonly associated with NARST [Reference Capoor2, Reference Hirose5, Reference Ling9]. Nonetheless, the single mutations seen in NARST isolates at Asp76→Asn in gyrA and Phe31→Tyr outside the QRDR of gyrA are hitherto unknown [Reference Levy, Sharma and Cebula3, Reference Renuka13, Reference Giraud21]. However, substitution at Asp76→Asn has been reported from a ciprofloxacin intermediate strain from a molecular study (2001–2003) from this hospital [Reference Capoor2]. As mutations were not found in 15 NARST strains, other possibilities of mutations present outside the QRDR region or other mechanisms of quinolone resistance possibly exist.

The mechanisms of high-level fluroquinolone resistance in clinical isolates of S. Typhi and S. Paratyphi A are not completely understood, as there are only a few reports on resistance in the literature (Table 2). Most studies, including the present study, give evidence for sequential accumulation of target gene mutations in the QRDR region. In stark contrast to previous communications, in the present study, seven (50%) of the ciprofloxacin-resistant isolates had a single mutation in gyrA Phe72→Tyr (three isolates), and Asp76→Asn (four isolates), sufficient to confer high-level resistance (8–256 μg/ml). This unique observation coupled with the absence of mutations in other topoisomerases and 50% of NARST isolates reinforces the fact that other mechanisms must co-exist to mediate resistance. Moreover, even the MIC of the isolates was unlinked to the number of mutations observed. Substitution at Glu133→Gly has not been observed previously in S. Typhi, S. Paratyphi A, other salmonellae or E. coli [Reference Levy, Sharma and Cebula3, Reference Hirose5, Reference Ling9, Reference Adachi16, Reference Giraud21, Reference Kariuki24]. The mutations at positions 76 and 72 are also infrequently reported; nonetheless, there are a few citations of single substitution at Asp76→Asn and Phe72→Tyr in S. Typhi [Reference Capoor2] and Phe72→Tyr in combination with Ser83→Phe in S. Senftenfberg [Reference Eaves7].

However, the most striking observation was the co-existence of mutations outside the QRDR region (Met52→Leu, Leu44→Ile) in seven strains (50%). In Salmonella, QRDR spans from amino acids 54 to 171 [Reference Adachi16]. Therefore, it is speculated that QRDR of Salmonella should be expanded to include these positions. In a review of the literature, few reports document mutations outside the QRDR domain [Reference Capoor2, Reference Friedman, Lu and Drlica25].

Due to paucity of sequencing data on clinical isolates of ciprofloxacin-resistant S. Typhi and S. Paratyphi A, the aforementioned novel substitutions or observations could not be compared with prior reports. Nevertheless, they may become frequent in future owing to selective pressures exerted by the irrational use of ciprofloxacin in human and veterinary therapeutics, in a population endemic with NARST strains. Meanwhile, more such studies are warranted in order to determine whether such novel mutations, when present alone, confer resistance or decreased susceptibility to ciprofloxacin in vitro or are just ‘bystanders’.

Moreover, the finding of sequential accumulations of mutations is further corroborated by the fact that eight (57%) patients had history of incomplete fluoroquinolone therapy. It is probable, as inferred from their history records that these patients were initially infected with isolates having decrease susceptibility that subsequently mutated to high-level ciprofloxacin isolates. Observation of de novo mutation is supported by the fact that in six patients (43%) prior history of fluoroquinolone was not elicited, therefore, only molecular typing will clarify these relevant issues. In the present study three groups emerged showing mutations at positions 83, 87, 133 and at 72 and 76. The phenotypic expression of level of resistance (MIC) of these groups were heterogeneous. Establishing the clonality, or the lack of it, is therefore critical at this stage in India, as there seems to be an unusually increasing occurrence of high-level ciprofloxacin- resistant S. Typhi.

In the present study genes encoding qnr plasmid (qnr A, QNR B, AAC1-F) were not detected in ciprofloxacin-resistant or decreased-susceptibility strains. These proteins protect the target enzymes (DNA gyrase and type IV topoisomerase) from quinolone inhibition and the AAC enzyme acetylates quinolones. Although these PMQR determinants confer only low-level resistance, nonetheless, they provide a background against which selection of additional chromosomal-encoded quinolone-resistance mechanisms occur. These might become important in future in S. Typhi and S. Paratyphi A as linkage between qnr plasmid, genes encoding extended spectrum β-lactamases and AmpC type β-lactamases may reflect association between resistance to quinolones and extended-spectrum cephalosporins [Reference Yamane12, Reference Wang22].

The limitation of this work is, that epidemiological typing of ciprofloxacin-resistant strains was not performed. Furthermore, investigations for possible mutations at other loci (MAR) and OMP profile, qepA gene, etc., for other mechanisms of resistance were not elucidated. A large number of studies is warranted from this region to find novel target genes thereby aiding in new drug discoveries.

In the present study, MIC 90 and MIC 50 for ceftriaxone were 0·25 μg/ml and 0·125 μg/ml, respectively. A high MIC for the third-generation cephalosporins has also been observed in previous studies [Reference Capoor26, Reference Marano27]. The therapeutics of ciprofloxacin-resistant enteric fever narrows to third- and fourth-generation cephalosporins and azithromycins which are not affordable in nations with limited resources. Of the first-line antimicrobials ampicillin, chloramphenicol and cotrimoxazole, especially chloramphenicol, need to be utilized.

Therefore, antimicrobial surveillance coupled with molecular analysis of fluoroquinolone resistance is warranted for reconfirming novel and established molecular patterns for therapeutic reappraisal and for novel drug targets.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Threlfall, EJ, et al. Ciprofloxacin-resistant Salmonella typhi and treatment failure. Lancet 1999; 353: 15901591.CrossRefGoogle ScholarPubMed
2. Capoor, MR, et al. Salmonella enterica serovar Typhi: molecular analysis of ciprofloxacin decreased susceptibility and resistant isolates from India (2001–2003). Brazilian Journal of Infectious Diseases 2007; 11: 423425.CrossRefGoogle ScholarPubMed
3. Levy, DD, Sharma, B, Cebula, TA. Single-nucleotide polymorphism mutation spectra and resistance to quinolones in Salmonella enterica serovar enteritidis with a mutator phenotype. Antimicrobial Agents and Chemotherapy 2004; 48: 23552363.CrossRefGoogle ScholarPubMed
4. Nair, S, et al. Molecular analysis of fluoroquinolone-resistant Salmonella Paratyphi A isolate, India. Emerging Infectious Diseases 2006 12: 489491.CrossRefGoogle ScholarPubMed
5. Hirose, K, et al. DNA sequence analysis of DNA gyrase and DNA topoisomerase in the quinolone resistance determining regions of Salmonella enterica serovar Typhi and serovar Paratyphi A. Antimicrobial Agents and Chemotherapy 2002; 46: 32493252.CrossRefGoogle ScholarPubMed
6. Lindgren, PK, Karlsson, ASA, Hughes, D. Mutation rate and evolution of fluroquinolone resistance in E. coli isolates from patients in urinary tract infections. Antimicrobial Agents and Chemotherapy 2003; 47: 32223232.CrossRefGoogle Scholar
7. Eaves, DJ, et al. Prevalence of mutations within the quinolone resistance determining region of gyrA, gyrB, parC, and parE and association with antibiotic resistance in quinolone-resistance Salmonella enterica. Antimicrobial Agents and Chemotherapy 2004; 48: 40124015.CrossRefGoogle ScholarPubMed
8. Baucheron, S, et al. High level resistance to fluoroquinolones linked to mutations in gyr A, par C and par E in Salmonella enterica serovar Schwarzengrund isolated from humans in Taiwan. Antimicrobial Agents and Chemotherapy 2005; 49: 862863.CrossRefGoogle Scholar
9. Ling, JM, et al. Mutations in topoisomerase genes of fluoroquinolone resistant Salmonella in Hong Kong. Antimicrobial Agents and Chemotherapy 2003; 47: 35673573.CrossRefGoogle ScholarPubMed
10. Sanders, CC. Mechanisms responsible for cross-resistance and dichotomous resistance among quinolones. Clinical Infectious Diseases 2001; 32: 8188.CrossRefGoogle ScholarPubMed
11. Crump, JA, et al. Clinical response and outcome of infection with Salmonella enterica serotype Typhi with decreased susceptibility to fluoroquinolones: a United Stat FoodNet Multicenter Retospective Cohort study. Antimicrobial Agents and Chemotherapy 2008; 52: 12781284.CrossRefGoogle Scholar
12. Yamane, K, et al. New plasmid-mediated fluoroquinolone efflux pump, QepA, found in an Escherichia coli clinical isolate. Antimicrobial Agents and Chemotherapy 2007; 51: 33543360.CrossRefGoogle Scholar
13. Renuka, K, et al. High-level ciprofloxacin resistance in Salmonella enterica serovar Typhi in India. Journal of Medical Microbiology 2005; 54: 9991000.CrossRefGoogle ScholarPubMed
14. Capoor, MR, et al. Enteric fever perspective in India: emergence of high-level ciprofloxacin resistance and rising MIC to cephalosporins. Journal of Medical Microbiology 2007; 56: 11311132.CrossRefGoogle ScholarPubMed
15. Kownhar, H, et al. Emergence of nalidixic acid-resistant Salmonella enterica serovar Typhi resistant to ciprofloxacin in India. Journal of Medical Microbiology 2007; 56: 136137.CrossRefGoogle ScholarPubMed
16. Adachi, T, et al. Fluoroquinolone-resistant Salmonella enterica serovar Paratyphi A. Emerging Infectious Diseases 2005; 11: 172174.CrossRefGoogle Scholar
17. Saha, SK, et al. Molecular basis of resistance displayed by highly-ciprofloxacin resistant Salmonella enterica serovar Typhi in Bangladesh. Journal of Clinical Microbiology 2006; 44: 38113813.CrossRefGoogle ScholarPubMed
18. Gaind, R, et al. Molecular characterization of ciprofloxacin-resistant Salmonella enterica serovar Typhi and S. Paratyphi A causing enteric fever in India. Journal of Antimicrobial Chemotherapy 2006; 58: 11391144.CrossRefGoogle ScholarPubMed
19. Old, DC. Salmonella. In: Collee, JG, Fraser, AG, Marmion, BP, Simmons, A eds. Mackie and McCartney Practical Medical Microbiology, 14th edn. New York: Churchill Livingstone, 1996, pp. 385404.Google Scholar
20. Clinical and Laboratory Standards Institute. Performance standards for antimicrobial susceptibility testing. CLSI document (M100-S16), p. 26. Clinical and Laboratory Standards Institute, 2007. Wayne, Pennsylvania.Google Scholar
21. Giraud, E, et al. Comparative study of animal isolates and experimental in vitro- and in vivo-selected mutants of Salmonella spp. suggest a counterselection of highly fluoroquinolone-resistant strains in the field. Antimicrobial Agents and Chemotherapy 1999; 43: 2131–2037.CrossRefGoogle ScholarPubMed
22. Wang, M, et al. Plasmid-mediated Quinolone resistance in clinical isolated in clinical isolates of Escherichia coli from Shanghai, China. Antimicrobial Agents and Chemotherapy 2003; 47: 22422248.CrossRefGoogle ScholarPubMed
23. Mammarei, H, et al. Emergence of plasmid-mediated quinolone resistance in Escherichia coli in Europe. Antimicrobial Agents and Chemotherapy 2005; 49: 7176.CrossRefGoogle Scholar
24. Kariuki, S, et al. Genotypic analysis of multidrug-resistant Salmonella enterica serovar Typhi, Kenya. Emerging Infectious Diseases 2000; 6: 649651.CrossRefGoogle ScholarPubMed
25. Friedman, SM, Lu, T, Drlica, K. Mutation in the DNA Gyrase A gene of Escherichia coli that expands the quinolone resistance-determining region. Antimicrobial Agents and Chemotherapy 2001; 45: 23782380.CrossRefGoogle ScholarPubMed
26. Capoor, MR, et al. In vitro activity of azithromycin, newer quinolones and cephalosporins in ciprofloxacin resistant Salmonella causing enteric fever. Journal of Medical Microbiology 2007; 58: 14901494.CrossRefGoogle Scholar
27. Marano, NK, et al. Emerging quinolone and extended spectrum cephalosporin resistant Salmonella in the United States. American Society for Microbiology, 99th General Meeting. Chicago, IL, May 1999.Google Scholar
Figure 0

Table 1. Presence of mutations in DNA gyrase, topoisomerase IV and qnrA, qnrB, AAC in S. Typhi (n=13) and S. Paratyphi A (n=1) isolates with resistance to ciprofloxacin

Figure 1

Table 2. Studies reporting molecular analysis of ciprofloxacin-resistant S. Typhi and S. Paratyphi A from enteric fever patients