Fluoroquinolone and other antimicrobial resistance in invasive pneumococci, Hong Kong, 1995-2001.
The emergence of antimicrobial resistance in Streptococcus pneumoniae worldwide is an important public health issue because this organism is the leading cause of many infections, particularly community-acquired pneumonia. In many countries, rates of resistance for penicillin, macrolides, and tetracyclines have reached levels of 30% to 40% or higher and are increasing. In recent years, the emergence of fluoroquinolone resistance is being increasingly recognized among multidrug-resistant strains of S. pneumoniae. Hong Kong, Ireland, Canada, and Spain have reported increasing rates of fluoroquinolone resistance among S. pneumoniae (1-3). So far, reports on fluoroquinolone resistance in S. pneumoniae have predominantly involved respiratory tract isolates, and whether this type of resistance is emerging among the invasive isolates is unknown. In this study, we evaluated the comparative activities el" five fluoroquinolones against invasive isolates of S. pneumoniae from Hong Kong that were collected during a period when fluoroquinolone resistance had increased rapidly among noninvasive respiratory isolates.
Materials and Methods
Stored isolates of S. pneumoniae were obtained from the blood and cerebrospinal fluid (CSF) of patients admitted to five hospitals in Hong Kong during 1995 to 2001. These five hospitals were chosen because they represent the same sentinel network that participated in an earlier study conducted by the same group (4). One hospital did not store the isolates and thus was not included in the present study. The following numbers of isolates were obtained from each of the hospitals: A (140 isolates from 1995 to 2001), B (22 isolates from 1996 to 2001), C (34 isolates from 1997 to 2001), D (64 isolates from 1998 to 2001), and E (5 isolates from 2001). All are public hospitals that provide acute patient care, including all the major specialties. Hospital A is a university teaching hospital with a bone marrow transplant unit, and the others are regional hospitals. Hospitals A and B are located in the same region, and they together serve a population of approximately 1.4 million. Hospitals C, D, and E serve populations of 0.6, 1, and 0.4 million, respectively. Thus, this network together serves approximately 53% of the 6.5 million population in Hong Kong. Isolates included in this study represented all the invasive pneumococcal case-patients with a positive blood or CSF culture in the stated periods. All invasive isolates were tested for antimicrobial susceptibility. Only one isolate from the same patient episode of infection was included. Three patients had two episodes of infections separated by intervals of 3 months to 2 years. All isolates were subcultured and reidentified by considering the following characteristics: colony morphologic features, Gram stain results, optochin susceptibility, and bile solubility. Isolates were stored at -20[degrees]C until they were tested in batches.
Antimicrobial Agents and Susceptibility Testing
E-test strips of penicillin, amoxycillin (as amoxycillin-clavulanate 2:1), cefotaxime, cefepime, clarithromycin, vancomycin, ciprofloxacin, levofloxacin, sparfloxacin, gatifloxacin, and moxifloxacin were purchased from AB Biodisk, Solna, Sweden. E-test MICs were determined following the manufacturer's instructions. All susceptibility testing was conducted in a single laboratory at the University of Hong Kong. Test inocula were prepared from pnemnococcal colonies grown on sheep blood agar that had been incubated for 20 to 24 h in 5% C[O.sub.2]. Colonies were suspended in 0.9% saline to obtain a suspension equivalent to a 0.5 McFarland standard of turbidity. From this suspension, E-tests were performed on Mueller-Hinton agar with 5% sheep blood (BBL, Becton Dickinson Microbiology Systems, Cockeysville, MD). The plates were incubated at 35[degrees]C in 5% C[O.sub.2] for 20 h to 24 h. MICs falling between two marks on the E-test strip were rounded up to the next higher twofold dilution, as recommended in the instructions. For all MIC determinations, the bacterial inocula were validated by back titration in 10% of the tests to ensure the desired inoculum density. Quality control strains (S. pneumoniae ATCC 49619, Staphylococcus aureus ATCC 29213, and Escherichia coli ATCC 25922) were included with each run. Results were interpreted according to published breakpoints of the National Committee for Clinical Laboratory Standards (5). The term nonsusceptible was used to denote both intermediate and resistant isolates. For ciprofloxacin, the criteria were susceptible, [less than or equal to] 2 [micro]g/mL; resistant, [greater than or equal to] 4 [micro]g/mL.
Typing of Isolates
All isolates were serotyped by the quellung reaction (6) with sera of various levels of reactivity from the Statens Seruminstitut (Copenhagen, Denmark). The subset of 11 isolates with resistance to ciprofloxacin was examined further by multilocus sequence typing (MLST) and by HinfI restriction analysis of their pbp 2b and 2x genes (7). The well-defined Spanish clones of serotypes 23F and 6B (SP264 ATCC 700669 and GM17 ATCC 700670, respectively) and a strain representative of the fluoroquinolone-resistant variant [Hong Kong.sup.23F]-1 clone were used as controls (4).
Polymerase Chain Reaction (PCR) and DNA Sequencing
The quinolone resistance-determining regions of gyrA, gyrB, parC, and pare were amplified by using primers described previously (8). Nucleotide sequencing was performed by the ByeDye dideoxynucleotide chain termination method (Applied Biosystems, Hong Kong). The sequences of both strands of the amplicons were determined.
Chi-square or Fisher exact test was used for statistical analysis. A p value of <0.05 was considered significant.
Emergence of Fluoroquinolone Resistance among Multidrug-resistant Isolates
The number of isolates obtained from different age groups was as follows: <2 years (n = 48); 2 5 years (n = 40); 6-17 years (n - 14); 18-49 years (n = 30); 50-64 (n = 27), and [greater than or equal to] 65 years (n = 106). Of the isolates, 256 (96.6%) were from blood, 6 from CSF, and 3 from brain abscess. The susceptibilities of the 265 pneumococcal isolates to 11 antimicrobial agents are summarized in Table 1. The annual susceptibility rates for penicillin, clarithromycin, and levofloxacin are shown in Figure 1. Overall, 166 (62.6%) were penicillin-susceptible, 53 (20%) were penicillin-intermediate, and 46 (17.3%) were penicillin-resistant. Rates of penicillin nonsusceptibility (MIC >0.06 [micro]g/mL) do not differ significantly in the five hospitals (p = 0.1): 35.7% (50 of 140) for laboratory A, 50% (11 of 22) for laboratory B, 32.4% (11 of 34) for laboratory C, 37.5% (24 of 64) for laboratory D, and 60% (3 of 5) for laboratory E.
[FIGURE 1 OMITTED]
In children (ages [less than or equal to] 12 years), the rate of penicillin nonsusceptibility was significantly higher than that in adults ([greater than or equal to] 13 years of age) (48% vs. 30.9%, respectively; p = 0.005). In general, MICs of penicillin were identical or within one dilution difference of that of amoxicillin. For these two penicillins, the [MIC.sub.50], [MIC.sub.90], and mode MIC values were identical. On the other hand, MICs of cefotaxime were generally one dilution lower than that of cefepime. High MICs of penicillin (4 [micro]g/mL) and cefotaxime (4 [micro]g/mL) were found in 2 (0.8%) and 1 (0.4%) of 265 isolates, respectively.
Of the 265 isolates, 97 (36.6%) were clarithromycin-susceptible, 1 (0.4%) was clarithromycin-intermediate, and 167 (63%) were clarithromycin-resistant. In most isolates, the resistance was of a high level type. Among 168 clarithromycin-nonsusceptible isolates, 102 (60.7%) had MIC ([greater than or equal to] 32 [micro]g/mL, and 78 (46.4%) had MIC ([greater than or equal to] 256 [micro]g/mL. Again, clarithromycin resistance rate was higher among children than adults (83 [83%] of 100 vs. 85 [51.5%] of 165, respectively; p < 0.001). The clarithromycin-nonsusceptibility rates in penicillin-susceptible and nonsusceptible isolates were 73 (44%) of 166 and 95 (95.9%) of 99, respectively (p < 0.001).
Overall, 10 (3.8%) of 265 isolates were resistant to levofloxacin. The levofloxacin-resistance rate increased to 15.2% among the penicillin-resistant pneumococcal isolates and was 7.5% among isolates derived from persons ([greater than or equal to] 50 years of age. One penicillin-susceptible isolate (S1D3) had a ciprofloxacin MIC of 4 [micro]g/mL. This isolate remained susceptible to levofloxacin. The 10 resistant isolates had a levofloxacin MIC from 16 [micro]g/mL to 32 [micro]g/mL; 8 of these were resistant to gatifloxacin (MIC range, 4-16 [micro]g/mL), and 6 were resistant to moxifloxacin (MIC range, 4-8 [micro]g/mL). All levofloxacin-resistant isolates were also either intermediately resistant or resistant to penicillin (MIC range, 1-4 [micro]g/mL) and clarithromyein (MIC range, 2-([greater than or equal to] 256 [micro]g/mL). All levofloxacin-resistant isolates were from adults (one from the 50-to 64-year age group and nine from ([greater than or equal to] 65-year group). Seven were nosocomial infections (having onset >2 days after admission), and three were community-acquired infections. For the levofloxacin-susceptible isolates, the rank order of potency ([MIC.sub.50]/[MIC.sub.90]) was as follows: moxifloxacin (0.125/0.25) > gatifloxacin (0.25/0.25) > sparfloxacin (0.25/0.5) > levofloxacin (1/1) = ciprofloxacin (1/1).
Serotype Distribution of Isolates and Resistance Patterns
Of 265 isolates, 8 isolates could not be typed; 34 different serotypes were identified among the remaining isolates. The serotype distribution of the isolates according to age group of patients and penicillin resistance is shown in Table 2. Serotype 14 was the most common serotype (24.5%). Four serotypes (6B, 14, 19F, and 23F) accounted for 92.9% of all penicillin-nonsusceptble isolates and 84.5% of all clarithromycin-nonsusceptible isolates. The capsular serotypes of the levofloxacin-resistant isolates were 14 (n = 4), 19F (n = 2), and 23F (n = 4). Serotypes included in 7-valent pneumococcal conjugate vaccine formulations (4, 6B, 9V, 14, 18C, 19F, and 23F) comprised 90.4% and 90.6% of penicillin- and clarithromycin-nonsusceptible strains isolated from persons with age [less than or equal to] 5 years, respectively. Coverage of the 7-valent conjugate vaccine for all isolates from young children ([less than or equal to] 5 years of age) was 89.7% (79/88). Serotypes included in the 23-valent pneumococcal polysaccharide vaccine accounted for 92.9% of penicillin-nonsusceptible and 91.1% of clarithromycin-nonsusceptible isolates for all ages, respectively.
Molecular Analysis of Fluoroquinolone-resistant Isolates
Molecular analysis of the 11 fluoroquinolone-resistant isolates is summarized in Table 3. Analysis by MLST showed that a single allelic profile (4-4-2-4-4-1-1) or sequence type (ST 81) was shared by all 10 levofloxacin-resistant isolates. Fingerprint patterns after HinfI digestion of the amplified pbp 2x and 2b genes are shown in the Figure 2. One fingerprint pattern for pbp 2b was shared by nine levofloxacin-resistant isolates. The remaining levofloxacin-resistant isolate has a pattern that differed from the major pattern by one band. A single fingerprint pattern for pbp 2x was shared by all 10 levofloxacin-resistant isolates. Both pbp 2b and 2x fingerprint patterns among the levofioxacin-resistant isolates were indistinguishable from that displayed by the [Spain.sup.23F-1] clone. The remaining ciprofloxacin-resistant, levofloxacin-susceptible strain had distinct php 2b and 2x fingerprint patterns. Furthermore, the 10 isolates all had similar pattern of mutations in gyrA, parC, and parE genes. In GyrA, all 10 isolates had a S81F or Y substitution. In ParC, the 10 isolates had at least one amino acid substitution, and 6 isolates had two substitutions, an S79F plus K137N pair. In ParE, one isolate had no substitution. Five isolates had one substitution (1460V), and four had two substitutions (1460V plus D435 or E474K pair). The remaining ciprofloxacin-resistant, levofloxacin-susceptible isolate (S1D3) had a distinct MLST pattern and PBP 2B and 2X gene profiles. This isolate had one substitution in each of ParC and ParE. No strains had substitutions in GyrB.
[FIGURE 2 OMITTED]
This study showed that fluoroquinolone resistance among pneumococci that cause invasive infections is emerging. Our finding of a 3.8% resistance rate for levofloxacin is among the highest ever reported in the world and could be attributed in part to suboptimal use of the fluoroquinolones (9). In a case-control study, we have previously shown that chronic obstructive airway disease, nosocomial infection, nursing home residence, and exposure to lesser potent fluoroquinolones were independently associated with fluoroquinolone-resistant Streptococcus pneumoniae (9). Elsewhere, levofloxacin resistance among the invasive pneumococcal isolates was still rare at <1% (10-12). In the United States, Jorgensen et al. recently reported that fluoroquinolone-resistant pneumococci could be also emerging in some of the Active Bacterial Core Surveillance Areas (ABCs). Of 538 invasive pneumococci collected from 1998 to 2000 from California, 3.2% had ciprofloxacin MIC of [greater than or equal to] 4 [micro]g/mL (13). In general, antimicrobial resistance among the pneumococci occured more frequently among respiratory tract isolates than blood isolates (2). In our previous studies, the fluoroquinolone resistance rate among the respiratory isolates was 5.5% and 13% in 1998 and 2000, respectively (3,4).
Our findings show that invasive pneumococci with fluoroquinolone resistance in this locality were related to the multidrug-resistant Spanish 23F clone. Three different serotypes were identified among the 10 clonally related levofloxacin-resistant isolates, indicating that this clone is evolving by horizontal transfer of the capsular genes. Elsewhere, early evidence suggested that epidemic clones could be playing a role in dissemination of fluoroquinolone resistance, in an analysis of 29 fluoroquinolone-resistant pneumococci, McGee et al. reported that 6 isolates from Ireland and 1 from France were indistinguishable from the [Spain.sup.9V]-3 clone (14). In Birmingham, George et al. recently reported that two fluoroquinolone-resistant variants closely related to the widely distributed penicillin-resistant [Spain.sup.9V]-3 clone were emerging (15). Furthermore, Alou et al. report that 30% of 82 pneumococci with reduced susceptibility to ciprofloxacin from 20 hospitals in Spain belonged to two internationally spread clones: [France.sup.9V]-3 and [Spain.sup23F]-1 (16). The emergence of fluoroquinolone resistance among the internationally distributed S. pneumoniae clones is of concern. The Hong Kong experience is an example of how resistance to the fluoroquinolones could evolve rapidly in pneumococci as a result of clonal expansion.
This study found a high rate of macrolide resistance among the invasive pneumococcal isolates, as was reported for noninvasive isolates (4). This circumstance is likely related to the high local use of macrolides and the dissemination of several drug-resistant clones (17). Among invasive isolates, our figure was similar to that reported in Taiwan (72%) but was higher than those reported from the United States (20.4%), Canada (14.8%), or Germany (15.3%) (18-21). Despite early skepticism, increasing evidence shows that in vitro macrolide resistance does result in clinical and microbiologic failures in systemic pneumococcal infection (22,23). Hence, in the empirical treatment of community-acquired pneumonia, our findings imply that monotherapy with a macrolide is not appropriate in this region.
Our data show that 90% or more of the resistant pneumococci that cause invasive infections in persons of all ages belonged to serotypes that are included in the 23-valent pneumococcal polysaccharide vaccine as well as the 7-valent conjugate vaccine. The 7-valent conjugate vaccine is indicated in young children and is highly effective in preventing vaccine serotype-related invasive diseases (24). In the United States, the 7-valent conjugate vaccine was added to the routine schedule in 2000. According to Whitney et al. (25), after the conjugate vaccine was introduced, the rate of invasive disease caused by vaccine and vaccine-related serotypes has markedly declined. The rate of disease caused by strains that were not susceptible to penicillin was 35% lower in 2001 than in 1999. The rate of disease in adults also declined (25). From the results of trials reported so far, the vaccine will likely also reduce carriage of vaccine types of pneurnococci (26,27). Hence, resistant pnemnocoeci might diminish as the vaccine becomes more widely available (25,28). The effectiveness of the 23-valent polysaccharide vaccine has not been as dramatic. In older adults, vaccination with the polysaccharide vaccine effectively reduced the rate of bacteremia but not that of nonbacteremic pneumonia (29). The use of the 23-valent pneumococcal vaccine in Hong Kong is low (with estimated coverage of <10% for those [greater than or equal to] 65 years). While data on the efficacy of the 23-valent pneumococcal vaccine are considered insufficient in patients with chronic obstructive pulmonary disease (30), the benefits of vaccinating elderly people with the 23-valent pneumococcal vaccine are clear (31). In view of the findings from this and our previous study that the elderly and persons with chronic obstructive pulmonary disease are at high risk of developing infection by fluoroquinolone-resistant S. pneumoniae, we believe both patient groups in this locality should receive pneumococcal vaccine.
In conclusion, this study reported high rates of fluoroquinolone resistance among multidrug-resistant strains of pneumococci that cause invasive infections among older adults in Hong Kong. Our experience leads us to call for a more prudent use of fluoroquinolones in all clinical settings. Since carriage of pneumococci is common, collateral exposure could occur anytime a person is treated with fluoroquinolones for any infection, including skin, soft tissue, or urinary tract infections. In patients with chronic obstructive pulmonary disease, high-density colonization of the airway is common, which could explain why these patients are at high risk for fluoroquinolone-resistant pneumococci (9). In young children, high numbers of pneumococci are frequently found in the nasopharynx. If fluoroquinolone use is extended from adults to children, who are frequently colonized by the antimicrobial resistant serotypes, transmission and spread of fluoroquinolone-resistant strains would occur rapidly in the community (32). For pneumonia, all evidence so far indicates that infection caused by pneumococci intermediately resistant to penicillin (MIC [less than or equal to] 1 [micro]g/mL or 2 [micro]g/mL) should respond well to a penicillin given in appropriate doses. In view of this and the emergence of fluoroquinolone resistance in both noninvasive and invasive isolates in this locality, we believe that fluoroquinolones should not be used as first-line treatment in community-acquired pneumonia. In local guidelines, amoxicillin-clavulanate or the combination of amoxicillin and a new macrolide are the recommended first-line drugs for empirical treatment of community-acquired pneumonia in the outpatient setting. As pneumococcal infections become increasing difficult to treat, public health authorities should give priority to pneumococcal vaccination of persons at high risk of acquiring infections by the resistant pneumococci. Since substantial changes can occur in a short period, fluoroquinolone-resistant isolates must be monitored and tracked as part of ongoing and routine pneumococcal surveillance.
Table 1. MICs of 11 antimicrobial agents for Streptococcus pneumoniae isolates based on susceptibility to penicillin (a,b) Antimicrobial agent and penicillin MIC ([micro]g/mL) susceptibility status Range 50% 90% Mode Penicillin All 0.008-4 0.032 2 0.016 Pen-S 0.008-0.064 0.016 0.032 0.016 Pen-I 0.125-1 1 1 1 Pen-R 2-4 2 2.0 2 Amoxicillin All 0.016-4 0.032 2 0.016 Pen-S 0.016-0.125 0.016 0.032 0.016 Pen-I 0.032-2 1 2 1 Pen-R 0.5-4 2 2 2 Cefotaxime All 0.016-4 0.032 1 0.016 Pen-S 0.016-0.125 0.016 0.032 0.016 Pen-I 0.032-2 1 1 1 Pen-R 0.5-4 1 2 1 Cefepime All 0.016-4 0.064 2 0.064 Pen-S 0.016-0.25 0.064 0.125 0.064 Pen-I 0.032-1 1 2 2 Pen-R 1-4 2 2 2 Clarithromycin All 0.032-256 4 256 256 Pen-S 0.032-256 0.125 256 0.125 Pen-I 0.064-256 256 256 256 Pen-R 2-256 4 256 2 Vancomycin All 0.25-1 0.50 0.5 0.5 Pen-S 0.25-1 0.50 0.5 0.5 Pen-I 0.25-1 0.50 0.5 0.5 Pen-R 0.25-1 0.50 1 0.5 Ciprofloxacin All 0.25-32 1 1 1 Pen-S 0.25-4 1 1 1 Pen-I 0.25-32 1 1 1 Pen-R 0.5-32 1 32 1 Levofloxacin All 0.125-32 1 1 1 Pen-S 0.125-2 1 1 1 Pen-I 0.125-32 1 1 1 Pen-R 0.5-32 1 32 1 Sparfloxacin All 0.125-32 0.25 0.5 0.5 Pen-S 0.125-1 0.25 0.5 0.5 Pen-I 0.125-32 0.25 0.5 0.5 Pen-R 0.25-32 0.5 32 0.5 Gatifloxacin All 0.064-16 0.25 0.25 0.25 Pen-S 0.064-1 0.25 0.25 0.25 Pen-I 0.125-8 0.25 0.25 0.25 Pen-R 0.125-16 0.25 8 0.25 Moxifloxacin All 0.064-8 0.125 0.25 0.125 Pen-S 0.064-1 0.125 0.25 0.125 Pen-I 0.064-4 0.125 0.25 0.125 Pen-R 0.125-8 0.125 4 0.125 Antimicrobial agent and penicillin % of isolates susceptibility status S I R Penicillin All 62.6 20.0 17.4 Pen-S 100 0.0 0.0 Pen-I 0.0 100 0.0 Pen-R 0.0 0.0 100 Amoxicillin All 99.6 0.4 0.0 Pen-S 100.0 0.0 0.0 Pen-I 100.0 0.0 0.0 Pen-R 97.8 2.2 0.0 Cefotaxime All 97.0 2.6 0.4 Pen-S 100.0 0.0 0.0 Pen-I 100.0 0.0 0.0 Pen-R 82.6 15.2 2.2 Cefepime All 76.2 21.9 1.9 Pen-S 100.0 0.0 0.0 Pen-I 66.0 34.0 0.0 Pen-R 2.2 87 10.9 Clarithromycin All 36.6 0.4 63.0 Pen-S 56.0 0.0 44.0 Pen-I 7.5 1.9 90.6 Pen-R 0.0 0.0 100.0 Vancomycin All 100.0 0.0 0.0 Pen-S 100.0 0.0 0.0 Pen-I 100.0 0.0 0.0 Pen-R 100.0 0.0 0.0 Ciprofloxacin All 95.8 -- 4.2 Pen-S 99.4 -- 0.6 Pen-I 94.3 -- 5.7 Pen-R 84.8 -- 15.2 Levofloxacin All 96.2 0.0 3.8 Pen-S 100.0 0.0 0.0 Pen-I 94.3 0.0 5.7 Pen-R 84.8 0.0 15.2 Sparfloxacin All 95.8 0.8 3.2 Pen-S 99.4 0.6 0.0 Pen-I 94.3 0.0 5.7 Pen-R 84.8 2.2 13.0 Gatifloxacin All 96.2 0.8 3.0 Pen-S 100.0 0.0 0.0 Pen-I 94.3 1.9 3.8 Pen-R 84.8 2.2 13.0 Moxifloxacin All 97.0 0.8 2.3 Pen-S 100.0 0.0 0.0 Pen-I 96.2 1.9 1.9 Pen-R 87.0 2.2 10.9 (a) N = 265; a total of 166 isolates were penicillin-susceptible (Pen-S), 53 were penicillin-intermediate (Pen-I), and 46 were penicillin-resistant Pen-R). (b) 50% and 90%, [MIC.sub.50], and [MIC.sub.90], respectively. Table 2. Distribution of pneumococcal capsular types according to age group of patient and penicillin resistance, 1995-2001 All ages Serotype (a) No. of isolates Penicillin-resistant (%) 14 65 32.3 23F 46 82.6 6B 26 69.2 3 24 0.0 19F 19 78.9 18C 12 0.0 9V 8 0.0 4 7 0.0 All others 58 12.1 Total 265 37.4 Age [less than or equal to] 5 years Serotype (a) No. of isolates Penicillin-resistant (%) 14 31 25.8 23F 15 80.0 6B 18 72.2 3 1 0.0 19F 9 55.6 18C 4 0.0 9V 2 0.0 4 0 0.0 All others 8 50.0 Total 88 47.7 (a) MIC [greater than or equal to] 0.12 [micro]g/mL. Serotypes included in 7-valent pneumococcal conjugate vaccine formulations included 4, 6B, 9V, 14, 18C, 19F, and 23F (in italics). Table 3. Characteristics of 11 strains of Streptococcus pneumoniae with reduced susceptibility to ciprofloxacin Strain Y Source Serotype (a) MLST profile (a) S3F7 1996 A 23F 4-4-2-4-4-1-1 S2H9 1997 A 23F 4-4-2-4-4-1-1 S1B7 1999 B 23F 4-4-2-4-4-1-1 S1B9 1999 B 23F 4-4-2-4-4-1-1 S1D5 1999 C 19F 4-4-2-4-4-1-1 S2D6 1999 A 14 4-4-2-4-4-1-1 S1D2 2000 C 19F 4-4-2-4-4-1-1 S1D3 2000 C 4 8-8-8-1-17-1-18 S2F3 2000 A 14 4-4-2-4-4-1-1 186G1 2001 A 23F 4-4-2-4-4-1-1 216D2 2001 A 14 4-4-2-4-4-1-1 MIC ([micro]g/mL) (b) Strain CIP LVX GAT MO S3F7 32 32 2 1 S2H9 32 32 4 2 S1B7 32 32 8 4 S1B9 32 32 16 4 S1D5 32 32 8 4 S2D6 32 32 8 4 S1D2 32 32 8 8 S1D3 4 2 0.5 0.25 S2F3 32 32 4 2 186G1 32 16 2 0.5 216D2 32 32 4 4 Mutation in QRDR of (c,d) Strain GyrA ParC ParE S3F7 S81F K137N E474K, 1460V S2H9 S81Y K137N D435N, 1460V S1B7 S81F S79F, K137N 1460V S1B9 S81F S79F, K137N 1460V S1D5 S81F S79F, K137N 1460V S2D6 S81F S79F, K137N 1460V S1D2 S81F S79F, K137N -- S1D3 -- K137N 1460V S2F3 S81F K137N D435N, 1460V 186G1 S81F K137N E474K, 1460V 216D2 S81F S79F, K137N 1460V (a) MLST, multilocus sequence typing. Number refers to allelle of aroE, gdh, gki, recP, spi, xpt, and ddiA genes, respectively. (b) CIP, ciprofloxacin; LVX, levofloxacin; GAT, gatifloxacin; MO, moxifloxacin. (c) No strains had mutations in GyrB sequence. QRDR, quinolone resistance-determining region. (d) S. pneumoniae numbering.
We thank Frankie Chow for excellent technical support, Frances Wong for dedicated secretarial assistance, and K.R Klugmans for kindly providing Spanish clones of serotypes 23F and 6B.
This work was supported by grants from the Health Care and Promotion Fund Committee, the Committee on Research and Conference Grants and Bristol-Myers Squibb (Hong Kong) Ltd.
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Address for correspondence: Pak-Leung Ho, Division of Infectious Diseases, Department of Microbiology. Queen Mary Hospital The University of Hong Kong, Pokfulam Road, Pokfulam, Hong Kong Special Administrative Region, China; fax: 852-2855-1241; email: email@example.com
Pak-Leung Ho, * Tak-Lun Que, ([dagger]) Susan S. Chiu, * Raymond W. H. Yung, ([double dagger]) Tak-Keung Ng, ([section]) Dominic N.C. Tsang, ([paragraph]) Wing-Hong Seto, * and Yu-Lung Lau *
* Queen Mary Hospital, The University of Hong Kong, Hong Kong Special Administrative Region (SAR), China; ([dagger]) Tuen Mun Hospital, Hong Kong SAR, China; ([double dagger]) Pamela Youde Nethersole Eastern Hospital, Hong Kong SAR, China; ([section])Princess Margaret Hospital, Hong Kong, SAR, China; and Queen Elizabeth Hospital, Hong Kong SAR, China
Dr. Ho is associate professor in the Department of Microbiology, University of Hung Kong. His research interests include emerging infectious diseases and antimicrobial resistance.
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|Publication:||Emerging Infectious Diseases|
|Date:||Jul 1, 2004|
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