Fluoroquinolone-resistant escherichia coli, Indonesia.In a recent, population-based survey of 3,996 persons in Indonesia, fluoroquinolone fluoroquinolone /flu·o·ro·quin·o·lone/ (-kwin´o-lon) any of a subgroup of fluorine-substituted quinolones, having a broader spectrum of activity than nalidixic acid. fluor·o·quin·o·lone n. (FQ)-resistant Escherichia coli Escherichia coli (ĕsh'ərĭk`ēə kō`lī), common bacterium that normally inhabits the intestinal tracts of humans and animals, but can cause infection in other parts of the body, especially the urinary tract. was prevalent in the fecal flora of 6% of patients at hospital admission and 23% of patients at discharge, but not among healthy relatives or patients visiting primary healthcare centers (2%). Molecular typing showed extensive genetic diversity with only limited clonality among isolates. This finding suggests that independent selection of resistant mutants occurs frequently. FQ-resistant isolates exhibited a higher rate of spontaneous mutation spontaneous mutation n. A mutation that arises naturally and not as a result of exposure to mutagens. Also called natural mutation. , but sparser virulence profiles, than FQ-susceptible isolates from the same population. The resistant isolates belonged predominantly to phylogenetic phy·lo·ge·net·ic adj. 1. Of or relating to phylogeny or phylogenetics. 2. Relating to or based on evolutionary development or history. groups A (57%) and B1 (22%) but also to the moderately virulent group D (20%). Hypervirulent strains from the B2 cluster were underrepresented un·der·rep·re·sent·ed adj. Insufficiently or inadequately represented: the underrepresented minority groups, ignored by the government. (1%). Because FQ-resistant E. coli E. coli: see Escherichia coli. E. coli in full Escherichia coli Species of bacterium that inhabits the stomach and intestines. E. coli can be transmitted by water, milk, food, or flies and other insects. can cause disease, especially nosocomial infections Nosocomial infections Infections that were not present before the patient came to a hospital, but were acquired by a patient while in the hospital. Mentioned in: Enterobacterial Infections, Staphylococcal Infections in immunocompromised immunocompromised /im·mu·no·com·pro·mised/ (-kom´pro-mizd) having the immune response attenuated by administration of immunosuppressive drugs, by irradiation, by malnutrition, or by certain disease processes (e.g., cancer). patients, spread of such strains must be stopped. ********** Escherichia coli is a common constituent of the gastrointestinal flora of most vertebrates, including humans, and may be isolated from a variety of environmental sources. While most strains are nonpathogenic, certain ones can cause a variety of intestinal and extraintestinal infections. Pathogenicity is largely determined by gene-encoding virulence factors (VFs), such as adhesins, toxins, and polysaccharide polysaccharide: see carbohydrate. polysaccharide Any of a large class of long-chain sugars composed of monosaccharides. Because the chains may be unbranched or branched and the monosaccharides may be of one, two, or occasionally more kinds, surface coatings (1). Phylogenetic analysis showed that most E. coli strains fall into 4 main phylogenetic groups, designated A, B1, B2, and D (2). E. coli strains that cause extraintestinal infections derive predominantly from group B2 and, to a lesser extent, group D. Strains of groups A and B 1 represent most commensal commensal /com·men·sal/ (kom-men´sil) 1. living on or within another organism, and deriving benefit without harming or benefiting the host. 2. a parasite that causes no harm to the host. strains and are largely devoid of virulence determinants (3). Although strains harboring a robust extraintestinal VF repertoire cluster predominantly in groups B2 and D, isolates within each phylogenetic group can be further classified as extraintestinal pathogenic E. coli (ExPEC) or non-ExPEC depending on whether specific virulence traits are present (4,5). The fluoroquinolones (FQs) are potent antimicrobial agents Antimicrobial agents Chemical compounds biosynthetically or synthetically produced which either destroy or usefully suppress the growth or metabolism of a variety of microscopic or submicroscopic forms of life. used for the treatment and prophylaxis prophylaxis (prō'fĭlăk`sĭs), measures designed to prevent the occurrence of disease or its dissemination. Some examples of prophylaxis are immunization against serious diseases such as smallpox or diphtheria; quarantine to confine of infections caused by gram-negative bacteria, including E. coli. FQ-resistant E. coli has been reported increasingly during the last decade in both the hospital environment and the community, which may ultimately limit the utility of these broad-spectrum agents (6-8). Moreover, FQ-resistant E. coli strains often show resistance to other drugs, such as ampicillin ampicillin (ăm'pĭsĭl`ĭn), a penicillin-type antibiotic that is effective against both gram-negative microorganisms and gram-positive microorganisms such as Escherichia coli. , tetracycline tetracycline (tĕ'trəsī`klēn), any of a group of antibiotics produced by bacteria of the genus Streptomyces. They are effective against a wide range of Gram positive and Gram negative bacteria, interfering with protein , chloramphenicol chloramphenicol (klōr'ămfĕn`əkŏl'), antibiotic effective against a wide range of gram-negative and gram-positive bacteria (see Gram's stain). It was originally isolated from a species of Streptomyces bacteria. , trimethoprimsulfamethoxazole, and gentamicin gentamicin /gen·ta·mi·cin/ (jen?tah-mi´sin) an aminoglycoside antibiotic complex isolated from bacteria of the genus Micromonospora, (7,9). Recent reports have suggested that clinical FQ-resistant E. coli actually tends to be less virulent than susceptible isolates. FQ-resistant E. coli from hospitalized Dutch patients derived predominantly from the low-virulence phylogenetic groups A and B 1. None of the 13 invasive isolates derived from phylogenetic group B2 (10). In addition, evidence suggests that clinical FQ-resistant E. coli isolates from humans in Iowa were associated with a shift toward non-B2 phylogenetic groups and to a lower overall virulence genotype genotype (jēn`ətīp'): see genetics. genotype Genetic makeup of an organism. The genotype determines the hereditary potentials and limitations of an individual. (4). FQ resistance may also be associated with strains that intrinsically have a higher overall mutation rate In genetics, the mutation rate is the chance of a mutation occurring in an organism or gene in each generation (or, in the case of multicellular organisms, cell division). See Luria-Delbrück experiment. , since the resistance to FQs in E. coli involves the accumulation of multiple spontaneously occurring point mutations in several genes (9,11). These associations, however, may depend on the strains' geographic or clinical origin. In our study, we investigated these putative associations in a well-defined collection of isolates from Indonesia. A population-based survey of [approximately equal to] 4,000 people in 2 cities on the island of Java (Surabaya and Semarang) was initiated in 2000 by the Antimicrobial antimicrobial /an·ti·mi·cro·bi·al/ (-mi-kro´be-al) 1. killing microorganisms or suppressing their multiplication or growth. 2. an agent with such effects. Resistance in Indonesia, Prevalence and Prevention study group to investigate the level of carriage of resistant microorganisms. FQ-resistant E. coli was prevalent in the fecal flora of 6% of patients at hospital admission and 23% of patients at discharge but not among healthy relatives or patients visiting primary healthcare centers (2% in both groups) (ES Lestari, unpub. data). In our study, we analyzed these FQ-resistant E. coli isolates to elucidate their molecular epidemiology molecular epidemiology Molecular medicine An evolving field that combines the tools of standard epidemiology–case studies, questionnaires and monitoring of exposure to external factors with the tools of molecular biology–eg, restriction endonucleases, and virulence. To define clonal relatedness, we performed enterobacterial repetitive intergenic consensus (ERIC) polymerase chain reactions polymerase chain reaction (pŏl`ĭmərās') (PCR), laboratory process in which a particular DNA segment from a mixture of DNA chains is rapidly replicated, producing a large, readily analyzed sample of a piece of DNA; the process is (PCR PCR polymerase chain reaction. PCR abbr. polymerase chain reaction Polymerase chain reaction (PCR) ). The phylogenetic background and virulence profile of these isolates were determined by PCR methods and compared with similar data for FQ-susceptible E. coli isolated from the same population. Finally, we examined the link between FQ resistance and the intrinsic mutation rate. Materials and Methods Strains The study group program surveillance was initiated to determine the prevalence of antimicrobial resistance in Indonesia. Four different groups of persons in Surabaya and Semarang were studied for carriage of resistant microorganisms in their stools. The 4 groups were patients on the day of admission to the hospital (group 1), patients on the day of discharge after [greater than or equal to] 5 days of hospitalization (group 2), patients visiting a primary healthcare center (group 3), and healthy relatives or household members of group 1 patients (group 4). In groups 1 and 2. rectal swabs were taken from patients in the internal medicine, surgery, gynecology/obstetrics, or pediatrics departments. The specimens were collected from July to October 2001 in Surabaya and from January to May 2002 in Semarang. Further details on the methods of culturing will be published elsewhere. A total of 5,535 E. coli isolates from 3,284 patients were cultured. Antimicrobial susceptibility testing was performed for 1 isolate per patient. The overall by-isolate prevalence of resistance to ciprofloxacin ciprofloxacin /cip·ro·flox·a·cin/ (sip?ro-flok´sah-sin) a synthetic antibacterial effective against many gram-positive and gram-negative bacteria; used as the hydrochloride salt. cip·ro·flox·a·cin n. as determined by disk diffusion was 8%. The prevalence of resistance was highest among patients on the day of discharge (18% in Surabaya and 27% in Semarang) and lowest among patients visiting primary healthcare centers and among family members of patients admitted to the hospital (2% in both groups). The prevalence of FQ-resistant E. coli among patients who were tested on the day of admission was 8% in Surabaya and 4% in Semarang. We studied 196 FQ-resistant isolates in more detail. Seventy-five (38%) of these were from Surabaya (19, 48, 4, and 4 isolates from stated population groups 1, 2, 3, and 4, respectively) and 121 (62%) from Semarang (13, 92, 11, and 5, respectively). The FQ-resistant isolates were recovered from patients from all 4 hospital departments in both cities. In Semarang, 43% of these isolates were from surgery departments and 41% were from internal medicine departments. In Surabaya, 43% of the isolates were from the internal medicine department. All 196 ciprofloxacin-resistant E. coli and 200 ciprofloxacin-susceptible E. coli (20 randomly chosen isolates from groups 1, 2, and 3 and 40 from group 4, from each city) were confirmed by Vitek 2 (bioMerieux, Marcy-l'Etoile. France) according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the manufacturer's instructions and included in the molecular analyses. DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. Isolation Bacterial DNA was isolated by using the MagNA Pure LC with the MagNA Pure LC DNA Isolation Kit III for bacteria and fungi (standard protocol: Roche Molecular Biochemicals, Mannheim, Germany). DNA concentration was assessed spectophotometrically. Samples were frozen at -20[degrees]C until used. Bacterial Typing by ERIC-PCR ERIC-PCR was conducted with primers ERIC-1R and ERIC-2 as described previously (8,12,13). The amplification products were subjected to electrophoresis in a 1% agarose agarose more highly purified form of agar with similar uses to agar and widely used in the separation of nucleic acid fragments. gel and were stained with ethidium bromide Ethidium bromide (sometimes abbreviated as EtBr) is an intercalating agent commonly used as a nucleic acid stain in molecular biology laboratories for techniques such as agarose gel electrophoresis. (50 [micro]g/mL). The ERIC-PCRs were performed by 1 technician within 1 month. Profiles were visually analyzed by 2 microbiologists. Single-band differences in profiles among strains led to the definition of separate genotypes. Ambiguous isolates were retested and analyzed by 2 other microbiologists. Phylogenetic Analysis and Virulence Typing Isolates were assigned to 1 of 4 main E. coli phylogenetic groups (A, B1, B2, and D) according to an established triplex triplex /tri·plex/ (tri´pleks) triple or threefold. triplex triple or threefold. PCR assay, in which the 4 phylogenetic groups yield distinct combinations of 3 possible PCR products, chuA (heme transport), yjaA (unknown function gene from E. coli K-12 genome), and TSPE TSPE Texas Society of Professional Engineers 4.C2 (anonymous fragment identified by subtractive sub·trac·tive adj. 1. Producing or involving subtraction. 2. Of or being a color produced by light passing through or reflecting off a colorant, such as a filter or pigment, that absorbs certain wavelengths and transmits or hybridization hybridization /hy·brid·iza·tion/ (hi?brid-i-za´shun) 1. crossbreeding; the act or process of producing hybrids. 2. molecular hybridization 3. ) (2,14). All isolates were screened for 5 ExPEC-defining virulence markers, papA/papC, sfa/focDE, afa/draBC, kpsM II, and iutA. Based on previous statistical analyses of similar data, from collections within which each isolate's ExPEC status could be inferred based on ecologic source or experimental virulence, isolates were classified as ExPEC if positive for [greater than or equal to] 2 of these 5 defining virulence markers (4). All isolates were also screened for hlyD (hemolysin hemolysin /he·mol·y·sin/ (he-mol´i-sin) a substance that liberates hemoglobin from erythrocytes by interrupting their structural integrity. he·mol·y·sin n. ), another ExPEC-associated VF. Subsequently, all isolates that satisfied molecular criteria for ExPEC were screened for 32 additional virulence markers (1). These virulence genes were detected by a combination of multiplex PCR and dot-blot hybridization with primers specific for internal or flanking sequences and probes generated and labeled with these primers; this method was previously validated by using dot-blot hybridization with defined control strains (15). A VF score was calculated for each strain as the sum of all VF genes for which the strain tested positive. In all of these PCR assays, the identity of the PCR products was deduced by comparing their size to molecular size standards in ethidium bromide-stained agarose gels. Appropriate positive and negative controls were included in each run. Mutation Rate Analysis The mutation rate was determined for 20 randomly selected isolates from phylogenetic group A (10 FQ-susceptible and 10 FQ-resistant) by monitoring the isolates' capacity to generate mutations conferring resistance to rifampin rifampin (rĭfăm`pĭn), antibiotic used in the treatment of tuberculosis. It is also used to eliminate the meningococcus microorganism from carriers and to treat leprosy, or Hansen's disease. , as described previously (9,16). Forty independent cultures of each of the 20 strains were set up in Luria broth. After overnight incubation, equal concentrations of cultures were suspended in 0.85% NaCl. The suspensions were spread on Luria agar plates containing 100 [micro]g/mL rifampin and incubated overnight. For each strain, the proportion of cultures giving 11o resistant mutants was used to calculate the mutation rate per cell per generation according to the fluctuation test of Luria and Delbruck. To avoid confounding confounding when the effects of two, or more, processes on results cannot be separated, the results are said to be confounded, a cause of bias in disease studies. confounding factor by variation in phylogenetic background, only phylogenetic group A isolates were investigated. For comparisons of results, we used the relative mutation rate, which was defined as the rate relative to the rate for E. coli strain Nu14 (5 x [10.sup.-9] per cell per generation) (9). Statistical Analysis All data were analyzed by using the statistic software packages SPSS A statistical package from SPSS, Inc., Chicago (www.spss.com) that runs on PCs, most mainframes and minis and is used extensively in marketing research. It provides over 50 statistical processes, including regression analysis, correlation and analysis of variance. version 10.0 (SPSS, Chicago, IL, USA) and EpiInfo version 5.00 (Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. , Atlanta, GA, USA). Chi-square or Fisher exact tests (2-tailed) were used when appropriate for comparisons of proportions. Comparisons involving VF scores and relative mutation rates were analyzed by using the Mann-Whitney U test Mann-Whitney U test, n.pr See test, Mann-Whitney U. . The criterion for statistical significance was a p value <0.05. Results Spread of FQ-resistant E. coli Genetic heterogeneity among the 196 FQ-resistant E. coli was assessed by ERIC-PCR. We documented 158 different patterns, designated types 1-158, which indicated a genetically diverse collection of strains. Twenty pairs of isolates with identical profiles were identified, and 9 distinct multiple-isolate clones were represented by isolates from 3 patients each. The limited number of shared genotypes was mainly recovered from group 2 patients, i.e., patients at the time of discharge from the hospital, 49 (73%) of 67 isolates. Among the total number of 140 isolates from group 2, we identified 119 different ERtC-PCR profiles. Type 37 occurred in 3 patients from the internal medicine department in Surabaya; all 3 patients were present within this department on the same day. The finding of this unique isolated cluster can be explained by patient-topatient transmission or a nonpatient-associated environmental source. This explanation was not further examined in this study. Type 90 was isolated from 2 patients on the day they were discharged from the internal medicine department in Semarang. Samples were collected on consecutive days. An isolate with an identical ERIC-PCR pattern was found in the same period in the same hospital in a pediatric patient pediatric patient Child, see there at discharge. No further obvious clustering in time and place was observed among isolates from the 9 multiple-strain clusters. Phylogenetic Analysis PCR-based phylotyping showed that the 200 FQ-susceptible isolates were predominantly from phylogenetic groups A (52%) and B1 (30%) (Table 1). The 196 FQresistant isolates also mainly derived from phylogenetic groups A (57%) and B1 (22%), but some derived from the moderately virulent phylogenetic group D (20%). Hypervirulent strains fi'om the B2 cluster were underrepresented (1%). Eighteen (67%) of the 27 isolates from the 9 distinct clones that were represented by 3 isolates each belonged to group A. Table 1 shows that the resistant isolates were significandy depleted de·plete tr.v. de·plet·ed, de·plet·ing, de·pletes To decrease the fullness of; use up or empty out. [Latin d for phylogenetic group B2 and enriched for group D, when compared with the susceptible isolates. These shifts in phylogenetic distribution were significant both overall and specifically in Semarang, whereas a similar but nonsignificant non·sig·nif·i·cant adj. 1. Not significant. 2. Having, producing, or being a value obtained from a statistical test that lies within the limits for being of random occurrence. trend was observed in Surabaya. The phylogenetic distribution of all 396 isolates among the 2 cities was highly similar (data not shown). Comparisons of the distributions among the 4 population groups showed that group D isolates were more often obtained from patients sampled on the day of discharge than from other population groups (37 [21%] of the 180 group 2 isolates belonged to group D versus 25 [12%] of the 216 nongroup 2 isolates, p = 0.01). Stratifcation showed, however, that this association was due to the excess prevalence of FQ-resistant group D isolates among the group 2 patients. Furthermore, B2 isolates were significantly more prevalent in group 3, patients visiting public healthcare centers (7 [13%] of the 55 group 3 isolates belonged to group B2 versus 10 [3%] of the 341 nongroup 3 isolates, p = 0.004). Virulence Typing All E. coli isolates were tested for a set of virulence tlqctors to allow an inference as to their pathogenic potential. The overall prevalence of the 5 defining ExPEC VFs ranged from 2% (sfa/focDE) to 33% (iutA) (Table 1). The FQ-resistant isolates were significantly depleted forpapA, papC, sfa/focDE, afa/draBC hlyD, and kpsM II (Table 1), when compared with the susceptible isolates. Accordingly, 40 (20%) FQ-susceptible E. coli isolates, but only 4 (2%) FQ-resistant isolates (2%), were classified as ExPEC, as they exhibited [greater than or equal to] 2 of the 5 key ExPEC VFs (p<0.001). Thus, FQ resistance was associated with redticed inferred virulence. All FQ-resistant E. coli isolates from the 9 distinct clones that were represented by 3 patients each were tbund to be non-ExPEC. The distribution of the 6 screening VFs was also analyzed in relation to the 4 phylogenetic groups (Table 2). Each VF was broadly distributed, occurring in [greater than or equal to] 3 phylogenetic groups. However, papA, papC, kpsM II, hlyD, and sfa/focDE were all significantly associated with phylogenetic group B2. Accordingly, 53% of the phylogenetic group B2 isolates qualified as ExPEC versus 9% of the non-B2 isolates (p<0.001) (Tables 2 and 3). The 44 ExPEC isolates were studied in more detail (Table 3). The ExPEC isolates derived mainly from phylogenetic groups A (36%) and B1 (32%), with the 4 FQresistant ExPEC isolates belonging to groups A (n = 2) and D (n = 2). Many (36%) ExPEC isolates originated from patients on the day of discharge. Both of the FQ-resistant ExPEC isolates from group 2 were from patients in the stirgical ward in Semarang. Again, no evidence for clonality was seen. The 4 resistant ExPEC isolates exhibited sparse VF profiles when compared with the susceptible ExPEC isolates. These isolates lacked classic ExPEC VFs such as focG, hlyD, and cnfl. Four other VFs, iha, sat, fyuA, and malX, were more prevalent among susceptible, rather than resistant, ExPEC isolates. Only ibeA was more prevalent among the resistant isolates. The VF iutA was detected in all FQ-resistant ExPEC isolates and in 27 (68%) of the 40 FQ-sensitive isolates. This difference was not significant. Aggregate VF scores were lower among FQ-resistant ExPEC isolates (median 6, range 4-8) than among the 40 FQ-susceptible ExPEC isolates (median 10, range 3-16, p = 0.024). Mutation Rate The link between mutation rate and resistance to FQs was studied, as the rate of mutation accumulation might be a factor in the development of FQ resistance. The 10 FQ-susceptible isolates had relative mutation rates of [less than or equal to] 0.52 (median rate 0.32, range 0.03 0.52), whereas the 10 FQ-resistant E. coli exhibited relative mutation rates of [greater than or equal to] 0.55 (median rate 0.97, range 0.55-4.58) (p<0.001) (Figure). Discussion In this study, we investigated the epidemiology and virulence characteristics of FQ-resistant E. coli collected during a large, population-based survey of [approximately equal to] 4,000 people in 2 cities in Indonesia This is a list of cities in Indonesia, by major island or region: Java and Bali
Dissemination of FQ-resistant E. coli and Mutation Rate Three possible explanations for the high prevalence of FQ-resistant E. coli among patients that had been hospitalized for [greater than or equal to] 5 days must be considered: transferable resistance, clonal spread, and mutation-based selection of resistance fostered by the use of antimicrobial agents. Transferable plasmid-mediated quinolone resistance has been described recently in E. co/i from China (17). Wang et al. found that 6 (8%) of 78 ciprofloxacin-resistant E. coli strains from a hospital in Shanghai contained qnr. However, from the present study we cannot draw any conclusion about the contribution of this mechanism in Indonesia. As for clonal spread, molecular typing showed extensive genetic diversity among FQ-resistant isolates in Indonesia. We identified a few distinct multiple-isolate clones in the hospital environment. Although all these clonal strains were shown to be non-ExPEC, they may still pose a health threat, especially to imnmnocompromised patients in hospital settings. Nosocomial nosocomial /noso·co·mi·al/ (nos?o-ko´me-il) pertaining to or originating in a hospital. nos·o·co·mi·al adj. 1. Of or relating to a hospital. 2. outbreaks of infections caused by disseminating FQ-resistant clones have already been described (8). However, in our study, limited clonality among isolates was found, which suggests that other factors contribute more to the high prevalence of FQ-resistant E. coli among hospitalized patients. To determine whether mutation-based resistance fostered by selection pressure contributed to the prevalence of FQ-resistant E. coli in Indonesia, we performed a mutation rate analysis of selected isolates. We found a strong correlation between resistance and an elevated mutation rate. This finding agrees with a recent report from Komp Lindgren et al., in which high mutation rates of E. coli strains from urinary tract infections urinary tract infection (UTI), n infection in one or more of the structures that make up the urinary system. Occurs more often in women and is most commonly caused by bacteria. were strongly associated with FQ resistance (9). To demonstrate that this mutation-based resistance was selected for by the use of FQs, we must know the consumption figures of the quinolones. In other reports, evidence suggests that the use (and misuse) of ciprofloxacin in human and animal medicine may predispose pre·dis·pose v. To make susceptible, as to a disease. to an increase in infections with resistant E. coli (8). As information on the use of FQs in Indonesia is currently not available, we cannot draw any conclusions on a potential link between antimicrobial drug use, selection pressure, and mutation-based resistance. Thus, based on the large clonal diversity of the FQ-resistant E. coli and the resistant isolates that have a slightly elevated mutation rate relative to FQ-sensitive isolates, independent emergence of new resistant mutants likely occurs regularly in this setting. Phylogenetic Typing and Virulence Profiling Phylogenetic typing and virulence profiling were performed to investigate whether a potential clinical hazard was associated with the presence of these isolates. Our data on the distribution of phylogenetic groups among the 396 E. coli isolates are consistent with those of most other studies. In an examination of human commensal E. coli strains, the frequencies of B2 strains were found to be 1 (2%) of 55 in Mali, 6 (11%) of 56 in France, and 11 (19%) of 57 in Croatia (18). In our study, 4% of the isolates overall were of B2 origin. However, the results from a report by Zhang et al. do not agree with our data (19). B2 strains accounted for 42 (48%) of 88 commensal rectal strains from healthy college-aged women in Michigan. Likewise, Sannes et al. noted a high prevalence of group B2 among rectal isolates from hospitalized, elderly, male veterans in Minnesota (20). Differences may be due to geographic variation, differences in host population characteristics, or differences in strain characteristics such as antimicrobial resistance. We did not observe a significant shift toward low-virulence phylogenetic groups for resistant isolates, as was reported by Johnson et al. (10). However, we confirmed that the isolates were notably depleted for phylogenetic group B2 and enriched for group D. We also confirmed that FQ-resistant E. coli exhibited sparser virulence profiles. The most prevalent VF was iutA, which was detected in 36% of the resistant isolates; however, this VF is less common in virulent group B2 strains (1). Accordingly, only 2% of the resistant isolates were found to be ExPEC. These 4 isolates also lacked the VFs iha, sat, fyuA, and malX as compared to the FQ-susceptible ExPEC. Whether ExPEC strains cause infection in humans depends on several other factors, including susceptibility of the host. Therefore, that many (36%) of the 44 ExPEC isolates were from group 2 patients who had been hospitalized for [greater than or equal to] 5 days is of concern. When patients become colonized Colonized This occurs when a microorganism is found on or in a person without causing a disease. Mentioned in: Isolation with FQ-resistant ExPEC strains in the hospital, they presumably pre·sum·a·ble adj. That can be presumed or taken for granted; reasonable as a supposition: presumable causes of the disaster. will have an increased risk of acquiring a nosocomial infection Nosocomial infection An infection that can be acquired in a hospital. ABPA is a nosocomial infection. Mentioned in: Allergic Bronchopulmonary Aspergillosis, Hospital-Acquired Infections, Pseudomonas Infections and, when discharged with such a strain, also for community-acquired infection; in such case, an optimal therapy will be more difficult to select. Of note, a relationship has recently been shown to exist between ciprofloxacin-resistance in E. coli and the production of extended-spectrum [beta]-lactamases, which would further limit therapeutic options (21). Our observations provide insight into the epidemiology and virulence characteristics of FQ-resistant E. coli from stools of patients and healthy participants in Indonesia. The high prevalence of FQ-resistant E. coli in the hospital environment seems to be primarily due to a combination of limited clonal spread and the spontaneous emergence of resistant strains, possibly fostered by selection pressure. Transferable resistance, however, cannot be ruled out as an additional explanation in the present study and will be the subject of future investigations. Although the resistant isolates mainly belong to phylogenetic groups A and B I and show a low virulence profile, similar strains have caused disease in humans (3,10). The data support the need to implement strict infection control measures in hospitals and to promote and monitor the prudent use of antimicrobial drugs. Continued surveillance of the changes of resistance patterns and virulence profiles of clinical and nonclinical E. coli isolates is warranted. This work was facilitated by grant number 99-MED-3 from the Royal Netherlands Academy of Sciences and Arts in the framework of its Scientific Program Indonesia-Netherlands (SPIN), Amsterdam, the Netherlands, and by RUTI grant number RUTI II--KMRT 2003 from the Ministry of Research and Technology, Jakarta, Republic of Indonesia. The contribution of JR Johnson was supported by the Office of Research and Development, Medical Research Service, Department of Veterans Affairs Veterans Affairs is a term of the business that deals with the relation between a government and its veteran communities, usually administered by the designated government agency. ; Minnesota Department of Health: and National Research Initiative Competitive Grants Program/US Department of Agriculture grant 00-35212-9408. A van Belkum was awarded with the AstraZeneca ESCMID ESCMID European Society of Clinical Microbiology and Infectious Diseases Turning the Tide of Resistance Grant 2003, which further supported the current study. Dr Kuntaman is a clinical microbiologist at the Dr Soetomo Hospital in Surabaya, Indonesia, and a lecturer and researcher at the Medical Faculty of the Airlangga University, Surabaya, Indonesia. Since 1987, his research activities have focused on the mechanisms of antimicrobial drag resistance in Indonesia. 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Rapid emergence of ciprofloxacin-resistant enterobacteriaceae containing multiple gentamicin resistance-associated integrons in a Dutch hospital. Emerg Infect Dis. 2001;7:862 7l. (9.) Komp Lindgren P, Karlsson A, Hughes D. Mutation rate and evolution of fluoroquinolone resistance in Escherichia coli isolates from patients with urinary tract infections. Antimicrob Agents Chemother. 2003;47:3222 32. (10.) Johnson JR, Van der Schee (27, Kuskowski MA, Goessens W, Van Belkum A. Phylogenetic background and virulence profiles of fluoroquinolone-resistant clinical Escherichia coli isolates from the Netherlands. J Infect Dis. 2002;186:1852-6. (11.) McDonald LC, Chen FJ, Lo HJ, Yin HC, Lu PL, Huang CH, et al. Emergence of reduced susceptibility and resistance to fluoroquinolones in Escherichia coli in Taiwan and contributions of distinct selective pressures. Antimicrob Agents Chemother. 2001;45: 3084-91. (12.) Van Belkum A, Van Leeuwen W, Kluytmans J, Verbrugh H. 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Rapid and simple determination of the Escherichia coli phylogenetic group. Appl Environ Microbiol. 2000;66:4555-8. (15.) Johnson JR, Stell AL. Extended virulence genotypes of Escherichia coli strains from patients with urosepsis in relation to phylogeny and host compromise. J Infect Dis. 2000; 181:261-72. (16.) Luria SE, Delbruck M. Mutations of bacteria from virus sensitivity to virus resistance. Genetics. 1943;28:491-511. (17.) Wang M, Tran JH, Jacoby GA, Zhang Y, Wang F, Hooper DC. Plasmid-mediated quinolone resistance in clinical isolates of Escherichia coli from Shanghai, China. Antimicrob Agents Chemothcr. 2003:47:2242-8. (18.) Duriez P, Clermont O, Bonacorsi S, Bingen E, Chaventre A, Elion J, et al. Commensal Escherichia coli isolates are phylogenetically phy·lo·ge·net·ic adj. 1. Of or relating to phylogeny or phylogenetics. 2. Relating to or based on evolutionary development or history: a phylogenetic classification of species. distributed among geographically distinct human populations. Microbiology. 2001;147:1671-6. (19.) Zhang L, Foxman B, Marrs C. Both urinary and rectal Escherichia coli isolates are dominated by strains of phylogenetic group B2. J Clin Microbiol. 2002;40:3951-5. (20.) Sannes MR, Kuskowski MA, Owens K, Gajewski A, Johnson JR. Virulence factor profiles and phylogenetic background of Escherichia coli isolates from veterans with bacteremia bacteremia: see septicemia. bacteremia Presence of bacteria in the blood. Short-term bacteremia follows dental or surgical procedures, especially if local infection or very high-risk surgery releases bacteria from isolated sites. versus uninfected control patients. J Infect Dis. 2004;190:2121-8. (21.) Tolun V, Kucukbasmaci O, Torumkuney-Akbulut D, Catal C, Ang-Kucuker M, Ang O. Relationship between ciprofloxacin resistance and extended-spectrum beta-lactamase extended-spectrum beta-lactamase Third generation cephalosporinase Microbiology A beta-lactamase produced by gram-negative enteric bacteria, in particular K pneumoniae and E coli, which are resistant to third-generation cephalosporins. production in Escherichia coli and Klebsiella pneumoniae Klebsiella pneu·mo·ni·ae n. Friedlander's bacillus. strains. Clin Microbiol Infect. 2004:10:72 5. All material published in Emerging Infectious Diseases An emerging infectious disease (EID) is an infectious disease whose incidence has increased in the past 20 years and threatens to increase in the near future. EIDs include diseases caused by a newly identified microorganism or newly identified strain of a known microorganism (e.g. is in the public domain and may be used and reprinted without special permission; proper citation, however, is required. (1) ExPEC: papEF (P fimbrial fimbrial pertaining to or emanating from fimbriae. fimbrial cysts cysts in the region of the ovulation fossa; appear to cause no impediment to fertility except in very old mares where they may obstruct ovulation. tip pilins); papG (P adhesin); papG alleles I, II, and Ill; sfaS (S fimbriae); focG (F1C fimbriae); iha (putative adhesin-siderophore); bmaE (M fimbriae); gafD (G fimbriae); F17a (F17a fimbriae); clpG (CS31A adhesin); afaE8 (afimbrial adhesin VIII); fimH (type 1 fimbriae); cnf1 (cytotoxic cy·to·tox·ic adj. Of, relating to, or producing a toxic effect on cells. cy  to·tox·ic necrotizing necrotizing /nec·ro·tiz·ing/ (nek´ro-tiz?ing) causing necrosis. Necrotizing Causing the death of a specific area of tissue. Human bites frequently cause necrotizing infections. factor); cdtB (cytolethal distending toxin); ireA (siderophore siderophore /sid·ero·phore/ (sid´er-o-for?) a macrophage containing hemosiderin. sid·er·o·phore n. A large, extravasated, mononuclear phagocyte containing a granule of hemosiderin. receptor); sat (secreted autotransporter toxin); astA (S-like enterotoxin enterotoxin /en·tero·tox·in/ (en´ter-o-tok?sin) 1. a toxin specific for the cells of the intestinal mucosa. 2. a toxin arising in the intestine. 3. ); iroN (siderophore receptor); fyuA (yersiniabactin receptor); kpsM II, K1, and K2 (kpsM II variants; group 2 capsule); kpsM III (group 3 capsule); rfc (O4 lipopolysaccharide lipopolysaccharide /lipo·poly·sac·cha·ride/ (-pol?e-sak´ah-rid) 1. a molecule in which lipids and polysaccharides are linked. 2. synthesis); cvaC (colicin colicin /col·i·cin/ (kol´i-sin) a protein secreted by colicinogenic strains of Escherichia coli and other enteric bacteria; lethal to related, sensitive bacteria. col·i·cin n. V); traT (serum-resistance associated outer membrane The outer membrane refers to the outside membranes of Gram-negative bacteria, the chloroplast, or the mitochondria. It is used to maintain the shape of the organelle contained within its structure, and it acts as a barrier against certain dangers. protein); ibeA (invasion of brain endothelium endothelium /en·do·the·li·um/ (-the´le-um) pl. endothe´lia the layer of epithelial cells that lines the cavities of the heart, the serous cavities, and the lumina of the blood and lymph vessels. ); ompT (outer membrane protease protease /pro·te·ase/ (pro´te-as) endopeptidase. pro·te·ase n. Any of various enzymes, including the proteinases and peptidases, that catalyze the hydrolytic breakdown of proteins. T); iss (increased serum survival); usp (uropathogenic specific protein); malX (marker for pathogenicity-associated island from strain CFT CFT complement fixation test; see under fixation. CFT complement fixation test. 073); and H7 fliC variant (flagellin flagellin /fla·gel·lin/ (flah-jel´in) a protein of bacterial flagella; it is composed of subunits in several-stranded helical arrangement. ). Kuntaman Kuntaman, *(1) Endang Sri Lestari, ([dagger])(1) Juliette A. Severin, ([double dagger double dagger n. A reference mark (  ) used in printing and writing. Also called diesis.Noun 1. ])(1) Irma M. Kershof, ([double dagger]) Ni Made Mertaniasih, * Marijam Purwanta, * Usman Hadi, * James R. Johnson, ([section]) Alex van Belkum, ([double dagger]) and Henri A. Verbrugh ([double dagger]), on behalf of the Antimicrobial Resistance in Indonesia, Prevalence and Prevention Study Group (2) * Airlangga University, Surabaya, Indonesia; ([dagger]) Diponegoro University Pleburan Campus is the oldest campus since the existed campuses were merged in its early establishment. This campus occupies seven-hectare area, which facilitates School of Social Sciences, Magister Program and some operational units. , Semarang, Indonesia; ([double dagger]) Erasmus Medical Center, Rotterdam, the Netherlands; and ([section]) Minneapolis Veterans Affairs Medical Center, Minneapolis, Minnesota “Minneapolis” redirects here. For other uses, see Minneapolis (disambiguation). Minneapolis (pronounced IPA: /ˌmɪniˈæpəlɪs/) is the largest city in the U.S. , USA (1) The first 3 authors contributed equally to this manuscript. (2) Widjoseno Gardjito, Erni P. Kolopaking, Djoko Roeshadi, Eddy Rahardjo, Hari Parathon, Kuntaman Kuntaman, Ni Made Mertaniasih, Nun Zairina, Endang Isbandiati, Mariyatul Qibtiyah, Marijam Purwanta, Usman Hadi, Ariawan Soejoenoes, Budi Riyanto, Hendro Wahyono, Musrichan Adhisaputro, Bambang Triwara, Endang Sri Lestari, Bambang Wibowo, Muchlis AU Sofro, Helmia Farida, Peterhans van den Broek, Offra Duerink, Henri Verbrugh, Inge Gyssens, and Monique Keuters. Address for correspondence: Alex van Belkum, Erasmus MC The Erasmus MC (medical center) is the university hospital of the city of Rotterdam. It is affiliated with the Erasmus University. Special units include:
Table 1. Distribution of phylogenetic groups and virulence factors *
Group or All isolates FQ-susceptible FQ-resistant
factor (n = 396) (n = 200) (n = 196) p values
A 215 (54) 103 (52) 112 (57) NS
B1 102 (26) 59 (30) 43 (22) NS
B2 17 (4) 15 (8) 2 (1) 0.001
D 62 (16) 23 (12) 39 (20) 0.02
papA 28 (7) 27 (14) 1 (1) <0.001
papC 29 (7) 28 (14) 1 (1) <0.001
sfa/focDE 8 (2) 8 (4) 0 0.007
afa/draBC 11 (3) 11 (6) 0 0.001
iutA 131 (33) 61 (31) 70 (36) NS
hlyD 20 (5) 20 (10) 0 <0.001
kpsM II 56 (14) 54 (27) 2 (1) <0.001
ExPEC 44 (11) 40 (20) 4 (2) <0.001
* FQ, fluoroquinolone; ExPEC, extraintestinal pathogenic Escherichia
coli, NS, not significant. Screening for ExPEC was performed for 199
FQ-susceptible and 195 FQ-resistant isolates. Data are no. (%) of
isolates.
Table 2. Distribution of virulence factors
Phylogenetic group, n (%)
All
Virulence isolates A B1 B2
factor (n = 394) (n = 215) (n = 101) (n = 17) D (n = 61)
papA 28 (7) 7 (3) 11 (11) 8 (47) * 2 (3)
papC 29 (7) 8 (4) 11 (11) 8 (47) * 2 (3)
iutA 131 (33) 66 (31) 32 (32) 8 (47) * 25 (41)
kpsM II 56 (14) 19 (9) 23 (23) 11 (65) * 3 (5)
hlyD 20 (5) 8 (4) 7 (7) 5 (29) * 0
sfa/focDE 8 (2) 2 (1) 4 (4) 2 (12) * 0
afa/draBC 11 (3) 6 (3) 2 (2) 1 (6) 2 (3)
* p<0.05.
Table 3. Distribution of phylogenetic groups and virulence factors *
Prevalence of associated characteristic, n (%)
All isolates FQ-susceptible FQ-resistant p
Characteristic (n = 44) (n = 40) (n = 4) values
Group A 16 (36) 14 (35) 2 (50) NS
Group B1 14 (32) 14 (35) 0 NS
Group B2 9 (21) 9 (23) 0 NS
Group D 5 (11) 3 (8) 2 (50) NS
Surabaya 23 (52) 22 (55) 1 (25) NS
Semarang 21 (48) 18 (45) 3 (75) NS
Admission 13 (30) 12 (30) 1 (25) NS
Discharge 16 (36) 14 (35) 2 (50) NS
PHC 10 (23) 9 (23) 1 (25) NS
Relatives 5 (11) 5 (13) 0 NS
iha 25 (58) 25 (64) 0 0.025
sat 25 (58) 25 (64) 0 0.025
fyuA 35 (81) 35 (90) 0 0.001
ibeA 3 (7) 1 (3) 2 (50) 0.019
malX 26 (60) 26 (67) 0 0.019
* FQ, fluoroquinolone; NS, not significant; PHC, primary healthcare
center. Extended virulence typing was performed for 39 FQ-susceptible
isolates and 4 FQ-resistant isolates. Only those virulence factors are
shown for which the comparison of FQ-resistant extraintestinal
pathogenic Escherichia coli (ExPEC) to FQ-susceptible ExPEC was
significant.
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