Distribution and characteristics of Escherichia coli clonal group A(1).Among 1,102 recent Escherichia Escherichia co´li a species constituting the greater part of the normal intestinal flora of humans and other animals; it is a frequent cause of urinary tract infections and epidemic diarrheal disease, especially in children. Esch·e·rich·i·a ( coil clinical isolates, clonal group A was identified in 17 of 20 (U.S. and non-U.S.) geographic locales, mainly among U.S. isolates (9% vs. 3%; p < 0.001) and those resistant to trimethoprim-sulfamethoxazole (10% vs. 1.7%; p < 0.001). The extensive antimicrobial resistance and virulence profiles of clonal underlie its recent widespread emergence. The Study The recently recognized 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. clonal group A (CGA CGA - Color Graphics Adapter (320 by 200 pixels, 4 colors; 1.60:1 or 640 by 200 pixels, 2 colors; 3.20:1) CGA - California Grocers Association CGA - Canadian Gas Association CGA - Canadian Gelbvieh Association (Calgary, Alberta, Canada) CGA - Carrier Group Alarm CGA - Central of Georgia Railway Company CGA - Certified General Accountant CGA - Certified Graphoanalyst CGA - Charitable Gift Annuity CGA - Chinese Gymnastics Association) accounts for up to 50% of trimethoprim-sulfamethoxazole (TMP-SMZ--resistant E. coli from U.S. women with acute uncomplicated cystitis and pyelonephritis (1-3). Available data show CGA to exhibit a stereotypical virulence factor (VF) profile and a conserved multidrug antimicrobial resistance phenotype, i.e., to ampicillin, chloramphenicol, streptomycin, sulfonamides, tetracycline, and trimethoprim (ACSSuTTp), which is conjugally transferable on a large plasmid (1,2). Together with CGA's unusual O antigens (O11, O17, 073, and O77), these findings suggested that CGA represents a newly emerged virulent clonal group (1,2). CGA's homogeneity across geographic locales, and the indistinguishable pulsed-field gel electrophoresis (PFGE) profiles of clustered CGA isolates within 1 community (1), suggested recent and possibly ongoing dissemination, a novel paradigm for extraintestinal pathogenic E. coli (ExPEC) (4). To date, CGA has been studied only within the United States, predominantly among women with uncomplicated urinary tract infections (UTI). Its occurrence in some locales has been questioned (5), and its antimicrobial susceptibility profile has been assessed for only 12 drugs (1,2,6). Accordingly, we sought to more fully define the global distribution, host range, virulence characteristics, and resistance phenotypes of CGA. Twenty clinical microbiology laboratories (10 U.S., 10 non-U.S.) each provided approximately 25 consecutive TMP-SMZ-resistant and TMP-SMZ susceptible E. coli isolates, except for 2 laboratories that provided resistant isolates only (Table 1). Isolates were distributed by specimen type (urine/other) and source (inpatient/outpatient). Antimicrobial drug-resistant and -susceptible isolates were collected approximately concurrently during 2001 from each site, except London (1999) (7) and Columbus (1999 and 2002). When available, data regarding specimen type and host gender, age, and inpatient/outpatient status were provided. Phylogenetic group (A, B1, B2, or D) was defined by triplex polymerase chain reaction (PCR) (8). Group D isolates were defined as CGA if by random amplified polymorphic DNA (RAPD) analysis they resembled CGA controls with primers 1254 and 1290, or with one of these plus [greater than or equal to] 2 of primers 1247, 1281, or 1283 (2). PFGE analysis used XbaI (1). CGA isolates and (2:1) geographically matched controls selected randomly based on the local TMP-SMZ resistance prevalence were tested for 35 ExPEC-associated virulence markers and 13 papA alleles by PCR (2). Such typing predicts experimental in vivo virulence (9). Isolates were defined as ExPEC if positive for [greater than or equal to] 2 of papA and/or papC, sfa/foc, afa/dra, iutA, and kpsM (10). The aggregate virulence score was the number of different virulence markers detected in an isolate, adjusted for multiple detection of certain operons. O typing was carried out by the E. coli Reference Center (University Park, PA). O antigens O1, 02, 04, 06, 07, 016, 018, 025, and 075 were considered UTI-associated (O-UTI) (10). Susceptibility testing of the isolates to 30 drugs was carried out by broth microdilution (11) or disk diffusion (nitrofurantoin) (11), by using E. coli ATCC 25299 for reference and National Committee for Clinical Laboratory Standards (NCCLS)--specified interpretative criteria (12), except for kanamycin kanamycin /kan·a·my·cin/ (kan?ah-mi´sin) an aminoglycoside antibiotic derived from Streptomyces kanamyceticus, effective against aerobic gram-negative bacilli and some gram-positive bacteria, including mycobacteria; used as the sulfate salt., spectinomycin, and streptomycin (resistant at MICs of [greater than or equal to] 25 mg/L, [greater than or equal to] 128 mg/L, and [greater than or equal to] 8 mg/L, respectively). The aggregate resistance score was the number of different agents to which an isolate exhibited resistance. Statistical analysis used a Fisher exact or a chi-square test for comparisons of proportions and the Mann-Whitney U test for comparisons of scores. Multiple variables were assessed as predictors of selected outcomes by multivariate logistic regression or multiple linear regression. The 1,102 clinical E. coli isolates were divided evenly by U.S. and non-U.S. origin and TMP-SMZ resistance stares (Table 2). Overall, phylogenetic group B2 predominated (44%), followed by group D (27%). Group D was significantly more prevalent among U.S. than non-U.S. isolates (34% vs. 21%: p < 0.001). TMP-SMZ-resistant isolates exhibited significant shifts from group B2 toward groups A, D, or both. The nearly 2-fold greater prevalence of group D among TMP-SMZ-resistant isolates reversed, for U.S. isolates, the "B2 > D" pattern of susceptible isolates. By RAPD analysis, 23% of group D isolates (6% overall) represented CGA (Table 2). CGA was strongly associated with TMP-SMZ resistance (10% of resistant isolates, 1.7% of susceptible: p < 0.001) and a U.S. origin (9% vs. 3%: p < 0.001). CGA accounted for 15% of U.S. TMP-SMZ--resistant isolates and 5% of those from abroad (p < 0.001), but for a similarly low proportion of U.S. (2%) and non-U.S. (1.5%) susceptible isolates. According to multivariate logistic regression analysis, after accounting for TMP-SMZ resistance and U.S. origin, none of the other source variables (specimen type and host gender, age, and inpatient/outpatient status) was significantly associated with CGA status or appreciably altered the association of TMP-SMZ resistance or U.S. origin with CGA status (not shown). CGA occurred in all but 3 locales (1-10 isolates per locale), accounting for up to 29% of local resistant isolates (median, 9.5%) (Table l). CGA was highly prevalent (20%-25%) among resistant isolates from the 3 pediatric centers (Columbus, Houston, and Toulouse) and the veterans' hospital (Tucson). Toulouse exhibited the highest non-U.S. CGA prevalence, whereas nearby Brest Brest, city, FranceBrest (brĕst), city (1990 pop. 153,099), Finistère dept., NW France, on an inlet of the Atlantic Ocean. It is a commercial port, an important naval station, and the seat of the French Naval Academy. There is a national engineering school in Brest and nearby is the Oceanographic Center of Brittany. lacked CGA (Table 1). CGA accounted for 29% of the ostensibly nonclonal (5) TMP-SMZ-resistant isolates from Chicago. Consistent with this, XbaI PFGE profiles of 6 Chicago and 2 reference CGA isolates were highly similar (Figure 1).[FIGURE 1 OMITTED] CGA isolates differed significantly from controls, according to almost all characteristics analyzed; they were significantly enriched with the O11, O17, and 077 antigens, certain VFs (F16 papA allele, papAHCEFG, papG allele II, iha, iutA, kpsM II, traT, and ompT), and ExPEC status, but lacked other traits (Figure 2). Aggregate virulence scores were similar for CGA and controls (medians, 8.0) but were less diverse for CGA (range 5-9, vs. 1-13). [FIGURE 2 OMITTED] By multivariate logistic regression, both CGA status and phylogenetic group B2 were significant independent predictors of ExPEC status, with CGA exhibiting an odds ratio (OR) of 21.9 (95% confidence interval [CI], 6.1-78.2; p < 0.001), and group B2 an OR of 2.4 (CI, 1.7-3.4; p < 0.001). Additionally, by multiple linear regression, CGA status (standardized regression coefficient [beta] = 0.57; p < 0.001) and group B2 status ([beta] = 0.596; p < 0.001) predicted VF score better than did O-UTI ([beta] = 0.32; p = 0.002). Antimicrobial resistance phenotypes were compared between CGA isolates and a subset of the controls, which had been selected to provide an unbiased distribution of TMP-SMZ resistance (Figure 2). CGA exhibited a higher prevalence of resistance to 10 individual drugs, any drug, and ACSSuTTp, whereas controls exhibited a low but measurable prevalence of resistance to 7 drugs to which all CGA isolates were susceptible. Accordingly, resistance scores were significantly higher for CGA than controls (median 8.0 [range 1-11] vs. 5.5 [range 0-15]; p = 0.001). Among TMP-SMZ-resistant isolates, TMP-SMZ MICs ranged from 32/608 mg/L to >520/9,880 rag/L; 61% of resistant isolates had MICs [greater than or equal to] 520/9,880 mg/L. CGA accounted for 67% of this highly resistant population (p = 0.01 vs. controls). The U.S. and non-U.S. CGA isolates exhibited only 2 statistically significant differences for VF profiles, O antigens, and resistance phenotypes, with iroN (p = 0.03) and absence of ompT (p = 0.008) associated with non-U.S. isolates. Conclusions We found that the recently described E. coli CGA is globally but heterogeneously distributed and more prevalent within the United States than abroad. Clonal group A affects diverse host populations (including inpatients, outpatients, adults, children, men, and women), infects urinary tract and nonurinary tract sites, is strongly associated with TMP-SMZ resistance (particularly high-level resistance), and exhibits a robust virulence profile suggesting enhanced extraintestinal virulence. This combination of resistance and virulence may account for CGA's recent emergence as a broadly disseminated "epidemic clone" (1-3,6,13,14). The greater overall prevalence of CGA within the United States suggests a U.S. origin for CGA. However, it also could reflect more rapid clonal expansion within the United States due to enhanced dissemination or more favorable conditions for outgrowth, including possibly less competition from other potential occupants of the same niche(s). The variable prevalence of CGA among even closely situated locales, both within the United States and abroad, might reflect true geographic heterogeneity, versus locale-specific differences in patient populations, selection criteria, and collection intervals. Studies that compare well-defined, homogeneous, concurrent populations from different locales are needed. The new evidence of CGA as a prominent TMP-SMZ-resistant pathogen among children and veterans extends the0 known host range of CGA, consistent with a recent report of CGA as a community-wide TMP-SMZ-resistant pathogen in Denver, Colorado (6). This finding illustrates CGA's pathogenic versatility. That 29% of the TMP-SMZ-resistant isolates from Chicago, Illinois, proved to be CGA and resembled reference CGA isolates by PFGE, despite a previous PFGEbased assessment of nonclonality (5), illustrates the limitations of conventional PFGE analysis as a screen for CGA. We have developed a CGA-specific PCR assay, based on a single nucleotide polymorphism within fumC, to provide improved screening for CGA (15). CGA's robust, highly homogeneous consensus VF profile (F16 papA allele, papG allele II, iutA, kpsM II, traT, and ompT) suggests considerable extraintestinal virulence potential, an inference supported by experimental data indicating that CGA is able to compete successfully with classic group B2-derived pathogens in a mouse UTI model (J.R. Johnson, unpub, data). Determination of which VFs of CGA contribute most to pathogenicity may identify future targets for preventive interventions. In our study, antimicrobial resistance was more extensive and, with TMP-SMZ, more potent for CGA than controls. These factors may be contributing to CGA's global emergence. Conceivably, high-level TMP-SMZ resistance could allow CGA to out-compete even other TMP-SMZ resistant strains. CGA's resistance involved primarily older agents, whereas fluoroquinolone and cephalosporin resistance was confined to controls. However, the emergence of fluoroquinolone resistance within the closely related O15:K52:H1 clonal group (2,13) suggests that this potential exists also for CGA. The study's strengths include large population, broad geographic sampling, matching of CGA and control isolates, and extensive range of traits analyzed. Limitations include the heterogeneous inclusion criteria, gaps in global surveillance, possible type I errors from multiple comparisons, and limited sampling per locale. In summary, we found CGA to be a globally disseminated, multidrug-resistant clonal group of pathogenic E. coli with a broad range of human hosts. Although more prevalent within the United States than abroad, CGA exhibits characteristic O antigens, resistance markers, and virulence traits wherever encountered. Further study is needed of the origins, virulence mechanisms, geographic distribution, clinical associations, and modes of dissemination of CQA CQA - Canadian Quilters' Association (Association Canadienne de la Courtepointe) CQA - Center For Quality Education CQA - Central Quality Assurance CQA - Certified Quality Analyst CQA - Certified Quality Auditor CQA - Chicago Quantitative Alliance CQA - Commandant's Quality Award (USCG) CQA - Construction Quality Assurance CQA - Contemporary QuiltArt Association CQA - Contract Quality Assurance CQA - Customer Quality Action CQA - Quality Auditor Certification.
Table 1. Sources of Escherichia coliclinical isolates and local
prevalence of E. coliclonal group A (CGA) by
trimethoprim-sulfamethoxazole (TMP-SMZ) phenotype *
I/P or
Location and Patient Specimen O/P
type of institution population type(s) ([dagger])
Curitiba, Brazil Mostly adults Urine Unk
University medical center
Montreal, Canada Mostly adults Urine, other I/P, O/P
University medical center
London, England Mostly adults Urine Unk
Teaching hospital
Brest, France Mostly adults Urine, blood I/P, O/P
University medical center
Toulouse, France Children Urine, other I/P, O/P
Children's hospital
Milnich, Germany Mostly adults Unknown Unk
University medical center
Afula, Israel Women Urine O/P
Outpatient clinic
Barcelona, Spain Mostly adults Urine, other I/P, O/P
Private medical center
Goteborg, Sweden Mostly adults Unknown Unk
University medical center
Bangkok, Thailand Adults Urine, other VP, O/P
Government hospital
Baltimore, MD, USA Mostly women Urine O/P
Student health center
Billings, MT, USA Mostly adults Urine, other I/P, O/P
Private medical center
Birmingham, AL, USA Mostly adults Urine, other I/P, O/P
University medical center
Chicago, IL, USA Mostly adults Urine O/P
County medical center
Columbus, OH, USA Children Urine I/P, O/P
University medical center
Iowa City, IA, USA Unknown Urine, other Unk
(Multiple)
Houston, TX, USA Children Urine, other I/P, O/P
Children's medical center
Rochester, MN, USA Mostly adults Urine, other I/P, O/P
Private medical center
Seattle, WA, USA Adults Unknown Unk
Teaching hospital
Tucson, AZ, USA Men Unknown Unk
Veterans' medical center
Local
TMP-SMZ
Location and resistance Total no.
type of institution rate (%) isolates
Curitiba, Brazil 33 60
University medical center
Montreal, Canada 33 50
University medical center
London, England 29 46
Teaching hospital
Brest, France 30 59
University medical center
Toulouse, France 24 50
Children's hospital
Milnich, Germany 24 55
University medical center
Afula, Israel 30 100
Outpatient clinic
Barcelona, Spain 37 74
Private medical center
Goteborg, Sweden 10 48
University medical center
Bangkok, Thailand 67 48
Government hospital
Baltimore, MD, USA 29 62
Student health center
Billings, MT, USA 11 50
Private medical center
Birmingham, AL, USA 18 48
University medical center
Chicago, IL, USA 24 24
County medical center
Columbus, OH, USA 13 59
University medical center
Iowa City, IA, USA 18 58
(Multiple)
Houston, TX, USA 36 60
Children's medical center
Rochester, MN, USA 16 54
Private medical center
Seattle, WA, USA 15 50
Teaching hospital
Tucson, AZ, USA 25 47
Veterans' medical center
Prevalence of CGA,
proportion (%)
([double dagger])
Location and TMP-SMZ- TMP-SMZ-
type of institution susceptible resistant p value
Curitiba, Brazil 1/30 (3) 2/30 (7)
University medical center
Montreal, Canada 0/25 (0) 0/25 (0)
University medical center
London, England n.a. 0/46 (0)
Teaching hospital
Brest, France 0/29 (0) 0/30 (0)
University medical center
Toulouse, France 0/25 (0) 5/25 (20) 0.05
Children's hospital
Milnich, Germany 0/27 (0) 2/28 (14)
University medical center
Afula, Israel 1/51 (2) 3/49 (6)
Outpatient clinic
Barcelona, Spain 2/30 (7) 0/44 (0)
Private medical center
Goteborg, Sweden 0/25 (0) 1/23 (4)
University medical center
Bangkok, Thailand 0/24 (0) 1/24 (4)
Government hospital
Baltimore, MD, USA 2/24 (8) 7/38 (18)
Student health center
Billings, MT, USA 0/25 (0) 3/25 (12)
Private medical center
Birmingham, AL, USA 1/23 (4) 1/25 (4)
University medical center
Chicago, IL, USA NA 7/24 (29)
County medical center
Columbus, OH, USA 0/33 (0) 6/26 (23) 0.005
University medical center
Iowa City, IA, USA 0/27 (0) 4/31 (13)
(Multiple)
Houston, TX, USA 1/32 (3) 7/28 (25) 0.02
Children's medical center
Rochester, MN, USA 1/28 (4) 0/26 (0)
Private medical center
Seattle, WA, USA 0/24 (0) 6/26 (23) 0.02
Teaching hospital
Tucson, AZ, USA 0/34 (0) 2/13 (15)
Veterans' medical center
* Isolates were collected in 2001 for all sites except London, England
(1999), and Columbus, OH, USA (1999 for susceptible isolates and part
of resistant isolates; 2002 for remaining resistant isolates).
([dagger]) I/P, inpatient; O/P, outpatient; Unk, unknown.
([double dagger]) Eighteen centers contributed both susceptible and
resistant isolates (total, 47 to 100 isolates each; median, 55). Two
centers contributed only resistant isolates (Chicago, IL, USA: 24
isolates; London, England: 46 isolates). Specimen type was known for 55
of the CGA isolates and was urine for 42, nonurine for 13 (10 blood, 1
tracheal aspirate, 1 fecal, 1 unspecified nonurine).
Table 2. Prevalence of phylogenetic groups and Escherichia coli clonal
group A (CGA) according to locale and resistance phenotype
Prevalence of indicated E. coli group by locale and TMP-SMZ *
phenotype, no. (column %)
Total (N = 1,102)
E. coli p value
group Susceptible Resistant ([double
([dagger]) Overall (n = 516) (n = 586) dagger])
ECOR A 168 (15) 65 (13) 103 (18) 0.02
ECOR B1 143 (13) 70 (14 73 (12) NS
ECOR B2 483 (44) 277 (54) 210 (35) <0.001
([section]) ([section])
ECOR D 298 (27) 98 (19) 200 (34) <0.001
([section]) ([section])
CGA 68 (6) 9 (1.7) 59 (10) <0.001
United States (N = 512)
E. coli
group Susceptible Resistant p value
([dagger]) Overall (n = 250) (n = 262) ([dagger])
ECOR A 63 (12) 28 (11) 35 (13) NS
ECOR B1 59 (12) 27 (11) 32 (12) NS
ECOR B2 213 (42) 134 (54) 79 (30) <0.001
([section]) ([section])
ECOR D 176 (34) 60 (24) 116 (44) <0.001
([section]) ([section])
([paragraph]) (#)
CGA 48 (9) 5 (2) 43 (16) <0.001
Non-United States (N = 590)
E. coli
group Susceptible Resistant p value
([dagger]) Overall (n = 266) (n = 324) ([dagger])
ECOR A 105 (18) 37 (14) 68 (21) 0.03
ECOR B1 84 (14) 43 (16) 41 (13) NS
ECOR B2 270 (46) 143 (54) 127 (39) <0.001
([section]) ([section])
ECOR D 122 (21) 38 (14) 84 (26) 0.001
([section]) ([section])
([paragraph]) (#)
CGA 20 (3.4) 4 (1.5) 16 (5) 0.02
* ECOR, E. coli reference
([dagger]) TMP-SMZ, trimethoprim-sulfamethoxazole.
([double dagger]) p values (by Fisher exact test) for comparison of
susceptible and resistant isolates are shown when <0.05. NS, not
significant.
([section]) For prevalence of group B2 (versus group D) within same
column; p [less than or equal to] 0.01, McNemar's test.
([paragraph]) For prevalence of group D among U.S. (vs. non-U.S.)
susceptible isolates; p = 0.005 (Fisher exact test).
(#) For prevalence of group D among U.S. (vs. non-U.S.) resistant
isolates; p < 0.001 (Fisher exact test).
Acknowledgments We thank Dave Prentiss for preparing the figures; Sheldon Finver, Abby Gajewski, and Timothy T. O'Bryan for invaluable laboratory assistance; the clinical microbiology laboratory of the Minneapolis VA Medical Center for assisting with antimicrobial susceptibility testing; and Amee Manges and Lee Riley for providing strain SEQ102. This material is based upon work supported by Office of Research and Development, Medical Research Service, Department of Veterans Affairs, and by Bayer Inc., Merck, and Procter & Gamble (J.R.J.). J.R.J. has received grants, honoraria, or both, from Bayer, Merck, Ortho-McNeill, Procter and Gamble, and Wyeth-Ayerst. References (1.) Manges AR, Johnson JR, Foxman B, O'Bryan TT, Fullerton KE, Riley LW. Widespread distribution of urinary tract infections caused by a multidrug-resistant Escherichia coli clonal group. N Engl J Med. 2001;345:1007-13. (2.) Johnson JR, Manges AR, O'Bryan TT, Riley LR. A disseminated multi-drug resistant clonal group of extraintestinal pathogenic Escherichia coli as a cause of pyelonephritis. Lancet. 2002;359:2249-51. (3.) Manges AR, Dietrich PS, Riley LW. Multidrug-resistant Escherichia coli clonal groups causing community-acquired pyelonephritis. Clin Infect Dis. 2004;38:329-34. (4.) Stature WE. An epidemic of urinary tract infections? N Engl J Med. 2001;345:1055-7. (5.) Petrof EO, Schwartz DN, Quinnn JP. Urinary tract infections and a nmltidrug-resistant Escherichia coli clonal group [letter]. N Engl J Med. 2002;346:535. (6.) Burman WJ, Breese PE, Murray BE, Singh KV, Batal HA, MacKenzie TA, et al. Conventional and molecular epidemiology of trimethoprim-sulfamethoxazole resistance among urinary Escherichia coli isolates. Am J Med.2003;115:358-64. (7.) Enne VI, Livermore DM, Stephens P, Hall LCM. Persistence of sulphonamide resistance in Escherichia coli in the UK despite national prescribing restriction. Lancet. 2001;357:1325-8. (8.) Clermont O, Bonacorsi S, Bingen Bingen (bĭng`ən) or Bingen am Rhein (äm rīn), city (1994 pop. 25,020), Rhineland-Palatinate, W Germany, where the Nahe River enters the Rhine. E. Rapid and simple determination of the Escherichia coli phylogenetic group. Appl Environ Microbiol. 2000;66:4555-8. (9.) Johnson JR, Kuskowski M, Denamur E, Elion Gertrude Belle 1918-1999. American drug researcher. She shared a 1988 Nobel Prize for developing drugs to treat leukemia and gout. (10.) Johnson JR, Murray AC, Gajewski A, Sullivan M, Shippes P, Kuskowski MA, et al. Isolation and molecular characterization of nalidixic acid-resistant cxtraintestinal pathogenic Escherichia coli from retail chicken products. Antimicrob Agents Chemother. 2003;47:2161-8. (11.) National Committee for Clinical Laboratory Standards. Methods for dilution antimicrobial susceptibility tests for bacteria that grow aerobically, 6th ed. Vol. 23, no. 2. M7-A6. Wayne (PA): The Committee; 2003. (12.) National Committee for Clinical Laboratory Standards. Performance standards for antimicrobial susceptibility testing; fourteenth informational supplement. Vol. 24, no. 1. M100-S14. Wayne (PA): The Committee; 2004. (13.) Johnson JR, Kuskowski MA, Owens K, Gajewski A, Winokur PL. Phylogenetic origin and virulence genotype in relation to resistance to fluoroquinolones and/or extended spectrum cephalosporins and cephamycins among Escherichia coli isolates from animals and humans. J Infect Dis. 2003;188:759-68. (14.) Johnson JR, Russo TA. "Uropathogenic" Escherichia coil as agents of diverse non-urinary-tract extraintestinal infections. J Infect Dis. 2002;186:859-64. (15.) Johnson JR, Owens, Manges A, Riley L. Rapid and specific detection of Escherichia coli clonal group A by gene-specific PCR. J Clin Microbiol. 2004;42:2618-22. James R. Johnson, * ([dagger]) Andrew C. Murray, * ([dagger]) Michael A. Kuskowski, * ([dagger]) Soren Schubert, ([double dagger]) Marie-Francoise Prere, ([sections]) Bertrand Picard, ([paragraph]) Raul Colodner, (#) Raul Raz, (#) ** and the Trans-Global Initiative for Antimicrobial Resistance Analysis (TIARA) Investigators (2) * VA Medical Center, Minneapolis, Minnesota, USA; ([dagger]) University of Minnesota, Minneapolis, Minnesota, USA; ([double dagger]) Max von Pettenkofer-Institut fur Hygiene und Medizinische Mikrobiologie, Munchen, Germany; ([sections]) Centre Hospitalier Universitaire Purpan, Toulouse, France; ([paragraph]) Hopital Morvan, Brest, France; (#) HaEmek Medical Center, Afula, Israel; and ** Technion School of Medicine, Afula, Israel (1) Presented in part at the American Society for Microbiology 103rd General Meeting, May 18-22, 2003, Washington, D.C. (2) The TIARA investigators include the following: Sacared Bodison (University of Maryland, College Park, MD), Franklin R. Cockerill, III (Mayo Clinic and Mayo Medical School, Rochester, MN), Clovis Arns da Cunha (Curitiba-PR, Brazil), Peter Echeverria and Sriluck Simasathien (Armed Forces Research Institute of Medical Sciences and Phramonkutkho Army Hospital, Bangkok, Thailand), Wim Gaastra (University of Utrecht, Utrecht, The Netherlands), Lucinda M.C. Hall (St Bartholomew's and the Royal London School of Medicine and Dentistry, London, UK), Marina Klein (McGill University Health Centre, Montreal, Quebec, Canada), Hank A. Lockman (Battelle Memorial Institute, Columbus, OH), Imad Omer and Jane R. Schwebke (University of Alabama, Birmingham, AL), Guillem Prats (Hospital Vail d'Hebron, Barcelona, Spain), Robed M. Rakita (Virginia Mason Medical Center, Seattle, WA), Susan Rossman (Texas Childrens Hospital, Houston, TX), Ronald Schifman (Southern Arizona VA Medical Center, Tucson, AZ), Ronald Smith (Billings Clinic and Providence Medical Center, Billings, MT), and Patricia L. Winokur (VA Medical Center and University of Iowa, Iowa City, IA). Address for correspondence: James R. Johnson, Infectious Diseases (111F), Minneapolis VA Medical Center, 1 Veterans Drive, Minneapolis, MN 55417, USA; fax: 612-727-5995, email: johns007@umn.edu Dr. Johnson is professor of medicine and director of the Infectious Diseases Fellowship Program at the University of Minnesota, and head of the molecular epidemiology laboratory at the Minneapolis VA Medical Center. His research focuses on the molecular epidemiology, ecology, evolution, and virulence of extraintestinal pathogenic and antimicrobial-resistant E. coli. |
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