The Effect of Mutations in Type II Topoisomerases on Fluoroquinolone Resistance in Clinical Canine Urine Escherichia coli Isolates by Megan Grace Behringer A thesis submitted to the Graduate Faculty of Auburn University in partial fulfillment of the requirements for the Degree of Masters of Science Auburn, Alabama May 9, 2011 Approved by Dawn M. Boothe, Chair, Professor of Physiology and Pharmacology Stuart Price, Associate Professor of Pathobiology Jacek Wower, Professor of Biochemistry ii Abstract A series of experiments were preformed in order to validate a rapid FRET-PCR based assay for the detection of fluoroquinolone resistance in small animal Escherichia coli urinary tract infection (UTI) isolates. Three hundred and six canine UTI E. coli isolates from pure culture were subjected to the FRET-PCR assay. Fourty-three of 50 enrofloxacin resistant isolates were detected by FRET-PCR for a sensitivity of 86% and a specificity of 97%. Urine was then spiked with 7 isolates of varying minimum inhibitory concentration for enrofloxacin (MICEnro) to evaluate sensitivity of detection and resistant isolates were detected at concentrations as small as 103 CFUs. Lastly DNA extracted from 438 small animal urine samples was subjected to the FRET-PCR assay. Two hundred and seventy-eight were confirmed to contain E. coli, 18 of which were resistant to enrofloxacin based on susceptibility testing. The FRET assay positively identified 15 of 18 enrofloxacin resistant urine samples (sensitivity of 83.33%) and negatively identified 388 of 420 samples (specificity of 92.36%). When compared to FRET run on DNA extracted from isolates, isolates had better specificity and sensitivity than FRET run on DNA extracted from urine samples. iii Acknowledgments This thesis is the product of the love and support of so many individuals. Dr. Dawn Boothe provided the opportunity and guidance that allowed me to successfully conduct my research. Thanks to my committee members, Dr. Jacek Wower and Dr. Stuart Price for their time and assistance. Special thanks to Jameson Sofge for managing my funding and handling the ordering of all of my supplies which without none of this would have been at all possible. Many thanks to Kamoltip Thungrat for her emotional support and for providing the susceptibility data . Also, thanks to Auburn University Clinical Pathology and Clinical Microbiology for supplying the urine samples. Most of all I would like to thank my family, my father David and mother Kathleen who kept me motivated throughout the entire process. Without their love I would have never had made it this far in my studies and for that I am endlessly grateful. Blane Hollingsworth has remained patient with me, kept me sane and took care of me whenever I felt the world crashing down on me. Lastly, I am grateful to my brother Alex, for giving his encouragement when I needed it most. iv Table of Contents Abstract ......................................................................................................................................... ii Acknowledgements ...................................................................................................................... iii List of Tables ................................................................................................................................ v List of Figures .............................................................................................................................. vi Chapter 1: Literature Review: Genetic Factors Influencing Fluoroquinolone Resistance in Escherichia coli ........................................................................................................ 1 Chapter 2: Development and Evaluation of a FRET-PCR Assay for Determining Fluoroquinolone Resistance in Canine Urine Escherichia coli Isolates .............. ...34 Chapter 3: Evaluation of a FRET-PCR Assay for Determining Fluoroquinolone Resistant Escherichia coli in Clinical Urine Samples from Companion Animals ..................................................................................................................55 Appendix A: Data for Urines Containing Negative or Single Cultures?. .................................76 Appendix B: Data for Urines Containing Multiple Cultures?... ................................................90 v List of Tables Table 1: Drug MICs for E. coli cells over expressing acrAB, mdfA and norE. .......................... 12 Table 2: Susceptibilities of E. coli transformed with plasmids harboring different qnr genes. . 14 Table 3: Notation for Antimicrobials used and their respective drug classes............................. 43 Table 4: Results of Nucleotide Sequences for Determination of Assay Specificity ................... 48 Table 5: 7 Escherichia coli isolates of increasing MICEnro in inoculated urine .......................... 50 Table 6: Species, source, and origin of organisms isolated from urine samples ........................ 62 Table 7: Comparison of sensitivity and specificity of FRET assay by DNA extraction method ........................................................................................................................ 63 Table 8: Sensitivity and Specificity of FRET Assay by Collection Method .............................. 64 Table 9: FRET results for urine samples containing enrofloxacin resistant E. coli ................... 65 Table 10: Urine samples falsely identified by FRET to have enrofloxacin resistant E. coli ...... 66 vi List of Figures Figure 1: Progression of quinolone structure through generations ............................................... 3 Figure 2: Structure of AcrAB/TolC efflux system in E. coli ...................................................... 10 Figure 3: Prediction of secondary structure for plasmid based quinolone efflux pump QepA .. 16 Figure 4: Primer and Probe set designed for FRET-PCR ........................................................... 44 Figure 5: Melting curves from 3 gyrA mutation profiles encountered in the clinical isolates.... 45 Figure 6: Scatter plot of isolate MICEnro respective to Tm .......................................................... 46 Figure 7: Mean and Standard Deviation of Tm for isolates grouped by MICEnro class ........... 47 Figure 8: Melting Curves of Canine Urine Innoculated with Dilutions of E. coli...................... 51 Figure 8: log2 MICEnro vs. Tm for urine samples containing E. coli and E. coli isolates ............ 68 Figure 9: Contents of urine samples by collection method. ........................................................ 69 Figure 10: Distribution of urine samples containing multiple infective species by collection method ...................................................................................................... 70 Figure 11: Representative Melting curve analysis of DNA from both extraction methods ........ 71 Figure 12: Amplification curves of DNA from both extraction methods ................................... 72 1 CHAPTER I LITERATURE REVIEW: GENETIC FACTORS INFLUENCING FLUOROQUINOLONE RESISTANCE IN ESCHERICHIA COLI Topoisomerases Topoisomerases are enzymes responsible for controlling the tension of supercoiled DNA by facilitating the winding and unwinding during DNA replication and transcription. Winding and unwinding is especially important to reducing tension in front of the replication fork where the progress of the helicase and DNA polymerase machinery cause large amounts of force on the downstream DNA. Two classes of toposiomerases; Type I and Type II have been described. Type I topoisomerases are monomer proteins that cut and reanneal single stands of double stranded DNA, allowing for a change in the linking number by +1 or -1 coils to the double helix. Type I can be further broken down into three subclasses: Type IA, Type IB, and Type IC. Type IA?s structure resembles a lock and makes a break in the DNA to form a 5? phosphotyrosine intermediate. A strand or duplex of DNA is then passed through the break before reannealing the strands back together, thus introducing a positive or negative coil in an ATP independent process. In E. coli, the gene that codes for this enzyme is referred to as topA. Type IB and IC both work in a rotary fashion by nicking the double stranded DNA and forming a 3? phosphotyrosine intermediate while allowing the torque of the wound DNA to control the unwinding of the DNA until the single strands are reannealed. This process is also ATP independent. Type IB is coded for by topB in E. coli (Dean et al, 1983). 2 Type II topoisomerases are multimer proteins that cut and reanneal double strands of DNA, allowing for a change in the linking number by +2 or -2 coils to the double helix in an ATP dependant process. Type II can also be broken into subclasses Type IIA and Type IIB. Type IIA includes bacterial DNA gyrase and bacterial topoisomerase IV (topo IV) while Type IIB are only found in archaea and higher plants. E. coli DNA gyrase is a heterodimer coded for by genes gyrAB, while topo IV is of similar design but coded for by parCE. Their structure consists of an ATPase domain, a Rossmann fold (a motif that binds nucleotides such as NAD and FMN), a DNA binding domain, and a variable C terminus (Watt et al, 1994). DNA gyrase is solely responsible for relaxing positive supercoils ahead of the DNA replication fork. Topo IV, however, has an extra function in the cell. In addition to working like DNA gyrase to remove positive supercoils, it also has decatenating activity, being responsible for separating the daughter chromosome from the parent chromosome at the end of replication so that cell division can occur (Kato et al, 1990). Topoisomerases are the target of the quinolone drug class of antimicrobials. Quinolones interfere with DNA replication and RNA transcription by targeting the DNA/Topoisomerase duplex. Two quinolone molecules bind to the duplex (Yoshida et. al. 1993) and DNA is then cleaved by topoisomerase; however, religation of the double stranded break is inhibited and the unreligated DNA/topoisomerase complex is trapped within a DNA/topoisomerase/quinolone ternary complex (Critchlow and Maxwell, 1996) (Anderson et.al.1998). The Topoisomerase is unable to reanneal and religate the DNA strands back together, causing a lethal SOS response by the cell. Topoisomerase IV is also inhibited similarly in its concatamer releasing activity. In gram-negative bacteria, DNA gyrase is the primary target for quinolones while for gram-positive bacteria topoisomerase IV is the primary target. In E. coli the effects of quinolones on 3 topoisomerase IV appear to be more bacteriostatic as opposed to the bacteriacidal effects associated with DNA gyrase. (Khodursky, 1995) Quinolones and Drug Development Development of drugs in the quinolone class began with the discovery of naladixic acid in 1962 (Lesher, et. al, 1962). Discovered while producing chloroquine, an antimalarial drug as a derivative of 1,8-Naphthyridine, naladixic acid was found to be an effective antimicrobial against Enterobacteriaceae. Naladixic acid was followed by oxolinic acid (Turner, et. al., 1967), cinoxacin (Wick, et. al., 1973), and pipemidic acid (Shimizu, et. al.,1975); together, these drugs comprised the first generation of quinolone drugs. By 1963, naladixic acid-induced resistance in patients with E. coli urinary tract infections was observed (Barlow, 1963). Figure 1: Progression of quinolone structure through generations. 1,8-napthyridine is core molecule leading to the first generation quinolones (Naladixic acid), second generation quinolones (ciprofloxacin), third generation quinolones (levofloxacin) and fourth generation quinolones (moxifloxacin). 4 The second generation of quinolones marks the advent of fluoroquinolones in which a fluorine atom was added to C6 and the methyl group at C7 was replaced with a piperazine group. These changes increased bactericidal potency by improving cell penetration and binding to the DNA/Gyrase complex (Chu and Fernandes, 1989). This second generation was further divided into two classes. Class 1 includes norfloxacin, the first fluoroquinolone to be approved for use in humans in the United States, (Ito et. al., 1980), lomefloxacin (Hirose et. al. 1987), and enoxacin whose spectrum are similar to first generation. Class two includes ciprofloxacin, enrofloxacin and ofloxacin, each of which is characterized by a broader spectrum of microbial targets, including atypical pathogens (e.g., Bacillus anthracis, Yersinia pestis, Vibrio cholerae) and Pseudomonas aeruginosa. Other R group adjustments in the class 2 fluoroquinolones included replacement of the N1 ethyl group with a cyclopropane (figure1), which allowed for ciprofloxacin?s increased bioavailability, allowing more convenient usage of these antimicrobial on systemic infections (Domagala, 1994). However, even as second generation quinolones were synthesized, new patterns of resistance began to emerge. These quinolones were shown to cause cross-resistance with each other as well as the original class of quinolones (Barry and Jones, 1984). In 1984, Sanders et al. showed that Klebsiella pneumoniae mutant isolates selected with naladixic acid, ciprofloxacin, and norfloxacin also expressed resistance to antibiotics in the beta- lactam class (Sanders et. al, 1984). For gram positive isolates, resistance to second generation quinolones was quickly detected in Staphylococcus aureus. This resistance emerged because single nucleotide polymorphism (SNP) mutations increased their MIC to concentrations higher than could be achieved in serum at recommended doses. In S. aureus, resistance emerged more quickly in methicillin resistant (MRSA) strains (Blumberg, et. al 1991). In a study conducted at Atlanta Veteran?s Medical Center, MRSA was observed within 3 months of introducing 5 ciprofloxacin as a treatment. In methicillin susceptible (MSSA) strains resistance was observed within 7 months of introducing ciprofloxacin as a treatment. With the coming of third generation quinolones the antimicrobial properties were extended to Streptococcus. Development of sparfloxacin (Nakamura et. al., 1989), levofloxacin (the l- enantiomer form of ofloxacin) (Tanaka et al, 1992), grepafloxacin (Imada et. al., 1992), Marbofloxacin, and temafloxacin involved modifications such as methyl groups to the piperazine ring at C7. These methyl groups reduced central nervous system adverse reactions in the patient and the potential for drug interactions, while improving activity against gram positive organisms (Domagala, 1994). Once again, not long after levofloxacin was introduced in 1992 as a treatment for Streptococcus pneumoniae, resistance induced by its use was observed (Laferedo et al., 1993). In addition, cross resistance with ciprofloxacin was also observed. The fourth generation quinolones currently are a rising group of fluoroquinolones including the drugs gatifloxacin (Hosaka et. al, 1992), moxifloxacin (Dalhoff et. al., 1996) trovafloxacin, and clinafloxacin. These drugs act dually on DNA gyrase as well as topoisomerase IV slowing emerging resistance. Additionally, trovafloxacin?s substitution of a difluorophenyl group at N8 and clinifloxacin?s addition of a chlorine atom at C8 accounts for their heightened activity against Bacteroides fragilis (Ashina et al. 1992) (Hecht et. al 1996). Mechanisms of Quinolone Resistance E. coli is a common cause of urinary tract infections (UTI). Antibioctic resistant E. coli is increasingly identified in association with both UTI and nosocomial infections in human and veterinary teaching hospitals. An increase in fluroquinolone resistance in particular has been reported and this fluoroquinolone resistance is progressively more associated with MDR (Cohn 6 et. al. 2003) (Boothe et al., 2006) (Shaheen, et. al., 2010). An important risk factor associated with the emergence of fluroquinolone resistance is use of fluroquinolone antimicrobials (Richard et. al. 1994). Resistant E. coli have been documented to emerge during treatment of E. coli infections with quinolones, resulting in therapeutic failure. (Webber et. al. 2004) High levels of naladixic acid resistance has been reported from single step exposure with a frequency of 10-7 while low level resistance to fluroquinolones have been detected from single step exposure with a frequency of 10-9 (Wolfson and Hooper, 1989). Sources of quinolone resistance have been identified such as mutations in the quinolone resistance determining region (QRDR) of gyrAB (Yoshida et. al 1988) (Yamagishi et. al. 1986), (Shaheen et al., 2011) and parCE (Vila et. al. 1996) (Breines et. al. 1997), plasmid mediated factors qnrA, qnrB, qnrS, aac(6')-Ib-cr, and qepA, as well as overexpression of efflux pumps, specifically acrAB/tolC. Conformational Change of Topoisomerases Single nucleotide polymorphisms located within gyrAB and parCE coding for non- synonymous mutations lead to fluroquinolone resistance in both gram-positive and gram- negative isolates. These mutations reside in a region referred to as the quinolone resistance determining region (QRDR). The QRDR is located between nucleotides 199-318 of gyrA or parC (Yoshida et. al. 1990), and 1276-1392 of gyrB or parE (Yoshida et. al. 1991, Soussy et. al 1993). In E. coli, mutations in gyrase can increase resistance to fluoroquinolones by a factor of 100 x (ug/ml) (Cullen et. al., 1989), while mutations in topoisomerase IV can contribute to a increase of a factor of 10 in fluoroquinolone resistance (Khodursky et. al 1995). Among the studies providing evidence of the role of mutations in topoisomerase are those which replace 7 mutations with wild-type sequences. Cullen and co-workers isolated DNA gyrase A from an E. coli strain that was cross resistant to several second generation fluoroquinolones, and then complemented the protein with wild-type gyrase B. The supercoiling function of the topoisomerase of the resultant isolate was characterized by an 100 fold increase in resistance to enoxacin. Genetic analysis of gyrase A revealed that an amino acid substitution of S83W was solely responsible for the increase. Subsequent studies revealed that a S83L substitution was more common due to C ? T transition in the second position (resulting in a leucine substitution) than a C ?G transversion (resulting in a tryptophan substitution). Levofloxacin resistant ParC mutant E. coli became susceptible after transformation of plasmids containing wild-type parC resulting in an MIC change from 50 to 1.56 ug/ml. It was also observed that resistance could be induced by introducing a multicopy plasmid containing mutated parC into a quinolone susceptible E. coli (Kumagai et.al 1996). Further, mutations in GyrA have been demonstrated to affect the supercoiling activity of the protein, not just the protein?s susceptibility to quinolones. Barnard and Maxwell conducted a study in which the hypermutable amino acids in GyrA (codon 83 and 87) were substituted with alanine to make 3 different mutant proteins, GyrA S83A, GyrA N87D, and GyrA S83A, N87D. In the GyrA mutant with only the S83A substitution, while the mutation was only responsible for conferring low levels of quinolone resistance and it had little to no affect on the catalytic activity of DNA gyrase. However, in the N87D mutant and the S83A, N87D double mutant, the mutated region appeared to have a higher affinity to DNA therefore resulting in 2.5 fold less supercoiling activity in the N87D mutant and 5 fold less supercoiling activity in the S83A, N87D double mutant resulting in a situation where protein function is compromised in exchange for resistance. 8 The N87D mutation did account for high level quinolone resistance in both the single mutant and the double mutant. Pfeiffer and Hiasa addressed the sequelae on norfloxacin resistance when the ?4 region of Topoisomerase IV (the region that houses the QRDR for ParC) was replaced with the ?4 region of DNA gyrase using overlap extension PCR. The PCR product was cloned into a plasmid vector and transformed into E. coli HMS174 (DE3). This vector was expressed with wild type parE to create a protein with two mutated ParC subunits and two wildtype ParE subunits. Whereas the substitution of the ?4 region of GyrA into ParC didn?t affect the quinolone sensitivity of the protein, it significantly and negatively affected the catalytic activity of the protein. Interestingly, the norfloxacin/ParC?4GyrA/DNA ternary complex was found to be more stable, and the inhibition more cytotoxic than the norfloxacin/ParC/DNA ternary complex, but less stable and cytotoxic than the norfloxacin/GyrA/DNA ternary complex. This suggests a stabilizing interaction between the amino acids in the catalytic sites of the topoisomerases with quinolone antibiotics. The Role of Efflux Systems in Fluroquinolone Resistance Five major families of efflux pumps exist in E. coli: ATP-Binding Cassette (ABC) superfamily, major facilitator superfamily (MFS), multidrug and toxic compound extrusion (MATE) family, resistance nodulation cell division (RND) family, and small multidrug resistance (SMR) family. The efflux system which most effects quinolone resistance is AcrAB which belongs to the Resistance Nodulation Cell Division (RND) family. The AcrAB efflux system also includes one copy of the outer membrane protein TolC. TolC is a transmembrane protein channel that 9 reaches out through the outer membrane to allow the substrate to cross the periplasmic space as part of a RND or MFS efflux pump (Fralick, 1996). Ma et. al. observed that when acrAB is deleted, the E. coli cell becomes hypersusceptible to bile salts. They also observed that acrAB expression was increased in multidrug resistant E. coli mutants. AcrB is the portion of the pump located in the inner membrane, deriving energy from proton motive force (Ma et al, 1993). This portion of the protein is believed to be the part of the efflux system that captures the molecule, transferring it to TolC for efflux. In contrast, AcrA is a lipoprotein found in the periplasmic space and the inner membrane; it serves to transport non polar molecules (Zgurskaya and Nikaido, 1999) but also appears to stabilize the TolC-AcrAB complex. All three proteins are needed in order for the AcrAB/TolC efflux system to be functional. Figure 2 shows the structure and mechanism for AcrAB/TolC efflux system. 10 Figure 2: Structure for AcrAB/TolC efflux system in E. coli. (Murakami et. al., 2002) Substrates for the AcrAB/TolC efflux system include such compounds as tetracycline, chloramphenicol, fluoroquinolones, ?-lactams, erythromycin, fusidic acid, ethidium bromide, crystal violet, sodium dodecyl sulfate (SDS), and bile acids. marABR is believed to code for regulators of antimicrobial resistance. The marABR operon is located on the chromosome of E. coli; when expressed, it increases resistance seen initially to chloramphenicol and tetracycline. The accepted functions of these three genes are as follows: MarA is thought to be a transcriptional activator of antimicrobial resistance genes by 11 activating sodA (a superoxide dismutase), zwf (a glucose-6-phosphate dehydrogenase) and micF (an antisense RNA regulator of outer membrane porins). The function of MarB is still yet to be determined. MarR is the repressor of the marABR operon. (Cohen et. al. 1993) With MarA sharing a pathway with SoxS, MarA is also found to be associated with upregulation of AcrAB, making it also part of the multi-antimicrobial resistance pathway. (Ma et. al, 1996). Several other genes contribute to efflux pump activity in E. coli. mdfA encodes for the major facilitator superfamily (MFS) of efflux pumps.. MdfA is a multidrug efflux pump. Originally identified as a chloramphenicol resistance pump, it is now known to efflux other antimicrobial substrates such as tetraphenylphosphonium (TPP+), ciprofloxacin, and ethidium bromide. norE was also identified as a multi substrate efflux pump, this time belonging to the multi antimicrobial extrusion (MATE) family. Yang et. al in 2003 compared the roles of AcrAB, MdfA, and NorE in quinolone resistance. Regardless of the efflux pump, expression of each increased resistance (based on magnitude of increase in MIC) only 10 fold. Strains of E. coli studied (n=15) including those with mutations gyrA S83L, parC E84K, gyrA S83L parC E84K, and each of those strains with each combinations of deletions: ?acrB1, ?norE, ?mdfA or overexpression by plasmid of acrB1, norE and mdfA. In cells overexpressing acrB1, resistance increased up to 6.4for ciprofloxacin and 5.3 for norfloxacin; overexpression of acrB1 and norE, resulted in increases of 9.4 and 16.0 fold, for ciprofloxacin and norfloxacin respectively, and overexpression of acrB1 and mdfA, an increase in 11.8 fold and 16 fold, respectively (Shaheen et al., 2010a). The deletion of norE or mdfA alone or in combination had no significant effect compared with the wild type, although deletion of acrA1 decreased the MICCip 8 fold. The combined deletion of acrA1 and mdfA increased MICCip by1.1 fold, for acrA1, and norE as well as 12 combination of all three deleted the increase was 1.05 fold. When coupled with the MIC?s resulting from deletion of the efflux pump genes, the data suggests that overexpression of efflux pumps, and especially combinations of efflux pumps, significantly increases E. coli resistance to fluoroquinolones. Resistance Mechanism Gene MICCipro Change Efflux Pump acrAB 10x mdfA 10x norE 10x Efflux Pump Gene Overexpression acrB1 6.4x acrB1/mdfA 11.8x acrB1/norE 9.4x Efflux Pump Gene Deletion acrB1 .125x mdfA No Change norE No Change acrB1/mdfA 1.1x acrB1/norE 1.1x acrB1/mdfA norE 1.05x Table1: Fold change in MICCipro for E. coli cells expressing acrAB, mdfA and norE, overexpressing acrB1, acrB1/mdfA, acrB1/norE, and with deletions of acrB1, mdfA, norE, acrB1/mdfA, acrB1/norE, acrB1/mdfA/norE (Yang et al, 2003) According to a study in 2000 by Maira-Litr?n et. al, while in biofilm (in which bacterial cells specialize in their function to form large bacterial communities), E. coli resistance to antimicrobials does not appear to be mediated through the upregulation of mar or acrAB operons. Further, mutations in gyrAB and parCE are ineffective at conferring quinolone 13 resistance, with acrAB being severely down-regulated or deleted. (Oethinger et. al, 2000) These findings exemplify the complexity involved in conferring antimicrobial resistance. Emerging Factors: Plasmid Mediated Quinolone Resistance and More Plasmid mediated quiniolone resistance genes termed qnr code for pentapeptide repeat proteins located on integron structures (Tran and Jacoby, 2002). First discovered on multi- resistance plasmid pMG252 in Klebsiella pneumonia, QnrA was determined to have a broad host range found to exist in many gram negative microorganisms as well as some select gram positive microorganisms (Mart?nez-Mart?nez et. al. 1998). Antimicrobial susceptibility testing to an E. coli with a plasmid containing qnrA gene demonstrated an increased MICCip by 4 to 7 fold. Tran et. al. (2005) demonstrated that QnrA is able to cause this increase by binding specifically to DNA gyrase, thus sheltering the target enzyme from fluroquinolones. Although the mode of action may reflect prevention of the ternary complex of DNA gyrase/ DNA/ fluroquinolone from forming, it is not through interference of DNA gyrase/ DNA interaction nor creation of the heterodimer required for DNA gyrase activity. The authors also proposed that QnrA may allow the toxic ternary complex to form, but that the replication fork is preserved by destabilizing the cleavage complex, thus avoiding the lethal double stand break. In a 2005 publication Tran et. al also showed similar patterns for topoisomerase IV and QnrA interaction. . Other Qnr proteins have also been identified; however the homology by amino acid identity is below 60% across all Qnr proteins. In 2005 Hata et. al. isolated QnrS from a clinical strain of Shigella flexneri via pulse field gel electrophoresis, and conjugated the wild plasmid carrying the quinolone resistance gene into competent strain E. coli HB101. Transconjugant E. coli HB101 displayed a MICCip of .25mcg/ml compared to baseline 0.06mcg/ml MICCip. A 14 second experiment in which the wild plasmid was conjugated into quinolone susceptible S. flexneri resulted in an increase in MICCip 4 fold, thus demonstrating that the qnrS gene encoded on this wild plasmid was responsible for conferring the observed quinolone resistance. Sequencing showed that QnrS shared an amino acid identity of 59% with QnrA. The next Qnr protein to be identified was QnrB isolated from K. pneumonia clinical isolates in India exhibiting low level fluoroquinolone resistance. (Jacoby et al, 2004) These isolates, however, were QnrA negative. Cloning studies confirmed QnrB protein as responsible for the low level fluroquinolone resistance. Table 2: Susceptibilities of E. coli transformed with plasmids harboring different qnr genes. (Jacoby et al, 2004) Other variants of qnr include, 6 qnrA, 20 qnrB, 4 qnrS, qnrC in Proteus mirabilis, and qnrD in Salmonella enterica serovar Kentucky with qnrB19 being the most common (Rodr?guez- Mart?nez, J. et. al 2010). qnrB is thought to be the oldest of the qnr genes with the first evidence of qnrB being identified from E. coli isolated in 1988. (Jacoby et. al. 2009) Another plasmid mediated mechanism for quinolone resistance is the cr variant of aac(6?)-Ib an aminoglycoside acetyltransferase found to inactivate ciprofloxacin by acetylating the antibiotic at the amino nitrogen on its piperazinyl ring; this change causes an increase of 15 MICCip to 1.0 ug/ml. This was a groundbreaking finding since fluroquinolones are synthetic drugs and it was thought that there was no natural source of modification to them. Through the course of this finding Robicsek et. al. identified two mutations in aac(6?)-Ib that conferred this cr variant. Mutations in Trp102Arg and Asp179Tyr were revealed to be responsible for the ability to modify ciprofloxacin at the piperazyl ring. This claim was strengthened by performing site directed mutagenesis on aac(6?)-Ib-cr: in the absence of those two mutations the enzyme was no longer linked to ciprofloxacin resistance. (Robicsek et. al., 2007) In a survey of clinical isolates, aac(6?)-Ib-cr was found in 15 of 47 ciprofloxacin resistant E. coli isolates. (Park et. al. 2006) (Shaheen et al, 2010b) In 2007 a third class of plasmid mediated resistance was discovered in QepA, a plasmid mediated quinolone efflux pump first isolated from an E. coli in Japan. An E. coli KAM32 was transformed with pSTV with qepA as well as pSTV with qepA deleted. When subjected to susceptibility testing it revealed that pSTVqepA exhibited a 32 fold increase in MIC to ciprofloxacin when compared to pSTV ?qepA. An increase was also observed across all quinolones: naladixic acid, lomefloxacin, and sparfloxacin 2 fold, levofloxacin and pazufloxacin 4 fold, moxifloxacin and gatafloxacin 8 fold, tosufloxacin 16 fold, enrofloxacin 32 fold, and norfloxacin 64 fold, (Yamane et. al. 2007) The amino acid sequence of QepA was found to be similar to EmrB from the MFS class of efflux pumps and secondary structure and super secondary structure was predicted and is shown in Figure 5. 16 Figure 3: Prediction of the secondary structure for the plasmid mediated quinolone efflux pump QepA. (Yamane et al. 2007) A second efflux pump, OqxAB conferring quinolone resistance is associated with the pOLA52 plasmid, belonging to the RND superfamily of efflux pumps. Originally associated with resistance to olaquindox, it also confers resistance to ethidium bromide (a DNA mutagen) and chloramphenicol. E. coli N43 transformed with a pLOW plasmid with and without oqxAB exhibited no change in the MIC of 3 compounds, but an increase of MIC in 16 out of 19 compounds including Chloramphenicol and Sodium doecyl sulfate (128x), Ciprofloxacin and Flumequine (32x), Norfloxacin, Olaquindox and Trimethoprim (64x),. (Hansen et. al. 2007) An emerging factor contributing to antimicrobial resistance is a state of persistence, a transient physiological state not associated with genetic modification but in which antibiotics are ineffective. Persisters to ciprofloxacin develop randomly, in response to antimicrobial exposure. 17 However, the mechanisms conferring persistence are not yet understood. Dorr et.al (2006) suggested that persistent bacteria do not experience double strand breaks in the presence of fluoroquinolones, eliminating the signals that induce genetic mutation, or subsequent repair functions, or allow a plasmid mediated response typical of such exposure. RecA and RecBCD are proteins expressed during the SOS response, RecA is responsible for binding to single stranded DNA and RecBCD is responsible for facilitating recombination repair. Mutants with recA or recB deleted were used to test this hypothesis; the remaining persisters in ?recA mutants were greatly reduced. In ?recB mutants persisters were eliminated within 6 hours of exposure. This suggests that the recBCD response is needed to repair double strand breaks in persisters and to induce the SOS response. There is also evidence that persisters undergo at least one site specific recombination event in order to repair damage from the double strand break. Therefore, in order for persistence to occur the SOS response must be induced by RecA binding to damaged DNA. Conversely, this does not rule out spontaneous induction of the SOS response in order to create the physiological state necessary for fluoroquinolone persistence. This study revealed that a certain level of SOS response is necessary for persistence to occur since antimicrobials elicit an SOS response from all bacteria. In the natural environment of a specific bacterium, the bacterium is usually faced consistently with stresses and growth is commonly being inhibited. It is now predicted that in the wild it is not uncommon to find persistent bacteria (Dorr et. al 2009). Levels of persistence are seen to differ between stages of the bacteria growth curve, with persistence being low during exponential phase and high in stationary phase. This is because in a state of non growth their drug targets are inactivated. (Dorr et. al 2009). 18 Methods for Detection of Resistance Methods by which fluoroquinolones resistance can be detected are numerous. The oldest is susceptibility testing by either broth dilution (Donovick et al., 1945) Kirby-Bauer antibiotic testing (Kirby et al., 1956), or Episilometer testing (Bolmstrom et al., 1988). Broth dilution is the original modern susceptibility test and remains as the gold standard today. The broth dilution method was first introduced in 1945 by Donovick, R., et al., as a solution to standardize susceptibility testing. Previously, antimicrobial susceptibility was measured in dilution units (Waksman, 1943), from agar dilution and diffusion units (Schatz et. al., 1944), from antimicrobial diffused across agar. These practices lead to publishing of Escherichia coli units, Bacillus subtilis units, Staphylococcus aureus units, etc. all of which were incomparable. The lack of standardization was addressed with broth dilution performed using multiple dilutions of each antimicrobial in nutrient broth and inoculating this broth with standardized numbers of colonies of the organism of interest. The inoculated sample is incubated in optimal growth conditions until log phase growth, dilutions are then inspected for growth inhibition. The greatest dilution (or lowest concentration of drug) in which growth is not observed is considered the organism?s minimum inhibitory concentration (MIC) toward that drug (Donvick, R. et al, 1945). This procedure has since been updated to such that it is performed using microbroth dilution procedures which is the considered the gold standard by the Clinical Laboratory Standards Institute (CLSI, 2008). Kirby-Bauer antibiotic testing, also known as the disk diffusion method, is performed using solid agar inoculated with a known amount of bacterial or fungal suspension. A disk infused with the antimicrobial of choice is placed on the agar creating an antimicrobial gradient. 19 Susceptible organisms will not grow in the presence of the antibiotic creating a zone of inhibition. Large zones of inhibition indicate organisms that have greater susceptibility to the antimicrobial and therefore smaller MICs. The radius of the zone of inhibition is measured and compared to the time elapsed since exposure to the disk and a MIC is estimated (Bauer et. al, 1966). Episilometer testing (E-test) is conducted similarly to the Kirby- Bauer method. However the disk is substituted for a metered strip impregnated with the antimicrobial of choice at the top. The antimicrobial diffuses in to the agar creating a gradient. Susceptibility is measured by comparing the area of inhibited growth to the coordinating meter on the strip indicating the amount of antimicrobial present at that point in the gradient (Bolmstrom, et. al., 1988). Advantages of culture and susceptibility testing is that a clear quantitative susceptibility threshold is acquired; however the disadvantage is for organisms like M. tuberculosis. For such organisms, slow growth complicates susceptibility testing due to risk of contamination and extended time between sample collection and sensitivity result. There is a need for development of more rapid assays. Other novel approaches for detecting quinolone resistance have also been described. These approaches have been molecular approaches aim at creating rapid detection of quinolone resistance. Techniques such as blotting, high performance liquid chromatography, pyrosequencing, mismatch amplification mutation assay, single-strand conformation polymorphism, and quantitative PCR have been utilized to bypass susceptibility testing. In 1996, a technique for detection of ciprofloxacin resistant Mycobacterium tuberculosis was introduced utilizing 16S rRNA precursor. The assay uses slot blots hybridized with 20 nucleotide probes specific for the sequences found in terminal stems of 16S pre-rRNA which is spliced during RNA maturation. They observed that in rifampin and ciprofloxacin resistant strains when exposed to these drugs in broth, 16S pre-rRNA collected in the cell unprocessed to mature rRNA and was detected in large amounts by the nucleotide probe. However, in susceptible strains pre-RNA was not detected after exposure to the antimicrobials (Cangelosi, et. al., 1996). For Campylobacter jejuni, a nonradioisotopic single-strand conformation polymorphism (non-RI SSCP) assay has been described for rapid detection of quinolone resistance. This assay takes advantage of changes in gyrA folding by comparing its mobility in a polyacrylamide gel, and silver staining which produces better resolution bands so that small differences can be detected. (Charvalos, et. al, 1996) A mismatch amplification mutation assay (MAMA) was developed by Zirnstein et al. to detect ciprofloxacin resistance in Campylobacter. MAMA uses a conserved primer coupled with a mutation detection primer for PCR and products are analyzed by gel electrophoresis. Isolates that contain the targeted mutation in gyrA are amplified in the PCR reaction while wild type or non targeted mutations are not (Zirnstein et. al, 1999). In a further search for a rapid and sensitive assay, denaturing high performance liquid chromatography was attempted in Salmonella enterica to detect a DNA sequence variation indicative of quinolone resistance. This technique consists of temperature dependant denaturation of dsDNA followed by ion pair chromatography. In this study 11 profiles were created; however, the profile for the resistant Asp87Gly mutation was indistinguishable from the wild type (Eaves et al, 2002). Quantitative PCR based assays were the next frontier for rapid detection of quinolone resistance. Again, in C. jejuni a technique was developed to detect quinolone resistance by targeting mutations in gyrA. Using Taq-man probe TAQ1 and primers designed specifically to 21 the QRDR of C. jejuni this assay was able to rapidly detect SNPs in C. jejuni gyrA responsible for quinolone resistance (Wilson, et al, 2000), a similar assay was also developed for Salmonella enterica (Esaki et al, 2004) and using a dual probe approach for Mycoplasma bovis (Ben Shabat et al, 2010). Soon FRET-PCR assays detecting SNPs in gyrA were developed for Yersinia pestis (Lindler et. al, 2001), Neisseria gonorrhoeae (Li et al, 2002), Streptococcus pneumoniae (Page et. al, 2008) along with a protocol for Haemophilus influenza for SNP detection in gyrA/parC (Nakamura et al, 2009) and gyrA/gyrB in Clostridium difficile (Spigaglia et al, 2010). Recently a new assay has been developed using qPCR for M. tuberculosis. 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New plasmid-mediated fluoroquinolone efflux pump, QepA, found in an Escherichia coli clinical isolate. Antimicrob Agents Chemother. 51; 3354- 3360. 33 Yang, S., Clayton, S.R., Zechiedrich, E.L., 2003. Relative contributions of the AcrAB, MdfA, and NorE efflux pumps to quinolone resistance in Escherichia coli. J Antimicrob Chemother. 51; 545-556. Yoshida , H., Kojima, T., Yamagishi, J., Nakamura, S., 1988. Quinolone Resistant Mutations of the gyrA Gene of Escherichia coli. Mol. Gen, Genet. 211; 1-7. Yoshida, H., Bogaki, M., Nakamura, M., Nakamura, S., 1990. Quinolone resistance-determining region in the DNA gyrase gyrA gene of Escherichia coli. Antimicrob Agents Chemother. 34; 1271-1272. Yoshida, H., Bogaki, M., Nakamura, M., Yamanaka, L.M., Nakamura, S., 1991. Quinolone resistance-determining region in the DNA gyrase gyrB gene of Escherichia coli. Antimicrob Agents Chemother. 35; 1647?1650 Yoshida, H., Nakamura, M., Bogaki, M., Ito, H., Kojima, T., Hattori, H., and Nakamura, S., 1993. Mechanism of action of quinolones against Escherichia coli DNA gyrase. Antimicrobial Agents and Chemotherapy. 37; 839-845. Zirnstein, G., Li, Y., Swaminathan, B., Angulo, F., 1999. Ciprofloxacin resistance in Campylobacter jejuni isolates: detection of gyrA resistance mutations by mismatch amplification mutation assay PCR and DNA sequence analysis. J Clin Microbiol. 37; 3276-3280 34 CHAPTER 2 DEVELOPMENT AND EVALUATION OF A FRET-PCR ASSAY FOR DETERMINING FLUOROQUINOLONE RESISTANCE IN CANINE URINE ESCHERICHIA COLI ISOLATES Abstract Antimicrobial resistance in Escherichia coli particularly that associated with urinary tract infection (UTI) is increasing in both human and veterinary patients. Fluoroquinolones (FQ) such as enrofloxacin are among the drugs of choice for treatment in canines. E. coli resistance to FQ, including ENR, includes mutations in topoisomerases, but may involve mechanisms associated with multidrug resistance (MDR). Among the difficulties in effective treatment of E. coli UTI is rapid detection of FQ resistance. The purpose of this study was to determine the specificity and sensitivity of a FRET-PCR based assay for the rapid detection of UTI caused by ENR-R E. coli. Three hundred and six clinical canine urine E. coli isolates were subjected to susceptibility testing for 14 drugs representing 6 drug classes, including ENR at a range of MIC (0.03-512 ?g/ml). Isolates were designated (n) NDR (no drug resistance, n=89), SDR (single drug resistance, n=116) and MDR (multi-drug resistant, n=101, including ENR-S [n=51] and ENR-R [n=50]). Extracted DNA was subjected to FRET-PCR targeting single nucleotide polymorphisms in gyrA. Further, to determine the sensitivity of the assay, microbial free canine urine was inoculated with 106 to 101 CFU/ml of 7 E. coli isolates characterized by variable susceptibility to ENR (MICEnro=0.03, 0.06, 0.15, 1, 64, 128, 256 ?g/ml). Of 306 isolates, 43/50 ENR-R (MICEnro >4 ?g/ml), were positively identified by FRET- PCR to be enrofloxacin resistant (a sensitivity of 86%; increasing to 97% for isolates expressing 35 high level resistance (MIC > 8 X breakpoint [64 mcg/ml]), and MDR (n=34). Only 1/50 ENR-R isolate was not detected (specificity = 97%). Colony dilutions of E. coli in sterile urine confirmed the assay able to detect enrofloxacin resistance in as few as 101 CFU/ml. These results confirm that the assay designed provides the specificity and sensitivity to accurately predict antimicrobial resistance in clinical E. coli isolates. Studies now are needed in urine samples from clinical patients. Introduction E. coli is a major cause of urinary tract infections (UTI) in canines (Ling et. al. 1979). Of these infections, antimicrobial resistant E. coli is increasingly identified. An increase in fluroquinolone resistance in particular has been reported; such isolates invariably express multidrug resistance (MDR) (Hirsch et. al. 1973), (Cook et. al 2002), (Cohn et. al. 2003), (Boothe et. al 2006), (Shaheen et al, 2009). An important risk factor associated with the emergence of FQ resistance is use of FQ antimicrobials (Richard et. al. 1994). Resistant E. coli have been documented to emerge during treatment of E. coli infections with quinolones, resulting in therapeutic failure (Webber and Paddock, 2001). Culture and susceptibility testing of E. coli continues to be the gold standard for the detection of antimicrobial resistance. However, this technique is tedious and costly and far from rapid, requiring 2-5 days from time of sample collection until results are reported to the clinician. This window can contribute to therapeutic failure particularly if treatment is initiated with an antimicrobial to which the infecting isolate is resistant (Bubenik et al., 2007). There is a need for an alternative method that allows rapid and sensitive detection of MDR/FQ resistance in urinary isolates for a clinical setting (Siedner et al., 2007). 36 Mutations characterized by single nucleotide polymorphisms (SNPs) in the quinolone resistance determining regions (QRDR) of DNA gyrase (gyrAB) and topoisomerase IV (parCE) are the most common mechanisms causing fluoroquinolone resistance (Oram and Fisher, 1991), (Willmott and Maxwell, 1993), (Everett et. al. 1996), (Villa et. al. 1996), (Piddock, 1999). These SNPs can be easily detected by hybridization probes and quantitative PCR (qPCR). qPCR allows monitoring of PCR amplification with each cycle. This is in contrast to conventional PCR for which only qualitative information is provided and further processing of the amplicon by gel electrophoresis is necessary. Other molecular techniques such as mismatch amplification mutation assay (MAMA) combined with DNA sequencing have been developed for the detection of ciprofloxacin-resistant clinical E. coli isolates in human medicine (Qiang, et. al 2002). However, this method also requires gel electrophoresis. A quantitative PCR (qPCR) system can achieve precise discrimination with utilization of a Fluorescence Resonance Energy Transfer (FRET) assay monitoring the temperature-dependent hybridization of sequence-specific hybridization probes to single stranded DNA while performing melting curve analysis. The melting temperature (Tm) is dependent on the length, GC content, and on the degree of homology between the two DNA strands. Hybridization probes bound perfectly to the matching target DNA require a higher Tm to separate in comparison with those bound to DNA containing destabilizing mismatches. In this study we evaluate the effectiveness of a FRET-PCR based assay for detection of SNPs in E. coli gyrA from pure culture originally isolated from canine urine samples as well as urine inoculated with E. coli and its accuracy in predicting FQ resistance. 37 Materials and Methods Bacterial Isolate Culture Conditions Escherichia coli isolates were harvested from canine urine samples submitted to IDEXX laboratories for suspected urinary tract infections. Isolates had been identified by the laboratory and subjected to susceptibility testing before duplicate cultures were transferred by mail on trypticase soy agar (TSA) slants to the Auburn University Clinical Pharmacology Laboratory. Upon receipt, each E. coli isolate was re-cultured on BBL CHROMagar Orientation (BD Diagnostics) at 37?C overnight to confirm isolate identification as E. coli before transfer to TSA for collection in cryovials. Isolates were stored at -80?C in trypticase soy broth/glycerol cyrovials (mixture Percentage) until testing. Antimicrobial Susceptibility Testing Isolates were subjected to antimicrobial susceptibility testing in order to determine their minimum inhibitory concentrations (MIC).The isolates were cultured directly by transfer to a tryptic soy agar (TSA) plate. The colonies collected from TSA plates were subjected to broth microdilution for susceptibility testing as described by CLSI (CLSI, 2008). Fifteen drugs representing 6 classes of antimicrobials were tested: amoxicillin-clavulanic acid, ampicillin, ticlacillin-clavulanic acid, cefotaxime, cefoxitin, cefpodoxime, ceftazidime, cephalothin, chloramphenicol, doxycycline, enrofloxacin, ciprofloxacin, gentamicin, meropenam and trimethoprim-sulfamethoxazole. Inocula were prepared by suspending growth from overnight cultures in sterile normal saline to a turbidity of approximately 0.5 McFarland standards. Final inocula contained 2 to 7 x 105 CFU/ml. The suspension was used to inoculate custom prepared microtiter trays (TREK Diagnostic Systems, Cleveland, OH). The trays were incubated at 37?C and read at 18 h with a TREK VIZION System (Trek Diagnostic Systems, Cleveland, OH). The 38 minimum inhibitory concentration (MIC) of each antimicrobial was recorded. For quality control purposes E. coli ATCC? 25922 (American Tissue Cell Culture, Manassas, VA) was included in each sample set. Using CLSI standards, each isolate was designated as resistant (R; MIC ? the resistant breakpoint), susceptible (S; MIC ? the susceptible breakpoint) or intermediate (I; MIC between the two breakpoints; this designation is not provided by CLSI for each drug) (CLSI, 2008). In this study, intermediate isolates were recorded and analyzed as ?resistant?. Each isolate was designated as to the presence of no drug resistance to any drug (NDR), single drug resistance (SDR; resistance to one drug class), or multidrug resistance (MDR; resistance to 2 or more of drug classes). All SDR isolates were susceptible to fluoroquinolones (FQ); MDR isolates were further classified as FQ-susceptible (FQ-S), FQ-low level resistant (4 ?g/ml 64 ?g/ml; FQ-HR) (Table 1). Selection of Clinical Isolates and Sample Preparation 306 E. coli isolates (n=101 MDR, 51 MDR-FQ-S, 34 MDR-FQ-HR, and 16 MDR-FQ- LR), 116 SDR and 89 NDR) were revived on TSA plates at 37?C overnight. DNA was extracted using PrepMan ULTRA (Applied Biosystems, Foster City, CA) in preparation for the FRET assay. Experimentally Inoculated Urine Samples Canine urine was collected via cystocentesis, and submitted for culture to verify sterility. Urine determined as negative for bacteria was confirmed microbial-free by transfer of 10?l on to TSA and incubated at 37?C for 48h. After confirmation, 4.5 ml aliquots were made for dilutions. 7 E. coli isolates representing increasing enrofloxacin susceptibilites were suspended in 9% saline to .5 McFarland standard (~109 CFUs) (Table 3). Dilutions were made from 106 to 101 CFUs in microbial free urine. After dilutions were made, the inoculated urine samples were 39 applied to Microcep 100K Centrifugal Microconcentrators (Pall Corporation, Port Washington, NY) and centrifuged for 40m at 3000 rpm. After centrifugation, the filter was washed with 150uL of microbial free urine and the wash collected for DNA extraction. DNA was extracted using the Viral RNA Kit (Omega). Quantitative FRET-PCR The LightCycler 480 Real-time PCR system (Roche) was used for amplification, detection of quantification and melting curve analysis. Primers and probes were designed to be specific for a consensus QRDR wild-type sequence (Shaheen et. al, 2009). Fluorophores were selected with 3? labeled 6-FAM carboxyfluorescein for the donor probe and 5? labeled, 3? phosporylated LightCycler Red 640 for the reporter probe (Figure 1). LightCycler 480 Genotyping Master (Roche Applied Science, Indianapolis, IN) supplemented with 2.0 U Platinum Taq DNA Polymerase (Invitrogen, Carlsbad, CA) was used for the FRET-PCR reactions. The thermocycling program was based on a prior study with modifications for 96 well plates: 18 high stringency step down cycles were succeeded by 25 amplification and fluorescence acquisition cycles with a final melting curve (Shaheen et. al., 2009). The high stringency step down cycling program is as follows: 95?C for 5m; 6 cycles at 95 ?C for 15 s, 72 ?C for 30 s; 9 cycles at 95 ?C for 15 s, 70 ?C for 30 s; 3 cycles at 95 ?C for 15 s, 68 ?C for 30 s, 72 ?C for 30. Amplification was then achieved by 35 cycles of denaturation at 95 ?C 15 s, annealing at 52 ?C for 15 s, 66 ?C for 30 s, and extension at 72 ?C for 30 s. Emittance for the Lightcycler was set at 498nm and absorption at 640nm. Determination of nucleotide sequences was performed by Macrogen USA (Macrogen, Rockville, MD) on the QRDR of gyrA locus of 20 isolates in order to determine the specificity of the assay. 40 Sequencing of Isolates to confirm FRET Results 20 isolates were selected by FRET results to confirm accuracy of the assay. These isolates exhibited low melting temperatures suggesting extreme resistance (Tm<60C), melting temperatures suggesting only one mutation (63C68C) (Table 2). Results FRET-PCR on Clinical Isolates in Pure Culture Of 306 E. coli isolates, 50 were confirmed by susceptibility testing to be positive for enrofloxacin resistance (MICEnro >4 ?g/ml). 43 of these isolates were also positively identified by the FRET-PCR assay yielding a sensitivity of 86.00%. However, of the isolates expressing high level enrofloxacin resistance (MIC > 64 ?g/ml), and MDR phenotype (n=34), the assay yielded a sensitivity of 97.06%. 247 out of 256 isolates expressing an FQ-S MIC were negatively identified yielding a specificity of 96.66% (Figure 4). Three melting curve profiles for the isolates were produced by the assay (Figure 3). Sequences of the 20 selected isolates revealed a set of synonymous mutations present in 17 of the isolates (Arg91, Tyr100, Ser111). A complete deletion of codon 83 was also observed in one of the isolates creating the only false positive reading. FRET-PCR on Dilutions of Experimentally Infected Urine Colony dilutions of E. coli were detectable at as low as 101 CFU/mL (Figure 4). However, due to background, the melting temperatures could be accurately determined only at 41 dilutions ? 103 CFU/mL. No relationship between CFUs and the peak height of ?(d/dt) fluorescence could be discerned. When nucleic acid concentrations were checked with a Nanodrop 2000c spectrophotometer (Thermo Fisher Scientific, Wilmington, DE) it was concluded that there was no discernable relationship between DNA concentration and colony forming units (CFU/ml) (Figure 6). Discussion From the specificity and sensitivity results it is confirmed that the FRET assay is able to detect fluoroquinolone resistance in E. coli. The presence of false negatives may have arisen because there are many other genetic and physiological factors linked with FQ resistance other than mutations located in the QRDR of E. coli gyrA. Transmembrane factors such as overexpression of efflux pump (most notably AcrAB) and porin modification have been attributed to MDR phenotypes. (Everett et al., 1996), (Giraud et al., 2001), (Mazzariol et al., 2000), (Piddock, 1999). Mutations in soxS and additional mutations in the QRDRs of gyrB, parCE have been identified; these along with presence of plasmids containing qnr (quinolone resistance gene) have also been linked to FQ related MDR phenotypes. Since so many other factors are involved in the conformation of FQ resistance it is impossible for an assay targeting gyrA to give a completely accurate correlation of mutations to MIC. However, for high level enrofloxacin resistance that is only reported to appear with the occurrence of nonsynonymous mutations in the gyrA gene, the FRET-PCR assay is able to specifically discern such isolates in pure culture. The standard deviation (?) for Tm in isolates expressing extremely susceptible MICs (0.03-0.6 ?g/ml, n=225) is 0.991 for this set of isolates while ? for isolates expressing extremely resistant MICs (x ? 128 ?g/ml, n=19) is 0.671. Variation is observed in isolates expressing transition type MICs (0.12 ? x ? 32 ?g/ml, n=38) shown by an ? of 4.575. 42 From sequencing of the amplified regions in isolates exhibiting unexpected FRET results, a set of synonymous mutations (Arg91, Tyr100, Ser111) were present in 17 of the 20 isolates (Table 2). The mutations were always found together with Arg91 (C ?T), Tyr100 (T ?C) located within the QRDR where as Ser111 (T ?C) was located 5 residues outside the QRDR. The possibility of Arg91 and Tyr100 to mutate is a cause of concern since Arg91 is involved with ciprofloxacin binding when Asp87 has been mutated to Tyr or Gly (Black et al, 2008). Tyr100 is a site of interaction with ciprofloxacin and gatafloxacin and should nonsynonomous mutation occur may cause instability in drug binding. Another interesting finding was a deletion of Ser 83 in an isolate that exhibited an MIC of 0.06 ?g/ml, thus supporting the conclusion that Ser 83?s interaction with the fluoroquinolone (e.g, Naladixic acid or Ciprofloxacin) is not what confers suceptability but the overall conformation of the gyrase protein that when changed (i.e. Ser 83 Leu causing hydrophobic interaction) results in high level quinolone resistance . Results of the experimentally infected urine reveal that the FRET assay is sensitive enough to detect E. coli at 101 CFUs. However, if less than 103 CFU?s, background interference may affect interpretation of results. Never the less since most urinary tract infections are diagnosed with greater than 105 CFUs, the FRET assay proves to be sensitive enough to distinguish in pure culture. Further research will have to be preformed to determine the efficacy of the FRET assay for E. coli FQ resistance in mixed culture clinical isolates. 43 Drug Class Antimicrobial Beta-Lactamases (1) Ampicillin (A) Tricarcillin/Clavulanic Acid (R) Amoxicillin/Clavulanic Acid (X) Cephalothin (C) Cefoxitin (O) Cefpodoxime (P) Cefotaxime (T) Ceftazidime (Z) Tetracyclines (2) Doxycycline (D) Chloramphenicol (3) Chloramphenicol (H) Fluoroquinolones (4) Enrofloxacin (E) Ciprofloxacin (F) Aminoglycosides (5) Gentamicin (G) Sulfonamides (6) Trimethoprim/ Sulfamethoxazole (S) Table 1: Notation for the 14 Antimicrobials used and their respective drug classes. 44 Figure 1: Primer and Probe set designed for FRET-PCR. Shown is the alignment of Wild-Type and FQ-R E. coli QRDR regions, boxes outline the placement of described oligonucleotides. The 3? end of the reporter probe is labeled with LightCycler Red 640, while 5? end of the donor probe is labeled with 6-FAM fluorescein. 45 Sample ID MDRx MICEnro (?g/ml) Phenotype Mutations L9254925 MDR124 128 XATOPZCDER S83L, D87N , R91, Y100, S111, I112L, A123V, E139A, V146F B5664710 SDR 0.25 C D87N, R91, Y100, S111 L0255814 NDR 0.03 N/A N/A Figure 3: Melting curves from 3 different gyrA mutation profiles encountered in the clinical isolates. Melting temperature and MIC are negatively correlated. MDR indicates the isolate is Multi-drug resistant while SDR and NDR indicate single drug resistance and no drug resistance respectively. Phenotype describes the antimicrobials of which the isolate expressed resistance. 46 Figure 4: Scatter plot of isolate MICEnro respective to Tm. MIC and Tm are negatively correlated (R=-0.688). 4 (?g/ml) is the resistant break point for enrofloxacin after which a clear distinction is made between melting temperature. 47 Figure 5: Mean and Standard Deviation of Tm for isolates grouped by MICEnro class. Variability is not observed in base susceptibility where no mutations in QRDR exist, or in extreme resistance which can only be conferred by coexistence of S83L and D87N. All variablilty is observed in mid-range MICs which may be conferred through methods of resistance other than QRDR mutations alone. 48 Sample Location Melt temp MDRX PHENOTYPE ENROFL (E) MIC ?g/ml Resistance Forward Sequence comments M1896780 Box 3-13 56 MDR13456 XAFOPZCHEGRS 64 R Ser83Leu C->T Asp87Asn G->A C8994648 Box 4-66 57 MDR12345 AFHDES 16 R Ser83Leu C->T Asp87Asn G->A D8481203 Box 1-78 58 MDR16 CG 0.06 S Ser83 deleted Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C D8632999 Box 2-45 58 MDR12456 ACDEGRS 8 R Ser83Leu C->T Asp87Asn G->A Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C K5919720 Box 1-2 58 MDR12456 XAFCDEGRS 64 R Ser83Leu C->T Asp87Asn G->A Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C L9254925 Box 1 -89 58 MDR124 XATOPZCDER 128 R Ser83Leu C->T Asp87Asn G->A Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C Ile112Leu A->C Ala123Val C->T Glu139Ala A->C Val146Phe G->T M1671888 Box 1-1 58 MDR124 XAFTOPCDER 128 R Ser83Leu C->T Asp87Asn G->A Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C B5664710 Box 1-26 64 SDR C 0.25 S Asp87Asn G->A Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C C6393086 Box 1-22 64 SDR C 0.12 S Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C B5710554 Box 1-27 65 SDR D 0.06 S No Mutations 49 I9323218 Box 3-82 65 NDR N 0.5 S Ser83Leu C->T Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C Ala136Ala C->T I9874054 Box 3-33 65 NDR N 0.03 S Ser83Leu C->T Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C Ala136Ala C->T M1213579 Box 1-36 66 MDR12346 XAOPZCHDEGR 4 R Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C R6559423 Box 1-46 68 MDR13 CH 0.5 S Asp87Gly A->G Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C I0960311 Box 4-23 70 MDR1245 XAFTOPZCDERS 64 R Ser83Leu C->T Asp87Asn G->A Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C I3180001 Box 2-46 70 MDR14 EM 8 R Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C I7862967 Box 3-27 70 MDR134 HEM 64 R Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C Ala136Ala C->T K5693300 Box 2-50 70 MDR14 CE 1 I Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C L2020568 Box 3-7 70 MDR1234 HDEMR 4 R Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C L9245953 Box 2-49 70 SDR E 2 I Arg91Arg C->T Tyr100Tyr T->C Ser111Ser T->C Table 2: Results of Nucleotide Sequences for Determination of Assay Specificity 50 Sample MDRX MICEnro (?g/ml) Phenotype K5262419 NDR 0.006 N J8067928 SDR 0.12 C M1840309 MDR14 1 XAOPZCER I0960311 MDR1245 64 XAFTOPZCDERS M1671888 MDR124 128 XAFTOPCDER N0728888 MDR123456 256 XAFTOPZCHDEGRS ATCC SDR 0.015 C Table 3: 7 Escherichia coli isolates of increasing MICEnro used in inoculating urine. MDRX represents is isolate expresses no drug resistance (NDR), single drug resistance (SDR), or multi- drug resistance (MDR) and to which antimicrobial class resistance is observed. Phenotype represents the individual antimicrobials which the isolate expresses resistance. 51 Figure 6: Melting Curves of Canine Urine Inoculated with Dilutions of E. coli. Colors denote the following inoculation dilutions (CFU/ml): Green 106, Pink 105, Brown 104, Yellow 103, Red 102, Blue 101. Top: Isolate N0728888 MDR1234 MICEnro 256 ?g/ml Phenotype: XAFTOPZCHDEGRS, Bottom: ATCC25922 SDR MICEnro 0.015 ?g/ml Phenotype:C. 52 References Black, M. T., Stachyra,T., Platel, D., Girard, A., Claudon, M., Bruneau J., Miossec, C., 2008. Mechanism of Action of the Antibiotic NXL101, a Novel Nonfluoroquinolone Inhibitor of Bacterial Type II Topoisomerases. Antimicrob Agents Chemother. 52, 3339?3349. Boothe, D.M., Boeckh, A., Simpson, R.B., Dubose, K., 2006.Comparison of pharmacodynamic and pharmacokinetic indices of efficacy for 5 fluoroquinolones toward pathogens of dogs and cats, J. Vet. Intern. Med. 20; 1297?1306. Bubenik, L.J., Hosgood, G.L., Waldron, D.R., Snow, L.A., 2007. Frequency of urinary tract infection in catheterized dogs and comparison of bacterial culture and susceptibility testing results for catheterized and noncatheterized dogs with urinary tract infections, J. Am. Vet. Med. Assoc. 231; 893?902. Clinical and Laboratory Standards Institute, 2008. Performance standards for antimicrobial disk and dilution susceptibility tests for bacterial isolated from animals. Approved standard, 3rd ed. Document M31-A3. CLSI, Wayne, Pa. Cohn, L. A., Gary, A. T., Fales, W. H., Madsen, R. W., 2003. Trends in fluoroquinolone resistance of bacteria isolated from canine urinary tracts. J. Vet. Diagn. Invest. 15, 338- 343. 53 Cooke, C.L., Singer, R.S., Jang, S.S., Hirsh, D.C., 2002. Enrofloxacin resistance in Escherichia coli isolated from dogs with urinary tract infections, J. Am. Vet. Med. Assoc. 15; 190? 192. Everett, M. J., Jin, Y. F., Ricci, V., Piddock, L. J. V., 1996. Contribution of individual mechanisms to fluoroquinolone resistance in 36 Escherichia coli isolates from humans and animals. Antimicrob. Agents Chemother. 40, 2380?2386. Giraud, E., Leroy-S?trin, S., Flaujac, G., Cloeckaert, A., Dho-Moulin, M., Chaslus-Dancla, E., 2001. Characterization of high-level fluoroquinolone resistance in Escherichia coli O78:K80 isolated from turkeys, J. Antimicrob. Chemother. 47; 341?343. Hirsh, D.C., 1973. Multiple antimicrobial resistance in Escherichia coli isolated from the urine of dogs and cats with cystitis, J. Am. Vet. Med. Assoc. 162; 885?887 Ling, G. V., Bibestein, E. L., Hirsh, D. C., 1979. Bacterial pathogens associated with urinary tract infections. Vet. Clin. N. Am. Small Anim. Pract. 9; 617?630. Mazzariol, A., Tokue, Y., Kanegawa, T.M., Cornaglia, G., Nikaido, H., 2000. High-level fluoroquinolone-resistant clinical isolates of Escherichia coli overproduce multidrug efflux protein AcrA. Antimicrob. Agents Chemother. 44; 3441?3443. Oram, M., Fisher, L.M., 1991. 4-Quinolone resistance mutations in the DNA gyrase of Escherichia coli clinical isolates identified by using the polymerase chain reaction, Antimicrob. Agents Chemother. 35; 387?389. Piddock, L. J. V., 1999. Mechanisms of fluoroquinolone resistance: an update 1994?1998, Drugs 58, 11?18. 54 Qiang, Y. Z., Qin, T., Fu, W., Cheng, W. P., Li, Y. S., Yi, G., 2002. Use of a rapid mismatch PCR method to detect gyrA and parC mutations in ciprofloxacin-resistant clinical isolates of Escherichia coli. J. Antimicrob. Chemother. 49, 549?552. Richard, P., Delangle, M. H., Merrien, D., 1994. Fluoroquinolone use and fluoroquinolone resistance: is there an association?. Clin. Infect. Dis. 19, 54?59. Shaheen, B. W., Wang, C., Johnson, C. M., Kaltenboeck, B., Boothe, D. M., 2009. Detection of fluoroquinolone resistance level in clinical canine and feline Escherichia coli pathogens using rapid real-time PCR assay. J. Vet. Micro. 139, 379-385. Siedner, M.J., Pandori, M., Castro, L., Barry, P., Whittington, W.L., Liska, S. Klausner, J.D., 2007. Real-time PCR assay for detection of quinolone-resistant Neisseria gonorrhoeae in urine samples, J. Clin. Microbiol. 45; 1250?1254. Vila, J., Ruiz, J., Go?i, P., Jim?nez de Anta, T., 1996. Detection of mutations in parC in quinolone-resistant clinical isolates of Escherichia coli. Antimicrob. Agents Chemother. 40 , 491?493. Webber, M., Piddock, L. J., 2001.Quinolone resistance in Escherichia coli. Vet. Res. 32, 275? 284. Willmott, C.J.R., Maxwell, A., 1993. A single point mutation in the DNA gyrase A protein greatly reduces binding of fluoroquinolones to the gyrase-DNA complex, Antimicrob. Agents Chemother. 37; 126?127. 55 CHAPTER 3 EVALUATION OF A FRET-PCR ASSAY FOR DETERMINING FLUOROQUINOLONE RESISTANT ESCHERICHIA COLI IN CLINICAL URINE ISOLATES FROM COMPANION ANIMALS Abstract Antimicrobial resistance in Escherichia coli is becoming of increasing concern in public health affecting patients of both human and veterinary hospitals. A commonly selected antimicrobial for treatment in small animals is enrofloxacin, a second generation fluoroquinolone (FQ). Among the difficulties in effective E. coli treatment is rapid detection of fluoroquinolone resistance. The purpose of this study was to determine the specificity and sensitivity of a FRET based assay for the rapid detection of urinary tract infections caused by fluoroquinolone associated multi-drug resistant E.coli. Two hundred and thirty-eight clinical urine samples were collected via cystocentesis or free catch, and screened for presence of aerobic bacteria. Isolates were subjected to susceptibility testing for enrofloxacin and the FRET assay, while DNA was also collected directly from urine samples and subjected to the FRET assay. Of 438 urine samples, 278 were confirmed to contain E. coli 18 of which were confirmed to be resistant to enrofloxacin by susceptibility testing. The FRET assay positively identified 15 of the 18 enrofloxacin resistant E. coli urine samples for sensitivity of 83.33% and negatively identified 406 samples for specificity of 92.36%. 56 Introduction Escherichia coli is a major cause of urinary tract infections (UTI) in canines (Ling et. al. 1979). Of these infections, antimicrobial resistant E. coli is increasingly identified. In particular, an increase in fluoroquinolone resistance has been reported, and it is frequently associated with multidrug resistant phenotypes (Hirsch et. al. 1973), (Cook et. al 2002), (Cohn et. al. 2003), (Boothe et. al 2006). A previous study demonstrated that a FRET-PCR based assay could discriminate between fluroquinolone resistant and susceptible E. coli. (Shaheen et al, 2009). Such an assay might facilitate early treatment decisions in the clinical patients infected with E. coli by minimizing the inappropriate use of an FQ if the E. coli already is resistant or by detecting resistance that emerges in the face of therapy (Richard et. al. 1994),(Webber and Paddock, 2001). While culture and susceptibility testing of E. coli continues to be the gold standard for the detection of antimicrobial resistance, time becomes an issue, requiring 2-5 days to obtain results. There is a need for an alternative method that allows rapid and sensitive detection of MDR/FQ resistance in urinary isolates for a clinical setting (Siedner et al., 2007). Development of rapid diagnostic tools for E. coli have been attempted in DNA microarray (Yu et al, 2007), (Barl et al, 2008), pyrosequencing (Guillard et al, 2010), and mismatch amplification mutation assay; however these techniques can be costly, cumbersome, and require specialty equipment. A FRET-PCR based assay for detection directly from urine sample would decrease the window between the collection and susceptibility result. This type of technique has been developed for many other pathogens with success while maintaining cost effectiveness (Lindler et. al, 2001), (Qiang et al, 2002), (Page et. al, 2008), (Nakamura et al, 2009), and (Spigaglia et al, 2010). 57 In this study we evaluate the ability of a FRET-PCR based assay to discriminate fluroquinolone resistant E. coli in clinical urine samples from companion animal patients. Materials and Methods Collection of Urine Samples and Isolation of Bacteria Urine samples collected from dogs and cats and submitted to Auburn University Small Animal Teaching Hospital (AUSATH) through Clinical Pathology and Clinical Microbiology, and IDEXX Laboratory were studied. Samples had been collected either by cystocentesis or free catch. Upon receipt at Auburn University, samples were stored at 4C. 10uL of urine was transferred to CHROMagar (BD Diagnostics, Franklin Lakes, NJ) and incubated at 37C overnight for isolation, detection, and speciation of bacteria. Individual colonies from each present species were transferred to trypticase soy agar (TSA) in order to grow for cryogenic storageIsolates were preserved in brucella broth/ glycerol cyrovials (70% brucellla broth/30% glycerol); these samples were held in reserve (Table 1). Susceptibility Testing for Enrofloxacin Resistance Urine samples collected through AUSMTH Clinical Microbiology and IDEXX Laboratories were subjected to susceptibility testing appropriate to organism via CLSI guidelines (CLSI, 2008) and results forwarded to Auburn University Veterinary Clinical Pharmacology Laboratory. Isolates obtained through Clinical Pathology were subjected to susceptibility testing for enrofloxacin via E-test Epsilometer testing (bioM?rieux, Marcy l'Etoile, France). 58 Preparation of Urine Samples and Isolates for FRET-PCR Urine samples were concentrated using Microsep 100k Centrifugal Devices (Pall Corporation, Port Washington, NY). Samples were centrifuged at 1900 x g for 40m, precipitate was collected along with 150 uL of urine supernatant for DNA extraction. DNA was extracted with the E.Z.N.A. Viral RNA Kit (Omega Bio-tek,) using the extracting bacterial DNA from urine protocol. DNA was eluted to 50uL and stored at 4C. For the bacterial isolates, one bacterial colony was selected from TSA plates and DNA was extracted using 200 uL of PrepMan ULTRA sample preparation reagent (Applied Biosystems, Foster City, CA). Isolated DNA was then stored at 4C. Gyrase A FRET-PCR primers and probes (Shaheen et al, 2009) and LightCycler 480 Genotyping Master (Roche Applied Science, Indianapolis, IN) supplemented with 2.0 U Platinum Taq DNA Polymerase (Invitrogen, Carlsbad, CA) were used for the FRET-PCR reactions. Determination of FRET-PCR Results A result was considered a true positive if FRET-PCR Tm ? 60?C and if the sample contained an enrofloxacin resistant E. coli as determined by culture and susceptibility testing. A result was designated a true negative if FRET-PCR revealed 60?C < Tm despite the absence of enrofloxacin resistant E. coli. False positive samples yielded FRET-PCR Tm ? 60?C in samples containing no enrofloxacin resistant E. coli whereas false negative results reflected FRET-PCR 60?C < Tm in samples containing resistant E. coli. 59 Results Collection of Urine Samples and Susceptibility Testing From Each Origin Out of 438 urine samples collected, 327 were positive for aerobic bacterial growth. Of these, 31 contained multiple species accounting for a total of 362 isolates. 280 of these isolates were identified as E. coli, 21 of which exhibited intermediate (1 ug/ml ? MICEnro < 4 ug/ml, n=5) or resistant MICEnro (MICEnro ? 4 ug/ml, n=16) For the rest of the isolates, 26 were identified as Enterococcus sp., 22 were identified as Klebsiella sp., 13 were identified as Staphylococcus sp., 12 were identified as Proteus sp., 7 were identified as Streptococcus sp., and 4 were identified as Pseudomonas sp. (Table 1) (Figure 2) (Figure 3). The 64 isolates from Clinical Microbiology were unable to be cultured in the Clinical Pharmacology Laboratory due to hospital regulations on holding samples. Their isolates were unable to be compared to the urine sample results. Anaylsis of Urine Samples by FRET-PCR Of 438 urine samples, 17 were confirmed by culture and susceptibility testing to be positive for enrofloxacin resistant E. coli. 14 of these isolates were also positively (true positives) identified by the FRET-PCR assay yielding a sensitivity of 83.33%. 33 urine samples not containing E. coli FQ-R were detected yielding a specificity of 92.36% (false positives). Out of 298 aerobic bacterial isolates that were cultured from the urine, 8 were confirmed by culture and susceptibility testing to be positive for ENR-R E. coli. All of these isolates were positively identified by the FRET-PCR assay yielding a sensitivity of 100%. 278 isolates not containing E. coli expressing an FQ-R MIC were detected yielding a specificity of 95.86% (Table 2). When sensitivity and specificity is determined for isolates collected from AUSMTH by collection method cystocentesis has lower sensitivity (70.00%) but higher specificity (94.11%) compared to voided (sensitivity = 100%, specificity = 89.52%) (Table 3). 60 Discussion The results of this study confirm our findings from the previous study that the FRET assay is able to detect enrofloxacin resistant E. coli. While we do have discrepancy between specificity and sensitivity among the DNA extraction methods, it has been seen previously that extraction method can influence results (Behringer et al, 2011) (Figure 1). Sources of this discrepancy could be unculturable organisms found in the urine that would be lost when collecting isolates, interfering DNA from canine endothelial cells, or residual reagents from the different extraction methods may be enough to disrupt PCR reaction chemistry. In addition by products from the urine may contaminate the DNA elution or the extraction from urine may be too rigorous causing some damage to the DNA (Figure 4) (Figure5). Nucleic acids from these organisms would be present in the extracted DNA sample from urine and may interfere with probe specificity which is seen in the melting peaks in figure 5 there is noticeable background. Urine samples containing confirmed mixed cultures resulted in 4 false positive profiles (3 of which contained E.coli/Enterococcus) and 1 false negative profile. Urine samples containing Staphylococcus sp. (n= 12) accounted for 5 false positive profiles along with uninfected urine (n= 110) Urine samples containing Streptococcus pseudointermedius (n= 7) accounted for 4 false positive profiles while only 3 samples containing Enterococcus (n= 26) and 1 sample containing each Klebsiella sp. (n= 22) and Proteus sp. (n= 13) gave false positive profiles. For the Klebsiella isolate the MICEnro >32 ug/ml, while for the Proteus isolate the MICEnro = .12ug/ml. After examination of alignments of the reporter probe and laboratory strains of each organism, this is probably due to the greater homology between the front of the reporter probe and regions in Staphylococcus and Streptococcus gyrA thus giving the probe a stronger anchor near the 61 fluorophore allowing it to become excited creating a low Tm melting curve. Adjustments in annealing temperature during themocycling may allow the primers to be more specific and avoid producing template that the probes could bind to causing inaccurate results. 62 Origin Source Species Number of Strains Clinical Pathology Cystocentesis Escherichia coli 17 Enterococcus sp. 8 Klebsiella sp. 4 Proteus sp. 3 Staphylococcus sp. 1 Void Escherichia coli 22 Enterococcus sp. 14 Klebsiella sp. 15 Proteus sp. 4 Streptococcus sp. 5 Staphylococcus sp. 1 Catheter Escherichia coli 4 Enterococcus sp. 1 Klebsiella sp. 3 Clinical Microbiology Cystocentesis Escherichia coli 53 Enterococcus sp. 3 Pseudomonas sp. 2 Staphylococcus sp. 1 Void Escherichia coli 11 Proteus sp. 1 Streptococcus sp. 1 Catheter Escherichia coli 1 Streptococcus sp. 1 IDEXX Escherichia coli 171 Proteus sp. 4 Pseudomonas sp. 2 Staphylococcus sp. 9 Total 362 Table 1: Species, source, and origin of organisms isolated from urine samples 63 Source of DNA Extraction Result of FRET Assay Totals Urine True Positive 15 True Negative 387 False Positive 32 False Negative 3 Sensitivity 82.35% Specificity 92.36% Isolates True Positive 8 True Negative 278 False Positive 12 False Negative 0 Sensitivity 100.00% Specificity 95.86% Table 2: Comparison of sensitivity and specificity of FRET assay by DNA extraction method 64 Collection Method Result of FRET Assay Number of samples expressing result Cystocentesis True Positive 13 True Negative 214 False Positive 15 False Negative 3 Sensitivity 81.25% Specificity 93.44% Voided True Positive 5 True Negative 98 False Positive 14 False Negative 0 Sensitivity 100.00% Specificity 87.50% Catheter True Positive 0 True Negative 13 False Positive 0 False Negative 0 Sensitivity 0.00% Specificity 100.00% Table 3: Sensitivity and Specificity of FRET Assay by Collection Method; IDEXX samples are omitted because collection method was not disclosed. 65 Sample # ID# FRET Result Lab Collection Method Species 1 Phenotype Species 2 Phenotype 111 1091631 + Clin. Path Voided E. coli E 160 1082748 + Clin. Path Voided E. coli E Klebsiella E 249 1092349 - Clin. Path Cystocentesis E. coli XAVOYHDE *GMBRS Proteus 312 1092349 + Clin. Micro Cystocentesis E. coli XAVOYHDE GMBRS Pseudomonas H 319 1061672 - Clin. Micro Cystocentesis E. coli XAYDEGM BRS 323 1092933 + Clin. Micro Cystocentesis E. coli AVYEMBRS E. coli N 325 Bac 2399 + Clin. Micro Voided E. coli XAVOYHDE MBRS 341 1080953 + Clin. Micro Cystocentesis E. coli E 344 1079634 + Clin. Micro Cystocentesis E. coli XAVOYHEG MBR 345 1091476 - Clin. Micro Cystocentesis E. coli XAVOYHDE MBR 346 1061672 + Clin. Micro Cystocentesis E. coli XAVOYD E. coli XAVOYH DEMBRS 347 1082748 + Clin. Micro Cystocentesis E. coli ADEMBRS 1024 S5749049 + Idexx E. coli H*EGMS 1065 A8435917 + Idexx E. coli XVYH*EMB 1090 L1553660 + Idexx E. coli XVYEGM 1094 L1590805 + Idexx E. coli H*EM 1112 L1604320 + Idexx E. coli XVYHEMBS Table 4: FRET results for urine samples containing enrofloxacin resistant E. coli. For 17 resistant isolates, 14 were identified by the FRET assay. Species 1 designates primary infective species; Species 2 designates co infective species. Phenotype describes the antimicrobials to which the isolate expressed resistance. 66 Sample # ID# FRET Result Lab Collection Method Species 1 Phenotype Species 2 Phenotype 10 1090596 + Clin. Micro Cystocentesis E. coli 23 1085460 + Clin. Path Voided Klebsiella KHE*G Streptococcus E 33 1091169 + Clin. Path Voided - 62 1091330 + Clin. Path Voided Enterococcus 66 1069127 + Clin. Path Voided Streptococcus 85 1076465 + Clin. Path Cystocentesis E. coli 88 1082748 + Clin. Path Cystocentesis Enterococcus E* 116 1091653 + Clin. Path Voided - 119 1070105 + Clin. Path Voided - 125 1082748 + Clin. Micro Cystocentesis Enterococcus XAEM 134 1091717 + Clin. Path Voided E. coli Enterococcus E* 136 1073104 + Clin. Path Voided Streptococcus E* 153 1091783 + Clin. Path Voided - 213 1061672 + Clin. Path Cystocentesis E. coli 235 1090519 + Clin. Path Voided Proteus 240 1080953 + Clin. Path Cystocentesis Enterococcus 284 116514 + Clin. Path Cystocentesis Klebsiella E 321 Bac 2395 + Clin. Micro Voided E. coli N Streptococcus N 330 1090008 + Clin. Micro Cystocentesis E. coli AH Enterococcus N 1079 A8407897 + Idexx Staphylococcus N 1080 K2009631 + Idexx E. coli H* 1081 A8481393 + Idexx Staphylococcus N 1083 L1536014 + Idexx Staphylococcus XVYEG*MS 1084 C0551061 + Idexx E. coli N 1085 A8436315 + Idexx Proteus N 1086 A8480046 + Idexx Staphylococcus N 1089 A8312185 + Idexx Staphylococcus N 1096 A8547029 + Idexx E. coli N 1102 A8563514 + Idexx E. coli N 67 1105 L1607528 + Idexx E. coli N 1110 A8559398 + Idexx E. coli N 1111 L1610766 + Idexx E. coli H* 1114 L1602432 + Idexx E. coli N Table 5: Urine samples falsely identified by FRET to have enrofloxacin resistant E. coli. Species 1 designates primary infective species; Species 2 designates co infective species. Phenotype describes the antimicrobials to which the isolate expressed resistance. 68 Figure 1: log2 MICEnro vs. Tm for urine samples containing E. coli and E. coli isolates. A) Urine samples containing E. coli collected by cystocentesis. B) Urine samples containing E. coli collected by void. C) E. coli isolated from urine collected by cystocentesis. D) E. coli isolated from urine collected by void. R2 represents the correlation between MICEnro and Tm. 69 Figure 2: Contents of urine samples by collection method. Urine samples negative for bacteria were most prominent overall and for voided urine. For cystocentesis, E. coli infection was most prominent. 70 Figure 3: Distribution of Urine samples containing multiple organisms by species and collection method. Species1 represents primary infective organism while Species 2 represents secondary infective organism. This was designated by concentration of each organism. 71 Figure 4: Representative Melting curve analysis of DNA from both extraction methods. 1) DNA extracted from urine sample A) 1085460 Klebsiella sp./S. agalactiae, C) 1091182 E. coli, D) 1091330 Enterococcus sp. 2) DNA extracted from isolated colonies A) 1085460-1 Klebsiella sp., B) 1085460-2 S. agalactiae (Isolated from A in urine sample), C) 1091182 E. coli, D) 1091330 Enterococcus sp. The urine sample Tm is shifted left compared to isolate Tm, this may be due to other DNA contaminants found in the urine, such as host DNA. 72 Figure 5: Amplification curves of DNA from both extraction methods. 1) DNA extracted from urine sample A) 1085460 Klebsiella sp./S. agalactiae, C) 1091182 E. coli, D) 1091330 Enterococcus sp. 2) DNA extracted from isolated colonies A) 1085460-1 Klebsiella sp., B) 1085460-2 S. agalactiae, C) 1091182 E. coli, D) 1091330 Enterococcus sp. The urine sample amplification is not smooth; this may be due to different extraction methods. 73 References Barl T, Dobrindt U, Yu X, Katcoff DJ, Sompolinsky D, Bonacorsi S, Hacker J, Bachmann TT., 2008. Genotyping DNA chip for the simultaneous assessment of antibiotic resistance and pathogenic potential of extraintestinal pathogenic Escherichia coli. Int J Antimicrob Agents. 32; 272-277. Behringer, M.G., Miller, W.G., Oyarzabal, O.A., 2011. Typing of Campylobacter jejuni and Campylobacter coli isolated from live broilers and retail broiler meat by flaA-RFLP, MLST, PFGE and REP-PCR. J. Microbiol. Methods. 84; 194-201. Boothe, D.M., Boeckh, A., Simpson, R.B., Dubose, K., 2006. Comparison of pharmacodynamic and pharmacokinetic indices of efficacy for 5 fluoroquinolones toward pathogens of dogs and cats, J. Vet. Intern. Med. 20; 1297?1306. Clinical and Laboratory Standards Institute, 2008. 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Yu, X., Susa, M., Weile, J., Knabbe, C., Schmid, R.D., Bachmann, T.T., 2007. Rapid and sensitive detection of fluoroquinolone-resistant Escherichia coli from urine samples using a genotyping DNA microarray. Int J Med Microbiol. 297; 417-29. 76 APPENDIX A DATA FOR URINES CONTAINING NEGATIVE AND SINGLE CULTURES Sample ID Tm C FRET Result Lab Collection Method Species 1 Phenotype 4 1090460 70 - Clin. Micro Cystocentesis E. coli 5 1080784 70 - Clin. Micro Cystocentesis E. coli 6 1088931 70 - Clin. Micro Cystocentesis E. coli 7 1072801 70 - Clin. Micro Cystocentesis E. coli ABS 8 1085623 70 - Clin. Micro Cystocentesis E. coli 9 1090093 70 - Clin. Micro Cystocentesis E. coli 10 1090596 59 + Clin. Micro Cystocentesis E. coli 14 1090885 70 - Clin. Micro Cystocentesis E. coli N 15 1090777 70 - Clin. Micro Cystocentesis E. coli N 16 1091157 Clin. Path Voided - 17 1091149 69 - Clin. Path Voided - 18 1067405 70 - Clin. Path Voided - 19 1088390 64.5 - Clin. Path Voided - 20 1091151 64.5 - Clin. Path Cystocentesis E. coli N 21 1089306 69.5 - Clin. Path Voided - 22 1091170 69 - Clin. Path Voided - 23 1085460 59 + Clin. Path voided Klebsiella KHE*G 24 1091152 69.2 - Clin. Path Voided - 25 1091174 69.5 - Clin. Path Cystocentesis - 26 1091161 62.6 - Clin. Path Cystocentesis - 27 1091158 x - Clin. Path Cystocentesis Klebsiella HE* 77 28 1082748 69.6 - Clin. Path Cystocentesis Klebsiella E* 29 1091184 68.6 - Clin. Path Voided - 30 1076465 68.5 - Clin. Path Cystocentesis - 31 1066184 69.6 - Clin. Path Cystocentesis - 32 1091182 70.1 - Clin. Path Voided E. coli 33 1091169 60 + Clin. Path Voided - 34 1091152 64.25 - Clin. Path Voided - 35 1091211 70 - Clin. Path Voided - 36 1091210 70.3 - Clin. Path Voided - 37 1090550 69.5 - Clin. Path Cystocentesis - 38 1091258 70.8 - Clin. Path Cystocentesis - 39 1091256 70.1 - Clin. Path Voided - 40 1081036 70.48 - Clin. Path Voided - 41 1091249 70 - Clin. Path Voided - 42 1090899 69.6 - Clin. Path Catheter - 43 1085302 64.7 - Clin. Path Voided - 44 1091263 69.8 - Clin. Path Cystocentesis - 45 1091261 70.2 - Clin. Path Cystocentesis - 46 1091232 70 - Clin. Path Voided E. coli E* 47 1090805 69.5 - Clin. Path Cystocentesis - 48 1091281 69.7 - Clin. Path Voided - 49 1091278 68.7 - Clin. Path Cystocentesis - 50 1091291 69.9 - Clin. Path Catheter - 51 1091293 69.7 - Clin. Path Cystocentesis - 52 1091301 69.8 - Clin. Path Cystocentesis - 53 1091314 69.7 - Clin. Path Cystocentesis - 54 1091324 69.3 - Clin. Path Voided - 55 1091344 69.6 - Clin. Path Cystocentesis - 56 1076465 69.4 - Clin. Path Catheter Klebsiella 57 1091378 69.7 - Clin. Path Voided Klebsiella E* 78 58 1091373 69.1 - Clin. Path Voided - 59 1091391 69.2 - Clin. Path Voided E. coli 60 1091306 69.6 - Clin. Path Cystocentesis - 61 1091387 69.4 - Clin. Path Voided Enterococcus 62 1091330 59.9 + Clin. Path Voided Enterococcus 63 1091375 69.4 - Clin. Path Voided - 64 1091157 69.5 - Clin. Path Catheter - 65 1091401 68.7 - Clin. Path Voided Klebsiella E 66 1069127 59.1 + Clin. Path Voided Streptococcus 67 1091403 68.9 - Clin. Path Voided - 68 1091394 69.2 - Clin. Path Cystocentesis - 69 1091439 68.8 - Clin. Path Voided - 70 1091417 69.5 - Clin. Path Cystocentesis - 71 1091468 69.1 - Clin. Path Cystocentesis - 72 1091411 69.4 - Clin. Path Cystocentesis - 73 1091412 68.5 - Clin. Path Voided E. coli 74 1076465 69.2 - Clin. Path Voided E. coli ADB 75 1091402 69.4 - Clin. Path Voided - 76 126524 69.1 - Clin. Path Voided - 77 1091414 69.5 - Clin. Path Voided - 78 1082592 69.4 - Clin. Path Voided Klebsiella 79 1088390 69.2 - Clin. Path Voided - 80 1091477 69.3 - Clin. Path Cystocentesis E. coli 81 1091475 69.1 - Clin. Path Voided Enterococcus 82 1091478 69.2 - Clin. Path Cystocentesis E. coli 83 1082899 69.3 - Clin. Path Cystocentesis - 84 1091508 68.9 - Clin. Path Cystocentesis - 85 1076465 59.1 + Clin. Path Cystocentesis E. coli 86 1091473 69.3 - Clin. Path Voided E. coli 87 1090121 69 - Clin. Path Cystocentesis E. coli 79 88 1082748 59.3 + Clin. Path Cystocentesis Enterococcus E* 89 1091474 69.4 - Clin. Path Cystocentesis - 90 1091492 68.7 - Clin. Path Cystocentesis E. coli 91 1091521 68.9 - Clin. Path Voided - 92 1091522 68.9 - Clin. Path Cystocentesis - 93 1091523 69.3 - Clin. Path Cystocentesis - 94 1091528 69.1 - Clin. Path Cystocentesis - 95 1091531 69.1 - Clin. Path Voided Enterococcus 96 1091518 69.1 - Clin. Path Voided - 97 118704 68.9 - Clin. Path Cystocentesis - 98 1091524 62.2 - Clin. Path Voided E. coli 99 1091540 69.2 - Clin. Path Voided Enterococcus 100 1091542 68.9 - Clin. Path Cystocentesis - 101 1089908 69.1 - Clin. Path Cystocentesis E. coli N 102 1086044 69.1 - Clin. Path Voided Enterococcus 103 1076341 69.1 - Clin. Path Voided Klebsiella 104 1091559 69 - Clin. Path Cystocentesis Enterococcus 105 1091542 68.4 - Clin. Path Catheter Klebsiella 106 127374 67.6 - Clin. Path Cystocentesis Proteus D 107 1091258 68.7 - Clin. Path Cystocentesis E. coli 108 1091585 68.3 - Clin. Path Cystocentesis - 109 1083914 68.7 - Clin. Path Voided - 110 1088573 68.5 - Clin. Path Voided E. coli 111 1091631 58 + Clin. Path Voided E. coli E 112 1091630 68.5 - Clin. Path Cystocentesis - 113 1091391 68.5 - Clin. Path Voided - 114 1088785 68 - Clin. Path Cystocentesis - 115 1091648 66.7 - Clin. Path Cystocentesis - 116 1091653 58.4 + Clin. Path Voided - 117 1091644 68.6 - Clin. Path Voided - 80 118 1085164 68.4 - Clin. Path Cystocentesis - 119 1070105 57.8 + Clin. Path Voided - 120 1091649 66.6 - Clin. Path Voided Enterococcus 121 1618 66.9 - Clin. Micro Voided E. coli N 122 1059042 69.1 - Clin. Micro Cystocentesis E. coli XADBRS 123 1091559 61.18 - Clin. Micro Cystocentesis E. coli 124 1579 67.45 - Clin. Micro Voided E. coli N 125 1082748 58.65 + Clin. Micro Cystocentesis Enterococcus XAEM 126 1564 70 - Clin. Micro Voided E. coli N 127 1089908 69.31 - Clin. Micro Cystocentesis E. coli N 128 1091151 69.27 - Clin. Micro Cystocentesis E. coli N 129 1090828 69.51 - Clin. Path Voided E. coli 130 1068074 69.86 - Clin. Path Voided - 131 1085481 69.47 - Clin. Path Voided - 132 1088368 69.98 - Clin. Path Voided - 133 1091666 69.48 - Clin. Path Voided - 134 1091717 59.38 + Clin. Path Voided E. coli 135 1069127 69.5 - Clin. Path Voided E. coli 136 1073104 59.47 + Clin. Path Voided Streptococcus E* 137 1081614 69.58 - Clin. Path Cystocentesis - 138 1089682 68.45 - Clin. Path Cystocentesis - 139 1085563 68.67 - Clin. Path Voided - 140 1091739 68.99 - Clin. Path Voided - 141 1091742 69.04 - Clin. Path Cystocentesis - 142 127082 68.86 - Clin. Path Voided - 143 1088527 69.46 - Clin. Path Catheter Klebsiella E* 144 1061738 69.18 - Clin. Path Catheter - 145 1091764 68 - Clin. Path Cystocentesis - 146 1091766 68.56 - Clin. Path Voided - 147 1091767 68.09 - Clin. Path Cystocentesis - 81 148 1091754 x - Clin. Path Voided Enterococcus M 149 1087129 68.67 - Clin. Path Cystocentesis - 150 99480 69.08 - Clin. Path Voided - 151 1091761 62.71 - Clin. Path Cystocentesis - 152 1091796 67.8 - Clin. Path Catheter E. coli 153 1091783 58 + Clin. Path Voided - 154 1091791 66.19 - Clin. Path Voided - 155 122913 67.15 - Clin. Path Voided E. coli 156 1091805 68.77 - Clin. Path Voided - 157 1091823 66.49 - Clin. Path Voided - 158 1070473 67.95 - Clin. Path Voided - 159 1091828 66.29 - Clin. Path Catheter - 160 1082748 67.69 - Clin. Path Voided E. coli E 161 1091852 68.48 - Clin. Path Voided E. coli 167 1091874 x - Clin. Path Voided - 168 1091876 69.8 - Clin. Path Voided E. coli 174 1091426 71.75 - Clin. Path Cystocentesis E. coli 175 1081776 71.5 - Clin. Path Cystocentesis - 176 1091791 72.26 - Clin. Path Cystocentesis - 177 1067612 71.35 - Clin. Path Cystocentesis - 178 1090232 71.85 - Clin. Path Voided - 179 1084679 71.68 - Clin. Path Cystocentesis - 180 1087054 71.35 - Clin. Path Cystocentesis - 181 1091876 71.27 - Clin. Path Cystocentesis E. coli N 182 1091742 70.89 - Clin. Path Cystocentesis - 183 1088573 71.22 - Clin. Path Cystocentesis E. coli N 184 1091968 70.98 - Clin. Path Cystocentesis - 186 1091970 70.81 - Clin. Path Cystocentesis - 187 1091966 x - Clin. Path Cystocentesis - 188 1091972 72.36 - Clin. Micro Cystocentesis - 82 189 1082592 72.48 - Clin. Path Voided - 190 1091940 72.2 - Clin. Path Cystocentesis E. coli 191 1090805 71.71 - Clin. Path Cystocentesis - 192 1091941 71.56 - Clin. Path Voided Enterococcus 193 1091942 71.53 - Clin. Path Voided E. coli 196 1091952 x - Clin. Path Cystocentesis Proteus D 197 1090111 72.02 - Clin. Path Voided - 199 1075569 71.87 - Clin. Path Cystocentesis - 200 1088194 71.58 - Clin. Path Cystocentesis - 201 1779 72.08 - Clin. Micro Cystocentesis E. coli AB 202 1715 71.95 - Clin. Micro Voided E. coli N 203 1716 x - Clin. Micro Voided E. coli N 204 1085353 x - Clin. Micro Cystocentesis E. coli N 205 1091258 x - Clin. Path Cystocentesis - 206 1091850 72.35 - Clin. Path Voided E. coli 207 1091395 72.05 - Clin. Path Cystocentesis E. coli 208 1091991 69.22 - Clin. Path Voided - 209 1865 72.6 - Clin. Micro - 210 1088573 68.94 - Clin. Micro Cystocentesis E. coli N 211 1091876 69.75 - Clin. Micro Cystocentesis E. coli N 212 1091868 69.44 - Clin. Micro Cystocentesis E. coli N 213 1061672 58.61 + Clin. Path Cystocentesis E. coli XAVYDEGMBRS 214 1092223 69.37 - Clin. Path Catheter E. coli 215 113914 69.64 - Clin. Path Voided Klebsiella 221 1085353 69.7 - Clin. Path Voided E. coli 227 1092227 69.53 - Clin. Path Voided Enterococcus 235 1090519 57.83 + Clin. Path Voided Proteus 240 1080953 59.19 + Clin. Path Cystocentesis Enterococcus 241 1092328 70.3 - Clin. Path Cystocentesis E. coli N 249 1092349 69.25 - Clin. Path Cystocentesis E. coli XAVOYHDE*GMBRS 83 253 1092356 69.42 - Clin. Path Voided E. coli 256 1092263 68.91 - Clin. Path Cystocentesis E. coli XAVOYDGBRS 267 1092677 69.23 - Clin. Path Voided Klebsiella 271 1092762 69.76 - Clin. Path Voided E. coli 272 1092764 69.56 - Clin. Path Catheter E. coli 274 1092700 x - Clin. Path Voided Streptococcus 275 1092755 x - Clin. Path Cystocentesis Enterococcus E* 280 1092797 69.12 - Clin. Path Voided E. coli 284 116514 58.72 + Clin. Path Cystocentesis Klebsiella E 285 1092361 68.1 - Clin. Path Voided Streptococcus 290 1092764 70.13 - Clin. Path Catheter E. coli 291 1092753 68.95 - Clin. Path Voided Klebsiella 296 1090008 69.41 - Clin. Path Voided Klebsiella 312 1092349 58.64 + Clin. Micro Cystocentesis E. coli XAVOYHDEGMBRS 313 1092328 69.42 - Clin. Micro Cystocentesis E. coli N 314 1092223 69.51 - Clin. Micro Catheter E. coli XAVOYDBRS 315 1088549 69.54 - Clin. Micro Cystocentesis E. coli XAVOYDBR 316 1092542 69.3 - Clin. Micro Cystocentesis E. coli N 317 1092263 69.19 - Clin. Micro Cystocentesis E. coli XAVOYDGBRS 318 1092192 69.28 - Clin. Micro Cystocentesis E. coli D 319 1061672 69.15 - Clin. Micro Cystocentesis E. coli XAYDEGMBRS 320 Bac 2240 69.08 - Clin. Micro Voided E. coli N 321 Bac 2395 58.68 + Clin. Micro Voided E. coli N 322 Bac 2235 69.26 - Clin. Micro Voided E. coli AB 323 1092933 58.89 + Clin. Micro Cystocentesis E. coli AVYEMBRS 324 1092552 69.26 - Clin. Micro Cystocentesis E. coli N 325 Bac 2399 58.85 + Clin. Micro Voided E. coli XAVOYHDEMBRS 326 1092893 67.72 - Clin. Micro Cystocentesis E. coli N 327 1080924 69.63 - Clin. Micro Cystocentesis E. coli N 328 107958 68.85 - Clin. Micro Cystocentesis E. coli N 84 329 89045 69.23 - Clin. Micro Cystocentesis E. coli N 330 1090008 58.93 + Clin. Micro Cystocentesis E. coli AH 331 1071579 68.99 - Clin. Micro Cystocentesis E. coli N 332 Bac 2175 69.05 - Clin. Micro Voided E. coli A 333 1092930 69.07 - Clin. Micro Voided E. coli N 334 1093128 68.95 - Clin. Micro Cystocentesis E. coli AB 335 1093627 68.92 - Clin. Micro Cystocentesis E. coli A 336 1093584 68.92 - Clin. Micro Cystocentesis E. coli XAHDEMBRS 337 1093357 69.46 - Clin. Micro Cystocentesis E. coli A 338 1092952 69.95 - Clin. Micro Cystocentesis E. coli 339 1093217 69.47 - Clin. Micro Cystocentesis E. coli N 340 1093368 69.62 - Clin. Micro Cystocentesis E. coli A 341 1080953 58.93 + Clin. Micro Cystocentesis E. coli 342 1061672 69.36 - Clin. Micro Cystocentesis E. coli 343 1093457 69.32 - Clin. Micro Cystocentesis E. coli N 344 1079634 59.06 + Clin. Micro Cystocentesis E. coli XAVOYHEGMBR 345 1091476 69.26 - Clin. Micro Cystocentesis E. coli XAVOYHDEMBR 346 1061672 59.02 + Clin. Micro Cystocentesis E. coli XAVOYD 347 1082748 59.06 + Clin. Micro Cystocentesis E. coli ADEMBRS 348 1093680 69.25 - Clin. Micro Cystocentesis E. coli A 349 1093196 69.35 - Clin. Micro Cystocentesis E. coli A 1001 L1511445 63.95 - Idexx Proteus N 1002 D1213201- 1 69.04 - Idexx E. coli N 1004 L1514671 68.94 - Idexx E. coli N 1005 L1519471 69.11 - Idexx E. coli XHS 1006 L1513280 68.97 - Idexx E. coli N 1007 A8204277 64.1 - Idexx Staphylococcus N 1008 L1510448 68.86 - Idexx E. coli H* 1009 L1510822 69.37 - Idexx Staphylococcus N 1010 C0525802 64.25 - Idexx Staphylococcus N 1011 L1513163 64.36 - Idexx Proteus H* 1014 A8469156 69.18 - Idexx E. coli N 1015 A8465237 64.27 - Idexx E. coli XVH* 85 1016 A8451563 69.16 - Idexx E. coli XH* 1017 F1887207 69.14 - Idexx E. coli N 1018 L1553187 64.43 - Idexx E. coli H*E* 1019 A8448441 69.2 - Idexx E. coli H* 1020 A8448942 69.17 - Idexx E. coli H* 1021 L1533818 69.17 - Idexx E. coli H*S 1022 L1514975 69.25 - Idexx E. coli H* 1023 A8451222 69.31 - Idexx E. coli H* 1024 S5749049 58.95 + Idexx E. coli H*EGMS 1025 A8468319 69.67 - Idexx E. coli N 1026 F1888287 69.28 - Idexx E. coli XH* 1027 A8455320 69.37 - Idexx E. coli H* 1028 A8451803 69.16 - Idexx E. coli X*H* 1029 S5749076 69.19 - Idexx E. coli H* 1030 C0532173 69.16 - Idexx E. coli H* 1031 A8484466 69.14 - Idexx E. coli XVYH* 1032 K2007047 69.21 - Idexx E. coli N 1033 A8464230 69.19 - Idexx E. coli XV*H* 1034 L1533827 69.08 - Idexx E. coli H* 1036 D0242530 69.17 - Idexx E. coli H* 1038 L1519612 64.42 - Idexx E. coli H* 1039 S5747966 69.11 - Idexx E. coli H* 1040 F1836351 64.09 - Idexx E. coli H*E* 1041 A8440514 64.18 - Idexx E. coli H* 1042 F1872330 68.65 - Idexx E. coli N 1043 L1548900 64.11 - Idexx E. coli N 1044 L1544061 68.73 - Idexx E. coli H* 1045 A8450341 68.77 - Idexx E. coli H* 1046 A8469728 68.85 - Idexx E. coli E* 1047 L1522153 69.03 - Idexx E. coli H* 1048 L1514385 68.9 - Idexx E. coli H* 1050 A8478781 68.99 - Idexx E. coli H* 1051 L1555109 68.95 - Idexx E. coli N 1052 A8474989 69.12 - Idexx E. coli H* 1053 A8491381 69.12 - Idexx E. coli N 1054 A8437466 64.12 - Idexx Proteus N 1055 A8445833 69.23 - Idexx E. coli H* 1056 L1522162 69.2 - Idexx E. coli N 1058 A8461480 69.15 - Idexx E. coli H* 1059 A8484143 69.26 - Idexx E. coli N 1060 C0532281 69.17 - Idexx E. coli H* 86 1061 A8491273 69.28 - Idexx E. coli XVYH* 1062 L1551413 69.19 - Idexx E. coli N 1063 A8483665 69.27 - Idexx E. coli N 1064 A8503759 68.69 - Idexx E. coli N 1065 A8435917 58.47 + Idexx E. coli XVYH*EMB 1066 S5745282 68.81 - Idexx E. coli H* 1067 L1551431 68.57 - Idexx E. coli N 1068 A8468721 63.59 - Idexx Staphylococcus N 1069 L1567048 68.67 - Idexx E. coli N 1070 L1537746 68.65 - Idexx E. coli N 1071 A8480153 68.82 - Idexx E. coli N 1072 A8469791 64.09 - Idexx Pseudomonas HE*G* 1074 A8453666 68.76 - Idexx E. coli H* 1075 A8469782 69.22 - Idexx E. coli H* 1076 A8469488 69.16 - Idexx E. coli XVYH* 1077 A8456720 69.07 - Idexx E. coli N 1078 L1544491 68.94 - Idexx E. coli N 1079 A8407897 58.61 + Idexx Staphylococcus N 1080 K2009631 58.54 + Idexx E. coli H* 1081 A8481393 58.58 + Idexx Staphylococcus N 1082 D0242567 68.85 - Idexx E. coli N 1083 L1536014 58.45 + Idexx Staphylococcus XVYEG*MS 1084 C0551061 58.51 + Idexx E. coli N 1085 A8436315 58.58 + Idexx Proteus N 1086 A8480046 58.5 + Idexx Staphylococcus N 1087 L1551450 67.52 - Idexx E. coli N 1088 L1551422 69.27 - Idexx E. coli N 1089 A8312185 58.83 + Idexx Staphylococcus N 1090 L1553660 58.77 + Idexx E. coli XVYEGM 1091 A8312194 62.45 - Idexx E. coli H* 1092 A8469531 69.24 - Idexx E. coli N 1093 A8551451 67.33 - Idexx E. coli XVY 1094 L1590805 58.13 + Idexx E. coli H*EM 1095 K2016494 69.21 - Idexx E. coli XVY 1096 A8547029 58.67 + Idexx E. coli N 1097 L1598296 69.3 - Idexx E. coli N 1098 A8545651 69.36 - Idexx E. coli N 1099 F1913568 69.11 - Idexx E. coli N 1100 S5758692 69.18 - Idexx E. coli H* 1101 S5756259 67.9 - Idexx E. coli XVY*H* 1102 A8563514 58.35 + Idexx E. coli N 87 1103 A8559683 67.96 - Idexx E. coli N 1104 A8557455 68.8 - Idexx E. coli H* 1105 L1607528 58.35 + Idexx E. coli N 1106 A8561396 68.84 - Idexx E. coli N 1107 F1879911 69.24 - Idexx E. coli N 1108 L1603921 67.57 - Idexx E. coli H* 1109 L1600204 68.97 - Idexx E. coli N 1110 A8559398 58.38 + Idexx E. coli N 1111 L1610766 58.06 + Idexx E. coli H* 1112 L1604320 58.7 + Idexx E. coli XVYHEMBS 1113 L1611585 69.26 - Idexx E. coli N 1114 L1602432 58.74 + Idexx E. coli N 1115 A8514055 69.16 - Idexx E. coli N 1116 A8520132 69.4 - Idexx E. coli N 1117 C0570497 69.27 - Idexx E. coli N 1118 F1897956 69.46 - Idexx E. coli N 1119 A8510717 69.26 - Idexx E. coli H* 1120 A8510735 69.27 - Idexx E. coli N 1121 A8510726 63.94 - Idexx E. coli N 1122 A8519365 69.39 - Idexx E. coli N 1123 S5751038 64.78 - Idexx E. coli XH* 1124 A8510708 64.23 - Idexx E. coli X*H* 1125 L1570277 69.92 - Idexx E. coli N 1126 A8509494 69.16 - Idexx E. coli N 1127 A8516050 69.08 - Idexx E. coli H* 1128 K2012539 69.05 - Idexx E. coli H* 1129 L1582278 69.14 - Idexx E. coli H* 1130 T3604679 68.9 - Idexx E. coli H* 1131 A8510691 68.98 - Idexx E. coli N 1132 K2014570 69.32 - Idexx E. coli N 1133 A8502171 69.26 - Idexx E. coli H* 1134 A8530101 69.3 - Idexx E. coli H* 1135 F1850744 69.08 - Idexx E. coli N 1137 A8528462 69.07 - Idexx E. coli H* 1138 L1592748 69.56 - Idexx E. coli N 1140 A8538290 69.51 - Idexx E. coli N 1141 L1606084 69.38 - Idexx E. coli N 1143 A8518500 69.31 - Idexx E. coli N 1144 L1604473 69.48 - Idexx E. coli XVYH*B 1145 L1579639 69.36 - Idexx E. coli H* 1147 L1578435 69.49 - Idexx E. coli N 88 1148 A8528168 68.53 - Idexx E. coli N 1149 K1071535 69.06 - Idexx E. coli H* 1150 A8469352 68.18 - Idexx E. coli N 1152 C0553146 69.32 - Idexx E. coli N 1153 A8518484 68.99 - Idexx E. coli N 1154 A8518466 68.73 - Idexx E. coli N 1155 D1280606 68.32 - Idexx E. coli H* 1156 D0243420 68.64 - Idexx E. coli N 1157 K2012520 69.25 - Idexx E. coli N 1158 C0566609 69.06 - Idexx E. coli N 1159 L1614184 69.3 - Idexx E. coli N 1160 K1548688 64.43 - Idexx E. coli H* 1161 L1614219 69.8 - Idexx E. coli H* 1162 L1617248 69.44 - Idexx E. coli N 1163 L1716264 69.37 - Idexx E. coli H* 1166 C0572633 69.1 - Idexx E. coli N 1167 A8564269 69.5 - Idexx E. coli XH* 1168 C0559041 68.75 - Idexx E. coli N 1169 D0244169 69.43 - Idexx E. coli N 1170 A8580293 69.44 - Idexx E. coli N 1171 D0244571 69.46 - Idexx E. coli H* 1172 F1970967 69.3 - Idexx E. coli H* 1173 D0243850 68.9 - Idexx E. coli N 1174 D0244024 69.04 - Idexx E. coli N 1175 A8574026 69 - Idexx E. coli N 1176 L1614827 69.49 - Idexx E. coli H* 1177 S5761419 69.38 - Idexx E. coli H* 1178 C0559060 69.36 - Idexx E. coli N 1179 A8582298 x - Idexx E. coli N 1180 D0247115 69.05 - Idexx E. coli N 1181 L1626004 69.12 - Idexx E. coli N 1182 L1617883 68.92 - Idexx E. coli N 1183 D0243887 69 - Idexx E. coli XVY* 1184 C0730831 69.32 - Idexx E. coli N 1186 A8567916 68.86 - Idexx E. coli N 1187 C0731408 69.3 - Idexx E. coli H* 1188 A8567264 69.3 - Idexx E. coli N 1189 L1720131 69.29 - Idexx E. coli H* 1190 A8697812 69.29 - Idexx E. coli N 1191 K1563906 69.34 - Idexx E. coli H* 1192 S5765329 68.96 - Idexx Pseudomonas H 89 1035-1 L1535616 69.55 - Idexx E. coli H* 1037-1 F1847471 69.27 - Idexx E. coli H* 1049-1 F1886999 69.03 - Idexx E. coli H* 1057-1 A8481532 69.08 - Idexx E. coli HS 1073-1 A8469719 69.06 - Idexx E. coli N 1136-1 L1595786 69.09 - Idexx E. coli H* 1139-1 A8526459 69.46 - Idexx E. coli N 1142-1 F1850477 69.78 - Idexx E. coli H* 1146-1 F1878923 69.39 - Idexx E. coli H* 1151-1 L1582779 69.02 - Idexx E. coli XVY (*) denotes antibiotics that intermediate resistance was observed according to CLSI standards. 90 APPENDIX B DATA FOR URINES CONTAINING MULTIPLE CULTURES Sample # ID# Tm C FRET Result Lab Collection Method Species 1 Phenotype Species 2 Phenotype 23 1085460 59 + Clin. Path Voided Klebsiella KHE*G Streptococcus E 46 1091232 70 - Clin. Path Voided E. coli E* Klebsiella E* 59 1091391 69.2 - Clin. Path Voided E. coli Klebsiella E* 73 1091412 68.5 - Clin. Path Voided E. coli Proteus 74 1076465 69.2 - Clin. Path Voided E. coli ADB Klebsiella E* 80 1091477 69.3 - Clin. Path Cystocentesis E. coli Enterococcus 82 1091478 69.2 - Clin. Path Cystocentesis E. coli Enterococcus 90 1091492 68.7 - Clin. Path Cystocentesis E. coli Enterococcus 98 1091524 62.2 - Clin. Path Voided E. coli Klebsiella 101 1089908 69.1 - Clin. Path Cystocentesis E. coli N Enterococcus 105 1091542 68.4 - Clin. Path Catheter Klebsiella Enterococcus 106 127374 67.6 - Clin. Path Cystocentesis Proteus D Klebsiella 110 1088573 68.5 - Clin. Path Voided E. coli Enterococcus 120 1091649 66.6 - Clin. Path Voided Enterococcus Proteus 134 1091717 59.38 + Clin. Path Voided E. coli Enterococcus E* 135 1069127 69.5 - Clin. Path Voided E. coli Klebsiella E* 160 1082748 59.3 + Clin. Path Voided E. coli E Klebsiella E 161 1091852 68.48 - Clin. Path Voided E. coli Staphylococcus 190 1091940 72.2 - Clin. Path Cystocentesis E. coli Staphylococcus E 193 1091942 71.53 - Clin. Path Voided E. coli Enterococcus E* 249 1092349 69.25 - Clin. Path Cystocentesis E. coli XAVOY HDE*GM BRS Proteus 312 1092349 58.64 + Clin. Micro Cystocentesis E. coli XAVOY HDEGM BRS Pseudomonas H 314 1092223 69.51 - Clin. Micro Catheter E. coli XAVOY DBRS Streptococcus KG 320 2240 69.08 - Clin. Micro Voided E. coli N Proteus HD 321 2395 58.68 + Clin. Micro Voided E. coli N Streptococcus N 323 1092933 58.89 + Clin. Micro Cystocentesis E. coli AVYEM BRS E. coli N 324 1092552 69.26 - Clin. Micro Cystocentesis E. coli N E. coli N 327 1080924 69.63 - Clin. Micro Cystocentesis E. coli N Staphylococcus N 330 1090008 58.93 + Clin. Micro Cystocentesis E. coli AH Enterococcus N 91 336 1093584 68.92 - Clin. Micro Cystocentesis E. coli XAHDE MBRS E. coli N 346 1061672 59.02 + Clin. Micro Cystocentesis E. coli XAVOY D E. coli XAVOY HDEMB RS (*) denotes antibiotics that intermediate resistance was observed according to CLSI standards.