Open-access In vitro susceptibility to fosfomycin in clinical and environmental extended-spectrum beta-lactamase producing and/or ciprofloxacin-non-susceptible Escherichia coli isolates

ABSTRACT

Extended-spectrum beta-lactamase producing and ciprofloxacin-non-susceptible Escherichia coli are clinical and environmental issues. We evaluated the susceptibility profile of fosfomycin in non-susceptible E. coli isolated from urine and the environment. We measured the activity of fosfomycin against 319 and 36 E. coli strains from urine and environmental isolates, respectively, collected from rivers. Fosfomycin resistance profiles were investigated using the minimal inhibitory concentration (MIC), according to the Clinical and Laboratory Standards Institute (CLSI) and the European Committee for Antimicrobial Susceptibility Testing (EUCAST) guidelines. Antibiotic susceptibility testing revealed that 5% and 6.6% of urine samples were non-susceptible to fosfomycin according to CLSI and EUCAST guidelines, respectively. The fosfomycin MIC50/90 was 0.5/4 mg/L. Of the 36 E. coli isolates from river water, 11.1% and 13,8% were non-susceptible to fosfomycin according to CLSI and EUCAST, respectively (range ≤0.25 ≥512 mg/L). All the isolates with MIC ≥512 mg/L for fosfomycin showed the fosA3 gene. Fosfomycin resistance was more frequent in the environment than in clinical samples.

KEYWORDS Gram-negative bacilli; Escherichia coli ; Fosfomycin; ESBL; Environment

INTRODUCTION

Urinary tract infections (UTIs) are a prevalent occurrence among both outpatients and individuals suffering from bacterial infections, with a pronounced impact on women1. Uropathogenic Escherichia coli is the main causative agent of uncomplicated (acute cystitis) and complicated (pyelonephritis) conditions2,3. Uncomplicated UTIs account for most antibiotic prescriptions in primary care settings worldwide, and treatment continues to be predominantly empirical4,5. Fluoroquinolones (e.g., ciprofloxacin and norfloxacin) and oral β-lactams (e.g., amoxicillin-clavulanate and cephalexin) have been widely used to treat these infections, contributing to the selection of drug-resistant strains6,7. Considering the increasing resistance to fluoroquinolones and β-lactams that is currently being observed8, the Infectious Diseases Society of America (IDSA) recommends these drugs as second-line therapies9.

Over the past decade, the primary challenge in treating UTIs has been the resistance observed in third- and fourth-generation cephalosporins, often associated with extended-spectrum beta-lactamases (ESBL)10,11. This mechanism of resistance is mediated by plasmids that confer resistance to other antibiotics12. Bacteria harboring resistance genes, particularly ESBLs, have been detected in river water, and their presence during activities such as irrigation and recreational use can potentially lead to colonization or infection in both humans and animals13.

Nitrofurantoin, trimethoprim-sulfamethoxazole, fosfomycin, and pivmecillinam are currently recommended as first-line therapies for treating acute uncomplicated cystitis in women. These options are considered suitable if local resistance rates are below 20%, or if the specific infecting strain is confirmed to be susceptible to these medications9. Hence, obtaining local susceptibility patterns is a crucial step in selecting these antibiotics for accurate empirical therapy.

Fosfomycin, a bactericidal antimicrobial drug discovered in 1969, has emerged as one of the most active drugs for uncomplicated UTIs14. Fosfomycin can be found in high concentrations in the urinary tract, and due to its single-dose oral administration and minimal side effects, it has been increasingly prescribed. This study aimed to assess the susceptibility profile of E. coli isolates to fosfomycin, including those carrying ESBL and non-susceptible to ciprofloxacin, from both urinary samples and the local environment in a city in southern Brazil.

MATERIALS AND METHODS

This study evaluated the susceptibility of fosfomycin in 319 urinary E. coli strains isolated from May to September 2020 from 10 sanitary districts of Curitiba city, Parana State, Brazil, and 36 environmental isolates of E. coli collected from the main rivers of the Curitiba’s watershed (Atuba, Belem, Ribeirao dos Padilha, Barigui, Passauna, and Iguacu) from February to August 2021. Curitiba is a city located in Parana State, Brazil, with an estimated population of 1,963,726 inhabitants in an area of 434,892 km2 and 96.3% of adequate sanitation. The city is divided into 10 sanitary districts, defined as a geographical area that contains the population’s epidemiological and social characteristics and their necessities. Additionally, Curitiba presents a subtropical climate (according to the Köppen-Geiger’s classification scheme), with an annual precipitation of approximately 1,600 mm15.

Clinical and environmental isolates

From May 2020 to September 2020, 1,049 E. coli strains were identified in the microbiology section of the Municipal Laboratory of Curitiba. In total, 319 non-duplicate E. coli from clinical outpatients urine samples were selected based on ciprofloxacin susceptibility and ESBL detection; 303 were non-susceptible to ciprofloxacin (88 ESBL-positive and 215 ESBL-negative), and 16 were ciprofloxacin susceptible (ESBL-positive). E. coli was identified using chromID CPS® Elite (BioMérieux, Marcy l’Etoile, France). Ciprofloxacin susceptibility testing and ESBL detection were performed using a VITEK® 2 AST-N238 card (BioMérieux, Marcy l’Etoile, France).

A total of 36 non-duplicate E. coli isolates from the six main rivers of each watershed of Curitiba (environmental isolates) were selected based on ciprofloxacin susceptibility and ESBL detection (Figure 1 shows the sites of collection, considered as hotspots). First, 100 mL of river water from each site was collected in sterile flasks and placed on ice until processing (on the same day, no more than 2 h after collection). Subsequently, 100 mL of water was filtered through a 0.45 µm filter membrane (Merck Millipore, Darmstadt, Germany) and then added to EC Broth (Merck, San Luis, MI) at 36 °C for 24 h. After that, 100 µL of the resulting broth with observable growth was transferred to 9.9 mL of Mueller Hinton Cation Adjusted broth, supplemented with 1 mg/L of ciprofloxacin (Isofarma, Goiania, Brazil), aiming to select ciprofloxacin-non-susceptible E. coli. Simultaneously, another 100 µL of the initial broth was transferred to 9.9 mL of Mueller Hinton Cation Adjusted broth supplemented with 4 mg/L of ceftriaxone (ABL, Sao Paulo, Brazil) to select E. coli ESBL. Broth supplemented with ciprofloxacin or ceftriaxone were incubated at 36 °C for 24 h. After incubation, 10 µL was streaked on Chromocult® Coliform Agar (Merck Millipore, Darmstadt, Germany) and incubated at 36 °C for 24 h. Purple colonies were selected and subjected to matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF-MS) (bioMerieux, Marcy l’Etoile, France) to confirm the identification of E. coli.

Figure 1
Points of water collection in the main rivers of the six watersheds of Curitiba: 01) Passauna River, 02) Barigui River, 03) Belem River, 04) Atuba River, 05) Ribeirao dos Padilhas River, and 06) Iguacu River.

After this step, the colonies confirmed as E. coli in the previous step were subjected to testing on the Vitek®2 AST-N238 card (bioMerieux, Marcy l’Etoile, France) (Gram-negative susceptibility). Concomitantly, assessment of the ghost zone (conducted by the approximation of amoxicillin + clavulanic acid, ceftriaxone, cefepime, and ceftazidime disks) was conducted to confirm ESBL presence and/or ciprofloxacin resistance (evaluated in parallel by Vitek® 2 AST-N238 card).

Minimal inhibitory concentration (MIC)

Agar dilution (AD) quality control (QC) was performed using ATCC® strains E. coli 25922 (Laborclin, Pinhais, Brazil), Pseudomonas aeruginosa 27853 (Laborclin, Pinhais, Brazil), and Enterococcus faecalis 29212 (Laborclin, Pinhais, Brazil). QC testing was performed in triplicate, and the results for each organism were within the acceptable limits of 99%. The VITEK® 2 AST-N238 QC was performed weekly using ATCC® strains, Klebsiella pneumoniae 700603 for the ESBL test, E. coli 25922, and P. aeruginosa 27853.

The clinical, environmental, and ATCC® strains were initially subcultured on tryptic soy agar (18-24 h, 35 ± 2 °C). Fosfomycin MIC was determined using the AD method according to the Clinical and Laboratory Standards Institute (CLSI) M07-A10 guideline16 in the Laboratory of Emerging Infectious Diseases (LEID), School of Medicine, Pontificia Universidade Catolica do Parana, Curitiba city, Parana State, Brazil. Fosfomycin and D-glucose 6-phosphate were purchased from Sigma-Aldrich (St. Louis, MO, USA). AD tests for non-fastidious bacteria were performed using Mueller–Hinton agar (MHA) (BD Difco, Sparks, MD, USA). Glucose-6-phosphate was added to MHA at a 25 mg/L final concentration.

Briefly, 1 mL of each dilution and 1 mL of glucose-6-phosphate stock solution were added to 48 mL of agar in 45 to 50 °C in a Falcon tube. The tubes were mixed thoroughly and poured into 150 mm × 15 mm Petri plates. The agar solidified at room temperature, and plates were used immediately or stored in sealed plastic bags at 2 °C to 8 °C for up to five days. Two drug-free plates prepared from the base medium, with 1 mL of water and 1 mL of glucose-6-phosphate were used as growth controls, one at the beginning and the other at the end of inoculation. The bacterial suspension (0.5 McFarland standard) was prepared in saline by the direct colony suspension method using the Sensititre nephelometer (Thermo Fisher Scientific, MA), and 100 µL of each bacterium was dispensed in an ELISA plate without diluting the initial suspension. Using a Steers replicator with 1 mm pins, 0.1 µL to 0.2 µL were inoculated and plates incubated at 35 ± 2 °C for 16–20 h. The isolates and ATCC strains were evaluated in triplicate.

Polymerase Chain Reaction for detecting fosA3 gene

Polymerase Chain Reaction (PCR) was employed to detect and evaluate the fosA3 gene—the most reported plasmid-mediated fosfomycin resistance gene among Enterobacterales, linked to the resistance dissemination worldwide. Firstly, an isolated colony was added to a nuclease free 0.2 mL microtube, and to the solution was later added 10 µL of OneTaq 2X (New England Biolabs, Ipswich, MA, USA). Then, 8 µL of nuclease-free water was poured, with 1 µL of forward and 1 µL of reverse primers (sequences: fosA3_FWD-II: GCATGCTGCAGGGATTGAATC and fosA3_REV-II: GCCAATCAAAAAAGACCATCCCC). The following parameters were used in the thermocycler: initial denaturation at 94 °C for 30 s, denaturation at 94 °C for 30 s, annealing at 60 °C for 30 s, extension at 68 °C for 45 s, and final extension at 68 °C for 5 min. Then, 5 to 10 µL of the PCR product (sample) was poured at an agarose gel at 2% with TBE buffer 1X. The run occurred for 40 min at 100 V. For control, an 1Kb Plus marker was used.

MICs for ciprofloxacin and ESBL detection were determined by experienced technicians using the VITEK® 2 system (BioMérieux, Marcy l’Etoile, France) according to the manufacturer’s instructions. Ciprofloxacin MICs were interpreted following the European Committee for Antimicrobial Susceptibility Testing (EUCAST) guidelines as follows: susceptible (S) ≤ 0.25 mg/L; area of technical uncertainty (ATU) = 0.5; and resistant (R) ≥ 1 mg/L5. The VITEK® 2 ESBL test is a confirmation test for clavulanic acid inhibited ESBL and uses cefepime (1 µg/mL), cefotaxime (0.5 µg/mL), and ceftazidime (0.5 µg/mL) with and without clavulanic acid (10 µg/mL, 4 µg/mL, and 4 µg/mL, respectively) to determine a positive or negative result. Fosfomycin MICs were interpreted following CLSI and EUCAST guidelines17,18. The fosfomycin CLSI breakpoints were S ≤64 mg/L, intermediate (I) = 128 mg/L, and R ≥ 256 mg/L. The EUCAST breakpoints were S ≤8 mg/L and R >8 mg/L. The PCR for fosA3 gene was evaluated qualitatively.

Antibiotic prescribing evaluation

Data regarding the distribution of fosfomycin within the 10 sanitary districts were collected from the Municipal Health Department of Curitiba, which is part of the Brazilian Unified Health System (SUS). The data spanned from 2015, when fosfomycin was first introduced into the municipal health system, up to 2019. To assess the connection between fosfomycin-resistant isolates from clinical and environmental sources within the same geographic area, a correlation analysis was conducted. Statistical significance was considered if p-value < 0.05.

RESULTS

Of the 319 E. coli isolates from clinical urine samples from 10 sanitary districts, 16 (5%) and 21 (6.6%) were non-susceptible to fosfomycin according to CLSI and EUCAST guidelines, respectively. The fosfomycin MIC50/90 was 0.5/4 mg/L (range ≤ 0.25 to ≥ 512 mg/L). Only one sanitary district was absent of fosfomycin-non-susceptible E. coli (Bairro Novo) (Figure 2). Among the 303 non-susceptible to ciprofloxacin samples by EUCAST (MIC ≥ 0.5 mg/L), 17 (5.6%) had MIC ≥ 16 mg/L to fosfomycin, and among the 16 ciprofloxacin-sensitive samples, four (25%) had an MIC ≥ 16 mg/L to fosfomycin. Among the 104 ESBL-positive samples, 18 (17.3%) had an MIC ≥ 16 mg/L for fosfomycin, and among the 215 ESBL-negative samples, only three (1.4%) had an MIC ≥16 mg/L for fosfomycin (Table 1).

Figure 2
Detection and distribution of fosfomycin-resistant Escherichia coli according to sanitary districts (red dots) and rivers (yellow dots): 01) Passauna River, 02) Barigui River, 03) Belem River, 04) Atuba River, 05) Ribeirao dos Padilhas River, and 06) Iguacu River.

Table 1
Samples that showed resistance for fosfomycin among all the clinical urine samples. MIC results for ciprofloxacin (according to EUCAST), presence of ESBL and MIC results for fosfomycin (according to CLSI and EUCAST).

Of the 36 E. coli isolates from the six rivers (environmental samples), E. coli non-susceptible to fosfomycin was not detected in only two rivers (Passauna and Ribeirao dos Padilhas). In total, 22 samples were screened as ESBL-positive, 28 as non-susceptible to ciprofloxacin, and 14 as ESBL-positive with ciprofloxacin resistance. Moreover, four and five samples (11.1%) were non-susceptible to fosfomycin by CLSI and EUCAST (range ≤ 0.25 to ≥ 512 mg/L), respectively. Among the five fosfomycin non-sensitive by EUCAST, all samples were ESBL-producers, and three were non-susceptible to ciprofloxacin (≥ 0.5 mg/L) (Table 2).

Table 2
Samples that showed resistance for fosfomycin among all the environmental samples. MIC results for ciprofloxacin (according to EUCAST), presence of ESBL and MIC results for fosfomycin (according to CLSI and EUCAST).

When analyzing the fosA3 gene by PCR, all the isolates with MIC ≥ 512 mg/L for fosfomycin showed detection (Figure 3A and 3B). Isolates with MIC values < 512 mg/L showed no gene amplification.

Figure 3
Isolates with MIC ≥ 512 mg/L for fosfomycin showing detection (A and B). Isolates with MIC values < 512 mg/L showed no gene amplification (C).

DISCUSSION

Escherichia coli serves as a significant reservoir of resistance genes that have the potential to lead to treatment failures in both human and veterinary medicine19. In recent decades, increasing resistance genes in E. coli isolates have been observed, with a substantial portion of these resistance genes being acquired by horizontal gene transfer20. In the enterobacterial gene pool, E. coli acts as a donor and recipient of resistance genes and, thus, can acquire resistance genes from other bacteria, as well as pass on its resistance genes to other bacteria21.

Our study evaluated 319 clinical urine samples of 1,049 E. coli isolates from May 2020 to September 2020 at the Municipal Laboratory of Curitiba. Resistance to ciprofloxacin was higher than that of the ESBL-positive isolates (29% compared to 10%, respectively). The increasing emergence of fluoroquinolone-resistant E. coli has been reported worldwide, probably due to the excessive use of these antibiotics22. Shively et al.23 observed that, in 84% of cases, the prescription of ciprofloxacin for UTIs was inappropriate. In the same city as this study, a previous study from 2012 reported more than 20% fluoroquinolone resistance among E. coli11. In addition, the prevalence of ESBL in E. coli, including TEM, SHV, and CTX-M types, from nosocomial and community-acquired UTIs is also increasing7.

Resistance to fosfomycin was observed in 16 (5%) and 21 (6.6%) clinical urine samples according to the CLSI and EUCAST breakpoints, respectively. These isolates were geographically scattered in nine of 10 sanitary districts, and the resistance profile was higher than that previously reported in the same city24. Interestingly, fosfomycin resistance was higher in the ESBL-producing isolates in our study than in a previous study by Tuon et al.25 in carbapenemase-producing Klebsiella pneumoniae 10 years ago. In France, given the increasing fluoroquinolone resistance, fosfomycin prescription increased by 41%, whereas norfloxacin and ciprofloxacin prescription reduced by 80% and 26%, respectively26. In Curitiba, the data on fosfomycin consumption is not readily available. However, the observed increase in resistance, as indicated by previous publications, could be one plausible hypothesis for this trend. All the isolates with MIC ≥512 mg/L for fosfomycin showed the fosA3 gene. This gene was firstly described in Kluyvera georgiana27. This is the most common gene of fosfomycin resistance in the world, including in poultry28. The data we found are important to report the epidemiology of fosfomycin in Brazil.

The higher level of resistance to fosfomycin in isolates from the environment in comparison to clinical isolates (13.8% vs. 6.5%, respectively) was especially notable. Moreover, these environmental isolates were found in four out of the six main rivers in Curitiba city. The identification of mobile fosfomycin-resistance genes in isolates from various sources, including humans, animals, food, and the environment, has raised significant concerns regarding the potential for the dissemination of such bacteria, particularly E. coli and Salmonella, at the human-animal-environment interface29. To the best of our knowledge, no studies have assessed the presence of fosfomycin in river water or sewage. However, given the findings from a previous study in Curitiba city, which detected fluoroquinolone residues, it is reasonable to consider that a similar occurrence may be possible with fosfomycin30. Nonetheless, the genetic transfer of resistance mechanisms is a more plausible explanation for the development of resistance due to the presence of drugs in water. In our analysis, when we examined the correlation between the percentage of environmental isolates resistant to fosfomycin and the different sanitary districts, we found no significant association between environmental resistance and resistance observed in clinical isolates.

In a multicentric study conducted in Italy, the mean resistance rate against fosfomycin was 9.7% (range 7.1–11.3), higher among ESBL-producing bacteria when compared with non-ESBL-producing strains (10.8% vs. 7.9%, respectively; P < 0.001)31. In a study conducted in Portugal, out of the 19,186 E. coli isolates, 100 were fosfomycin resistant (0.5%), out of which 15 carried a fosA-like gene (15%)32. In Egypt, a study found a high percentage of fosfomycin resistance (37/96; 38.5%), which was reported among uropathogenic E. coli isolates33. In Belgium, fosfomycin and ciprofloxacin displayed higher resistance rates in subjects older than 80 years (18%–24% in females; 25%–35% in males, respectively)34. In Brazil, E. coli showed the highest rate of susceptibility to fosfomycin (98.1%)35.

Furthermore, we emphasize that a prior study conducted in Curitiba revealed that even though sewage effluents undergo treatment, the efficacy of this treatment in eliminating antibiotic-resistant microorganisms and antibiotic residues is limited. Additionally, another study in Curitiba demonstrated elevated antibiotic concentrations in certain rivers, indicating a substantial level of contamination from domestic sewage. This underscores the importance of proper sanitation practices and highlights how contaminated rivers can evolve into a natural reservoir of antibiotic resistance30,36.

Although a greater number of ciprofloxacin-resistant strains were isolated from both clinical and environmental strains (5.6% and 10.7%, respectively), fosfomycin resistance was more associated with the presence of ESBL in both groups (17.3% and 22.7%, respectively). Fosfomycin resistance rates among ESBL-producing Enterobacterales have been reported in previous studies and are increasing globally37. The three major mechanisms of fosfomycin resistance include: 1) reduced antibiotic uptake; 2) modification of the antibiotic target and; 3) inactivation by enzymes that can modify fosfomycin38. The fosA gene, a fosfomycin-modifying gene, was first reported in a plasmid of clinical isolates of Serratia marcescens in 198039. Plasmids carrying fosfomycin-modifying genes commonly harbor additional resistance genes, mainly the ESBL CTX-M gene, and selective pressure by other antimicrobial agents increases the risk of fosfomycin resistance40.

In this study, we focused solely on non-susceptible isolates of E. coli, specifically those that were ESBL-positive and non-susceptible to ciprofloxacin. This selection bias was intentional and does not necessarily reflect the susceptibility profile of fosfomycin in the broader population of E. coli isolates associated with urinary tract infections (UTIs). We highlight that our study did not primarily address molecular analysis of ESBL and ciprofloxacin resistance, although such analysis would be a valuable complement to the research. Moreover, the CTX-M genotype has been the most prevalent ESBL genotype in Curitiba over the past decade, providing insight into the local patterns of ESBL resistance30.

CONCLUSIONS

In this study, we identified E. coli strains with fosfomycin resistance in approximately 5% to 6.5% of clinical urine samples (as per CLSI and EUCAST standards, respectively), as well as in 11.1% to 13.8% of environmental river water samples (according to CLSI and EUCAST, respectively). These resistant strains were found distributed among nine out of the 10 sanitary districts and four out of the six main rivers in Curitiba City. We highlight that further research is needed to explore additional reservoirs and to continuously monitor the occurrence and resistance profiles. Moreover, resistance was higher in environmental isolates than in clinical. This discrepancy is an important issue for future discussions and interventions and contributes to our understanding of the dynamics of antimicrobial resistance.

ACKNOWLEDGMENTS

We would like to thank Ana Carolina Pianovski for elaborating the city maps and Adam Coelho de Aguiar, Luca Matsuda Kim, and Renan Kimura Rosot for collecting the environmental samples.

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  • FUNDING
    This study was supported by APSEN.

Publication Dates

  • Publication in this collection
    05 Feb 2024
  • Date of issue
    2024

History

  • Received
    01 Sept 2023
  • Accepted
    06 Dec 2023
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E-mail: revimtsp@usp.br
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