Abstract
Multidrug resistant (MDR) P. aeruginosa accounts for 35% of all P. aeruginosa isolated from respiratory samples of patients with cystic fibrosis (CF). The usefulness of β-lactam antibiotics for treating CF, such as carbapenems and later generation cephalosporins, is limited by the development of antibacterial resistance. A proven treatment approach is the combination of a β-lactam antibiotic with a β-lactamase inhibitor. New β-lactam/β-lactamase inhibitor combinations are available, but data are lacking regarding the susceptibility of MDR CF-associated P. aeruginosa (CFPA) to these new combination therapies. In this study we determined MIC values for three new combinations; imipenem-relebactam (I-R), ceftazidime-avibactam (CZA), and ceftolozane-tazobactam (C/T) against MDR CFPA (n = 20). The MIC90 of I-R, CZA, and C/T was 64/4, 32/4, and 16/8 (all µg/mL), respectively. The susceptibility of isolates to imipenem was not significantly improved with the addition of relebactam (p = 0.68). However, susceptibility to ceftazidime was significantly improved with the addition of avibactam (p < 0.01), and the susceptibility to C/T was improved compared to piperacillin/tazobactam (p < 0.05) These data provide in vitro evidence that I-R may not be any more effective than imipenem monotherapy against MDR CFPA. The pattern of susceptibility observed for CZA and C/T in the current study was similar to data previously reported for non-CF-associated MDR P. aeruginosa.
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Introduction
Cystic fibrosis (CF) is a genetic disease affecting the osmotic control of airway mucus. The resulting mucus is thick and tenacious, which impairs the mucociliary elevator, obstructs the flow of air, and impedes immune effectors from reaching the airways efficiently1. As a result of these disease features, bacterial infection is common in the CF patient population1. Pseudomonas aeruginosa is responsible for the majority of bacterial lung infections in the adult CF population; in 2019 77.6% of Australian CF patients older than 25 years had P. aeruginosa present in their respiratory tract2. Colonisation and infection with CF-associated P. aeruginosa (CFPA) are significant events in the clinical course of the CF, and are associated with increased morbidity and mortality3.
P. aeruginosa has intrinsic resistance to many antimicrobials and also has a propensity to both develop and acquire antimicrobial resistance (AMR) genes through mutation and horizontal gene transfer, respectively4. One method by which resistance may develop to β-lactam antibiotics in particular is by horizontal gene transfer of genes encoding β-lactamases5. In the twentieth century, a major clinical breakthrough was the discovery of compounds that bind to β-lactamases and inhibit their activity. These compounds (namely tazobactam, sulbactam, and clavulanic acid) decrease the effective rate of hydrolysis of β-lactam antibiotics by some β-lactamases, thereby renewing antimicrobial action against bacteria that relied on those enzymes for resistance6,7.
Unfortunately, the range of β-lactamases that these original three β-lactamase inhibitors can act upon is limited, causing an evolutionary pressure for these enzymes to mutate and become inhibitor resistant7. As with all AMR, there is an artificial selection pressure created leading to the proliferation of inhibitor-resistant β-lactamases7. Generally speaking, tazobactam/sulbactam/clavulanic acid are active against class A and class D serine β-lactamases, but not class B metallo-β-lactamases or class C serine β-lactamases7. Recent innovations have led to the development and licencing of new β-lactamase inhibitors that have activity against all serine β-lactamase (classes A, C, and D)8. The three new non-β-lactam β-lactamase inhibitors currently available are vaborbactam (with meropenem), avibactam (with ceftazidime), and relebactam (with imipenem [IPM] and cilastatin). Also, another recent innovation has led to the synthesis of a new cephalosporin with anti-pseudomonal activity, ceftolozane, which is available in combination with tazobactam.
Prior epidemiological and in vitro studies suggest that ceftazidime/avibactam (CZA) and ceftolozane/tazobactam (C/T) are effective therapies against β-lactam resistant P. aeruginosa (61.8–70.2%, and 72.5–78.7% of isolates susceptible, respectively)9,10. Meropenem/vaborbactam is active against narrower range of MDR P. aeruginosa isolates (59.0%)11. Imipenem/relebactam (I-R) is a more recent therapy and therefore the data are limited, however, some data suggest that the addition of relebactam may not be sufficient to lower the MIC of IPM below a clinically useful level in P. aeruginosa that produce β-lactamases12.
The high prevalence of multidrug resistant (MDR) CFPA is of particular concern and accounts for 35% of all CFPA in the Australian adult CF patient population13. New β-lactam/β-lactamase inhibitor combinations are available, but the in vitro efficacy of these new combinations is not well established against CFPA isolates.
CFPA isolates have a different distribution of genotypes compared to P. aeruginosa isolates not originating from CF14. Due to these genetic differences and the unique physiological conditions present in the CF airway, atypical phenotypes such as mucoid variants and small colony variants have emerged15,16,17. These macroscopic phenotypic changes are evidence of other more subtle changes in the phenome, some of which may include acquisition/expression of β-lactamases. Due to the phenotypic divergence of CFPA from non-CFPA, the efficacy of antimicrobials against this group must be verified. In this study we determined the MIC of I-R, CZA, and C/T against MDR CFPA isolates.
Results
MICs of I-R, CZA, and C/T for CFPA isolates (n = 20) are shown in Table 1. Of particular note are the MIC50 values for CZA and C/T which fall below the Clinical and Laboratory Standards Institute (CLSI) breakpoints that indicate susceptibility to those agents. Twenty percent (n = 3/15) of IPM resistant isolates were I-R susceptible, 68.8% (n = 11/16) of ceftazidime (CAZ) resistant isolates were CZA susceptible, and 68.8% (n = 11/16) of piperacillin/tazobactam (TZP) resistant isolates were C/T susceptible. Complete results for each isolate are shown in Table 2, and full sensitivities at the screening stage are showing in Supplementary Table S1. The addition of relebactam to IPM did not significantly change resistance to IPM alone (p = 0.6831), however the addition of avibactam to CAZ significantly altered resistance (p = 0.0094). The change from TZP to C/T had a significant effect on resistance phenotype (p = 0.0265). Some strains showed some level of phenotypic variance in that they would be sensitive to the single agent, but become phenotypically resistant when the inhibitor was added (e.g.: CFPA 04).
Discussion
In this study we have demonstrated the in vitro antimicrobial efficacy of three new antipseudomonal treatments, I-R, CZA and C/T, against CFPA isolates.
Only a modest proportion of IPM resistant isolates were I-R susceptible. This suggests that relatively few isolates had class A or class C β-lactamase-mediated IPM resistance. This is an expected result, as the majority of IPM resistance is mediated by changes in membrane permeability associated with inactivation of the efflux pump oprD, which is unaffected by β-lactamase inhibitors, including relebactam18. I-R may be useful in infections caused by the subset of CFPA isolates that have IPM resistance mediated by class A or class C β-lactamases only. Relebactam does not have class B metallo-β-lactamase or class D serine β-lactamase activity, and therefore I-R should not be considered when these enzymes are either suspected or confirmed to be a resistance mechanism in the target isolate12.
Our results are discordant with I-R susceptibility data for non-CFPA isolates, which indicate that approximately 80% of MDR isolates are susceptible to I-R19. β-lactamase-mediated resistance is more common in non-CFPA and non-β-lactamase mechanisms such as oprD inactivation are responsible for the some IPM resistance in MDR CFPA20.
The majority of CAZ resistant isolates were CZA susceptible, which is consistent with the literature for MDR non-CFPA isolates9,10. The relatively high proportion of CAZ resistant isolates that were also CZA susceptible suggests that the majority of CAZ resistance is mediated primarily by serine β-lactamases which have interactions with avibactam. Avibactam is known to interact strongly with class A, class C, and some class D β-lactamases21.
Piperacillin is used as a comparator to ceftolozane given that they both share tazobactam as a combination agent, and also have similar uses in the clinic in the context of P. aeruginosa. Predictably, the majority of TZP resistant isolates were C/T susceptible, demonstrating that the newest generation cephalosporin, ceftolozane, has a wider spectrum of activity compared to the ureidopenicillin piperacillin.
The proportions of MDR CFPA isolates in this study that were susceptible to CZA, and C/T are consistent with values reported in the literature for MDR non-CFPA9,10,12. This suggests that for CZA and C/T there is not yet a divergent resistance phenotype in CFPA, and that research to-date involving MDR P. aeruginosa and these agents can be broadly applied to MDR CFPA. Data from both the current and previous studies should be interpreted with some measure of caution as none of the conventionally used antibiotic susceptibility testing methods (disk diffusion assay, agar dilution assay, broth microdilution assay) account for the dynamic in vivo environment. One such consideration is the presence of biofilm. P. aeruginosa is a biofilm-forming organism, and the mature biofilm of P. aeruginosa confers tolerance to antimicrobials by virtue of limiting drug diffusion22. This is an important determinant of AMR and must always be considered in the treatment of P. aeruginosa infections22,23.
Having determined whether an organism is susceptible to an antimicrobial agent, the effective delivery of that antimicrobial must also be considered. Due to the altered whole body systems physiology present in CF patients, antimicrobial pharmacokinetics/pharmacodynamics are affected24. A pertinent example is the enhanced renal (and total) clearance of β-lactam antibiotics in the CF patient population24. Due to this niche pharmacokinetic difference, subinhibitory concentrations may develop quicker during intermittent dosing regimens in the CF patient population. Therapeutic drug monitoring and/or continuous dosing can be used to address this problem24,25.
Whilst this study provides important in vitro data supporting the clinical use of new combinations, it is important that the potential for MDR CFPA to develop resistance to these combinations also be evaluated. The CFPA isolates that were used in this study were naïve to I-R, CZA, and C/T, and there has been no opportunity allowed for our isolates to develop mutations conferring resistance on any meaningful timescale. However, it is clear that there was short-term variations in resistance phenotype. This is exemplified by resistance to a combination therapy, but susceptibility to the monotherapy. This may be an on-going limitation when performing in vitro susceptibility testing on hypermutative bacteria such as CFPA. Additional studies examining the propensity for organisms to develop and propagate resistance to these antimicrobial agents is needed at both the laboratory and population health scale, especially considering resistance mechanisms against each of the β-lactam/β-lactamase inhibitor combinations in this study have been identified and reported in the literature26,27,28.
Our results indicate a high proportion of CFPA isolates that are resistant to IPM are also resistant to I-R, however CAZ resistant isolates may be susceptible to CZA, and TZP resistant isolates may be susceptible to C/T. Where possible, antibiotic susceptibility testing should always be used to identify appropriate antimicrobial agents, and good prescribing practices should continue to reflect this important component of antimicrobial stewardship.
Materials and methods
Experimental isolates
Sputum samples were collected at the Western Australian Adult Cystic Fibrosis Centre between January 2017 and May 2018. All samples were cultured for P. aeruginosa. Collection of sputum samples was approved by the Sir Charles Gairdner Hospital Human Research Ethics Committee (SCGH HREC RGS 0000001815) and in accordance with institutional policies and procedures; informed consent was obtained from all patients. Any P. aeruginosa strains isolated subsequently underwent antimicrobial susceptibility testing via the disk diffusion assay against meropenem, IPM, TZP, cefepime, CAZ, aztreonam, colistin, tobramycin, gentamicin, amikacin, ciprofloxacin, and levofloxacin. The disk diffusion assay was performed and interpreted according the CLSI guidelines29,30. Based on these results, isolates were categorised as non-MDR or MDR using consensus criteria31. The genotype of each isolate was determined using iPLEX20SNP, a validated method using MassARRAY MALDI-TOF MS which is described elsewhere32. All isolates included in this study were obtained from samples provided by unique patients and were obtained on separate clinic visits. For these reasons, isolates with identical iPLEX20SNP profiles were considered unlikely to be clonal. P. aeruginosa ATCC® 27853 was included as a quality control organism and P. aeruginosa PAO1 was included as a comparator.
Determination of MICs
A broth microdilution assay was used to determine the MICs of I-R, CZA, and C/T. The procedure followed is described in the CLSI standard, and the results were interpreted using the CLSI published breakpoints, shown in Table 130,33. MICs were determined visually and verified by measuring the OD600 of each well of the microplate before and after incubation. A ≥ 90% reduction in OD600 compared to the positive growth control was considered to be inhibitory and was the method used to determine MIC values. The spectrophotometric method corresponded well with the results obtained visually.
Antimicrobial agents
CAZ, IPM, relebactam, and avibactam (item numbers HY-B0593, HY-B1369, HY-16752, and H-14879A) were purchased from MedChemExpress. Ceftolozane was not available as a single agent, and therefore the clinical formulation of C/T (ARTG 229608) was used. Since this formulation contained ceftolozane in a fixed concentration of 2:1 with tazobactam (1 g/0.5 g), this represents a variance form the CLSI protocol which uses a tazobactam concentration of 4 µg/mL in all microplate test wells30,34.
Statistical analyses
All MIC values were obtained in biological triplicates for each strain and the modal value was reported as the MIC value in this study. For the purposes of analysis, isolates that had MICs falling in the intermediate breakpoint range were reported as resistant. McNemar’s test was performed to test for statistical significance between the resistance of IPM and I-R, CAZ and CZA, TZP and C/T. P values less than 0.05 were considered significant. McNemar’s tests were performed using the free browser tool QuickCalcs provided by GraphPad Software LLC (https://www.graphpad.com/quickcalcs/).
Data availability
All data generated is contained within the tables published.
References
Edmondson, C. & Davies, J. C. Current and future treatment options for cystic fibrosis lung disease: Latest evidence and clinical implications. Ther. Adv. Chronic Dis. 7, 170–183 (2016).
Ahem, S. et al. The Australian Cystic Fibrosis Data Registry Annual Report, 2019. (2021).
Milczewska, J. et al. Clinical outcomes for cystic fibrosis patients with Pseudomonas aeruginosa cross-infections. Pediatr. Pulmonol. 55, 161–168 (2020).
Pang, Z., Raudonis, R., Glick, B. R., Lin, T.-J. & Cheng, Z. Antibiotic resistance in Pseudomonas aeruginosa: Mechanisms and alternative therapeutic strategies. Biotechnol. Adv. 37, 177–192 (2019).
Pechère, J.-C. & Köhler, T. Patterns and modes of β-lactam resistance in Pseudomonas aeruginosa. Clin. Microbiol. Infect. 5, S15–S18 (1999).
Payne, D. J., Cramp, R., Winstanley, D. J. & Knowles, D. J. Comparative activities of clavulanic acid, sulbactam, and tazobactam against clinically important beta-lactamases. Antimicrob. Agents Chemother. 38, 767–772 (1994).
Drawz, S. M. & Bonomo, R. A. Three decades of beta-lactamase inhibitors. Clin. Microbiol. Rev. 23, 160–201 (2010).
Wong, D. & van Duin, D. Novel beta-lactamase inhibitors: Unlocking their potential in therapy. Drugs 77, 615–628 (2017).
Humphries, R. M., Hindler, J. A., Wong-Beringer, A. & Miller, S. A. Activity of Ceftolozane-Tazobactam and Ceftazidime-Avibactam against Beta-Lactam-Resistant Pseudomonas aeruginosa Isolates. Antimicrob. Agents Chemother. 61, (2017).
Sader, H. S., Flamm, R. K., Carvalhaes, C. G. & Castanheira, M. Antimicrobial Susceptibility of Pseudomonas aeruginosa to Ceftazidime-Avibactam, Ceftolozane-Tazobactam, Piperacillin-Tazobactam, and Meropenem Stratified by U.S. Census Divisions: Results from the 2017 INFORM Program. Antimicrob. Agents Chemother. 62, (2018).
Carvalhaes, C. G., Shortridge, D., Sader, H. S. & Castanheira, M. Activity of Meropenem-Vaborbactam against Bacterial Isolates Causing Pneumonia in Patients in U.S. Hospitals during 2014 to 2018. Antimicrob. Agents Chemother. 64, (2020).
Mushtaq, S., Meunier, D., Vickers, A., Woodford, N. & Livermore, D. M. Activity of imipenem/relebactam against Pseudomonas aeruginosa producing ESBLs and carbapenemases. J. Antimicrob. Chemother. 76, 434–442 (2021).
Smith, D. J. et al. Pseudomonas aeruginosa antibiotic resistance in Australian cystic fibrosis centres. Respirology 21, 329–337 (2016).
Lanotte, P. et al. Genetic features of Pseudomonas aeruginosa isolates from cystic fibrosis patients compared with those of isolates from other origins. J. Med. Microbiol. 53, 73–81 (2004).
Lyczak, J. B., Cannon, C. L. & Pier, G. B. Lung infections associated with cystic fibrosis. Clin. Microbiol. Rev. 15, 194–222 (2002).
Starkey, M. et al. Pseudomonas aeruginosa rugose small-colony variants have adaptations that likely promote persistence in the cystic fibrosis lung. J. Bacteriol. 191, 3492–3503 (2009).
Ryall, B. et al. The mucoid switch in Pseudomonas aeruginosa represses quorum sensing systems and leads to complex changes to stationary phase virulence factor regulation. PLoS ONE 9, e96166 (2014).
Riera, E. et al. Pseudomonas aeruginosa carbapenem resistance mechanisms in Spain: Impact on the activity of imipenem, meropenem and doripenem. J. Antimicrob. Chemother. 66, 2022–2027 (2011).
Lob, S. H. et al. Activity of imipenem/relebactam against MDR Pseudomonas aeruginosa in Europe: SMART 2015–17. J. Antimicrob. Chemother. 74, 2284–2288 (2019).
Sherrard, L. J. et al. Emergence and impact of oprD mutations in Pseudomonas aeruginosa strains in cystic fibrosis. J. Cyst. Fibros. 21, e35–e43 (2022).
Zasowski, E. J., Rybak, J. M. & Rybak, M. J. The β-lactams strike back: Ceftazidime-avibactam. Pharmacother. J. Hum. Pharmacol. Drug Ther. 35, 755–770 (2015).
Ciofu, O. & Tolker-Nielsen, T. Tolerance and Resistance of Pseudomonas aeruginosa Biofilms to Antimicrobial Agents-How P. aeruginosa Can Escape Antibiotics. Front. Microbiol. 10, 913 (2019).
Olivares, E. et al. Clinical Impact of Antibiotics for the Treatment of Pseudomonas aeruginosa Biofilm Infections. Front. Microbiol. 10, 2894 (2020).
Castagnola, E. et al. Pharmacokinetics and pharmacodynamics of antibiotics in cystic fibrosis: a narrative review. Int. J. Antimicrob. Agents 106381 (2021). https://doi.org/10.1016/j.ijantimicag.2021.106381.
Hubert, D. et al. Continuous versus Intermittent Infusions of ceftazidime for treating exacerbation of cystic fibrosis. Antimicrob. Agents Chemother. 53, 3650–3656 (2009).
Fraile-Ribot, P. A. et al. Mechanisms leading to in vivo ceftolozane/tazobactam resistance development during the treatment of infections caused by MDR Pseudomonas aeruginosa. J. Antimicrob. Chemother. 73, 658–663 (2018).
Fröhlich, C. et al. OXA-48-Mediated Ceftazidime-Avibactam Resistance Is Associated with Evolutionary Trade-Offs. mSphere 4, (2019).
Gomis-Font, M. A. et al. In vitro dynamics and mechanisms of resistance development to imipenem and imipenem/relebactam in Pseudomonas aeruginosa. J. Antimicrob. Chemother. 75, 2508–2515 (2020).
CLSI. Performance Standards for Antimicrobial Disk Susceptibility Tests, 11th Edition. CLSI Guideline M02. (Clinical and Laboratory Standards Institute, 2012).
CLSI. Performance Standards for Antimicrobial Susceptibility Testing, 31st Edition. CLSI guideline M100. (Clinical and Laboratory Standards Institute, 2013).
Magiorakos, A.-P. et al. Multidrug-resistant, extensively drug-resistant and pandrug-resistant bacteria: an international expert proposal for interim standard definitions for acquired resistance. Clin. Microbiol. Infect. 18, 268–281 (2012).
Syrmis, M. W. et al. A comparison of two informative SNP-based strategies for typing Pseudomonas aeruginosa isolates from patients with cystic fibrosis. BMC Infect. Dis. 14, 307 (2014).
CLSI. Methods for Dilution Antimicrobial Susceptibility Tests for Bacteria That Grow Aerobically, 11th Edition. CLSI guideline M07. (Clinical and Laboratory Standards Institute, 2018).
Therapeutic Goods Administration. Australian Register of Therpeutic Goods. https://www.tga.gov.au/australian-register-therapeutic-goods (2021).
Acknowledgements
This project was supported by a Conquer Cystic Fibrosis Research Grant from Conquer Cystic Fibrosis.
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Conceptualization: R.H., P.P., K.H. and A.T.; data curation: R.H. and K.H.; formal analysis: R.H. and K.H.; funding acquisition: A.T.; investigation: R.H.; methodology: R.H., P.P. and K.H.; project administration: K.H. and A.T.; resources: R.H., P.P., K.H. and A.T.; supervision: P.P., K.H. and A.T.; validation: R.H.; visualization: R.H.; writing—original draft: R.H.; writing—review and editing: R.H., P.P., K.H. and A.T.
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Haines, R.R., Putsathit, P., Hammer, K.A. et al. Activity of newest generation β-lactam/β-lactamase inhibitor combination therapies against multidrug resistant Pseudomonas aeruginosa. Sci Rep 12, 16814 (2022). https://doi.org/10.1038/s41598-022-21101-x
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DOI: https://doi.org/10.1038/s41598-022-21101-x
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