Abstract
Purpose
To evaluate the different present and future therapeutic β-lactam/β-lactamase inhibitor (BL/BLI) alternatives, namely aztreonam-avibactam, imipenem-relebactam, meropenem-vaborbactam, cefepime-zidebactam, cefepime-taniborbactam, meropenem-nacubactam, and sulbactam-durlobactam against clinical isolates showing reduced susceptibility or resistance to cefiderocol in Enterobacterales, Acinetobacter baumannii, and Pseudomonas aeruginosa.
Methods
MIC values of aztreonam, aztreonam-avibactam, cefepime, cefepime-taniborbactam, cefepime-zidebactam, imipenem, imipenem-relebactam, meropenem, meropenem-vaborbactam, meropenem-nacubactam, sulbactam-durlobactam, and cefiderocol combined with a BLI were determined for 67, 9, and 11 clinical Enterobacterales, P. aeruginosa or A. baumannii isolates, respectively, showing MIC values of cefiderocol being ≥1 mg/L. If unavailable, the respective β-lactam breakpoints according to EUCAST were used for BL/BLI combinations.
Results
For Enterobacterales, the susceptibility rates for aztreonam, cefepime, imipenem, and meropenem were 7.5%, 0%, 10.4%, and 10.4%, respectively, while they were much higher for cefepime-zidebactam (91%), cefiderocol-zidebactam (91%), meropenem-nacubactam (71.6%), cefiderocol-nacubactam (74.6%), and cefiderocol-taniborbactam (76.1%), as expected. For P. aeruginosa isolates, the higher susceptibility rates were observed for imipenem-relebactam, cefiderocol-zidebactam, and meropenem-vaborbactam (56% for all combinations). For A. baumannii isolates, lower susceptibility rates were observed with commercially or under development BL/BLI combos; however, a high susceptibility rate (70%) was found for sulbactam-durlobactam and when cefiderocol was associated to some BLIs.
Conclusions
Zidebactam- and nacubactam-containing combinations showed a significant in vitro activity against multidrug-resistant Enterobacterales clinical isolates with reduced susceptibility to cefiderocol. On the other hand, imipenem-relebactam and meropenem-vaborbactam showed the highest susceptibility rates against P. aeruginosa isolates. Finally, sulbactam-durlobactam and cefiderocol combined with a BLI were the only effective options against A. baumannii tested isolates.
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Introduction
The global spread of Gram-negative bacteria with pan-drug resistance is a worrying concern [1]. In 2017, the World Health Organization (WHO) ranked carbapenem-resistant Enterobacteriaceae (CRE), carbapenem-resistant Pseudomonas aeruginosa, and carbapenem-resistant Acinetobacter baumannii in the critical global priority list of pathogens [2]. This matter of concern has promoted research and development in the area of antibiotic resistance including the development of novel antibiotics. Acquired resistance to carbapenems may be driven either by non-enzymatic mechanisms including loss of or weaker expression of porin-encoding genes, mutations in chromosomally encoded porin genes (such as OprD in P. aeruginosa, or OmpK35 and OmpK36 in Klebsiella pneumoniae), overexpression of genes encoding efflux pumps, or modifications of penicillin-binding proteins affecting the binding affinity of the β-lactams, particularly in A. baumannii [3,4,5,6]. However, the main concern regarding the mechanism of carbapenem resistance is the production of acquired carbapenemases, belonging to either Ambler class A (mainly KPC and GES), class B (i.e., NDM, VIM, IMP), or class D (i.e., OXA-23, OXA-24/40, OXA-48, and OXA-181) β-lactamases, particularly found in Enterobacterales or A. baumannii. Considering that those different resistance mechanisms are often combined, very few therapeutical options may sometimes be left, especially when dealing with infections caused by producers of metallo-β-lactamases (class B).
The new siderophore cephalosporin cefiderocol is one of the few antibiotics being considered for treating infections caused by these so-called difficult-to-treat (DTR) Gram-negative pathogens, since this molecule is not significatively hydrolyzed by most β-lactamases, including carbapenemases. In addition, cefiderocol bactericidal activity can overcome most non-enzymatic resistance mechanisms (porin mutations, and efflux pumps) [7]. Nevertheless, several mechanisms of resistance to cefiderocol have been recently reported, such as porin mutations, mutations affecting siderophore receptors, efflux pump overproduction, and modifications of the target (penicillin binding protein 3, or PBP-3), or production of some given β-lactamases [8]. A wide range of β-lactamases including class A (PER, BEL, SHV, KPC), class B (NDM, VIM), class C (AmpC), or class D β-lactamases (OXA-2, OXA-10, OXA-46) has been demonstrated to contribute to reduce the susceptibility to cefiderocol [8,9,10,11]. In addition, the progressive in vivo development of reduced susceptibility to cefiderocol has been reported in clinical contexts, particularly within two clinical trials [12, 13].
Recently, many promising β-lactamase inhibitors have been developed and might be soon clinically available along with respective β-lactam partner molecules, providing novel clinically relevant β-lactamase/β-lactamase inhibitor (BL/BLI) combos, useful to treat infections caused by extensively drug-resistant strains [14]. Among the newly developed BLIs, there are diazabicyclooctane (DBO) molecules, namely zidebactam, durlobactam, and nacubactam, that efficiently inhibit most class A and C (also some class D for zidebactam and durlobactam) β-lactamases, and additionally, they exhibit effective antibacterial activity by targeting PBP-2, in contrast to the presently available DBO avibactam, which have a weaker antibacterial activity. Another class of inhibitors corresponds to the boronic acid derivatives, with taniborbactam inhibiting the hydrolytic activity of class A and C β-lactamases, but also that of metallo-beta-lactamases (MBLs). Taniborbactam inhibits most NDM- and VIM-type β-lactamases (except NDM-9, NDM-30, and VIM-83), but does not show significant inhibitory activity against IMP-type enzymes [15,16,17,18]. Altogether, the development of all those new BLIs has promoted the development and the evaluation of novel BL/BLI combinations including aztreonam-avibactam, cefepime-zidebactam (WCK 5107, DBO), cefepime-taniborbactam (VNRX-5133, boronate), meropenem-nacubactam (FPI-1465, DBO), and sulbactam-durlobactam (ETX-2514) which have been tested in several in vitro studies and are now undergoing clinical evaluations, while imipenem-relebactam and meropenem-vaborbactam are already clinically-available [19,20,21,22,23,24,25,26,27].
The objective of our study was therefore to evaluate the in vitro activity of these new combos against multidrug-resistant Gram-negative isolates showing reduced susceptibility to cefiderocol, and to evaluate the potential benefit of adding a BLI (avibactam, relebactam, nacubactam, zidebactam, or taniborbactam) together with cefiderocol.
Material and methods
Bacterial isolates
A collection of 67 multidrug-resistant Enterobacterales, nine P. aeruginosa, and eleven A. baumannii clinical isolates showing reduced susceptibility to cefiderocol (MIC value ≥1 mg/L) determined by broth microdilution method using iron depleted Mueller-Hinton that had been collected by the Swiss National Reference Center for Emerging Antibiotic Resistance (NARA) across all Switzerland was used for this study [28]. Clinical isolates included Escherichia coli (n= 28), Klebsiella pneumoniae (n=19), Enterobacter cloacae (n=12), Citrobacter freundii (n=6), Klebsiella oxytoca (n=2), P. aeruginosa (n=9), and A. baumannii (n=11). Most of those isolates produced an MBL, including NDM-like (n=61), or VIM-like (n=6) and had previously been characterized at the molecular level (Table 1). Most of these isolates additionally produced extended-spectrum β-lactamases (Table 1). Our collection included also 25 non-duplicate E. coli strains possessing a four amino-acid insertion (YRIN or YRIK) in their PBP3 protein sequence that had been previously found to be less susceptible or resistant to the aztreonam-avibactam combination [22].
Susceptibility testing
MIC values were determined in duplicate by broth microdilution method using Mueller-Hinton (Bio-Rad Laboratories, Hercules, USA) for all β-lactams and their combinations except for cefiderocol, for which an iron-depleted Mueller-Hinton was used in accordance with EUCAST guidelines [29]. MIC value of the ongoing BL/BLI, cefepime-taniborbactam, cefepime-zidebactam, meropenem-nacubactam, and sulbactam-durlobactam was determined using a fixed concentration at 4 mg/L for these inhibitors [17, 26, 30]. The clinically used BL/BLI combinations aztreonam-avibactam, meropenem-vaborbactam, and imipenem-relebactam were also evaluated for comparison using a fixed concentration of 4 mg/L for avibactam and relebactam, and 8 mg/L for vaborbactam. Susceptibility of cefiderocol was determined alone or in combination with a fixed concentration of avibactam (4 mg/L) (cefiderocol-avibactam), relebactam (4 mg/L) (cefiderocol-relebactam), taniborbactam (4 mg/L) (cefiderocol-taniborbactam), zidebactam (4 mg/L) (cefiderocol-zidebactam), vaborbactam (8mg/L) (cefiderocol-vaborbactam), and nacubactam (4 mg/L) (cefiderocol-nacubactam) [30]. Interpretation was based on EUCAST breakpoints if available; otherwise, the breakpoints were chosen according to the corresponding β-lactam included in the BL/BLI combination [29]. Hence, resistance to cefepime-taniborbactam, cefepime-zidebactam, and meropenem-nacubactam (meropenem-nacubactam) were defined as MIC values > 4 mg/L for Enterobacterales and > 8 mg/L for P. aeruginosa and A. baumannii, whereas susceptibility was defined as MIC values ≤ 1 mg/L for cefepime-based combinations and ≤ 2 mg/L for meropenem-nacubactam for Enterobacterales, and MIC values ≤ 8 mg/L for cefepime-taniborbactam, cefepime-zidebactam, and meropenem-nacubactam for P. aeruginosa and A. baumannii. Resistance to sulbactam-durlobactam combination was defined as MIC values > 4 mg/L in A. baumannii, and resistance to cefiderocol and cefiderocol-based combinations were defined as MIC values > 2 mg/L for Enterobacterales and P. aeruginosa. In order to further evaluate the contribution of zidebactam and nacubactam that possess significant antibacterial activity on their own [17, 30], MICs of zidebactam and nacubactam alone were also determined. To better describe our strain collection, not only MIC50 but also MIC90 values of all β-lactams were determined and provided here.
Results
Susceptibility to the newly developed BL/BLI combinations in Enterobacterales
All enterobacterial clinical isolates tested included in our study showed resistance or reduced susceptibility to cefiderocol. Of note, 38.8% of those isolates showed an MIC value of cefiderocol close to the susceptibility breakpoint, being at 1 or 2 mg/L. The cefepime-zidebactam combination was the most effective with 91% of isolates showing MIC values ≤ 1 mg/L, and MIC50 and MIC90 values being at 0.125 mg/L and 1 mg/L, respectively (Table 2). The second-best option was meropenem-nacubactam with 71.6% of isolates exhibiting MIC values ≤ 2 mg/L, and MIC50 and MIC90 values being respectively at 0.125 mg/L and 128 mg/L. Of note, these results were mainly related to the MIC50 and MIC90 values for zidebactam and nacubactam alone evaluated at 0.125 and 2 mg/L and 2 and 8 mg/L, respectively, thus to the intrinsic activity of those latter molecules as antibacterial agents rather to their capacity to inhibit the corresponding β-lactamase genes. Interestingly, these two combinations were more effective than aztreonam-avibactam and cefepime-taniborbactam, which, along with cefiderocol, are considered last-line options against MBL producers. Given the following susceptibility rates obtained, respectively, 37.3% for meropenem-vaborbactam and 10.4% for imipenem-relebactam, those combinations did not display a high effectiveness against this strain collection. All these data are consistent with the results provided according to the production of NDM-like or VIM-like enzymes (Table S1). The activity of the combinations mentioned above was overall the same when testing PBP3-modified E. coli, therefore evidencing that this latter feature was not playing a major role in the resistance phenotype for those combinations. Nevertheless, it is worth highlighting that the percentage of enterobacterial isolates displaying MIC values ≤ 1 mg/L for cefepime-taniborbactam was only 19.4%, and was 0% among the PBP3-modified E. coli strains, suggesting a cross-resistance between cefiderocol and cefepime-taniborbactam.
Susceptibility to cefiderocol in combination with β-lactamase inhibitors in Enterobacterales
When testing Enterobacterales isolates, all combinations of cefiderocol and β-lactamase inhibitors exhibited higher susceptibility levels (lower MICs) than for cefiderocol alone, as shown in Table 3. Considering an MIC breakpoint at 2 mg/L, the susceptibility rates were highest for cefepime-zidebactam (91%), followed by cefiderocol-taniborbactam (76.1%), cefiderocol-nacubactam (74.6%), cefiderocol-avibactam (64.7%), cefiderocol-relebactam (59.7%), and cefiderocol-vaborbactam (22.4%). Of note, lower susceptibility rates were found when testing the PBP3-modified E. coli strains, likely due to the contribution of these modifications in the reduced susceptibility to cefiderocol. For those latter mutated isolates, the best combinations were cefiderocol-zidebactam (88%) and cefiderocol-nacubactam (64%), likely due to the high bactericidal activity of these both BLIs in this specie. All these data are in line with the results obtained after classification of NDM-like or VIM-like producers (Table S1).
Susceptibility to BL/BLI and cefiderocol/inhibitor combinations for P. aeruginosa and A. baumannii
For P. aeruginosa, the combinations that showed the higher susceptibility rates were imipenem-relebactam and meropenem-vaborbactam, with 55.6% of the isolates being susceptible. On the other hand, the following combinations aztreonam-avibactam, cefepime-taniborbactam, cefepime-zidebactam, and meropenem-nacubactam showed poor activities (MIC50 ≥ 16 mg/L) against those P. aeruginosa isolates showing reduced susceptibility to cefiderocol. Worryingly, a poor activity of those BL/BLI combinations was also observed with A. baumannii (all MIC50 ≥ 32 mg/L). The only effective combo against those A. baumannii isolates was SUL-DUR as 72.7% of isolates had MIC values ≤ 4 mg/L. MIC results for all clinical isolates showing reduced susceptibility or resistance to cefiderocol are shown in Table 1, including their β-lactam resistance determinants. Regarding cefiderocol combinations, the addition of β-lactamase inhibitors contributed to significantly decrease the MIC values for P. aeruginosa. Hence, cefiderocol-zidebactam showed the highest susceptibility rate (55.6%), whereas it was only 44.4% or less for all other combinations, the lowest rate being observed with cefiderocol-vaborbactam reporting (22.2%). For A. baumannii, combinations including cefiderocol with either avibactam, zidebactam, tanoborbactam, or relebactam displayed susceptibility rates higher than 90%, although these rates were at 9.1% for cefiderocol alone.
Discussion
Our data highlighted that the best in vitro activities against Enterobacterales showing reduced susceptibility or resistance to cefiderocol are cefepime-zidebactam and meropenem-nacubactam, even against E. coli strains exhibiting PBP3 modifications. In addition, MIC values of cefiderocol combined with BLIs, especially zidebactam, nacubactam, and taniborbactam, were significantly lower than those of cefiderocol alone. Those data might be explained by several reasons. First, the reduced susceptibility to cefiderocol in Enterobacterales was mainly associated to the co-production of CMY-like and/or SHV-like β-lactamases in addition to NDM-like enzymes, the former having been already shown to contribute to cefiderocol resistance [8]. Hence, combining cefiderocol with a BLI that can antagonize the activity of those CMY- or SHV-type β-lactamases basically constitute a significant advantage [8, 9]. Second, zidebactam and nacubactam have not only the ability to inhibit class A β-lactamases, but also possess a significant antibacterial activity by targeting the PBP-2 of Enterobacterales; therefore, those BLIs exhibit a so-called enhancer activity, in line with the low MIC values observed in this study and another [30]. Third, our collection included a high proportion of PBP3-modified E. coli strains, that latter feature being known to affect the susceptibility to cefiderocol, but also that of aztreonam-avibactam and cefepime-taniborbactam, considering that cefiderocol, aztreonam, and cefepime mainly act by targeting the PBP-3 [22, 31,32,33]. Of note, imipenem-relebactam and meropenem-vaborbactam did not show any significant antibacterial activity against the Enterobacterales tested, which can be explained by the majority being MBL producers.
When considering cefiderocol-resistant P. aeruginosa isolates, the most efficient option was imipenem-relebactam, likely due a high proportion of AmpC overproducers and/or co-producers of SHV-like or VEB-like ESBLs. These results are in line with other studies reporting that the imipenem-relebactam combination is one of the best alternatives to treat infections caused by imipenem-non susceptible P. aeruginosa, mainly driven by multiple resistances mechanisms including combinations of OprD inactivation and AmpC or/and efflux overexproduction [34]. Noteworthy, avibactam and vaborbactam have a negligible effect on restoring susceptibility to aztreonam and meropenem, respectively, probably related to the fact that both β-lactams are very good substrates of the MexAB-OprM efflux system, which is commonly overexpressed in a large proportion of clinical isolates and against which the addition of β-lactamase inhibitors is ineffective. Interestingly, the β-lactamase inhibitor relebactam not only showed an excellent inhibitory activity against class A β-lactamases (i.e., SHV-like and VEB-like enzymes), but also against class C β-lactamases such as the intrinsic PDC-like enzymes. Hence, the association of relebactam with imipenem could restore low MIC values against isogenic imipenem non-susceptible P. aeruginosa isolates producing a wide range of non-enzymatic resistance mechanisms identified in that species, eventually contributing to cefiderocol resistance [34, 35]. On the other hand, the cefepime-taniborbactam and cefepime-zidebactam combinations were not as effective against P. aeruginosa isolates as they were against Enterobacterales. This may be explained by the fact that cefepime is particularly affected by the overexproduction of efflux pumps such as MexAB-OprM, or MexXY. In addition, we did not analyze the presence or absence of blaOXA-like in our P. aeruginosa isolate collection, and it may be that zidebactam and taniborbactam are not efficient β-lactamase inhibitors against OXA-2- or OXA-10-type β-lactamases, which are known to be widely distributed in P. aeruginosa and contributing to the reduced susceptibility to cefiderocol [11, 19]. Finally, zidebactam and nacubactam have a lower intrinsic antibacterial activity against P. aeruginosa in comparison to Enterobacterales, considering that the MIC values are approximately around 4–16 mg/L for zidebactam, and above 32 mg/L for nacubactam for Pseudomonas spp. [36, 37].
When considering cefiderocol-resistant A. baumannii, the main resistance mechanism is driven by the production of PER-like or NDM-like enzymes, as already described [9]. Our data showed that aztreonam-avibactam was not an interesting option, since A. baumannii naturally exhibits high MIC values of aztreonam, and this β-lactam is also hydrolyzed at high level by PER-like enzymes, often produced in that species [9, 17]. Additionally, the class D β-lactamase OXA-23 (which is very commonly produced in carbapenem-resistant isolates) significantly hydrolyzes imipenem and meropenem, but neither nacubactam nor relebactam inhibit OXA-23-like enzymes, eventually leading to resistance to meropenem-nacubactam and imipenem-relebactam. However, durlobactam inhibits class A β-lactamases, such as PER-like enzymes, as well as some class D β-lactamases such as OXA-23, which explains the high susceptibility rate observed for sulbactam-durlobactam in this strain collection. Cefepime being a very good substrate for PER-like enzyme, but also for efflux pumps oftenly overproduced in A. baumannii, this may explain why combinations including taniborbactam and zidebactam were not sufficiently active to restore MIC values in the susceptibility range. Finally, it is worth highlighting that zidebactam and nacubactam do not possess significant direct antibacterial activity in that species [36, 37]. The main feature to be highlighted is that combining cefiderocol with most β-lactamase inhibitors in this study resulted in low MIC values for most isolates. This is most likely due to the ability of all BLI tested to inhibit PER-like enzymes, which were the most relevant resistance factors of cefiderocol detected in this specie. Those results strongly suggest that combination therapies including cefiderocol with a β-lactamase inhibitor, and sulbactam-durlobactam, might be extremely effective in the treatment of infections caused by cefiderocol-resistant A. baumannii isolates.
In conclusion, we showed here that cefepime-zidebactam, meropenem-nacubactam, and aztreonam-avibactam are the best therapeutic alternatives against multidrug-resistant Enterobacterales exhibiting reduced susceptibility or resistance to cefiderocol. By contrast, imipenem-relebactam was the best option against P. aeruginosa isolates. Worryingly, with the exception of sulbactam-durlobactam, none of the novel β-lactam/β-lactamase inhibitor combinations were effective against A. baumannii isolates. Nevertheless, combinations made of cefiderocol and several β-lactamase inhibitors (namely avibactam, taniborbactam, relebectam, zidebactam, and nacubactam) constitute interesting alternative therapeutics against all tested Gram-negative clinical isolates showing reduced susceptibility to cefiderocol.
Data availability
All data generated through this study can be available upon request.
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CLT, PN, LP: conceptualization, methodology, and design of the study; CLT, SF: investigation; PN: supervision and funding acquisition; all authors: analysis and interpretation of the results; CLT, PN, LP: writing—original and final draft.
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Le Terrier, C., Freire, S., Nordmann, P. et al. Multidrug-resistant Gram-negative clinical isolates with reduced susceptibility/resistance to cefiderocol: which are the best present and future therapeutic alternatives?. Eur J Clin Microbiol Infect Dis 43, 339–354 (2024). https://doi.org/10.1007/s10096-023-04732-4
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DOI: https://doi.org/10.1007/s10096-023-04732-4