Abstract
The escalating antimicrobial resistance crisis urges the development of new antibacterial treatments with innovative mechanisms of action, particularly against the critical priority carbapenem-resistant Acinetobacter baumannii (CRAB), Pseudomonas aeruginosa (CRPA) and Enterobacteriaceae (CRE). Membrane-disrupting dodecyl deoxyglycosides have been reported for their interesting phosphatidylethanolamine-associated bactericidal activity against Gram-positive strains; however, their inability to penetrate the Gram-negative outer membrane (OM) renders them useless against the most challenging pathogens. Aiming to repurpose alkyl deoxyglycosides against Gram-negative bacteria, this study investigates the antimicrobial effects of five reference compounds with different deoxygenation patterns or anomeric configurations in combination with polymyxins as adjuvants for enhanced OM permeability. The generation of the lead 4,6-dideoxy scaffold was optimized through a simultaneous dideoxygenation step and applied to the synthesis of a novel alkyl 4,6-dideoxy C-glycoside 5, herein reported for the first time. When combined with subtherapeutic colistin concentrations, most glycosides demonstrated potent antimicrobial activity against several multidrug-resistant clinical isolates of CRAB, CRE and CRPA exhibiting distinct carbapenem resistance mechanisms, together with acceptable cytotoxicity against human HEK-293T and Caco-2 cells. The novel 4,6-dideoxy C-glycoside 5 emerged as the most promising prototype structure for further development (MIC 3.1 μg/mL when combined with colistin 0.5 μg/mL against CRPA or 0.25 μg/mL against several CRE and CRAB strains), highlighting the potential of C-glycosylation for an improved bioactive profile. This study is the first to show the potential of IM-targeting carbohydrate-based compounds for the treatment of infections caused by MDR Gram-negative pathogens of clinical importance.
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Introduction
Also referred to as the silent pandemic, antimicrobial resistance (AMR) is one of the most alarming threats posed to human health in the twenty-first century1. In 2019 alone, 4.95 million deaths were associated with bacterial AMR, of which 1.27 million were directly attributable to infections caused by antimicrobial-resistant bacteria2. The Gram-negative ESKAPE pathogens Escherichia coli, Klebsiella pneumoniae, Acinetobacter baumannii, and Pseudomonas aeruginosa are among the top six bacteria responsible for these estimates2,3. In agreement, carbapenem-resistant A. baumannii (CRAB), P. aeruginosa (CRPA), and Enterobacteriaceae (CRE) were placed at the very top of the World Health Organization (WHO)’s list of priority pathogens under the “critical priority” category. The fact that only one broad-spectrum agent, cefidorocol, is currently available to treat infections caused by all three bacteria highlights the urgent need for new therapeutic options, preferably with novel mechanisms of action (MoA)4.
Carbohydrates are increasingly recognized as valuable scaffolds for the rational design and development of new compounds with antibiotic activity and innovative MoA5. In 2018, Rauter and co-workers reported a series of membrane-disrupting dodecyl deoxyglycosides with potent inhibitory activity against a small panel of Gram-positive bacteria, namely Bacillus anthracis (Sterne, ovine and pathogenic forms), Enterococcus faecalis and Bacillus cereus6. With a minimum inhibitory concentration (MIC) of 12.6 μM against all tested pathogens, the 4,6-dideoxy α-D-glycoside 1 (Fig. 1) was the best in the series, whereas the corresponding β-anomer (2) was virtually inactive (MIC > 405 μM). The 2,6-dideoxy α-L-glycoside 3 (MIC 20–50 μM), chosen as the representative structure of this class of compounds, was found to selectively interact with phosphatidylethanolamine (PE), present in bacterial membranes, versus phosphatidylcholine (PC), present in eukaryotic ones. When tested against the Gram-negative E. coli K12, compound 3 was not active per se (MIC 256 μg/mL), despite the 80% of PE in its inner membrane (IM) composition vs. the 43% reported for the membrane of B. cereus7. Yet, in E. coli K12 spheroplasts, where only the IM is left intact, a dramatic increase in inhibitory activity was observed (MIC 4 μg/mL), suggesting a complete lack of outer membrane (OM) permeability for these glycosides, but a clear potential for use in PE-enriched membranes in conditions where the OM integrity is compromised6. Furthermore, likely because of the membrane-targeting MoA, compound 3 presented low susceptibility to common mechanisms of resistance against several antibiotics used in the clinical setting, including erythromycin, penicillin, vancomycin, ciprofloxacin, and tetracycline6, ultimately pointing towards a vast therapeutic potential of dodecyl deoxyglycosides against MDR bacteria—one that is yet to be explored.
Due to the presence of the lipopolysaccharide (LPS)-encompassing OM, Gram-negative bacteria are indeed less susceptible to antibiotic entrance compared to Gram-positive bacteria, in addition to being particularly prone to develop permeability-related AMR mechanisms8. Because of the disparity observed between IM and OM in terms of physicochemical characteristics, compounds that are able to pass through the IM are not likely to pass through the OM and vice-versa9. Therefore, creative solutions involving the concomitant use of more than one compound may often be required when it comes to the development of new antimicrobial strategies directed against Gram-negative bacteria, particularly when the goal is to repurpose antibiotics with demonstrated activity against Gram-positive organisms10. In this context, this study explores the potential of dodecyl deoxyglycoside leads against the critical priority Gram-negative pathogens CRAB, CRPA, and CRE, ultimately aiming to contribute to new solutions for the emerging AMR threat. We hypothesized that by using subtherapeutic concentrations of an adjuvant agent able to enhance OM permeability, our glycosides would then succeed at disrupting the IM and cause bacterial cell lysis through a concerted, membrane-exclusive MoA. Polymyxins B (PMB) and E (colistin) were chosen as adjuvant agents for a few reasons: (i) these are last-resort antibiotics approved for clinical use and listed among the critically important antibiotics for combating AMR11,12; (ii) they act by binding to the OM LPS lipids, thus increasing OM permeability, as required10; (iii) polymyxins and polymyxin analogs have been previously shown to potentiate the activity of several antibiotics13,14,15. However, while these antibiotics are important for combating antimicrobial resistance, they should be carefully considered due to their potential for neurotoxicity and nephrotoxicity. Fortunately, these adverse effects are generally dose-dependent and typically reversible when the drug is discontinued early16. Moreover, there is evidence indicating that colistin does not appear to influence clinical outcomes or mortality, whether used alone or in combination17.
In addition to disclosing the lowest possible polymyxin concentration able to render the desired OM permeation, this study was also designed to identify the best glycoside among five reference structures for structural optimization. Besides the already described compounds 1 and 3, 4,6-dideoxy β-D-glycoside 2 (Fig. 1) was chosen to provide a source of comparison between configuration α- vs. β- in O-glycosides against Gram-negative bacteria, since a huge disparity in activity between 1 and 2 has been reported in Gram-positive pathogens6. Furthermore, 2-deoxy α-D-glycoside 4 (Fig. 1), which exhibits limited affinity towards PE6, was also included to corroborate the importance of the PE-related MoA of alkyl deoxyglycosides in Gram-negative bacteria, as well as to highlight the role of the 6-deoxygenation pattern in activity. Last but not least, due to the potential for improved metabolic stability of C-glycosides versus their O-glycoside analogs18 and previous evidence of C-glycoside efficacy in carbohydrate-based antibiotic development19,20, we envisioned the anomeric O → C substitution in compound 1 to afford the more structurally robust α-glycoside 5 (Fig. 2), obtained through a simultaneous deoxygenation procedure and herein reported for the first time.
Results and discussion
Synthesis
Even though compounds 1 and 2 had previously been reported6,21, one of our goals was to further explore and optimize the construction of the desired 4,6-dideoxy pattern that was still offering significant potential for improvement. The synthesis started from the commercially available methyl α-D-glucopyranoside which, after 4,6-O-benzylidene introduction and subsequent benzylation of positions 2 and 3, rendered intermediate 6 in excellent yield (Fig. 3). In previous work (Fig. 2), selective benzylidene opening at position 4 in the presence of sodium cyanoborohydride and molecular iodine was the first step in the reported sequential deoxygenation procedure21. After triflate introduction followed by reduction of position 4, the sugar donor was immediately glycosylated. It was only after full benzyl removal that the last deoxygenation step was conducted, taking advantage of the preferential reactivity of position 6 when compared to positions 2 and 3. However, this procedure required a total of seven reaction steps from compound 6 before the 4,6-dideoxy pattern could be achieved21. In the present work, we opted for a full benzylidene deprotection in mildly acidic conditions at 50 ºC, which afforded intermediate 7 in almost quantitative yield (Fig. 3). Then, simultaneous triflation of positions 4 and 6, followed by reduction with tetrabutylammonium borohydride at 85 ºC gave the key intermediate 8 in 88% yield over two steps. We were hence able to access the target 4,6-dideoxy pattern in only three reaction steps, rendering the synthetic route toward the sugar donor for both O- and C-glycosylation much more concise, straightforward, and efficient.
For the synthesis of compounds 1 and 2, intermediate 8 was O-glycosylated in the presence of dodecan-1-ol in acidic conditions, affording the inseparable anomeric mixture 9 in high yield (Fig. 4A). As previously described21, debenzylation still did not enable the separation of 1 and 2. Therefore, the mixture was acetylated, the anomers separated by column chromatography, and Zemplén deacetylation gave the desired products in good overall yields. Compounds 1 and 2 were successfully accessed through this new procedure with only eight reaction steps, in 25% and 17% overall yield, respectively, compared with 11 steps in the previously described route, which gave 1 and 2 in 11% and 5% overall yield, respectively.
When it comes to C-glycosylation, intermediate 8 was first submitted to anomeric activation as previously described6. However, the use of strong acid in the attempted protocol for demethylation with concomitant acetylation led to a complex mixture of compounds, with 10 (Fig. 4B) being identified as the major product (35% yield) as a result of selective debenzylation and acetylation at position 3. After coming across such a low yield for a supposedly straightforward activation step, we decided to explore more efficient alternatives, starting with the full debenzylation of 8 prior to anomeric activation. Thus, catalytic dehydrogenation followed by acid-promoted demethylation was conducted, after which full acetylation in the presence of acetic anhydride and pyridine gave compound 11 in 90% yield over three steps. At this point, it became clear that the switch from benzyl to acetate groups was a requirement for efficient anomeric activation. We, therefore, pondered the use of the 2,3-di-O-acetyl-4,6-O-benzylidene precursor S1 (see Supplementary Fig. S1 online) as the starting material. Given the incompatibility of acetate protection with hydride-donor reagents such as the one used in the synthesis of 8, an alternative route towards 11 relying on sequential iodination of positions 4 and 6 through the Garegg method22 followed by catalytic hydrogenation in the presence of a base23 was explored. Yet, due to the extent of this procedure compared to the above-described simultaneous 4,6-dideoxygenation, anomeric activation starting from the benzyl-protected intermediate 8 still proved to be more efficient.
For comparison purposes, C-glycosylation of both 10 and 11 was carried out in parallel. The use of boron trifluoride etherate in the presence of allyl trimethylsilane6 at 0 ºC gave the allyl α-C-glycosides 12 and 13, respectively, in equally high yields (Fig. 4B). Then, a chain-elongation metathesis reaction catalysed by the 2nd Generation Grubbs-Hoveyda catalyst in the presence of undec-1-ene6 followed by catalytic hydrogenation and deacetylation afforded, in both cases, the final compound 5 in moderate and good yields, respectively. All in all, the synthesis of this new C-glycoside was found to be significantly more efficient through intermediate 11 (47% overall yield over 12 reaction steps) than through intermediate 10 (13% overall yield over 10 steps), regardless of the two additionally required reaction steps. Of note, compounds 3 and 4 were synthesized according to the previously described methodology6.
Antibacterial activity
Glycosides and glycoside-adjuvant combinations were evaluated against two well-characterized Gram-negative strains for validation of our study: the antibiotic-susceptible E. coli ATCC 25922, and the colistin-resistant E. coli NCTC 13846 strains. We then set a panel of six carbapenem-resistant Gram-negative clinical isolates as test strains, all of which are part of the Portuguese National Reference Laboratory for Antibiotic Resistance and Healthcare-Associated Infections (NRL-AR/HAI, INSA) collection. These comprise several colistin-susceptible Gram-negative ESKAPE pathogens (K. pneumoniae, E. cloacae, A. baumannii and P. aeruginosa) expressing different types of carbapenem-hydrolyzing enzymes, including OXA-48, NDM-1, KPC-3, IMP-1 and GES-12. Most of these strains are also resistant to penicillins, cephalosporins, fluoroquinolones and aminoglycosides, with the complete antibiotic susceptibility and resistance profiles being presented in Supplementary Table S1 online. All test strains were susceptible to both colistin and PMB with a MIC value of 0.5 μg/mL or 1 μg/mL (P. aeruginosa CQ4924). Based on the reported concentration-dependent polymyxin-LPS electrostatic interactions leading to OM permeation24,25,26, we envisioned that polymyxin concentrations lower than the MIC would be sufficient to enhance OM permeability to our glycosides without causing significant inhibition in bacterial cell growth. Furthermore, subtherapeutic polymyxin concentrations have been described to enhance OM permeability in Gram-negative bacteria without interfering with IM integrity27. Therefore, the maximum polymyxin concentration for glycoside-polymyxin combination assays was established at the first two-fold dilution of the maximum MIC, i.e., 0.5 μg/mL. Of note, MIC values for the colistin-resistant control strain (E. coli NCTC 13846) were, as anticipated, significantly higher (4 μg/mL; Table 1) compared to the remaining bacteria, which should result in complete glycoside inactivity for the maximum used polymyxin concentration of 0.5 μg/mL.
Glycoside-colistin combinations
The heatmaps depicted in Fig. 5 show the antimicrobial activities of compounds 1–5 when combined with colistin at 0.5 μg/mL, 0.25 μg/mL or 0.125 μg/mL. All in all, with 0.5 μg/mL of colistin (Fig. 5A), both colistin-susceptible control (strain A) and test strains (strains C-H) were susceptible to glycoside-polymyxin combinations, with MIC values ranging from ≤ 0.1 μg/mL to 3.1 μg/mL in the most colistin-susceptible pathogens (strains C-G) and from 3.1 μg/mL to 6.3 μg/mL in P. aeruginosa CQ4924 (strain H). For all test strains except for the latter, the use of colistin at the MIC can merely rule out significant antagonistic effects between glycosides and the permeabilizing agent that would potentially hinder its ability to interact with the LPS and interfere with OM integrity. The close-to-zero MIC values observed throughout test strains (in most cases ≤ 0.1 μg/mL) indicate that these glycosides should generally be unable to interfere with the MoA of colistin to a significant extent, with compounds 2 and 5 clearly presenting the potential for additive or synergistic effects (see Supplementary Table S1 online). In fact, by calculating the Fractional Inhibitory Concentration Index (FICI) (Table 2)28,29,30, we were able to assert with more detail that these two glycosides act synergistically with colistin in E. cloacae CQ1941 (strain D) and A. baumannii CQ4322 (strain G), and additively in the remaining test strains.
Despite the absence of antagonistic effects (Table 2), there was a lack of antimicrobial activity of 1 towards P. aeruginosa CQ4924 (strain H) even in the presence of colistin at 0.5 μg/mL (Fig. 5A). Given that 0.5 μg/mL corresponds to half of the MIC value of colistin against CRPA CQ4924 (and therefore to a concentration that should be unable to cause inhibition of bacterial growth per se in this strain), our results suggest, on the other hand, that compounds 2, 3 and 5 were able to effectively penetrate the OM and induce IM lysis — particularly 3 and 5, which exhibited the lowest MIC (3.1 μg/mL). It is important to highlight that, according to the previously established MoA for these types of compounds6, the high IM PE levels displayed by Gram-negative bacteria (60–82%7), which can furthermore be upregulated in the presence of low colistin concentrations31, should be the core factor enabling the effective targeting of the IM, and could furthermore justify the five-fold lower MIC values vs. those reported in Gram-positive pathogens (e.g. 16 μg/mL for compound 3 in B. cereus ATCC 145796, exhibiting 43% of PE in the membrane7). Moreover, these glycosides were not active per se (i.e. in the absence of polymyxins) in any of the eight tested bacterial strains (MIC > 100 μg/mL, see Supplementary Tables S3and S4 online), thus validating our concept that antimicrobial activity in Gram-negative bacteria is observed due to polymyxin-induced OM permeabilization. As expected, the colistin-resistant E. coli NCTC 13846 (strain B; colistin-resistant control) was not susceptible to any of the tested antibiotic combinations.
It is interesting to note the activity observed for β-O-glycoside 2 in light of the lack of antimicrobial effects previously reported for this compound in Gram-positive bacteria6. Rather than an intrinsic inability of the β-anomer to interact with PE and act as a bactericide, this result strongly points towards other factors contributing to its divergent behaviour when encountering variations in the bacterial cell envelope from Gram-positive to Gram-negative pathogens. We postulate that one possible explanation for this result could be related to target inaccessibility due to enzymatic liability. Indeed, being a β-O-glycoside, 2 should display a naturally higher susceptibility to hydrolysis by enzymes with β-glycosidase activity when compared with its α analogue (1). If, on the one hand, both Gram-positive and Gram-negative bacteria redundantly express cell wall-associated enzymes required for the cleavage of β-1,4 glycosidic bonds between MurNAc and GlcNAc peptidoglycan units32, on the other hand, the regulation of such enzymes may widely vary among types of bacteria and environmental factors33,34. Consequently, in case 2 is a substrate of one or more of these peptidoglycan-recycling enzymes, the compound could indeed reach the IM to a lower extent in bacteria with higher rates of cell wall remodeling and turnover.
As for glycoside 4, it was found to be inactive against P. aeruginosa CQ4924 when combined with colistin at 0.5 μg/mL (Fig. 5A), pointing towards the inability of this 2-deoxy glycoside to inhibit bacterial cell growth even in conditions that favour OM permeabilization. This inability was indeed confirmed when the colistin concentration was lowered to 0.25 μg/mL (Fig. 5B), rendering 4 fully inactive even against the antibiotic-susceptible E. coli ATCC 25922 (control strain A).
Taken together, the results for compounds 1–3 and 5 (Fig. 5B), demonstrate that colistin 0.25 μg/mL is sufficient for OM permeabilization in all test strains except for P. aeruginosa CQ4924 (strain H). Under these conditions, however, compounds 1–3 failed to be active against K. pneumoniae CQ1947 (strain F), an IMP-1-producing MDR clinical isolate. K. pneumoniae is the most common pathogen causing bloodstream infections, pneumonia, urinary tract infections (UTIs) and peritonitis, being typically associated with infections occurring in hospitalized or immunocompromised patients35,36. In the early 2000s, an outbreak of carbapenem-resistant K. pneumoniae in the United States marked the onset of the CRE epidemic37. In Portugal, carbapenem-resistant K. pneumoniae isolates were reported in 201038, suggesting a relatively rapid importation of CRE strains to the European continent. Indeed, these remain a threat to public health to this day: with limited treatment options, patients infected with carbapenem-resistant K. pneumoniae are at a significantly higher risk of in-hospital death and poorer health outcomes than those infected with carbapenem-sensitive K. pneumoniae39, which urgently calls for the identification and development of new antibiotic approaches against K. pneumoniae strains expressing carbapenemases. Despite the results for compounds 1–3, we were pleased to find that, with a subtherapeutic colistin concentration of 0.25 μg/mL, C-glycoside 5 exhibited antimicrobial activity against all three carbapenem-resistant K. pneumoniae isolates tested, including the IMP-1-producing strain CQ1947 (strain F). This result already denotes a positive impact of the O → C bioisosteric replacement from 1 to 5 on the antimicrobial activity of alkyl 4,6-dideoxy-α-D-xylo glycosides, and highlights the potential of compound 5 as a lead for further development against CRE.
Using a colistin concentration fourfold lower than the MIC, both K. pneumoniae CQ1942 (strain E) and K. pneumoniae CQ1947 (strain F) became non-susceptible to any of the glycosides (Fig. 5C). Yet, 0.125 μg/mL was sufficient to allow the entry of compounds 2 and 5 through the OM of K. pneumoniae CQ4921 (strain C), E. cloacae CQ1941 (strain D) and A. baumannii CQ4322 (strain G), which promoted visible antibacterial effects (MIC 3.1–25 μg/mL). Notably, the OXA-48-producing K. pneumoniae CQ4921 is not only susceptible to imipenem upon increased exposure but is also susceptible to ciprofloxacin and aminoglycoside antibiotics, contrarily to the above-mentioned imipenem-resistant CQ1942 (KPC-3-producing) and CQ1947 (IMP-1-producing) strains (see Supplementary Table S1 online). Hence, even though all three strains are colistin-susceptible, our results reflect a higher sensitivity of the more susceptible K. pneumoniae CQ4921 to colistin-LPS interactions than the remaining two less susceptible K. pneumoniae strains. Moreover, to our surprise, the β configuration (2) of alkyl 4,6-dideoxy-D-xylo O-glycosides seems to be more beneficial to activity at low colistin concentrations than the α configuration (1).
As part of the CRE epidemic37,38, the reported rise in infections caused by carbapenem-resistant K. pneumoniae in the last decade40 is accompanied by an increase in the rate of nosocomial infections caused by carbapenem-resistant E. cloacae as well41. The expression of the New Delhi metallo-β-lactamase 1 (NDM-1) has been described as one of the most common carbapenem resistance-associated mechanisms in this type of bacteria41,42,43,44, which is captured by E. cloacae CQ1941 (strain D), used in the present study. This strain is not only resistant to penicillins, cephalosporins, and aminoglycosides, but also to the synthetic monobactam aztreonam (see Supplementary Table S1 online), which is still seen as a valid bet for pharmaceutical investment. Indeed, aztreonam is currently under Phase 3 trials in combination with avibactam for the treatment of serious infections caused by carbapenemase-producing MDR Gram-negative pathogens for which available therapeutic options are limited45. With a MIC of 3.1 μg/mL, C-glycoside 5 has the potential to be further explored against this aztreonam-resistant CRE strain when combined with colistin at 0.125 μg/mL, while O-glycoside 2 was significantly less active in the same conditions (MIC of 12 μg/mL) (Fig. 5C).
In contrast, 2 was significantly more active against the GES-12-producing A. baumannii CQ4322 (strain G) than 5, in spite of the higher MIC value observed (6.3 μg/mL). In addition to CRPA and CRE, CRAB was also included in our MDR Gram-negative pathogen panel for being a top-priority pathogen in urgent need of novel antibiotic development, with frequent healthcare-associated outbreaks leading to high mortality rates in critically ill patients4,46. Hence, even though lead 5 seems to be the most promising glycoside of the series overall, lead 2 may offer a relevant alternative to cover a wider spectrum of pathogens and different carbapenem resistance mechanisms, and thus should also be further explored.
It is worth mentioning that 0.06 μg/mL of colistin led to OM permeabilization in the antibiotic-susceptible control strain E. coli ATCC 25922, but not in either of the carbapenem-resistant test strains (see Supplementary Table S3 online). A colistin concentration of 0.125 μg/mL can, therefore, be established as the lowest subtherapeutic colistin dilution with observable OM-permeabilizing effects in MDR Gram-negative pathogens with a MIC of colistin of 0.5 μg/mL (strains C, D and G), while 0.5 μg/mL is the lowest subtherapeutic colistin dilution capable of such effects in CRPA CQ4929 (strain H), which has a MIC of colistin of 1 μg/mL (Table 1).
To corroborate the bactericide MoA that was previously proposed for this class of glycosides, the minimum bactericidal concentration (MBC) was also determined for the best compounds in combination with colistin at 0.125 μg/mL. Since the MBC of compounds 2 and 5 was either equal to or just one dilution higher than the MIC (Table 3), we conclude that these compounds are, indeed, bactericides in Gram-negative bacteria when in the presence of an OM-permeabilizing agent. This is in alignment with previous evidence supporting a bactericidal MoA of alkyl deoxyglycosides in Gram-positive bacteria6.
PMB-glycoside combinations
As a potentially useful alternative to colistin, PMB was also tested in combination with all five glycosides against the same panel of control and test CRE, CRAB and CRPA strains. The results, shown in Fig. 6 (and in Supplementary Table S4 online), reveal MIC values that were overall higher with PMB as adjuvant agent compared with colistin. For instance, at 0.5 μg/mL of PMB, only C-glycoside 5 was active against CRPA CQ4924 (MIC of 6.3 μg/mL) (Fig. 6A). Furthermore, at 0.25 μg/mL, only compounds 2 and 3 were active against a few carbapenem-resistant strains (C, D and G), but with higher MIC values compared with the same concentration of colistin (Fig. 6B). In fact, PMB and colistin are two cationic polypeptide antibiotics differing only in the amino acid residue at position 6 of the peptide ring (D-Phe vs. D-Leu, respectively)47. Even though both polymyxins should enhance OM permeability mainly via their amine moieties—which are protonated at physiological pH and involved in a cation-displacement MoA26,48—these antibiotics also rely upon their hydrophobic domains to interact with LPS and get inserted into the membrane47. In this perspective, our results indicate that the D-leucine residue present in colistin presents benefits in terms of OM permeabilization when used at subtherapeutic concentrations compared to the D-phenylalanine residue of PMB, probably by favouring hydrophobic interactions with LPS. Hence, colistin should be pursued as the most adequate adjuvant agent to be used with these types of glycosides. Lower concentrations of PMB were, therefore, not explored.
Cytotoxic effects
Cytotoxicity of each compound alone or in combination with different polymyxin concentrations was evaluated through the resazurin cell viability assay49 in human embryonic HEK-293T cells, as well as in human colon adenocarcinoma Caco-2 cells, after a 72-h long incubation period. Results (IC50 values expressed in μg/mL) for glycoside and glycoside-polymyxin combinations (except for the inactive glycoside 4) are visually presented in Fig. 7 (IC50 values expressed in μM are presented in Supplementary Tables S5 and S6 online).
When tested alone in HEK-293T cells, colistin and PMB displayed an IC50 value > 115 μg/mL (not graphically shown), which is in agreement with previously reported values in HEK-293 cells (> 1000 and > 500 μg/mL, respectively)50 and other human cell lines51,52. An identical result was obtained for both polymyxins in Caco-2 cells (IC50 > 115 μg/mL). With regards to glycosides, compounds 1–3 presented IC50 values above 17 μg/mL in Caco-2 cells (Fig. 7B), which is also in agreement with previous results6, but slightly higher in HEK-293T cells (> 20 μg/mL, Fig. 7A). All in all, our results indicate that Caco-2 cells were more sensitive to the cytotoxic effects caused by the glycosides compared with HEK-293 T cells. Of note, in both cell lines, the inactive glycoside 4 displayed an IC50 value > 100 μM (i.e., > 33 μg/mL; see Supplementary Tables S5nd S6online).
Results for glycoside-polymyxin combinations indicate that there is not a significant increase in cytotoxic effects on human cells with the addition of subtherapeutic concentrations of colistin or PMB, regardless of the cell line (HEK-293T cells, Fig. 7A and Caco-2 cells, Fig. 7B). Indeed, a two-way ANOVA revealed a non-significant polymyxin effect, thus denoting that the use of polymyxins as adjuvant agents is effective for Gram-negative OM permeabilization but is not accompanied by increased cytotoxic effects in human cells. This observation is of particular importance given the known nephrotoxic effects of colistin and PMB, despite being considered safe enough for administration in patients with infections caused by Gram-negative bacteria53.
On the other hand, statistically significant differences in toxicity were found between glycosides (p < 0.0001). Compound 1 alone, with an IC50 of 20.8 μg/mL (65.8 μM) in HEK-293T cells and 17.2 μg/mL (54.3 μM) in Caco-2 cells, was significantly more cytotoxic than all the remaining compounds, including its β-epimer (2) in HEK-293 T cells (IC50 of 26.6 μg/mL or 84.2 μM; p < 0.0001), and its C-glycoside analogue (5) in both cell lines (IC50 of 24.0 μg/mL or 79.7 μM in HEK-293 T cells and 18.7 μg/mL or 64.2 μM in Caco-2 cells; p < 0.0001 for both comparisons). These results denote that these structural changes (β vs. α configuration and C- vs. O-glycosylation) were not only favourable in terms of antimicrobial activity but also in terms of cytotoxicity.
With these results, we calculated the lowest in vitro therapeutic index (TI = lowest determined IC50/MIC) for the microbiologically active glycoside-colistin concentrations. The TI is commonly used to quantify the balance between the efficacy and safety of a given drug, and reflects the therapeutic window that exists between the drug concentration that results in no significant toxicity and the concentration that produces the desired efficacy54. As compounds presented the lowest IC50 value in Caco-2 cells, the lowest in vitro TI was calculated based on the cytotoxic effects of each combination toward these cells.
With colistin 0.5 μg/mL, compounds 3 and 5 presented the best TI against P. aeruginosa CQ4924 (strain H; approximately 6.9 and 6.2, respectively, Fig. 8). With colistin 0.25 μg/mL, the best TIs were seen against E. cloacae CQ1941 (strain D; maximum observed TI of approximately 13.7 for compound 3) — the strain for which MIC values were generally the lowest. Importantly, compound 5 presented a consistent TI of approximately 6.3 against all test strains C-G (Fig. 8). Despite seemingly narrow, this value reflects a reasonable (at least sixfold) margin for observing antimicrobial effects without significant toxicity in mammalian cells. Importantly, since the antimicrobial activity was fully retained when using compound 5 plus 0.125 μg/mL of colistin in K. pneumoniae CQ4921 and E. cloacae CQ1941 (MIC 3.1 μg/mL for both, Fig. 5C) without a significant change in cytotoxicity, this margin was also maintained against these two bacterial targets despite the use of a twofold lower adjuvant concentration. However, the 25 μg/mL MIC against A. baumannii CQ4322 (strain G; Fig. 5) exceeded the IC50 observed in both HEK-293 T and Caco-2 cells (24.0 μg/mL and 18.7 μg/mL, respectively; Fig. 7), suggesting the potential for general toxicity of compound 5 when used at this concentration against this particular isolate.
Conclusions
In this study, several dodecyl deoxyglycoside leads were explored in combination with subtherapeutic concentrations of two OM-permeabilizing agents, colistin and PMB, and were successfully repurposed against a panel of critical priority carbapenem-resistant Gram-negative ESKAPE pathogens exhibiting different carbapenem resistance mechanisms. The route toward glycosides 1 and 2 was optimized through a simultaneous dideoxygenation methodology, which enabled the development of a much more expedient synthesis compared to that originally described21. Furthermore, a new C-glycoside lead (5) was herein reported for the first time, and several alternative procedures were exploited to set a solid foundation for its synthesis under optimized conditions. This novel α-C-glycoside (5) was active against CRPA when combined with colistin at 0.5 μg/mL, as well as against CRAB and several CRE clinical isolates with colistin 0.25 μg/mL and, in some cases, 0.125 μg/mL. With a generally wider range of susceptible clinical isolates compared to other compounds, the C-glycoside 5 was found to be the most promising glycoside of the series together with the O-glycoside 2 with β-anomeric configuration. Both were found to display synergistic effects with colistin against clinical isolates of E. cloacae and A. baumannii. Importantly, the bactericidal MoA of both compounds was confirmed after MBC determination. Since glycoside-PE interactions have been proposed as the main MoA of this class of bactericidal glycosides in Gram-positive bacteria6, this result suggests that IM disruption could be the prime cause for the observed antimicrobial effects in Gram-negative pathogens as well. Furthermore, better antimicrobial activities were observed when using colistin as an adjuvant agent rather than PMB, but neither of these polymyxins led to a significant increase in glycoside cytotoxicity when tested in HEK-293T and Caco-2 cells at the OM-permeabilizing subtherapeutic concentrations of 0.5 μg/mL and below. On the other hand, compounds 2 and 5 were significantly less toxic than the corresponding α-O-glycoside (1), leading to a calculated in vitro therapeutic index of, at least, 6. Together, our results would suggest that alkyl deoxyglycosides could potentially be used with subtherapeutic concentrations of colistin for the targeting of MDR Gram-negative ESKAPE pathogens labeled as a critical priority by the WHO4, setting the α-anomer C-glycoside 5 and β-anomer O-glycoside 2 as promising lead compounds for further development. Even though according to Dombach et al. another molecule (JD1) has already been shown to interfere with the IM of Gram-negative bacteria in conditions where the OM is compromised27, to the best of our knowledge this is the first study showing the potential of IM-targeting carbohydrate-based compounds for the treatment of infections caused by MDR Gram-negative pathogens of clinical importance. Furthermore, our results corroborate the previously highlighted importance of adjuvant agents in finding new solutions against Gram-negative AMR55,56, and validate the use of subtherapeutic concentrations of polymyxins for this purpose.
Experimental section
General experimental procedures
HPLC-grade solvents and reagents were obtained from commercial suppliers and were used without further purification. Thin-layer chromatography (TLC) was carried out on aluminum sheets (20 × 20 cm) coated with silica gel 60F-254 (0.2 mm thick, Merck) with detection by charring with 10% H2SO4 in ethanol. Column chromatography (CC) was performed using silica gel 230 − 400 mesh (Merck). Nuclear magnetic resonance (NMR) experiments were recorded on a Bruker Avance 400 spectrometer at 298 K, operating at 100.62 MHz for 13C and at 400.13 MHz for 1H for solutions in CDCl3, CO(CD3)2, or CD3OD (Sigma-Aldrich). Chemical shifts are expressed in δ (ppm) and the proton coupling constants J in Hertz (Hz), and spectra were assigned using appropriate COSY, DEPT, HMQC, and HMBC spectra. The high-resolution mass spectra of new compounds were acquired on a HR QqTOF Impact II mass spectrometer (Bruker Daltonics Billerica, MA, USA) interfaced with an ESI source operating in the positive ion mode. Samples were analyzed by flow injection analysis (FIA) using an isocratic gradient 30 A:70 B of 0.1% formic acid in water (A) and in acetonitrile (B), at a flow rate of 10 µL min−1 over 15 min. Internal calibration was achieved with a solution of ammonium formate 10 mM introduced to the ion source via a 20 µL loop at the beginning of each analysis, using a six-port valve. The full scan mass spectra were acquired over a mass range of 100–1000 m/z at a spectra rate of 1 Hz.
Synthesis of methyl 2,3-Di-O-benzyl-4,6-O-benzylidene-α-D-glucopyranoside (6)
To a stirring solution of the commercially available methyl α-D-glucopyranoside (7.0 g, 36.0 mmol) in ACN (35 mL), p-toluenesulfonic acid monohydrate (137.0 mg, 0.72 mmol, 0.02 equiv.) was added, followed by benzaldehyde dimethyl acetal (10.8 mL, 72.0 mmol, 2.0 equiv.). The reaction was stirred at 82 ºC for 19 h. Then, the reaction was cooled to room temperature, washed with a saturated solution of sodium bicarbonate (50 mL), and extracted with DCM (3 × 50 mL). Organic phases were combined, dried with MgSO4, filtered, and concentrated under reduced pressure. The residue was resuspended in a small amount of DCM at 30 ºC, after which cold petroleum ether was added, affording a precipitate that was filtered and dried under vacuum. 4,6-O-benzylidene-α-D-glucopyranoside was hence obtained as a white solid in 91% yield, with physical and spectroscopic data that were in agreement with those previously reported in the literature57. The compound (3.0 g, 10.6 mmol) was then dissolved in DMF (160 mL) at 0 ºC, after which NaH (60%, dispersion in paraffin; 1.70 g, 42.2 mmol, 4 equiv.) was added in small portions over 5 min. Then, benzyl bromide (5.04 mL, 42.4 mmol, 4 equiv.) was added to the mixture, and the reaction was stirred at room temperature for 17 h. The reaction was quenched with MeOH, and the solvent was evaporated. The residue was then resuspended in EtOAc, washed with brine (50 mL), and extracted with EtOAc (3 × 50 mL). Organic phases were combined, dried with MgSO4, filtered, and concentrated under reduced pressure to give a syrup that was purified by CC (Hex/EtOAc 1:0 to 8:1). Compound 6 was obtained as a colorless oil in 91% yield, with physical and spectroscopic data that were in full agreement with the literature58.
Synthesis of methyl 4,6-O-benzylidene-α-D-glucopyranoside (7)
A solution of compound 6 (4.0 g, 8.65 mmol) in 80% (v/v) acetic acid (50 mL) was stirred at 50 ºC for 24 h, after which the solvent was co-evaporated with toluene under reduced pressure. The residue was then resuspended in a small amount of DCM at 30 ºC, cold petroleum was added, and the mixture was left at 0 ºC for 2 h. The so-formed white crystals were filtered and dried under reduced pressure, affording compound 7 in 98% yield. Rf (Hex/EtOAc 1:1) = 0.21; 1H NMR (400.13 MHz, CO(CD3)2 , 25 ºC): δ 7.42–7.24 (m, 10H, Ar–H), 4.88 (AB system, 2H, JA-B = 11.25 Hz, Ar-CH2), 4.80 (d, 1H, J1-2 = 3.51 Hz, H-1), 4.71 (AB system, 2H, JA-B = 12.49 Hz, Ar-CH2), 4.43 (br t, 1H, OH-4), 3.82–3.65 (m, 3H, H-3, H-6a and H-6b), 3.58–3.52 (m, 2H, H-4 and H-5), 3.46 (dd, 1H, J2-1 = 3.53 Hz, J2-3 = 9.59 Hz, H-2), 3.36 (s, 3H, OCH3), 2.86 (d, 1H, J = 13.32 Hz, OH-6); 13C NMR (100.62 MHz, CO(CD3)2, 25 ºC): δ 146.7, 140.0 (Ar-Cq), 129.1, 128.9, 128.54, 128.5, 128.3, 128.0 (Ar–CH), 98.7 (C-1), 82.6 (C-3), 80.9 (C-2), 75.6 (Ar-CH2-3), 73.1 (C-5), 72.9 (Ar-CH2-2), 71.7 (C-4), 62.7 (C-6), 55.0 (O-CH3). HRMS: Calcd. [C21H27O6] 375.1802, found 375.1810 (error -2.0 ppm); Calcd. [C21H26NaO6] 397.1622, found 397.1634 (error -3.0 ppm).
Synthesis of methyl 4,6-dideoxy-α-D-xylo-hexopyranoside (8)
Compound 7 (1.0 g, 2.67 mmol) was dissolved in anhydrous DCM (43 mL) and pyridine (1.0 mL, 12.3 mmol, 4.6 equiv.) under nitrogen atmosphere, and the mixture was cooled down to 0 ºC. Then, trifluoromethanesulfonic anhydride (2.1 mL, 12.3 mmol, 4.6 equiv.) was added dropwise, and the reaction was left stirring for 2 h and 30 min. As starting material was still detected by TLC, another portion of pyridine (2.2 mL, 2.7 mmol, 1 equiv.) and trifluoromethanesulfonic anhydride (0.46 mL, 2.7 mmol, 1 equiv.) was added as previously described, and the mixture stirred for another 3 h and 30 min. The reaction was quenched with cooled distilled water (100 mL), followed by extraction with DCM (3 × 100 mL). Organic phases were combined and dried with MgSO4 filtered, and concentrated under reduced pressure to afford a highly labile brownish oil that was used in the subsequent reaction without further purification. The residue was hence dissolved in toluene (36 mL), and tetra-n-butylammonium borohydride (4.13 g, 16.0 mmol, 6 equiv.) was added. The mixture was stirred at 85 ºC for 1 h and 30 min, cooled down to room temperature, poured into cooled distilled water (100 mL) and extracted with DCM (3 × 100 mL). Organic phases were combined and dried with MgSO4, filtered, and concentrated under reduced pressure. The resulting residue was purified by CC (Hex/EtOAc 10:1 to 9:1) to afford compound 8 as a colorless oil in 88% yield. Rf (CyHex/EtOAc 3:1) = 0.56; 1H NMR (400.13 MHz, CDCl3, 25 ºC): δ 7.40–7.25 (m, 10H, Ar–H), 4.85 (part A of AB system 1, 1H, JA-B = 12.13 Hz, Ar-CH2), 4.74 (AB system 2, 2H, JA-B = 11.63 Hz, Ar-CH2), 4.69 (part B of AB system 2, 1H, JA-B = 11.63, Ar-CH2), 4.63 (d, 1H, J1-2 = 3.55 Hz, H-1), 3.95–3.83 (m, 2H, H-3 and H-5), 3.46 (dd, 1H, J2-3 = 9.45 Hz, J2-1 = 3.61 Hz, H-2), 3.37 (s, 3H, OCH3), 2.07 (ddd, 1H, J4eq-4ax = 12.84 Hz, J4eq-5 = 4.99 Hz, J4eq-3 = 2.30 Hz, H-4 eq), 1.38 (dt, 1H, J4ax-4 eq = 12.60 Hz, J4ax-3 = J4ax-5 = 10.68 Hz, H-4ax), 1.17 (d, 3H, J6-5 = 6.35 Hz, H-6); 13C NMR (100.62 MHz, CDCl3, 25 ºC): δ 139.1, 138.7 (Ar-Cq), 128.5, 128.1, 127.8, 127.7, 127.6 (Ar–CH), 99.1 (C-1), 80.6 (C-2), 75.4 (C-3), 73.3, 72.6 (Ar-CH2), 63.5 (C-5), 55.2 (OCH3), 39.3 (C-4), 21.0 (C-6). HRMS: Calcd. [C21H26NaO4] 365.1723, found 365.1724 (error -0.2 ppm).
Synthesis of dodecyl 2,3-di-O-benzyl-4,6-dideoxy-α/β-D-xylo-hexopyranoside (9)
A solution of 8 (0.89 g, 2.60 mmol) in anhydrous DCM (5 mL) containing Amberlyst 15 beads (0.195 g) and dodecan-1-ol (2.90 mL, 12.95 mmol, 5 equiv.) was stirred at 40 ºC over 40 h. The reaction mixture was then cooled down to room temperature, diluted in DCM (30 mL), filtered, and concentrated under reduced pressure. The resulting residue was purified by CC (Hex/DCM 1:1), affording the inseparable anomeric mixture (1.35:1 α/β) 9 as a colorless oil in 93% yield. Rf (DCM) = 0.6; 1H NMR (400.13 MHz, CDCl3, 25 ºC): δ 7.40–7.26 (m, 23.5H, Ar–H), 4.95 (Part A of AB system, 1H, JA-B = 11.05 Hz, Ar-CH2β), 4.84–4.66 (m, 9.75H, Ar-CH2, H-1α), 4.31 (d, 1H, J1-2 = 7.79 Hz, H-1β), 3.96–3.87 (m, 3.7H, H-1ʹaα, H-3α and H-5β), 3.65–3.39 (m, 7.05H, H-1ʹbα, H-1ʹβ, H-2α, H-3β and H-5α), 3.30 (t, 1H, J2-1 = J2-3 = 7.80 Hz, H-2β), 2.11–2.00 (m, 2.35H, H-4 eq), 1.71–1.58 (m, 5.7H, H-2ʹ and H-4axβ), 1.48–1.26 (m, 46.3H, H-4axα, H-6β and H-3ʹ to H-11ʹ), 1.16 (d, 4.05H, J6-5 = 6.29 Hz, H-6α), 0.89 (t, J12ʹ-11ʹ = 7.07 Hz, H-12ʹ); 13C NMR (100.62 MHz, CDCl3, 25 ºC): δ 139.2, 139.0, 138.9, 138.9 (Ar-Cq), 128.5, 128.4, 128.4, 128.2, 128.0, 127.8, 127.7, 127.6, 127.5 (Ar–CH), 103.9 (C-1β), 97.7 (C-1α), 83.0 (C-2β), 80.9 (C-2α), 78.4 (C-3β), 75.5 (C-3α), 75.0, 73.0, 72.6, 72.4 (Ar-CH2), 70.2 (C-1ʹα or β), 68.0 (C-1ʹα or β), 67.7 (C-5β), 63.6 (C-5α), 39.4 (C-4α), 38.9 (C-4β), 32.1, 30.0, 29.8, 29.8, 29.7, 29.6, 29.6, 29.5, 26.3, 22.8 (C2’ to C11’), 21.1 (C-6β), 21.1 (C-6α), 14.3 (C-12ʹ). HRMS: Calcd. [C32H49O4] 497.3625, found 497.3635 (error -1.9 ppm); Calcd. [C32H48NaO4] 519.3445, found 519.3460 (error -2.8 ppm).
Synthesis of dodecyl 4,6-dideoxy-α/β-D-xylo-hexopyranoside (1,2)
The anomeric mixture 9 (0.838 g, 1.69 mmol) was dissolved in methanol (12 mL). After the addition of Pd/C 10% (29 mg) under N2 atmosphere, triethylsilane (6.45 mL, 40.39 mmol, 23.9 equiv.) was added dropwise and the reaction was stirred at room temperature. After 24 h, the catalyst was filtered off through a pad of Celite, and the solvent was evaporated under reduced pressure, affording an inseparable mixture of anomers as observed by TLC. To allow anomer separation, the residue was dissolved in pyridine (5 mL) and acetic anhydride was added (0.46 mL, 6.76 mmol, 4 equiv.), followed by a spatula tip of DMAP. After stirring for 4 h at room temperature, the reaction reached completion and both anomers were finally visible by TLC. The solvent was removed by co-evaporation with toluene and the residue was purified by CC (Hex/EtOAc 10:1), affording the α anomer as a colorless oil (256 mg, 38% yield), and the β anomer as a white solid (172.7 mg, 26% yield), as previously reported21. Each anomer was then separately dissolved in methanol (100 mg/mL), followed by the addition of a 1 M solution of NaOMe in methanol (0.1 mL per 0.1 mg of substrate). For anomer α, the reaction was stirred at room temperature for 2 h, whereas for anomer β the reaction was stirred at room temperature for 1 h. Both mixtures were neutralized with Amberlite IR-120, filtered and the solvent was evaporated. Both final compounds were found to be pure by TLC; however, to ensure maximum purity, both were purified by CC (EA), affording compound 1 as a white solid in 97% yield and compound 2 as a white solid in quantitative yield, with physical and spectroscopic data that were in full agreement with the literature21. HRMS for compound 1: Calcd. [C18H36NaO4] 339.2506, found 339.2512 (error -1.8 ppm); HRMS for compound 2: Calcd. [C18H36NaO4] 339.2506, found 339.2510 (error -1.1 ppm).
Synthesis of dodecyl 2,6-dideoxy-α-L-arabino-hexopyranoside (3)
Synthesized according to the previously described methodology6. Physical and spectroscopic data are in full agreement with the literature6. HRMS: Calcd. [C18H36NaO4] 339.2506, found 339.2513 (error -2.0 ppm).
Synthesis of dodecyl 2-deoxy-α-D-arabino-hexopyranoside (4)
Synthesized according to the previously described methodology59. Physical and spectroscopic data are in full agreement with the literature59. HRMS: Calcd. [C18H37O5] 333.2636, found 333.2634 (error 0.6 ppm); Calcd. [C18H36NaO5] 355.2455, found 355.2457 (error -0.5 ppm).
Synthesis of 1,3-di-O-acetyl-2-O-benzyl-4,6-dideoxy-α/β-D-xylo-hexopyranoside (10)
To a stirring solution of compound 8 (0.559 g, 1.63 mmol) in acetic acid (5 mL) and acetic anhydride (5 mL) at 0 ºC, H2SO4 97% (90 μL) was added dropwise. The reaction was stirred at 0 ºC for the first 4 h, and at room temperature for another 16 h. The mixture was then washed with a saturated solution of sodium bicarbonate (20 mL), extracted with DCM (2 × 20 mL), then washed with distilled water (20 mL), and again extracted with DCM (3 × 20 mL). Organic phases were combined and dried with MgSO4, filtered, and concentrated under reduced pressure. The resulting residue was purified by CC (Hex/EtOAc 10:1 to 6:1) to afford the anomeric mixture (1:0.3 α/β) 10 as a white solid in 35% yield. Rf (Hex/EtOAc 2:1) = 0.57; 1H NMR (400.13 MHz, CDCl3, 25 ºC): 7.36–7.28 (m, 6.5H, Ar–H), 6.33 (d, 1H, J1-2 = 3.39 Hz, H-1α), 5.60 (d, 0.3H, J1-2 = 8.13 Hz, H-1β), 5.19 (dt, 1H, J3-2 ≈ J3-4ax = 10.34 Hz, J3-4 eq = 4.66 Hz, H-3α), 4.97 (dt, 0.3H, m, H-3β), 4.73–4.54 (m, 2.6H, Ar-CH2), 4.11–4.04 (m, 1H, H-5α), 3.81–3.73 (m, 0.3H, H-5β), 3.56 (dd, 1H, J2-1 = 3.37 Hz, J2-3 = 9.90 Hz, H-2α), 3.44 (t, 0.3H, J2-1 = J2-3 = 8.56 Hz, H-2β), 2.19–2.10 (m, 4.3H, CH3 OAcα and H-4 eq), 2.03 (s, 0.9H, CH3 OAcβ), 2.03 (s, 3H, CH3 OAcα), 1.98 (s, 0.9H, CH3 OAcβ), 1.43–1.33 (m, 1.3H, H-4ax), 1.24 (d, 0.9H, J6-5 = 6.12 Hz, H-6β), 1.17 (d, 3H, J6-5 = 6.12 Hz, H-6α); 13C NMR (100.62 MHz, CDCl3, 25 ºC): δ 170.5 (C = O OAcα), 170.4 (C = O OAcβ), 169.9 (C = O OAcα), 169.3 (C = O OAcβ), 138.3 (Ar-Cqβ), 137.8 (Ar-Cqα), 128.5, 128.5, 127.9, 127.9, 127.8 (Ar–CH), 94.3 (C-1β), 90.6 (C-1α), 79.1 (C-2β), 76.5 (C-2α), 74.8 (Ar-CH2β), 72.8 (C-3β), 72.7 (Ar-CH2α), 69.7 (C-3α), 68.8 (C-5β), 66.1 (C-5α), 37.9 (C-4α), 37.8 (C-4β), 21.3 (CH3 OAc), 21.3 (CH3 OAcα), 21.2 (CH3 OAcβ), 20.9 (C-6α), 20.7 (C-6β). HRMS: Calcd. [C17H22NaO6] 345.1309, found 345.1306 (error 0.8 ppm).
Synthesis of 1,2,3-tri-O-acetyl-4,6-dideoxy-α/β-D-xylo-hexopyranoside (11)
To a stirring solution of compound 8 (0.550 g, 1.61 mmol) in ethyl acetate (10 mL) under N2 atmosphere, Pd/C 10% (53 mg) was carefully added. The reaction mixture was stirred for 3 h under H2 atmosphere, after which the catalyst was filtered off through a pad of Celite, and the solvent evaporated under reduced pressure. The obtained residue was then dissolved in acetic acid (2.26 mL) and acetic anhydride (2.26 mL) at 0 ºC, and H2SO4 97% (40 μL) was added dropwise. The reaction was stirred at 0 ºC for the first 4 h, and then at room temperature overnight. The mixture was washed with a saturated solution of sodium bicarbonate (20 mL) and extracted with DCM (3 × 25 mL). Organic phases were combined and dried with MgSO4, filtered, and concentrated under reduced pressure. As TLC showed that acetylation was not complete, the residue was resuspended in pyridine (13.5 mL) and acetic anhydride (5.5 mL), and the mixture was stirred for 1 h and 45 min. The solvent was removed by co-evaporation with toluene, affording the anomeric mixture (1:0.3 α/β) 11 as a colorless oil in 90% yield over three steps. Rf (Hex/EtOAc 3:1) = 0.57; 1H NMR (400.13 MHz, CDCl3, 25 ºC): 6.27 (d, 1H, J2-1 = 3.56 Hz, H-1α), 5.62 (d, 1H, J2-1 = 7.92 Hz, H-1β), 5.25 (dt, 1H, J3-2 ≈ J3-4ax = 10.44 Hz, J3-4 eq = 5.01 Hz, H-3α), 5.04–4.93 (m, 1.6H, H-3β, H-2α and H-2β), 4.11 (dtd, J5-4ax = 11.70 Hz, J5-6 = 5.98 Hz, J5-4 eq = 2.20 Hz, 1H, H-5α), 3.79 (dtd, J5-4ax = 11.70 Hz, J5-6 = 5.45 Hz, J5-4 eq = 1.94 Hz, 1H, H-5β), 2.23–2.14 (m, 1.3H, H-4eqα and H-4eqβ), 2.13 (s, 3H, OAcα), 2.09 (s, 0.9H, OAcβ), 2.03–2.00 (m, 6.9H, 2 × CH3 OAcα and 2 × CH3 OAcβ), 1.56–1.46 (m, 1.3H, H-4axα and H-4axβ), 1.27 (d, 0.9H, J6-5 = 6.15 Hz, H-6β), 1.27 (d, 3H, J6-5 = 6.36 Hz, H-6α); 13C NMR (100.62 MHz, CDCl3, 25 ºC): δ 170.6 (C = O OAcα), 170.4 (C = O OAcβ), 170.2 (C = O OAcα), 169.9 (C = O OAcβ), 169.5 (C = O OAcα), 169.4 (C = O OAcβ), 92.4 (C-1β), 90.5 (C-1α), 71.5 (C-2β or C-3β), 71.4 (), 70.5 (C-2α), 69.0 (C-5β), 67.8 (C-3α), 66.3 (C-5α), 37.6 (C-4α), 37.6 (C-4β), 21.2, 21.1 (CH3 OAcα), 21.1, 21.1, 20.9 (CH3 OAcβ), 20.8 (CH3 OAcα and C-6α), 20.8 (C-6β). HRMS: Calcd. [C12H19O7] 275.1125, found 275.1118 (error -0.3 ppm); Calcd. [C12H18NaO7] 297.0945, found 297.0950 (error -1.8 ppm).
Synthesis of 1-(3-O-acetyl-2-O-benzyl-4,6-dideoxy-α-D-xylo-hexopyranosyl)prop-2-ene (12)
To a solution of compound 10 (0.173 g, 0.54 mmol) in dry ACN (1 mL), allyltrimethylsilane (0.18 mL, 1.13 mmol, 2.1 equiv.) was added at 0 ºC under N2 atmosphere. Then, boron trifluoride etherate (0.28 mL, 2.25 mmol, 4.2 equiv.) was added in a dropwise manner, and the reaction was stirred for 30 min at 0 ºC. The mixture was then washed with a saturated solution of sodium bicarbonate (5 mL), extracted with DCM (2 × 10 mL), then washed with distilled water (10 mL), and again extracted with DCM (2 × 10 mL). Organic phases were combined and dried with MgSO4, filtered, and concentrated under reduced pressure, and the residue was purified by CC (Hex/Acetone 1:0 to 10:1) to afford compound 12 as a colorless oil in 70% yield. Rf (Hex/EtOAc 5:1) = 0.46; 1H NMR (400.13 MHz, CDCl3, 25 ºC): 7.36–7.28 (m, 5H, Ar–H), 5.85–5.75 (m, 1H, H-2), 5.13–5.06 (m, 3H, H-3 and H-3ʹ), 4.61 (s, 2H, Ar-CH2), 4.08 (dt, 1H, J1ʹ-1a = 10.74 Hz, J1ʹ-2ʹ ≈ J1ʹ-1b = 5.40 Hz, H-1ʹ), 3.88–3.80 (m, 1H, H-5ʹ), 3.60 (dd, 1H, J2ʹ-3ʹ = 9.14 Hz, J2ʹ-1ʹ = 5.50 Hz, H-2ʹ), 2.54–2.39 (m, 2H, H-1), 2.13 (ddd, 1H, J4ʹeq-4ʹax = 12.81 Hz, J4ʹeq-5ʹ = 4.97 Hz, J4ʹeq-3ʹ = 2.49 Hz, H-4ʹeq), 2.04 (s, 3H, CH3 OAc), 1.38 (dt, 1H, J4ʹax-4ʹeq = 12.61 Hz, J4ʹax-3ʹ = J4ʹax-5ʹ = 10.70 Hz, H-4ʹax), 1.15 (d, 3H, J6ʹ-5ʹ = 6.36 Hz, H-6ʹ); 13C NMR (100.62 MHz, CDCl3, 25 ºC): δ 170.7 (C = O OAc), 138.4 (Ar-Cqβ), 135.1 (C-2), 128.5, 127.9, 127.8 (Ar–CH), 117.0 (C-3), 77.6 (C-2ʹ), 73.8 (C-1ʹ), 72.8 (Ar-CH2), 70.5 (C-3ʹ), 63.9 (C-5ʹ), 37.9 (C-4ʹ), 30.7 (C-1), 21.4 (CH3 OAc), 21.1 (C-6ʹ). The presence of a single benzyl group at position 2 was unequivocally confirmed by HMBC. HRMS: Calcd. [C12H24NaO4] 327.1567, found 327.1572 (error -1.5 ppm).
Synthesis of 1-(2,3-di-O-acetyl-4,6-dideoxy-α-D-xylo-hexopyranosyl)prop-2-ene (13)
To a solution of compound 11 (0.43 g, 1.57 mmol) in ACN (3 mL), allyltrimethylsilane (0.65 mL, 3.29 mmol, 2.1 equiv.) was added at 0 ºC under N2 atmosphere. Then, boron trifluoride etherate (0.81 mL, 6.58 mmol, 4.2 equiv.) was added in a dropwise manner, and the reaction was stirred for 3 h at 0 ºC. The mixture was then washed with a saturated solution of sodium bicarbonate (100 mL), extracted with DCM (2 × 100 mL), then washed with distilled water (100 mL), and again extracted with DCM (2 × 100 mL). Organic phases were combined and dried with MgSO4, filtered, and concentrated under reduced pressure, and the residue was purified by CC (CyHex/EtOAc 1:0 to 20:1) to afford compound 13 as a colorless oil in 86% yield. Rf (CyHex/EtOAc 3:1) = 0.49; 1H NMR (400.13 MHz, CDCl3, 25 ºC): 5.77 (ddt, 1H, J2-3trans = 17.12 Hz, J2-3cis = 10.25 Hz, J2-1 = 6.86 Hz, H-2), 5.15–5.06 (m, 3H, H-3 and H-3ʹ), 4.99 (dd, 1H, J2ʹ-3ʹ = 9.36 Hz, J2ʹ-1ʹ = 5.40 Hz, H-2ʹ), 4.18 (dt, 1H, J1ʹ-1a = 10.20 Hz, J1ʹ-2ʹ ≈ J1ʹ-1b = 5.26 Hz, H-1’), 3.87 (dqd, 1H, J5ʹ-4ʹax = 9.09 Hz, J5ʹ-4ʹeq = 6.19 Hz, J5ʹ-6ʹ = 6.25 Hz, H-5ʹ), 2.53–2.44 (m, 1H, H-1a), 2.30–2.23 (m, 1H, H-1b), 2.13 (ddd, 1H, J4ʹeq-4ʹax = 12.92 Hz, J4ʹeq-5ʹ = 5.08 Hz, J4ʹeq-3ʹ = 2.77 Hz, H-4ʹeq), 2.04 (s, 3H, CH3 OAc), 2.03 (s, 3H, CH3 OAc), 1.45 (dt, 1H, J4ʹax-4ʹeq = 13.01 Hz, J4ʹax-3ʹ = J4ʹax-5ʹ = 10.24 Hz, H-4ʹax), 1.18 (d, 3H, J6ʹ-5ʹ = 6.29 Hz, H-6ʹ); 13C NMR (100.62 MHz, CDCl3, 25 ºC): δ 170.5 (C = O OAc), 170.2 (C = O OAc), 134.2 (C-2), 117.3 (C-3), 72.1 (C-1ʹ), 71.5 (C-2ʹ), 68.6 (C-3ʹ), 64.2 (C-5ʹ), 37.3 (C-4ʹ), 31.4 (C-1), 21.2 (CH3 OAc), 21.0 (CH3 OAc), 20.9 (C-6ʹ). HRMS: Calcd. [C13H21O5] 257.1384, found 257.1386 (error -1.0 ppm); Calcd. [C13H20NaO5] 279.1203, found 279.1207 (error -1.6 ppm).
Synthesis of 1-(4,6-dideoxy-α-D-xylo-hexopyranosyl)dodecane (5)
To a solution of 12 (0.157 g, 0.52 mmol) or 13 (0.330 g, 1.30 mmol) in dry DCM (3.1 mL or 7 mL, respectively), the 2nd generation Grubbs-Hoveyda catalyst (10%) was added under N2 atmosphere, followed by undec-1-ene (5.5 equiv.). Each mixture was stirred for 24 h at 40 ºC, and the solvent was evaporated under reduced pressure. To remove the catalyst and the excess of undec-1-ene, a flash CC (Hex/Acetone 10:1 and Hex/EtOAc 3:1, respectively) afforded the metathesis products (3-O-acetyl-2-O-benzyl-4,6-dideoxy-α-D-xylo-hexopyranosyl-dodec-2-ene: 0.170 g, 77% yield; 2,3-di-O-acetyl-4,6-dideoxy-α-D-xylo-hexopyranosyl-dodec-2-ene: 0.480 g, 96% yield) that were used in the following reactions without further characterization. Each compound (0.150 g and 0.430 g, respectively) was then dissolved in EtOAc (5 mL or 6 mL, respectively) under N2 atmosphere, after which Pd/C 10% (20 mg or 57 mg, respectively) was added. The mixtures were stirred under H2 atmosphere at room temperature (for 20 h and 6 h, respectively). Upon reaction completion, the catalyst was filtered off through a pad of Celite, and the solvent was evaporated under reduced pressure, and each crude was individually submitted to deacetylation according to the procedure described for compound 1. After 1 h, both mixtures were neutralized with Amberlite IR-120, filtered and the solvent evaporated. Finally, CC (Hex/Acetone 1:0 to 6:1) afforded compound 5 as a white solid in 56% or 85% overall yield over three steps, respectively. Rf (Hex/Acetone 2:1) = 0.42; 1H NMR (400.13 MHz, CDCl3, 25 ºC): 3.95 (dt, 1H, J1ʹ-1a = 9.80 Hz, J1ʹ-2ʹ ≈ J1ʹ-1b = 5.00 Hz, H-1ʹ), 3.82–3.70 (m, 2H, H-3ʹ and H-5ʹ), 3.62 (dd, 1H, J2ʹ-3ʹ = 9.00 Hz, J2ʹ-1ʹ = 5.91 Hz, H-2ʹ), 2.37 (br d, 2H, OH-2ʹ and OH-3ʹ), 1.98 (ddd, 1H, J4ʹeq-4ʹax = 12.92 Hz, J4ʹeq-5ʹ = 5.02 Hz, J4ʹeq-3ʹ = 2.30 Hz, H-4ʹeq), 1.63–1.51 (m, 2H, H-1), 1.48–1.16 (m, 23H, H-2 to H-11 and H-6ʹ), 0.87 (t, 3H, J6ʹ-5ʹ = 6.65 Hz, H-6ʹ); 13C NMR (100.62 MHz, CDCl3, 25 ºC): δ 76.0 (C-1ʹ), 74.5 (C-2ʹ), 69.0 (C-3ʹ), 64.1 (C-5ʹ), 40.9 (C-4ʹ), 32.1, 29.8, 29.8, 29.8, 29.7, 29.5, 25.9, 24.8, 22.8 (C-2 to C-11), 21.5 (C-6ʹ), 14.3 (C-12). HRMS: Calcd. [C18H37O3] 301.2737, found 301.2742 (error -1.7 ppm); Calcd. [C18H36NaO3] 323.2557, found 323.2563 (error -1.8 ppm).
Bacterial strains and antibacterial activity assays
The E. coli ATCC 25922 and E. coli NCTC 13846 reference strains were used as polymyxin-susceptible and polymyxin-resistant bacterial control strains, respectively. Test strains comprised carbapenem-resistant clinical isolates K. pneumoniae CQ4921, E. cloacae CQ1941, K. pneumoniae CQ1942, K. pneumoniae CQ1947, A. baumannii CQ4322, and P. aeruginosa CQ4924, from INSA’s strain collection. Information on antibiotic susceptibility and resistance mechanisms of each of these strains can be found in Supplementary Table S1 online. In vitro susceptibility to glycosides with or without polymyxins (colistin sulfate and polymyxin B sulfate for microbiological assays, European Pharmacopoeia Reference Standards, Sigma-Aldrich) was assessed by MICs. An in-house broth microdilution method was used in a two-fold concentration series according to the modified method accredited at NRL-AR/HAI and recommended by the EUCAST (2022), which follows the ISO 20776–1 (2006) and ISO 20776–2 (2007). Briefly, antibiotic combinations and controls were prepared at the desired dilutions in 96-well plates. The compounds underwent a serial dilution from 0.1 to 100 µg/mL, while colistin or PMB remained fixed at concentrations of 0.06, 0.125, 0.25 or 0.5 µg/mL. Bacterial cells were added to obtain a final concentration of 5 × 105 CFU/mL and a final volume of 200 µL per well. The preparation of the 96-well plates and the distribution of the inoculum were carried out automatically using the Precision Microplate Pipetting System (Biotek). The plates were incubated at 35 °C for 18 h. The lowest concentration of compound and polymyxin that showed no growth was determined as the combination MIC and the lowest concentration causing at least a 99.9% reduction in CFU/mL compared to the starting inoculum was determined as the combination MBC. All experiments were carried out in triplicate.
The fractional inhibitory concentration index (FICI) of each combination (compound/ polymyxin) was calculated according to the following formula: FICI = [MICA(A+B)/MICA] + [MICB(A+B)/MICB], where MICA(A+B) represents the MIC of compound A within the compound A and compound B combination, while MICB(A+B) represents the MIC of compound B within the same combination. Values of FICI ≤ 0.5 were considered synergistic, from 0.5 to 1.0 were additive, 1.0 to 4.0 were indifferent, and ≥ 4.0 were considered antagonistic28.
Cytotoxicity assays
HEK-293T and Caco-2 cells were grown in RPMI 1640 medium (VWR) supplemented with 10% FBS (Biowest), 1% PenStrep (Sigma Aldrich), and 1% glutamine (Biowest) in a humidified incubator at 37 °C with a 5% CO2 atmosphere. Twice a week, the medium was aspirated, the cells were washed with DPBS (VWR), trypsinized with trypsin–EDTA solution (Biowest), and resuspended in fresh culture medium. The dose-dependent effects of each glycoside or glycoside-polymyxin combination were evaluated by the resazurin cell viability assay49. Polymyxins (colistin sulfate and PMB sulfate for microbiological assays, European Pharmacopoeia Reference Standards, Sigma-Aldrich) were firstly dissolved in sterilized Mili-Q water to a stock concentration of 1 mg/mL, while glycosides were dissolved in DMSO to a stock concentration of 30 mM. 1.5 × 104 cells/well in 96.5 µL of medium were seeded onto 96-well plates and incubated at 37 °C for 24 h. For each compound, ten stock dilutions (with concentrations from 750 to 75 µM) were prepared in fresh medium immediately prior to incubation. 16 µL of each dilution were added to each well so that the final glycoside concentrations ranged from 100 to 10 µM in each row in a final assay volume of 120 µL. In addition, the previously prepared polymyxin stock solutions were diluted in fresh medium, affording new stocks of 8, 4, and 2 µg/mL. The same volume (7.5 µL/well) of PMB or colistin was then added to each row to achieve a final polymyxin concentration of 0.5, 0.25, and 0.125 µg/mL, respectively, regardless of the glycoside concentration. In assays without polymyxin, the same volume (7.5 µL/well) of medium was added. In all assays, the maximum DMSO concentration was 0.33%. After a 72-h incubation at 37 ºC, 12 µL of a 0.15 mg/mL resazurin (Sigma-Aldrich) in sterilized Mili-Q water were added to each well, and the plates were left incubating for another 4 h at 37 ºC. Resorufin was measured at 570/600 nm, and the percentage of resazurin reduction, corresponding to the cell viability percentage, was calculated according to Eq. (1)60. IC50 values were obtained by best fitting the dose-dependent inhibition curves using the Prism 9® software. The results were expressed as the mean ± SD of three independent replicates, with only data from analysis with R2 > 0.90 being considered.
Statistical analysis
Cell viability results were evaluated through a two-way ANOVA followed by a Tukey’s multiple comparisons test using Prism 9® software. Results were considered statistically significant when the p-value was equal to or inferior to 0.05.
Data availability
The data that support the findings of this study are available online in the Supplementary Information of this article.
References
Rehman, S. A. A parallel and silent emerging pandemic: Antimicrobial resistance (AMR) amid COVID-19 pandemic. J. Infect. Public Health. 16, 611–617 (2023).
Murray, C. J. L. et al. Global burden of bacterial antimicrobial resistance in 2019: A systematic analysis. The Lancet. 399, 629–655 (2022).
De Oliveira, D. M. P. et al. Antimicrobial resistance in ESKAPE pathogens. Clin. Microbiol. Rev. 22, e00181. https://doi.org/10.1128/CMR.00181-19 (2022).
World Health Organization. Antibacterial agents in clinical and preclinical development: An overview and analysis. https://www.who.int/publications/i/item/WHO-EMP-IAU-2021.01 (2022).
de Matos, A. M. Recent advances in the development and synthesis of carbohydrate-based molecules with promising antibacterial activity. Eur. J. Org. Chem. 26, e202200919. https://doi.org/10.1002/ejoc.202200919 (2023).
Dias, C. et al. Sugar-based bactericides targeting phosphatidylethanolamine-enriched membranes. Nat. Commun. 9, 4857 (2018).
Epand, R. M. & Epand, R. F. Lipid domains in bacterial membranes and the action of antimicrobial agents. Biochim. Biophys. Acta. 1788, 289–294 (2009).
Sun, J., Rutherford, S. T., Silhavy, T. J. & Huang, K. C. Physical properties of the bacterial outer membrane. Nat. Rev. Microbiol. 20, 236–248 (2022).
Domalon, R., Idowu, T., Zhanel, G. G. & Schweizer, F. Antibiotic hybrids: the next generation of agents and adjuvants against Gram-negative pathogens?. Clin. Microbiol. Rev. 31, e00077. https://doi.org/10.1128/CMR.00077-17 (2018).
MacNair, C. R., Tsai, C. N. & Brown, E. D. Creative targeting of the Gram-negative outer membrane in antibiotic discovery. Ann. N. Y. Acad. Sci. 1459, 69–85 (2020).
Moubareck, C. A. Polymyxins and bacterial membranes: A review of antibacterial activity and mechanisms of resistance. Membranes. 10, 181 (2020).
European Medicines Agency. Assessment Report on Polymyxin-based products (EMA/CHMP/153652/2015). https://www.ema.europa.eu/en/documents/referral/polymyxin-article-31-referral-assessment-report_en.pdf (2015).
Sobieszczyk, M. E. et al. Combination therapy with polymyxin B for the treatment of multidrug-resistant Gram-negative respiratory tract infections. J. Antimicrob. Chemother. 54, 566–569 (2004).
Hussein, M. et al. Polymyxin B combinations with FDA-approved non-antibiotic phenothiazine drugs targeting multidrug-resistance of Gram-negative pathogens. Comput. Struct. Biotechnol. J. 18, 2247–2258 (2020).
French, S. et al. Potentiation of antibiotics against Gram-negative bacteria by polymyxin B analogue SPR741 from unique perturbation of the outer membrane. ACS Infect. Dis. 6, 1405–1412 (2020).
Lim, L. M. et al. Resurgence of colistin: a review of resistance, toxicity, pharmacodynamics, and dosing. Pharmacotherapy. 30, 1279–1291 (2010).
Perez, F., et al. Polymyxins: To Combine or Not to Combine? Antibiotics (Basel). 8, 38. (2019).
Meng, W. et al. Discovery of dapagliflozin: a potent, selective renal sodium-dependent glucose cotransporter 2 (SGLT2) inhibitor for the treatment of type 2 diabetes. J. Med. Chem. 51, 1145–1149 (2008).
Meiers, J. et al. Directing drugs to bugs: Antibiotic-carbohydrates targeting biofilm-associated lectins of Pseudomonas aeruginosa. J. Med. Chem. 63, 11707–11724 (2020).
Sommer, R. et al. Anti-biofilm agents against Pseudomonas aeruginosa: A structure-activity relationship study of C-glycosidic LecB inhibitors. J. Med. Chem. 62, 9201–9216 (2019).
Dias, C. et al. Assessing the optimal deoxygenation pattern of dodecyl glycosides for antimicrobial activity against Bacillus anthracis. Eur. J. Org. Chem. 12, 2224–2233 (2019).
Garegg, P. J., Johansson, R., Ortega, C. & Samuelsson, B. Novel reagent system for converting a hydroxy-group into an iodogroup in carbohydrates with inversion of configuration. Part 3. J. Chem. Soc. Perkin Trans. 681, 681–683 (1982).
Wessel, H.-P., Viaud, M.-C. & Gardon, V. Preparation of 4,6-cyclo-hexopyranoses by palladium-mediated intramolecular cyclodehalogenation. Carbohydr. Res. 245, 233–244 (1993).
Domingues, M. M. et al. Biophysical characterization of polymyxin B interaction with LPS aggregates and membrane model systems. Biopolymers. 98, 338–344 (2012).
Velkov, T. et al. Surface changes and polymyxin interactions with a resistant strain of Klebsiella pneumoniae. Innate Immun. 20, 350–363 (2014).
Khadka, N. K., Aryal, C. M. & Pan, J. Lipopolysaccharide-dependent membrane permeation and lipid clustering caused by cyclic lipopeptide colistin. ACS Omega. 3, 17828–17834 (2018).
Dombach, J. L. et al. A small molecule that mitigates bacterial infection disrupts Gram-negative cell membranes and is inhibited by cholesterol and neutral lipids. PLoS Pathog. 16, e1009119. https://doi.org/10.1371/journal.ppat.1009119 (2020).
Aoki, N. et al. Efficacy of colistin combination therapy in a mouse model of pneumonia caused by multidrug-resistant Pseudomonas aeruginosa. J. Antibimicrob. Chemother. 63, 534–542 (2009).
Mood, E. H. et al. Antibiotic potentiation in multidrug-resistant Gram-negative pathogenic bacteria by a synthetic Peptidomimetic. ACS Infect. Dis. 7, 2152–2163 (2021).
Ghosal, A. & Nielsen, P. E. Potent antibacterial antisense peptide-peptide nucleic acid conjugates against Pseudomonas aeruginosa. Nucleic Acid Ther. 22, 323–334 (2012).
Tao, Y. et al. Colistin treatment affects lipid composition of Acinetobacter baumannii. Antibiotics. 10, 528. https://doi.org/10.3390/antibiotics10050528 (2021).
Vermassen, A. et al. Cell wall hydrolases in bacteria: Insight on the diversity of cell wall amidases, glycosidases and peptidases toward peptidoglycan. Front. Microbiol. 10, 331. https://doi.org/10.3389/fmicb.2019.00331 (2019).
Do, T., Page, J. E. & Walker, S. Uncovering the activities, biological roles, and regulation of bacterial cell wall hydrolases and tailoring enzymes. J. Biol. Chem. 295, 3347–3361 (2020).
Irazoki, O., Hernandez, S. B. & Cava, F. Peptidoglycan muropeptides: Release, perception, and functions as signaling molecules. Front. Microbiol. 10, 500. https://doi.org/10.3389/fmicb.2019.00500 (2019).
Lee, J. Y. et al. Outbreak of imipenemase-1-producing carbapenem-resistant Klebsiella pneumoniae in an intensive care unit. Korean J. Crit. Care Med. 32, 29–38 (2017).
Martin, R. M. & Bachman, M. A. Colonization, infection, and the accessory genome of Klebsiella pneumoniae. Front. Cell Infect. Microbiol. 8, 4. https://doi.org/10.3389/fcimb.2018.00004 (2018).
Wilson, B. M. et al. Carbapenem-resistant Enterobacter cloacae in patients from the US veterans health administration, 2006–2015. Emerg. Infect. Dis. 23, 878–880 (2017).
Manageiro, V. et al. Predominance of KPC-3 in a Survey for Carbapenemase-Producing Enterobacteriaceae in Portugal. Antimicrob. Agents Chemother. 59, 3588–3592 (2015).
Liang, X. et al. Outcomes and risk factors of bloodstream infections caused by carbapenem-resistant and non-carbapenem-resistant Klebsiella pneumoniae in China. Infect. Drug Resist. 15, 3161–3171 (2022).
Chen, K. et al. Risk factors and mortality of carbapenem-resistant Klebsiella pneumoniae bloodstream infection in a tertiary-care hospital in China: an eight-year retrospective study. Antimicrob. Resist. Infect. Control. 11, 161. https://doi.org/10.1186/s13756-022-01204-w (2022).
Chen, J. et al. Carbapenem-resistant Enterobacter cloacae complex in a tertiary hospital in Northeast China, 2010–2019. BMC Infect. Dis. 21, 611. https://doi.org/10.1186/s12879-021-06250-0 (2021).
Liu, S. et al. Molecular mechanisms and epidemiology of carbapenem-resistant Enterobacter cloacae complex isolated from Chinese patients during 2004–2018. Infect. Drug Resist. 14, 3647–3658 (2021).
Tian, X. et al. Carbapenem-resistant Enterobacter cloacae causing nosocomial infections in southwestern China: Molecular epidemiology, risk factors, and predictors of mortality. Infect. Drug Resist. 13, 129–137 (2020).
Shi, Z., Zhao, H., Li, G. & Jia, W. Molecular characteristics of carbapenem-resistant Enterobacter cloacae in Ningxia Province, China. Front. Microbiol. 8, 94. https://doi.org/10.3389/fmicb.2017.00094 (2017).
Pfizer, Inc. Phase 3 studies of Pfizer’s novel antibiotic combination offer new treatment hope for patients with multidrug-resistant infections and limited treatment options. https://www.pfizer.com/news/press-release/press-release-detail/phase-3-studies-pfizers-novel-antibiotic-combination-offer (2023).
Kollef, M. et al. The prospective role of cefiderocol in the management of carbapenem-resistant Acinetobacter baumannii infections: review of the evidence. Int. J. Antimicrob. Agents. 62, 106882. https://doi.org/10.1016/j.ijantimicag.2023.106882 (2023).
Moubareck, C. A. Polymyxins and bacterial membranes: A review of antibacterial activity and mechanisms of resistance. Membranes. 10, 181. https://doi.org/10.3390/membranes10080181 (2020).
Santos, D. E. S., Pol-Fachin, L., Lins, R. D. & Soares, T. A. Polymyxin binding to the bacterial outer membrane reveals cation displacement and increasing membrane curvature in susceptible but not resistant lipopolysaccharide chemotypes. J. Chem. Inf. Model. 57, 2181–2193 (2017).
Lavogina, D. et al. Revisiting the resazurin-based sensing of cellular viability: Widening the application horizon. Biosensors. 12, 196 (2022).
Jangra, M. et al. Purification, characterization and in vitro evaluation of polymyxin A from Paenibacillus dendritiformis: An unexplored member of the polymyxin family. Front. Microbiol. 9, 2864. https://doi.org/10.3389/fmicb.2018.02864 (2018).
Abdelarouf, K. et al. Characterization of polymyxin B-induced nephrotoxicity: Implications for dosing regimen design. Antimicrob. Agents Chemother. 56, 4625–4629 (2012).
Gallardo-Godoy, A. et al. Activity and predicted nephrotoxicity of synthetic antibiotics based on polymyxin B. J. Med. Chem. 59, 1068–1077 (2016).
Wang, J. et al. Comparative study of polymyxin B and colistin sulfate in the treatment of severe comorbid patients infected with CR-GNB. BMC Infect. Dis. 23, 351. https://doi.org/10.1186/s12879-023-08339-0 (2023).
Muller, P. Y. & Milton, M. N. The determination and interpretation of the therapeutic index in drug development. Nat. Rev. Drug Discov. 11, 751–761 (2012).
Troudi, A., Bolla, J. M., Klibi, N. & Brunel, J. M. An original and efficient antibiotic adjuvant strategy to enhance the activity of macrolide antibiotics against Gram-negative resistant strains. Int. J. Mol. Sci. 23, 12457. https://doi.org/10.3390/ijms232012457 (2022).
Kim, S. Y. et al. Exploitation of a novel adjuvant for polymyxin B against multidrug-resistant Acinetobacter baumannii. J. Antimicrob. Chemother. 78, 923–932 (2023).
Demchenko, A. V., Pornsuriyasak, P. & De Meo, C. Acetal protecting groups in the organic laboratory: Synthesis of methyl 4,6-O-benzylidene-α-D-glucopyranoside. J. Chem. Educ. 83, 782–784 (2006).
Beaupere, D., Boutbaiba, I., Menailly, G. & Uzan, R. Déprotection sélective par transfert d’hydrogène, du groupe OH-2 dans le méthyl-2,3-di-O-benzyl-4,6-O-benzylidène-α-D-glucopyranoside. Carbohydr. Res. 180, 152–155 (1988).
Martins, A. et al. Tuning the bioactivity of tensioactive deoxy glycosides to structure: Antibacterial activity versus selective cholinesterase inhibition rationalized by molecular docking. Eur. J. Org. Chem. 2013, 1448–1459 (2013).
de Matos, A. M. et al. Epoxylathyrol derivatives: Modulation of ABCB1-mediated multidrug resistance in human colon adenocarcinoma and mouse T-lymphoma cells. J. Nat. Prod. 78, 2215–2228 (2015).
Acknowledgements
The authors thank INSA for providing the strains from its collection, which were used for the tests carried out in this study. CQE-Ciências is also acknowledged for making available the Cell Culture Facility where cell viability assays were conducted.
Funding
This work was funded by FCT/MCTES (UIDB/00100/2020, LA/P/0056/2020 and UIDB/00211/2020) through national funds. A.M.M. also thanks FCT for funding through the Individual Call for Scientific Employment Stimulus (2022.07037.CEECIND).
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A.M.M. conceptualized the study, analyzed the results and drafted the manuscript. A.M.M., M.M., P.C. and R.A. performed the synthesis. A.P.R. supervised P.C. and A.M.M. supervised M.M. and R.A. M.C.O. conducted HRMS analysis. M.C. and V.M. performed all antimicrobial activity assays. A.M.M. performed cell viability assays and statistical analysis. All authors have read and agreed to the published version of the manuscript.
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de Matos, A.M., Calado, P., Miranda, M. et al. Alkyl deoxyglycoside-polymyxin combinations against critical priority carbapenem-resistant gram-negative bacteria. Sci Rep 14, 2219 (2024). https://doi.org/10.1038/s41598-024-51428-6
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DOI: https://doi.org/10.1038/s41598-024-51428-6
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