Abstract
Antimicrobial resistance has been a growing concern that gradually undermines our tradition treatment regimens. The fact that few antibacterial drugs with new scaffolds or targets have been approved in the past two decades aggravates this crisis. Repurposing drugs as potent antibiotic adjuvants offers a cost-effective strategy to mitigate the development of resistance and tackle the increasing infections by multidrug-resistant (MDR) bacteria. Herein, we found that benzydamine, a widely used non‐steroidal anti‐inflammatory drug in clinic, remarkably potentiated broad-spectrum antibiotic-tetracyclines activity against a panel of clinically important pathogens, including MRSA, VRE, MCRPEC and tet(X)-positive Gram-negative bacteria. Mechanistic studies showed that benzydamine dissipated membrane potential (▵Ψ) in both Gram-positive and Gram-negative bacteria, which in turn upregulated the transmembrane proton gradient (▵pH) and promoted the uptake of tetracyclines. Additionally, benzydamine exacerbated the oxidative stress by triggering the production of ROS and suppressing GAD system-mediated oxidative defensive. This mode of action explains the great bactericidal activity of the doxycycline-benzydamine combination against different metabolic states of bacteria involve persister cells. As a proof-of-concept, the in vivo efficacy of this drug combination was evidenced in multiple animal infection models. These findings indicate that benzydamine is a potential tetracyclines adjuvant to address life-threatening infections by MDR bacteria.
Similar content being viewed by others
Introduction
The prevalence of chromosome or plasmid-conferred resistance determinants has severely impaired the efficacy of clinically available antibiotics, rendering the onset of the global antimicrobial resistance crisis1. Among these pathogenic bacteria, of particular concern are ESKAPE (Enterococcus, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, and Enterobacter species), which are responsible for the majority of nosocomial infections worldwide with high morbidity and mortality2,3. With the increasing incidence of drug resistance in ESKAPE clinical isolates, bacterial infection-associated diseases are becoming harder to treat. Notably, carbapenems, colistin, and tigecycline are recognized as extremely crucial antibiotics and last options against these drug-resistant bacteria. However, the emergence of carbapenemase4, mcr-1-encoded phosphoethanolamine transferase5, and tet(X)-mediated flavin-dependent monooxygenase6,7 in bacteria from animal and human source leaves few choices for clinicians from these traditional pipelines. Meanwhile, few novel antibiotic entities with distinct scaffolds or modes of action have been approved for clinical use during the past decades due to the huge scientific and commercial challenges in the development of new drugs8,9. There is a dire need to identify alternative strategies to address these infections.
Repurposing drugs as potential antibiotic adjuvants to reverse antibiotic resistance and enhance antibiotic activity represents a simple but effective approach to counter this problem10,11,12. For example, our previous studies have shown that hypoglycemic agent metformin could resensitize tet(A)-positive bacteria to tetracyclines through disrupting the functions of efflux pumps13. Melatonin, which has been applied for treating sleep disturbances and circadian disorders, potentiated colistin activity against MCR-positive bacteria by enhancing the membrane damage14. Anti-HIV agent azidothymidine decreased Tet(X3/X4)-mediated bacterial resistance to tigecycline in Escherichia coli via specifically inhibiting DNA synthesis and suppressing resistance enzyme activity15,16. In addition, other compounds such as natural products or synthetic drugs have also been demonstrated to enhance the activity of existing antibiotics. The condensed tannins of American cranberry fruit, cranberry proanthocyanidin, increased the activity of a broad range of antibiotic classes against opportunistic pathogens by interfering with intrinsic resistance mechanisms17. Synthetic tobramycin−lysine conjugates displayed a synergistic effect with minocycline or rifampicin against clinical multidrug-resistant (MDR) P. aeruginosa isolates18. Benzydamine is a locally acting nonsteroidal anti-inflammatory drug with local anesthetic and analgesic properties by selectively binding to prostaglandin synthetase19,20. Recently, benzydamine was found to inhibit osteoclast differentiation and bone resorption via down-regulating the expression of interleukin-1β21. In addition, benzydamine drastically reduced oral mucositis even at doses >50 Gy in head and neck cancer patients22. However, the adjuvant potential of benzydamine to existing antibiotics is still not fully understood.
In this study, we characterized the synergistic activity of benzydamine with different classes of antibiotics, and found that it drastically potentiated tetracyclines activity against various MDR pathogens. Importantly, benzydamine dissipated membrane potential (▵Ψ) in both Gram-positive and negative bacteria, which in turn upregulated the transmembrane proton gradient (▵pH) and promoted the uptake of tetracyclines. Meanwhile, benzydamine synergized with doxycycline on killing a spectrum of bacterial pathogens carrying mecA, blaMBL and/or mcr genes, as well as tet(X) by triggering oxidative damage. Notably, benzydamine potently rescued the activity of doxycycline in multiple animal infection models infected by MDR MRSA T144 or E. coli B2. This study reveals the therapeutic potential of benzydamine as an antibiotic adjuvant for the treatment of infection caused by MDR pathogens.
Results
Benzydamine potentiates doxycycline activity in both drug-susceptible and -resistant bacteria
We first evaluated the synergistic activity of benzydamine with eight classes of antibiotics against MDR E. coli B2 using checkerboard broth microdilution assays. Out of these drugs, colistin, ciprofloxacin, and doxycycline showed synergistic activity with benzydamine, whereas kanamycin displayed an antagonistic effect with benzydamine (Supplementary Fig. 1 and Supplementary Table 2). Remarkably, the combination of benzydamine and doxycycline possessed the highest synergistic effect (FIC index (FICI) = 0.188), which enabled the MIC value of doxycycline to decrease from 32 to 2 μg/mL (16-fold). We further tested the potentiation of benzydamine to other tetracyclines, including tetracycline, oxytetracycline, minocycline, and tigecycline. As expected, their antibacterial activity was all substantially improved in the presence of benzydamine (Supplementary Table 2). Subsequently, the checkerboard assays were performed in both drug-susceptible and -resistant bacteria. Interestingly, the combination of benzydamine and doxycycline showed synergistic effect in all test bacteria, including hard-to-treat pathogenic bacteria methicillin-resistant Staphylococcus aureus (MRSA) T144 (FICI = 0.188), vancomycin-resistant enterococci (VRE) A4 (FICI = 0.375), blaNDM-5-positive E. coli G6 (FICI = 0.375), mcr-1-carrying K. pneumoniae D120 (FICI = 0.375) and tet(X6)-positive A. baumannii C222 (FICI = 0.5). In detail, the MIC values of doxycycline in drug-susceptible bacteria (including S. aureus ATCC 29213, E. coli ATCC 25922, S. Enteritidis ATCC 13076, and E. coli MG1655) were all lower than 2 μg/mL. And in the presence of 0.25× MIC of benzydamine, the MICs of doxycycline were decreased by 4-fold. In contrast, the MICs of doxycycline in drug-resistant pathogens ranged from 16 to 32 μg/mL, which dropped sharply to 1–8 μg/mL at 0.25× MIC of benzydamine, corresponding 4–16-fold potentiating. Overall, this combination displayed a higher synergistic effect on drug-resistant bacteria than -susceptible bacteria, suggesting that its activity is also related to the inhibition of resistance determinants (Fig. 1 and Supplementary Table 3).
Next, we assessed whether the synergistic activity of this combination would result in increased toxicity, including hemolytic activity on mammals RBCs and in vivo toxicity in mice23. Surprisingly, no detectable toxicity in hemolysis rate, body weight, and blood biochemical analysis was found in the benzydamine–doxycycline combination treatment (Supplementary Figs. 2 and3). These data suggest that benzydamine is a safe and potent antibiotic adjuvant to tetracyclines.
Benzydamine dissipates the electric potential (ΔΨ) component of the proton motive force and promotes the uptake of doxycycline
Our prior results have shown that benzydamine is a universal adjuvant to tetracycline antibiotics in all tested strains, but antagonizes kanamycin activity in E. coli B2. We next assessed the interaction of benzydamine and kanamycin in a panel of bacteria. As a consequence, a remarkable antagonism effect was found in all bacteria (FICI > 2.0, Supplementary Fig. 1 and 4). The opposite effect of benzydamine in combination with doxycycline or kanamycin inspired us to speculate that the mechanism of action of benzydamine may be directly related to the destruction of the bacterial proton motive force (PMF)24. In bacteria, the transmembrane transfer of proton H+ by the respiratory chain results in an electrochemical gradient, named PMF. It consists of two parts, electric potential (ΔΨ) and transmembrane proton gradient (ΔpH)25. Damage to one will be compensated by increasing another to achieve dynamic balance26. Previous studies have indicated that the uptake of tetracyclines by bacterial cells depends on ΔpH, whereas aminoglycosides utilize the ΔΨ component for transport, therefore, we are concerned that benzydamine might target the ΔΨ component of bacterial PMF. To test our hypothesis, a fluorescent probe 3,3'-dipropylthiadicarbocyanine iodide (DiSC3(5))27 was used to assess membrane potential changes induced by doxycycline, benzydamine alone, or their combination in four representative strains (S. aureus ATCC 29213, MRSA T144, E. coli ATCC 25922 and E. coli B2; two Gram-positive and two Gram-negative bacteria). Consequently, no obvious fluorescence change was observed in the doxycycline treatment group. In contrast, benzydamine treatment resulted in rapid disruption of electric potential in a dose-dependent manner (Fig. 2a). Next, we measured the fluorescence with one to fourfold MIC of doxycycline or combination with 250 μg/mL of benzydamine. Benzydamine plus doxycycline indeed resulted in increased fluorescence compared with doxycycline alone (Fig. 2b), suggesting that benzydamine is definitely a potential dissipator of ΔΨ. The extracellular pH values are also related to the PMF. A previous study demonstrated that the antibacterial activity of the dissipater of ΔΨ will be strengthened when the extracellular pH changed to the alkaline values28. Consistent with the membrane potential results, the MICs of benzydamine were reduced by four to eightfold when the pH changed from 5.5 to 9.5 in both Gram-negative bacteria and Gram-positive bacteria (Fig. 2c). An intact PMF is required for the bacterial function in flagellar secretion, thus, we next examined the integrity of PMF through swimming motility experiments29. Exposure of four strains to sub-inhibitory concentrations of benzydamine drastically decreased bacterial motility (Fig. 2d), suggesting the impaired PMF in benzydamine-treated bacterial cells. These evidence demonstrates that benzydamine disrupts the PMF by targeting ΔΨ component.
After showing that benzydamine selectively disrupted the ΔΨ, we set out to test whether ΔpH will be compensatorily upregulated. A membrane-permeable fluorescent probe termed BCECF-AM30 was used to monitor intracellular pH changes in four strains. Interestingly, benzydamine led to the acidification of the cytoplasm in Gram-positive bacteria, but alkalization of cytoplasm in Gram-negative bacteria (Fig. 3a). Nevertheless, both these actions triggered the upregulation of ΔpH in bacteria. Given that the increasing ΔpH may contribute to the uptake of tetracyclines, thus we next determined the intracellular doxycycline accumulation after exposure to varying concentrations of benzydamine31. As expected, benzydamine supplementation remarkably enhanced the content of doxycycline in four strains (Fig. 3b). Tetracyclines act by specifically binding to the 30S subunit of the ribosome, thus inhibiting bacterial protein synthesis32. Therefore, the uptake and accumulation of tetracyclines are of importance for their antibacterial activity. Collectively, our results indicate that benzydamine dissipates the ΔΨ, in turn, upregulates the ΔpH, thereby promoting the uptake of tetracyclines.
Doxycycline plus benzydamine is bactericidal against MDR bacteria and biofilm-producing bacteria
It has been widely acknowledged that tetracyclines belong to bacteriostatic antibiotics. We reasoned whether the benzydamine–doxycycline combination would possess bactericidal activity, which would markedly extend its therapeutic potential. To test this hypothesis, we performed time-killing experiments on various MDR pathogens. Impressively, a direct synergistic bactericidal effect was observed in rich growth conditions (Fig. 4a). Specifically, either 32 μg/mL doxycycline or 250 μg/mL benzydamine showed slight bactericidal activities. In comparison, the combination of doxycycline plus benzydamine (32 + 250 μg/mL) exhibited excellent bactericidal activity, especially for E. coli B2. Besides, to determine whether benzydamine has the potency to combat metabolically repressed and non-replicating cells, we tested the bactericidal activity of this drug combination in the nutrient-free buffer. Remarkably, this combination retained potent bactericidal activity against E. coli B2 (Fig. 4b).
The formation of antibiotic-tolerant biofilms greatly affects the efficacy of antibiotics33,34. To explore whether benzydamine supplementation can enhance doxycycline activity against the biofilm-producing bacteria, we performed the formation and eradication of biofilms experiments in the presence or absence of different concentrations of benzydamine. As shown in Supplementary Fig. 5a, b, the combination of benzydamine at 50 μg/mL with sub-MIC of doxycycline significantly inhibited biofilm formation of MRSA T144 and E. coli B2. Notably, in the biofilm inhibition assay, the benzydamine plus doxycycline at concentrations of ≤2 μg/mL did not have bacteriostatic activity against two test strains, indicating that the inhibition of biofilm formation at these concentrations was not owing to the effect on bacterial growth. Besides, in the presence of benzydamine, the eradication effect of doxycycline on mature biofilm was markedly enhanced (Supplementary Fig. 5c, d). Taken together, we unexpectedly found that the combination of doxycycline plus benzydamine displays great bactericidal activity against various MDR pathogens in different metabolic states, including metabolically active cells, antibiotic-tolerant cells, and biofilm-producing bacteria.
Benzydamine aggravates oxidative damage and inhibits the function of MDR efflux pumps
Having shown that the synergistic bactericidal activity of the benzydamin–doxycycline combination, we reasoned that benzydamine may trigger other unknown modes of action except for the promotion of doxycycline uptake. To explore the underlying mechanisms, we performed transcription analysis of E. coli B2 under treatment with doxycycline or doxycycline plus benzydamine for 4 h. The comparison of treatment with combination to doxycycline alone revealed an upregulation of 35 differentially expressed genes (DEGs) and downregulation of 14 DEGs (Supplementary Fig. 6a). Go annotation analysis showed that these DEGs were involved in biological processes, cellular components, and molecular functions (Supplementary Fig. 6b). KEGG enrichment analysis displayed that these DEGs with increased expression were involved in ribosome synthesis, and DEGs with repressed expression was associated with glutamate metabolism and GABA shunt (Supplementary Fig. 6c, d). Notably, genes with 30S and 50S subunits were upregulated, which may be caused by increased accumulation of doxycycline that inhibits protein synthesis (Fig. 5a). In contrast, multidrug efflux pumps-related genes, glutamate decarboxylase (GAD) system-associated genes, and acid resistance-related genes were obviously decreased in the combination treatment group (Fig. 5b).
Based on the transcription results, we next performed a series of phenotype experiments to elucidate the other functions of benzydamine. First, we evaluated the activity of drug combinations in the different pH growth environments via time-killing experiments. We found that it had almost no bactericidal effect in the acid media, however, this combination showed enhanced bactericidal activity while a change in pH to alkaline values. After treatment for 4 h, the bacteria were all killed in the MHB broth at pH 8.5 and 9.5 (Fig. 6a). These data were in agreement with the previous observations that the antibacterial activity of benzydamine was strengthened in the alkaline conditions and the genes associated with acid resistance were downregulated. Recently, several studies reported that GAD systems, which were downregulated in the combination group, play a critical role in protecting bacteria against oxidative stress35,36, we hypothesized that the potentiation of benzydamine to antibiotics may also correlate to enhanced oxidative damage. Thus, we tested the generation of reactive oxygen species (ROS)37 in E. coli B2 treated by either benzydamine or in combination with doxycycline. Surprisingly, benzydamine markedly promoted the generation of ROS in a dose-dependent manner (Fig. 6b). Meanwhile, the combination treatment showed higher ROS levels compared to doxycycline monotreatment (Fig. 6c). Accordingly, ROS has been recognized as one of the common mechanisms in the antibiotic-mediated killing of bacteria. The over-production of ROS in the benzydamine–doxycycline combination gives an interpretation of their synergistic bactericidal activity. To further verify it, N-acetyl-l-cysteine (NAC), a ROS scavenger, was added in time-killing assays. As shown in Fig. 6d, the potentiation of benzydamine to doxycycline was greatly impaired when incubation with 2 or 4 mM NAC. Finally, we used a fluorescent dye rhodamine B to assay the function of the efflux pump in bacteria under the treatment of benzydamine (Fig. 6e). As a result, it showed that the activity of the efflux pump was dose-dependently suppressed by benzydamine, which further promoted the accumulation of doxycycline in MDR bacteria. Collectively, these data together demonstrate that benzydamine enhances oxidative damage via triggering the production of ROS and inhibiting the function of MDR efflux pumps (Fig. 6f).
Benzydamine rescues doxycycline efficacy in vivo infection models
In view of the excellent synergy of doxycycline and benzydamine against MDR pathogens in vitro, we tested whether they have potent activity in vivo using two animal infection models infected by MRSA T144 or E. coli B2. First, we used G. mellonella larvae infection models to explore their efficacy in vivo. As shown in Fig. 7a, the infected larvae with the combination therapy of doxycycline plus benzydamine (50 + 50 mg/kg) resulted in above 80% survival during 5 days, which was higher than the doxycycline monotreatment (P = 0.0174 or 0.0397, corresponding to MRSA T144 and E. coli B2, respectively). In addition, the efficacy of this combination therapy in a neutropenic mouse thigh infection model was evaluated (Fig. 7b). Similarly, a single dose of doxycycline plus benzydamine (50 + 10 or 50 + 50 mg/kg) reduced bacterial burden in mice thighs compared with doxycycline alone (P < 0.0001). These data demonstrate the benzydamine plus doxycycline has a great synergy effect in vivo.
Discussion
The occurrence of MDR phenotype in pathogenic bacteria undermines the clinical efficacy of antibiotics and leaves no available options for the treatment of intractable infections38,39. Despite many ongoing effects in identifying new classes of antimicrobial agents40,41, few antibiotics have been approved for clinical use in the past 20 years. Accordingly, the average cost of research and development of a new drug from discovery to regulatory approval is US$2.6 billion, which takes >10 years, and the successful launch is less than one thousandth42,43. As such, alternative strategies are warranted to confront this serious global crisis. Repurposing non-antibacterial drugs as potential antibiotic adjuvants are gaining traction in both the public and private sector44. In this study, we revealed the synergistic effect of benzydamine, a widely used non‐steroidal anti‐inflammatory drug in the clinic, in combination with three classes of antibiotics against MDR E. coli B2. Most importantly, benzydamine displayed the greatest synergistic activity with tetracyclines, which belong to broad-spectrum antibiotics. For various MDR pathogens, including MRSA, VRE, NDM/MCR/Tet(X)-expressing Gram-negative bacteria, the doxycycline–benzydamine combination showed unprecedented synergistic activity. Biofilm-producing bacteria are important causes of chronic and recurrent bacterial infection but are commonly overlooked in drug discovery. We found that the doxycycline–benzydamine combination is able to prevent the formation of S. aureus and E. coli biofilm, as well as eradicate the established biofilms. These data further support the notion that benzydamine is a potential antibiotic adjuvant candidate to reverse bacterial resistance. Consistent with our finding, the prior study provided a preliminary observation regarding the antibacterial activity of the benzydamine-tetracyclines combination, whereas the antibacterial spectrum, mechanisms of action, and in vivo potency are not explored45.
Bacterial energy metabolism such as PMF has a critical role in cellular activities including material transport, flagellar motility, and ATP synthesis by the F1F0-ATPase46. The disruption of PMF would inhibit the basic functions of bacteria and accelerate its death. Recently, using a deep learning approach, a new broad-spectrum antibiotic termed halicin was identified to selectively destroy the PMF47. Molecules I1- I3 and D1-D3, the potential modulators of PMF, showed killing activity against MRSA by preventing electron transport and ATP synthesis28. Generally, PMF is comprised of ΔΨ and ΔpH. To maintain the bacterial PMF, dissipation of either component would be compensatory increased by another. In our study, we uncovered that benzydamine dissipated the ΔΨ component of PMF in both Gram-positive and Gram-negative bacteria, in turn, increased the ΔpH, which was critical for the uptake of tetracyclines. These findings were consistent with the previous studies that tetracyclines uptake is driven by ΔpH48, whereas aminoglycosides uptake is highly dependent on ΔΨ49. In addition, the successful paradigm of daptomycin depolarizing the cytoplasmic membrane provides a proof-of-concept for PMF-targeted antimicrobial agents50. These examples suggest that bacterial PMF is a promising target for the development of novel antimicrobial agents and antibiotic adjuvants. Toxicity concerns are critical factors that limit the clinical trials of new drugs51. Meaningfully, our experiments tentatively demonstrated that the combination of doxycycline and benzydamine exhibited negligible toxicity in a murine model. Nevertheless, considering the potential side effects of benzydamine in clinic such as nausea and vomiting52, more preclinical studies are needed for exploring the therapeutic potential of this particular combination. Moreover, we proposed that the structure optimization of benzydamine and the use of functionalized drug delivery system53 may contribute to reducing the toxicity and improving the effectiveness of this drug combination.
Furthermore, the doxycycline–benzydamine combination showed excellent synergistic bactericidal activity for all test MDR isolates, implying that the action of benzydamine is not merely to promote the uptake of tetracyclines. Transcriptomic analysis coupled with phenotype experiments indicated that benzydamine not only triggered the generation of ROS, but also downregulated the GAD system that protects bacteria from oxidative damage. These modes of action resulted in an oxidative burst, which has been proved to be important for antibiotic-mediated killing. In addition, the functions of MDR efflux pumps in bacteria were severely destroyed, partly owing to the dissipation of PMF by benzydamine. It would be interesting to investigate the potential of benzydamine as a new and broad-spectrum inhibitor of MDR efflux pumps.
To conclude, our findings reveal that non‐steroidal anti‐inflammatory drug benzydamine may serve as a potential antibiotic adjuvant to restore the activity of clinically relevant antibiotics particularly tetracyclines against infections caused by MDR pathogens. In addition, the elucidation of modes of action of benzydamine highlights the remarkable potential of PMF downregulators as a feasible adjuvant therapy to tackle the escalating concern of antibiotic resistance.
Materials and methods
Bacterial strains and reagents
All strains used in this study were listed in Supplementary Table 1. The bacteria were stored in nutrient broth supplemented with 20% (v/v) glycerol at −80 °C. For experiments, all strains were grown in Mueller-Hinton Broth (MHB) or on LB agar (LBA) plates. Antibiotics were obtained from China Institute of Veterinary Drug Control and other chemical reagents were purchased from Aladdin (Shanghai, China) or TCI (Shanghai, China).
MIC determinations
The MICs of all antibiotics and benzydamine were determined using the broth dilution method, according to the CLSI 2018 guideline54. All drugs were twofold diluted in MHB and equally mixed with bacterial suspensions in a 96-well microtiter plate (Corning, New York, USA). After 16–20 h incubation at 37 °C, the MICs were defined as the lowest concentrations of drugs that no bacteria can be detected.
Checkerboard analyses and FIC index determination
The fractional inhibitory concentrations (FIC) indices were measured by the checkerboard analyses55. In brief, 100 μL of MHB was added into each well of a 96-well plate with an 8 × 8 matrix, then the antibiotics and compounds were twofold diluted along the abscissa and ordinate, respectively. After incubated at 37°C for 18 h with bacterial suspension (105 CFUs/well), the absorbance of each well at 600 nm was determined. The FIC was calculated as the MIC when the compound is used in combination divided by the MIC when it is used alone. The FICI is the sum of the FICs of two compounds, and synergy is defined with the FIC index ≤0.5.
Hemolysis analysis
Hemolytic activity of doxycycline or in combination with benzydamine was assessed based on a previous study56. In brief, 8% of sheep blood cells were equal to volume incubated with 0–256 μg/mL doxycycline alone or in combination with 250 μg/mL benzydamine at 37 °C for 1 h. Phosphate buffer saline (PBS) and double-distilled water were used as a negative and positive control, respectively. The absorbance of released hemoglobin was determined at 576 nm using an Infinite M200 Microplate reader (Tecan, Männedorf, Switzerland). Hemolysis rate (%) was calculated by the result of absorbance of the sample subtracting the negative control divided by the positive control subtracting the negative control.
In vivo toxicity of benzydamine–doxycycline combination
The in vivo toxicity was evaluated by gavaging a combination of doxycycline plus benzydamine (10 + 10 mg/kg) to female CD-1 mice (n = 6 per group). Mice were continuously gavaged for 6 days and body weights were recorded daily. On the seventh day, blood was collected for blood biochemical tests and cell analysis.
Inhibition of biofilm formation
MRSA T144 and E. coli B2 suspensions (1 × 107 CFUs per mL) were exposed to doxycycline solutions (final concentrations ranging from 0.125 to 2 μg/mL) in the presence or absence of 50 μg/mL benzydamine. As a negative control, bacteria were exposed to MHB without drugs. Bacteria were grown for 36 h at 37 °C under static conditions, and then 300 μL PBS was used to remove the planktonic bacteria. Then, 200 μL of methanol was added to fix for 15 min, after that, the fixative was aspirated to air dry and 0.1% crystal violet was added for staining for 15 min. The dye solution was removed and stained-biofilm was washed three times with PBS and dried naturally. At last, crystal violet-stained biofilms were solubilized with 33% glacial acetic acid (100 μL) and incubated at 37 °C for 30 min. Biofilm mass was determined by monitoring the absorbance of the supernatant at 570 nm57.
Biofilm eradication assay
Overnight MRSA T144 and E. coli B2 were diluted 1:100 into MHB and incubated at 37 °C with sharking at 200 rpm for 6 h. Subsequently, 100 μL bacterial suspensions were mixed with an equal volume of MHB in 96-well microtitre plate. After 36 h incubation at 37 °C, the planktonic bacteria were removed. Next, biofilms were treated with 32–256 μg/mL doxycycline alone or in combination with 50 μg/mL benzydamine. After 2 h incubation at 37 °C, the remaining cells were dispersed via ultrasonic treatment for 20 min. Finally, the mixed liquor was resuspended in sterile PBS and then the dilutions were plated on LBA plates and incubated overnight at 37 °C.
Measurement of membrane potential
The membrane potential of S. aureus ATCC 29213, MRSA T144, E. coli ATCC 25922, and E. coli B2 was tested by the fluorescent probe DiSC3(5) (Aladdin, Shanghai, China). Bacterial cells were grown to the log phase in MHB, then washed with PBS to an OD600 of 0.5 and incubated with DiSC3(5) (0.5 × 10−6 M) for 30 min. Finally, varying concentrations of benzydamine (10 μL) were added into the 190 μL of DiSC3(5)-loaded cells. For all membrane potential experiments, the fluorescence intensity was measured with the excitation wavelength at 622 nm and emission wavelength at 670 nm using a Microplate reader (Tecan, Männedorf, Switzerland).
Swimming motility experiment
In all, 0.3% (w/v) agar media composed of trypticase peptone (10 g/L), NaCl (10 g/L), and yeast extract (5 g/L) was used to assess bacterial swimming motility31. After the medium reached 50 °C, the final concentrations of benzydamine at 0, 31.25, 62.5, 125, and 250 μg/mL were added. A 2 µL volume of S. aureus 29213, MRSA T144, E. coli 25922, and E. coli B2 culture at an OD600 of 0.5 was placed in the center of each plate and allowed to stay for 30 min. The plates were placed in a 37 °C incubator for 48 h.
Measurement of intracellular pH values
Overnight S. aureus ATCC 29213, MRSA T144, E. coli ATCC 25922, and E. coli B2 were resuspended to OD600 of 0.5 with PBS, and the final concentration of pH-sensitive fluorescent probe BCECF-AM30 (2 × 10−6 M for Gram-negative bacteria and 0.5 × 10−6 M for Gram-positive bacteria) was added. After incubation for 30 min, four strains were treated with the final concentration of benzydamine (125–1000 μg/mL). The fluorescence intensity was immediately monitored with the excitation wavelength of 488 nm and emission wavelength of 535 nm.
Uptake of doxycycline
Doxycycline uptake was evaluated by monitoring the fluorescence change of the drug in bacteria31. Culture of MRSA T144 and E. coli B2 were grown to an OD600 of 0.5. Cells were centrifuged at 3500 rpm for 10 min and washed in an equal volume of PBS three times. Subsequently, doxycycline at MIC alone or with a final concentration of benzydamine at 250–1000 μg/mL was added into the 96-wells plates containing cell suspensions at 100 µL/well. An infinite Microplate reader was used to monitor the fluorescence intensity with the excitation wavelength of 405 nm and emission wavelength of 535 nm.
Measurement of ROS levels
The fluorescence probe 2′,7′-dichlorodihydrofluorescein diacetate (DCFH-DA, 10 μM)58 (Beyotime, Shanghai, China) was used to test the levels of ROS in E. coli B2 treated by benzydamine, doxycycline, or their combination. After incubation 1 h, the fluorescence intensity was detected with the excitation and emission wavelength of 488 and 525 nm, respectively.
Efflux pump assay
A fluorescence dye, rhodamine B59 has been applied to assay the inhibition of efflux pump of E. coli B2 and MRSA T144 treated by benzydamine. Bacterial cells were grown in MHB broth to mid-log phase (OD600 = 0.5) at 37 °C with shaking 200 rpm, then the cultures were washed and suspended with PBS. Subsequently, a final concentration of rhodamine B (Aladdin, Shanghai, China) (5 × 10−6 M) was added. After incubation at 37 °C for 30 min, the cultures were washed and suspended with PBS containing 1% glucose. Next, probe labeled cells were treated with varying concentrations of benzydamine. After incubation at 37 °C for 30 min, bacterial cells were centrifuged at 6000 rpm at 4 °C for 5 min and the supernatant was collected for fluorescence analysis with the excitation wavelength of 540 nm and emission wavelength of 625 nm.
Time-dependent killing curves
Overnight culture of E. coli B2, K. pneumoniae D120 (mcr-8), A. baumannii C222 (tet(X6)), MRSA T144, and VRE A4 were diluted 1/1000 in MHB, and incubated for 4 h at 37 °C with sharking at 200 rpm. Bacteria were then treated with either PBS, doxycycline (16 or 32 μg/mL), or benzydamine (250 μg/mL) alone or their combination. At the time points 0, 4, 8, 12, and 24 h, 100 μL aliquots were removed, centrifuged, and resuspended in sterile PBS, the dilutions were plated on LBA plates, and incubated overnight at 37 °C.
Transcriptomic analysis
The final concentration of doxycycline (32 μg/mL) alone or in the combination with benzydamine (250 μg/mL) was added to the early exponential-phase E. coli B2. After incubation for 4 h, the total RNA of culture was extracted by an EASYspin Plus kit (Aidlab, Beijing, China) and quantified by using a Nanodrop spectrophotometer (Thermo Scientific, MA, USA). Subsequently, sequenced on Hiseq2000 with Truseq SBS Kit v3‐HS (200 cycles) (Illumina) with the read length as 2 × 100 (PE100). Raw sequencing reads were filtrated and mapped against the reference genome of E. coli K-12. The FPKM (Fragments Per Kilobase of transcript per Million mapped reads) method was used to identify differentially expressed genes with p values ≤0.05 and fold change (FC) values ≥2 (log2 FC ≥ 1 or log2 FC ≤ −1). Differences between these two treatments were studied by Cuffdiff program (http://cufflinks.cbcb.umd.edu/).
Galleria mellonella infection model
Galleria mellonella larvae (Huiyude Biotech Company, Tianjin, China) were divided into four groups (n = 8 per group) and infected with MRSA T144 (106 CFUS) or E. coli B2 (107 CFUS) suspension. After 1 h post infection, group 1 was subjected to PBS treatment, groups 2 and 3 were treated with doxycycline or benzydamine (50 mg/kg) respectively, group 4 was treated with doxycycline plus benzydamine (50 + 50 mg/kg). Survival rates of Galleria mellonella larvae were recorded for 5 days.
Neutropenic mouse thigh infection model
6–8-week-old female CD-1 mice were obtained from the Comparative Medicine Centre of Yangzhou University (Jiangsu, China). Mice studies were performed in accordance with the relevant guidelines of Jiangsu Laboratory Animal Welfare and Ethical of Jiangsu Administrative Committee of Laboratory Animals (permission number, SYXKSU-2007-0005). The laboratory animal usage license number is SCXK-2017-0044, certified by Jiangsu Association for Science and Technology.
Female CD-1 mice (n = 6 per group) were treated with cyclophosphamide with 150 mg/kg in the 4 days before infection, and 100 mg/kg in the 1 day before infection. The exponential-phase MRSA T144 or E. coli B2 suspension (100 μL, 105 CFUs per mouse) was injected into the right thighs of mice. After 2 h of infection, a single dose of PBS, doxycycline (50 mg/kg), benzydamine (50 mg/kg), or combinations (50 + 10 mg/kg, 50 + 50 mg/kg) was administered. At 48 h post infection, mice were euthanized due to dislocation of the cervical spine. The right thigh muscle was aseptically resected, homogenized, serially diluted, and plated on LBA to determine bacterial numbers.
Statistics and reproducibility
Statistical analysis was performed using GraphPad Prism version 8.3.0. All data from at least three biological replicates are shown as mean ± SD. Unless otherwise noted, unpaired t test between two groups or one-way analysis of variance among multiple groups were used to calculate P values (*P < 0.05, **P < 0.01, ***P < 0.001, and ****P < 0.0001).
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
RNA-sequencing data have been deposited in the National Center for Biotechnology Information (NCBI) Sequence Read Archive (SRA) database (PRJNA766533). Source data for the main figures are provided in Supplementary Data 1. All other data are available from the corresponding authors.
References
Harrison, E. & Brockhurst, M. A. Plasmid-mediated horizontal gene transfer is a coevolutionary process. Trends Microbiol. 20, 262–267 (2012).
De Oliveira, D. M. P. et al. Antimicrobial resistance in ESKAPE pathogens. Clin. Microbiol. Rev. 33, e00181–19 (2020).
Ma, Y.-X. et al. Considerations and caveats in combating ESKAPE pathogens against nosocomial infections. Adv. Sci. 7, 1901872 (2020).
Gupta, N., Limbago, B. M., Patel, J. B. & Kallen, A. J. Carbapenem-resistant Enterobacteriaceae: epidemiology and prevention. Clin. Infect. Dis. 53, 60–67 (2011).
Liu, Y.-Y. et al. Emergence of plasmid-mediated colistin resistance mechanism MCR-1 in animals and human beings in China: a microbiological and molecular biological study. Lancet Infect. Dis. 16, 161–168 (2016).
Sun, J. et al. Plasmid-encoded tet(X) genes that confer high-level tigecycline resistance in Escherichia coli. Nat. Microbiol. 4, 1457–1464 (2019).
He, T. et al. Emergence of plasmid-mediated high-level tigecycline resistance genes in animals and humans. Nat. Microbiol. 4, 1450–1456 (2019).
Liu, Y., Ding, S., Shen, J. & Zhu, K. Nonribosomal antibacterial peptides that target multidrug-resistant bacteria. Nat. Prod. Rep. 36, 573–592 (2019).
Lewis, K. The science of antibiotic discovery. Cell 181, 29–45 (2020).
Wright, G. D. Antibiotic adjuvants: rescuing antibiotics from resistance. Trends Microbiol. 24, 862–871 (2016).
Liu, Y., Li, R., Xiao, X. & Wang, Z. Antibiotic adjuvants: an alternative approach to overcome multi-drug resistant Gram-negative bacteria. Crit. Rev. Microbiol. 45, 301–314 (2019).
Liu, Y. et al. Drug repurposing for next-generation combination therapies against multidrug-resistant bacteria. Theranostics 11, 4910–4928 (2021).
Liu, Y. et al. Metformin restores tetracyclines susceptibility against multidrug resistant bacteria. Adv. Sci. 7, 1902227 (2020).
Liu, Y. et al. Melatonin overcomes MCR-mediated colistin resistance in Gram-negative pathogens. Theranostics 10, 10697–10711 (2020).
Liu, Y. et al. Anti-HIV agent azidothymidine decreases Tet(X)-mediated bacterial resistance to tigecycline in Escherichia coli. Commun. Biol. 3, 162 (2020).
Zhou, Y.-F. et al. Activity of tigecycline or colistin in combination with zidovudine against harboring tet(X) and mcr-1. Antimicrob. Agents Chemother. 65, e01172–01120 (2020).
Maisuria, V. B., Okshevsky, M., Deziel, E. & Tufenkji, N. Proanthocyanidin interferes with intrinsic antibiotic resistance mechanisms of Gram-negative bacteria. Adv. Sci. 6, 1802333 (2019).
Lyu, Y. F. et al. Amphiphilic tobramycin-lysine conjugates sensitize multidrug resistant Gram-negative bacteria to rifampicin and minocycline. J. Med. Chem. 60, 3684–3702 (2017).
Avvisati, R. et al. Intravenous self-administration of benzydamine, a non-steroidal anti-inflammatory drug with a central cannabinoidergic mechanism of action. Addict. Biol. 23, 610–619 (2018).
Nettis, E., Di Paola, R., Napoli, G., Ferrannini, A. & Tursi, A. Benzydamine: an alternative nonsteroidal anti-inflammatory drug in patients with nimesulide-induced urticaria. Allergy 57, 442–445 (2002).
Son, H. S. et al. Benzydamine inhibits osteoclast differentiation and bone resorption via down-regulation of interleukin-1β expression. Acta Pharm. Sin. B 10, 462–474 (2020).
Rastogi, M. et al. Role of benzydamine hydrochloride in the prevention of oral mucositis in head and neck cancer patients treated with radiotherapy (>50 Gy) with or without chemotherapy. Support. Care Cancer 25, 1439–1443 (2017).
Lakshmaiah Narayana, J. et al. Two distinct amphipathic peptide antibiotics with systemic efficacy. Proc. Natl. Acad. Sci. USA 117, 19446–19454 (2020).
Farha, M. A., French, S., Stokes, J. M. & Brown, E. D. Bicarbonate alters bacterial susceptibility to antibiotics by targeting the proton motive force. ACS Infect. Dis. 4, 382–390 (2018).
Mitchell, P. Chemiosmotic coupling in oxidative and photosynthetic phosphorylation. 1966. Biochim. Biophys. Acta 1807, 1507–1538 (2011).
Chen, H. et al. Isolation and characterization of lipopeptide antibiotics produced by Bacillus subtilis. Lett. Appl. Microbiol. 47, 180–186 (2008).
Liu, Y. et al. Potent broad-spectrum antibacterial activity of amphiphilic peptides against multidrug-resistant bacteria. Microorganisms 8, 1398 (2020).
Farha, M. A., Verschoor, C. P., Bowdish, D. & Brown, E. D. Collapsing the proton motive force to identify synergistic combinations against Staphylococcus aureus. Chem. Biol. 20, 1168–1178 (2013).
Brunelle, B. W., Bearson, B. L., Bearson, S. M. D. & Casey, T. A. Multidrug-resistant Salmonella enterica serovar Typhimurium isolates are resistant to antibiotics that influence their swimming and swarming motility. mSphere 2, e00306–e00317 (2017).
Ozkan, P. & Mutharasan, R. A rapid method for measuring intracellular pH using BCECF-AM. Biochim. Biophys. Acta 1572, 143–148 (2002).
Ejim, L. et al. Combinations of antibiotics and nonantibiotic drugs enhance antimicrobial efficacy. Nat. Chem. Biol. 7, 348 (2011).
Chopra, I. & Roberts, M. Tetracycline antibiotics: mode of action, applications, molecular biology, and epidemiology of bacterial resistance. Microbiol. Mol. Biol. Rev. 65, 232–260 (2001).
Hall, C. W. & Mah, T.-F. Molecular mechanisms of biofilm-based antibiotic resistance and tolerance in pathogenic bacteria. FEMS Microbiol. Rev. 41, 276–301 (2017).
Yan, J. & Bassler, B. L. Surviving as a community: antibiotic tolerance and persistence in bacterial biofilms. Cell Host Microbe 26, 15–21 (2019).
Boura, M., Brensone, D. & Karatzas, K. A. G. A novel role for the glutamate decarboxylase system in Listeria monocytogenes; protection against oxidative stress. Food Microbiol. 85, 103284 (2020).
Feehily, C. & Karatzas, K. A. G. Role of glutamate metabolism in bacterial responses towards acid and other stresses. J. Appl. Microbiol. 114, 11–24 (2013).
Voorhees, A. J. M. A. K. J. Detection of cyclic lipopeptide biomarkers from bacillus species using atmospheric pressure matrix-assisted laser desorption/ionization mass spectrometry. Anal. Chem. 75, 1628–1673 (2003).
Magiorakos, A. P. et al. Multidrug-resistant, extensively drug-resistant and pandrug-resistant bacteria: an international expert proposal for interim standard definitions for acquired resistance. Clin. Microbiol. Infect. 18, 268–281 (2012).
Falagas, M. E. & Karageorgopoulos, D. E. Pandrug resistance (PDR), extensive drug resistance (XDR), and multidrug resistance (MDR) among Gram-negative bacilli: need for international harmonization in terminology. Clin. Infect. Dis. 46, 1121–1122 (2008).
Luther, A. et al. Chimeric peptidomimetic antibiotics against Gram-negative bacteria. Nature 576, 452–458 (2019).
Imai, Y. et al. A new antibiotic selectively kills Gram-negative pathogens. Nature 576, 459–464 (2019).
Avorn, J. The $2.6 billion pill–methodologic and policy considerations. N. Engl. J. Med. 372, 1877–1879 (2015).
DiMasi, J. A., Grabowski, H. G. & Hansen, R. W. Innovation in the pharmaceutical industry: new estimates of R&D costs. J. Health Econ. 47, 20–33 (2016).
Tyers, M. & Wright, G. D. Drug combinations: a strategy to extend the life of antibiotics in the 21st century. Nat. Rev. Microbiol. 17, 141–155 (2019).
Fanaki, N. H. & El-Nakeeb, M. A. Antibacterial activity of benzydamine and antibiotic-benzydamine combinations against multifold resistant clinical isolates. Arzneimittelforschung 46, 320–323 (1996).
Paul, K., Erhardt, M., Hirano, T., Blair, D. F. & Hughes, K. T. Energy source of flagellar type III secretion. Nature 451, 489–492 (2008).
Stokes, J. M. et al. A deep learning approach to antibiotic discovery. Cell 180, 688–702 (2020).
Yamaguchi, A., Ohmori, H., Kaneko-Ohdera, M., Nomura, T. & Sawai, T. Delta pH-dependent accumulation of tetracycline in Escherichia coli. Antimicrob. Agents Chemother. 35, 53–56 (1991).
Taber, H. W., Mueller, J. P., Miller, P. F. & Arrow, A. S. Bacterial uptake of aminoglycoside antibiotics. Microbiol. Rev. 51, 439–457 (1987).
Hawkey, P. M. Pre-clinical experience with daptomycin. J. Antimicrob. Chemother. 62, iii7–iii14 (2008).
Segall, M. D. & Barber, C. Addressing toxicity risk when designing and selecting compounds in early drug discovery. Drug Discov. Today 19, 688–693 (2014).
Altinsoy, S., Ütebey, G., Kavak Akelma, F. & Ergil, J. The effects of topical chlorhexidine-benzydamine spray on laryngeal mask airway application. Minerva Anestesiol. 86, 277–285 (2020).
Pham, T.-N., Loupias, P., Dassonville-Klimpt, A. & Sonnet, P. Drug delivery systems designed to overcome antimicrobial resistance. Med. Res. Rev. 39, 2343–2396 (2019).
Clinical and Laboratory Standards Institute. Performance standards for antimicrobial susceptibility testing. CLSI (2018).
Song, M. et al. A broad-spectrum antibiotic adjuvant reverses multidrug-resistant Gram-negative pathogens. Nat. Microbiol. 5, 1040–1050 (2020).
Liu, Y., Ding, S., Dietrich, R., Märtlbauer, E. & Zhu, K. A biosurfactant-inspired heptapeptide with improved specificity to kill MRSA. Angew. Chem. Int. Ed. 56, 1486–1490 (2017).
De, A. B. et al. The antimicrobial peptide SAAP-148 combats drug-resistant bacteria and biofilms. Sci. Transl. Med. 10, eaan4044 (2018).
Aranda, A. et al. Dichloro-dihydro-fluorescein diacetate (DCFH-DA) assay: a quantitative method for oxidative stress assessment of nanoparticle-treated cells. Toxicol In Vitro 27, 954–963 (2013).
Forster, S., Thumser, A. E., Hood, S. R. & Plant, N. Characterization of rhodamine-123 as a tracer dye for use in in vitro drug transport assays. PloS One 7, e33253 (2012).
Acknowledgements
This work was supported by the National Natural Science Foundation of China (32172907 and 32002331), National Key Research and Development Program of China (2018YFA0903400), Natural Science Foundation of Jiangsu Province of China (BK20190893), Agricultural Science and Technology Independent Innovation Fund of Jiangsu Province (CX(20)3091 and CX(21)2010), China Postdoctoral Science Foundation funded project (2019M651984 and 2021T140579), A Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD) and Young Elite Scientists Sponsorship Program by CAST (2020QNRC001).
Author information
Authors and Affiliations
Contributions
Y.L. and Z.W. design and conceived the project. Z.T., J. S., Y.J. and T.D. performed all of the experiments. Z.T. and J.S. performed MIC experiments, checkboard assay, biofilm studies, fluorescence probe-related experiments, and transcriptomic analysis. Y.J. and T.D. performed safety evaluation, swimming motility experiment, and animal studies. Y.L. and Z.T. analyzed the data and wrote/revised the manuscript. All of the authors read and approved the final manuscript.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Peer review information Communications Biology thanks the anonymous reviewers for their contribution to the peer review of this work. Primary Handling Editors: Cesar de la Fuente, Anam Akhtar, and Brooke LaFlamme.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Liu, Y., Tong, Z., Shi, J. et al. Reversion of antibiotic resistance in multidrug-resistant pathogens using non-antibiotic pharmaceutical benzydamine. Commun Biol 4, 1328 (2021). https://doi.org/10.1038/s42003-021-02854-z
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s42003-021-02854-z
- Springer Nature Limited
This article is cited by
-
Metabolomics analysis of the lactobacillus plantarum ATCC 14917 response to antibiotic stress
BMC Microbiology (2024)
-
Non-antibiotic pharmaceuticals are toxic against Escherichia coli with no evolution of cross-resistance to antibiotics
npj Antimicrobials and Resistance (2024)
-
Resensitizing multidrug-resistant Gram-negative bacteria to carbapenems and colistin using disulfiram
Communications Biology (2023)
-
An optimized antimicrobial peptide analog acts as an antibiotic adjuvant to reverse methicillin-resistant Staphylococcus aureus
npj Science of Food (2022)
-
The antimicrobial peptide LI14 combats multidrug-resistant bacterial infections
Communications Biology (2022)