Abstract
With rising antibiotic resistance, alternative treatments for communicable diseases are increasingly relevant. One possible alternative for some types of infections is honey, used in wound care since before 2000 BCE and more recently in licensed, medical-grade products. However, it is unclear whether medical application of honey results in the evolution of bacterial honey resistance, and whether this has collateral effects on other bacterial traits such as antibiotic resistance. Here, we used single-step screening assays and serial transfer at increasing concentrations to isolate honey-resistant mutants of Escherichia coli. We only detected bacteria with consistently increased resistance to the honey they evolved in with two of the four tested honey products, and the observed increases were small (maximum two-fold increase in IC90). Genomic sequencing and experiments with single-gene knockouts showed a key mechanism by which bacteria increased their honey resistance was by mutating genes involved in detoxifying methylglyoxal, which contributes to the antibacterial activity of Leptospermum honeys. Crucially, we found no evidence that honey adaptation conferred cross-resistance or collateral sensitivity against nine antibiotics from six different classes. These results reveal constraints on bacterial adaptation to different types of honey, improving our ability to predict downstream consequences of wider honey application in medicine.
Introduction
Antimicrobial resistance is one of the biggest challenges facing global public health (WHO, 2018). To preserve the effectiveness of antibiotics and to treat infections caused by resistant bacteria, alternative approaches are required that can be used instead of antibiotics or after they have failed. One possible alternative currently being investigated for some applications is honey (Descottes, 2009; Knipping et al., 2012; Vandamme et al., 2013). Produced by the honey bee, Apis mellifera, honey has a long history in human medicine (Breasted, 1948) and has remained a staple treatment in traditional medicine. More recently, medically certified honeys and honey-containing products have been licensed in various part of the world, primarily for topical application, such as in wound healing (Molan and Betts, 2004; Cooke et al., 2015), and treatment of otorhinolaryngological diseases (Werner and Laccourreye, 2011). The idea is appealing: honey is generally cheap and non-harmful to patients (Dunford and Hanano, 2004; Knottenbelt, 2014), inhibits bacterial growth (Basualdo et al., 2007; Carter et al., 2016) and can promote wound closure and healing (Molan, 1999). If honey could be used instead of antibiotics for some applications, this could contribute to managing antibiotic resistance. However, several open questions remain about whether bacteria exposed to inhibitory concentrations of honey evolve resistance to it, which genes or pathways are involved, and whether any such evolutionary responses have downstream effects on other properties relevant for treatment, in particular antibiotic resistance.
Despite open questions about how bacteria evolve honey resistance, the physiological causes of honey’s antibacterial activity have been investigated in various species, including human pathogens such as Staphylococcus aureus, Pseudomonas aeruginosa, Streptococcus mutans and Enterococcus faecium (Kwakman et al., 2008, 2011; Badet and Quero, 2011; Camplin and Maddocks, 2014). Multiple mechanisms have been implicated, including high sugar/low water content, acidity, hydrogen peroxide and non-peroxide molecules such as methylglyoxal (White et al., 1963; Allen et al., 1991; Molan, 1992; Mavric et al., 2008), with floral source of the honey being a major determinant of its mechanism of action (Allen et al., 1991; Lu et al., 2013; Maddocks and Jenkins, 2013). At the phenotypic level, various effects of honey have been reported across different species, including changes in cell-wall integrity and cell shape (Henriques et al., 2011; Brudzynski and Sjaarda, 2014; Wasfi et al., 2016), quorum sensing (Truchado et al., 2009; Lee et al., 2011; Wang et al., 2012), iron acquisition (Kronda et al., 2013; Ankley et al., 2020) and biofilm formation (Merckoll et al., 2009; Badet and Quero, 2011; Halstead et al., 2016). Perhaps unsurprisingly given this complex picture of inhibitory mechanisms, research to date on the evolution of honey resistance in bacteria has reached no clear consensus. For example, Cooper et al. (2010) reported no stable increase in resistance after exposure of various species to medical-grade Leptospermum honey in vitro, while Camplin and Maddocks (2014) and Lu et al (2019) detected increased resistance in P. aeruginosa cells recovered from honey-exposed biofilms in vitro. Thus, it remains unclear how rapidly bacteria exposed to honey can evolve reduced susceptibility to it. Another important question is whether adaptation to honey has side effects for antibiotic susceptibility. This is important for assessing the risk that honey application could contribute to the spread of antibiotic resistance, affecting the success of antibiotic treatments used in combination or later against the same bacteria. There is some evidence that honey resistance affects susceptibility to rifampicin and imipenem in P. aeruginosa (Camplin and Maddocks, 2014). To understand the general picture of how honey resistance affects antibiotic susceptibility, we need to test a wider range of bacteria and antibiotics, and characterise the genetic pathways by which bacteria become resistant.
We chose to study E. coli because it is a common pathogen in humans and animals (Dowd et al., 2008; Suojala et al., 2013), frequently associated with surface wounds and infections of the intestinal tract that might be suitable for honey treatment (Haffejee and Moosa, 1985; Willix et al., 1992; Carnwath et al., 2014). Antibacterial resistance has increased in E. coli (Tadesse et al., 2012; O’Neill, 2014), and many of the resistance mechanisms found in E. coli can also be found in other species (Philippon et al., 1989; Paulsen et al., 1996), suggesting it as a good model for studying resistance evolution. To find out how bacteria respond to honey exposure phenotypically and genotypically, we experimentally evolved E. coli in the presence of four different honeys (two medical-grade honeys, two commercially available honeys) by gradually exposing bacteria to increased honey concentrations during serial passage. We then measured honey susceptibility of evolved bacteria from this experiment, as well as population growth in the absence of honey. To identify genes involved in honey resistance, we used whole-genome sequencing of these evolved isolates, as well as single-gene knockout variants. We also used a second screen for honey-resistant mutants, by exposing many replicate populations to high honey concentrations in a single-step (selective plating of overnight cultures). Lastly, we tested for collateral effects of honey adaptation on antibiotic resistance by determining the phenotypic resistance of honey-adapted isolates to antibiotics of different classes. Our results show that, even upon gradually increasing exposure, large changes in honey resistance in E. coli populations growing in vitro are rare. However, for some honey products we identified mechanisms driving moderate increases in honey resistance, and we find no indication for cross-resistance between honey and antibiotics.
Materials and Methods
Organisms and Growth Conditions
We used E. coli K-12 MG1655 as parental strain for the evolution experiment and isolation of single-step mutants. We used E. coli K-12 BW25113 and single-gene knockout variants derived from it (Keio Knockout Collection (Baba et al., 2006)) for knockout experiments. We stored all isolates in 25% glycerol at −80°C. We performed routine culturing in lysogeny broth (LB, Sigma-Aldrich (Merck KGaA, Germany)) at 37°C with shaking at 180rpm.
Honeys and Antibiotics
The different honey products we used are listed in Table 1. Honeys were stored in a cool, dark place and, in the case of medical-grade honeys, opened tubes were only used as long as recommended by the manufacturer (SurgihoneyRO™: 4 weeks; Medihoney™ Medical Honey: 4 months). Because the best-before date on commercial honeys does not concern their antimicrobial activity but its edibility, and because prolonged storage can affect hydrogen peroxide content of honey (Irish et al., 2011), non-medical-grade honeys were also used for a maximum of four months after opening. After plating honey samples on agar plates (LB broth with agar (Lennox) (Sigma-Aldrich (Merck KGaA, Germany)) at 35g/L), we observed colony-forming units with the commercial honey and Manuka honey. This was no longer the case after filtering honey solutions with a Filtropur S 0.45 filter (Sarstedt, Germany) (Wasfi et al., 2016). Accordingly, for all four honeys, honey-containing growth media were prepared immediately before the start of each experiment by diluting honey in LB (pre-heated to 55°C) and filter sterilizing. We purchased amoxicillin (product number A8523), chloramphenicol (product number 23275), ciprofloxacin (product number 17850), gentamicin (product number 48760), kanamycin (product number 60615), neomycin trisulfate salt hydrate (product number N1876), polymyxin B (product number 5291), tobramycin (product number T4014), and trimethoprim (product number 92131) from Sigma-Aldrich (Merck KGaA, Germany). We prepared antibiotic stock solutions at the outset of the experiments and filter sterilized (Filtropur S 0.2 (Sarstedt, Germany)) and stored them according to the manufacturers’ instructions (stock solutions: amoxicillin 25mg/mL in sterile distilled water (dH2O); chloramphenicol 50mg/mL in 70% ethanol; ciprofloxacin 20mg/mL in 0.1M HCl; gentamicin 50mg/mL in dH2O; kanamycin 40mg/mL in dH2O; neomycin 40mg/mL in dH2O; polymyxin B 20mg/mL in dH2O; tobramycin 40mg/mL in dH2O; trimethoprim 25mg/mL in DMSO).
Measuring Susceptibility of Isolates to Different Honeys
We used the 90% inhibitory concentration (IC90) of each antibacterial compound as an indicator of resistance. We defined the IC90 as the lowest concentration tested above which bacterial growth did not exceed 10% of growth of the same isolate in the absence of antibacterials (i.e. none of the tested concentrations at or above the IC90 supported >10% growth; this definition is used in the results sections below). A minority of dose-response curves were not monotonic, in that some individual concentrations below the IC90 inferred using the above definition supported <10% growth; this did not affect our overall conclusions (checked by using an alternative definition of the IC90 as the lowest individual concentration supporting <10% growth, which supported the same conclusions). We estimated the IC90 towards four honey products for ancestral strain E. coli K-12 MG1655 (assay A); for 18 single-step putative resistant mutants (assay B, also including the ancestral strain); for 14 serially-passaged putative honey-resistant mutants and six serially -p assaged control isolates (assay C, also including the ancestral strain); and for 28 single-gene knockout variants and their ancestral strain E. coli BW25113 (assay D, for details on selection of single-gene knockout variants see below) by measuring their growth in liquid culture at different concentrations. For each assay, we transferred independent LB-overnight cultures (cultured in flat-based 96-well microplates (Sarstedt, Germany)) into microplates filled with various honey concentrations and plain LB as a control, using a pin replicator (1/100 dilution, 2μL in 200μL). We used slightly different concentration ranges in different sets of assays (range of tested concentrations is given in Table S1). The assays were conducted with independent controls (ancestral strain) on different days. After inoculating assay microplates, we incubated them overnight at 37°C and quantified bacterial growth by measuring optical density at 600nm (OD600) with a microplate reader (Infinite® 200 PRO, Tecan Trading AG, Switzerland) at the beginning and end of the experiment (0h and 24h). We corrected OD600 scores for the optical density of the media. In each assay, we assessed multiple replicates of each strain-compound combination (assay A: three replicates; assay B: five replicates; assay C: four replicates; assay D: three replicates).
Experimental Evolution (Fig. S1A)
We serially passaged multiple selection lines of E. coli K-12 MG1655 in filtered solutions of each of the four honey products and in the absence of honey for 22 days, transferring daily (4 honey treatments + 1 control treatment = 5 evolution environments). In summary: at each transfer, each selection line was inoculated into multiple wells containing various honey concentrations. After overnight incubation, we transferred from the well with the highest concentration supporting viable growth (Fig. S1A). In more detail: to begin the experiment, we streaked out E. coli K-12 MG1655 from glycerol stocks onto LB agar plates. After overnight incubation, we inoculated six selection lines in each evolution environment, each with an independent colony (5 evolution environments x 6 colonies = 30 selection lines). In this first step, we cultured each selection line for 2h in 5mL of LB at 37°C with shaking at 180rpm. Then, for every selection line, we inoculated seven microplate wells filled with 200μL LB. After overnight incubation, we transferred the seven cultures of each selection line (5μL of each culture) into a fresh microplate filled with: 200μL of unsupplemented LB (“rescue well”), LB supplemented with one of five concentrations of the respective honey product, or honey stock solution (30 or 50 %(w/v)). We incubated microplates overnight at 37°C and quantified bacterial growth by measuring OD600 after 0h and 24h. On the following days, for every selection line, we determined the well at the highest honey concentration where ΔOD600 (OD600 24h – OD600 0h) > 0.1 (an arbitrary cut-off we took as an indication of viable growth) and transferred 5μL to seven wells in a new microplate. In cases where ΔOD600 in all honey-supplemented wells was < 0.1, we used the rescue-well culture to inoculate the fresh microplate. To gradually expose selection lines to higher concentrations of honey, we adjusted the range of concentrations tested over time, according to the performance of individual selection lines (concentrations and OD scores over time are given in Fig. S2). In the control treatment (no honey), we used a single well for each selection line at each transfer. We did this for 22 days, freezing microplates from days 3, 6, 9, 12, 15, 18, 21 and 22.
At the end of the experiment, we isolated a single colony at random from each selection line. On day 22, we streaked out a sample from the well with the highest honey concentration where ΔOD600 > 0.1 onto LB agar. After overnight incubation, we picked one colony per selection line, grew it overnight in 5mL LB and stored it at −80°C. We used colony PCR (primer sequences: forward: 5’-AGA CGA CCA ATA GCC GCT TT-3’; reverse: 5’-TTG ATG TTC CGC TGA CGT CT-3’) to ensure that all colony isolates were E. coli K-12 MG1655. For five selection lines (Medihoney_01, Commercial_02, Commercial_03, Commercial_04, Commercial_05), we found no colonies when streaking out samples on LB agar at day 22. We initially screened for honey-resistant phenotypes of colony isolates from the other selection lines by culturing each colony isolate in honey-supplemented medium at a concentration in which the parental strain was not able to grow. This led us to exclude five isolates that did not grow at honey concentrations above that of the parental strain (Surgihoney_01, Surgihoney_02, Surgihoney_03, Surgihoney_06, Commercial_01). We then proceeded with the remaining 14 serially-passaged putative honey-resistant mutants, plus six control isolates serially passaged in LB, sequencing all 20 genomes and quantifying their honey susceptibility as described below/above respectively.
Genetic Analysis of Serially-Passaged Mutants
We sequenced the 14 serially-passaged, putative resistant mutants and the six LB-adapted control isolates. Overnight cultures inoculated with single colonies were centrifuged at 5000xg at room temperature for 10 min. After removal of the supernatant, we stored cell pellets at −20°C until further processing. We used the QIAGEN Genomic-tip 20/G (Cat. No. 10223, Qiagen, the Netherlands) according to the manufacturer’s instructions for genomic DNA (gDNA) extraction. In brief: We resuspended the bacterial cell pellets in 1mL Buffer B1, 2μL RNase A solution (100mg/mL), 20μL lysozyme (100mg/mL) and 45μL Proteinase K (20mg/mL). Afterwards, we incubated them at 37°C for up to 1h. Then, we added 350μL of Buffer B2 and mixed thoroughly by inverting the tubes several times and vortexing them a few seconds. Following incubation at 50°C for up to 1h, we loaded the lysates onto the pre-equilibrated QIAGEN Genomic-tips and left the samples to pass the resin by gravity flow. We washed the QIAGEN Genomic-tips thrice with 1mL Buffer QC to remove any remaining contaminants. We eluted the DNA twice with 1mL Buffer QF pre-warmed to 50°C, discarded the Genomic-tips and precipitated the DNA by adding 1.4mL room-temperature isopropanol to the eluted DNA. We precipitated the DNA by inverting the tube 10-20 times and spooled the DNA using a glass rod. We immediately transferred the spooled DNA to a microcentrifuge tube containing 160μL elution buffer (Buffer EB: 10 mM Tris-Cl, pH 8.5) and dissolved the DNA overnight on a shaker (20rpm). We quantified the obtained gDNA using the Quant-iTTM dsDNA BR (Broad Range) Assay Kit (Thermo Fisher Scientific, USA) in the QubitTM Fluorometer (Thermo Fisher Scientific). We used a Nanodrop (Thermo Fisher Scientific) to control the purity of gDNA (ratios A260/A280 and A260/A230 ≥ 1.8). We sequenced at the Functional Genomic Center, Zurich, Switzerland, using the Illumina Hiseq 4000 platform after library preparation with the Nextera XT DNA Library Prep kit (Illumina, USA).
We trimmed and quality-filtered all sequences with trimmomatic (Bolger et al., 2014) with the following parameters: ILLUMINACLIP:<NexteraPE adapters fasta file>2:30:10; LEADING: 3; TRAILING: 3; SLIDINGWINDOW:4:15; MINLEN:80.. We mapped the reads of the ancestral strain of our resistance isolation experiment (2.5 x 106 reads) against the reference sequence of E. coli K-12 MG1655 (NCBI accession number: U00096) using breseq 0.33.1 (Deatherage and Barrick, 2014). We used gdtools implemented in breseq to integrate the identified mutations into the reference genome. For variant calling, we mapped all reads of the serially-passaged and single-step putative resistant mutants (average number of reads per sample: 4.1 x 106 ± 1.5 x 106) against the refined reference genome using breseq. The sequencing data has been deposited in the European Nucleotide Archive under the study accession number PRJEB35347 (https://www.ebi.ac.uk/ena).
Experiments with Single-Gene Knockout Variants
After identifying genes that potentially contribute to honey adaptation (Table S2), we tested for further evidence of the role of these genes in honey resistance using single-gene knockout variants from the Keio Knockout Collection (Baba et al., 2006) for E. coli K-12. We tested for a change in the resistance phenotype of these knockout variants relative to the ancestral strain of the knockout collection, E. coli K-12 BW25113, using the resistance phenotyping assay described above (assay D). When choosing genes to investigate, we concentrated on those (1) which were affected by independent mutations in at least two selection lines, (2) where mutations were not detected in isolates from the control treatment, (3) which were not annotated as “pseudogene”, “intergenic” nor “non-coding”, and (4) for which there is an available knockout variant in the Keio Collection (limited to non-essential genes).
Measuring Population Growth of Serially-Passaged Mutants in the Absence of Honey
We tested whether our serially passaged isolates showed altered population growth in the absence of honey relative to the ancestral strain. To do this, we grew four independent cultures (each inoculated from a different colony) of each serially-passaged isolate (including control-evolved isolates, n = 20) and the ancestral isolate, each in 150μL LB in a microplate in a randomized layout. After overnight incubation, we used a pin replicator to inoculate a fresh microplate (all wells filled with 150μL LB). We then measured OD600 every 15min for 24h (shaking before each measurement).
Measuring Susceptibility of Serially-Passaged Mutants to Antibiotics
We measured the phenotypic resistance (IC90) of the 20 serially-passaged isolates (14 putative resistant mutants, six LB-adapted control isolates) and of the parental strain (E. coli K-12 MG1655) for nine antibiotics representing six different classes: amoxicillin (penicillin), ciprofloxacin (fluoroquinolone), chloramphenicol (chloramphenicol), gentamicin (aminoglycoside), kanamycin (aminoglycoside), neomycin (aminoglycoside), polymyxin B (polymyxin), tobramycin (aminoglycoside), and trimethoprim (dihydrofolate reductase inhibitor). We decided to test several aminoglycoside drugs (gentamicin, kanamycin, neomycin, tobramycin) because previous studies have found that bacteria exposed to honey reduce the expression of genes involved in the TCA cycle (Lee et al., 2011; Jenkins et al., 2014), while others report a link between aminoglycoside susceptibility and defects or down-regulated gene expression in the bacterial respiratory chain, including the TCA cycle (Magnet and Blanchard, 2005; Chittezham Thomas et al., 2013; Shan et al., 2015; Su et al., 2018; Zhou et al., 2019). We conducted the assays using a similar protocol as described above for honey. In brief, we first incubated independent replicate populations of each isolate in a randomized layout in microplates overnight. From these microplates we inoculated assay plates filled with LB supplemented with antibiotics at various concentrations. With 2-fold broth dilution, the non-zero concentration ranges were: amoxicillin 128 – 4 μg/mL, chloramphenicol 32 – 1 μg/mL, ciprofloxacin 1 – 0.0.03125 μg/mL, gentamicin 32 – 1 μg/mL, kanamycin 32-1 μg/mL, neomycin 64 – 2 μg/mL, polymyxin B 4 – 0.125 μg/mL, tobramycin 32 – 1 μg/mL, trimethoprim 4 – 0.125 μg/mL. We measured bacterial growth by the change in OD600 (0h, 24h) as described above. We conducted the assays for all antibiotics on the same day.
Single-Step Isolation of Honey-Resistant Mutants (Fig. S1B)
As a second screen for mutants of E. coli K12 MG1655 with increased honey-resistance, we plated aliquots of multiple independent overnight cultures, grown in the absence of antibiotics, on LB agar supplemented with each honey product.
For each honey type, we first grew 54 independent overnight cultures (250μL per culture in LB in a 96-well microplate; Fig. S1B). We then plated each culture onto a separate honey-supplemented LB agar plate (prepared in 6-well culture plates (Sarstedt, Germany)), plating 100μL of 18 separate cultures at each of three concentrations per honey product. We prepared honey-supplemented LB agar by adding LB-honey solution (at double the concentration of the desired final concentration in the plates, prepared as described above) to hand-warm double concentrated LB agar (i.e., at 70g/L agar). After mixing, we added 4mL of this honey-supplemented agar to wells. We used honey concentrations 1.25-, 1.5-, 2- or 3-times higher than previously determined IC90s of the wild-type strain in liquid. We incubated the plates overnight at 37°C before checking for resistant mutants. For SurgihoneyRO™, Medihoney™ and Manuka honey, we picked six putative honey-resistant colonies, each from a separate well. When isolating colonies, we prioritized those from wells with higher concentrations of honey. For commercial honey, we observed no viable colonies on honey-supplemented agar despite four attempts on different days (total of 216 cultures). We cultured the selected putative resistant colonies overnight in 5mL LB and suspended them in 25% glycerol for storage at −80°C. We then tested these 18 single-step putative honey-resistant mutants for phenotypic resistance as described above. We also used a second test to see if putative honey resistance phenotypes were robust, by streaking out frozen stocks of each colony isolate on honey-supplemented agar at a concentration inhibitory to the parental strain. Only three of 18 single-step putative honey-resistant mutants were able to form colonies under these conditions (Medihoney_10, Surgihoney_09, Surgihoney_10).
Statistical Analysis
Phenotypic honey resistance of serially-passaged mutants
To test whether isolates from different evolution environments had different honey-resistance profiles, we used a linear-mixed effects model (lmer function in R’s lmerTest package (R version: 4.0; package version: 3.1-2)), with evolution environment and assay compound as fixed effects and genotype (isolate) as a random effect. We compared models with and without the interaction between fixed effects, using the anova function of the stats package to test significance. When looking at individual assay compounds, we used evolution environment as a fixed effect and genotype as a random effect. We used maximum likelihood estimation (REML = F). Wild-type data was excluded from this analysis; we tested for differences in IC90 between evolved isolates and the wild type separately, with t-tests (p-values adjusted for multiple testing using the Holm-Bonferroni method).
Population growth of serially-passaged mutants in absence of honey
We used R’s nls and SSlogis functions in the stats package to estimate the growth rate and yield for each culture, with yield corresponding to the Asym parameter of the models (= asymptote) and growth rate corresponding to the inverse of the scal parameter (= numeric scale parameter on input axis). We tested for a difference in growth parameters between each evolved isolate and the parental strain with a t-test, adjusting p-values using sequential Bonferroni correction. We also tested for an average difference in growth rate or yield among evolved isolates from different evolution environments. We did this using a linear mixed-effects model, with evolution environment as a fixed effect and genotype as random effect, and excluding data from the wild type. We used maximum likelihood estimation (REML = F) with the lmer function in the lmerTest package.
Phenotypic resistance profiles of serially-passaged mutants (antibiotics)
We conducted an Analysis of Variance (ANOVA), using the aov function in R’s stats package, to test whether there is cross-resistance between honey and antibiotics, with data on the phenotypic antibiotic resistance of isolates serially passaged in different honeys. We tested each evolved-isolate-versus-wild-type combination separately, with genotype (evolved vs wild type) and assay compound (antibiotic) as factors, including the interaction term and with p-values adjusted using the Holm-Bonferroni method.
Results
Experimental Evolution of Manuka Honey-Resistant Bacteria by Serial Passaging
During serial passage at gradually increasing honey concentrations (Fig. S1A), most selection lines showed improved population growth at concentrations that were initially inhibitory to the ancestral strain (Fig. S2 & S3). When we measured the phenotypic resistance of 14 putative honey-resistant mutants and six control isolates, each isolated from a different selection line after 22 days, several showed increased resistance compared to the ancestral strain against one or more honey products (Fig. 1 & S4). The average change in resistance varied among evolved isolates passaged with different honey compounds (effect of evolution environment: F4, 20 = 1.799, p > 0.1). These differences also depended on which honey compound was used in the assay (evolution environment × assay environment interaction: χ2(12) = 234.99, p < 0.001). We observed the largest change in resistance for mutants selected with Manuka honey or Medihoney™ when they were assayed with Manuka honey (mean change relative to the ancestor of 2.13-fold (s.d. = ±0.22) and 2.07-fold (s.d. = ±0.2), respectively). Manuka honey resistance of Manuka honey- and Medihoney™-evolved isolates was also significantly higher than for control-evolved isolates from the honey-free LB-medium treatment (t9.9 = 6.71, p < 0.001 and t9 = 6.15, p < 0.001, respectively). On average, Manuka honey-evolved and Medihoney™-evolved isolates also had moderately increased resistance to Medihoney™ (mean change relative to the ancestor of 1.15-fold (s.d. = ±0.16) and 1.17-fold (s.d. = ±0.1), respectively), but this was not significantly different from that of control-evolved isolates on average (Manuka: t8.1 = −0.24, p > 0.05; Medihoney™: t8.2 = 0, p > 0.05). Some other individual isolates had consistently increased Manuka honey or SurgihoneyRO™ resistance (all replicates for a given isolate higher than all replicates for the ancestor; Fig. 1 & S4), but these changes were small compared to those for Manuka honey- and Medihoney™-evolved isolates tested with Manuka honey. Thus, after experimental evolution we observed the strongest evidence of honey adaptation with Manuka honey.
Honey Adaptation Is Linked to Mutations in nemAR and clpP
Genomic sequencing of our serially passaged isolates revealed changes at several loci (Fig. 2, Table S2). Some loci were mutated multiple times independently in honey-evolved colony isolates, but not in control-evolved isolates (Table S2, Fig. 2), indicating a possible role in adaptation to honey. Two such genes were clpP (serine protease, mutated in two Manuka honey-evolved isolates) and nemR (DNA-binding transcriptional repressor, mutated in four Manuka honey-evolved isolates and three Medihoney™-evolved isolates; Table S2, Fig. 2). The intergenic region between ydhL and nemR was mutated in the remaining two Manuka honey-adapted isolates and the remaining two Medihoney™-adapted isolates (Table S2, Fig. 2). An additional gene for which we found mutations in multiple isolates serially passaged in Manuka honey is yafS (methyltransferase; Table S2, Fig. 2), located next to gloB, the gene encoding glyoxalase II, an enzyme involved in detoxification of reactive aldehydes (Ozyamak et al., 2010). In control-evolved isolates, we found parallel mutations in fimE, a recombinase responsible for on-to-off switching of type 1 fimbriae expression, and flhD, one of two transcriptional activators of the E. coli flagellar regulon but also involved in cell division (Klemm, 1986; Iino et al., 1988; Liu and Matsumura, 1994; Prüß and Matsumura, 1996), consistent with past work with LB-adapted isolates (Knöppel et al., 2018). In summary, we found parallelisms in both control-evolved and honey-evolved isolates, and in particular every Manuka honey- and Medihoney™-evolved isolate had a mutation in or affecting nemR. As we discuss below, this may reflect the role of nemR in methylglyoxal degradation (Ozyamak et al., 2013), an active component of Leptospermum honeys.
Single-Gene Knockouts Support a Role for nemR in Honey Resistance
We used single-gene knockout variants of several genes that were mutated in serially-passaged isolates to test for further evidence that they play a role in honey resistance (Fig. 3 & S5). The knockout variant ΔnemR had increased Manuka honey resistance (all replicates higher than all replicates of the wild-type strain). This variant also showed increased average resistance to Medihoney™, although this was not consistent across all replicate assays (Fig. 3 & S5). This is consistent with the above finding that all isolates serially passaged in Manuka honey or Medihoney™ had mutations in or close to nemR, and all were more resistant to Manuka honey and Medihoney™ than the ancestral strain. In ΔclpP, the knockout of the other gene for which we observed independent mutations in multiple honey-evolved isolates, we observed a similar pattern: increased resistance to Manuka honey (in all replicate assays) and higher median Medihoney™ resistance (two out of three replicates higher than wild-type). This is consistent with the increased resistance for these honeys we observed with the two Manuka honey-selected isolates with mutations in clpP (Fig. 2 & S4). Two other knockout variants, ΔnemA and Δeda, had consistently altered resistance to Manuka honey, with Δeda having a higher susceptibility than the ancestral strain. In summary, independent deletion of two genes, nemR and clpP, which were also directly or indirectly affected by mutations in several of our serially-passaged isolates, conferred increased resistance to Manuka honey and Medihoney™.
Impaired Growth in the Absence of Honey for Honey-Evolved Compared With Control-Evolved Isolates
Most serially passaged isolates (both honey-evolved and control-evolved) had increased population growth rates relative to the ancestral strain in the absence of honey (Fig. 6). However, when we compared control-evolved isolates with honey-evolved isolates, control-evolved isolates had higher growth rates on average compared to all four types of honey-evolved isolates (linear mixed-effects model: Manuka honey: t20 = −4.355, p < 0.001; Medihoney™: t20 = −5.538, p < 0.001; SurgihoneyRO™: t20 = −4.078, p < 0.001; commercial honey: t20 = −4.671, p < 0.001). By contrast, we found little effect of serial passaging on growth yield in evolved isolates compared to the ancestral strain (Fig. S6). Comparing the growth yield in different evolution environments, we found no significant difference between isolates serially passaged in LB and honey-evolved isolates (linear mixed-effects model: all p > 0.05; Fig. S6). In summary, for most experimentally evolved isolates we found a positive effect of serial passage on growth rate, but honey-adapted isolates had a lower growth rate on average compared to isolates serially passaged in the absence of honey.
No Evidence for Cross-Resistance Between Honey and Antibiotics
We determined the phenotypic resistance of our serially-passaged isolates and the ancestral strain to nine antibiotics of six different classes (Fig. 5; Fig. S7). We found only a single case out of 180 combinations (20 serially-passaged isolates × 9 antibiotics) where antibiotic resistance was consistently altered compared to the ancestral strain (higher/lower IC90 for all mutant replicates compared to all replicates of ancestor). This was for one Manuka honey-evolved isolate, Manuka_05, tested with polymyxin B. For seven of the other eight antibiotics, the largest difference shown by individual replicates relative to the median of the ancestral replicates was two-fold or less. For the remaining antibiotic, kanamycin, some individual replicates had differences of four-fold compared to the ancestor. The overall lack of major differences between evolved isolates and the ancestral strain was supported by Analysis of Variance (testing each evolved-isolate-versus-wild-type combination separately, with genotype (evolved vs wild type) and assay compound (antibiotic) as factors, including the interaction term and with p-values adjusted using the Holm-Bonferroni method); this indicated a single significant effect of genotype, for isolate Manuka_06. Thus, we found no evidence for appreciable changes in sensitivity to antibiotics in serially-passaged honey-adapted isolates.
Single-Step Screening Supports Similar Variation of Resistance Evolution Among Honey Products
We tested whether our finding that resistance evolution was more pervasive with Manuka honey than the other honey compounds also holds true when bacteria are exposed to inhibitory honey concentrations suddenly, rather than gradually. We did this by plating aliquots from multiple independent, replicate overnight cultures directly onto honey-supplemented agar, and picking the resulting colony isolates that showed a putative resistance phenotype. As for our serially passaged isolates above, we observed the largest increases in resistance for colony isolates from the Manuka-honey treatment, when assayed with Manuka honey (Fig. S8). For SurgihoneyRO™ and Medihoney™, we observed colonies on some of our plates, but after picking six colonies for each compound and testing their phenotypic resistance, none of them had consistently altered resistance to the honey they were selected with. When we streaked out frozen stocks of these 12 putative honey-resistant colony isolate on honey-supplemented agar at a concentration inhibitory to the parental strain, only 3 out of 12 isolates formed colonies (Medihoney_10, Surgihoney_09, Surgihoney_10). Thus, most putative SurgihoneyRO™- and Medihoney™-resistant mutants showed unstable phenotypic resistance across multiple rounds of isolation, culturing and restreaking (we discuss this further in the context of earlier, similar observations below). For commercial honey, we obtained no viable colonies despite repeating the assay an additional three times on different days (216 aliquots in total for commercial honey). In summary, we isolated single-step resistant mutants with Manuka honey, but found no colony isolates with robust resistance phenotypes to SurgihoneyRO™, Medihoney™ or commercial honey, consistent with our finding in serial passage that resistance evolved most readily against Manuka honey.
DISCUSSION
We found E. coli does not easily develop large increases in honey resistance upon serial passage at gradually increasing concentrations, or upon plating of many replicate populations at inhibitory concentrations. However, we identified a set of genes important in adaptation to honey, which conferred moderate increases in resistance to Manuka honey. The known physiological role of this genetic pathway helps to explain why these genetic changes, and associated increases in phenotypic resistance, were specific to Leptospermum honeys (detoxification of methylglyoxal, which has been found to be the major contributor to the antibacterial activity of these honeys (Adams et al., 2008; Mavric et al., 2008)). This indicates the likelihood of honey resistance upon medical application may depend critically on the type or combination of honey products used. Furthermore, we found that honey adaptation in vitro had only minimal side-effects for antibiotic resistance.
The first important implication of our results is that E. coli does not readily become resistant to honey, which is promising in the context of expanding medical use of honey. Previous studies also had difficulty in isolating mutants with stable honey resistance, and/or found that honey resistance phenotypes revert quickly in the absence of honey (Cooper et al., 2010). This is consistent with our observation that several putative resistant mutants from our single-step screen had unstable phenotypes, and some serially passaged populations that attained the ability to grow at increased honey concentrations subsequently lost this ability upon transfer to fresh medium (referred to by (Abdel-Azim et al., 2019) as second transfer crash (STC)). One possible explanation is that non-genetic changes such as persister formation or other morphological changes enable temporary population survival or growth in otherwise inhibitory concentrations. Consistent with honey inducing physiological responses that are not necessarily heritable, Brudzynski and Sjaarda (2014) observed morphological changes in E. coli cultures exposed to honey, including changes in cell shape / filamentation.
The second key implication of our results is that, to our knowledge, this is the first report of a specific genetic mechanism linked to decreased honey susceptibility, namely changes affecting the nemAR operon, and alternatively via changes affecting clpP. In support, nemR and its operon have previously been described as being involved in physiological processes that we can expect to be beneficial during honey exposure. Manuka honey and Medihoney™ are both Leptospermum honeys, whose high non-peroxide antimicrobial activity is attributed to their relatively high content of methylglyoxal (Allen et al., 1991; Mavric et al., 2008), a small amount of which bacteria produce intracellularly (Tötemeyer et al., 1998). Ozyamak et al. (2013) linked the nemAR operon to methylglyoxal detoxification. The nemAR operon is located upstream from the glyoxalase system (Ozyamak et al., 2013) which consists of GlxI and GlxII (glyoxalase I and II, encoded by gloA and gloB respectively), the two most important enzymes in the detoxification pathway of methylglyoxal (Clugston et al., 1998; MacLean et al., 1998; Mannervik, 2008). Deletion of nemR, the repressor gene, results in increased transcription both of nemA and gloA (Ozyamak et al., 2013). Thus, the finding that all isolates serially passaged in supposedly methylglyoxal-rich Leptospermum honeys have mutations in or close to the repressor gene nemR allows for the speculation that, in this context, deletion of this gene is beneficial because it leads to increased methylglyoal detoxification. Similarly, clpP, another gene we found independently mutated in multiple Manuka honey-adapted isolates, was shown by Jenkins et al. (2014) to be overexpressed in Leptospermum honey-exposed methicillin-resistant S. aureus, supporting a role for this gene in honey resistance in multiple species.
The importance of methylglyoxal detoxification in increased honey resistance is further supported by the variation we observed among honey compounds. Robust resistant mutants emerged in our single-step screen only with a Leptospermum honey (Manuka) with a high concentration of methylglyoxal, but not with the other three compounds. During serial passage we saw a similar trend: the most consistent increases in resistance were with the two Leptospermum honey products. By contrast, resistance of putative single-step resistant mutants isolated from SurgihoneyRO™-supplemented agar was not stable, and we could not isolate any spontaneous mutants for the commercial honey we used (despite observing increased population growth at inhibitory concentrations during serial passage). This commercial honey is a blend of honeys with unknown flower sources from different South-American countries. Drawing a parallel to antibiotics, where combinations of antibiotics can make it harder for bacteria to evolve resistance (Baym et al., 2016), we speculate that resistance evolution against this honey was rare in our experiments because it is a form of combination treatment. This raises the possibility that effective application of honey in treatment may benefit from combining multiple types of honey products with different mechanisms of action. We note that despite variation among honey products, all isolates in our experiment were inhibited by honey concentrations comparable to those found in medical-grade honey products (63–100% in products recommended/licensed for medical wound care, http://www.medihoney.de/index.html). We hypothesize that the multi-faceted nature of honey’s antibacterial activity (Wang et al., 2012; Nolan et al., 2019) contributes to the difficulty of bacteria evolving resistance to such high concentrations.
The third major implication of our results is that honey adaptation did not come with collateral effects on antibiotic resistance. The lack of collateral effects on antibiotic resistance is an important and promising aspect in the context of wider medical application of honey, and contrasts starkly with the frequent occurrence of cross-resistances between antibiotics (Szybalski and Bryson, 1952; Gutmann et al., 1985) and between antibiotics and some other antimicrobial agents (Loughlin et al., 2002; Braoudaki and Hilton, 2004; Baker-Austin et al., 2006; Allen et al., 2017; Bischofberger et al., 2020). We do not exclude that more significant changes in antibiotic resistance might be observed in mutants or strains with larger changes in honey resistance than the moderate increases we observed here, if such strains exist. A key avenue for future work is therefore to determine whether any genetic variation in natural populations associated with variable honey resistance is independent of variation in antibiotic resistance, as in our experiment. Another important aspect to consider is honey’s potential effect on other bacterial virulence factors. Biofilm formation is an effective bacterial defense mechanism against a wide range of antimicrobials (Costerton et al., 1995). Several of the genes we found mutated in honey-adapted isolates have a known role in biofilm formation (fimA, fimE, nlpD, ompR, yeaJ (Prigent-Combaret et al., 2001; Niba et al., 2007; Wu and Outten, 2009; Amores et al., 2017)). Honey or honey-resistance mechanisms might therefore also have downstream effects for biofilm formation or the expression of other virulence factors. On the other hand, because honey has shown effective inhibition of a wide range of pathogens (Carter et al., 2016; Hillitt et al., 2017; Yabes et al., 2017), and the principal genes involved in honey resistance in our experiment are conserved in multiple pathogenic species (e.g., nemR or analogues are present in Klebsiella pneumonia, Acinetobacter baumannii and Salmonella typhimurium), our work identifies candidate loci that may be involved in resistance in other species. This is another relevant area for future research in the context of medical honey application.
Our results also provided indirect evidence of growth costs associated with honey adaptation. Growth in the absence of selecting antibacterials is widely considered an important parameter in the long-term spread of resistance (Andersson and Hughes, 2010). The larger increase in growth rate observed in our control-evolved isolates compared to honey-adapted isolates suggests either (i) that honey adaptation constrained adaptation to other aspects of the environment, preventing acquisition of other beneficial mutations, or (ii) that honey-resistance mutations combined with other types of beneficial mutations conferred a smaller net increase in growth rate in honey-free growth medium compared to other beneficial mutations alone. Our sequence data are more consistent with the former: control-evolved populations had parallel mutations in flagella and fimbriae genes (flhD and fimE), consistent with past work with LB-adapted E. coli (Knöppel et al., 2018). These mutations were much less common in honey-adapted colony isolates (Fig. 2). This could be due, for example, to epistatic interactions between the different types of adaptive mutations (Scanlan et al., 2015). The parallelism we observed for these genes might also be responsible for the increased honey resistance of control isolates (Fig. S4). However, a full understanding of the growth costs and benefits associated with individual honey-resistance alleles and their interactions with other types of beneficial mutations is beyond the scope of this paper, and was not our aim here, but would make an interesting avenue for future work.
In conclusion, honey resistance in our experiment only evolved with a subset of the compounds we tested, and only to a moderate degree. This is promising in the context of medical application of honey. A further positive aspect is that we found no evidence of strong downstream effects on antibiotic susceptibility in isolates adapted to honey in vitro via chromosomal mutation. Finally, we identified putative genetic mechanisms involved in honey adaptation, via changes affecting genes involved in detoxifying methylglyoxal, making this mechanism most relevant for Leptospermum honeys such as Manuka honey.
Data Archiving Statement
The data that support the findings of this study will be made openly available at Dryad Digital Repository: to be completed after manuscript is accepted for publication.
Acknowledgments
A.B. thanks Richard Allen for help with statistical analysis. A.H. acknowledges Swiss National Science Foundation project 31003A_165803.
Footnotes
anna.bischofberger{at}env.ethz.ch, katia.pfrunder{at}env.ethz.ch, michael.baumgartner{at}env.ethz.ch, alex.hall{at}env.ethz.ch