Assessment of Phenotype Microarray plates for rapid and high-throughput analysis of collateral sensitivity networks
Authors:
Elsie J. Dunkley aff001; James D. Chalmers aff002; Stephanie Cho aff002; Thomas J. Finn aff002; Wayne M. Patrick aff001
Authors place of work:
Centre for Biodiscovery, School of Biological Sciences, Victoria University, Wellington, New Zealand
aff001; Department of Biochemistry, University of Otago, Dunedin, New Zealand
aff002
Published in the journal:
PLoS ONE 14(12)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0219879
Summary
The crisis of antimicrobial resistance is driving research into the phenomenon of collateral sensitivity. Sometimes, when a bacterium evolves resistance to one antimicrobial, it becomes sensitive to others. In this study, we have investigated the utility of Phenotype Microarray (PM) plates for identifying collateral sensitivities with unprecedented throughput. We assessed the relative resistance/sensitivity phenotypes of nine strains of Staphylococcus aureus (two laboratory strains and seven clinical isolates) towards the 72 antimicrobials contained in three PM plates. In general, the PM plates reported on resistance and sensitivity with a high degree of reproducibility. However, a rigorous comparison of PM growth phenotypes with minimum inhibitory concentration (MIC) measurements revealed a trade-off between throughput and accuracy. Small differences in PM growth phenotype did not necessarily correlate with changes in MIC. Thus, we conclude that PM plates are useful for the rapid and high-throughput assessment of large changes in collateral sensitivity phenotypes during the evolution of antimicrobial resistance, but more subtle examples of cross-resistance or collateral sensitivity cannot be identified reliably using this approach.
Keywords:
Staphylococcus aureus – Methicillin-resistant Staphylococcus aureus – antibiotics – Eyes – Antimicrobial resistance – Microarrays – Clinical laboratories – Broth microdilution
Introduction
Collateral sensitivity is when bacteria develop resistance to one antibiotic, and in doing so increase their susceptibility to one or more others. The phenomenon was first observed in 1952 [1] but it was largely ignored in the subsequent decades. With the emergence of the antimicrobial resistance crisis, collateral sensitivity has garnered new attention because it offers the potential to preserve the utility of our diminishing supply of antibiotics [2–4]. Were collateral sensitivity to be understood in a systematic and predictable manner, a clinician could treat a persistent infection by cycling through antibiotics in such a way that the second antibiotic was chosen for its enhanced efficacy against resistant microorganisms that develop during treatment with the first.
Many studies into the potential of collateral sensitivity have focused on strains of Escherichia coli [5–8], Pseudomonas aeruginosa [9] or Staphylococcus aureus [10, 11] that were subjected to evolution in vitro. In each case, a strain was exposed to one antibiotic, resistant mutants were isolated, and their sensitivities towards up to 25 other antibiotics were tested. The clinical relevance of this in vitro approach has been questioned because of the stochasticity of evolution [12]. It also emphasizes mutationally acquired resistance, which is known to occur in vivo [13, 14], but clinical strains of bacteria more commonly acquire resistance through horizontal gene transfer [15]. This has led to studies seeking to identify collateral sensitivities that are more directly relevant in clinical settings. For example, 10 genetically-diverse clinical urinary tract isolates of E. coli showed broadly conserved patterns of collateral sensitivity to a panel of 16 antimicrobials [16]. With evidence accumulating that collateral sensitivities may indeed be predictable [17, 18]–but with outstanding questions about how to apply this knowledge–the field is primed to advance rapidly.
In this work we aimed to develop, implement and validate a high-throughput screen for collateral sensitivities. Agar dilution and broth dilution methods [19] to determine differences in minimum inhibitory concentration (MIC) are highly accurate but labour intensive. As a result, it is unusual for any given study to test for collateral sensitivities towards >20 antimicrobials. We hypothesised that higher throughput experiments might reveal previously-overlooked sensitivities, which in turn could help to accelerate the field.
Phenotype Microarray (PM) plates have become a widely used tool for phenotypic characterization of microorganisms [20, 21]. Each 96-well PM plate contains different nutrient sources, growth additives or, in the case of PM plates 11–20, antimicrobial compounds. Each of PM plates 11 to 20 contains 24 antimicrobials, present at different concentrations in four wells. A redox dye is added to each well, which changes from colourless to purple in response to microbial metabolic activity. The rate of colour formation can be monitored automatically using an OmniLog instrument; however, we and others have successfully scored colour development by eye [20, 22–24]. Persistent, well-specific variability has also been observed in OmniLog data collected for plates PM 1–10 [25], suggesting that data collection by eye or by OmniLog is equally valid. We set out to assess whether PM plates could provide sensitive and reproducible enough data to be useful in building collateral sensitivity networks. We concentrated on scoring growth data by eye, in order to develop a protocol with the broadest possible applicability.
In our proof-of-principle experiments, we have focused on the Gram-positive bacterium, S. aureus. We have compared resistance and sensitivity to 72 antimicrobials (three PM plates) between seven clinical isolates of S. aureus including four methicillin-resistant strains (MRSA), one laboratory strain, and one descendent of this strain that was evolved in vitro towards oxacillin resistance. Overall we found PM plates to provide reproducible data, although their correlation with broth microdilution was more variable.
Materials and Methods
Materials
Mueller-Hinton (MH) medium (ForMedium, Hunstanton, UK) was used to culture S. aureus. Antibiotics and other specialty chemicals were from Sigma-Aldrich (St Louis, MO, USA) unless noted otherwise. Cefazolin, demeclocycline and oxacillin were from Melford Laboratories (Ipswich, Suffolk, UK).
Phenotype Microarray plates (Biolog, Hayward, CA, USA) were used for chemical sensitivity testing. PM plates 11–13 were used as these cover a range of common and clinically relevant antibiotics, as well as other antimicrobial compounds.
S. aureus strains
Seven clinical isolates of S. aureus were obtained from the collection held at Christchurch Hospital, New Zealand. These isolates were fully anonymized before we accessed them. The genomes of these isolates had previously been sequenced and typed using SCCmecFinder. This web-based tool identifies and classifies the staphylococcal cassette chromosome mec (SCCmec) elements used to type MRSA [26]. Four of our seven clinical isolates were MRSA sequence type IV and carried the mecA methicillin-resistance gene. These were identified as isolates TT, BE, BR and BK. The three remaining clinical isolates (SO, SY and UB) did not carry mecA, nor any other element of SCCmec. They had also been typed as methicillin-sensitive when they were isolated at Christchurch Hospital.
The laboratory strain S. aureus ATCC 25923 was tested in parallel to the clinical isolates. This is a standard control strain for testing antibiotic resistance or susceptibility. It does not carry the mecA gene, although it has regions of homology with SCCmec that do not confer any resistance [27, 28].
Further, S. aureus ATCC 25923 was evolved to be more oxacillin resistant by serial passaging. The strain was streaked on MH-agar and after overnight incubation at 37°C, a single colony was used to inoculate MH broth (3 ml). This was grown for 18 h with shaking at 37°C, resulting in a saturated culture (OD600 ~ 6.5). From this culture, a 10 μl aliquot was used to inoculate 1 ml fresh MH broth, now containing oxacillin at 0.125 μg/ml. The culture was incubated at 37°C, with shaking, for 24 h. The presence of the antibiotic slowed growth: the OD600 measurement for this culture was ~0.8. Two aliquots (each 10 μl) were taken and used to inoculate 1 ml of fresh broth (1:100 dilution), with the oxacillin concentration doubled (0.25 μg/ml). After 24 h with shaking at 37°C, the replicate with the highest OD600 was used to inoculate 2 × 1 ml of fresh broth (1:100 dilution), with the oxacillin concentration again doubled (0.50 μg/ml). This process was continued, with growth steps being extended as necessary to obtain cultures with OD600 measurements in the range 0.7–1.2. When no growth was observed after 6 days incubation, serial passaging was stopped and the last surviving isolate was termed 25923evo.
Phenotype Microarrays
Bacterial strains to be assayed were cultured overnight in 3 ml of MH broth. Each saturated culture was diluted to an OD600 of 0.5 ± 0.05, and then used to prepare the PM plate inoculum as follows. Each batch of three PM plates was prepared according to the manufacturer’s protocol for Gram-positive bacteria. Inoculum solution A (6 ml, total volume) was assembled by combining 1 ml of diluted overnight culture with 4.94 ml inoculating fluid IF-0 (sold by Biolog at 1.2× concentration) and 60 μl redox Dye H (sold by Biolog at 100× concentration).
A Gram-positive additive solution (12× concentration) was made according to the manufacturer’s instructions for aiding the growth of Gram-positive bacteria in PM plates. This comprised 24 mM MgCl2, 12 mM CaCl2, 0.06% (w/v) yeast extract, 0.06% (v/v) Tween 80, 30 mM D-glucose and 60 mM sodium pyruvate.
Inoculum solution B (35 ml, total volume) was prepared by combining the following components: 29.2 ml of inoculating fluid IF-10b (Biolog; sold as a 1.2× stock); 2.92 ml of the Gram-positive additive solution; 350 μl of Dye H (100× stock); and 2.53 ml of inoculum solution A (described above). Aliquots of inoculum solution B (100 μl) were dispensed into each well of PM plates 11–13. Plates were incubated for 24 h at 37°C without shaking.
After incubation, growth in each well was scored by eye. Each well was given a score out of 2: 0 for colourless (no growth); 1 for light purple (intermediate growth); and 2 for dark purple (full growth). Each antimicrobial was present in four wells at increasing concentrations. Growth scores across the four wells were summed. Maximal resistance therefore corresponded to a growth score of 8, whereas a growth score of 0 corresponded to complete sensitivity.
Determination of minimum inhibitory concentrations
Minimum inhibitory concentrations (MICs) for six antimicrobial compounds were determined by the broth microdilution method, as described previously [19, 22]. The ranges of concentrations tested were based on the EUCAST breakpoints for each compound, where available from http://www.eucast.org/. These MIC breakpoints were 2 μg/ml for erythromycin, tetracycline and oxacillin, and 4 μg/ml for cefazolin. The range was subsequently lowered for demeclocycline MIC tests to bring the point of inhibition for these isolates within range. The first column of wells in a 96-well plate was filled with 200 μl of MH broth plus the antimicrobial at the maximum concentration to be tested. The remaining wells contained 100 μl MH broth. This was used to begin a two-fold dilution series, which covered 12 concentrations. A 100 μl aliquot from column 1 was transferred into the wells in column 2, pipetted up and down to mix, and repeated for the remaining rows. A 3-μl aliquot of saturated cell culture, diluted to OD600 = 0.5, was used to inoculate each well. Plates were sealed with a breathable membrane (Aeraseal) and incubated in an Incumix plate shaker (Select Bioproducts) at 37°C and 600 rpm for 16 h. The percentage of growth inhibition in each well was calculated by measuring OD600 in a plate reader (PerkinElmer) and comparing it to a blank and a well with no antibiotic, according to the following formula (Clinical and Laboratory Standards Institute, https://clsi.org/):
Percentage inhibition = 100× (OD600 of untreated well–OD600 of well at known concentration plus cells) / (OD600 of untreated well–OD600 of blank).
The first well which showed ≥95% inhibition was deemed to be the MIC cut-off for that isolate.
Results
We assessed the accuracy of PM plates for the discovery of collateral sensitivity networks by assaying seven clinical isolates and two laboratory strains of S. aureus. We set out to test two aspects of the accuracy of these assays: reproducibility and reliability. Reproducibility was tested by comparing independent biological replicates in duplicate microarray assays. Reliability was assessed by correlating the relative levels of resistance observed in PM assays with MICs determined using the broth microdilution method [19], which is a particularly common test used in clinical settings [29].
Reproducibility
All nine strains of S. aureus were assayed in duplicate using PM plates 11–13. In total, this experiment therefore probed 648 combinations (9 strains × 72 antimicrobials). The antimicrobials in PM plates 11–13 were grouped according to their mode of action: cell wall-acting antibiotics (16 compounds); protein synthesis inhibitors (22 compounds); inhibitors of nucleic acid synthesis (11 compounds); repurposed cancer and anti-psychotic drugs (7 compounds); and others including antiseptics, disinfectants and metal ions (16 compounds). The full list of compounds is provided in the Supporting Information (S1 Table). As described in the Materials and Methods, relative resistance to each antimicrobial was assessed using a growth score that ranged from 0 (completely sensitive) to 8 (maximally resistant). Independent duplicates were performed several weeks apart. Examples of the PM assays are depicted in Fig 1.
Overall, the PM data revealed high levels of resistance in all S. aureus strains to many of the compounds tested (Fig 2 and S1–S5 Figs, Supporting Information). As expected, for example, the aminoglycosides were not effective against this Gram-positive bacterium (S2 Fig). Comparing the clinical isolates with S. aureus ATCC 25923 revealed hints of collateral sensitivity; for example, the clinical isolates all appeared more sensitive to doxycycline (S2 Fig) and 5-fluorouracil (S4 Fig). As expected, S. aureus ATCC 25923 showed a low level of oxacillin resistance (average growth score = 1.5), whereas its oxacillin-resistant descendent (25923evo) showed increased resistance (growth score = 3).
Comparison of the replicated sets of PM data revealed that the growth scores for each antimicrobial were identical between duplicates 84% of the time (Fig 2). When the growth scores were different, it was most commonly only by one point on the 8-point scale. The scores differed by one point 11.5% of the time, and only differed by more than one point in 4.5% of the duplicated assays (29 of 648 combinations). Most of the variability in duplicates was observed for the β-lactams, the tetracyclines and the metal chlorides. In one extreme case, 25923evo returned growth scores of 0 and 8 in duplicate vancomycin tests. The other eight S. aureus strains showed reproducible growth scores of 0 for vancomycin, suggesting to us that the score of 8 was the result of a technical or manufacturing error. The overarching conclusion of this experiment was that PM plates yield reproducible data on relative resistance and sensitivity, across both clinical and laboratory strains of S. aureus.
Correlation with broth microdilution
PM plates have been compared favourably against disc diffusion, broth microdilution or molecular methods in terms of throughput, chemical use and time cost [30]. However, the same authors also pointed out that PM plates are best used for preliminary estimates of inhibitory concentrations. We wanted to gauge whether PM assays are sensitive and accurate enough to discover novel collateral sensitivities and build large-scale resistance/sensitivity networks. Therefore, we compared the output from our PM assays with classical MIC determination by broth microdilution.
Within our resistance/sensitivity network (Fig 3 and S1–S5 Figs) we noted that the nine S. aureus strains responded very similarly to some compounds, but for others the response was highly variable. For example, as shown in Fig 3, the clinical MRSA isolates BR and TT were highly resistant to erythromycin (average growth scores of 8 and 7.5 respectively) while most of the other strains we tested were relatively sensitive (growth scores of 2 to 4). On the other hand, all nine strains showed moderate-to-high levels of resistance to cefazolin (growth scores of 5.5 to 8). This reproducible inter-strain variability in the PM data provided us with a way to rigorously assess the degree of correlation with broth microdilution.
We selected six antimicrobial compounds to analyze in more detail. Erythromycin and oxacillin had highly variable efficacies against the nine S. aureus strains. Nickel chloride and 2,2′-dipyridyl elicited moderate variability in growth scores between strains. Cefazolin and demeclocycline had relatively uniform efficacies against all strains. The growth scores for each strain against each of these six antimicrobials are summarized in Fig 3. In order to appraise the sensitivity and accuracy of our PM assays, we also determined the MICs for these six compounds. Our goal was to assess whether the large and small growth differences we observed in the wells of PM plates truly reflected differences in antimicrobial resistance/sensitivity.
The comparison of PM growth scores and broth microdilution MICs is shown in Fig 4. In general, large differences in PM growth score faithfully reflected large differences in MIC. For example, a high growth score for erythromycin (8 or 7.5) corresponded to an MIC of 128 μg/ml, whereas a low growth score (2) corresponded to MICs of 8 μg/ml or less. At the same time, the correlation between PM growth score and MIC was far from perfect. The five strains that showed a growth score of 2 in erythromycin-containing PM wells varied in their MICs from 2 μg/ml (clinical isolate SO) to 8 μg/ml (clinical isolates BE and UB). Another strain with an MIC of 8 μg/ml (clinical isolate SY) had a growth score of 4, not 2.
This pattern was consistent across clinical and laboratory strains, and across all of the antimicrobials tested. Results on the polar ends of each scale were more consistent than intermediary scores. For 5 out of the 6 antimicrobials, the highest MICs were directly correlated with the highest PM growth scores (darkest shading in Fig 4). The outlier was clinical isolate SY, which reproducibly failed to grow in any oxacillin-containing PM well, but which was highly resistant to oxacillin (MIC = 64 μg/ml) in the broth microdilution assay. Similarly, for 5 of the antimicrobials, the lowest MICs were reflected in the lowest PM growth scores (lightest shading in Fig 4). The exception was 2,2′-dipyridyl, for which the most sensitive strain (S. aureus ATCC 25923, MIC = 32 μg/ml) grew unusually well in the PM assay (growth score = 7).
On the other hand, differences in PM growth score of less than 2 units could not reliably predict differences in MIC. For example, growth scores of 4, 5 or 6 could all correspond to a demeclocycline MIC of 0.0156 μg/ml (Fig 4). Similarly, growth scores of 5, 7 or even 7.5 could correspond to a nickel chloride MIC of 64 μg/ml.
The manufacturer of PM plates (Biolog Inc.) does not disclose the concentrations of compounds in their plates. The sizes of the incremental increases in concentration across the four PM wells are also unknown for each compound. Not knowing the working range of concentrations complicates the use of PM plates to assess sensitivity/resistance networks. For example, six of the nine S. aureus strains showed full growth in all four cefazolin-containing PM wells; that is, they had growth scores of 8. However, the cefazolin MICs of these strains ranged from 1 μg/ml to 16 μg/ml (Fig 4). The most likely explanation is that the four PM wells containing cefazolin range from a very low concentration up to, perhaps, 0.5 μg/ml. If this is the case, any strain with an MIC > 0.5 μg/ml will show full growth in all four wells; however, it becomes impossible to assess the relative resistance or sensitivity of any strain that fulfils this criterion.
Discussion
This study has emphasized the potential power and pitfalls of PM plates for the large-scale assessment of cross resistance and collateral sensitivity. We were able to rapidly obtain resistance and sensitivity data for 72 antimicrobials, which is many more than have been tested in previous studies [8, 12, 16, 17]. It would be straightforward to expand our approach to more of the antimicrobial-containing PM plates. In total, plates 11–20 contain 237 antimicrobials; testing the entire set would represent an order of magnitude increase in screening breadth compared to current approaches. Moreover, scoring PM growth by eye (Fig 1) proved to be a fast, technically straightforward, cost effective and reproducible way to collect resistance and sensitivity data. In independent duplicates, carried out several weeks apart, we obtained identical growth scores in 544 of 648 antimicrobial/strain combinations. Of the remaining combinations, 75 differed by a single point on our 8-point growth scale (Fig 2). This corresponded to the difference between no growth and intermediate growth, or intermediate growth and full growth, in one of the four wells containing a given antimicrobial.
When PM growth scores were carefully compared with MIC data obtained by broth microdilution, a trade-off between throughput and accuracy became apparent. Small differences in PM growth score did not reliably correlate with MIC. Our data suggest that a difference in growth score of at least 2 points is required to indicate a genuine difference in MIC between two S. aureus strains. For example, the PM assays suggested that many of the clinical isolates were more sensitive to demeclocyline, nickel chloride or 2,2′-dipyridyl than the laboratory strain S. aureus ATCC 25923 (Fig 3). However, the differences in PM growth score were small and the evidence for increased sensitivity was not borne out by MIC testing (Fig 4). The level of agreement (or disagreement) between PM scores and MICs was comparable for the clinical isolates and the laboratory strains S. aureus 25923 and 25923evo. For the purpose of discovering novel collateral sensitivities, the power of these assays appears to be limited to detecting large reductions in resistance. With one exception (clinical isolate SY in oxacillin), differences of ≥16-fold in MIC between any two strains were always correlated with differences in PM growth.
Our results build on previous findings that laboratory strains are not necessarily good models for exploring collateral sensitivity in the clinical setting [12, 31]. Our laboratory-evolved, oxacillin-resistant strain 25923evo frequently behaved closer to its parent, S. aureus ATCC 25923, than to any of the clinical isolates. Collateral sensitivities could not be extrapolated from 25923evo to the clinical isolates, either from PM results or from MIC data. This lack of predictive power held when 25923evo was compared either to MRSA (strains TT, BE, BR and BK, carrying the mecA gene) or to the methicillin-sensitive hospital isolates SO, SY and UB (lacking mecA).
There remains a chasm between the expanding body of laboratory research into collateral sensitivity and the implementation of this research as a therapeutic strategy. A high-throughput assay using PM plates could go some way towards bridging this gap. Our research has concentrated on the easiest to implement, most universally applicable option of scoring growth in PM plates by eye. It is possible that measurements using the OmniLog instrument (sold by Biolog Inc.) would resolve some the issues we encountered; however, this remains to be tested. We also note that other groups have found OmniLog results to be variable or imperfect [25, 32]. The assay we have implemented here offers speed and breadth, and is capable of reproducibly identifying large differences in cross-resistance or collateral sensitivity between otherwise closely-related strains.
Supporting information
S1 Fig [pdf]
Phenotype Microarray growth scores for nine . strains in the presence of cell wall-acting antibiotics.
S2 Fig [pdf]
Phenotype Microarray scores for nine . strains in the presence of protein synthesis-inhibiting antibiotics.
S3 Fig [pdf]
Phenotype Microarray scores for nine . strains in the presence of antibiotics that inhibit nucleic acid synthesis.
S4 Fig [pdf]
Phenotype Microarray scores for nine . strains in the presence of repurposed cancer and antipsychotic drugs.
S5 Fig [pdf]
Phenotype Microarray scores for nine . strains in the presence of antiseptics, disinfectants, metal ions, etc.
S1 Table [pdf]
Full list of antimicrobial compounds tested in PM plates 11, 12 and 13, grouped according to mode of action.
Zdroje
1. Szybalski W, Bryson V. Genetic studies on microbial cross resistance to toxic agents. I. Cross resistance of Escherichia coli to fifteen antibiotics. J Bacteriol. 1952;64:489–99. 12999676
2. Hancock RE. Collateral damage. Nat Biotechnol. 2014;32:66–8. doi: 10.1038/nbt.2779 24406933
3. Pál C, Papp B, Lázár V. Collateral sensitivity of antibiotic-resistant microbes. Trends Microbiol. 2015;23:401–7. doi: 10.1016/j.tim.2015.02.009 25818802
4. Baym M, Stone LK, Kishony R. Multidrug evolutionary strategies to reverse antibiotic resistance. Science. 2016;351:aad3292. doi: 10.1126/science.aad3292 26722002
5. Imamovic L, Sommer MO. Use of collateral sensitivity networks to design drug cycling protocols that avoid resistance development. Sci Transl Med. 2013;5:204ra132. 24068739
6. Lázár V, Singh GP, Spohn R, Nagy I, Horváth B, Hrtyan M, et al. Bacterial evolution of antibiotic hypersensitivity. Mol Syst Biol. 2013;9:700. 24169403
7. Oz T, Guvenek A, Yildiz S, Karaboga E, Tamer YT, Mumcuyan N, et al. Strength of selection pressure is an important parameter contributing to the complexity of antibiotic resistance evolution. Mol Biol Evol. 2014;31:2387–401. doi: 10.1093/molbev/msu191 24962091
8. Suzuki S, Horinouchi T, Furusawa C. Prediction of antibiotic resistance by gene expression profiles. Nat Commun. 2014;5:5792. doi: 10.1038/ncomms6792 25517437
9. Yen P, Papin JA. History of antibiotic adaptation influences microbial evolutionary dynamics during subsequent treatment. PLoS Biol. 2017;15:e2001586. doi: 10.1371/journal.pbio.2001586 28792497
10. Kim S, Lieberman TD, Kishony R. Alternating antibiotic treatments constrain evolutionary paths to multidrug resistance. Proc Natl Acad Sci USA. 2014;111:14494–9. doi: 10.1073/pnas.1409800111 25246554
11. Rodriguez de Evgrafov M, Gumpert H, Munck C, Thomsen TT, Sommer MO. Collateral resistance and sensitivity modulate evolution of high-level resistance to drug combination treatment in Staphylococcus aureus. Mol Biol Evol. 2015;32:1175–85. doi: 10.1093/molbev/msv006 25618457
12. Nichol D, Rutter J, Bryant C, Hujer AM, Lek S, Adams MD, et al. Antibiotic collateral sensitivity is contingent on the repeatability of evolution. Nat Commun. 2019;10:334. doi: 10.1038/s41467-018-08098-6 30659188
13. Mwangi MM, Wu SW, Zhou Y, Sieradzki K, de Lencastre H, Richardson P, et al. Tracking the in vivo evolution of multidrug resistance in Staphylococcus aureus by whole-genome sequencing. Proc Natl Acad Sci USA. 2007;104:9451–6. doi: 10.1073/pnas.0609839104 17517606
14. Sieradzki K, Tomasz A. Alterations of cell wall structure and metabolism accompany reduced susceptibility to vancomycin in an isogenic series of clinical isolates of Staphylococcus aureus. J Bacteriol. 2003;185:7103–10. doi: 10.1128/JB.185.24.7103-7110.2003 14645269
15. Hughes D, Andersson DI. Evolutionary consequences of drug resistance: shared principles across diverse targets and organisms. Nat Rev Genet. 2015;16:459–71. doi: 10.1038/nrg3922 26149714
16. Podnecky NL, Fredheim EGA, Kloos J, Sørum V, Primicerio R, Roberts AP, et al. Conserved collateral antibiotic susceptibility networks in diverse clinical strains of Escherichia coli. Nat Commun. 2018;9:3673. doi: 10.1038/s41467-018-06143-y 30202004
17. Imamovic L, Ellabaan MMH, Dantas Machado AM, Citterio L, Wulff T, Molin S, et al. Drug-driven phenotypic convergence supports rational treatment strategies of chronic infections. Cell. 2018;172:121–34. doi: 10.1016/j.cell.2017.12.012 29307490
18. Rosenkilde CEH, Munck C, Porse A, Linkevicius M, Andersson DI, Sommer MOA. Collateral sensitivity constrains resistance evolution of the CTX-M-15 β-lactamase. Nat Commun. 2019;10:618. doi: 10.1038/s41467-019-08529-y 30728359
19. Wiegand I, Hilpert K, Hancock RE. Agar and broth dilution methods to determine the minimal inhibitory concentration (MIC) of antimicrobial substances. Nat Protoc. 2008;3:163–75. doi: 10.1038/nprot.2007.521 18274517
20. Bochner BR, Gadzinski P, Panomitros E. Phenotype MicroArrays for high-throughput phenotypic testing and assay of gene function. Genome Res. 2001;11:1246–55. doi: 10.1101/gr.186501 11435407
21. Bochner BR. Global phenotypic characterization of bacteria. FEMS Microbiol Rev. 2009;33:191–205. doi: 10.1111/j.1574-6976.2008.00149.x 19054113
22. Soo VWC, Hanson-Manful P, Patrick WM. Artificial gene amplification reveals an abundance of promiscuous resistance determinants in Escherichia coli. Proc Natl Acad Sci USA. 2011;108:1484–9. doi: 10.1073/pnas.1012108108 21173244
23. Garland JL. Analytical approaches to the characterization of samples of microbial communities using patterns of potential C source utilization. Soil Biol Biochem. 1996;28:213–21.
24. Blumenstein K, Macaya-Sanz D, Martín JA, Albrectsen BR, Witzell J. Phenotype MicroArrays as a complementary tool to next generation sequencing for characterization of tree endophytes. Front Microbiol. 2015;6:1033. doi: 10.3389/fmicb.2015.01033 26441951
25. Johnson DA, Tetu SG, Phillippy K, Chen J, Ren Q, Paulsen IT. High-throughput phenotypic characterization of Pseudomonas aeruginosa membrane transport genes. PLoS Genet. 2008;4:e1000211. doi: 10.1371/journal.pgen.1000211 18833300
26. Kaya H, Hasman H, Larsen J, Stegger M, Johannesen TB, Allesoe RL, et al. SCCmecFinder, a web-based tool for typing of staphylococcal cassette chromosome mec in Staphylococcus aureus using whole-genome sequence data. mSphere. 2018;3:e00612–17. doi: 10.1128/mSphere.00612-17 29468193
27. Ito T, Katayama Y, Asada K, Mori N, Tsutsumimoto K, Tiensasitorn C, et al. Structural comparison of three types of staphylococcal cassette chromosome mec integrated in the chromosome in methicillin-resistant Staphylococcus aureus. Antimicrob Agents Chemother. 2001;45:1323–36. doi: 10.1128/AAC.45.5.1323-1336.2001 11302791
28. Treangen TJ, Maybank RA, Enke S, Friss MB, Diviak LF, Karaolis DK, et al. Complete genome sequence of the quality control strain Staphylococcus aureus subsp. aureus ATCC 25923. Genome Announc. 2014;2:e01110–14. doi: 10.1128/genomeA.01110-14 25377701
29. Jorgensen JH, Ferraro MJ. Antimicrobial susceptibility testing: a review of general principles and contemporary practices. Clin Infect Dis. 2009;49:1749–55. doi: 10.1086/647952 19857164
30. Jałowiecki Ł, Chojniak J, Dorgeloh E, Hegedusova B, Ejhed H, Magnér J, et al. Using phenotype microarrays in the assessment of the antibiotic susceptibility profile of bacteria isolated from wastewater in on-site treatment facilities. Folia Microbiol. 2017;62:453–61.
31. Obolski U, Dellus-Gur E, Stein GY, Hadany L. Antibiotic cross-resistance in the lab and resistance co-occurrence in the clinic: discrepancies and implications in E. coli. Infect Genet Evol. 2016;40:155–61. doi: 10.1016/j.meegid.2016.02.017 26883379
32. Lamy B, Laurent F, Verdier I, Decousser JW, Lecaillon E, Marchandin H, et al. Accuracy of 6 commercial systems for identifying clinical Aeromonas isolates. Diagn Microbiol Infect Dis. 2010;67:9–14. doi: 10.1016/j.diagmicrobio.2009.12.012 20167449
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