Abstract
Evolve and resequence experiments have provided us a tool to understand bacterial adaptation to antibiotics by the gain of genomic mutations. In our previous work, we used short term evolution to isolate mutants resistant to the ribosome targeting antibiotic kanamycin. We had reported gain of resistance to kanamycin via multiple different point mutations in the translation elongation factor G (EF-G). Furthermore, we had shown that the resistance of EF-G mutants could be increased by second site mutations in the genes rpoD / cpxA / topA / cyaA. Mutations in three of these genes had been discovered in earlier screens for aminoglycoside resistance. In this work we expand on our understanding of these second site mutations. Using genetic tools we asked how mutations in the cell envelope stress sensor kinase (CpxAF218Y) and adenylate cyclase (CyaAN600Y) could alter their activities to result in resistance. We found that the mutation in cpxA most likely results in an active Cpx stress response. Further evolution of an EF-G mutant in a higher concentration of kanamycin than what was used in our previous experiments identified the cpxA locus as a primary target for a significant increase in resistance. The mutation in cyaA results in a loss of catalytic activity and probably results in resistance via altered CRP function. Despite a reduction in cAMP levels, the CyaAN600Y mutant has a transcriptome indicative of increased CRP activity, pointing to an unknown non-catalytic role for CyaA in gene expression. From the transcriptomes of double and single mutants we describe the epistasis between the mutation in EF-G and these second site mutations. We show that the large scale transcriptomic changes in the topoisomerase I (FusAA608E-TopAS180L) mutant likely result from increased negative supercoiling in the cell. Finally, genes with known roles in aminoglycoside resistance were present among the mis-regulated genes in the mutants.
Introduction
The efficacy of antibiotics, once heralded as miracle drugs, is now under threat because of the emergence of resistance (Davies, 1996; Levy & Marshall, 2004). One way in which bacteria become resistant to antibiotics is by gaining genomic mutations. These genomic mutations tend to accumulate mostly in the target of the antibiotic, and more often than not result in a fitness defect because these target genes tend to be essential or important for cell growth (Lenski, 1998; Andersson & Levin, 1999; Björkman & Andersson, 2000; Andersson, 2006; Andersson & Hughes, 2010). Resistance can also evolve via mutations in non-target genes (Kern et al., 2000), and studying such mutations will yield insight into the mechanism of action of the antibiotic inside the bacterial cell.
Aminoglycosides, a group of ribosome targeting antibiotics (Becker & Cooper, 2013), have a target that is difficult to modify mutationally. This difficulty arises, especially in fast growing organisms like E. coli, because of the presence of multiple copies of the gene encoding the target of aminoglycosides, i.e. the 16S rRNA. On short timescales, it is not possible to mutate all copies of the target gene, seven of which are present in E. coli for instance, to achieve resistance (Kotra, Haddad & Mobashery, 2000).
In our previous work, we evolved E. coli in different sublethal levels of a model aminoglycoside kanamycin (Mogre et al., 2014). We obtained multiple kanamycin resistant mutants of the translation elongation factor EF-G (FusA). At the lower 4-kan (4 μg/ml; 25% lethal concentration kanamycin), we found a single point mutation in EF-G (FusAP610T), whereas at the higher 8-kan (50% lethal concentration kanamycin), we found two different point mutations in EF-G (FusAA608E and FusAP610L). The FusAP610T allele dominated evolved populations for five transfers (rounds of subculture) in 4-kan; whereas in 8-kan, the FusAA608E allele appeared in the first round of growth, followed by the FusAP610L allele in the next transfer. Among the three EF-G mutants, the FusAP610L allele had the best growth in 8-kan. Interestingly the FusAA608E allele had also accumulated second site mutations in four genes, viz., rpoD, cpxA, topA and cyaA, in four different isolates. Apart from our work, evolution experiments in aminoglycosides done by Lazar et al., have revealed resistance conferring mutations in fusA, rpoD, cpxA and crp (whose protein product acts downstream of CyaA), but not in cyaA and topA (Lázár et al., 2013).
EF-G is a translation factor and a part of this protein, specifically the tip of domain IV, interacts with the decoding centre, the binding site of aminoglycosides (Feldman et al., 2010). Thus, whereas the contribution of EF-G – a factor associated with the binding site of the antibiotic – to resistance is easier to understand, the mechansims by which these second site mutations confer resistance are not immediately apparent. Interestingly, all of the above second site mutations could affect transcription. More specifically, RpoD is the major sigma factor responsible for much of transcription in exponentially-growing E. coli (Feklístov et al., 2014). CpxA is an envelope stress sensor kinase, which by phosphorylating its response regulator CpxR, activates the expression of genes that tackle membrane stress (Hunke, Keller & Müller, 2012). Activation of the Cpx response upon antibiotic exposure was thought to result in increased oxidative stress and consequently cell death (Kohanski et al., 2008). However, more recent work has shown that Cpx activation confers resistance and not sensitivity to certain antibiotics (Mahoney & Silhavy, 2013; Manoil, 2013). Topoisomerase I (TopA) relaxes negatively supercoiled DNA, and can thereby affect the transcription of many genes (Travers & Muskhelishvili, 2005). Adenylate cyclase (CyaA) produces cAMP (cyclic adenosine monophosphate), a cellular second messenger, that can influence the expression of a large number of genes via the global regulator CRP (cAMP Receptor Protein) (Zheng et al., 2004). Furthermore, Girgis et al., were able to show that disruptions of cyaA and crp were beneficial to growth in aminoglycosides (Girgis, Hottes & Tavazoie, 2009).
To understand the contribution of these second site mutations to kanamycin resistance, we first generated their single mutant versions. We found that the second site mutations by themselves provide only a marginal increase in growth in kanamycin. These second site mutations however allow better growth in kanamycin in either the FusAP610T or the FusAA608E background. By comparing these second site mutants with their corresponding whole gene deletions, we attempted to clarify their roles in kanamycin resistance. Further, using RNA-seq, we found a non-additive effect between the mutation in EF-G and that in the second-site on gene expression. By comparing our transcriptome data with previously published datasets, alongwith measurements of plasmid supercoiling, we provide tentative evidence for elevated negative supercoiling in the chromosome of the FusAA608E-TopAS180L mutant. Lastly, we were able to see sets of genes with known roles in aminoglycoside resistance among those mis-regulated in these mutants. This reinforces the idea that mutating promiscuous regulators of transcription might be an effective early strategy for adaptation to stress (Finkel, 2006; Wang et al., 2010).
Materials & Methods
Strain construction
All strains used had the non-pathogenic E. coli K12 MG1655 background. RpoDL261Q, CpxAF218Y and CyaAN600Y mutants were constructed from their respective FusAA608E-RpoDL261Q / CpxAF218Y / CyaAN600Y double mutants by replacing the FusAA608E allele with the wildtype fusA allele linked to a kanamycin resistance cassette. This was done by P1 phage transduction according to the Court lab protocol (Thomason, Costantino & Court, 2007). Selection with a higher concentration of kanamycin (70-80 μg/ml) ensured that only transductants with the wildtype fusA linked to the kanamycin resistance cassette were selected, and that the non-transduced recipient double mutants were not. Background growth of the non-transduced double mutants was a common problem; however only the best growing colonies were picked since these would contain the kanamycin resistance cassette. All transductants were verified by PCR to ensure the presence of the kanamycin cassette. The kanamycin resistance cassette was flanked by FRT sites and thus was flipped out using the site specific recombinase Flp provided by the plasmid pCP20. Finally the temperature sensitive plasmid pCP20 was cured from these cells by growing them at 42 0C. The wildtype strain containing the kanamycin cassette near fusA was also treated similarly to generate a strain containing the FRT site near fusA (WTfrt) and was used as the reference strain. The mutations in fusA, rpoD, cpxA, topA and cyaA were checked by Sanger sequencing.
Knockout strains AcyaA::kanR, Acrp::kanR were earlier generated in the lab, whereas AcpxA::kanR and AcpxR::kanR were obtained from Coli Genetic Stock Center (CGSC). These knockouts were transferred into the wildtype used in this study, FusAP610T and FusAA608E strains by phage transduction. The process outlined above was used to get rid of the kanamycin resistance cassette after transferring the gene knockouts to the relevant strains including the wildtype used in this study.
Growth curves and Minimum Inhibitory Concentration (MIC) determination
Growth curves were performed in Luria-Bertani broth (LB) in either flasks or 96-well plates. For the purpose of sample collection and RNA extraction growth curves were performed in flasks at 37 Oc, 200 rpm with optical density readings measured at 600 nm using a Metertech SP-8001 Spectrophotometer. For strain comparisons, growth curves were performed in 96-well plates. These growth curves were performed using the Tecan Infinite F200pro plate reader. The machine incubated the plate at 37 °C and carried out shaking at 198 rpm with optical density readings measured at 600 nm every 15 minutes.
MICs were measured as previously described, using a modification of the broth dilution technique (Mogre et al., 2014).
Cyclic adenosine monophosphate (cAMP) estimation
Estimation of intracellular cAMP levels was carried out using the cyclic AMP Select EIA kit (501040, Cayman Chemical). Cells growing exponentially (~1.5 hours in LB) and in the stationary phase (-12-15 hours in LB) were harvested by centrifugation at 13,000 g for 1 minute. Cells were immediately transferred onto ice to prevent breakdown of cAMP by phosphodiesterases. Cell pellets were washed once with TBST (20 mM Tris, 150 mM NaCl, 0.05% Tween 20, pH 7.5) before being resuspended in 0.05 N HCl. Cells were then boiled for 5 minutes to extract cAMP. Cells were then spun down at 14000 g and the supernatant containing cAMP was collected. Estimations of cAMP were carried out according to the kit's instructions with the exception that the provided cAMP standard was diluted in 0.05 N HCl to generate the standard curve, since HCl was used for the extraction process.
Chloroquine gel analysis
Overnight grown cultures of wildtype, FusP610T, FusA608E and FusA608E-TopAS180L, transformed with the pUC18 plasmid, were diluted 1:100 in LB and grown to exponential and stationary phase. pUC18 extraction was done using the QIAprep Spin Miniprep Kit (Qiagen). About 1 μg plasmid was loaded onto 1% agarose gel containing 2.5 μg/ml chloroquine made in 2X Tris Borate EDTA (TBE) buffer. Samples were run in 2X TBE at 3V/cm for 17 hours. After the run, the gel was washed with tap water for three hours, with the water being changed every 20 minutes to remove chloroquine. After the wash, the gel was stained with 1 μg/ml ethidium bromide solution for 1 hour. After a brief wash with tap water for a minute to get rid of excess stain, the gel was illuminated with UV to visualize the different plasmid topoisomers. At the concentration of chloroquine used in these experiments, more supercoiled forms of the plasmid migrate further in the gel. Two biological replicates were analyzed for each strain and the results of one are shown.
Evolution in kanamycin
The MIC of kanamycin of the FusAP610T mutant was around 60 μg/ml. 25% of this concentration, i.e. 15 μg/ml, was selected for evolving FusAP610T towards higher resistance. Evolution experiments were carried out by batch transfers in LB with and without kanamycin. Two overnight grown replicate populations of E. coli were diluted 1:100 in 100 ml LB containing 15 μg/ml kanamycin and 100 ml plain LB as control. Thus two populations evolving in 15 μg/ml kanamycin and two control populations evolving in plain LB were incubated at 37 Oc, 200 rpm for 24 hours before the next transfer. Each evolving population was transferred by 1:100 dilution into fresh medium. The concentration of kanamycin was not changed during the course of the evolution experiment. MICs of all populations were followed at the end of each transfer.
Genomic DNA was extracted from both control and experimental populations using the GenElute Bacterial Genomic DNA Kit (NA2120, Sigma-Aldrich). Integrity of the extracted gDNA was checked on agarose gel, and quality and concentration were checked using NanoDrop UV-Vis Spectrophotometer (Thermo Scientific). Library preparation for deep sequencing was carried out using the Truseq Nano DNA Library Preparation Kit (FC-121-4001, Illumina). Paired end sequencing was carried out using the Illumina HiSeq sequencer (2 x 100 Cycles) at the Next Generation Genomics Facility, Centre for Cellular and Molecular Platforms (C-CAMP). FASTX (http://hannonlab.cshl.edu/fastx_toolkit/) quality filtered reads were trimmed using CUTADAPT version 1.9.dev1 (Martin, 2011), to remove adapter sequences. Error tolerance in identifying adapters was set to 20% and trimmed reads with less than 30 bases were discarded. These trimmed reads, were then mapped to the E. coli K12 MG1655 reference genome (NC_000913.3) using BWA mem version 0.7.5a-r405 (Li & Durbin, 2010); paired files were input together at this step. SAMTOOLS version 1.3 (Li et al., 2009) was then used to generate the pileup file from the sam files generated by BWA. Finally, the list of single nucleotide polymorphisms (SNPs) and indels was compiled from the pileup file using VARSCAN version 2.3.8 (Koboldt et al., 2012).
RNA extraction, sequencing and analysis
For RNA extraction, cells were grown in LB and harvested at the point of maximal growth rate (Fig. S1) after the addition of stop solution to stabilise cellular RNA and stop transcription. Two biological replicates were harvested for each strain including the reference strain WTfrt. RNA was extracted using the hot phenol-chloroform method. DNase treated RNA was depleted of ribosomal RNA using the Ambion Microbe Express Kit (AM1905). RNA was checked for quality using Bioanalyzer (Agilent). Checked RNA was used for library preparation and sequencing. RNA quality checks, library preparation and sequencing were carried out at Genotypic (India). Briefly, 100 ng of qubit quantified RNA was used for library preparation using the NEXTflex Rapid Directional RNA-Seq kit (5138-08 Bioo Scientific). The library was quantified using qubit and its quality was checked using Agilent Bioanalyzer before proceeding for sequencing on the Illumina NextSeq 500 sequencer.
FASTX filtered reads were trimmed using CUTADAPT and aligned to the E. coli reference genome (NC_000913.3) using BWA. SNP and indel calling was done to ensure that the correct mutations were present in the relevant samples (Fig. S2). The number of reads mapping to each gene was obtained using custom Python scripts. Correlation of raw read counts between replicates were high (>0.9, Fig. S3). Even across different strains, the strength of correlation was high (>0.8, Fig. S3). We also checked that genes within operons were similarly expressed (Fig. S4).
Subsequently the R (R Core Team, 2016) package EdgeR (Robinson, McCarthy & Smyth, 2010) was used to call differentially expressed genes using a P value cutoff of 0.001 (using the Benjamini Hochberg method to control the false discovery rate in multiple testing).
Gene ontology analysis was carried out using the R package topGO (Alexa & Rahnenfuhrer, 2010). E. coli gene annotations were obtained from Ecocyc (Karp et al., 2014) and gene ontology terms were obtained from the Gene Ontology Consortium (Gene Ontology Consortium, 2015). In topGO, the Fisher test was used to assess significance of enriched gene sets and terms with P values < 0.01 were considered significant.
All scripts are available on Github (https://github.com/aswinsainarain/mogre_kan_secondsite), as well as on http://bugbears.ncbs.res.in/mogre_kan_secondsite/.
Results and Discussion
Second site mutations increase kanamycin resistance of EF-G mutants
In our previous work we had found that four 'second-site’ mutations, namely RpoDL26lQ, CpxAF2l8Y, CyaAN600Y and TopAS180L, appeared on a FusAA608E background in 8-kan. The double mutants had marginally greater resistance to kanamycin, as measured by their MICs, than the single FusAP610T/A608E mutants; this difference was statistically significant in the case of the FusAA608E mutant, but not the FusAP610T mutant (Fig. 1A). However, the double mutants grew to a higher cell density in 8-kan, thus pointing to their selective advantage over the single mutant in kanamycin (Fig. 1B).
We replaced the FusAA608E mutation in all the double mutants with the FusAP610T mutation that had evolved in the wildtype background in 4-kan. The FusAP610T mutation showed sub-optimal growth under conditions in which FusAA608E and its second-site mutants had emerged (8-kan, Fig. 1B). These FusAP610T double mutants grew to a higher cell density than the FusAP610T single mutant alone in 8-kan (Fig. S5, control growth curves in 0-kan in Fig. S6). Thus, the selective advantage conferred by these second site mutations was similar between the two primary FusA mutants.
We constructed single mutant versions of RpoDL261Q, CpxAF218Y and CyaAN600Y from their respective double mutants by replacing the mutant FusAA608E allele with the wildtype allele (see Materials & Methods). For reasons not understood, we were unable to construct the TopAS180L single mutant. We saw that the resistance of the double mutants decreased to almost wildtype levels in these single second-site mutants (Fig. 1A). This is seen more clearly in the growth curves of these single mutants in 8-kan (Fig. 1B). These single mutants, however, fared better than the wildtype at a very low concentration of kanamycin (Fig. 1C).
From the order of occurrence of mutations in our evolution experiments, and the inability of single mutants of cpxA, cyaA and rpoD to grow well in kanamycin, it is reasonable to suggest that the mutation in EF-G potentiates the second site mutations, which further increase its resistance.
Mutation in the extra-cytoplasmic stress sensor CpxA results in resistance via hyper-activation of the Cpx stress response
The Cpx stress response is mediated by the CpxA sensor kinase and its cognate response regulator CpxR (~58 targets in RegulonDB). This versatile two-component system responds to various kinds of stress signals, especially those associated with membrane stress (Pogliano et al., 1997; Raivio & Silhavy, 1997; Hunke, Keller & Müller, 2012; Vogt & Raivio, 2012). Aminoglycosides cause the accumulation of misfolded proteins in the cell membrane and periplasmic space (Bryan & Kwan, 1983; Davis, 1987; Kohanski et al., 2008). The Cpx system responds to this stress (Kohanski et al., 2008). It was thought that the crosstalk of the Cpx response with the redox reactive Arc two-component system results in oxidative stress that kills cells (Kohanski et al., 2008). However, more recent genetic experiments have revealed that activation of the Cpx response has a protective role (Mahoney & Silhavy, 2013).
To understand the effect of the point mutation in cpxA on the activity of the Cpx response, we deleted cpxR in the EF-G mutants and the wildtype to see whether this increased or decreased their growth in kanamycin. Deleting the response regulator CpxR and not the sensor kinase CpxA is the best way to attenuate the Cpx response. This is because, in the absence of CpxA, CpxR can be cross-activated by other kinases, and this can in fact result in the hyper-activation of the Cpx response. FusAA608E-ΔcpxR resulted in a decrease in growth in kanamycin, while there was no discernible effect of the deletion on the wildtype (Fig. 2A). This suggests that an intact Cpx response is essential for the resistance of these mutants.
We saw that the FusAA608E-ΔcpxR mutants showed a spurt in growth at a certain point in batch culture, whence these mutants grew better than their EF-G single mutant counterparts (Fig. 2A). This was consistent across the different transductants tested (Fig. S7 and S8). However, even after this growth spurt, their saturation optical density never reached that of the FusAA608E-CpxAF218Y double mutant obtained from the evolution experiment (Fig. 2A).
Control growth experiments in the absence of kanamycin told us that the decreased growth of the FusAA608E-ΔcpxR strains seen in kanamycin was not the result of any generic growth defect conferred by the deletion itself (Fig. 2B). Thus, it is reasonable to conclude that the Cpx system is active, and perhaps hyperactive, in the double mutant, and that its activity is linked to resistance. CpxR has fifty eight targets in RegulonDB (Gama-Castro et al., 2016). However only a handful of these genes are among the differentially regulated genes in the FusAA608E-CpxAF218Y and CpxAF218Y mutants in relation to the wildtype (18 in the CpxAF218Y mutant and 10 in the FusAA608E-CpxAF218Y mutant), as measured by RNA-seq experiments of these mutants in the absence of kanamycin. There are nearly equal numbers of positive and negative targets of CpxR among the up and down-regulated genes. Thus, the status of the Cpx response is not clarified by a bird's eye view of the transcriptome of these mutants. However, cpxA and cpxP are up-regulated in both the FusAA608E-CpxAF218Y and CpxAF218Y mutants; and cpxR is up-regulated in the CpxAF218Y mutant. All these three genes are positive targets of CpxR, and their up-regulation in the mutant suggests that the Cpx system might be hyper-active.
Further evolution of the FusAP610T mutant in kanamycin reveals cpxA as the primary locus targeted for a further increase in resistance
In our previous evolution experiment, while the FusAA608E mutant rapidly accumulated second site mutations in 8-kan, the FusAP610T mutant which had evolved in 4-kan did not accumulate other mutations even after five transfers (Mogre et al., 2014). Thus we decided to evolve FusAP610T in a higher concentration of kanamycin (15-kan; 15 μg/ml kanamycin; 25% of the MIC of FusAP610T) to see what second site mutations would accumulate and eventually dominate in the FusAP610T background. The evolution experiment involved serial batch transfers of pure FusAP610T mutant populations in 15-kan every twenty four hours. MICs of all populations were followed at the end of each transfer throughout the experiment.
We observed an initial increase in MIC of around two-fold almost immediately and it notched up further at the end of the fourth transfer to around five to six-fold (Fig. 2C). At the end of the fifth transfer, genomic DNA from both control and evolved populations were sequenced. We looked at the mutations that were present in at least one sample in greater than 20% frequency (Fig. 2D). In the populations evolved in 15-kan we saw multiple mutations in cpxA present in different frequencies. There were two point mutations and one deletion of 6 nucleotides in cpxA. We also found several other cpxA mutations, present at very low frequencies (<20%), only in the populations exposed to kanamycin (Fig. 2E). Thus we see a heterogeneous population with different mutations in cpxA. This heterogeneity might be responsible for the large variations in the MIC determinations of these populations (Fig. 2C).
Residue changes in CpxA that confer kanamycin resistance were scattered across the protein and were located in helix-I, periplasmic and cytoplasmic-II domains (Fig. S9). In particular, mutations in helix-I reached high frequencies (>50%) in the FusAP610T populations evolved in 15-kan. The residue T16 in helix-I was particularly targeted with three different mutations, two of which reached high frequencies. Mutations in the periplasmic domain, helix-II and cytoplasmic-II domain are known to result in kanamycin resistance due to hyperactivation of CpxA (Raivio & Silhavy, 1997). However, we did not see any mutations in helix-II.
We noticed that multiple low frequency mutations in the gene sbmA had appeared in the populations evolved in kanamycin (Fig. S10). The product of this gene is involved in the transport of peptide antibiotics and its deletion results in increase of resistance to antimicrobial peptides (Laviña, Pugsley & Moreno, 1986; Yorgey et al., 1994; Salomón & Farias, 1995; Saier et al., 2009; Corbalan et al., 2013; Runti et al., 2013; Paulsen et al., 2016).
To summarize, the cpxA locus seems to be the primary region targeted for the next significant increase in resistance of the EF-G point mutant.
Disruption of adenylate cyclase catalytic activity gives kanamycin resistance mediated by altered CRP function
Adenylate cyclase is an enzyme that catalyzes the synthesis of cyclic adenosine monophosphate (cAMP) from ATP. cAMP functions as a second messenger in E. coli (Botsford & Harman, 1992; McDonough & Rodriguez, 2012). A well-known mechanism by which cAMP alters gene expression is by binding to and allosterically activating the global transcription regulator cAMP receptor protein (CRP) (Botsford & Harman, 1992; McDonough & Rodriguez, 2012), which has 477 targets in RegulonDB. Girgis et al., subsequent to a transposon mutagenesis screen, demonstrated that deletions of cyaA and crp increased resistance to aminoglycosides (Girgis, Hottes & Tavazoie, 2009). Furthermore, inactivation of adenylate cyclase was shown to result in activation of the Cpx system (Strozen, Langen & Howard, 2005) which has a known role to play in kanamycin resistance (Mahoney & Silhavy, 2013).
We found that the level of cAMP in both the CyaAN600Y and FusAA608E-CyaAN600Y mutants was lower than that in the wildtype and comparable to that in AcyaA (Fig. 3A). Thus, the CyaAN600Y mutation results in a loss of catalytic activity. The greater spread in the cAMP levels in the CyaAN600Y and FusAA608E-CyaAN600Y mutants suggests that the mutated adenylate cyclase might have reduced catalytic activity, and not a complete loss of function. This is consistent with the fact that this mutation is present in the regulatory domain of the protein and not the catalytic domain.
We also found an increase in the stationary phase cell density of the FusAP610T/A608E-ΔcyaA strains in kanamycin whereas WT-ΔcyaA was not affected considerably (Fig. 3B). FusAP610T/A608E-Δcrp also grew to a higher stationary phase cell density in kanamycin, whereas the WT-Δcrp did not (Fig. 3B). Both these observations were consistent across multiple transductants tested (Fig. S11).
Both ΔcyaA and Δcrp, in the FusAP610T/A608E mutant backgrounds, had lower growth rates in kanamycin compared to FusAP610T/A608E and FusAA608E-CyaAN600Y. The presence of a similar growth defect in the wildtype strain containing these gene knockouts, during growth in the absence of kanamycin, indicated that the growth defect was specific to the gene knockouts (Fig. 3C and S12), and not the mutants isolated.
Together, we conclude that the evolved point mutation in cyaA results in kanamycin resistance via an altered adenylate cyclase and subsequently altered CRP function. This mutation has the added benefit of not conferring the growth defect associated with the knockouts of either of these genes.
We next compared the transcriptomes of the CyaAN600Y mutant with the transcriptomes of the ΔcyaA and Δcrp strains. Surprisingly, fold changes of genes in CyaAN600Y, in comparison to the wildtype, negatively correlated with those in the ΔcyaA and Δcrp strains (Fig. 3D and E). This correlation was low but significant. This is consistent with the results of our comparison with the list of CRP targets available in the RegulonDB database. As expected, genes that are activated by cAMP-CRP are down-regulated in the ΔcyaA and Δcrp strains (Fig. 3F). However such genes are mostly up-regulated in the CyaAN600Y mutant (Fig. 6C). This stands for the FusAA608E-CyaAN600Y mutant as well (Fig. S13).
Thus although the levels of cAMP are low in the CyaAN600Y mutant (Fig. 3A), their transcriptomes are opposite to that of ΔcyaA / Δcrp (Fig. 3D and E). This is contradictory to expectation, more so since since the FusAP610T/A608E-ΔcyaA / Δcrp strains grow better in kanamycin than the FusAP610T/A608E mutants. It is possible that this phenotypic similarity of the FusAP610T/A608E-ΔcyaA / Δcrp strains to the FusAP610T-CyaAN600Y mutant is coincidental and that the full knockout and the point mutant confer resistance through distinct means. We ensured the absence of other mutations in the genomes of the ΔcyaA / Δcrp transductants using whole genome sequencing (Fig. S14) and the absence of other mutations in the FusAA608E-CyaAN600Y and CyaAN600Y strains by calling mutations from the RNA-seq data.
This unexpected behaviour of the CyaAN600Y mutation could stem from the fact that the CyaAN600Y mutation is a point mutation and not a knockout. As a result, the adenylate cyclase protein would still be produced, and this could have alternative functions. There could also be feedback involved: although not called up-regulated, the fold changes of both cyaA and crp are higher by around 2-fold in the CyaAN600Y and FusAA608E-CyaAN600Y mutants (Fig. S15). In line with this, the promoter activities of these two genes were also higher in the CyaAN600Y mutant (Fig. S15A and B), as revealed by promoter-GFP fusions. Thus, further work is required to understand the function of CyaAN600Y.
The FusAA608E-TopAS180L mutant displays increased negative supercoiling
The bacterial chromosome is a highly condensed and supercoiled DNA molecule (Woldringh, 2002; Thanbichler, Wang & Shapiro, 2005; Thanbichler & Shapiro, 2006; Toro & Shapiro, 2010). The extent of supercoiling can influence gene expression (Travers & Muskhelishvili, 2005), and is known to be affected by various environmental factors (Rui & Tse-Dinh, 2003) such as osmotic stress (McClellan et al., 1990; Cheung et al., 2003), starvation (Balke & Gralla, 1987), temperature (McClellan et al., 1990) and oxygen tension (Hsieh, Burger & Drlica, 1991). Global supercoiling of the chromosome is maintained by a balance between the activities of enzymes called topoisomerases. DNA gyrase (Topoisomerase II, encoded by the genes gyrA and gyrB) catalyzes an increase in negative superhelicity. Topoisomerases I (topA), III (topB) and IV (parC and parE) relax negative supercoils (Travers & Muskhelishvili, 2005; Gubaev & Klostermeier, 2014). Topoisomerase IV can also relax positive supercoils, which is its preferred substrate (Crisona et al., 2000) and is involved in decatenation and unknotting of DNA (López et al., 2012). The decatenation activity is triggered by an increase in negative supercoiling (Zechiedrich, Khodursky & Cozzarelli, 1997). The levels of these enzymes in the cell are maintained by a homeostatic feedback from the supercoiled state of the chromosome (Menzel & Gellert, 1987; Tse-Dinh & Beran, 1988; Pruss & Drlica, 1989; Snoep et al., 2002).
One of the second site mutations in the FusAA608E mutant lies in Topoisomerase I (TopAS180L). To understand the supercoiling state of the chromosome in the FusAA608E-TopAS180L mutant we employed the cholorquine gel assay (Hsieh, Burger & Drlica, 1991) to look at the supercoiling of a reporter plasmid – pUC18 (Fig. 4A). When plasmid DNA is run through an agarose gel containing 2.5 μg/ml chloroquine by electrophoresis, a separation of different topoisomers is achieved, where more supercoiled topoisomers run further than relaxed topoisomers. In both exponential and stationary phases of growth, we found that the pUC18 molecules were more negatively supercoiled, i.e. they ran further on the chlroquine gel, in the FusAA608E-TopAS180L mutant than in the wildtype or the single mutants in FusA.
In an earlier gene expression study, Peter et al. used topoisomerase targeting antibiotics and temperature sensitive DNA gyrase mutants to change the supercoiling of the E. coli chromosome, and profile the resulting changes in the transcriptome using microarrays (Peter et al., 2004). Their data consists of gene expression ratios obtained from microarrays, loaded with RNA from cells at multiple timepoints after treatment / temperature shift, with RNA from cells before treatment / temperature shift serving as a reference. We found that the gene expression profile of FusAA608E-TopAS180L mutant negatively correlates with that of Peter et al's novobiocin treated E. coli (Fig. 4B). Negative correlation with novobiocin treatment suggests that there is increased negative supercoiling in the cell, since novobiocin inhibits DNA gyrase. This view is supported by the expression levels of the topoisomerases themselves: as expected from a negative feedback in the presence of high negative supercoiling, the levels of gyrA and gyrB (DNA gyrase) are low and that of topA (Topoisomerase I) is high (GEO accession number GSE82343). Furthermore, we see that up-regulated genes in the mutant are AT rich (Fig S16), which is in accord with the fact that AT rich regions are more susceptible to unwinding in negatively supercoiled DNA. Finally, the FusAA608E-TopAS180L mutant shows a slight growth defect at a lower temperature (Fig. S17), which is in line with the known cold sensitivity of the topA deletion strain (Stupina & Wang, 2005).
Taken together, we show that the mutation in topA reduces its activity and results in increased negative supercoiling in the cell due to intact DNA gyrase function. The loss in activity could also result in increased R-loop formation in the mutant since Topoisomerase I resolves R-loops (Massé & Drolet, 1999; Usongo et al., 2008). Increased translation may help reduce R-loops (Massé & Drolet, 1999; Broccoli et al., 2004; Gowrishankar & Harinarayanan, 2004; Gowrishankar, Leela & Anupama, 2013). This might even potentially explain the possible genetic interaction between fusA and topA. Increased dosage of genes encoding Topoisomerase IV (parC and parE) have been shown to relieve growth defects caused by inactivation of topA (Kato et al., 1990). We also see an increased expression of parC and parE in the FusAA608E-TopAS180L mutant (GEO Series accession number number GSE82343).
To our knowledge, we are the first to explore the link between chromosomal supercoiling and aminoglycoside resistance. Since we do not have a TopAS180L single mutant we don't understand the effects of the FusAA608E mutation on the TopAS180L mutation. Further experiments will help work out the biochemical activity of the TopAS180L mutant, its genetic interaction with FusAA608E, and the mechanism of resistance of this mutant.
Similarities among mutants
The number of differentially expressed genes varied substantially among the mutants (Fig. 5A). The CpxAF218Y, CyaAN600Y and FusAA608E-TopAS180L mutants had the most number of differentially expressed genes. The FusAA608E, RpoDL261Q and FusAA608E-RpoDL261Q mutants had the least number of differentially expressed genes.
We were surprised that the rpoD mutants had the least number of differentially expressed genes considering the role of this gene as a transcription initiation factor for around 50% of the genes in E. coli, particularly those expressed in exponentially growing cells. How this mutation results in resistance remains elusive. Nonetheless, the location of the mutation is interesting. The mutation resides in a highly conserved residue in the large non-conserved domain of this protein (Fig. S19). While no clear function is ascribed to this domain, certain residues in this domain have been shown to be involved in promoter escape (Leibman & Hochschild, 2007), and one of these residues lies very close to the mutated residue mentioned in our study. It is difficult to hypothesise how a residue involved in allowing the escape of the RNA polymerase from the housekeeping sigma factor to facilitate transcription initiation, must be involved in aminoglycoside resistance (unless this has something to do with coupled transcription and translation), but in the absence of other information remains a valuable lead.
Clustering based on correlation between fold changes of all genes relative to the wildtype across mutants tends to cluster the dataset according to the mutants, but not always so (Fig. 5B). Notably, fold changes of differentially expressed genes in the CyaAN600Y mutant are well correlated with that in the CpxAF218Y mutant. This further highlights the link between CRP and the Cpx response mentioned earlier (Strozen, Langen & Howard, 2005). Thus, as an outcome of the evolution experiment, we see two different mutations resulting in similar transcriptional states. The correlation between the FusAA608E-CpxAF218Y, FusAA608E-RpoDL261Q and FusAA608E-TopAS180L mutants were high, offering another example of converging effects of different mutations.
Effect of second site mutants on gene expression and dependence on EF-G
We evaluated the impact of the FusAA608E mutation on the transcriptomes of the double mutants in detail. The FusAA608E single mutant had roughly thirty genes up and fifty genes down-regulated (Fig. 5A). Sequencing of the transcriptomes of single and double mutants enabled us to look at interactions of the FusAA608E mutant with the second site mutations in terms of fold changes of differentially expressed genes. From the transcriptomes of exponentially growing cells, we saw clear interactions of the primary kanamycin resistance conferring mutation in fusA with the second site mutations in cyaA, cpxA and rpoD.
To assess the extent to which the transcriptomes of the FusAA608E single mutant and CyaAN600Y / CpxAF218Y / RpoDL261Q single mutants explain the gene expression state of the FusAA608E-CyaAN600Y / CpxAF218Y / RpoDL261Q double mutants, we plotted the log2 fold change in the double mutant against the sum of the log2 fold changes in the FusAA608E single mutant and the second site single mutants (Fig. S22D, H and L). In the absence of a genetic interaction between the two single mutants, we would expect the scatter plot to lie along the 45° line. We find that this is not the case in each of the three double mutants we evaluated. In other words, the absolute difference in log2 fold change in expression between the double mutant and the sum of the two corresponding single mutants is significantly different from zero (Wilcoxon signed rank test P value < 2.2 x 10-16, Fig. S22). These indicate that the FusAA608E background affects the transcriptional state of the CyaAN600Y / CpxAF218Y / RpoDL261Q single mutants in a non-additive manner.
More specifically, we saw that the fold changes of genes differentially expressed in the CyaAN600Y mutant were reduced in the FusAA608E-CyaAN600Y mutant (Fig. 6A). Most of these genes were not differentially expressed in the FusAA608E mutant (Fig. 6B and C).
We saw that this was the case with the CpxAF218Y and FusAA608E-CpxAF218Y mutants as well (Fig. 6D-F). As a result of this, the number of differentially expressed genes in the FusAA608E-CyaAN600Y or FusAA608E-CpxAF218Y mutants is lesser than that in the CyaAN600Y or CpxAF218Y mutants (Fig. 5A). The effect of the mutation in fusA on the fold changes of genes seems to be more extreme in the case of the mutation in cpxA than cyaA, since FusAA608E-CpxAF218Y does not correlate as well with CpxAF218Y as does FusAA608E-CyaAN600Y with CyaAN600Y (Fig. 5B). These observations bear in part from the fact that the fold changes of genes differentially expressed in the CyaAN600Y and CpxAF218Y mutants are opposite to the fold changes of these genes in the FusAA608E mutant (Fig. S23A and B), even though they were not classified as differentially expressed in FusAA608E. In other words, a gene that is up-regulated in CyaAN600Y / CpxAF218Y displays a mild negative fold change in FusAA608E; whereas one that is down-regulated in the former shows a slight positive fold change in the latter (Fig. S23A and B).
We notice that the effect of FusAA608E on RpoDL261Q is opposite to that on CyaAN600Y / CpxAF218Y. Genes down-regulated in the RpoDL261Q mutant were further down-regulated in the FusAA608E-RpoDL261Q mutant (Fig. 6G-I). In this case, many down-regulated genes in RpoDL261Q or FusAA608E-RpoDL261Q were also down-regulated in the FusAA608E mutant (Fig. 6 H and I). This bears from the fact that genes down-regulated in the RpoDL261Q mutant are also down-regulated in the FusAA608E mutant, thus leading to more extreme down-regulation in the FusAA608E-RpoDL261Q mutant (Fig. S23C).
Unfortunately we do not have information of this sort for the FusAA608E-TopAS180L mutant since we did not have the corresponding second site single mutant. However, it is possible that the interaction between the mutation in fusA and the mutation in topA must be extreme since we were unable to construct the topA single mutant.
Thus the mutation in a translation elongation factor has a large effect on the transcriptional state of the cell, beyond that indicated by threshold-dependent calls of differential expression, presumably through feedback from levels of partially folded proteins. The second-site mutations display epistasis with the FusAA608E mutation, as manifested in their transcriptomes.
Genes with known roles to play in aminoglycoside resistance are mis-regulated in the mutants
Are the mechanisms of kanamycin resistance different or common across our set of mutants? To understand this, we looked at the kinds of genes differentially expressed in these mutants using gene ontology (GO) or known transcription factor-target interactions to guide us.
Common trends in terms of shared gene functions are outlined in (Fig. 5C) and a more detailed list is provided in Fig. S20. In general, we found several metabolism related genes mis-regulated in the mutants. Mis-regulated genes with known roles in aminoglycoside resistance include genes involved in oxidative phosphorylation, protein folding and motility.
Genes involved in oxidative phosphorylation are down-regulated in the FusAA608E mutant. Oxidative phosphorylation produces reactive oxygen species (ROS), as a by-product, which is thought to be involved in antibiotic mediated killing (Kohanski et al., 2007). A functional proton motive force generated by oxidative phosphorylation is required for aminoglycoside uptake (Taber et al., 1987). Furthermore, the components of the electron transport chain (ETC) tend to be Fe-S proteins and are membrane associated. Mistranslation of membrane associated proteins induced by aminoglycosides, and hence their misfolding could affect the integrity of the cell membrane and result in hydroxyl radical mediated cell death (Kohanski et al., 2008). Misfolded versions of these proteins could also release Fenton reactive Fe2+, which in turn could again result in hydroxyl radical generation (Kohanski et al., 2007). Thus, there are many ways in which down-regulating genes involved in oxidative phosphorylation, as in the FusAA608E mutant, can alleviate the lethal effects of kanamycin.
Apart from these genes, genes associated with enterobactin biosynthesis or iron homeostasis are known to affect intracellular ROS levels (Méhi et al., 2014). It is possible that the up-regulation of these genes in the FusAA608E, FusAA608E-CpxAF218Y and FusAA608E-TopAS180L mutants could reduce the production of ROS in the cells via sequestration of free Fe2+ and hence contribute to resistance.
The downregulation of oxidative phosphorylation and the up-regulation of siderophore metabolism genes are in line with the hypothesis of oxidative damage mediated cell death in the presence of antibiotics. While this theory is fiercely disputed, it is possible that ROS aggravate the effect of antibiotics, if not dominate it. For example, Ling et al., show that aminoglycoside induced protein aggregation is prevented by hydrogen peroxide quenchers (Ling et al., 2012). Dealing with ROS might result just in that extra protection that cells need in the presence of aminoglycosides.
ROS is a double edged sword. While it can damage cellular macromolecules and confer stress, the outcome of this stress could also result in an increase in mutagenesis (Kohanski, DePristo & Collins, 2010). Thus if these mutants do indeed reduce oxidative stress, it is quite possible that they will slow down further adaptation to kanamycin by reducing the occurrence of resistance conferring mutations. This however remains to be tested.
We see a strong and consistent down-regulation of motility associated genes, in all except the cyaA mutants. Using a transposon mutagenesis screen Shan et al., show that the loss of these genes results in decreased persister formation in aminoglycosides (Shan et al., 2015), and thus their down-regulation in the mutants is contrary to our expectation. However these genes are up-regulated in the CyaAN600Y and FusAA608E-CyaAN600Y mutants and there they could contribute to resistance. Notably, motility genes are not found in the list of knockouts sensitive to aminoglycosides provided by Tamae et al. (Tamae et al., 2008), or in the list of loci that significantly affect susceptibility to aminoglycosides in the transposon insertion screen performed by Girgis et al (Girgis, Hottes & Tavazoie, 2009).
Resistance to aminoglycosides can be provided by genes involved in protein transport/ folding/ secretion as these could help refold misfolded proteins (Goltermann, Good & Bentin, 2013). However, we see a down-regulation of these genes in the FusAA608E-RpoDL261Q, FusAA608E-CpxAF218Y and FusAA608E-TopAS180L mutants, and this is contrary to our expectation.
Conclusions
We saw that mutations that modify global transcriptional regulatory networks increase the resistance of the kanamycin conferring mutation in the translational elongation factor EF-G. These “second-site” mutations resulted in large changes in gene expression and displayed epistatic interactions with the mutation in EF-G, which itself drove expression changes of many genes. We show that these second site mutations reduce the activities of CyaA (adenylate cyclase) and TopA (Topoisomerase I), and increase the activity of CpxA. Further evolution of an EF-G mutant in higher concentration of kanamycin suggested CpxA as the next target for an increase in resistance, with many high frequency mutations located in the helix-I domain of this protein. Although the activity of the mutated adenylate cyclase is reduced in the CyaA mutant that we isolated, many CRP targets are unexpectedly up-regulated and this contradictory behaviour needs further investigation. We suggest that FusAA608E-TopAS180L results in a reduction in the function of Topoisomerase I. Many genes with known roles in aminoglycoside resistance, for example genes involved in oxidative phosphorylation and enterobactin metabolism, were mis-regulated in these mutants thus pointing to possible mechanisms of resistance.
Accession Numbers
RNA-seq data can be found on the NCBI Gene Expression Omnibus database (Edgar, Domrachev & Lash, 2002; Barrett et al., 2013) with the GEO Series accession number GSE82343 (http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE82343). Deep-sequencing data of populations in the 15-kan evolution experiment can be found with the accession number SRP076371 and deep-sequencing data of some strains can be found with the accession number SRP087477 from the NCBI Sequence Read Archive.
Acknowledgements
We thank Parul Singh, NCBS, for providing E. coli MG1655 ΔcyaA and Δcrp strains and for sharing the transcriptome data (unpublished) of these strains. We thank Sunil Laxman, NCBS, for his guidance with cAMP estimation experiments. We thank Reshma T. V. and Revathy Krishnamurthy, NCBS, for help with some experiments. We thank Charles Dorman and Aoife Colgan, Trinity Collge Dublin, for their help with the chloroquine gel assay. Next-generation sequencing services were provided by C-CAMP and Genotypic, India.
Footnotes
National Centre for Biological Sciences, Tata Institute of Fundamental Research, GKVK, Bellary Road, Bangalore, Karnataka 560065, India Email id: aswin{at}ncbs.res.in