Abstract Purpose Colistin is one of the last-resort antimicrobial agents that combat the increasing threat of multi-drug resistant (MDR) gram-negative bacteria. Based on the known mechanism of colistin resistance which contributes to chromosomal mutations involved in the synthesis and modification of lipopolysaccharide (LPS), we explored the regulatory genes mediate colistin resistance, by whole genome sequencing and transcriptome analysis. Materials and Methods In this study, a colistin-resistant (Col^r) strain Escherichia coli ATCC 25922-R was generated from colistin-sensible (Col^s) strain E. coli ATCC 25922 by colistin induction. We compared the genome and transcriptome sequencing result from Col^s and Col^r strain. MALDI-TOF mass spectrometry was used to detect LPS. Results Genomic analysis and complementation experiment demonstrated the PmrB amino acid substitution in ATCC 25922-R (L14R) conferred the colistin resistance phenotype. Results of RNA sequencing (RNA-Seq) and comparative transcriptome analysis indicated that the two-component system EvgS/EvgA is highly involved in the global regulation of colistin resistance. Conclusion This study demonstrated that PmrB L14R amino acid substitution resulted in colistin resistance, and two-component system EvgS/EvgA might participate in colistin resistance in E. coli. Keywords: colistin resistance, Escherichia coli, PmrAB, EvgS/EvgA Introduction Multi-drug resistant (MDR) bacteria are a global healthcare concern responsible for increased morbidity and mortality, hospitalization, and huge financial loss. In order to combat increasing rise of MDR bacteria, various therapies have been developed to inhibit MDR bacterial infection including traditional antibiotics, phage therapies, monoclonal antibodies (mAbs), immune stimulation, vaccines and antimicrobial peptides.[32]^1–4 But there are very few phages available to doctors and the number of currently licensed mAbs is limited in clinical practice. In terms of traditional antibiotics, only a handful of last-line antibiotics, such as colistin and tigecycline, are proven to be effective in MDR bacteria treatment.[33]^5 Colistin (polymyxin E) is a decades-old antimicrobial agent, intensively used in veterinary medicine and animal husbandry.[34]^6 In humans, the global spread of MDR Gram-negative bacteria with limited therapeutic options has resulted in the return of colistin use regardless of its documented nephrotoxicity.[35]^7 Colistin is a cationic polypeptide that disrupts membrane integrity through displacement of cations like Mg^2+ and Ca^2+ in the outer membrane, leading to cell lysis.[36]^5^,[37]^8 Two widely accepted mechanisms of colistin resistance that have been described in Gram-negative bacteria are as follows: chromosomal mutations in genes involved in the synthesis and modification of lipopolysaccharide (LPS) and the acquisition of mobile colistin resistance (mcr) genes encoding phosphoethanolamine transferases, resulting in a more cationic charged LPS or loss of LPS that confers reduced susceptibility to colistin.[38]^8 The critical step of colistin resistance is the modification of negatively charged lipid A, the endotoxic component, via diverse routes, particularly through derivation of lipid A phosphate moieties with a sugar or ethanolamine.[39]^9 The two-component regulatory systems PmrAB and PhoPQ regulate expression of the genes (pmrC, arn and eptA) that mediate phosphoethanolamine modification of lipid A, which results in a decreased binding to the bacterial outer membrane surface.[40]^10^,[41]^11 Mutations in pmrAB, phoPQ have been identified in several colistin resistant bacteria, including Escherichia coli, Klebsiella pneumoniae and Acinetobacter baumannii.[42]^12–14 In the transcriptomes of colistin-resistant K. pneumoniae, an elevated expression of pmrH orperon was responsible for the biosynthesis of Ara4N and modification of the lipid A component.[43]^12 In A. baumannii, up-regulated expression of pmrAB and lpxB (enzyme involved in the lipid A biosynthesis pathway) genes associated with colistin resistance has also been reported.[44]^15 Recent studies of colistin resistance mostly focus on the plasmid-encoded mobilized colistin resistant gene mcr-1 in many aspects, such as its prevalence, antibiotic resistance mechanism, and its transmission between different bacteria. But in fact, chromosomal gene mutation mediated colistin resistance always possesses higher level of resistance and is not easily lost in the process of passage. Therefore, it is worth studying the mechanisms of chromosome mediated colistin resistance, especially the less studied regulation profile. Here, by treating E. coli with consistent colistin stimulation which imitates the clinical treatment condition, we obtained the colistin-resistant strain E. coli ATCC 25922-R. Using genomic, transcriptomic, bioinformatics and other approaches to study the mechanism of chromosome-related colistin resistant genes, we successfully explored the genetic basis and analyzed the global transcription profile to figure out new genes responsible for colistin resistance. Our results revealed that it is highly possible that two-component system EvgS/EvgA participates in the regulation of colistin resistance in E. coli. Materials and Methods Strains and Antimicrobial Susceptibility Testing The strain E. coli ATCC 25922 was used to conduct this study. Laboratory evolution of mutant with reduced colistin susceptibility, E. coli ATCC 25922-R was generated by broth step-wise induction.[45]^16 Briefly, a single colony of E. coli ATCC 25922 was grown in Muller-Hinton (MH) broth overnight at 37°C, and cultures were diluted 1:100 in MH broth containing serially increasing concentrations of colistin, starting at the one-half MIC of the respective isolate, and doubling every 24 hours until bacterial growth was completely inhibited. Cultures were plated on MH agar plates and a colony, namely E. coli ATCC 25922-R was stored for the following study. Colistin MIC determination was performed by broth microdilution methods in accordance with the Clinical and Laboratory Standards Institute 2019 (CLSI 2019). Genomic Analysis and Gene Complementation Genomic DNA of E. coli ATCC 25922 and Col^r strain E. coli ATCC 25922-R were extracted using Gentra Puregene Yeast/Bact. Kit (Qiagen, Hilden, Germany) according to the manufacturer’s instructions, from overnight cultures. After library preparation, genome of ATCC 25922 was sequenced using the PacBio RS II and Illumina Hiseq platform (Illumina, San Diego, CA, USA), and the genome of ATCC 25922-R was sequenced by Illumina Hiseq platform. Library construction and sequencing was performed at Beijing Novogene Bioinformatics Technology Co. Ltd. The filtered reads were assembled to generate one contig without gaps by SMRT 2.3.0. The Illumina-generated contigs were mapped to the PacBio-generated contigs for correction. Coding genes were annotated using Rapid Annotation using Subsystem Technology (RAST). For the genome comparison, assembled genomes were annotated using Prokka Software for unified comparison.[46]^17 Then Roary, a high speed pan-genome pipeline was used to cluster the genes encoding complete protein sequences.[47]^18 Complementation of pmrB was conducted by plasmid pHGE-Ptac.[48]^19 The gene of interest was amplified and inserted into MCS of pHGE-Ptac under the control of the tac promoter. The resulting vectors were transferred into its corresponding mutant strain via electro-transformation. Real-Time PCR Overnight cultures of the strains were diluted 1:100 and subcultured in MH medium for ~3 hrs at 37°C (absorbance at 600 nm [OD600] ~ 0.6) with or without colistin. Cells were collected at 4°C by centrifuging at 10000 rpm for 1 min, and total RNA of E. coli ATCC 25922 and E. coli ATCC 25922-R were extracted with RNeasy Mini Kit (QIAGEN, Alameda, USA) as the production protocol told. RNA degradation and contamination were monitored on 1% agarose gels. cDNA was created from each RNA sample. RT-qPCR was performed using an ABI 7300 96-well RT-qPCR system (Applied Biosystems) with SYBR Premix Ex Taq II (cat. no. RR820A; TaKaRa). mRNA expression levels of genes pmrB, relA, evgS and evgA were examined using real-time PCR primers (EC-gene-RT-F/R) listed in [49]Supplementary Table S1. Relative expression values of each gene were normalized against the 16S rRNA gene of E. coli ATCC 25922 using the standard curve method. All samples were tested in triplicate, and the data were represented as means±SD (standard deviation). RNA-Seq Experiments For mRNA sequencing, overnight cultures of the strains were diluted 1:100 and subcultured in MH medium to OD600 ~ 0.5. Then the culture was induced with (ATCC 25922-R) or without (ATCC 25922 and ATCC 25922-R) 2 mg/L colistin for half an hour. Total RNA was extracted with RNeasy Mini Kit (QIAGEN, Alameda, USA) as the production protocol told. cDNA libraries were constructed and were sequenced on an Illumina HiSeq platform. Reads from each strain were mapped to the corresponding genome assembly and RPKM (reads per kilobase of transcript per million mapped reads) values were calculated based on the length of the gene reads count mapped to the gene. The cutoff for gene expression was set at an RPKM value of at least 10. The raw sequencing data were deposited in the NCBI Sequence Read Archive (BioProject accession number PRJNA681352). Genes with significant expression RPKM values were identified. Gene transcripts with ≥ 2-fold change in expression and a q value of ≤ 0.05 were considered as differentially expressed. Gene ontology (GO) was analyzed using the GOseq R package. GO terms with p-value less than 0.5 were considered significantly enriched by differentially expressed genes. KEGG pathway mapping analysis was performed to examine the associated pathways and functions in the differentially expressed genes. Extraction of LPS-Lipid A and MALDI-TOF Analysis The crude LPS was isolated by hot phenol/water extraction.[50]^20 Briefly, overnight bacterial cultures were collected for LPS isolation. Bacterial cells (1~10 mg) were washed with Tris-HCl (30mM, pH 8.0) twice, centrifuged at 6000 rpm for 10 min, and resuspended in 0.4 mL of Tris-HCl containing 20% sucrose. Bacterial samples were incubated for 0.5 h after adding 40 μL of lysozyme (1mg/mL, 100 mM EDTA, pH 7.3), and frozen at −80°C for 0.5 h, then thawed at room temperature. Following several freezing and thawing cycles, the samples were lysed by sonication and cell lysate was removed for 15 min at 6000 rpm. The supernatant was further centrifuged at 16,000 rpm for 1 h to precipitate the crude LPS. Then the crude LPS was freeze-dried and resuspended in a solution of 20 mM Tris-HCl with 0.2% SDS. DNase I (25 μg/mL) and RNase A (100 μg/mL) were added and the solution was incubated for 2h at 37°C after following a removal of protein contaminants via treatment with proteinase K at 37°C for 1h. To cleave the Kdo linkage, the crude LPS was heated in 10 mM sodium acetate buffer (pH 4.5) with aqueous 0.2% SDS at 100°C for 1 h and then precipitated with acidified ethanol (100 μL) to remove SDS by centrifugation at 5000 rpm for 5 min. The resulting pellets were washed with 95% ethanol twice and freeze-dried for storage. Negative ion MALDI-TOF mass spectra were used to analyze the chemical structures of lipid A from different strains. Lipid A fractions were dissolved in 20 μL of chloroform/methanol (2:1) solution and mixed with 2,5-dihydroxybenzoic acid matrix in the solution of chloroform/methanol/water (3:1.5:0.25) (20 mg/mL). One microliter of lipid A solution was loaded to produce the MS spectrum. An average of 500 shots was summed into a single mass spectrum. Results Generation of Colistin Resistant Strain and Complementation E. coli ATCC 25922 was treated with colistin to obtain colistin resistant strain E. coli ATCC 25922-R as described in materials and methods. Its flow chart was shown in [51]Figure 1. The colistin MICs of E. coli ATCC 25922 and E. coli ATCC 25922-R were 0.25 mg/L and 64 mg/L, respectively. Comparative genomic analysis observed a mutation of PmrB (L14R) in ATCC 25922-R, which may responsible for the covalent modification of phosphate groups on lipid A. We also found an additional mutation in RelA (R137W), the GTP pyrophosphokinase, which is involved in the synthesis of guanosine 3ʹ,5ʹ-bispyrophosphate (ppGpp) during the stringent response to amino acid starvation[52]^21^,[53]^22 ([54]Figure 2A). Complementation of pmrB gene amplified from ATCC 25922 to ATCC 25922-R restored the susceptibility of ATCC 25922-R (colistin MIC of the complementary strain is 0.5 mg/L), which demonstrated that the point mutation of PmrB (L14R) in this study contributed to the colistin resistant phenotype of ATCC 25922-R. Therefore, the identification of the mutation in pmrB is involved in colistin resistance in ATCC 25922-R isolated after in vitro colistin exposure. Figure 1. [55]Figure 1 [56]Open in a new tab Flow chart of colistin resistant strain induction assay. Colistin concentration was started at one-half MIC of E. coli ATCC 25922, doubling every 24 hours until bacterial growth was completely inhibited. Cultures were plated on MH agar plates and the resistant colony was named E. coli ATCC 25922-R. Figure 2. [57]Figure 2 [58]Open in a new tab Point mutations in pmrB and relA of E. coli ATCC 25922-R (A) and gene expressions in E. coli ATCC 25922-R by quantitative RT-PCR (B). Relative expressions of genes were determined using 2^−ΔΔCt method. Error bars represent the standard deviations of three biological repeats. Expression Analysis of pmrB and relA Based on the prior knowledge of pmrB function reported previously, we inferred that this mutation might cause the transcriptional alteration in the pmrAB system. To evaluate the effect of this mutation on the induced Col^r strain, quantitative RT-PCR was performed using the primers designed for pmrB transcript. The Col^r strain displayed 2.3-fold increased expression of pmrB, which is consistent with activating mutations in pmrB ([59]Figure 2B). RT-PCR result showed no significant change in the expression of another mutated gene, relA ([60]Figure 2B). Since lipid A modification has been associated with colistin resistance, we analyzed lipid A moieties from E. coli ATCC 25922-R by MALDI-TOF mass spectrometry. Peak at m/z 1914.5 corresponded to the addition of one phosphoethanolamine (pEtN) moiety and to the phosphate group of the native lipid A, leading to an increase of +123 mass units compared to the mass of the major peak of native lipid A at m/z 1797.4. Two additional peaks at m/z 1934.4 and m/z 2164.5 corresponded to the addition of 4-amino-L-arabinose (L-Ara4N) to the phosphate of the native lipid A, generating an increase of +131 mass units compared to the native lipid A ([61]Figure S1). Both pEtN and L-Ara4N additions were detected in E. coli ATCC 25922-R, suggesting that pmrB mutation altered the lipid A structure with various forms. Transcriptome Characterization In order to gain a deeper insight into the mechanism of the E. coli ATCC 25922-R resistant to colistin and gene expression change under the clinical treatment of colistin, we performed RNA-seq analysis of three samples, E. coli ATCC 25922 (sample A), ATCC 25922-R (sample B), and ATCC 25922-R with colistin treatment under the dosage of 2 mg/L (sample C), a concentration that is used in clinical therapy with the aim to simulate medication in clinical practice, as described in materials and methods. Over 99% of all clean reads were aligned to reference genome of E. coli ATCC 25922. Each biological replicate was highly similar to each other (R[62]^2>0.95), which indicates the RNA-seq data were suitable for transcriptome analysis. The transcriptome comparisons were conducted between sample A and B, sample B and C. The expression profile in the two comparisons was shown in [63]Figure 3. Hierarchical clustering in the differentially expressed genes was analyzed and shown in the format of heat map observed in [64]Figure 4. Figure 3. [65]Figure 3 [66]Open in a new tab Difference in gene expression profile between the two groups. Sample A E. coli ATCC 25922. Sample B E. coli ATCC 25922-R. Sample C E. coli ATCC 25922-R grown with 2 mg/L colistin. The red and blue bars represent up- and down-regulated genes. Number labels represent the number of genes in each group. Figure 4. [67]Figure 4 [68]Open in a new tab Heat map of hierarchical clustering in differentially expressed genes in the groups. (A): E coli ATCC 25922 (sample A) and E. coli ATCC 25922-R (sample B); (B): E coli ATCC 25922-R (sample B) and E. coli ATCC 25922-R grown with 2 mg/L colistin (sample C). Blue represents down-regulated expression and red represents up-regulated expression, respectively, relative to that of the reference culture. In the comparison of sample B vs sample A, there were 278 differentially expressed genes, of which 59 were up-regulated and 219 were down-regulated ([69]Supplementary Table S2). Kyoto encyclopedia of genes and genomes (KEGG) was used to compare the transcriptome data. Most differentially expressed genes were focused on citrate cycle (TCA cycle) and oxidative phosphorylation, which indicates that these biological processes might be affected by colistin resistance ([70]Figure 4A). The top ten up-regulated and ten most down-regulated genes are listed in [71]Table 1. Among the most up-regulated genes, gene yibD (D1792_15900) encoding a glycosyltransferase responsible for the synthesis of LPS cores was shown to be significantly up-regulated in colistin resistant E. coli ATCC 25922-R. Elevated transcription of arn operon and eptA associated with lipopolysaccharide modification were observed as well, which might partly explain the enhanced colistin resistance trait in the induced Col^r strain. Other components of the PmrAB regulon, such as pmrD, showed no significant change in both strains. Most of the highly down-regulated genes were involved in glycolate utilization, an important energy source which provides an energetic advantage to bacterial species. The glc operon, consisting of GlcB encoding malate synthase G and the gene encoding glycolate oxidase, exhibited notable decline in transcriptional levels. Other genes participating in TCA cycle, such as D1792_24720 encoding succinate dehydrogenase, were down-regulated obviously. From these results, we inferred that E. coli ATCC 25922-R may reduce unnecessary energy demands to maintain the colistin resistance phenotype. Table 1. Top Ten Up- and Down-Regulated E. coli ATCC 25922-R (Sample B) Genes in Comparison with E. coli ATCC 25922 (Sample A) Rank Genes Log[2] Fold Change Annotation 1↑ yibD 3.8 Glycosyltransferase 2↑ D1792_18405 2.8 Maltoporin 3↑ D1792_19050 2.6 Lysine decarboxylase CadA 4↑ malE 2.3 maltose ABC transporter periplasmic protein 5↑ D1792_13205 2.3 Serine/threonine dehydratase 6↑ D1792_00690 2.2 Flagellar basal body rod protein FlgG 7↑ D1792_18170 2.2 Zinc resistance-associated protein 8↑ D1792_15315 2.2 Acid stress chaperone HdeB 9↑ hdeA 2.1 Acid-resistance protein 10↑ D1792_13305 2.1 Agas family sugar isomerase 1↓ D1792_00864 −4.5 Multiple stress resistance protein BshA 2↓ glcG −4.5 Malate synthase G 3↓ tnaA −3.8 Tryptophanase 4↓ D1792_15610 −3.7 Cold-shock protein 5↓ D1792_11760 −3.7 MarR family transcriptional regulator 6↓ glcB −3.6 Malate synthase B 7↓ D1792_24740 −3.4 Succinyl-CoA ligase subunit 8↓ D1792_12370 −3.2 Glycolate oxidase 9↓ D1792_16520 −3.0 Low affinity typtophan permease 10↓ D1792_12360 -2.6 Glycolate oxidase iron-sulfur subunit [72]Open in a new tab In E. coli ATCC 25922-R and its counterpart treated with 2 mg/L colistin (sample C vs sample B), a distinct transcriptional pattern was observed. Only 54 up-regulated genes and 5 noticeably down-regulated genes were observed, characterized by the elevated transcription of glycosyltransferase, which is involved in colistin resistance ([73]Supplementary Table S3). Top ten genes that exhibited significant expression levels are listed in [74]Table 2. The Toll-like receptor homologous protein TcpC (D1792_06120) was greatly up-regulated in E. coli ATCC 25922-R grown with 2 mg/L colistin ([75]Table 2). Combined with the fact that TcpC was identified as a virulence factor of E.coli and interfered with the innate immune response of the host by interrupting the NF-κB signaling pathway,[76]^23 we speculated that the pathogenicity of E. coli ATCC 25922-R might be enhanced when treated with colistin. Furthermore, the transcriptional levels of proteins like XcbB (D1792_12290) belonging to K-antigen gene cluster and PapX (D1792_11760) encoding a fimbrial-specific inhibitor were markedly increased, indicating that serological phenotype and motility might be affected ([77]Table S2). The biological functions associated with differentially expressed genes were also analyzed in KEGG pathway ([78]Figure 5B). Among them, “ubiquitin mediated proteolysis” was the most highly represented category. Table 2. Top Ten Up-Regulated Genes in E. coli ATCC 25922-R Resistant Treated with 2mg/L Colistin (Sample C) Gene Log[2] Fold change Annotation D1792_27685 5.5 Hypothetical protein D1792_06175 4.9 Hypothetical protein clbA 4.6 Colibactin biosynthesis phosphopantetheinyl transferase D1792_22260 4.6 Hypothetical protein tdcR 4.4 Threonine dehydratase operon activator protein tcpC 4.4 Toll like receptor domain-containing protein D1792_06170 4.3 Replication protein D1792_12305 4.3 Glycerol-3-phosphate cytidylytransferase D1792_06960 4.1 Glycosyltransferase D1792_06970 4.0 Glycosyltransferase [79]Open in a new tab Figure 5. [80]Figure 5 [81]Open in a new tab KEGG pathway enrichment analysis of differentially expressed genes between the two groups. (A): Pathway enrichment genes for sample A (E. coli ATCC 25922) and sample B (E. coli ATCC 25922-R). (B): Pathway enrichment genes for sample C (E. coli ATCC 25922-R grown with 2 mg/L colistin) and sample B (E. coli ATCC 25922-R). Based on the knowledge that membrane transporters and two component systems (TCS) are closely connected with colistin resistance, we searched for these genes that changed expression levels both in sample B vs A and sample C vs B groups ([82]Table 3). Because there were only 59 genes that showed remarkably up-regulated expression, we set the value of Log2 fold change above 0.5 for screening condition in order to get a more comprehensive result about genes with changed expression level. The most distinctive difference was the expression of evgS (1.34-fold down-regulated and 0.71-fold up-regulated, respectively), encoding sensor histidine kinase EvgS of TCS EvgS/EvgA which confers acid resistance in E. coli. Moreover, we also noticed that the expression level of another AraC-XylS family transcription factor ydeO altered both in two groups, which was consistent with the previous research findings that ydeO expression is activated by TCS EvgS/EvgA.[83]^24 qRT-PCR experiment was performed to verify the transcriptome result ([84]Figure 6). According to the report that activated EvgS/EvgA promoted expression of PhoP-activated genes,[85]^25^,[86]^26 our data suggest that EvgS/EvgA might be involved in the colistin resistance by interacting indirectly with PhoQ/PhoP system. Table 3. Differentially Expressed Genes Both in Sample B vs A and Sample C vs B Gene ID Annotation Log[2] Fold Change B vs A C vs B ydeO Helix-turn-helix domain protein 1.89 −1.07 D1792_22035 Hypothetical protein 0.91 0.92 D1792_14815 Fimbrial family protein 0.86 0.64 D1792_15930 O-Antigen ligase family protein 0.62 0.59 D1792_15820 Hypothetical protein 0.52 0.54 D1792_03220 Hypothetical protein −0.56 1.08 D1792_11820 Fimbrial regulatory protein −0.74 0.78 D1792_22270 Putative membrane protein −0.85 0.55 D1792_06985 Oligosaccharide repeat unit polymerase family protein −0.87 2.20 D1792_26225 Hypothetical protein −1.0 2.67 D1792_19485 Bacterial regulatory tetR family protein −1.18 0.90 D1792_27530 PI protein −1.33 1.16 evgS Sensor protein −1.34 0.71 D1792_11570 L-asparaginase −1.47 0.63 D1792_05880 Helix-turn-helix domain protein −1.69 1.79 D1792_12250 Hypothetical protein −1.89 1.07 D1792_00210 Helix DNA-binding domain protein −2.06 2.13 papE Fimbrial protein −3.07 2.19 [87]Open in a new tab Figure 6. [88]Figure 6 [89]Open in a new tab Gene expressions of TCS EvgS/EvgA in E. coli ATCC 25922 and E. coli ATCC 25922-R in comparison with their counterparts by quantitative RT-qPCR. Relative expressions of genes were determined using 2^−ΔΔCt method. Error bars represent the standard deviations of three biological repeats. Discussion Antibiotics like colistin are the last resort to treat clinical infections caused by carbapenem-resistant Enterobacteriaceae (CRE). However, the new emergence of resistance to colistin severely restricts therapeutic options. Among Enterobacteriaceae,E. coli tops the list in causing infections because of high prevalence, multidrug resistance and rapid transfer or acquisition of antimicrobial resistant traits through horizontal gene transfer. The mechanism of colistin resistance employed by the majority of bacteria can be explained in two ways: chromosomal point mutations in pmrA/pmrB and phoP/phoQ; and plasmid mediated colistin resistant mcr-1 and mcr-2 genes. Hence, most of the studies are focused on alterations in the expression and regulation mode of these genes. There are relatively few studies which have investigated colistin resistance in global transcriptome of E. coli. In this study, we aimed to identify two distinct transcription profiles by comparing whole genomic and transcriptomes from colistin-susceptible and colistin-resistant strains. The mutation at the position of 14th amino acid substitution of PmrB from Leu to Arg has been reported in E. coli previously,[90]^27^,[91]^28 and this alteration might lead to a constitutive activation of PmrB sensor that is responsible for colistin resistance in E. coli, which implicates the ability of clinical strains to evolve to a Col^r phenotype. The mechanism by which the Leu14Arg replacement alters the functions of PmrB remains unknown. This mutation is located at the amino-terminal protein portion of cytoplasmic secretion signal domain of PmrB, which remarkably altered the structure of the cytoplasmic domain and downstream regions. The mutations in the PmrB have previously been reported to be associated with acquisition of a colistin resistance phenotype in other pathogenic species including P. aeruginosa, A. baumannii and E. coli, underscoring the role of PmrB as an important mutational target in the evolution of colistin resistance in Gram-negative pathogens.[92]^14^,[93]^29^,[94]^30 In addition, our previous data indicated that mutations in PmrB would alter the expression level of pmrAB operon and its downstream genes in the mutants.[95]^18 Previous studies have revealed that Pmr mutation leads to the composition alteration of lipid A in several gram-negative bacteria, which reduces LPS affinity for colistin by reducing positive charges.[96]^8^,[97]^31 As we expected, our data also showed the lipid A modification with L-Ara4N and pEtN in Col^r strains, which indicates that lipid A aminoarabinosylation would be sufficient to confer colistin resistance. The comparative transcriptome analysis discovered interesting genes that might be involved in colistin resistance in E. coli. Transcriptional level of gene yibD encoding glycoslytransferases regulated by PmrA increased nearly 16-fold in Col^r strain, which implicates increased production of LPS synthesized by the sequential addition of sugar moieties by glycosyltransferases. It is worth noting that the expression of two-component system EvgS/EvgA was strongly affected in E. coli ATCC 25922-R. The EvgS/EvgA two-component system signal transduction regulates genes encoding the glutamate-dependent acid resistance system and a number of drug efflux pumps in response to low pH and antibiotic stress. Several studies have revealed that EvgS/EvgA system interacts with PhoQ/PhoP system by enhancing the expression of PhoP regulons via the small connecter protein SafA, signal transduction cascade between EvgS/EvgA and PhoQ/PhoP TCSs in E. coli.[98]^25 Another report showed that overexpression of EvgA is known to induce multidrug resistance by up-regulating the multi-drug efflux pump genes.[99]^32 Moreover, a study reported that regulator YdeO activated by EvgS also contributes to multi-drug resistance through the activation of MdtEF efflux pump.[100]^33 Therefore, combined with these studies, we hypothesize that EvgS/EvgA might participate in colistin resistance either by regulating the multi-drug efflux protein or by interacting with TCS PhoQ/PhoP in E. coli. The biological function of the EvgS/EvgA system in colistin resistance needs further investigation. These findings will contribute to our understanding of the mechanism underlying the occurrence of colistin resistance. Conclusion In conclusion, our findings revealed two new mutations in the genome of colistin-resistant E. coli, and analyzing transcriptome profiles of colistin-resistant E. coli under the treatment of colistin, which indicated that two-component system EvgS/EvgA might be responsible for colistin resistance in E. coli. Acknowledgment