Analysis of a complete library of putative drug transporter genes in Escherichia coli

The complete sequencing of bacterial genomes has revealed a large number of drug transporter genes. In Escherichia coli, there are 37 open reading frames (ORFs) assumed to be drug transporter genes on the basis of sequence similarities, although the transport capabilities of most of them have not been established yet. We cloned all 37 putative drug transporter genes in E. coli and investigated their drug resistance phenotypes using an E. coli drug-sensitive mutant as a host. E. coli cells transformed with a plasmid carrying one of 20 ORFs, i.e., fsr, mdfA, yceE, yceL, bcr, emrKY, emrAB, emrD, yidY, yjiO, ydhE, acrAB, cusA (formerly ybdE), yegMNO, acrD, acrEF, yhiUV, emrE, ydgFE, and ybjYZ, exhibited increased resistance to some of the 26 representative antimicrobial agents and chemical compounds tested in this study. Of these 20 ORFs, cusA, yegMNO, ydgFE, yceE, yceL, yidY, and ybjYZ are novel drug resistance genes. The fsr, bcr, yjiO, ydhE, acrD, and yhiUV genes gave broader resistance spectra than previously reported.     

Null mutations in the essential gene yrfF (mucM) are not lethal in rcsB,yojN or rcsC strains of Salmonella enterica serovar Typhimurium

Insertion of factor MudJ in the intergenic region between divergent genes yrfF and yrfE, at centisome 76 in the genome of Salmonella enterica serovar Typhimurium LT2, confers the characteristics recently described for mucM mutants, i.e. mucoidy and resistance to mecillinam. Cloning of the intergenic region plus either the yrfF or the yrfE gene in a multicopy plasmid showed that only the plasmid carrying the yrfF gene complemented mucM mutants, thus suggesting that mucM mutations are in fact yrfF mutations. A null yrfF mutation obtained by insertion of a kanamycin cassette into the yrfF open reading frame (yrfF28::Kan) produced abortive colonies when transduced to a wild-type strain but was normally accepted by rcsB, rcsC or yojN strains. Neither mutations preventing synthesis of the capsular exopolysaccharide colanic acid (cps, galE) nor rcsA mutations, which reduce expression of cps genes, conferred tolerance to the lethal yrfF28::Kan mutation. Spontaneous suppressor mutations arose very frequently in abortive yrfF28::Kan colonies, and all of them affected either rcsC, yojN, or rcsB genes. Thus, the lethal effect caused by inactivation of gene yrfF appears to be mediated by a function that is dependent on the rcsC-yojN-rcsB phosphorelay system but does not involve synthesis of colanic acid.     

Novel Macrolide-Specific ABC-Type Efflux Transporter in Escherichia coli

In the Escherichia coli genome, five putative open reading frame (ORF) clusters, mdlAB, ybjYZ, yddA, yojHI, and yhiH, have been assumed to be possible genes for ABC drug efflux transporters (I. T. Paulsen, M. K. Sliwinski, and M. H. Saier, Jr., J. Mol. Biol. 277:573-592, 1998). We cloned all of these ORFs in multicopy plasmids and investigated the drug resistance of drug-supersensitive host cells lacking constitutive multidrug efflux transporter genes acrAB. Among them, only ybjYZ gave significant erythromycin resistance and significantly decreased the accumulation of [(14)C]erythromycin. Therefore, ybjYZ was renamed macAB (macrolide-specific ABC-type efflux carrier). Plasmids carrying both the macA and -B genes conferred resistance against macrolides composed of 14- and 15-membered lactones but no or weak resistance against 16-membered ones. Neither of the two genes produced resistance alone. The DNA sequence suggests that MacB is an integral membrane protein with four transmembrane segments and one nucleotide-binding domain, while MacA belongs to a membrane fusion protein (MFP) family with a signal-like sequence at its N terminus. The expression of the histidine-tagged proteins confirmed that MacB is an integral membrane protein and MacA is a peripheral membrane protein. In addition, MacAB required TolC for its function in a way similar to that of most of the MFP-dependent transporters in E. coli. MacB is thus a novel ABC-type macrolide efflux transporter which functions by cooperating with the MFP MacA and the multifunctional outer membrane channel TolC. This is the first case of an experimentally identified ABC antibiotic efflux transporter in gram-negative organisms.     

Complementation analysis of the wild-type and mutant ompR genes exhibiting different phenotypes of osmoregulation of the ompF and ompC genes of Escherichia coli

Expression of the ompF and ompC genes, which encode the major outer membrane proteins, OmpF and OmpC, respectively, is affected in a reciprocal manner by the osmolarity of the growth medium. This osmoregulation is mediated by the OmpR protein, a positive regulator of both genes, which is encoded by the ompR gene. Structural and functional properties of this regulatory protein were studied through complementation analysis of the wild-type and five mutant ompR genes that exhibited differences in osmoregulation of the expression of the OmpF and OmpC proteins. Complementation was carried out with combinations of a host strain and a plasmid, each of which carried either the wild-type or a mutant ompR gene. In some combinations, negative complementation was observed. For example, ompR1, a deletion mutation with an OmpF- OmpC- phenotype, was dominant to OmpF+ or OmpC+ phenotypes conferred by other ompR genes. Positive complementation of two mutant ompR genes was also observed in other combinations, when the two mutations were distantly located from each other on the OmpR protein. These results, together with other observations, support the view that the OmpR protein has a two-domain structure, each domain exhibiting a different role in the expression of the OmpF and OmpC proteins, and that this protein takes a multimeric structure as a functional unit.     

The baeSR two-component regulatory system activates transcription of the yegMNOB (mdtABCD) transporter gene cluster in Escherichia coli and increases its resistance to novobiocin and deoxycholate

Screening of random fragments of Escherichia coli genomic DNA for their ability to increase the novobiocin resistance of a hypersusceptible (Delta)acrAB mutant resulted in the isolation of a plasmid containing baeR, which codes for the response regulator of the two-component regulatory system BaeSR. When induced for expression, baeR cloned in multicopy plasmid pTrc99A significantly increased the resistance of the (Delta)acrAB host strain to novobiocin (16-fold) and to deoxycholate (8-fold). Incubation of cells with novobiocin followed by a chromatographic assay for intracellular drug showed that overproduced BaeR decreased drastically the drug accumulation, presumably via increased active efflux. The genes baeSR are part of a putative operon, yegMNOB baeSR. Direct binding of BaeR to the yegM promoter was demonstrated in vitro by gel retardation assay. The gene yegB, which codes for a major facilitator superfamily transporter, was not necessary for increased resistance, but deletion of yegO or an in-frame deletion of yegN, both of which code for resistance-nodulation-cell division-type multidrug transporters, abolished the BaeR-induced increase in resistance. It is likely that both YegN and YegO produce a complex(es) with the membrane fusion protein family member YegM and pump out novobiocin and deoxycholate. We accordingly propose to rename yegMNOB as mdtABCD (mdt for multidrug transporter). Finally, the expression of two other genes, yicO and ygcL, was shown to be regulated by BaeR, but it is not known if they play any roles in resistance.     

A third envelope stress signal transduction pathway in Escherichia coli

Escherichia coli uses overlapping envelope stress responses to adapt to insults to the bacterial envelope that cause protein misfolding. The sigmaE and Cpx envelope stress responses are activated by both common and distinct envelope stresses and respond by increasing the expression of the periplasmic protease DegP as well as target genes unique to each response. The sigmaE pathway is involved in outer membrane protein (OMP) folding quality control whereas the Cpx pathway plays an important role in the assembly of at least one pilus. Previously, we identified the spy gene as a new Cpx regulon member of unknown function. Interestingly, induction of spy expression by severe envelope stresses such as spheroplasting is only partially dependent on an intact Cpx signalling pathway, unlike other Cpx-regulated genes. Here we show that the BaeS sensor kinase and BaeR response regulator also control expression of spy in response to envelope stress. BaeS and BaeR do not affect expression of other known Cpx-regulated genes, however, baeR cpxR double mutants show increased sensitivity to envelope stresses relative to either single mutant alone. We propose that the Bae signal transduction pathway controls a third envelope stress response in E. coli that induces expression of a distinct set of adaptive genes.     

Molecular analysis of mutant ompR genes exhibiting different phenotypes as to osmoregulation of the ompF and ompC genes of Escherichia coli

Summary Expression of the ompF and ompC genes coding for major outer membrane proteins is osmoregulated by solutes, such as sucrose and NaCl, in the growth medium. The OmpR protein, a positive regulator of these genes, is involved in the osmoregulation (Dairi et al. 1985; Nara et al. 1984). In the present work, five mutant ompR genes exhibiting different phenotypes of osmoregulation were cloned and sequenced. Three of them, ompR1, ompR2 and ompR20, were previously isolated mutants. The others, ompR3 and ompR4, were isolated in the present work. The ompR1 mutation resulted in the deletion of 19 amino acids near the C-terminus of the OmpR protein. The ompR3 and ompR4 mutations resulted in Arg¹⁵ to Cys and Arg⁷¹ to Thr conversions, respectively, at the N-terminal portion, whereas the ompR20 and ompR2 mutations resulted in Arg¹⁵⁰ to Cys and Val²⁰⁷ to Met conversions, respectively, at the C-terminal portion. Based on these results, the structure and function of the OmpR protein are discussed in relation to the mechanism of osmoregulation.Abbreviations Tc^r tetracycline resistance - Sm^r streptomycin resistance - Cm^r chloramphenicol resistance - Km^r kanamycin resistance - SDS sodium dodecyl sulphate     

鼠疫菌重要调控子蛋白的表达纯化及DNA结合活性分析

目的:利用大肠杆菌BL21(λDE3)的表达系统,表达7个有活性的、与鼠疫耶尔森菌(鼠疫菌)传播及致病密切相关的调控子蛋白,并对这些蛋白与DNA的结合活性进行分析,为构建鼠疫菌毒力基因转录调控网络建立分子生化实验平台。方法:通过分子克隆技术构建鼠疫菌调控子蛋白的表达菌株,所得菌株经IPTG诱导后能分别表达鼠疫菌CRP、Fur、PhoP、OxyR、OmpR、RcsB和RovA带His标签的融合蛋白;对这些蛋白与DNA的结合基序进行生物信息学预测;通过体外凝胶迁移实验验证上述蛋白与靶DNA的结合活性。结果:表达了7种有活性的鼠疫菌调控子蛋白,这些蛋白与靶基因启动子区具有体外结合活性。结论:表达的7种调控子蛋白在鼠疫菌的传播致病中有重要作用,这些调控子蛋白与DNA体外结合实验平台的建立,是构建鼠疫菌毒力基因转录调控网络的基础。     

Phenotypic revertant mutations of a new OmpR2 mutant (V203Q) of Escherichia coli lie in the envZ gene, which encodes the OmpR kinase.

The Escherichia coli ompR2 allele ompR472 contains a valine-to-methionine point mutation at position 203, resulting in an OmpF-constitutive OmpC- outer membrane phenotype. In the present study, OmpR residue V-203 was replaced with glutamine (V203Q mutation), resulting in the same outer membrane phenotype. However, unlike the OmpFc OmpC- phenotype conferred by the OmpR(V203M) mutant protein, the OmpFc OmpC- phenotype produced by the OmpR(V203Q) mutation was suppressed by the envZ11(T247R) allele. Additional suppressors of OmpR(V203Q) were isolated by random mutagenesis. All suppressor mutations were found in the envZ gene and conferred an OmpC+ OmpF- phenotype in the presence of the wild-type ompR. These envZ11-like mutations mapped to a region different from those previously reported and were incapable of suppressing the ompR(V203M) allele. Our results indicate that while methionine or glutamine replacements could cause similar effects on OmpF and OmpC expression, they conferred different abilities on the mutant proteins to be suppressed by envZ.     

Isolation and characterization of a substitution mutation in the ompR gene of Salmonella typhimurium LT2.

The expression of the genes ompC and ompF encoding major outer membrane proteins is dependent on the ompR-envZ operon. Here we describe the isolation and characterization of an ompR mutation, a single-base-pair change, that results in an Arg-to-Cys substitution. When present in multiple copies, the mutant allele conferred a dominant OmpC- OmpF+ phenotype. Furthermore, the mutant allele exhibited allele-specific negative complementation with other ompR mutations. This ability, together with its dominant character, suggested that the OmpR protein is capable of multimerization.     

Isolation from Klebsiella and characterization of two rcs genes that activate colanic acid capsular biosynthesis in Escherichia coli

Two genes, designated rcsA (regulation of capsule synthesis) and rcsB, that had been cloned from the chromosome of Klebsiella aerogenes (K. pneumoniae) capsular serotype K21 were capable of activating expression of colanic acid capsular polysaccharide in Escherichia coli K12. The Klebsiella rcsA gene encoded a polypeptide of 23 kDa that was required for the induction of a mucoid phenotype at less than or equal to 30 degrees C but not at greater than or equal to 37 C. The Klebsiella rcsB locus encoded no apparent polypeptides and was not capable by itself of causing the overproduction of colanic acid. However, when present in the same cell with rcsA, either in cis or in trans, rcsB caused expression of mucoidy in E. coli at all growth temperatures. These findings are best explained if the Klebsiella rcsA gene product acts as a positive regulator of colanic acid biosynthesis in E. coli and that activity of this protein is in turn subject to regulation by Lon protease. The Klebsiella rcsB locus may exert its effect by preferentially binding a negative regulator of capsular biosynthesis, possibly Lon itself. DNA sequences homologous to the Klebsiella K21b rcsA and rcsB genes were found in the genomes of all other capsular serotypes of klebsiellae examined, including K2, K12, K36 and K43. However, there was no homology between such genes and the chromosome of E. coli. The ability of these rcs genes to induce a mucoid phenotype explains the apparent conjugative transfer from klebsiellae to E. coli of the ability to produce K21 or other Klebsiella capsular polysaccharides that are structurally and antigenically related to colanic acid.     

The putative response regulator BaeR stimulates multidrug resistance of Escherichia coli via a novel multidrug exporter system,MdtABC

Overproduction of the response regulator BaeR confers resistance to novobiocin and bile salts in a DeltaacrAB mutant by stimulating drug exporter gene expression. The mdtABC (multidrug transporter ABC, formerly known as yegMNO) genes, which encode a resistance-nodulation-cell division (RND) drug efflux system, are responsible for resistance. The MdtABC system comprises the transmembrane MdtB/MdtC heteromultimer and MdtA membrane fusion protein. MdtAC also confers bile salt, but not novobiocin, resistance. This indicates that the evolution from an MdtC homomultimer to an MdtBC heteromultimer contributed to extend the drug resistance spectrum. A BLAST search suggested that such a heteromultimer-type RND exporter constitutes a unique family among gram-negative organisms.     

Regulation of capsular polysaccharide synthesis in Escherichia coli K-12: characterization of three regulatory genes.

The synthesis of the Escherichia coli capsular polysaccharide varies with growth medium, temperature of growth, and genetic background. lac fusions to genes necessary for capsule synthesis (cps) demonstrated that these genes are regulated negatively in vivo by the lon gene product. We have now isolated, characterized, and mapped mutations in three new regulatory genes (rcs, for regulator of capsule synthesis) that control expression of these same fusions. rcsA and rcsB are positive regulators of capsule synthesis. rcsA is located at min 43 on the E. coli map, whereas rcsB lies at 47 min. rcsC, a negative regulator of capsule synthesis, is located at min 47, close to rcsB. All three regulatory mutations are unlinked to either the structural genes cpsA-F or lon. Mutations in all three rcs genes are recessive to the wild type. We postulate that lon may regulate capsule synthesis indirectly, by regulating the availability of one of the positive regulators.     

Evidence for the physiological importance of the phosphotransfer between the two regulatory components, EnvZ and OmpR, in osmoregulation in Escherichia coli

Previously, the transfer of the phosphoryl group between the EnvZ and OmpR proteins, which are involved in activation of the ompF and ompC genes in response to the medium osmolarity, has been demonstrated in vitro. In this study, we characterized mutant EnvZ and OmpR proteins in terms of their in vitro phosphorylation and dephosphorylation. The proteins isolated from the mutants, envZ11 and ompR3, were found to be defective in seemingly the same aspect, i.e. OmpR dephosphorylation. The protein isolated from the ompR77 mutant, which is a suppressor mutant specific for envZ11, was found to be defective in another aspect, i.e. OmpR phosphorylation. These results imply that the phosphotransfer reactions observed in vitro play roles in the mechanism underlying the osmoregulatory expression of the ompF and ompC genes in vivo. We provide evidence that the EnvZ protein is involved not only in OmpR phosphorylation but also in OmpR dephosphorylation.     

Indole induces the expression of multidrug exporter genes in Escherichia coli

Our comprehensive expression cloning studies previously revealed that 20 intrinsic xenobiotic exporter systems are encoded in the Escherichia coli chromosome, but most of them are not expressed under normal conditions. In this study, we investigated the compounds that induce the expression of these xenobiotic exporter genes, and found that indole induces a variety of xenobiotic exporter genes including acrD, acrE, cusB, emrK, mdtA, mdtE and yceL. Indole treatment of E. coli cells confers rhodamine 6G and SDS resistance through the induction of mdtEF and acrD gene expression respectively. The induction of mdtE by indole is independent of the EvgSA two-component signal transduction system that regulates the mdtE gene, but mediated by GadX. On the other hand, the induction of acrD and mdtA was mediated by BaeSR and CpxAR, two-component systems. Interestingly, CpxAR system-mediated induction required intrinsic baeSR genes, whereas BaeSR-mediated induction was observed in the cpxAR gene-deletion mutant. BaeR and CpxR directly bound to different sequences of the acrD and mdtA promoter regions. These observations indicate that BaeR is a primary regulator, and CpxR enhances the effect of BaeR.