Amino acid substitutions in the CytR repressor which alter its capacity to regulate gene expression

Roles of CytR, an anti-activator of cyclic-AMP receptor protein (CRP) on flagellar expression and virulence in uropathogenic Escherichia coli

Uropathogenic Escherichia coli (UPEC) is a major pathogen that causes urinary tract infection (UTI), a common bacterial infectious disease. This bacterium invades the urinary tract cells, where it aggregates, and subsequently forms multicellular colonies termed intracellular bacterial communities (IBCs). The motility of the bacteria plays a key role in the mechanism of virulence in the host bladder. Here, we show that CytR is a modulator of bacterial internalization and aggregation within the bladder epithelial cells sustained by CRP in UPEC. Mutational analyses and gel-shift assays indicated that CytR represses the expression of flhD, thereby encoding a master regulator for flagellar expression that is responsible for bacterial motility when CRP is present, whereas CRP is an activator of flhD expression. Thus, elevated flagellar expression was involved in promoted virulence in the cytR mutant. These combined observations suggest another regulatory layer of flagellar expression and the role of CytR in UPEC virulence.

Antidepressant fluoxetine induces multiple antibiotics resistance in Escherichia coli via ROS-mediated mutagenesis

BACKGROUND

Antibiotic resistance poses a great threat to global public health. Overuse of antibiotics is generally considered as the major factor contributing to it. However, little is known about whether non-antibiotic drugs could play potential roles in the emergence of antibiotic resistance.

OBJECTIVE

We aimed to investigate whether antidepressant fluoxetine induces multiple antibiotic resistances and reveal underlying mechanisms.

METHODOLOGY

Escherichia coli K12 was exposed to different concentrations of fluoxetine (0, 0.5, 5, 50 and 100 mg/L) and the resistant strains were isolated by plating on antibiotic containing plates. Resistant strains were randomly selected to determine the increase of minimum inhibition concentration (MIC) of multiple antibiotics. Genome-wide DNA sequencing was performed on cells cultured in lysogeny broth (LB) without any fluoxetine or antibiotics exposure. RNA sequencing and proteomic profiling of isolated mutants grown in LB with 100 mg/L fluoxetine were analyzed to reveal the underlying mechanisms.

RESULTS

Exposure of Escherichia coli to fluoxetine at 5-100 mg/L after repeated subculture in LB for 30 days promoted its mutation frequency resulting in increased resistance against the antibiotics chloramphenicol, amoxicillin and tetracycline. This increase was up to 5.0 × 10⁷ fold in a dose-time pattern. Isolated mutants with resistance to one of these antibiotics also exhibited multiple resistances against fluoroquinolone, aminoglycoside, β-lactams, tetracycline and chloramphenicol. According to global transcriptional and proteomic analyses, the AcrAB-TolC pump together with the YadG/YadH transporter, a Tsx channel and the MdtEF-TolC pump have been triggered to export the antibiotics to the exterior of the cell. Whole-genome DNA analysis of the mutants further revealed that ROS-mediated mutagenesis (e.g., deletion, insertion, and substitution) of DNA-binding transcriptional regulators (e.g., marR, rob, sdiA, cytR and crp) to up-regulate the expression of efflux pumps, may further enhance the antibiotic efflux.

CONCLUSIONS

Our findings for the first time demonstrated that the exposure to antidepressant fluoxetine induces multiple antibiotic resistance in E. coli via the ROS-mediated mutagenesis.

Data on publications, structural analyses, and queries used to build and utilize the AlloRep database

The AlloRep database (www.AlloRep.org) (Sousa et al., 2016) [1] compiles extensive sequence, mutagenesis, and structural information for the LacI/GalR family of transcription regulators. Sequence alignments are presented for >3000 proteins in 45 paralog subfamilies and as a subsampled alignment of the whole family. Phenotypic and biochemical data on almost 6000 mutants have been compiled from an exhaustive search of the literature; citations for these data are included herein. These data include information about oligomerization state, stability, DNA binding and allosteric regulation. Protein structural data for 65 proteins are presented as easily-accessible, residue-contact networks. Finally, this article includes example queries to enable the use of the AlloRep database. See the related article, “AlloRep: a repository of sequence, structural and mutagenesis data for the LacI/GalR transcription regulators” (Sousa et al., 2016) [1].

Natural competence in Vibrio cholerae is controlled by a nucleoside scavenging response that requires CytR-dependent anti-activation

Competence for genetic transformation in Vibrio cholerae is triggered by chitin-induced transcription factor TfoX and quorum sensing (QS) regulator HapR. Transformation requires expression of ComEA, described as a DNA receptor in other competent bacteria. A screen for mutants that poorly expressed a comEA-luciferase fusion identified cytR, encoding the nucleoside scavenging cytidine repressor, previously shown in V. cholerae to be a biofilm repressor and positively regulated by TfoX, but not linked to transformation. A ΔcytR mutant was non-transformable and defective in expression of comEA and additional TfoX-induced genes, including pilA (transformation pseudopilus) and chiA-1 (chitinase). In Escherichia coli, 'anti-activation' of nucleoside metabolism genes, via protein-protein interactions between critical residues in CytR and CRP (cAMP receptor protein), is disrupted by exogenous cytidine. Amino acid substitutions of the corresponding V. cholerae CytR residues impaired expression of comEA, pilA and chiA-1, and halted DNA uptake; while exogenous cytidine hampered comEA expression levels and prevented transformation. Our results support a speculative model that when V. cholerae reaches high density on chitin, CytR-CRP interactions 'anti-activate' multiple genes, including a possible factor that negatively controls DNA uptake. Thus, a nucleoside scavenging mechanism couples nutrient stress and cell-cell signalling to natural transformation in V. cholerae as described in other bacterial pathogens.

Multiple conformations of the cytidine repressor DNA-binding domain coalesce to one upon recognition of a specific DNA surface

The cytidine repressor (CytR) is a member of the LacR family of bacterial repressors with distinct functional features. The Escherichia coli CytR regulon comprises nine operons whose palindromic operators vary in both sequence and, most significantly, spacing between the recognition half-sites. This suggests a strong likelihood that protein folding would be coupled to DNA binding as a mechanism to accommodate the variety of different operator architectures to which CytR is targeted. Such coupling is a common feature of sequence-specific DNA-binding proteins, including the LacR family repressors; however, there are no significant structural rearrangements upon DNA binding within the three-helix DNA-binding domains (DBDs) studied to date. We used nuclear magnetic resonance (NMR) spectroscopy to characterize the CytR DBD free in solution and to determine the high-resolution structure of a CytR DBD monomer bound specifically to one DNA half-site of the uridine phosphorylase (udp) operator. We find that the free DBD populates multiple distinct conformations distinguished by up to four sets of NMR peaks per residue. This structural heterogeneity is previously unknown in the LacR family. These stable structures coalesce into a single, more stable udp-bound form that features a three-helix bundle containing a canonical helix-turn-helix motif. However, this structure differs from all other LacR family members whose structures are known with regard to the packing of the helices and consequently their relative orientations. Aspects of CytR activity are unique among repressors; we identify here structural properties that are also distinct and that might underlie the different functional properties.

Vibrio cholerae CytR is a repressor of biofilm development

Vibrio cholerae is both a human pathogen and a natural inhabitant of aquatic environments. In the aquatic environment, microorganisms are found attached to surfaces in structures known as biofilms. We have identified a transcriptional repressor in V. cholerae that inhibits exopolysaccharide synthesis and biofilm development. Our studies show that this repressor is the V. cholerae homologue of Escherichia coli CytR, a protein that represses nucleoside uptake and catabolism when nucleosides are scarce. We propose that the role of CytR in V. cholerae biofilm development is to co-ordinate bacterial biofilm accumulation with the presence of nucleosides. Thus, nucleosides may be a signal to planktonic cells to join the biofilm.

Role of multiple CytR binding sites on cooperativity, competition, and induction at the Escherichia coli udp promoter

The CytR repressor fulfills dual roles as both a repressor of transcription from promoters of the Escherichia coli CytR regulon and a co-activator in some circumstances. Transcription is repressed by a three-protein complex (cAMP receptor protein (CRP)-CytR-CRP) that is stabilized by cooperative interactions between CRP and CytR. However, cooperativity also means that CytR can recruit CRP and, by doing so, can act as a co-activator. The central role of cooperativity in regulation is highlighted by the fact that binding of the inducer, cytidine, to CytR is coupled to CytR-CRP cooperativity; this underlies the mechanism for induction. Similar interactions at the different promoters of the CytR regulon coordinate expression of the transport proteins and enzymes required for nucleoside catabolism but also provide differential expression of these genes. A fundamental question in both prokaryotic and eukaryotic gene regulation is how combinatorial mechanisms of this sort regulate differential expression. Recently, we showed that CytR binds specifically to multiple sites in the E. coli deoP promoter, thereby providing competition for CRP binding to CRP operator site 1 (CRP1) and CRP2 as well as cooperativity. The effect of the competition at this promoter is to negate the role of CytR in recruiting CRP. Here, we have used quantitative footprint and mobility shift analysis to investigate CRP and CytR binding to the E. coli udp promoter. Here too, we find that CytR both cooperates and competes for CRP binding. However, consistent with both the distribution of CytR recognition motifs in the sequence of the promoter and the regulation of the promoter, the competition is limited to CRP2. When cytidine binds to CytR, the effect on cooperativity is very different at the udp promoter than at the deoP2 promoter. Cooperativity with CRP at CRP1 is nearly eliminated, but the effect on CytR-CRP2 cooperativity is negligible. These results are discussed in relation to the current structural model of CytR in which the core, inducer-binding domain is tethered to the helix-turn-helix, DNA-binding domain via flexible peptide linkers.

Protein-ligand interaction: grafting of the uridine-specific determinants from the CytR regulator of Salmonella typhimurium to Escherichia coli CytR

Members of the LacI family of transcriptional repressors respond to the presence of small effector molecules. The binding of the ligands affect the proteins ability to repress transcription by stabilizing a conformation that, in most cases, is unfavorable for high-affinity DNA binding. The CytR anti-activator diverges from the other family members by relying on the cooperative DNA binding with the global regulator CRP. The inducers of CytR do not affect CytR-DNA binding per se, but alleviate repression by interrupting protein-protein interactions between the two regulators. Here, we have studied of the CytR-inducer interaction by exploring a discrepancy in the inducer response observed for the homologous CytR regulators of Escherichia coli and Salmonella typhimurium. CytR of S. typhimurium (CytRSt) appears to respond to the presence of both uridine and cytidine nucleosides, whereas E. coli CytR (CytREc) responds to cytidine only. We have used a combination of genetic and structural modeling studies to provide detailed information regarding the nature of this discrepancy. By analysis of hybrid CytR proteins followed by site-directed mutagenesis, we have successfully transferred the specificity determinants for uridine from CytRSt to CytREc, revealing that serine substitutions of only two residues (G131 and A152) in CytREc is required to make CytREc sensitive to uridine. In addition, by employing a genetic screen for induction of defective mutants, we have identified four amino acid residues in CytRSt that appear to be important for the response to uridine. The implications of these findings for the understanding of the ligand binding and induction of CytR are discussed in the context of the structural knowledge of CytR and homologous protein-ligand complexes.

Allosteric mechanism of induction of CytR-regulated gene expression. Cytr repressor-cytidine interaction

Transcription from cistrons of the Escherichia coli CytR regulon is activated by E. coli cAMP receptor protein (CRP) and repressed by a multiprotein complex composed of CRP and CytR. De-repression results when CytR binds cytidine. CytR is a homodimer and a LacI family member. A central question for all LacI family proteins concerns the allosteric mechanism that couples ligand binding to the protein-DNA and protein-protein interactions that regulate transcription. To explore this mechanism for CytR, we analyzed nucleoside binding in vitro and its coupling to cooperative CytR binding to operator DNA. Analysis of the thermodynamic linkage between sequential cytidine binding to dimeric CytR and cooperative binding of CytR to deoP2 indicates that de-repression results from just one of the two cytidine binding steps. To test this conclusion in vivo, CytR mutants that have wild-type repressor function but are cytidine induction-deficient (CID) were identified. Each has a substitution for Asp281 or neighboring residue. CID CytR281N was found to bind cytidine with three orders of magnitude lower affinity than wild-type CytR. Other CytR mutants that do not exhibit the CID phenotype were found to bind cytidine with affinity similar to wild-type CytR. The rate of transcription regulated by heterodimeric CytR composed of one CytR281N and one wild-type subunit was compared with that regulated by wild-type CytR under inducing conditions. The data support the conclusion that the first cytidine binding step alone is sufficient to induce.

Analysis of CRP-CytR interactions at the Escherichia coli udp promoter

Multiprotein complexes regulate the transcription of certain bacterial genes in a sensitive, physiologically responsive manner. In particular, the transcription of genes needed for utilization of nucleosides in Escherichia coli is regulated by a repressor protein, CytR, in concert with the cyclic AMP (cAMP) activated form of cAMP receptor protein (CRP). We studied this regulation by selecting and characterizing spontaneous constitutive mutations in the promoter of the udp (uridine phosphorylase) gene, one of the genes most strongly regulated by CytR. We found deletions, duplications, and point mutations that affect key regulatory sites in the udp promoter, insertion sequence element insertions that activated cryptic internal promoters or provided new promoters, and large duplications that may have increased expression by udp gene amplification. Unusual duplications and deletions that resulted in constitutive udp expression that depended on the presence of CytR were also found. Our results support the model in which repression normally involves the binding of CytR to cAMP-CRP to form a complex which binds to specific sites in the udp promoter, without direct interaction between CytR protein and a specific operator DNA sequence, and in which induction by specific inducer cytidine involves dissociation of CytR from cAMP-CRP and the RNA polymerase interaction with cAMP-CRP bound to a site upstream of then transcription start point. The stimulation of udp expression by CytR in certain mutants may reflect its stabilization of cAMP-CRP binding to target DNA and illustrates that only modest evolutionary changes could allow particular multiprotein complexes to serve as either repressors or transcriptional activators.

Crystal structure of LacI member, PurR, bound to DNA: minor groove binding by alpha helices

The three-dimensional structure of a ternary complex of the purine repressor, PurR, bound to both its corepressor, hypoxanthine, and the 16-base pair purF operator site has been solved at 2.7 A resolution by x-ray crystallography. The bipartite structure of PurR consists of an amino-terminal DNA-binding domain and a larger carboxyl-terminal corepressor binding and dimerization domain that is similar to that of the bacterial periplasmic binding proteins. The DNA-binding domain contains a helix-turn-helix motif that makes base-specific contacts in the major groove of the DNA. Base contacts are also made by residues of symmetry-related alpha helices, the "hinge" helices, which bind deeply in the minor groove. Critical to hinge helix-minor groove binding is the intercalation of the side chains of Leu54 and its symmetry-related mate, Leu54', into the central CpG-base pair step. These residues thereby act as "leucine levers" to pry open the minor groove and kink the purF operator by 45 degrees.

Functions of the gene products of Escherichia coli

A list of currently identified gene products of Escherichia coli is given, together with a bibliography that provides pointers to the literature on each gene product. A scheme to categorize cellular functions is used to classify the gene products of E. coli so far identified. A count shows that the numbers of genes concerned with small-molecule metabolism are on the same order as the numbers concerned with macromolecule biosynthesis and degradation. One large category is the category of tRNAs and their synthetases. Another is the category of transport elements. The categories of cell structure and cellular processes other than metabolism are smaller. Other subjects discussed are the occurrence in the E. coli genome of redundant pairs and groups of genes of identical or closely similar function, as well as variation in the degree of density of genetic information in different parts of the genome.

Protein-protein interactions in gene regulation: the cAMP-CRP complex sets the specificity of a second DNA-binding protein, the CytR repressor

Maximal repression by the CytR protein depends on the formation of nucleoprotein complexes in which CytR interacts with DNA and with cAMP-cAMP receptor protein (CRP). Here we demonstrate that CytR regulates transcription from deoP2 promoters in which the entire CytR recognition sequence has been eliminated. Furthermore, CytR proteins deleted for the DNA-binding domain repress deoP2 in vivo and interact with deoP2 in vitro in a strictly cAMP-CRP-dependent fashion. These experiments show that the site of action of CytR can be specified by protein-protein interactions to cAMP-CRP, whereas CytR-DNA interactions may primarily serve to stabilize the nucleo-protein complex. This type of specificity mechanism may represent a general concept in the recruitment of DNA-binding proteins in combinatorial regulatory systems.

Detecting subtle sequence signals: a Gibbs sampling strategy for multiple alignment

A wealth of protein and DNA sequence data is being generated by genome projects and other sequencing efforts. A crucial barrier to deciphering these sequences and understanding the relations among them is the difficulty of detecting subtle local residue patterns common to multiple sequences. Such patterns frequently reflect similar molecular structures and biological properties. A mathematical definition of this "local multiple alignment" problem suitable for full computer automation has been used to develop a new and sensitive algorithm, based on the statistical method of iterative sampling. This algorithm finds an optimized local alignment model for N sequences in N-linear time, requiring only seconds on current workstations, and allows the simultaneous detection and optimization of multiple patterns and pattern repeats. The method is illustrated as applied to helix-turn-helix proteins, lipocalins, and prenyltransferases.

Characterization of cytR mutations that influence oligomerization of mutant repressor subunits

In Escherichia coli, the transport and catabolism of nucleosides require expression of the genes composing the CytR regulon. The role of the CytR repressor in transcriptional regulation has been examined through a study of mutant CytR proteins. Two important and interrelated CytR mutants are encoded by cytR delta M149, a dominant negative allele, and cytRC289R. Studies with CytR delta M149 indicated that the native, repression-competent CytR protein is multimeric while the CytR amino acid substitution C-289-->R has been proposed to affect subunit oligomerization on the basis of its ability to suppress the transdominance of CytR delta M149. The present study identifies other CytR amino acid residues proximal to Cys-289 that may also participate in normal subunit oligomerization. Mutations in these CytR residues, cytRA307P, cytRM308R, and cytRL309P, encoded inactive repressors in a CytR- background and, when combined with cytR delta M149, yielded hybrid repressors that were recessive in a CytR+ genetic background. Because the stability and solubility observed for the new, mutant CytR proteins and the wild-type CytR protein were indistinguishable, these residue replacements, like the C-289-->R substitution, are envisaged as being located at the subunit interface and thus suppress the CytR delta M149 transdominance by blocking efficient and stable assembly of wild-type and hybrid CytR subunits. The assignment of CytR amino acids to a protein region involved in subunit association is also consistent with the observations that these CytR amino acids are roughly colinear with regions of the LacI repressor that influence monomer-dimer association and would be surface located by alignment to the E. coli galactose-binding protein crystal structure.

Identification of the nucleotide sequence recognized by the cAMP-CRP dependent CytR repressor protein in the deoP2 promoter in E. coli

In E. coli repression of transcription initiation by the CytR protein relies on CytR-DNA interactions as well as on interactions between CytR and the cAMP-CRP activator complex. To identify the nucleotide sequence recognized by CytR, mutants of the deoP2 promoter with a reduced regulatory response to CytR have been isolated. Five single bp mutation derivatives of deoP2 with a 2-5-fold decrease in CytR regulation have been characterized. In vitro, the only effect of the mutations was a decrease in the binding affinity of CytR, and a clear correlation was observed between the reduction in CytR regulation in vivo and the reduction in CytR binding in vitro. The mutations all reside in a sequence element that contains an imperfect direct as well as an imperfect inverted repeat. As the active form of CytR, most likely, is an oligomer with two-fold rotational symmetry, CytR probably interacts with the inverted repeat. Degenerate versions of the inverted repeat are present in all CytR binding sites characterized so far, however, the distance between the half-sites varies.