Use of urea and glycine betaine to quantify coupled folding and probe the burial of DNA phosphates in lac repressor-lac operator binding

Thermodynamic analysis of urea-biopolymer interactions and effects of urea on folding of proteins and alpha-helical peptides shows that urea interacts primarily with polar amide surface. Urea is therefore predicted to be a quantitative probe of coupled folding, remodeling, and other large-scale changes in the amount of water-accessible polar amide surface in protein processes. A parallel analysis indicates that glycine betaine [N,N,N-trimethylglycine (GB)] can be used to detect burial or exposure of anionic (carboxylate, phosphate) biopolymer surface. To test these predictions, we have investigated the effects of these solutes (0-3 m) on the formation of 1:1 complexes between lac repressor (LacI) and its symmetric operator site (SymL) at a constant KCl molality. Urea reduces the binding constant K(TO) [initial slope dlnK(TO)/dm(urea) = -1.7 +/- 0.2], and GB increases K(TO) [initial slope dlnK(TO)/dm(GB) = 2.1 +/- 0.2]. For both solutes, this derivative decreases with an increase in solute concentration. Analysis of these initial slopes predicts that (1.5 +/- 0.3) x 10(3) A2 of polar amide surface and (4.5 +/- 1.0) x 10(2) A2 of anionic surface are buried in the association process. Analysis of published structural data, together with modeling of unfolded regions of free LacI as extended chains, indicates that 1.5 x 10(3) A2 of polar amide surface and 6.3 x 10(2) A2 of anionic surface are buried in complexation. Quantitative agreement between structural and thermodynamic results is obtained for amide surface (urea); for anionic surface (GB), the experimental value is approximately 70% of the structural value. For LacI-SymL binding, two-thirds of the structurally predicted change in amide surface (1.0 x 10(3) A2) occurs outside the protein-DNA interface in protein-protein interfaces formed by folding of the hinge helices and interactions of the DNA binding domain (DBD) with the core of the repressor. Since urea interacts principally with amide surface, it is particularly well-suited to detect and quantify the extent of coupled folding and other large-scale remodeling events in the steps of protein-nucleic acid interactions and other protein associations.

Three-stage Regulation of the Amphibolic gal Operon: From Repressosome to GalR-free DNA

The gal operon of Escherichia coli is negatively regulated by the Gal repressosome, a higher order nucleoprotein complex containing a DNA loop that encompasses two gal promoters. In the repressosome structure, Gal repressor (GalR) dimers are bound to the two operator sites, flanking the promoter region, thus generating a DNA loop. The DNA loop is stabilized by binding of the architectural HU protein to the apex of the loop, and negative supercoiling. The gal promoters are also regulated in opposite directions by GalR without DNA looping. The repressosome-mediated as well as looping-independent transcription regulation of the two promoters is lifted in the presence of the inducer D-galactose. We tested the effect of D-galactose on various DNA-protein and protein-protein interactions of different regulatory complexes and on transcription repression in vitro. We found that the inducer breaks up the repressosome with clear intermediates in a concentration-dependent manner. The sequential disassembly generates different stages of regulation of the gal operon. The D-galactose-dependent switch from one stage of regulation to another satisfies the amphibolic requirement of the gal operon.

Distance determination by GIY-YIG intron endonucleases: discrimination between repression and cleavage functions

GIY-YIG homing endonucleases are modular proteins, with conserved N-terminal catalytic domains connected by linkers to C-terminal DNA-binding domains. I-TevI, the T4 phage GIY-YIG intron endonuclease, functions both in promoting td intron homing, and in acting as a transcriptional autorepressor. Repression is achieved by binding to an operator, which is cleaved at 100-fold reduced efficiency relative to the intronless homing site. The linker includes a zinc finger, which functions in distance determination, to constrain the catalytic domain to cleave the homing site at a fixed position. Here we show that I-BmoI, a related GIY-YIG endonuclease lacking a zinc finger, also possesses some cleavage distance discrimination. Furthermore, hybrid endonucleases constructed by swapping the domains of I-BmoI and I-TevI are active, precise and demonstrate that features other than the zinc finger facilitate distance determination. Most importantly, I-TevI zinc finger mutants cleave the operator more efficiently than the homing site, the converse of wild-type protein. These results are consistent with the zinc finger acting as a measuring device, directing efficient cleavage of the homing site to promote intron mobility, while reducing cleavage at the operator to ensure transcriptional autorepression and phage viability.

Effector-Repressor Interactions, Binding of a Single Effector Molecule to the Operator-bound TtgR Homodimer Mediates Derepression

The RND family transporter TtgABC and its cognate repressor TtgR from Pseudomonas putida DOT-T1E were both shown to possess multidrug recognition properties. Structurally unrelated molecules such as chloramphenicol, butyl paraben, 1,3-dihydroxynaphthalene, and several flavonoids are substrates of TtgABC and activate pump expression by binding to the TtgR-operator complex. Isothermal titration calorimetry was employed to determine the thermodynamic parameters for the binding of these molecules to TtgR. Dissociation constants were in the range from 1 to 150 microm, the binding stoichiometry was one effector molecule per dimer of TtgR, and the process was driven by favorable enthalpy changes. Although TtgR exhibits a large multidrug binding profile, the plant-derived compounds phloretin and quercetin were shown to bind with the highest affinity (K(D) of around 1 microm), in contrast to other effectors (chloramphenicol and aromatic solvents) for which exhibited a more reduced affinity. Structure-function studies of effectors indicate that the presence of aromatic rings as well as hydroxyl groups are determinants for TtgR binding. The binding of TtgR to its operator DNA does not alter the protein effector profile nor the effector binding stoichiometry. Moreover, we demonstrate here for the first time that the binding of a single effector molecule to the DNA-bound TtgR homodimer induces the dissociation of the repressor-operator complex. This provides important insight into the molecular mechanism of effector-mediated derepression.

The Mcp element mediates stable long-range chromosome-chromosome interactions in Drosophila

Chromosome organization inside the nucleus is not random but rather is determined by a variety of factors, including interactions between chromosomes and nuclear components such as the nuclear envelope or nuclear matrix. Such interactions may be critical for proper nuclear organization, chromosome partitioning during cell division, and gene regulation. An important, but poorly documented subset, includes interactions between specific chromosomal regions. Interactions of this type are thought to be involved in long-range promoter regulation by distant enhancers or locus control regions and may underlie phenomena such as transvection. Here, we used an in vivo microscopy assay based on Lac Repressor/operator recognition to show that Mcp, a polycomb response element from the Drosophila bithorax complex, is able to mediate physical interaction between remote chromosomal regions. These interactions are tissue specific, can take place between multiple Mcp elements, and seem to be stable once established. We speculate that this ability to interact may be part of the mechanism through which Mcp mediates its regulatory function in the bithorax complex.

Repressor of Phage 16 - 3 with Altered Binding Specificity Indicates Spatial Differences in Repressor-Operator Complexes

The C repressor protein of phage 16-3 , which is required for establishing and maintaining lysogeny, recognizes structurally different operators which differ by 2 bp in the length of the spacer between the conserved palindromic sequences. A “rotationally flexible protein homodimers” model has been proposed in order to explain the conformational adaptivity of the 16-3 repressor. In this paper, we report on the isolation of a repressor mutant with altered binding specificity which was used to identify a residue-base pair contact and to monitor the spatial relationship of the recognition helix of C repressor to the contacting major groove of DNA within the two kinds of repressor-operator complexes. Our results indicate spatial differences at the interface which may reflect different docking arrangements in recognition of the structurally different operators by the 16-3 repressor.

Induction of the lac promoter in the absence of DNA loops and the stoichiometry of induction

In vivo induction of the Escherichia coli lactose operon as a function of inducer concentration generates a sigmoidal curve, indicating a non-linear response. Suggested explanations for this dependence include a 2:1 inducer–repressor stoichiometry of induction, which is the currently accepted view. It is, however, known for decades that, in vitro, operator binding as a function of inducer concentration is not sigmoidal. This discrepancy between in vivo and in vitro data has so far not been resolved. We demonstrate that the in vivo non-linearity of induction is due to cooperative repression of the wild-type lac operon through DNA loop formation. In the absence of DNA loops, in vivo induction curves are hyperbolic. In the light of this result, we re-address the question of functional molecular inducer–repressor stoichiometry in induction of the lac operon.

Structures of omega repressors bound to direct and inverted DNA repeats explain modulation of transcription

Repressor omega regulates transcription of genes required for copy number control, accurate segregation and stable maintenance of inc18 plasmids hosted by Gram-positive bacteria. omega belongs to homodimeric ribbon-helix-helix (RHH2) repressors typified by a central, antiparallel beta-sheet for DNA major groove binding. Homodimeric omega2 binds cooperatively to promotors with 7 to 10 consecutive non-palindromic DNA heptad repeats (5'-(A)/(T)ATCAC(A)/(T)-3', symbolized by -->) in palindromic inverted, converging (--><--) or diverging (<---->) orientation and also, unique to omega2 and contrasting other RHH2 repressors, to non-palindromic direct (-->-->) repeats. Here we investigate with crystal structures how omega2 binds specifically to heptads in minimal operators with (-->-->) and (--><--) repeats. Since the pseudo-2-fold axis relating the monomers in omega(2) passes the central C-G base pair of each heptad with approximately 0.3 A downstream offset, the separation between the pseudo-2-fold axes is exactly 7 bp in (-->-->), approximately 0.6 A shorter in (--><--) but would be approximately 0.6 A longer in (<---->). These variations grade interactions between adjacent omega2 and explain modulations in cooperative binding affinity of omega2 to operators with different heptad orientations.

Genetic composition of the Bacillus subtilis SOS system

The SOS response in bacteria includes a global transcriptional response to DNA damage. DNA damage is sensed by the highly conserved recombination protein RecA, which facilitates inactivation of the transcriptional repressor LexA. Inactivation of LexA causes induction (derepression) of genes of the LexA regulon, many of which are involved in DNA repair and survival after DNA damage. To identify potential RecA-LexA-regulated genes in Bacillus subtilis, we searched the genome for putative LexA binding sites within 300 bp upstream of the start codons of all annotated open reading frames. We found 62 genes that could be regulated by putative LexA binding sites. Using mobility shift assays, we found that LexA binds specifically to DNA in the regulatory regions of 54 of these genes, which are organized in 34 putative operons. Using DNA microarray analyses, we found that 33 of the genes with LexA binding sites exhibit RecA-dependent induction by both mitomycin C and UV radiation. Among these 33 SOS genes, there are 22 distinct LexA binding sites preceding 18 putative operons. Alignment of the distinct LexA binding sites reveals an expanded consensus sequence for the B. subtilis operator: 5'-CGAACATATGTTCG-3'. Although the number of genes controlled by RecA and LexA in B. subtilis is similar to that of Escherichia coli, only eight B. subtilis RecA-dependent SOS genes have homologous counterparts in E. coli.

In vitro analysis of protein-operator interactions of the NikR and fur metal-responsive regulators of coregulated genes in Helicobacter pylori

Two important metal-responsive regulators, NikR and Fur, are involved in nickel and iron homeostasis and controlling gene expression in Helicobacter pylori. To date, they have been implicated in the regulation of sets of overlapping genes. We have attempted here dissection of the molecular mechanisms involved in transcriptional regulation of the NikR and Fur proteins, and we investigated protein-promoter interactions of the regulators with known target genes. We show that H. pylori NikR is a tetrameric protein and, through DNase I footprinting analysis, we have identified operators for NikR to which it binds with different affinities in a metal-responsive way. Mapping of the NikR binding site upstream of the urease promoter established a direct role for NikR as a positive regulator of transcription and, through scanning mutagenesis of this binding site, we have determined two subsites that are important for the binding of the protein to its target sequence. Furthermore, by alignment of the operators for NikR, we have shown that the H. pylori protein recognizes a sequence that is distinct from its well-studied orthologue in Escherichia coli. Moreover, we show that NikR and Fur can bind independently at distinct operators and also compete for overlapping operators in some coregulated gene promoters, adding another dimension to the previous suggested link between iron and nickel regulation. Finally, the importance of an interconnection between metal-responsive gene networks for homeostasis is discussed.

Role of the N-terminal region and of beta-sheet residue Thr29 on the activity of the omega2 global regulator from the broad-host range Streptococcus pyogenes plasmid pSM19035

The dimeric regulatory protein wild-type omega (wt omega2) binds to arrays of 7-bp sequences (heptads) present in the operator DNA region of copy control and partition functions of plasmid pSM19035. Each omega2 protein probably binds with an antiparallel beta-sheet structure in the major groove of the 7-bp subsite of the operator DNA. Exchange of threonine at position 29 to alanine (T29A) drastically affects the activity of variant protein omega2T29A both in vivo and in vitro, and reduces the thermodynamic stability deltaG(o)u, but does not change the conformation. Likewise, the binding affinity to DNA is reduced and the association of the two monomeric subunits of the omega2T29A dimer is weakened, as manifested by an increase in the dissociation constant from 3.2 microM for wt omega2 to 6.3 microM for omega2T29A. Denatured dimers are formed upon thermal unfolding of wt omega2 and omega2T29A at ca. 45 microM (D(n)<-->D(u)). Removal of 8 (omega2deltaN8), or even 18 (omega2deltaN18) N-terminal amino acids has no obvious effect either on the core structure or on the activity in comparison to wt omega2. The stability of variants omega2deltaN8 and omega2deltaN18 is similar to that of wt omega2, and their binding to operator DNA is not impaired.

Chlamydial GroEL autoregulates its own expression through direct interactions with the HrcA repressor protein

In the pathogenic bacterium Chlamydia trachomatis, a transcriptional repressor, HrcA, regulates the major heat shock operons, dnaK and groE. Cellular stress causes a transient increase in transcription of these heat shock operons through relief of HrcA-mediated repression, but the pathway leading to derepression is unclear. Elevated temperature alone is not sufficient, and it is hypothesized that additional chlamydial factors play a role. We used DNA affinity chromatography to purify proteins that interact with HrcA in vivo and identified a higher-order complex consisting of HrcA, GroEL, and GroES. This endogenous HrcA complex migrated differently than recombinant HrcA, but the complex could be disrupted, releasing native HrcA that resembled recombinant HrcA. In in vitro assays, GroEL increased the ability of HrcA to bind to the CIRCE operator and to repress transcription. Other chlamydial heat shock proteins, including the two additional GroEL paralogs present in all chlamydial species, did not modulate HrcA activity.

Binding of the Bacillus subtilis LexA protein to the SOS operator

The Bacillus subtilis LexA protein represses the SOS response to DNA damage by binding as a dimer to the consensus operator sequence 5'-CGAACN(4)GTTCG-3'. To characterize the requirements for LexA binding to SOS operators, we determined the operator bases needed for site-specific binding as well as the LexA amino acids required for operator recognition. Using mobility shift assays to determine equilibrium constants for B.subtilis LexA binding to recA operator mutants, we found that several single base substitutions within the 14 bp recA operator sequence destabilized binding enough to abolish site-specific binding. Our results show that the AT base pairs at the third and fourth positions from the 5' end of a 7 bp half-site are essential and that the preferred binding site for a LexA dimer is 5'-CGAACATATGTTCG-3'. Binding studies with LexA mutants, in which the solvent accessible amino acid residues in the putative DNA binding domain were mutated, indicate that Arg-49 and His-46 are essential for binding and that Lys-53 and Ala-48 are also involved in operator recognition. Guided by our mutational analyses as well as hydroxyl radical footprinting studies of the dinC and recA operators we docked a computer model of B.subtilis LexA on the preferred operator sequence in silico. Our model suggests that binding by a LexA dimer involves bending of the DNA helix within the internal 4 bp of the operator.

Switching DNA-binding specificity by unnatural amino acid substitution

The specificity of protein–nucleic acid recognition is believed to originate largely from hydrogen bonding between protein polar atoms, primarily side-chain and polar atoms of nucleic acid bases. One way to design new nucleic acid binding proteins of novel specificity is by structure-guided alterations of the hydrogen bonding patterns of a nucleic acid–protein complex. We have used cI repressor of bacteriophage λ as a model system. In the λ-repressor–DNA complex, the ɛ-NH₂ group (hydrogen bond donor) of lysine-4 of λ-repressor forms hydrogen bonds with the amide carbonyl atom of asparagine-55 (acceptor) and the O6 (acceptor) of CG6 of operator site O_L1. Substitution of lysine-4 (two donors) by iso-steric S-(2-hydroxyethyl)-cysteine (one donor and one acceptor), by site-directed mutagenesis and chemical modification, leads to switch of binding specificity of λ-repressor from C:G to T:A at position 6 of O_L1. This suggests that unnatural amino acid substitutions could be a simple way of generating nucleic acid binding proteins of altered specificity.

Production of fuculose-1-phosphate aldolase using operator-repressor titration for plasmid maintenance in high cell density Escherichia coli fermentations

We report a novel application for the operator-repressor titration (ORT) plasmid maintenance system. The ability of ORT to maintain a plasmid during production of DNA has been demonstrated previously. In this study, we have used the ORT system to maintain a plasmid during high cell density cultivation and expression of a recombinant protein. No evidence of plasmid loss was seen during protein expression at high cell densities. In addition, the quantity of protein produced using this system was similar to traditional plasmid maintenance systems.

Mutational analysis of the Bacillus subtilis purA operator site

The Bacillus subtilis purine repressor, PurR, regulates many genes involved in purine metabolism. These genes contain a conserved 14-nucleotide inverted repeat (PurBox). Both pur operon and purA, which are regulated by PurR, have this inverted repeat with a 16- or 17-nucleotide spacer, respectively. Mutational studies have earlier shown that PurR binding is dependent on the PurBox of pur operon. In contrast, these studies failed to establish the importance of purA PurBox to PurR binding. To examine this inconsistency, we studied the effects of PurBox mutations both in vivo and in vitro. The data presented here indicate that purA PurBox has a similar role as pur operon PurBox in PurR binding. In addition, our data suggest that the previously proposed classification of the two halves of the Purbox into weak and strong may need to be revised.

In vivo HP1 targeting causes large-scale chromatin condensation and enhanced histone lysine methylation

Changes in chromatin structure are a key aspect in the epigenetic regulation of gene expression. We have used a lac operator array system to visualize by light microscopy the effect of heterochromatin protein 1 (HP1) alpha (HP1alpha) and HP1beta on large-scale chromatin structure in living mammalian cells. The structure of HP1, containing a chromodomain, a chromoshadow domain, and a hinge domain, allows it to bind to a variety of proteins. In vivo targeting of an enhanced green fluorescent protein-tagged HP1-lac repressor fusion to a lac operator-containing, gene-amplified chromosome region causes local condensation of the higher-order chromatin structure, recruitment of the histone methyltransferase SETDB1, and enhanced trimethylation of histone H3 lysine 9. Polycomb group proteins of both the HPC/HPH and the EED/EZH2 complexes, which are involved in the heritable repression of gene activity, are not recruited to the amplified chromosome region by HP1alpha and HP1beta in vivo targeting. HP1alpha targeting causes the recruitment of endogenous HP1beta to the chromatin region and vice versa, indicating a direct interaction between the two HP1 homologous proteins. Our findings indicate that HP1alpha and HP1beta targeting is sufficient to induce heterochromatin formation.

Autorepression of AdpA of the AraC/XylS family, a key transcriptional activator in the A-factor regulatory cascade in Streptomyces griseus

AdpA belonging to the AraC/XylS family is a key transcriptional activator in the A-factor regulatory cascade in Streptomyces griseus, activating a number of genes required for physiological and morphological differentiation. On the other hand, AdpA repressed its own transcription by cooperative binding to the promoter region containing multiple operator sites. AdpA contained three operator sites, site 1 approximately at nucleotide position -100, site 2 at the promoter elements, and site 3 at position +80. AdpA bound to a strong binding site 1 increased the affinity for AdpA of a weak site 2, probably by forming a DNA loop via the two molecules of AdpA dimer, thus preventing RNA polymerase from access to the promoter. AdpA bound to site 3 with rather weak affinity repressed the AdpA promoter activity independently of sites 1 and 2, perhaps preventing RNA polymerase from chain elongation. Consistent with this model, the in vivo transcription of AdpA containing mutated site 1 or site 3 was greatly increased. In addition, streptomycin production, one of the phenotypes controlled positively by AdpA, was greatly increased in the mutants containing AdpA with a mutation at site 1 and site 3. The in vitro transcription of AdpA containing mutated site 1 was also increased. Thus, the transcription of AdpA, encoding an important transcriptional factor for ordered physiological and morphological development, is self-controlled.

A novel mammalian expression system derived from components coordinating nicotine degradation in arthrobacter nicotinovorans pAO1

We describe the design and detailed characterization of 6-hydroxy-nicotine (6HNic)-adjustable transgene expression (NICE) systems engineered for lentiviral transduction and in vivo modulation of angiogenic responses. Arthrobacter nicotinovorans pAO1 encodes a unique catabolic machinery on its plasmid pAO1, which enables this Gram-positive soil bacterium to use the tobacco alkaloid nicotine as the exclusive carbon source. The 6HNic-responsive repressor-operator (HdnoR-O(NIC)) interaction, controlling 6HNic oxidase production in A.nicotinovorans pAO1, was engineered for generic 6HNic-adjustable transgene expression in mammalian cells. HdnoR fused to different transactivation domains retained its O(NIC)-binding capacity in mammalian cells and reversibly adjusted transgene transcription from chimeric O(NIC)-containing promoters (P(NIC); O(NIC) fused to a minimal eukaryotic promoter [P(min)]) in a 6HNic-responsive manner. The combination of transactivators containing various transactivation domains with promoters differing in the number of operator modules as well as in their relative inter-O(NIC) and/or O(NIC)-P(min) spacing revealed steric constraints influencing overall NICE regulation performance in mammalian cells. Mice implanted with microencapsulated cells engineered for NICE-controlled expression of the human glycoprotein secreted placental alkaline phosphatase (SEAP) showed high SEAP serum levels in the absence of regulating 6HNic. 6HNic was unable to modulate SEAP expression, suggesting that this nicotine derivative exhibits control-incompatible pharmacokinetics in mice. However, chicken embryos transduced with HIV-1-derived self-inactivating lentiviral particles transgenic for NICE-adjustable expression of the human vascular endothelial growth factor 121 (VEGF121) showed graded 6HNic response following administration of different 6HNic concentrations. Owing to the clinically inert and highly water-soluble compound 6HNic, NICE-adjustable transgene control systems may become a welcome alternative to available drug-responsive homologs in basic research, therapeutic cell engineering and biopharmaceutical manufacturing.

Gal repressor-operator-HU ternary complex: pathway of repressosome formation

DNA transaction reactions require formation of nucleoprotein complexes that involve multifaceted DNA-protein and protein-protein interactions. Genetic and biochemical studies suggested that the higher order Gal repressosome structure, which governs the transcription of two tandem galpromoters in Escherichia coli, involves sequence-specific binding of GalR repressor dimers to two operators, O(E) and O(I), located 113 bp apart, binding of GalR to the sequence-nonspecific DNA binding protein HU, interaction of HU with an architecturally critical DNA site between the two operators, and interaction between two DNA-bound GalR dimers generating a loop of the intervening DNA segment. In this paper, we demonstrate and determine the thermodynamic parameters of several of these interactions, GalR dimer-O(E), GalR tetramerization, HU-GalR, and HU-GalR-O(E) interactions, by analytical ultracentrifugation, fluorescence anisotropy, and fluorescence resonance energy transfer. The physiological significance of several of these interactions was confirmed by the finding that a mutant HU, which is unable to form the repressosome in vivo and in vitro, failed to show the HU-GalR interaction. The results help to construct a pathway of Gal repressosome assembly.

Natural and synthetic tetracycline-inducible promoters for use in the antibiotic-producing bacteria Streptomyces

Bacteria in the genus Streptomyces are major producers of antibiotics and other pharmacologically active compounds. Genetic and physiological manipulations of these bacteria are important for new drug discovery and production development. An essential part of any 'genetic toolkit' is the availability of regulatable promoters. We have adapted the tetracycline (Tc) repressor/operator (TetR/tetO) regulatable system from transposon Tn10 for use in Streptomyces. The synthetic Tc controllable promoter (tcp), tcp830, was active in a wide range of Streptomyces species, and varying levels of induction were observed after the addition of 1-100 ng/ml of anhydrotetracycline (aTc). Streptomyces coelicolor contained an innate Tc-controllable promoter regulated by a TetR homologue (SCO0253). Both natural and synthetic promoters were active and inducible throughout growth. Using the luxAB genes expressing luciferase as a reporter system, we showed that induction factors of up to 270 could be obtained for tcp830. The effect of inducers on the growth of S.coelicolor was determined; addition of aTc at concentrations where induction is optimal, i.e. 0.1-1 microg/ml, ranged from no effect on growth rate to a small increase in the lag period compared with cultures with no inducer.

Arc Repressor−Operator DNA Interactions and Contribution of Phe10 to Binding Specificity

Solution properties of Arc repressors (wild-type and F10H variant) from Salmonella bacteriophage P22 and their complexes with operator DNA (Arc-wt-DNA and Arc-F10H-DNA) were characterized by circular dichroism, fluorescence, and Raman difference spectroscopy and compared with the crystal structures of free and DNA-bound Arc repressors (wild-type and F10V variant). From the crystal structure of Arc-wt-operator DNA complex, it is known that amino acids Phe10/10' flip out of the hydrophobic protein core, and in the Arc-F10V-DNA complex, the methyl groups of Val10/10' rotate toward the DNA. Arc-wt and Arc-F10H significantly perturb the Raman signatures of the operator DNA upon complex formation. The two proteins induce similar changes in the DNA spectra. Raman markers in the difference spectra (spectrum of the complex minus spectra of DNA and Arc) indicate binding of Arc in the major groove, several direct contacts, e.g., hydrogen bonds of protein residues with bases, and slight perturbations of the deoxyribose ring systems that are consistent with bending of the operator DNA. Trp14, the only one tryptophan of Arc repressor monomers, serves as a very sensitive tool for changes of the hydrophobic core of the protein. The Raman spectra identify in the free Arc-F10H variant a largely different chi(2,1) rotation angle of Trp14 compared to that in wild-type Arc. In the Arc-wt-DNA and Arc-F10H-DNA complexes, however, the Trp14 chi(2,1) rotation angles are similar in both proteins. Furthermore, in both complexes, a strengthening of the van der Waals interactions of the aromatic ring of Trp14 is indicated compared to these interactions in the free proteins. According to the fluorescence and Raman data, His10 is buried in the hydrophobic core of free Arc-F10H, resembling the "core" conformation of Phe10 in Arc-wt, but His10 is looped out in the complex with DNA resembling the "bound" conformation of Phe10 in the Arc-wt-operator DNA complex.

Comparative and functional genomic analyses of the pathogenicity of phytopathogen Xanthomonas campestris pv. campestris

Xanthomonas campestris pathovar campestris (Xcc) is the causative agent of crucifer black rot disease, which causes severe losses in agricultural yield world-wide. This bacterium is a model organism for studying plant-bacteria interactions. We sequenced the complete genome of Xcc 8004 (5,148,708 bp), which is highly conserved relative to that of Xcc ATCC 33913. Comparative genomics analysis indicated that, in addition to a significant genomic-scale rearrangement cross the replication axis between two IS1478 elements, loss and acquisition of blocks of genes, rather than point mutations, constitute the main genetic variation between the two Xcc strains. Screening of a high-density transposon insertional mutant library (16,512 clones) of Xcc 8004 against a host plant (Brassica oleraceae) identified 75 nonredundant, single-copy insertions in protein-coding sequences (CDSs) and intergenic regions. In addition to known virulence factors, full virulence was found to require several additional metabolic pathways and regulatory systems, such as fatty acid degradation, type IV secretion system, cell signaling, and amino acids and nucleotide metabolism. Among the identified pathogenicity-related genes, three of unknown function were found in Xcc 8004-specific chromosomal segments, revealing a direct correlation between genomic dynamics and Xcc virulence. The present combination of comparative and functional genomic analyses provides valuable information about the genetic basis of Xcc pathogenicity, which may offer novel insight toward the development of efficient methods for prevention of this important plant disease.

Activity of Lac repressor anchored to the Escherichia coli inner membrane

The transient inactivation of gene regulatory proteins by their sequestration to the cytoplasmic membrane in response to cognate signals is an increasingly recognized mechanism of gene regulation in bacteria. It remained to be shown, however, whether tethering to the membrane per se could be responsible for inactivation, i.e. whether such relocation leads to a spatial separation from the chromosome that results in inactivity or whether other mechanisms are involved. We, therefore, investigated the activity of Lac repressor artificially attached to the Escherichia coli cytoplasmic membrane. We demonstrate that this chimeric protein perfectly represses transcription initiated at the tac operator–promoter present on a plasmid and even in the chromosome. Moreover, this repression is inducible as normal. The data suggest that proteins localized to the inner face of the cytoplasmic membrane in principle have unrestricted access to the chromosome. Thus sequestration to the membrane in terms of physical separation from the chromosome cannot account alone for the inactivation of regulatory proteins. Other mechanisms, like induction of a conformational change or masking of binding domains are required additionally.

Tetracycline-dependent conditional gene knockout in Bacillus subtilis

Reversible tetracycline-dependent gene regulation allows induction of expression with the tetracycline repressor (TetR) or gene silencing with the newly developed reverse mutant revTetR. We report here the implementation of both approaches with full regulatory range in gram-positive bacteria as exemplified in Bacillus subtilis. A chromosomally located gene is controlled by one or two tet operators. The precise adjustment of regulatory windows is accomplished by adjusting tetR or revtetR expression via different promoters. The most efficient induction was 300-fold in the presence of 0.4 microM anhydrotetracycline obtained with a Pr-xylA-tetR fusion. Reversible 500-fold gene knockouts were obtained in B. subtilis after adjusting expression of revTetR by synthetically designed promoters. We anticipate that these tools will also be useful in many other gram-positive bacteria.

Mutations in PurBox1 of the Bacillus subtilis pur operon control site affect adenine-regulated expression in vivo

Transcription of the Bacillus subtilis pur operon is regulated by a purine repressor (PurR)-DNA control site interaction. The pur operon control site has two PurBoxes that are required for high-affinity PurR binding. An upstream, strong-binding PurBox1 is at position -81 to -68 relative to the transcription start site and a downstream weak-binding PurBox2 is at position -49 to -36. We constructed three PurBox1 mutations and the effects on binding of PurR to the control region in vitro and on regulation of pur operon expression in vivo were investigated. The mutations significantly reduced the binding of PurR to control region DNA. In strains with G-75A, G-75T and a five bp deletion (delta5) pur operon repression was defective in vivo. In addition in vivo PurR titration was used to confirm that sequences flanking PurBox1 and PurBox2 are required for PurR binding to the puroperon control site.

Logic functions of the genomic cis-regulatory code

cis-Regulatory modules that control developmental gene expression process the regulatory inputs provided by the transcription factors for which they contain specific target sites. A prominent class of cis-regulatory processing functions can be modeled as logic operations. Many of these are combinatorial because they are mediated by multiple sites, although others are unitary. In this work, we illustrate the repertoire of cis-regulatory logic operations, as an approach toward a functional interpretation of the genomic regulatory code.

Evidence that the Rhizobium regulatory protein RirA binds to cis-acting iron-responsive operators (IROs) at promoters of some Fe-regulated genes

Mutations in rirA of Rhizobium have been shown to deregulate expression of several genes that are normally repressed by iron. A conserved sequence, the iron-responsive operator (IRO), was identified near promoters of vbsC (involved in the synthesis of the siderophore vicibactin), rpoI (specifies an ECF sigma factor needed for vicibactin synthesis) and the two fhuA genes (encoding vicibactin receptor). Removal of these IRO sequences abolished Fe-responsive repression. Most of these genes were constitutively expressed in the heterologous host, Paracoccus denitrificans, but introduction of the cloned rirA gene repressed expression of these Rhizobium genes in this heterologous host if the corresponding IRO sequences were also intact. These observations are the first to examine the mechanisms of RirA, which has no sequence similarity to well-known iron-responsive regulators such as Fur or DtxR. They provide strong circumstantial evidence that RirA is a transcriptional regulator that binds to cis-acting regulatory sequences near the promoters of at least some of the genes whose expression it controls in response to Fe availability.

Second-generation tetracycline-regulatable promoter: repositioned tet operator elements optimize transactivator synergy while shorter minimal promoter offers tight basal leakiness

BACKGROUND

The tetracycline-regulatable system is one of the most valuable tools for controlling gene expression. In its current form, however, the system is less than ideal for in vivo or gene therapy uses due to difficulties in set-up procedures, high basal leakiness, and unpredictable delivery and efficiency.

METHODS

To address these issues, we have devised a second generation of tetracycline-regulated promoters (TREs). The second-generation TRE (SG-TRE) contains a shortened cytomegalovirus (CMV) minimal promoter together with eight tet operator sequences positioned in an optimized manner upstream of the TATA box. This construct displays far greater reduction in basal leakiness than maximal transgene expression. Conversely, maximal transgene expression is increased to a greater degree than basal leakiness by post-translational stabilization with bovine growth hormone poly A.

RESULTS

In transient studies, the SG-TRE displays over 100 000-fold regulation efficiency in HeLa cells at 1:1 ratio of transactivator to reporter plasmid in the Tet-Off system. This novel promoter achieves a regulation efficiency 500- to 1000-fold higher than that of the original TRE (P(hCMV*-1)) in HeLa cells by displaying undetectable levels of basal leakiness without compromised maximal expression. In other cell lines, the SG-TRE proves to be more efficient than the original P(hCMV*-1) in a cell-dependent manner. Furthermore, the SG-TRE preserves its enhanced regulation efficiency and its reduced basal leakiness in the context of a single positive feedback regulatory vector that presents ease of delivery of the system for use in vivo. Finally, in vivo, the biological function of granulocyte-macrophage colony stimulating factor is tightly regulated in the context of SG-TRE delivered via adeno-associated viruses.

Conditional expression of vaccinia virus genes in mammalian cell lines expressing the tetracycline repressor

A new system was developed for producing conditional-lethal vaccinia virus mutants using the tetracycline controlled gene expression system from bacteria. The tetracycline resistance operon (tetO) sequence was placed between the promoter and coding sequence of the target gene of the virus. To regulate the expression of the target gene, the tetO-containing virus was used to infect a tetracycline repressor (TetR) expressing cell line. This method allowed isolation of a tetO-containing virus in the absence of the TetR thereby eliminating the risk of selecting for an inactivated viral tetR gene caused by recombination of the virus genome and improving the stability of the engineered mutants.

Tetracycline-inducible gene regulation in mycobacteria

A system for the tetracycline-inducible regulation of gene expression in mycobacteria has been developed. We have sub-cloned the tetRO region from the Corynebacterium glutamicum TetZ locus into a mycobacterial shuttle plasmid, making expression of genes cloned downstream of tetRO responsive to tetracycline. Using the luxAB-encoded luciferase from Vibrio harveyi as a reporter (pMind-Lx), we observed a 40-fold increase in light output from Mycobacterium smegmatis cultures 2 h after adding 20 ng ml⁻¹ of tetracycline. Similarly, exposure to the drug resulted in up to 20-fold increase in relative light units from M.bovis BCG carrying the reporter construct, and a 10-fold increase for M.tuberculosis. Tetracycline induction was demonstrated in log and stationary phase cultures. To evaluate whether this system is amenable to use in vivo, J774 macrophages were infected with M.bovis BCG[pMind-Lx], treated with amikacin to kill extracellular bacteria, and then incubated with tetracycline. A 10-fold increase in light output was measured after 24 h, indicating that intracellular bacteria are accessible and responsive to exogenously added tetracycline. To test the use of the tetracycline-inducible system for conditional gene silencing, mycobacteria were transformed with a pMind construct with tetRO driving expression of antisense RNA for the ftsZ gene. Bacterial cells containing the antisense construct formed filaments after 24 h exposure to tetracycline. These results demonstrate the potential of this tetracycline-regulated system for the manipulation of mycobacterial gene expression inside and outside cells.

Controlling gene expression in mycobacteria with anhydrotetracycline and Tet repressor

Gene expression systems that allow the regulation of bacterial genes during an infection are valuable molecular tools but are lacking for mycobacterial pathogens. We report the development of mycobacterial gene regulation systems that allow controlling gene expression in fast and slow-growing mycobacteria, including Mycobacterium tuberculosis, using anhydrotetracycline (ATc) as inducer. The systems are based on the Escherichia coli Tn10-derived tet regulatory system and consist of a strong tet operator (tetO)-containing mycobacterial promoter, expression cassettes for the repressor TetR and the chemical inducer ATc. These systems allow gene regulation over two orders of magnitude in Mycobacterium smegmatis and M.tuberculosis. TetR-controlled gene expression was inducer concentration-dependent and maximal with ATc concentrations at least 10- and 20-fold below the minimal inhibitory concentration for M.smegmatis and M.tuberculosis, respectively. Using the essential mycobacterial gene ftsZ, we showed that these expression systems can be used to construct conditional knockouts and to analyze the function of essential mycobacterial genes. Finally, we demonstrated that these systems allow gene regulation in M.tuberculosis within the macrophage phagosome.

GntP is the Escherichia coli Fructuronic acid transporter and belongs to the UxuR regulon

Escherichia coli has four gluconate transporters, GntP, GntU, GntT, and IdnT, which are members of the major facilitator superfamily. The physiological function of GntP was previously unknown and is the subject of this study. GntP is not induced by gluconate, and despite being located adjacent to genes involved in glucuronate catabolism, gntP does not encode a glucuronate transporter. Here we identify gntP as the gene which encodes the fructuronate transporter. We show that gntP is induced by fructuronate and is a new member of the UxuR regulon: gntP is derepressed in an uxuR strain, UxuR binds in vitro specifically to an operator site that overlaps the gntP promoter, and UxuR binding is eliminated by fructuronate. Transcription of gntP requires activation by cyclic AMP (cAMP)-cAMP receptor protein. A gntP mutant cannot grow on fructuronate but grows normally on glucuronate and gluconate. Thus, the UxuR regulon is a module of sugar acid catabolism whose physiological role is for growth on fructuronate. Glucuronate, because it proceeds through a fructuronate intermediate, must induce the UxuR regulon and must also induce the ExuR regulon, which encodes the glucuronate transporter, ExuT, and the first step in its catabolism, UxaC. Thus, hexuronate catabolism in E. coli requires both the ExuR and UxuR regulons, while fructuronate catabolism requires only the UxuR regulon.

Nonspecific binding of the OR repressors CI and Cro of bacteriophage λ

We estimate the Gibbs free energy for nonspecific binding (DeltaGNSB) to the Escherichia coli DNA for two regulatory proteins of the lambda phage, CI and Cro. By means of a statistical-mechanical approach, we calculate the cI and cro activities associated with the operator OR of an introduced lambda phage genome (prophage). In this statistical model we apply in vitro-measured binding free energies to fit in vivo experimental data for cI and cro activities, respectively, where DeltaGNSB is introduced as a free (fitting) parameter. Without nonspecific binding included in the model, the quality of the description is fairly poor, whereas data are nicely correlating with our model with nonspecific binding included over the entire data range. The obtained values of DeltaGNSB are -4.1+/-0.9 kcal/mol, for CI, and -4.2+/-0.8 kcal/mol, for Cro. In particular, in a lysogen (approximately 250 CI monomers per cell) we conclude that 86% of the total CI in the cell is nonspecifically bound, leaving on average around 10 CI dimers freely available in the E. coli cytoplasma. These findings corroborate the view that due to low free cellular particle numbers a dynamical analysis of genetic regulation at OR and comparable systems should include a stochastic component. In addition, we perform a stability analysis of the OR system in the presence of nonspecific binding.

A Point Mutation at the C-Terminal Half of the Repressor of Temperate Mycobacteriophage L1 Affects Its Binding to the Operator DNA

The wild-type repressor CI of temperate mycobacteriophage L1 and the temperature-sensitive (ts) repressor CIts391 of a mutant L1 phage, L1cIts391, have been separately overexpressed in E. coli. Both these repressors were observed to specifically bind with the same cognate operator DNA. The operator-binding activity of CIts391 was shown to differ significantly than that of the CI at 32 to 42 degrees C. While 40-95% operator-binding activity was shown to be retained at 35 to 42 degrees C in CI, more than 75% operator-binding activity was lost in CIts391 at 35 to 38 degrees C, although the latter showed only 10% less binding compared to that of the former at 32 degrees C. The CIts391 showed almost no binding at 42 degrees C. An in vivo study showed that the CI repressor inhibited the growth of a clear plaque former mutant of the L1 phage more strongly than that of the CIts391 repressor at both 32 and 42 degrees C. The half-life of the CIts391-operator complex was found to be about 8 times less than that of the CI-operator complex at 32 degrees C. Interestingly, the repressor-operator complexes preformed at 0 degrees C have shown varying degrees of resistance to dissociation at the temperatures which inhibit the formation of these complexes are inhibited. The CI repressor, but not that of CIts391, regains most of the DNA-binding activity on cooling to 32 degrees C after preincubation at 42 to 52 degrees C. All these data suggest that the 131(st) proline residue at the C-terminal half of CI, which changed to leucine in the CIts391, plays a crucial role in binding the L1 repressor to the cognate operator DNA, although the helix-turn-helix DNA-binding motif of the L1 repressor is located at its N-terminal end.

In situ imaging and isolation of proteins using dsDNA oligonucleotides

As proteomics initiatives mature, the need will arise for the multiple visualization of proteins and supramolecular complexes within their true context, in situ. Single-stranded DNA and RNA aptamers can be used for low resolution imaging of cellular receptors and cytoplasmic proteins by light microscopy (LM). These techniques, however, cannot be applied to the imaging of nuclear antigens as these single-stranded aptamers bind endogenous RNA and DNA with high affinity. To overcome this problem, we have developed a novel method for the in situ detection of proteins using double-stranded DNA oligonucleotides. To demonstrate this system we have utilized the prokaryotic DNA-binding proteins LacI and TetR as peptide tags to image fusion proteins in situ using dsDNA oligonucleotides encoding either the Lac or Tet operator. Using fluorescent and fluorogold dsDNA oligonucleotides, we localized within the nucleus a TetR-PML fusion protein within promyelocytic leukaemia protein (PML) bodies by LM and a LacI-SC35 fusion protein within nuclear speckles by correlative light and electron microscopy (LM/EM). Isolation of LacI-SC35 was also accomplished by using biotinylated dsDNA and streptavidin sepharose. The use of dsDNA oligonucleotides should complement existing aptamer in situ detection techniques by allowing the multiple detection and localization of nuclear proteins in situ and at high resolution.

Constitutive over expression of serine/threonine protein phosphatase 5 (PP5) augments estrogen-dependent tumor growth in mice

Serine/threonine protein phosphatase 5 (PP5) appears to play an underappreciated role in the regulation of cellular proliferation. In estrogen-responsive cells, PP5 expression is stimulated by 17 beta-estradiol, and in a variety of p53 wild-type tumor cells the suppression of PP5 expression with ISIS 15534 inhibits growth. To further explore the relationship between PP5 and the development of human cancer, here we tested the effect of elevated PP5 expression on tumor growth using a mouse xenograph model and a stable MCF-7 cell line in which the expression of wild-type PP5 was placed under the control of tetracycline-off regulated transactivator and operator plasmids. In the xenograph model a modest two fold increase in PP5 protein levels significantly enhanced the growth rate of estrogen-dependent tumors, suggesting PP5 plays a positive role in tumor development.

Fur functions as an activator and as a repressor of putative virulence genes in Neisseria meningitidis

Fur is a well-known iron-responsive repressor of gene transcription, which is used by many bacteria to respond to the low-iron environment that pathogens encounter during infection. Four promoters of Neisseria meningitidis predicted to have Fur-binding boxes were selected to study the molecular interactions between Fur and the promoter regions of genes expected to play a central role in survival and pathogenesis. We demonstrate that Fur acts not only as a repressor, but also as an activator of gene expression both in vivo and in vitro. We report that Fur binds to operators located upstream of three promoters that are positively regulated in vivo by Fur and iron, whereas Fur binds to an operator overlapping the classically iron-repressed tbp promoter. Deletion of the upstream operator in the norB promoter abolished activation of transcription in vivo in response to iron and in vitro in response to Fur. The role of such a dual mechanism of Fur regulation during infection is discussed.

The Saccharomyces cerevisiae TRT2 tRNAThr gene upstream of STE6 is a barrier to repression in MATalpha cells and exerts a potential tRNA position effect in MATa cells

A growing body of evidence suggests that genes transcribed by RNA polymerase III exhibit multiple functions within a chromosome. While the predominant function of these genes is the synthesis of RNA molecules, certain RNA polymerase III genes also function as genomic landmarks. Transfer RNA genes are known to exhibit extra-transcriptional activities such as directing Ty element integration, pausing of replication forks, overriding nucleosome positioning sequences, repressing neighboring genes (tRNA position effect), and acting as a barrier to the spread of repressive chromatin. This study was designed to identify other tRNA loci that may act as barriers to chromatin-mediated repression, and focused on TRT2, a tRNA(Thr) adjacent to the STE6 alpha2 operator. We show that TRT2 acts as a barrier to repression, protecting the upstream CBT1 gene from the influence of the STE6 alpha2 operator in MATalpha cells. Interestingly, deletion of TRT2 results in an increase in CBT1 mRNA levels in MATa cells, indicating a potential tRNA position effect. The transcription of TRT2 itself is unaffected by the presence of the alpha2 operator, suggesting a hierarchy that favors assembly of the RNA polymerase III complex versus assembly of adjacent alpha2 operator-mediated repressed chromatin structures. This proposed hierarchy could explain how tRNA genes function as barriers to the propagation of repressive chromatin.

Transcriptional Repressor CopR: use of SELEX to study the copR operator indicates that evolution was directed at maximal binding affinity

CopR is one of the two copy number control elements of the streptococcal plasmid pIP501. It represses transcription of the repR mRNA encoding the essential replication initiator protein about 10- to 20-fold by binding to its operator region upstream of the repR promoter pII. CopR binds at two consecutive sites in the major groove of the DNA that share the consensus motif 5'-CGTG. Previously, the minimal operator was narrowed down to 17 bp, and equilibrium dissociation constants for DNA binding and dimerization were determined to be 0.4 nM and 1.4 microM, respectively. In this work, we used a SELEX procedure to study copR operator sequences of different lengths in combination with electrophoretic mobility shift assays of mutated copR operators as well as copy number determinations to assess the sequence requirements for CopR binding. The results suggest that in vivo evolution was directed at maximal binding affinity. Three simultaneous nucleotide exchanges outside the bases directly contacted by CopR only slightly affected CopR binding in vitro or copy numbers in vivo. Furthermore, the optimal spacer sequence was found to comprise 7 bp, to be AT rich, and to need an A/T and a T at the 3' positions, whereas broad variations in the sequences flanking the minimal 17-bp operator were well tolerated.

DNA-mediated assembly of weakly interacting DNA-binding protein subunits: in vitro recruitment of phage 434 repressor and yeast GCN4 DNA-binding domains

The specificity of DNA-mediated protein assembly was studied in two in vitro systems, based on (i) the DNA-binding domain of bacteriophage 434 repressor cI (amino acid residues 1-69), or (ii) the DNA-binding domain of the yeast transcription factor GCN4, (amino acids 1-34) and their respective oligonucleotide cognates. In vivo, both of these peptides are part of larger protein molecules that also contain dimerization domains, and the resulting dimers recognize cognate palindromic DNA sequences that contain two half-sites of 4 bp each. The dimerization domains were not included in the peptides tested, so in solution-in the presence or absence of non-cognate DNA oligonucleotides-these molecules did not show appreciable dimerization, as determined by pyrene excimer fluorescence spectroscopy and oxidative cross-linking monitored by mass spectrometry. Oligonucleotides with only one 4 bp cognate half-site were able to initiate measurable dimerization, and two half-sites were able to select specific dimers even from a heterogeneous pool of molecules of closely related specificity (such as DNA-binding domains of the 434 repressor and their engineered mutants that mimic the binding helix of the related P22 phage repressor). The fluorescent technique allowed us to separately monitor the unspecific, ionic interaction of the peptides with DNA which produced a roughly similar signal in the case of both cognate and non-cognate oligonucleotides. But in the former case, a concomitant excimer fluorescence signal showed the formation of correctly positioned dimers. The results suggest that DNA acts as a highly specific template for the recruitment of weakly interacting protein molecules that can thus build up highly specific complexes.

Identification of operators and promoters that control SXT conjugative transfer

Transfer of SXT, a Vibrio cholerae-derived integrating conjugative element that encodes multiple antibiotic resistance genes, is repressed by SetR, a lambda434 cI-related repressor. Here we identify divergent promoters between s086 and setR that drive expression of the regulators of SXT transfer. One transcript encodes the activators of transfer, setC and setD. The second transcript codes for SetR and, like the cI transcript of lambda, is leaderless. SetR binds to four operators located between setR and s086; the locations and relative affinities of these sites suggest a model for regulation of SXT transfer.

Effect of Plasmid Copy Number and lac Operator Sequence on Antibiotic-Free Plasmid Selection by Operator-Repressor Titration in Escherichia coli

The Escherichia coli strain DH1lacdapD enables plasmid selection and maintenance that is free from antibiotics and selectable marker genes. This is achieved by using only the lac operator sequence as a selectable element. This strain is currently used to generate high copy number plasmids with no antibiotic resistance genes for use as DNA vaccines and for expression of recombinant proteins. Until now these have been limited to pUC-based plasmids containing a high copy number pMB1-derived origin of replication, and the principle lacO(1) and auxiliary lacO(3) operators. In this study we have shown that this system can also be used to select and maintain pBR322-based plasmids with the lower copy number pMB1 origin of replication, and that lacO(1) alone or a palindromic version of lacO(1) can provide a sufficient level of repressor titration for plasmid selection. This is advantageous for recombinant protein production, where low copy number plasmids are often used and plasmid maintenance is important. The degree of repressor titration due to these plasmids was measured using the natural lactose operon in E. coli DH1 as a model.

Two arginine repressors regulate arginine biosynthesis in Lactobacillus plantarum

The repression of the carAB operon encoding carbamoyl phosphate synthase leads to Lactobacillus plantarum FB331 growth inhibition in the presence of arginine. This phenotype was used in a positive screening to select spontaneous mutants deregulated in the arginine biosynthesis pathway. Fourteen mutants were genetically characterized for constitutive arginine production. Mutations were located either in one of the arginine repressor genes (argR1 or argR2) present in L. plantarum or in a putative ARG operator in the intergenic region of the bipolar carAB-argCJBDF operons involved in arginine biosynthesis. Although the presence of two ArgR regulators is commonly found in gram-positive bacteria, only single arginine repressors have so far been well studied in Escherichia coli or Bacillus subtilis. In L. plantarum, arginine repression was abolished when ArgR1 or ArgR2 was mutated in the DNA binding domain, or in the oligomerization domain or when an A123D mutation occurred in ArgR1. A123, equivalent to the conserved residue A124 in E. coli ArgR involved in arginine binding, was different in the wild-type ArgR2. Thus, corepressor binding sites may be different in ArgR1 and ArgR2, which have only 35% identical residues. Other mutants harbored wild-type argR genes, and 20 mutants have lost their ability to grow in normal air without carbon dioxide enrichment; this revealed a link between arginine biosynthesis and a still-unknown CO2-dependent metabolic pathway. In many gram-positive bacteria, the expression and interaction of different ArgR-like proteins may imply a complex regulatory network in response to environmental stimuli.

Using networks to identify fine structural differences between functionally distinct protein states

The vast increase in available data from the "-omics" revolution has enabled the fields of structural proteomics and structure prediction to make great progress in assigning realistic three-dimensional structures to each protein molecule. The challenge now lies in determining the fine structural details that endow unique functions to sequences that assume a common fold. Similar problems are encountered in understanding how distinct conformations contribute to different phases of a single protein's dynamic function. However, efforts are hampered by the complexity of these large, three-dimensional molecules. To overcome this limitation, structural data have been recast as two-dimensional networks. This analysis greatly reduces visual complexity but retains information about individual residues. Such diagrams are very useful for comparing multiple structures, including (1) homologous proteins, (2) time points throughout a dynamics simulation, and (3) functionally different conformations of a given protein. Enhanced structural examination results in new functional hypotheses to test experimentally. Here, network representations were key to discerning a difference between unliganded and inducer-bound lactose repressor protein (LacI), which were previously presumed to be identical structures. Further, the interface of unliganded LacI was surprisingly similar to that of the K84L variant and various structures generated by molecular dynamics simulations. Apo-LacI appears to be poised to adopt the conformation of either the DNA- or inducer-bound structures, and the K84L mutation appears to freeze the structure partway through the conformational transition. Additional examination of the effector binding pocket results in specific hypotheses about how inducer, anti-inducer, and neutral sugars exert their effects on repressor function.

Genes regulated by TorR, the trimethylamine oxide response regulator of Shewanella oneidensis

The torECAD operon encoding the trimethylamine oxide (TMAO) respiratory system of Shewanella oneidensis is positively controlled by the TorS/TorR two-component system when TMAO is available. Activation of the tor operon occurs upon binding of the phosphorylated response regulator TorR to a single operator site containing the direct repeat nucleotide sequence TTCATAN4TTCATA. Here we show that the replacement of any nucleotide of one TTCATA hexamer prevented TorR binding in vitro, meaning that TorR specifically interacts with this DNA target. Identical direct repeat sequences were found in the promoter regions of torR and of the new gene torF (SO4694), and they allowed TorR binding to both promoters. Real-time PCR experiments revealed that torR is negatively autoregulated, whereas torF is strongly induced by TorR in response to TMAO. Transcription start site location and footprinting analysis indicate that the operator site at torR overlaps the promoter -10 box, whereas the operator site at torF is centered at -74 bp from the start site, in agreement with the opposite role of TorR in the regulation of the two genes. Since torF and torECAD are positively coregulated by TorR, we propose that the TorF protein plays a role related to TMAO respiration.

Quantitative modeling of DNA-protein interactions: effects of amino acid substitutions on binding specificity of the Mnt repressor

Understanding DNA-protein recognition quantitatively is essential to developing computational algorithms for accurate transcriptional binding site prediction. Using a quantitative, multiple fluorescence, relative affinity (QuMFRA) assay, we determine the binding specificity of 11 different position 6 variants of the Mnt repressor for operators containing all 16 possible dinucleotides at operator positions 16 and 17. We show that the wild-type and all variant proteins interact with the two positions in a non-independent manner, but that a simple independent model provides a close approximation to the true binding affinities. The wild-type His at amino acid 6 is the only protein to prefer the AC sequence of the wild-type operator, whereas most of the variant proteins prefer TA. H6R is unique in having a strong preference for C at position 16. A comparison of the quantitative binding data for all of the protein variants with a model for recognition of the early growth response (EGR) zinc finger family suggests that interactions of Mnt with positions 16 and 17 are similar to interactions of EGR with positions 1 and 2, respectively. This information leads to an augmented model for the interaction of Mnt with its operator.

DNA trajectory in the Gal repressosome

The Gal repressosome is a higher-order nucleoprotein complex that represses transcription of the gal operon in Escherichia coli. During the repressosome assembly, a DNA loop is formed by the interaction of two GalR dimers, bound to two spatially separated operators, OE and OI, flanking the gal promoters. Structure-based genetic analysis indicated that GalR homodimers interact directly and form a V-shaped stacked tetramer in repressosome, further stabilized by HU binding to an architecturally critical position on the DNA. In this scheme of GalR tetramerization, the alignment of the operators in the DNA loop could be in either parallel (PL) or antiparallel (AL) mode. As each mode can have two alternative geometries differing in the mutual stacking of the OE- and OI-bound GalR dimers, it is possible to have four different DNA trajectories in the repressosome. Feasibilities of these trajectories were tested by in vitro transcription repression assays, first by isolating GalR mutants with altered operator specificity and then by constructing four different potential loops with mutant GalR heterodimers bound to specifically designed hybrid operators in such a way as to give rise to only one of the four putative trajectories. Results show that OE and OI adopt a mutual antiparallel orientation in an under-twisted DNA loop, consistent with the energetically optimal structural model. In this structure the center of the HU-binding site is located at the apex of the DNA loop. The approach reported here can be used to distinguish between otherwise indistinguishable DNA trajectories in complex nucleoprotein machines.

pH-dependent autocleavage of lambda repressor occurs in the operator-bound form: characterization of lambda repressor autocleavage

The first-order rate constants for the RecA-independent, spontaneous, pH-dependent autocleavage of the lambda cI repressor was measured in the present study at pH 10.6 at 27, 37 and 42 degrees C respectively. Autocleavage of the repressor occurs also at pH 9 and 8, although at progressively slower rates. We demonstrate that the spontaneous autocleavage occurs also in the operator-bound state, at a rate either higher than or equal to the rate in solution, depending on the pH value. Owing to the near equality of the rate constant in both operator-free and operator-bound repressors, it can be inferred that the cleavage site has a similar structure and dynamics with respect to the catalytic site in both forms at neutral pH. Covalent modification using PMSF, brought about by a large molar excess of the reagent, inhibits autocleavage of the lambda repressor. The difficulty in obtaining this covalent modification is rationalized using our recent lambda repressor models. Bimolecular type II trans -cleavage was observed previously for mutant LexA repressors lacking a crucial catalytic serine or lysine residue [Kim and Little (1993) Cell (Cambridge, Mass.) 73, 1165-1173], but it could still be cleaved by an 85-202 'enzyme' fragment possessing an improved or hypercleavable character lacking its own cleavage site. Such a type II trans -cleavage was not observed with the covalently modified intact lambda repressor used as substrate and the purified wild-type lambda repressor 112-236 fragment used as the 'enzyme'. All these results show that for the wild-type lambda repressor, the catalytic site is close to the cleavage site in both operator-free and -bound states. In the lytic pathway, the repressor is mainly cleaved via RecA-mediated cleavage, which occurs much faster than the spontaneous autocleavage; the possible biological significance of this slow, spontaneous, but constant, autocleavage is related to the lysogenic state, when RecA-mediated cleavage is absent.