Activation from a distance: roles of Lrp and integration host factor in transcriptional activation of gltBDF.

The leucine-responsive regulatory protein (Lrp) binds to three sites centered 252, 216, and 152 bp upstream of the transcription start site of the Escherichia coli glutamate synthase operon (gltBDF) and activates transcription. Activators of sigma(70)-dependent promoters usually bind closer to the -35 hexamer of the core promoter sequence. To study the mechanism by which Lrp-dependent activation occurs over this relatively large distance, the gltBDF upstream region was sequentially replaced with corresponding portions from the well-characterized sigma(70)-dependent promoter lacZYAp. The glt-lac promoter hybrids were placed upstream of lacZ, allowing transcriptional activity to be monitored via beta-galactosidase assays. Even replacing all gltBDF sequences downstream of and including the -35 hexamer did not eliminate Lrp-dependent activation of transcription. When a 91-bp region between the -35 hexamer and the proximal Lrp binding site (-48 to -128) was replaced with heterologous DNA of the same length, transcription was reduced nearly 40-fold. Based on the presence of a consensus binding sequence, this region seemed likely to be a binding site for integration host factor (IHF). Experiments to study the effects of a himD mutant on expression of a gltB::lacZ transcriptional fusion, gel mobility shift analyses, and DNA footprinting assays were used to confirm the direct participation of IHF in gltBDF promoter regulation. Based on these results, we suggest that IHF plays a crucial architectural role, bringing the distant Lrp complex in close proximity to the promoter-bound RNA polymerase.

Recognition of native DNA methylation by the PvuII restriction endonuclease.

Recognizing the methylation status of specific DNA sequences is central to the function of many systems in eukaryotes and prokaryotes. Restriction-modification systems have to distinguish between 'self' and 'non-self' DNA and depend on the inability of restriction endonucleases to cleave their DNA substrates when the DNA is appropriately methylated. These endonucleases thus provide a model system for studying the recognition of DNA methylation by proteins. We have characterized the interaction of R.PVU:II with DNA containing the physiologically relevant N4-methylcytosine modification. R.PVU:II binds (N4m)C-modified DNA and cleaves it very slowly. Methylated strands in hemimethylated duplexes were cleaved at a higher rate than in fully methylated duplexes, in parallel with a higher binding affinity for hemimethylated DNA. The co-crystal structures of R.PVU:II-DNA, together with a mutagenesis study, have implicated specific amino acids in recognition of the methylatable base; one of these is His84. We report that replacing His84 with Ala reduced the rate of cleavage of unmodified DNA but, in contrast, slightly increased the cleavage of (N4m)C-modified DNA.

Role and mechanism of action of C. PvuII, a regulatory protein conserved among restriction-modification systems.

The PvuII restriction-modification system is a type II system, which means that its restriction endonuclease and modification methyltransferase are independently active proteins. The PvuII system is carried on a plasmid, and its movement into a new host cell is expected to be followed initially by expression of the methyltransferase gene alone so that the new host's DNA is protected before endonuclease activity appears. Previous studies have identified a regulatory gene (pvuIIC) between the divergently oriented genes for the restriction endonuclease (pvuIIR) and modification methyltransferase (pvuIIM), with pvuIIC in the same orientation as and partially overlapping pvuIIR. The product of pvuIIC, C. PvuII, was found to act in trans and to be required for expression of pvuIIR. In this study we demonstrate that premature expression of pvuIIC prevents establishment of the PvuII genes, consistent with the model that requiring C. PvuII for pvuIIR expression provides a timing delay essential for protection of the new host's DNA. We find that the opposing pvuIIC and pvuIIM transcripts overlap by over 60 nucleotides at their 5' ends, raising the possibility that their hybridization might play a regulatory role. We furthermore characterize the action of C. PvuII, demonstrating that it is a sequence-specific DNA-binding protein that binds to the pvuIIC promoter and stimulates transcription of both pvuIIC and pvuIIR into a polycistronic mRNA. The apparent location of C. PvuII binding, overlapping the -10 promoter hexamer and the pvuIICR transcriptional starting points, is highly unusual for transcriptional activators.

Mapping regulatory networks in microbial cells.

Genome sequences are the blueprints of diverse life forms but they reveal little information about how cells make coherent responses to environmental changes. The combined use of gene fusions, gene chips, 2-D polyacrylamide gel electrophoresis, mass spectrometry and 'old-fashioned' microbial physiology will provide the means to reveal a cell's regulatory networks and how those networks are integrated.

Substrate recognition by the Pvu II endonuclease: binding and cleavage of CAG5mCTG sites.

The Pvu II restriction endonuclease (R. Pvu II) cleaves CAG downward arrowCTG sequences as indicated, leaving blunt ends. Its cognate methyltransferase (M. Pvu II) generates N4-methylcytosine, yielding CAGN4mCTG, though the mechanism by which this prevents cleavage by R. Pvu II is unknown. The heterologous 5-methylcytosinemethylation CAG5mCTG has also been reported to prevent cleavage by R. Pvu II and this has been used in some cloning methods. Since this heterologousmethylation occurs at the native methylated base, it can provide insights into the detection of DNAmethylation by R. Pvu II. We found that the cloned gene for R. Pvu II could not stably transform cells protected only by M. Alu I (AG5mCT) and then determined that R. Pvu II cleaves CAG5mCTG in vitro, even when both strands are methylated. DNase I footprint analysis and competition experiments reveal that R. Pvu II binds to CAG5mCTG specifically, though with reduced affinity relative to the unmethylated sequence. These results provide biochemical support for the publishedstructures of R. Pvu II complexed with DNA containing CAGCTG and CAG5-iodoCTG and support a model for how methylation interferes with DNA cleavage by this enzyme.

Use of an inducible regulatory protein to identify members of a regulon: application to the regulon controlled by the leucine-responsive regulatory protein (Lrp) in Escherichia coli.

Procedures were developed to facilitate the identification of genes that belong to a given regulon and characterization of their responses to the regulator. The regulon controlled by the Escherichia coli leucine-responsive regulatory protein (Lrp) was studied by isolating random transcriptional fusions to lacZ, using lambda placMu53 and a strain in which lrp is under isopropylthio-beta-D-galactopyranoside (IPTG)-inducible control. Fusions exhibiting IPTG-responsive beta-galactosidase activity were cloned by integrating the suicide vector pIVET1 via homologous recombination at lacZ, followed by self-ligating digested chromosomal DNA. We verified the patterns of lacZ expression after using the plasmid clones to generate merodiploid strains with interrupted and uninterrupted copies of the same sequence. If the merodiploid expression pattern was unchanged from that shown by the original fusion strain, then the cloned fusion was responsible for the regulatory pattern of interest; a difference in the expression pattern could indicate that the original strain carried multiple fusions or that there were autogenous effects of having interrupted the fused gene. Using these procedures, we generated a fusion library of approximately 5 x 10(6) strains; approximately 3,000 of these strains were screened, yielding 84 Lrp-responsive fusions, and 10 of the 84 were phenotypically stable and were characterized. The responses of different fusions in a given operon to in vivo Lrp titrations revealed variations in expression with the position of insertion. Among the newly identified members of the regulon is an open reading frame (orf3) between rpiA and serA. Also, expression of a fusion just downstream of dinF was found to be Lrp dependent only in stationary phase.

Expression, purification, mass spectrometry, crystallization and multiwavelength anomalous diffraction of selenomethionyl PvuII DNA methyltransferase (cytosine-N4-specific).

The type II DNA-methyltransferase (cytosine N4-specific) M.PvuII was overexpressed in Escherichia coli, starting from the internal translation initiator at Met14. Selenomethionine was efficiently incorporated into this short form of M.PvuII by a strain prototrophic for methionine. Both native and selenomethionyl M.PvuII were purified to apparent homogeneity by a two-column chromatography procedure. The yield of purified protein was approximately 1.8 mg/g bacterial paste. Mass spectrometry analysis of selenomethionyl M.PvuII revealed three major forms that probably differ in the degree of selenomethionine incorporation and the extent of selenomethionine oxidation. Amino acid sequencing and mass spectrometry analysis of selenomethionine-containing peptides suggests that Met30, Met51, and Met261 were only partially replaced by selenomethionine. Furthermore, amino acid 261 may be preferentially oxidized in both native and selenomethionyl form. Selenomethionyl and native M.PvuII were crystallized separately as binary complexes of the methyl donor S-adenosyl-L-methionine in the monoclinic space group P2(1). Two complexes were present per asymmetric unit. Six out of nine selenium positions (per molecule), including the three that were found to be partially substituted, were identified crystallographically.

A nucleoprotein activation complex between the leucine-responsive regulatory protein and DNA upstream of the gltBDF operon in Escherichia coli.

The global regulator Lrp (leucine-responsive regulatory protein), in some cases modulated by its co-regulator leucine, has been shown to regulate more than 40 genes and operons in Escherichia coli. Leucine modulates Lrp regulation of leucine-responsive operons. The level of sensitivity of these operons to leucine varies greatly, but the basis for this variation is only partially understood. One operon controlled by Lrp that is relatively insensitive to leucine is gltBDF, which includes genes specifying the large (GltB) and small (GltD) subunits of glutamate synthase. Earlier gel mobility shift assays have demonstrated that Lrp binds to a fragment of DNA containing the gltBDF promoter region. To further define the nature of this Lrp-gltBDF interaction, DNase I footprinting experiments were performed. The results indicate that Lrp binds cooperatively to three sites quite far upstream, spanning the region from -140 to -260 base-pairs relative to the start of transcription. Phased hypersensitivity is observed throughout the entire binding region, suggesting that Lrp bends the DNA. To determine the relative importance of these three sites for the transcriptional activation of gltBDF, a series of site-directed mutations was generated. The effects of these mutations on Lrp binding were determined both by DNase I footprinting and by quantitative mobility shift assays, while their effects on transcription in vivo were examined by measuring beta-galactosidase activity levels of chromosomal gltB::lacZ operon fusions. Our results indicate that all three sites are required for maximal gene expression, as is the proper phasing of the sites with one another and with the start of transcription. Our results suggest that Lrp binds a central palindromic site, interacting predominantly with the major groove of its DNA target, and that additional dimers bind to flanking sites to form a nucleoprotein activation complex.

Structure of pvu II DNA-(cytosine N4) methyltransferase, an example of domain permutation and protein fold assignment.

We have determined the structure of Pvu II methyltransferase (M. Pvu II) complexed with S -adenosyl-L-methionine (AdoMet) by multiwavelength anomalous diffraction, using a crystal of the selenomethionine-substituted protein. M. Pvu II catalyzes transfer of the methyl group from AdoMet to the exocyclic amino (N4) nitrogen of the central cytosine in its recognition sequence 5'-CAGCTG-3'. The protein is dominated by an open alpha/beta-sheet structure with a prominent V-shaped cleft: AdoMet and catalytic amino acids are located at the bottom of this cleft. The size and the basic nature of the cleft are consistent with duplex DNA binding. The target (methylatable) cytosine, if flipped out of the double helical DNA as seen for DNA methyltransferases that generate 5-methylcytosine, would fit into the concave active site next to the AdoMet. This M. Pvu IIalpha/beta-sheet structure is very similar to those of M. Hha I (a cytosine C5 methyltransferase) and M. Taq I (an adenine N6 methyltransferase), consistent with a model predicting that DNA methyltransferases share a common structural fold while having the major functional regions permuted into three distinct linear orders. The main feature of the common fold is a seven-stranded beta-sheet (6 7 5 4 1 2 3) formed by five parallel beta-strands and an antiparallel beta-hairpin. The beta-sheet is flanked by six parallel alpha-helices, three on each side. The AdoMet binding site is located at the C-terminal ends of strands beta1 and beta2 and the active site is at the C-terminal ends of strands beta4 and beta5 and the N-terminal end of strand beta7. The AdoMet-protein interactions are almost identical among M. Pvu II, M. Hha I and M. Taq I, as well as in an RNA methyltransferase and at least one small molecule methyltransferase. The structural similarity among the active sites of M. Pvu II, M. Taq I and M. Hha I reveals that catalytic amino acids essential for cytosine N4 and adenine N6 methylation coincide spatially with those for cytosine C5 methylation, suggesting a mechanism for amino methylation.

The PvuII DNA (cytosine-N4)-methyltransferase comprises two trypsin-defined domains, each of which binds a molecule of S-adenosyl-L-methionine.

Earlier studies have shown that PvuII methyltransferase is monomeric and transfers a methyl group from S-adenosyl-l-methionine (AdoMet) to cytosine, generating N4-methylcytosine in duplex 5'-CAGCTG-3' DNA. This study examines the interactions between PvuII methyltransferase and AdoMet. Trypsin preferentially cleaved the protein into two large fragments, with initial cleavages after Arg183 and Lys186. UV-mediated photochemical labeling with [3H-CH3]AdoMet, followed by trypsin digestion, revealed that both large fragments of the protein were labeled. Rapid gel filtration confirmed that each molecule of the intact enzyme bound two molecules of AdoMet (net Kd = 9.3 microM). When PvuII methyltransferase was preincubated with a range of [3H-CH3]AdoMet concentrations, bursts of product formation resulted upon DNA addition. These data indicate that PvuII methyltransferase is catalytically competent with one and with two bound molecules of AdoMet. These results, together with those from earlier studies, suggest possible roles for the second molecule of AdoMet.

A genetic and functional analysis of the unusually large variable region in the M.AluI DNA-(cytosine C5)-methyltransferase.

The M.AluI DNA-(cytosine C5)-methyltransferase (5mC methylase) acts on the sequence 5'-AGCT-3'. The amino acid sequences of known 5mC methylases contain ten conserved motifs, with a variable region between Motifs VIII and IX that contains one or more "target-recognizing domains" (TRDs) responsible for DNA sequence specificity. Monospecific 5mC methylases are believed to have only one TRD, while multispecific 5mC methylases have as many as five. M.AluI has the second-largest variable region of all known 5mC methylases, and sequence analysis reveals five candidate TRDs. In testing whether M.AluI is in fact monospecific it was found that AGCT methylation represents only 80-90% of the methylating activity of this enzyme, while control experiments with the enzyme M.HhaI gave no unexplained activity. Because individual TRDs can be deleted from multispecific methylases without general loss of activity, a series of insertion and deletion mutants of the M.AluI variable region were prepared. All deletions that removed more than single amino acids from the variable region caused significant loss of activity; a sensitive in vivo assay for methylase activity based on McrBC restriction suggested that the central portion of the variable region is particularly important. In some cases, multispecific methylases can accommodate a TRD from another multispecific methylase, thereby acquiring an additional specificity. When TRDs were moved from a multispecific methylase into two different locations in the variable region of M.AluI, all hybrid enzymes had greatly reduced activity and no new specificities. M.AluI thus behaves in most respects as a monospecific methylase despite the remarkable size of its variable region.

Use of an in vivo titration method to study a global regulator: effect of varying Lrp levels on expression of gltBDF in Escherichia coli.

Most studies of global regulatory proteins are performed in vitro or involve phenotypic comparisons between wild-type and mutant strains. We report the use of strains in which the gene for the leucine-responsive regulatory protein (lrp) is transcribed from isopropyl-beta-D-thiogalactopyranoside (IPTG)-inducible promoters for the purpose of continuously varying the in vivo concentration of Lrp. To obtain a broad range of Lrp concentrations, strains were employed that contained the lrp fusion either in the chromosome (I. C. Blomfield, P. J. Calie, K. J. Eberhardt, M. S. McClain, and B. I. Eisenstein, J. Bacteriol. 175:27-36, 1993) or on a multicopy plasmid. Western blot (immunoblot) analysis with polyclonal antiserum to Lrp confirmed that Lrp levels could be varied more than 70-fold by growing the strains in glucose minimal 3-(N-morpholino)propanesulfonic acid (MOPS) medium containing different amounts of IPTG. Expression of an Lrp-regulated gltB::lacZ operon fusion was measured over this range of Lrp concentrations. beta-Galactosidase activity rose with increasing Lrp levels up to the level of Lrp found in wild-type strains, at which point expression is maximal. The presence of leucine in the medium increased the level of Lrp necessary to achieve half-maximal expression of the gltB::lacZ fusion, as predicted by earlier in vitro studies (B. R. Ernsting, J. W. Denninger, R. M. Blumenthal, and R. G. Matthews, J. Bacteriol. 175:7160-7169, 1993). Interestingly, levels of Lrp greater than those in wild-type cells interfered with activation of gltB::lacZ expression. The growth rate of cultures correlated with the intracellular Lrp concentration: levels of Lrp either lower or higher than wild-type levels resulted in significantly slower growth rates. Thus, the level of Lrp in the cell appears to be optimal for rapid growth in minimal medium, and the gltBDF control region is designed to give maximal expression at this Lrp level.

Finding a basis for flipping bases.

Rotation of a DNA nucleotide out of the double helix and into a protein binding pocket ('base flipping') was first observed in the structure of a DNA methyltransferase. There is now evidence that a variety of proteins use base flipping in their interactions with DNA. Though the mechanism for base flipping is still unclear, we propose a three-step pathway: recognizing the target site and increasing the interstrand phosphate-phosphate distance nearby, initiating base flipping by protein invasion of the DNA, and trapping the flipped DNA structure.

Host-mediated modification of PvuII restriction in Mycobacterium tuberculosis.

Restriction endonuclease PvuII plays a central role in restriction fragment length polymorphism analysis of Mycobacterium tuberculosis complex isolates with IS6110 as a genetic marker. We have investigated the basis for an apparent dichotomy in PvuII restriction fragment pattersn observed among strains of the M. tuberculosis complex. The chromosomal regions of two modified PvuII restriction sites, located upstream of the katG gene and downstream of an IS1081 insertion sequence, were studied in more detail. An identical 10-bp DNA sequence (CAGCTGGAGC) containing a PvuII site was found in both regions, and site-directed mutagenesis analysis revealed that this sequence was a target for modification. Strain-specific modification of PvuII sites was identified in DNA from over 80% of the nearly 800 isolates examined. Furthermore, the proportion of modifying and nonmodifying strains differs significantly from country to country.

Structure-guided analysis reveals nine sequence motifs conserved among DNA amino-methyltransferases, and suggests a catalytic mechanism for these enzymes.

Previous X-ray crystallographic studies have revealed that the catalytic domain of a DNA methyltransferase (Mtase) generating C5-methylcytosine bears a striking structural similarity to that of a Mtase generating N6-methyladenine. Guided by this common structure, we performed a multiple sequence alignment of 42 amino-Mtases (N6-adenine and N4-cytosine). This comparison revealed nine conserved motifs, corresponding to the motifs I to VIII and X previously defined in C5-cytosine Mtases. The amino and C5-cytosine Mtases thus appear to be more closely related than has been appreciated. The amino Mtases could be divided into three groups, based on the sequential order of motifs, and this variation in order may explain why only two motifs were previously recognized in the amino Mtases. The Mtases grouped in this way show several other group-specific properties, including differences in amino acid sequence, molecular mass and DNA sequence specificity. Surprisingly, the N4-cytosine and N6-adenine Mtases do not form separate groups. These results have implications for the catalytic mechanisms, evolution and diversification of this family of enzymes. Furthermore, a comparative analysis of the S-adenosyl-L-methionine and adenine/cytosine binding pockets suggests that, structurally and functionally, they are remarkably similar to one another.

Gene pvuIIW: a possible modulator of PvuII endonuclease subunit association.

The PvuII restriction-modification system has been found to contain three genes which code for a DNA methyltransferase (MTase), a restriction endonuclease (ENase) and a small protein required for expression of the ENase-encoding gene. In addition, there is a small open reading frame (ORF) within and opposite to the MTase-encoding gene. The region containing this ORF is transcribed, and the ORF has an excellent Shine-Dalgarno sequence with an ATA start codon. A closely related ORF is present in the SmaI system. The 28-amino-acid (aa) predicted peptide from the PvuII ORF resembles a region of the PvuII ENase at the dimer interface. We have cloned this ORF, giving it an ATG start codon and putting it under the control of an inducible promoter: induction leads to a slight but significant decrease in restriction of bacteriophage lambda. We also have obtained the 28-aa synthetic peptide, and are exploring the possibility that it modulates ENase subunit association. While this peptide has no detectable effect on dimeric PvuII ENase, it inhibits renaturation of urea-denatured ENase in a concentration-dependent manner. The ORF may represent an additional safeguard during establishment of the PvuII restriction-modification system in a new host cell, helping to delay the appearance of active ENase dimers, while the MTase accumulates and protects the host chromosome.

Characterization of pPvu1, the autonomous plasmid from Proteus vulgaris that carries the genes of the PvuII restriction-modification system.

Plasmid pPvu1 from Proteus vulgaris carries the genes of the PvuII restriction-modification system [Blumenthal et al., J. Bacteriol. 164 (1985) 501-509]. This report focuses on physical and functional features of the 4.84-kb plasmid, which shows a composite genetic architecture. Plasmid pPvu1 has a replication origin and an incompatibility locus that each function in Escherichia coli, and an apparent cer recombination site. The replication origin includes a possible RNA I gene, and the incompatibility locus closely resembles a rom gene. These loci show substantial sequence similarity to corresponding loci from the E. coli plasmids P15A, ColEI and pSC101, and closely flank the PvuII genes. The close association between a recombinational locus and the PvuII genes has implications for their mobility.

The leucine-responsive regulatory protein of Escherichia coli negatively regulates transcription of ompC and micF and positively regulates translation of ompF.

The two major porins of Escherichia coli K-12 strains, OmpC and OmpF, are inversely regulated with respect to one another. The expression of OmpC and OmpF has been shown to be influenced by the leucine-responsive regulatory protein (Lrp): two-dimensional gel electrophoresis of proteins from strains with and strains without a functional Lrp protein revealed that OmpC expression is increased in an lrp strain, while OmpF expression is decreased. In agreement with these findings, we now present evidence that transcriptional (operon) fusions of lacZ+ to ompC and micF are negatively regulated by Lrp. Lrp binds specifically to the intergenic region between micF and ompC, as indicated by mobility shift assays and by DNase I footprinting. The expression of an ompF'-lacZ+ gene (translational) fusion is increased 3.7-fold in an lrp+ background compared with an lrp background, but expression of an ompF-lacZ+ operon fusion is not. Studies of in vivo expression of the outer membrane porins during growth on glucose minimal medium showed that the OmpF/OmpC ratio is higher in lrp+ strains than it is in isogenic lrp strains. The effect of Lrp was not seen in a strain containing a deletion of micF. Our studies suggest that the positive effect of Lrp on OmpF expression stems from a negative effect of Lrp on the expression of micF, an antisense RNA that inhibits ompF translation.