[Proteolytic control of the antirestriction activity of Tn2l, Tn5053, Tn5045 Tn501 TN402 non-conjugative transposons]

Conjugative plasmids and conjugative transposons contain the genes, which products specifically inhibit the type I restriction--modification systems. Here is shown that non-conjugative transposons Tn2l, Tn5053, Tn5045, Tn501, Tn402 partially inhibit the restriction activity of the type I restriction-modification endonuclease EcoKI (R2M2S1) in Escherichia coli cells K12 (the phenomenon of restriction alleviation, RA). Antirestriction activity of the transposons is determined by the MerR and ArdD proteins. Antirestriction activity of transposons is absent in mutants E. coli K12 clpX and clpP and is decreased in mutants E. coli K12 recA, recBC and dnaQ (mutD). Induction of the RA in response to the MerR and ArdD activities is consistent with the production of unmodified target sequences following DNA repair and DNA synthesis associated with recombination repair or replication errors. RA effect is determined by the ClpXP-dependent degradation of the endonuclease activity R subunit of EcoKI (R2M2S1).

Research resource: The estrogen receptor α cistrome defined by DamIP

Gene expression is tightly regulated by transcription factors and cofactors that function by directly or indirectly interacting with DNA of the genome. Understanding how and where these proteins bind provides essential information to uncover genetic regulatory mechanisms. We have developed a new method to study DNA-protein interaction in vivo called DNA adenine methyltransferase (Dam)IP, which is based on fusing a protein of interest to a mutant form of Dam from Escherichia coli. We showed previously that DamIP can efficiently identify in vivo binding sites of Dam-tethered human estrogen receptor (hER)α. In current study, we present the cistrome of hERα determined by DamIP and high throughput sequencing (DamIP-seq). The DamIP-seq-defined hERα cistrome identifies many new binding regions and overlaps with those determined by chromatin immunoprecipitation (ChIP)-chip or ChIP-seq. Elements uniquely identified by DamIP-seq include a unique class of elements that show low, but persistent, hERα binding when reexamined by conventional ChIP. In contrast, DamIP-seq fails to detect some elements with very transient hERα binding. The methyl-adenine modifications introduced by Dam are stable and do not decrease over 12 d. In summary, the current study provides both an alternate view of the hERα cistrome to further understand the mechanism of hERα-mediated transcription and a new tool to explore other transcriptional factors and cofactors that is very different from conventional ChIP.

[Purification of recombinant DNA methyltransferase M2.BstSE from nickase-modification system NM.BstSEI and study of the enzyme properties]

The operon of nickase-modification system from Bacillus stearothermophilus SE-589 (recognition site 5'-GAGTC-3') includes two DNA methyltransferase genes: bstSEIM1 and bstSEIM2. Gene encoding DNA methyltransferase M2.BstSEI was cloned in pJW vector and expressed in E. coli cells. The enzyme M2.BstSEI has been isolated by chromatographic purification. M2.BstSEI displays maximum activity at 55 degrees C and pH 7.5. The enzyme modifies adenine in DNA sequence 5'-GAGTC-3' and has substrate specificity 5'-GASTC-3'. The kinetic parameters of methylation reaction have been determined. The catalytic constant--2.2 min(-1), the Michaelis constant on T7 DNA--9.8 nM and on SAM--5.8 microM.

Molecular cloning and characterization of the DNA adenine methyltransferase gene in Feldmannia sp. virus

The genome of Feldmannia sp. virus (FsV), a marine brown alga virus, contains a putative DNA adenine methyltransferase (dam) gene of 1,245 bp that encodes a polypeptide of 45.8 kDa. A BLAST search with the FsV dam gene showed high amino acid identity to two putative methyltransferase genes, ORF B29 of Feldmannia irregularis virus (FirrV, 54%) and ORF129 of Ectocarpus siliculosus virus (EsV, 36%); and a PSI BLAST search revealed similarity to the N(6)-adenine methyltransferases (MTases) of other species. Most conserved motifs of beta-class MTases were observed in the FsV dam gene. However, neither of the highly conserved sequences in motifs I (FxGxG) or IV [(S/N/D)PP(Y/F/W)] perfectly matched those in the FsV dam gene. The highly conserved DPPY consensus sequence in motif IV was NTPW in the FsV dam gene, perfectly matching the sequences in ORF B29 of FirrV and ORF129 of EsV. Therefore, the dam genes in brown algae viruses may belong to a yet undiscovered group. The FsV Dam protein expressed from the cloned FsV dam gene methylated E. coli chromosomal DNA. This is the first report showing that a virus infecting marine filamentous brown algae encodes a functional Dam protein.

A Mutation in the Mod Subunit of EcoP15I Restriction Enzyme Converts the DNA Methyltransferase to a Site-specific Endonuclease

A closer inspection of the amino acid sequence of EcoP15I DNA methyltransferase revealed a region of similarity to the PDXn(D/E)XK catalytic site of type II restriction endonucleases, except for methionine in EcoP15I DNA methyltransferase instead of proline. Substitution of methionine at position 357 by proline converts EcoP15I DNA methyltransferase to a site-specific endonuclease. EcoP15I-M357P DNA methyltransferase specifically binds to the recognition sequence 5'-CAGCAG-3' and cleaves DNA asymmetrically EcoP151-M357P.DNA methyltransferase specifically binds to the recognition sequence 5'-CAGCAG-3' and cleaves DNA asymmetrically, 5'-CAGCAG(N)(10)-3', as indicated by the arrows, in presence of magnesium ions.

Altered Ca(2+) regulation of Yop secretion in Yersinia enterocolitica after DNA adenine methyltransferase overproduction is mediated by Clp-dependent degradation of LcrG

DNA methylation by the DNA adenine methyltransferase (Dam) interferes with the coordinated expression of virulence functions in an increasing number of pathogens. While analyzing the effect of Dam on the virulence of the human pathogen Yersinia enterocolitica, we observed type III secretion of Yop effector proteins under nonpermissive conditions. Dam alters the Ca(2+) regulation of Yop secretion but does not affect the temperature regulation of Yop/Ysc expression. The phenotype is different from that of classical "Ca(2+)-blind" mutants of Yersinia, as Dam-overproducing (Dam(OP)) strains still translocate Yops polarly into eukaryotic cells. Although transcription of the lcrGV and yopN-tyeA operons is slightly upregulated, LcrG is absent from lysates of Dam(OP) bacteria, while the amounts of YopN and TyeA are not changed. We present evidence that clpXP expression increases after Dam overproduction and that the ClpP protease then degrades LcrG, thereby releasing a block in type III secretion. This is the first example of posttranslational regulation of type III secretion by the Clp protease and adds a new flavor to the complex regulatory mechanisms underlying the controlled release of effector proteins from bacterial cells.

Transcription regulation of the EcoRV restriction-modification system

When a plasmid containing restriction–modification (R–M) genes enters a naïve host, unmodified host DNA can be destroyed by restriction endonuclease. Therefore, expression of R–M genes must be regulated to ensure that enough methyltransferase is produced and that host DNA is methylated before the endonuclease synthesis begins. In several R–M systems, specialized Control (C) proteins coordinate expression of the R and the M genes. C proteins bind to DNA sequences called C-boxes and activate expression of their cognate R genes and inhibit the M gene expression, however the mechanisms remain undefined. Here, we studied the regulation of gene expression in the C protein-dependent EcoRV system. We map the divergent EcoRV M and R gene promoters and we define the site of C protein-binding that is sufficient for activation of the EcoRV R transcription.

Markov Chain modeling of pyelonephritis-associated pili expression in uropathogenic Escherichia coli

Pyelonephritis-associated pili (Pap) expression in uropathogenic Escherichia coli is regulated by a complex phase variation mechanism involving the competition between leucine-responsive regulatory protein (Lrp) and DNA adenine methylase (Dam). Population dynamics of pap gene expression has been studied extensively and the detailed molecular mechanism has been largely elucidated, providing sufficient information for mathematical modeling. Although the Gillespie algorithm is suited for modeling of stochastic systems such as the pap operon, it becomes computationally expensive when detailed molecular steps are explicitly modeled in a population. Here we developed a Markov Chain model to simplify the computation. Our model is analytically derived from the molecular mechanism. The model presented here is able to reproduce results presented using the Gillespie method, but since the regulatory information is incorporated before simulation, our model runs more efficiently and allows investigation of additional regulatory features. The model predictions are consistent with experimental data obtained in this work and in the literature. The results show that pap expression in uropathogenic E. coli is initial-state-dependent, as previously reported. However, without environment stimuli, the pap-expressing fraction in a population will reach an equilibrium level after approximately 50-100 generations. The transient time before reaching equilibrium is determined by PapI stability and Lrp and Dam copy numbers per cell. This work demonstrates that the Markov Chain model captures the essence of the complex molecular mechanism and greatly simplifies the computation.

Significance of Codon Usage and Irregularities of Rare Codon Distribution in Genes for Expression of BspLU11III Methyltransferases

Genes of adenine-specific DNA-methyltransferase M.BspLU11IIIa and cytosine-specific DNA-methyltransferase M.BspLU11IIIb of the type IIG BspLU11III restriction-modification system from the thermophilic strain Bacillus sp. LU11 were expressed in E. coli. They contain a large number of codons that are rare in E. coli and are characterized by equal values of codon adaptation index (CAI) and expression level measure (E(g)). Rare codons are either diffused (M.BspLU11IIIa) or located in clusters (M.BspLU11IIIb). The expression level of the cytosine-specific DNA-methyltransferase was increased by a factor of 7.3 and that of adenine-specific DNA only by a factor of 1.25 after introduction of the plasmid pRARE supplying tRNA genes for six rare codons in E. coli. It can be assumed that the plasmid supplying minor tRNAs can strongly increase the expression level of only genes with cluster distribution of rare codons. Using heparin-Sepharose and phosphocellulose chromatography and gel filtration on Sephadex G-75 both DNA-methyltransferases were isolated as electrophoretically homogeneous proteins (according to the results of SDS-PAGE).

Assembly of EcoKI DNA methyltransferase requires the C-terminal region of the HsdM modification subunit

The methyltransferase component of type I DNA restriction and modification systems comprises three subunits, one DNA sequence specificity subunit and two DNA modification subunits. Limited proteolysis of the EcoKI methyltransferase shows that a 55-kDa N-terminal fragment of the 59-kDa modification subunit is resistant to degradation. We have purified this fragment and determined by mass spectrometry that proteolysis removes 43 or 44 amino acids from the C-terminus. The fragment fails to interact with the other subunits even though it still possesses secondary and tertiary structure and the ability to bind the S-adenosylmethionine cofactor. We conclude that the C-terminal region of the modification subunit of EcoKI is essential for the assembly of the EcoKI methyltransferase.

DNA adenine methylase overproduction in Yersinia pseudotuberculosis alters YopE expression and secretion and host immune responses to infection

Yersinia pseudotuberculosis mutants that overproduce the DNA adenine methylase (Dam) are highly attenuated, confer fully protective immune responses, and secrete several Yersinia virulence proteins (Yersinia outer proteins [Yops]) under conditions that are nonpermissive for secretion in wild-type strains. We examined here the effects of Dam overproduction on Yersinia virulence determinant expression and secretion, as well as the host immune response to Yersinia antigens. Western blot analysis with convalescent antisera identified several low-calcium-responsive antigens whose synthesis was affected by Dam overproduction. One of these antigens was shown to be the type III secretion effector protein, YopE, a cytotoxin involved in antiphagocytosis. Dam overproduction disrupted both the thermal and calcium regulation of YopE synthesis and relaxed the thermal but not the calcium dependence of YopE secretion. Altered expression and/or secretion of Yersinia proteins in Dam-overproducing strains may contribute to the decreased virulence and heightened immunity observed in vaccinated hosts and may provide a means by which to deliver heterologous antigens and/or immune modulators of the inflammatory response.

DNA adenine methylase is essential for viability and plays a role in the pathogenesis of Yersinia pseudotuberculosis and Vibrio cholerae

Salmonella strains that lack or overproduce DNA adenine methylase (Dam) elicit a protective immune response to different Salmonella species. To generate vaccines against other bacterial pathogens, the dam genes of Yersinia pseudotuberculosis and Vibrio cholerae were disrupted but found to be essential for viability. Overproduction of Dam significantly attenuated the virulence of these two pathogens, leading to, in Yersinia, the ectopic secretion of virulence proteins (Yersinia outer proteins) and a fully protective immune response in vaccinated hosts. Dysregulation of Dam activity may provide a means for the development of vaccines against varied bacterial pathogens.

The CtrA response regulator mediates temporal control of gene expression during the Caulobacter cell cycle

In its role as a global response regulator, CtrA controls the transcription of a diverse group of genes at different times in the Caulobacter crescentus cell cycle. To understand the differential regulation of CtrA-controlled genes, we compared the expression of two of these genes, the fliQ flagellar gene and the ccrM DNA methyltransferase gene. Despite their similar promoter architecture, these genes are transcribed at different times in the cell cycle. PfliQ is activated earlier than PccrM. Phosphorylated CtrA (CtrA approximately P) bound to the CtrA recognition sequence in both promoters but had a 10- to 20-fold greater affinity for PfliQ. This difference in affinity correlates with temporal changes in the cellular levels of CtrA. Disrupting a unique inverted repeat element in PccrM significantly reduced promoter activity but not the timing of transcription initiation, suggesting that the inverted repeat does not play a major role in the temporal control of ccrM expression. Our data indicate that differences in the affinity of CtrA approximately P for PfliQ and PccrM regulate, in part, the temporal expression of these genes. However, the timing of fliQ transcription but not of ccrM transcription was altered in cells expressing a stable CtrA derivative, indicating that changes in CtrA approximately P levels alone cannot govern the cell cycle transcription of these genes. We propose that changes in the cellular concentration of CtrA approximately P and its interaction with accessory proteins influence the temporal expression of fliQ, ccrM, and other key cell cycle genes and ultimately the regulation of the cell cycle.

Comparative analysis of expression of the SalI restriction-modification system in Escherichia coli and Streptomyces

The salIR and salIM genes encode the endonuclease and methyltransferase components of the SalI restriction-modification system from Streptomyces albus G. Expression of the salI genes in Escherichia coli was investigated and major differences with Streptomyces were found. In E. coli there is no detectable expression of the salI R gene due to inactivity of the sal-pR promoter region. In the natural host of the system this region directs transcription of the salI genes as a bicistronic message. In contrast to salIR, salIM is transcribed in the heterologous host from a promoter within the salI DNA. Since sal-pR is not active, the gene cannot be expressed as part of the salI operon. It is probably transcribed from sal-pM, a promoter internal to the operon which allows independent expression of the modification gene in Streptomyces. Replacement of sal-pR by the strong pLac promoter allows expression of salIR in E. coli and enhances expression of salIM. The resulting strain produces about 10 times more endonuclease than a Streptomyces clone containing the SalI system under the control of sal-pR.

A cell cycle-regulated bacterial DNA methyltransferase is essential for viability

The CcrM adenine DNA methyltransferase, which specifically modifies GANTC sequences, is necessary for viability in Caulobacter crescentus. To our knowledge, this is the first example of an essential prokaryotic DNA methyltransferase that is not part of a DNA restriction/modification system. Homologs of CcrM are widespread in the alpha subdivision of the Proteobacteria, suggesting that methylation at GANTC sites may have important functions in other members of this diverse group as well. Temporal control of DNA methylation state has an important role in Caulobacter development, and we show that this organism utilizes an unusual mechanism for control of remethylation of newly replicated DNA. CcrM is synthesized de novo late in the cell cycle, coincident with full methylation of the chromosome, and is then subjected to proteolysis prior to cell division.

Expression of the SalI restriction-modification system of Streptomyces albus G in Escherichia coli

The salIR and salIM genes of Streptomyces albus G encode the restriction endonuclease (ENase) and DNA methyltransferase (MTase) of the SalI restriction-modification (R-M) system. In S. albus G, the genes constitute an operon that is mainly transcribed from a promoter located upstream from salIR, the first gene of the operon. In addition, a second promoter, at the 3' end of salIR, allows independent transcription of the MTase gene. Expression of salIR and salIM in Escherichia coli was investigated. The ENase gene was not expressed in the heterologous host, probably due to inactivity of the main promoter of the salI operon. In contrast to salIR, salIM was functional in E. coli. Preliminary S1 nuclease mapping experiments suggest that the alternative promoter of the MTase gene can initiate transcription in the heterologous, as well as in the homologous host.

Mutational analysis of conserved amino-acid motifs in EcoKI adenine methyltransferase

The EcoKI methyltransferase (M.EcoKI, MTase) contains the amino acid (aa) sequences AAGTA and NPPF believed to represent the two sequences that are strongly conserved in adenine MTases [Klimasauskas et al., Nucleic Acids Res. 17 (1989) 9823-9831]. We have analysed a mutation in the first sequence that abolishes cofactor binding and enzyme activity, and mutations in the second sequence that reduce or abolish activity without affecting cofactor and DNA binding.

Biochemical characterization of VspI methyltransferase

The gene (vspIM) encoding VspI methyltransferase (MTase) has previously been cloned and sequenced, and shown to belong to the gamma class of m6-adenine MTases [Degtyarev et al., Nucleic Acids Res. 21 (1993) 2015]. Here it is shown that the MTase modifies the third adenine within the recognition sequence 5'-ATTAAT-3'.

Possible regulation of DNA methyltransferase expression by RNA processing in Streptococcus pneumoniae

Atypical ribosome-binding sites lacking Shine-Dalgarno sequences appear to be used for translation of the DpnM and DpnA DNA methyltransferases of the DpnII restriction system. Preliminary results indicate that the 5'-endpoints of DpnII system mRNAs result from degradation of the original transcript. These tentative findings serve as the basis for a possible regulatory model that would accommodate the DpnII cassette either as a single copy in the chromosome or on a multicopy plasmid.

Analysis of the temporal program of replication initiation in yeast chromosomes

The multiple origins of eukaryotic chromosomes vary in the time of their initiation during S phase. In the chromosomes of Saccharomyces cerevisiae the presence of a functional telomere causes nearby origins to delay initiation until the second half of S phase. The key feature of telomeres that causes the replication delay is the telomeric sequence (C(1-3)A/G(1-3)T) itself and not the proximity of the origin to a DNA end. A second group of late replicating origins has been found at an internal position on chromosome XIV. Four origins, spanning approximately 140 kb, initiate replication in the second half of S phase. At least two of these internal origins maintain their late replication time on circular plasmids. Each of these origins can be separated into two functional elements: those sequences that provide origin function and those that impose late activation. Because the assay for determining replication time is costly and laborious, it has not been possible to analyze in detail these 'late' elements. We report here the development of two new assays for determining replication time. The first exploits the expression of the Escherichia coli dam methylase in yeast and the characteristic period of hemimethylation that transiently follows the passage of a replication fork. The second uses quantitative hybridization to detect two-fold differences in the amount of specific restriction fragments as a function of progress through S phase. The novel aspect of this assay is the creation in vivo of a non-replicating DNA sequence by site-specific pop-out recombination. This non-replicating fragment acts as an internal control for copy number within and between samples. Both of these techniques are rapid and much less costly than the more conventional density transfer experiments that require CsCl gradients to detect replicated DNA. With these techniques it should be possible to identify the sequences responsible for late initiation, to search for other late replicating regions in the genome, and to begin to analyze the effect that altering the temporal program has on chromosome function.

Organization and sequence of the SalI restriction-modification system

The organization and nucleotide (nt) sequences were determined for the genes encoding the SalI restriction and modification (R-M) system (recognition sequence 5'-GTCGAC-3') from Streptomyces albus G. The system comprises two genes, salIR, coding for the restriction endonuclease (ENase, R.SalI; probably 315 amino acids (aa), a predicted M(r) of 35,305; product, G'TCGAC) and salIM, coding for the methyltransferase (MTase, M.SalI; probably 587 aa, a predicted M(r) of 64,943; product, GTCGm6AC). The genes are adjacent, they have the same orientation, and they occur in the order salIR then salIM. R.SalI contains a putative magnesium-binding motif similar to those at the active sites of R.EcoRI and R.EcoRV, but otherwise it bears little aa sequence similarity to other ENases. M.SalI is a member of the m6A gamma class of MTases. In aa sequence it resembles M.AccI, another m6A gamma-MTase whose recognition sequence includes the SalI recognition sequence as a subset.

Overproduction of the Hsd subunits leads to the loss of temperature-sensitive restriction and modification phenotype

The genes hsdM and hsdS for M. EcoKI modification methyltransferase and the complete set of hsdR, hsdM and hsdS genes coding for R. EcoKI restriction endonuclease, both with and without a temperature-sensitive (ts) mutation in hsdS gene, were cloned in pBR322 plasmid and introduced into E. coli C (a strain without a natural restriction-modification (R-M) system). The strains producing only the methyltransferase, or together with the endonuclease, were thus obtained. The hsdSts-1 mutation, mapped previously in the distal variable region of the hsdS gene with C1 245-T transition has no effect on the R-M phenotype expressed from cloned genes in bacteria grown at 42 degrees C. In clones transformed with the whole hsd region an alleviation of R-M functions was observed immediately after the transformation, but after subculture the transformants expressed the wild-type R-M phenotype irrespective of whether the wild-type or the mutant hsdS allele was present in the hybrid plasmid. Simultaneous overproduction of HsdS and HsdM subunits impairs the ts effect of the hsdSts-1 mutation on restriction and modification.

Ectopic expression of a viral adenine methyltransferase gene in tobacco

Plant genomes contain both methylated adenine and cytosine residues although the roles of these methylations are not well understood. A chlorella virus adenine methyltransferase gene under the control of cauliflower mosaic virus 35S promoter in a binary plant transformation vector was expressed both in transgenic tobacco plants and transformed tobacco calli. The transgenic plants as well as transformed calli produced functional adenine methyltransferase enzyme, but the level of expression was higher in tobacco calli. A transgenic tobacco cell line that expressed the methyltransferase enzyme and carried an Arabidopsis cab3 gene containing a single target site for the adenine methyltransferase enzyme showed that the adenine residue was not methylated. HPLC analysis of genomic DNA from transgenic calli also showed no detectable levels of methylated adenine residues.

The expression of the bstVIM gene from Bacillus stearothermophilus V is restricted to vegetative cell growth

The activity of BstVI DNA methyltransferase was monitored during the sporulative cycle of Bacillus stearothermophilus V. Significant methylase activity was found only in bacteria growing vegetatively. This was confirmed by Northern hybridization, which indicated that the bstVIM gene was not transcribed in cells undergoing sporulation. Supporting evidence came from experiments which demonstrated that the RNA polymerase holoenzyme from these cells did not recognize the promoter elements upstream of the bstVIM gene.

A novel class of FokI restriction endonuclease mutants that cleave hemi-methylated substrates

A genetic screen was used to identify amino acid substitutions that enable the FokI restriction endonuclease to cleave DNA in cells that express the cognate methyltransferase activity. Missense mutations that give rise to this phenotype were isolated at eight different positions (G188K, P196S, T343I, S388N, S395F, E407K, E410K, D421N), clustered in two regions of the polypeptide sequence of FokI. Two of the mutant endonucleases (P196S and D421N) were purified to homogeneity and analyzed in detail. Both mutants cleave FokI target sites (5'-GGATG-3') in a manner similar to the wild-type enzyme. Neither mutant cleaved noncanonical sequences, but both efficiently cleaved DNA substrates containing hemi-methylated FokI sites. This class of mutations has not been observed with other restriction enzymes.

Purification and characterization of the M.RsrI DNA methyltransferase from Escherichia coli

The gene (rsrIM) encoding the RsrI DNA methyltransferase (M.RsrI) from Rhodobacter sphaeroides was cloned and expressed in Escherichia coli. Under the control of a bacteriophage T7 promoter, 2% of the total protein in a crude extract was M.RsrI. This level of expression represents an approximately 50-fold increase over that present in the natural host. Chromatography using DNA cellulose and the S-adenosylmethionine analogue, sinefungin, was useful in purifying the enzyme to homogeneity. The purification yielded 100 times more enzyme than was obtained from the same quantity of R. sphaeroides cell paste. M.RsrI deposits one methyl group per productive DNA-binding event, as does its functional but sequence-nonhomologous analogue, M.EcoRI. Unlike M.EcoRI, the R. sphaeroides enzyme is a dimer at micromolar concentrations.

High-level expression of a semisynthetic dam gene in Escherichia coli

We constructed a semisynthetic gene encoding a DNA-adenine-methyltransferase (Dam) that codes for the same amino acid sequence as the wild type (wt) Escherichia coli dam gene. Since for unknown reasons the entire wt sequence, from the start codon to the end of the gene, could not be cloned, a gene was constructed consisting of a chemically synthesized 5' portion and a 3' portion from the E. coli chromosome. Introduction of this semisynthetic gene into a suitable vector allows overproduction of E. coli Dam in mg amounts per liter E. coli culture, with optimum expression of the gene in the vector pJLA503. This plasmid places the target gene under control of the strong, tandemly arranged pR pL promoters from bacteriophage lambda, regulated by a temperature-sensitive lambda repressor. A rapid, two-column purification protocol is described that allows for very fast purification of the protein. The 32-kDa recombinant protein methylates the sequence GATC.

Autogenous regulation of the Escherichia coli ksgA gene at the level of translation

Various plasmids that contain the Escherichia coli ksgA gene, which encodes a 16S rRNA adenosine dimethyltransferase (methylase), were constructed. In one of these plasmids, the DNA encoding the N-terminal part of the methylase was fused to the lacZ gene, and in another construct, the ksgA gene contained a deletion which resulted in a truncated version of the methylase. When a cell contained one plasmid directing the synthesis of the intact, active methylase and another plasmid encoding the methylase-beta-galactosidase protein, production of the latter product became strongly reduced. Likewise, synthesis of the truncated version of the methylase was diminished when the cell at the same time contained a plasmid producing the complete enzyme. These results were partly substantiated by in vitro experiments with a coupled transcription-translation assay system. By using a recently developed gel electrophoresis system for measuring protein-nucleic acid interactions, a specific binding of the ksgA methylase with its own mRNA could be established. Our results demonstrate that the expression of the ksgA gene can be, at least partly, autogenously controlled at the level of translation.

Overproduction and purification of the M.HhaII methyltransferase from Haemophilus haemolyticus

The HhaII methyltransferase gene from Haemophilus haemolyticus was subcloned in an expression vector under control of the hybrid trp-lac promoter. Induction with isopropyl-beta-D-thiogalactopyranoside results in overproduction of the methyltransferase to about 3% of total cellular protein. The methyltransferase was purified to near electrophoretic homogeneity by phosphocellulose, DEAE, and gel chromatography. Its monomer Mr by sodium dodecyl sulfate-polyacrylamide gel electrophoresis is 25 kDa, in good agreement with that predicted from the nucleotide sequence. Crystals of the methyltransferase were obtained in the presence of a two-fold molar excess of the duplex oligodeoxynucleotide substrate 5'd-GGACTCC.CCTGAGG.