Characterization of the genes coding for the Eco RV restriction and modification system of Escherichia coli

Constructing Cell-Free Expression Systems for Low-Cost Access

Cell-free systems for gene expression have gained attention as platforms for the facile study of genetic circuits and as highly effective tools for teaching. Despite recent progress, the technology remains inaccessible for many in low- and middle-income countries due to the expensive reagents required for its manufacturing, as well as specialized equipment required for distribution and storage. To address these challenges, we deconstructed processes required for cell-free mixture preparation and developed a set of alternative low-cost strategies for easy production and sharing of extracts. First, we explored the stability of cell-free reactions dried through a low-cost device based on silica beads, as an alternative to commercial automated freeze dryers. Second, we report the positive effect of lactose as an additive for increasing protein synthesis in maltodextrin-based cell-free reactions using either circular or linear DNA templates. The modifications were used to produce active amounts of two high-value reagents: the isothermal polymerase Bst and the restriction enzyme BsaI. Third, we demonstrated the endogenous regeneration of nucleoside triphosphates and synthesis of pyruvate in cell-free systems (CFSs) based on phosphoenol pyruvate (PEP) and maltodextrin (MDX). We exploited this novel finding to demonstrate the use of a cell-free mixture completely free of any exogenous nucleotide triphosphates (NTPs) to generate high yields of sfGFP expression. Together, these modifications can produce desiccated extracts that are 203-424-fold cheaper than commercial versions. These improvements will facilitate wider use of CFS for research and education purposes.

Characterization and use of Tetrahymena thermophila artificial chromosome 2 (TtAC2) constructed by biomimetic of macronuclear rDNA minichromosome

Efficient expression vectors for unicellular ciliate eukaryotic Tetrahymena thermophila are still needed in recombinant biology and biotechnology applications. Previously, the construction of the T. thermophila Macronuclear Artificial Chromosome 1 (TtAC1) vector revealed additional needs for structural improvements such as better in vivo stability and maintenance as a recombinant protein expression platform. In this study, we designed an efficiently maintained artificial chromosome by biomimetic of the native macronuclear rDNA minichromosome. TtAC2 was constructed by sequential cloning of subtelomeric 3'NTS region (1.8 kb), an antibiotic resistance gene cassette (2 kb neo4), a gene expression cassette (2 kb TtsfGFP), rDNA coding regions plus a dominant C3 origin sequence (10.3 kb), and telomeres (2.4 kb) in a pUC19 backbone plasmid (2.6 kb). The 21 kb TtAC2 was characterized using fluorescence microscopy, qPCR, western blot and Southern blot after its transformation to vegetative T. thermophila CU428.2 strain, which has a recessive B origin allele. All experimental data show that circular or linear forms of novel TtAC2 were maintained as free replicons in T. thermophila macronucleus with or without antibiotic treatment. Notably, TtAC2 carrying strains expressed a TtsfGFP marker protein, demonstrating the efficacy and functionality of the protein expression platform. We show that TtAC2 is functionally maintained for more than two months, and can be efficiently used in recombinant DNA, and protein production applications.

Type II restriction endonucleases--a historical perspective and more

This article continues the series of Surveys and Summaries on restriction endonucleases (REases) begun this year in Nucleic Acids Research. Here we discuss 'Type II' REases, the kind used for DNA analysis and cloning. We focus on their biochemistry: what they are, what they do, and how they do it. Type II REases are produced by prokaryotes to combat bacteriophages. With extreme accuracy, each recognizes a particular sequence in double-stranded DNA and cleaves at a fixed position within or nearby. The discoveries of these enzymes in the 1970s, and of the uses to which they could be put, have since impacted every corner of the life sciences. They became the enabling tools of molecular biology, genetics and biotechnology, and made analysis at the most fundamental levels routine. Hundreds of different REases have been discovered and are available commercially. Their genes have been cloned, sequenced and overexpressed. Most have been characterized to some extent, but few have been studied in depth. Here, we describe the original discoveries in this field, and the properties of the first Type II REases investigated. We discuss the mechanisms of sequence recognition and catalysis, and the varied oligomeric modes in which Type II REases act. We describe the surprising heterogeneity revealed by comparisons of their sequences and structures.

Highlights of the DNA cutters: a short history of the restriction enzymes

In the early 1950's, 'host-controlled variation in bacterial viruses' was reported as a non-hereditary phenomenon: one cycle of viral growth on certain bacterial hosts affected the ability of progeny virus to grow on other hosts by either restricting or enlarging their host range. Unlike mutation, this change was reversible, and one cycle of growth in the previous host returned the virus to its original form. These simple observations heralded the discovery of the endonuclease and methyltransferase activities of what are now termed Type I, II, III and IV DNA restriction-modification systems. The Type II restriction enzymes (e.g. EcoRI) gave rise to recombinant DNA technology that has transformed molecular biology and medicine. This review traces the discovery of restriction enzymes and their continuing impact on molecular biology and medicine.

Fused eco29kIR- and M genes coding for a fully functional hybrid polypeptide as a model of molecular evolution of restriction-modification systems

BACKGROUND

The discovery of restriction endonucleases and modification DNA methyltransferases, key instruments of genetic engineering, opened a new era of molecular biology through development of the recombinant DNA technology. Today, the number of potential proteins assigned to type II restriction enzymes alone is beyond 6000, which probably reflects the high diversity of evolutionary pathways. Here we present experimental evidence that a new type IIC restriction and modification enzymes carrying both activities in a single polypeptide could result from fusion of the appropriate genes from preexisting bipartite restriction-modification systems.

RESULTS

Fusion of eco29kIR and M ORFs gave a novel gene encoding for a fully functional hybrid polypeptide that carried both restriction endonuclease and DNA methyltransferase activities. It has been placed into a subclass of type II restriction and modification enzymes--type IIC. Its MTase activity, 80% that of the M.Eco29kI enzyme, remained almost unchanged, while its REase activity decreased by three times, concurrently with changed reaction optima, which presumably can be caused by increased steric hindrance in interaction with the substrate. In vitro the enzyme preferentially cuts DNA, with only a low level of DNA modification detected. In vivo new RMS can provide a 102-fold less protection of host cells against phage invasion.

CONCLUSIONS

We propose a molecular mechanism of appearing of type IIC restriction-modification and M.SsoII-related enzymes, as well as other multifunctional proteins. As shown, gene fusion could play an important role in evolution of restriction-modification systems and be responsible for the enzyme subclass interconversion. Based on the proposed approach, hundreds of new type IIC enzymes can be generated using head-to-tail oriented type I, II, and III restriction and modification genes. These bifunctional polypeptides can serve a basis for enzymes with altered recognition specificities. Lastly, this study demonstrates that protein fusion may change biochemical properties of the involved enzymes, thus giving a starting point for their further evolutionary divergence.

6His-Eco29kI methyltransferase methylation site and kinetic mechanism characterization

A new type II 6His-Eco29kI DNA methyltransferase was tested for methylation site (CC(Me)GCGG) and catalytic reaction optimal conditions. With high substrate concentrations, an inhibitory effect of DNA, but not AdoMet, on its activity was observed. Isotope partitioning and substrate preincubation assays showed that the enzyme-AdoMet complex is catalytically active. Considering effect of different concentrations of DNA and AdoMet on initial velocity, ping-pong mechanisms were ruled out. According to data obtained, the enzyme appears to work by preferred ordered bi-bi mechanism with AdoMet as leading substrate.

Construction of an overproducing strain, purification, and biochemical characterization of the 6His-Eco29kI restriction endonuclease

We constructed a strain of Escherichia coli overproducing 6His-tagged Eco29kI by placing the coding sequence under control of a strong bacteriophage T5 promoter. The yield of 6His-Eco29kI restriction endonuclease expression could be increased to about 20% of the total cellular protein, but inclusion bodies formed consisting of insoluble 6His-Eco29kI protein. We developed a fast and effective protocol for purification of the homogeneous enzyme from both soluble and insoluble fractions and established their identity by catalytic activity assay. The isolated enzymes were tested for recognition specificity and optimal reaction conditions as a function of NaCl and KCl concentrations, temperature, and pH compared with the native Eco29kI restriction endonuclease. The 6His-tagged enzyme retained the specificity of the native protein but had an altered optimum of its catalytic reaction.

Evidence for horizontal transfer of the EcoT38I restriction-modification gene to chromosomal DNA by the P2 phage and diversity of defective P2 prophages in Escherichia coli TH38 strains

A DNA fragment carrying the genes coding for a novel EcoT38I restriction endonuclease (R.EcoT38I) and EcoT38I methyltransferase (M.EcoT38I), which recognize G(A/G)GC(C/T)C, was cloned from the chromosomal DNA of Escherichia coli TH38. The endonuclease and methyltransferase genes were in a head-to-head orientation and were separated by a 330-nucleotide intergenic region. A third gene, the C.EcoT38I gene, was found in the intergenic region, partially overlapping the R.EcoT38I gene. The gene product, C.EcoT38I, acted as both a positive regulator of R.EcoT38I gene expression and a negative regulator of M.EcoT38I gene expression. M.EcoT38I purified from recombinant E. coli cells was shown to be a monomeric protein and to methylate the inner cytosines in the recognition sequence. R.EcoT38I was purified from E. coli HB101 expressing M.EcoT38I and formed a homodimer. The EcoT38I restriction (R)-modification (M) system (R-M system) was found to be inserted between the A and Q genes of defective bacteriophage P2, which was lysogenized in the chromosome at locI, one of the P2 phage attachment sites observed in both E. coli K-12 MG1655 and TH38 chromosomal DNAs. Ten strains of E. coli TH38 were examined for the presence of the EcoT38I R-M gene on the P2 prophage. Conventional PCR analysis and assaying of R activity demonstrated that all strains carried a single copy of the EcoT38I R-M gene and expressed R activity but that diversity of excision in the ogr, D, H, I, and J genes in the defective P2 prophage had arisen.

Biotin-avidin microplate assay for the quantitative analysis of enzymatic methylation of DNA by DNA methyltransferases

An assay is described to measure methylation of biotinylated oligonucleotide substrates by DNA methyltransferases using [methyl-3H]-AdoMet. After the methylation reaction the oligonucleotides are immobilized on an avidin-coated microplate. The incorporation of [3H] into the DNA is quenched by addition of unlabeled AdoMet to the binding buffer. Unreacted AdoMet and enzyme are removed by washing. To release the radioactivity incorporated into the DNA, the wells are incubated with a non-specific endonuclease and the radioactivity determined by liquid scintillation counting. As an example, we have studied methylation of DNA by the EcoRV DNA methyltransferase. The reaction progress curves measured with this assay are linear with respect to time. Methylation rates linearly increase with enzyme concentration. The rates are comparable to results obtained with the same enzyme using a different assay. The biotin-avidin assay is inexpensive, convenient, quantitative, fast and well suited to process many samples in parallel. The accuracy of the assay is high, allowing to reproduce results within +/- 10%. The assay is very sensitive as demonstrated by the detection of incorporation of 0.8 fmol methyl groups into the DNA. Under the experimental conditions, this corresponds to methylation of only 0.03% of all target sites of the substrate. Using this assay, the DNA methylation activity of some M.EcoRV variants could be detected that was not visible by other in vitro methylation assays.

Evidence of horizontal transfer of the EcoO109I restriction-modification gene to Escherichia coli chromosomal DNA

A DNA fragment carrying the genes coding for EcoO109I endonuclease and EcoO109I methylase, which recognize the nucleotide sequence 5'-(A/G)GGNCC(C/T)-3', was cloned from the chromosomal DNA of Escherichia coli H709c. The EcoO109I restriction-modification (R-M) system was found to be inserted between the int and psu genes from satellite bacteriophage P4, which were lysogenized in the chromosome at the P4 phage attachment site of the corresponding leuX gene observed in E. coli K-12 chromosomal DNA. The sid gene of the prophage was inactivated by insertion of one copy of IS21. These findings may shed light on the horizontal transfer and stable maintenance of the R-M system.

Structural analysis of a mutational hot-spot in the EcoRV restriction endonuclease: a catalytic role for a main chain carbonyl group

Following random mutagenesis of the Eco RV endonuclease, a high proportion of the null mutants carry substitutions at Gln69. Such mutants display reduced rates for the DNA cleavage step in the reaction pathway, yet the crystal structures of wild-type Eco RV fail to explain why Gln69 is crucial for activity. In this study, crystal structures were determined for two mutants of Eco RV, with Leu or Glu at residue 69, bound to specific DNA. The structures of the mutants are similar to the native protein and no function can be ascribed to the side chain of the amino acid at this locus. Instead, the structures of the mutant proteins suggest that the catalytic defect is due to the positioning of the main chain carbonyl group. In the enzyme-substrate complex for Eco RV, the main chain carbonyl of Gln69 makes no interactions with catalytic functions but, in the enzyme-product complex, it coordinates a metal ion bound to the newly liberated 5'-phosphate. This re-positioning may be hindered in the mutant proteins. Molecular dynamics calculations indicate that the metal on the phosphoryl oxygen interacts with the carbonyl group upon forming the pentavalent intermediate during phosphodiester hydrolysis. A main chain carbonyl may thus play a role in catalysis by Eco RV.

Mutational analysis of target base flipping by the EcoRV adenine-N6 DNA methyltransferase

DNA methyltransferases flip their target base out of the DNA helix. Here, we have investigated base flipping by wild-type EcoRV DNA methyltransferase (M.EcoRV) and five M.EcoRV variants (D193A, Y196A, S229A, W231R and Y258A). These variants bind to DNA and S-adenosylmethionine but have a severely reduced catalytic efficiency or are catalytically inactive. To measure base flipping three different assays were used, viz. analysis of the yields of photocrosslinking reactions between the enzymes and a substrate in which the target base is replaced by 5-iodouracil, analysis of the binding constants to substrates containing a mismatch base-pair at the target position and analysis of the salt dependence of specific complex formation. Our data show that the Y196A, W231R and Y258A variants are not able to stabilize a flipped target base, suggesting that the aromatic amino acid residues (Tyr196, Trp231 and Tyr258) are involved in hydrophobic interactions with the flipped base. The D193A variant behaves like wild-type M.EcoRV with respect to base flipping. The fact that this variant is catalytically inactive indicates that Asp193 has a function in chemical catalysis. The S229A variant can better flip modified bases but does not tightly lock the flipped base into the adenine-binding pocket, suggesting that Ser229 could form a contact to the flipped adenine.

Crystal structure of the DpnM DNA adenine methyltransferase from the DpnII restriction system of streptococcus pneumoniae bound to S-adenosylmethionine

BACKGROUND

. Methyltransferases (Mtases) catalyze the transfer of methyl groups from S-adenosylmethionine (AdoMet) to a variety of small molecular and macromolecular substrates. These enzymes contain a characteristic alpha/beta structural fold. Four groups of DNA Mtases have been defined and representative structures have been determined for three groups. DpnM is a DNA Mtase that acts on adenine N6 in the sequence GATC; the enzyme represents group alpha DNA Mtases, for which no structures are known.

RESULTS

. The structure of DpnM in complex with AdoMet was determined at 1.80 A resolution. The protein comprises a consensus Mtase fold with a helical cluster insert. DpnM binds AdoMet in a similar manner to most other Mtases and the enzyme contains a hollow that can accommodate DNA. The helical cluster supports a shelf within the hollow that may recognize the target sequence. Modeling studies indicate a potential site for binding the target adenine, everted from the DNA helix. Comparison of the DpnM structure and sequences of group alpha DNA Mtases indicates that the group is a genetically related family. Structural comparisons show DpnM to be most similar to a small-molecule Mtase and then to macromolecular Mtases, although several dehydrogenases show greater similarity than one DNA Mtase.

CONCLUSIONS

. DpnM, and by extension the DpnM family or group alpha Mtases, contains the consensus fold and AdoMet-binding motifs found in most Mtases. Structural considerations suggest that macromolecular Mtases evolved from small-molecule Mtases, with different groups of DNA Mtases evolving independently. Mtases may have evolved from dehydrogenases. Comparison of these enzymes indicates that in protein evolution, the structural fold is most highly conserved, then function and lastly sequence.

The Ecl18kI restriction-modification system: cloning, expression, properties of the purified enzymes

Ecl18kI is a type II restriction-modification system isolated from Enterobacter cloaceae 18kI strain. Genes encoding Ecl18kI methyltransferase (M.Ecl18kI) and Ecl18kI restriction endonuclease (R.Ecl18kI) have been cloned and expressed in Escherichia coli. These enzymes recognize the 5'.../CCNGG...3' sequence in DNA; M.Ecl18kI methylates the C5 carbon atom of the inner dC residue and R.Ecl18kI cuts DNA as shown by the arrow. The restriction endonuclease and the methyltransferase were purified from E. coli B834 [p18Ap1] cells to near homogeneity. The restriction endonuclease is present in the solution as a tetramer, while the methyltransferase is a monomer. The interactions of M.Ecl18kI and R.Ecl18kI with 1,2-dideoxy-D-ribofuranose containing DNA duplexes were investigated. The target base flipping-out mechanism is applicable in the case of M.Ecl18kI. Correct cleavage of the abasic substrates by R.Ecl18kI is accompanied by non-canonical hydrolysis of the modified strand.

Restriction-modification gene complexes as selfish gene entities: roles of a regulatory system in their establishment, maintenance, and apoptotic mutual exclusion

We have reported some type II restriction-modification (RM) gene complexes on plasmids resist displacement by an incompatible plasmid through postsegregational host killing. Such selfish behavior may have contributed to the spread and maintenance of RM systems. Here we analyze the role of regulatory genes (C), often found linked to RM gene complexes, in their interaction with the host and the other RM gene complexes. We identified the C gene of EcoRV as a positive regulator of restriction. A C mutation eliminated postsegregational killing by EcoRV. The C system has been proposed to allow establishment of RM systems in new hosts by delaying the appearance of restriction activity. Consistent with this proposal, bacteria preexpressing ecoRVC were transformed at a reduced efficiency by plasmids carrying the EcoRV RM gene complex. Cells carrying the BamHI RM gene complex were transformed at a reduced efficiency by a plasmid carrying a PvuII RM gene complex, which shares the same C specificity. The reduction most likely was caused by chromosome cleavage at unmodified PvuII sites by prematurely expressed PvuII restriction enzyme. Therefore, association of the C genes of the same specificity with RM gene complexes of different sequence specificities can confer on a resident RM gene complex the capacity to abort establishment of a second, incoming RM gene complex. This phenomenon, termed "apoptotic mutual exclusion," is reminiscent of suicidal defense against virus infection programmed by other selfish elements. pvuIIC and bamHIC genes define one incompatibility group of exclusion whereas ecoRVC gene defines another.

Functional mapping of the EcoRV DNA methyltransferase by random mutagenesis and screening for catalytically inactive mutants

M.EcoRV is an alpha-adenine DNA methyltransferase. According to structure predictions, the enzyme consists of a catalytic domain, which has a structure similar to all other DNA-methyltransferases, and a smaller DNA-recognition domain. We have investigated this enzyme by random mutagenesis, using error-prone PCR, followed by selection for catalytically inactive mutants. 20 single mutants were identified that are completely inactive in vivo as His6- and GST-fusion proteins. 13 of them could be overexpressed and purified. All of these mutants are also inactive in vitro. 5 of the mutations are located near the putative binding site for a flipped adenine residue (C192R, D193G, E212G, W231R, N239H). All of these variants bind to DNA, demonstrating the importance of this region of the protein in catalysis. Only the W231R mutant could be purified with high yields. It binds to DNA and AdoMet and, thus, behaves like a bona fide active site mutant. According to the structure prediction Trp231 corresponds to Val121 in M.HhaI, which forms a hydrophobic contact to the flipped target cytosine. 4 of the remaining purified variants are located within a small region of the putative DNA-recognition domain (F115S, F117L, S121P, C122Y). F117L, S121P and C122Y are unable to bind to DNA, suggesting a critical role of this region in DNA binding. Taken together, these results are in good agreement with the structural model of M.EcoRV.

Cloning and sequence analysis of the plasmid-borne genes encoding the Eco29kI restriction and modification enzymes

The Eco29kI restriction-modification system (RMS2) has been found to be localized on the plasmid pECO29 occurring naturally in the Escherichia coli strain 29k (Pertzev, A.V., Ruban, N.M., Zakharova, M.V., Beletskaya, I.V., Petrov, S.I., Kravetz, A.N., Solonin, A.S., 1992. Eco29kI, a novel plasmid encoded restriction endonuclease from Escherichia coli. Nucleic Acids Res. 20, 1991). The genes coding for this RMS2, a SacII isoschizomer recognizing the sequence CCGCGG have been cloned in Escherichia coli K802 and sequenced. The DNA sequence predicts the restriction endonuclease (ENase) of 214 amino acids (aa) (24,556 Da) and the DNA-methyltransferase (MTase) of 382 aa (43,007 Da) where the genes are separated by 2 bp and arranged in tandem with eco29kIR preceding eco29kIM. The recombinant plasmid with eco29kIR produces a protein of expected size. MEco29kI contains all the conserved aa sequence motifs characteristic of m5C-MTases. Remarkably, its variable region exhibits a significant similarity to the part of the specific target-recognition domain (TRD) from MBssHII--multispecific m5C-MTase (Schumann, J.J., Walter, J., Willert, J., Wild, C., Koch D., Trautner, T.A., 1996. MBssHII: a multispecific cytosine-C5-DNA-methyltransferase with unusual target recognizing properties. J. Mol. Biol. 257, 949-959), which recognizes five different sites on DNA (HaeII, MluI, Cfr10I, SacII and BssHII), and the comparison of the nt sequences of its variable regions allowed us to determine the putative TRD of MEco29kI.

Reactions of the eco RV restriction endonuclease with fluorescent oligodeoxynucleotides: identical equilibrium constants for binding to specific and non-specific DNA

The EcoRV restriction endonuclease cleaves DNA specifically at its recognition sequence in the presence of magnesium ions, but several studies have indicated that it binds to DNA in the absence of Mg2+ without any preference for its recognition site. However, specific binding to the recognition site has also been reported. To distinguish between these reports, oligodeoxynucleotides were tagged with either dansyl or eosin fluorophores at their 5' termini and annealed to form duplexes of 12 to 16 base-pairs. For each length of duplex, one derivative had the EcoRV recognition sequence while another lacked this sequence. For the duplexes with the recognition site, the fluorophores had no effect on DNA cleavage rates by EcoRV in the presence of Mg2+. The binding of the specific and non-specific duplexes to EcoRV in the absence of Mg2+ was measured by fluorescence resonance energy transfer and by fluorescence depolarization. In both procedures, the signal from the specific complex differed from the complex with non-specific DNA, with the depolarization data indicating that non-specific DNA bound to EcoRV retains a higher rotational freedom than specific DNA. Even so, the equilibrium constant for the binding of specific DNA was identical, within error limits, to that for non-specific DNA.

Kinetics of methylation and binding of DNA by the EcoRV adenine-N6 methyltransferase

The EcoRV DNA methyltransferase (M.EcoRV) specifically methylates the first adenine within its recognition sequence GATATC. Methylation rates of DNA by this enzyme are strongly influenced by the length of oligonucleotide substrates employed. If substrates >20 bp compared to a 12mer substrate, the kcat/Km increases 100-fold, although the enzyme does not contact more than 12 base-pairs on the DNA. Single-turnover rates are higher than kcat values. M.EcoRV binding to DNA is fast but dissociation from the DNA is slow, demonstrating that the multiple-turnover rate is limited by the rate of product release. The kinetics of DNA binding by M.EcoRV are not in accordance with the thermodynamics binding constant, suggesting that the M.EcoRV-DNA complex is involved in a slow conformational change. The salt dependence of DNA binding is different for non-specific substrates (d ln(KAss)/d ln(cNaCl) = - 2, indicative of electrostatic interactions) and specific substrates (d ln(KAss)/d ln(cNaCl) = + 1, indicative of hydrophobic interactions). This result demonstrates that the M.EcoRV-DNA complex has a different conformation in both binding modes. M.EcoRV does not discriminate between hemimethylated and unmethylated substrates. Using the 20mer we have analyzed the temperature and pH dependence of the single-turnover rate constant of M.EcoRV-DNA methylation by M.EcoRV has an activation energy of 40 kJ/mol and its rate increases with increasing pH. The pH dependence reveals the presence of an ionizable residue with a pKa of 7.9, which must be unprotonated for catalysis. The rates of DNA methylation remain unchanged if an abasic site is introduced instead of the thymidine residue that is base-paired to the target adenine, demonstrating that flipping out the target adenine cannot contribute to the rate-limiting step of the enzymatic reaction.

Specific binding by EcoRV endonuclease to its DNA recognition site GATATC

Restriction endonuclease EcoRV has been reported to be unable to distinguish its specific DNA site, GATATC, from non-specific DNA sites in the absence of the catalytic cofactor Mg2+, and thus to exercise sequence specificity solely in the catalytic step. In contrast, we show here that under appropriate conditions of pH and salt concentration, specific complexes with oligonucleotides containing the GATATC site can be detected by either filter-binding or gel-retardation. Equilibrium binding constants (K(A)) are easily measured by both direct equilibrium and equilibrium-competition methods. The preference for "specific" over "non-specific" binding at pH 7 in the absence of divalent cations is about 1000-fold (per mole of oligonucleotide) or 12,000-fold (per mole of binding sites). Ethylation-interference footprinting shows that the "specific" complex includes strong contacts to the phosphate groups GpApTpApTC. Specific DNA binding is strongly pH-dependent, decreasing about 15-fold for each increase of one pH unit above pH 6, but non-specific binding is not; thus, binding specificity decreases with increasing pH. Gel retardation and filter-binding at pH < or = 7 yield essentially identical values of K(A) for specific-site binding, but at pH > 7 gel retardation significantly underestimates K(A). Specific-site binding is stimulated about 700-fold by Ca2+ (not a cofactor for cleavage), but with non-cleavable 3'-phosphorothiolate and 4'-thiodeoxyribose derivatives whose response to Ca2+ is similar to that of the parent oligonucleotide, Mg2+ stimulates binding only fourfold and twofold, respectively. Thus, binding specificity is not dramatically enhanced by Mg2+. Taking into account discrimination in binding and in the first-order rate constant for phosphodiester bond scission, the overall discrimination exercised against the incorrect site GTTATC is about 10(7)-fold. EcoRV endonuclease is thus not a "new paradigm" for site-specific interaction without binding specificity, but like other type II restriction endonucleases achieves sequence specificity by discriminating both in DNA binding and in catalysis.

Cloning, expression and sequence analysis of the SphI restriction-modification system

SphI, a type II restriction-modification (R-M) system from the bacterium Streptomyces phaeochromogenes, recognizes the sequence 5'-GCATGC. The SphI methyltransferase (MTase)-encoding gene, sphIM, was cloned into Escherichia coli using MTase selection to isolate the clone. However, none of these clones contained the restriction endonuclease (ENase) gene. Repeated attempts to clone the complete ENase gene along with sphIM in one step failed, presumably due to expression of SphI ENase gene, sphIR, in the presence of inadequate expression of sphIM. The complete sphIR was finally cloned using a two-step process. PCR was used to isolate the 3' end of sphIR from a library. The intact sphIR, reconstructed under control of an inducible promoter, was introduced into an E. coli strain containing a plasmid with the NlaIII MTase-encoding gene (nlaIIIM). The nucleotide sequence of the SphI system was determined, analyzed and compared to previously sequenced R-M systems. The sequence was also examined for features which would help explain why sphIR unlike other actinomycete ENase genes seemed to be expressed in E. coli.

Vectors for a 'double-tagging' assay for protein-protein interactions: localization of the CDK2-binding domain of human p21

We report the construction of three new vectors which can be used for the 'double-tagging' assay previously reported [Germino et al., Proc. Natl. Acad. Sci. USA 90 (1993) 933-937]. The vectors include two plasmids (pTrc.BCCP and pTrc.EZZ::BCCP) which encode different 'tags' for the capture of a target protein of interest on a filter coated with either avidin or IgG, respectively. The first plasmid (pTrc.BCCP) encodes the C terminus of the biotin carboxylase carrier protein (BCCP) under the control of the Ptac promoter, while the second produces fusions to an IgG-binding domain (EZZ). The gene encoding a protein of interest can be inserted into these plasmids and thereby direct the production of a fusion protein which is biotinylated in vivo and can bind to avidin, or a fusion protein which can bind to IgG. The third is a positive-selection, phase lambda expression vector (lambdaFJG2) which permits the construction of lacZ::cDNA fusion proteins which retain beta-galactosidase activity. The insertion of an active ecoRVR gene between the cloning sites (EcoRI and HindII or NotI) permits the positive selection of inserts. The C-terminal two-thirds of the mouse retinoblastoma-encoding gene (containing the E1A-binding pocket) was cloned into pTrc.BCCP and pTrc.EZZ::BCCP, while the 13S E1a gene was cloned into lambdaFJG2. We show that the interaction between these two proteins can be detected using the 'double-tagging' filter assay, and that this assay has high sensitivity and specificity for detecting this interaction. Finally, we have used these vectors to localize the CDK2-binding domain of the cyclin-dependent kinase inhibitor, p21. These results closely correspond to those obtained using the yeast two-hybrid assay, as well as in vitro binding assays.

The regulatory C proteins from different restriction-modification systems can cross-complement

The BamHI restriction-modification system contains a third gene, bamHIC, which positively regulates bamHIR. Similar small genes from other systems were tested in vivo for their ability to cross-complement. C.BamHI protein was identified, purified, and used to raise polyclonal antibodies. Attempts to detect other C proteins in cell extracts by cross-reactivity with C.BamHI antibodies proved unsuccessful.

The eco72IC gene specifies a trans-acting factor which influences expression of both DNA methyltransferase and endonuclease from the Eco72I restriction-modification system

Eco72I from Escherichia coli RFL72 is a type-II restriction-modification (R-M) system recognizing and cleaving the sequence 5'-CAC decreases GTG-3'. The R-M genes are transcribed divergently and between the two genes is a small open reading frame codirectional to the R gene. This small ORF acts both to stimulate ENase expression and to depress DNA methyltransferase synthesis. The activity of beta Gal produced from the eco72IM::lacZ translational fusion increased tenfold, and eco72IR::lacZ translational fusion beta Gal activity decreased 130-fold when eco72IC was inactivated by a frameshift mutation. Analysis of nucleotide sequences of R-M systems, containing C genes, revealed a 5'-ACCTTATAGTC-3' consensus sequence upstream from the regulatory genes in all six analysed R-M systems. This sequence, named C-box, may play the role of an operator sequence.

Divalent metal ions at the active sites of the EcoRV and EcoRI restriction endonucleases

Restriction enzymes cannot cleave DNA without a metal ion cofactor. The specificities of the EcoRV and EcoRI endonucleases for metals were studied by measuring DNA cleavage rates with several metal ions and with combinations of metal ions. Both EcoRV and EcoRI had optimal activities with Mg2+, were less active with several other ions including Mn2+, and had virtually no activity with Ca2+. But the activities of EcoRV and EcoRI with either Mg2+ or Mn2+ were perturbed by Ca2+. For EcoRI, both Mg2+- and Mn(2+)-dependent activities, at both cognate and noncognate sites, were all inhibited by Ca2+. The activity of EcoRV at its recognition site with Mg2+ was also inhibited by Ca2+. But the Mn(2+)-dependent reaction at the EcoRV recognition site was stimulated by Ca2+. EcoRV activities at noncognate sites with either Mg2+ or Mn2+ displayed a biphasic response to Ca2+: stimulation at low concentrations of Ca2+ and inhibition at high concentrations. These observations, together with the known structures of the proteins, indicate that EcoRI needs only one metal ion per active site and is inactive when Mg2+ is displaced by Ca2+, while EcoRV needs two and that the displacement of one by Ca2+ can enhance activity. We propose a mechanism for phosphodiester hydrolysis by EcoRV that involves two metal ions.

Comparison of N-terminal affinity fusion domains: effect on expression level and product heterogeneity of recombinant restriction endonuclease EcoRV

The influence of different N-terminal affinity fusion domains on the product heterogeneity of recombinant proteins expressed in Escherichia coli was investigated. N-Terminal extended forms of the restriction endonuclease EcoRV with either glutathione-S-transferase [GST], histidine hexapeptide [(His)6], or a combination of GST and (His)6 [GST-(His)6] were compared to native EcoRV with respect to expression level, susceptibility to inclusion body formation and protein fragmentation. Fingerprinting of product heterogeneity was done by using two-dimensional (2-D) non-equilibrium pH-gradient electrophoresis with subsequent immunoblotting. Fusion proteins containing GST were poorly expressed compared to native EcoRV. In addition, GST fusion proteins were highly susceptible to in-vivo aggregation and fragmentation and displayed more heterogeneity on 2-D immunoblots. However, the sole presence of oligohistidine at the N-terminus of EcoRV proved to be advantageous. Fragmentation of (His)6-EcoRV was not observed and 2-D immunoblots did not show heterogeneous forms of the recombinant protein. In addition, fusion of the histidine-hexapeptide to the N-terminus of native EcoRV increased the expression level of the recombinant protein twofold compared to native EcoRV. Inclusion body formation of the (His)6-EcoRV fusion protein was intensive when cells were grown at 37 degrees C but not at 30 degrees C. The advantage of oligohistidine fusion to EcoRV was finally demonstrated by purifying soluble (His)6-EcoRV in a single-step procedure from crude cell lysates using immobilized metal chelate affinity chromatography.

Effect of site-specific modification on restriction endonucleases and DNA modification methyltransferases

Restriction endonucleases have site-specific interactions with DNA that can often be inhibited by site-specific DNA methylation and other site-specific DNA modifications. However, such inhibition cannot generally be predicted. The empirically acquired data on these effects are tabulated for over 320 restriction endonucleases. In addition, a table of known site-specific DNA modification methyltransferases and their specificities is presented along with EMBL database accession numbers for cloned genes.

Synthesis and properties of oligodeoxynucleotides containing the analogue 2'-deoxy-4'-thiothymidine

The 2'-deoxythymidine analogue 2'-deoxy-4'-thiothymidine has been incorporated, using standard methodology, into a series of dodecadeoxynucleotides containing the EcoRV restriction endonuclease recognition site (GATATC). The stability of these oligodeoxynucleotides and their ability to act as substrates for the restriction endonuclease and associated methylase have been compared with a normal unmodified oligodeoxynucleotide. No problems were encountered in the synthesis despite the presence of a potentially oxidisable sulfur atom in the sugar ring. The analogue had very little effect on the melting temperature of the self-complementary oligoeoxynucleotides so synthesised and all had a CD spectrum compatible with a B-DNA structure. The oligodeoxynucleotide containing one analogue in each strand within the recognition site, adjacent to the bond to be cleaved (i.e. GAXATC, where X is 2'-deoxy-4'-thiothymidine), was neither a substrate for the endonuclease nor was recognized by the associated methylase. When still within the recognition hexanucleotide but two further residues removed from the site of cleavage (i.e. GATAXC), the oligodeoxynucleotide was a poor substrate for both the endonuclease and methylase. Binding of the oligodeoxynucleotide to the endonuclease was unaffected but the kcat value was only 0.03% of the value obtained for the parent oligodeoxynucleotide. These results show that the incorporation of 2'-deoxy-4'-thionucleosides into synthetic oligodeoxynucleotides may shed light on subtle interactions between proteins and their normal substrates and may also show why 2'-deoxy-4'-thiothymidine itself is so toxic in cell culture.

Cloning and sequences of the genes encoding the CfrBI restriction-modification system from Citrobacter freundii

The genes encoding the CfrBI restriction and modification (R-M) systems from Citrobacter freundii and recognizing the sequence 5'-CCWWGG-3' (W = A or T) were cloned in Escherichia coli McrBC- cells. The nucleotide (nt) sequences of the genes were determined. Two large open reading frames were found. Deletion analysis showed that one of them [1128 nt coding for 376 amino acids (aa)] corresponds to a methyltransferase (MTase)-encoding gene and the other (1065 nt coding for 355 aa) to a restriction endonuclease-encoding gene. The genes are oriented divergently and separated by 76 bp. A CfrBI site (5'-m4CCATGG) was found in the intergenic region of the cfrBIRM genes. Analysis of the deduced aa sequence of M.CfrBI made it possible to determine the typical features of a m4C-specific MTase. Limited homology between the M.CfrBI and R.CfrBI proteins was also found.

The cleavage sites and localization of genes encoding the restriction endonucleases Eco1831I and EcoHI

The restriction endonucleases Eco1831I and EcoHI cleave before the first 5'-cytosine in the recognition sequence 5'-decreases CCSGG--3'/3'--GGSCC increases-5' (where S = G or C), generate 5-base 5' cohesive ends, and are encoded by homologous plasmids that are restricted in McrA+ hosts. Thus, they differ in their cleavage specificity from that of the BcnI isoschizomer, which cleaves after the second 5' cytosine.

Structure-function correlation for the EcoRV restriction enzyme: from non-specific binding to specific DNA cleavage

The EcoRV restriction endonuclease cleaves DNA at its recognition sequence at least a million times faster than at any other DNA sequence. The only cofactor it requires for activity is Mg2+; but in binding to DNA in the absence of Mg2+, the EcoRV enzyme shows no specificity for its recognition site. Instead, the reason why EcoRV cuts one DNA sequence faster than any other is that the rate of cleavage is controlled by the binding of Mg2+ to EcoRV-DNA complexes: the complex at the recognition site has a high affinity for Mg2+, while the complexes at other DNA sequences have low affinities for Mg2+. The structures of the EcoRV endonuclease, and of its complexes with either specific or non-specific DNA, have been solved by X-ray crystallography. In the specific complex, the protein interacts with the bases in the recognition sequence and the DNA takes up a highly distorted structure. In the non-specific complex with an unrelated DNA sequence, there are virtually no interactions with the bases and the DNA retains a B-like structure. Since the free energy changes for the formation of specific and non-specific complexes are the same, the energy from the specific interactions balances that required for the distortion of the DNA. The distortion inserts the phosphate at the scissile bond into the active site of the enzyme, where it forms part of the binding site for Mg2+. Without this distortion, the EcoRV-DNA complex would be unable to bind Mg2+ and thus unable to cleave DNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Gene structure and expression of the MboI restriction--modification system

The genes from Moraxella bovis encoding the MboI restriction--modification system were cloned and expressed in Escherichia coli. Three open reading frames were found in the sequence containing the genes. These genes, which we named mboA, mboB, and mboC, had the same orientation in the genome. Genes mboA and mboC encoded MboI methyltransferases (named M.MboA and M.MboC) with 294 and 273 amino acid residues, respectively. The mboB gene coded for MboI restriction endonuclease (R.MboI) with 280 amino acid residues. Recombinant E.coli-MBOI, which contained the whole MboI system, overproduced R.MboI. R.MboI activity from E.coli-MBOI was 480-fold that of M.bovis. The amino acid sequences deduced from these genes were compared with those of other restriction--modification systems. The protein sequences of the MboI system had 38-49% homology with those of the DpnII system.

The crystal structure of EcoRV endonuclease and of its complexes with cognate and non-cognate DNA fragments

The crystal structure of EcoRV endonuclease has been determined at 2.5 A resolution and that of its complexes with the cognate DNA decamer GGGATATCCC (recognition sequence underlined) and the non-cognate DNA octamer CGAGCTCG at 3.0 A resolution. Two octamer duplexes of the non-cognate DNA, stacked end-to-end, are bound to the dimeric enzyme in B-DNA-like conformations. The protein--DNA interactions of this complex are prototypic for non-specific DNA binding. In contrast, only one cognate decamer duplex is bound and deviates considerably from canonical B-form DNA. Most notably, a kink of approximately 50 degrees is observed at the central TA step with a concomitant compression of the major groove. Base-specific hydrogen bonds between the enzyme and the recognition base pairs occur exclusively in the major groove. These interactions appear highly co-operative as they are all made through one short surface loop comprising residues 182-186. Numerous contacts with the sugar phosphate backbone extending beyond the recognition sequence are observed in both types of complex. However, the total surface area buried on complex formation is > 1800 A2 larger in the case of cognate DNA binding. Two acidic side chains, Asp74 and Asp90, are close to the reactive phosphodiester group in the cognate complex and most probably provide oxygen ligands for binding the essential cofactor Mg2+. An important role is also indicated for Lys92, which together with the two acidic functions appears to be conserved in the otherwise unrelated structure of EcoRI endonuclease. The structural results give new insight into the physical basis of the remarkable sequence specificity of this enzyme.

Molecular characterization of the enniatin synthetase gene encoding a multifunctional enzyme catalysing N-methyldepsipeptide formation in Fusarium scirpi

The gene encoding the multifunctional enzyme enniatin synthetase from Fusarium scirpi (esyn1) was isolated and characterized by transcriptional mapping and expression studies in Escherichia coli. This is the first example of a gene encoding an N-methyl peptide synthetase. The nucleotide sequence revealed an open reading frame of 9393 bp encoding a protein of 3131 amino acids (M(r) 346,900). Two domains designated EA and EB within the protein were identified which share similarity to each other and to microbial peptide synthetase domains. In contrast to the N-terminal domain EA, the carboxyl terminal domain EB is interrupted by a 434-amino-acid portion which shows local similarity to a motif apparently conserved within adenine and cytosine RNA and DNA methyltransferases and therefore seems to harbour the N-methyl-transferase function of the multienzyme.

Cloning and sequence analysis of the genes coding for Eco57I type IV restriction-modification enzymes

A 6.3 kb fragment of E.coli RFL57 DNA coding for the type IV restriction-modification system Eco57I was cloned and expressed in E.coli RR1. A 5775 bp region of the cloned fragment was sequenced which contains three open reading frames (ORF). The methylase gene is 1623 bp long, corresponding to a protein of 543 amino acids (62 kDa); the endonuclease gene is 2991 bp in length (997 amino acids, 117 kDa). The two genes are transcribed convergently from different strands with their 3'-ends separated by 69 bp. The third short open reading frame (186 bp, 62 amino acids) has been identified, that precedes and overlaps by 7 nucleotides the ORF encoding the methylase. Comparison of the deduced Eco57I endonuclease and methylase amino acid sequences revealed three regions of significant similarity. Two of them resemble the conserved sequence motifs characteristic of the DNA[adenine-N6] methylases. The third one shares similarity with corresponding regions of the PaeR7I, TaqI, CviBIII, PstI, BamHI and HincII methylases. Homologs of this sequence are also found within the sequences of the PaeR7I, PstI and BamHI restriction endonucleases. This is the first example of a family of cognate restriction endonucleases and methylases sharing homologous regions. Analysis of the structural relationship suggests that the type IV enzymes represent an intermediate in the evolutionary pathway between the type III and type II enzymes.

Regulation of the BamHI restriction-modification system by a small intergenic open reading frame, bamHIC, in both Escherichia coli and Bacillus subtilis

BamHI, from Bacillus amyloliquefaciens H, is a type II restriction-modification system recognizing and cleaving the sequence G--GATCC. The BamHI restriction-modification system contains divergently transcribed endonuclease and methylase genes along with a small open reading frame oriented in the direction of the endonuclease gene. The small open reading frame has been designated bamHIC (for BamHI controlling element). It acts as both a positive activator of endonuclease expression and a negative repressor of methylase expression of BamHI clones in Escherichia coli. Methylase activity increased 15-fold and endonuclease activity decreased 100-fold when bamHIC was inactivated. The normal levels of activity for both methylase and endonuclease were restored by supplying bamHIC in trans. The BamHI restriction-modification system was transferred into Bacillus subtilis, where bamHIC also regulated endonuclease expression when present on multicopy plasmid vectors or integrated into the chromosome. In B. subtilis, disruption of bamHIC caused at least a 1,000-fold decrease in endonuclease activity; activity was partially restored by supplying bamHIC in trans.

Cloning and sequence analysis of the StsI restriction-modification gene: presence of homology to FokI restriction-modification enzymes

StsI endonuclease (R.StsI), a type IIs restriction endonuclease found in Streptococcus sanguis 54, recognizes the same sequence as FokI but cleaves at different positions. A DNA fragment that carried the genes for R.StsI and StsI methylase (M.StsI) was cloned from the chromosomal DNA of S.sanguis 54, and its nucleotide sequence was analyzed. The endonuclease gene was 1,806 bp long, corresponding to a protein of 602 amino acid residues (M(r) = 68,388), and the methylase gene was 1,959 bp long, corresponding to a protein of 653 amino acid residues (M(r) = 76,064). The assignment of the endonuclease gene was confirmed by analysis of the N-terminal amino acid sequence. Genes for the two proteins were in a tail-to-tail orientation, separated by a 131-nucleotide intercistronic region. The predicted amino acid sequences between the StsI system and the FokI system showed a 49% identity between the methylases and a 30% identity between the endonucleases. The sequence comparison of M.StsI with various methylases showed that the N-terminal half of M.StsI matches M.NIaIII, and the C-terminal half matches adenine methylases that recognize GATC and GATATC.

Sequence and characterization of pvuIIR, the PvuII endonuclease gene, and of pvuIIC, its regulatory gene

An open reading frame partially overlaps pvuIIR, and genetic evidence implies that this open reading frame, named pvuIIC, specifies a positive regulator of pvuIIR (T. Tao, J. C. Bourne, and R. M. Blumenthal, J. Bacteriol. 173:1367-1375, 1991). Inducible constructs of pvuIIC produced a protein of the expected size. The site of C.PvuII action appears to lie within pvuIIC itself; thus, pvuIIC may be a self-contained regulatory cassette.

Eco29kI, a novel plasmid encoded restriction endonuclease from Escherichia coli

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Cloning and molecular characterization of the HgiCI restriction/modification system from Herpetosiphon giganteus Hpg9 reveals high similarity to BanI

The genes coding for the GGYRCC specific restriction/modification system HgiCI from Herpetosiphon giganteus Hpg9 have been cloned in Escherichia coli in three steps. As an initial step, the methyltransferase gene could be obtained after heterologous in vitro selection of a plasmid gene bank by cleavage with the isoschizomeric restriction endonuclease BanI. The adjacent endonuclease gene was cloned following Southern blot analysis of flanking genomic regions. The two genes code for polypeptides of 420 amino acids (M.HgiCI) and 345 amino acids (R.HgiCI). Establishing a functional endonuclease gene could only be achieved using a tightly regulated expression system or by methylation of the genomic DNA prior to transformation of the endonuclease gene. The methyltransferase M.HgiCI shows significant similarities to the family of 5-methylcytidine methyltransferases. Striking similarities could be found with both the isoschizomeric endonuclease and methyltransferase of the BanI restriction/modification system from Bacillus aneurinolyticus.

Genetic organization of the KpnI restriction--modification system

The KpnI restriction-modification (KpnI RM) system was previously cloned and expressed in E. coli. The nucleotide sequences of the KpnI endonuclease (R.KpnI) and methylase (M. KpnI) genes have now been determined. The sequence of the amino acid residues predicted from the endonuclease gene DNA sequence and the sequence of the first 12 NH2-terminal amino acids determined from the purified endonuclease protein were identical. The kpnIR gene specifies a protein of 218 amino acids (MW: 25,115), while the kpnIM gene codes for a protein of 417 amino acids (MW: 47,582). The two genes transcribe divergently with a intergeneic region of 167 nucleotides containing the putative promoter regions for both genes. No protein sequence similarity was detected between R.KpnI and M.KpnI. Comparison of the amino acid sequence of M.KpnI with sequences of various methylases revealed a significant homology to N6-adenine methylases, a partial homology to N4-cytosine methylases, and no homology to C5-methylases.