Restriction enzyme analysis of Bacillus subtilis bacteriophage phi 105 DNA

The recognition sites on phi 105 DNA for the restriction endonucleases EcoRI, Bg/II, SmaI, KpnI, SstI, SalI, XhoI, NcoI, PstI, HindIII, ClaI, EcoRV and MluI have been mapped. The sites for EcoRI are shown to be different from those published earlier. The DNA from phi 105 contains no recognition sites for the endonucleases BamHI and XbaI.     

How does a DNA interacting enzyme change its specificity during molecular evolution? A site-directed mutagenesis study at the DNA binding site of the DNA-(adenine-N6)-methyltransferase EcoRV

The EcoRV DNA-(adenine-N6)-methyltransferase (MTase) recognizes GATATC sequences and modifies the first adenine residue within this site. Parts of its DNA interface show high sequence homology to DNA MTases of the dam family which recognize and modify GATC sequences. A phylogenetic analysis of M.EcoRV and dam-MTases suggests that EcoRV arose in evolution from a primordial dam-MTase in agreement to the finding that M.EcoRV also methylates GATC sites albeit at a strongly reduced rate. GATCTC sites that deviate in only one position from the EcoRV sequence are preferred over general dam sites. We have investigated by site-directed mutagenesis the function of 17 conserved and nonconserved residues within three loops flanking the DNA binding cleft of M.EcoRV. M.EcoRV contacts the GATATC sequence with two highly cooperative recognition modules. The contacts to the GAT-part of the recognition sequence are formed by residues conserved between dam MTases and M.EcoRV. Mutations at these positions lead to an increase in the discrimination between GATATC and GATC substrates. Our data show that the change in sequence specificity from dam (GATC) to EcoRV (GATATC) was accompanied by the generation of a second recognition module that contacts the second half of the target sequence. The new DNA contacts are formed by residues from all three loops that are not conserved between M.EcoRV and dam MTases. Mutagenesis at important residues within this module leads to variants that show a decreased ability to recognize the TC-part of the GATATC sequence.     

The M.EcoRV DNA-(adenine N6)-methyltransferase uses DNA bending for recognition of an expanded EcoDam recognition site

The M.EcoRV DNA methyltransferase recognizes GATATC sites. It is related to EcoDam, which methylates GATC sites. The DNA binding domain of M.EcoRV is similar to that of EcoDam suggesting a similar mechanism of DNA recognition. We show that amino acid residue Lys11 of M.EcoRV is involved in recognition of Gua1 and Arg128 contacts the Gua in base pair 6. These residues correspond to Lys9 and Arg124 in EcoDam, which recognize the Gua residues in both strands of the Dam recognition sequence, indicating that M.EcoRV and EcoDam make similar contacts to outermost base pairs of their recognition sequences and M.EcoRV recognizes its target site as an expanded GATC site. In contrast to EcoDam, M.EcoRV considerably bends the DNA (59+/-4 degrees) suggesting indirect readout of the AT-rich inner sequence. Recognition of an expanded target site by DNA bending is a new principle for changing DNA recognition specificity of proteins during molecular evolution. R128A is inefficient in DNA bending and binding, whereas K11A bends DNA with relaxed sequence specificity. These results suggest a temporal order of the formation of protein-DNA contacts in which the Gua6-Arg128 contact forms early followed by DNA bending and, finally, the formation of the Lys11-Gua1 contact.     

Relaxed specificity of the EcoRV restriction endonuclease

The EcoRV restriction endonuclease normally shows a high specificity for its recognition site on DNA, GATATC. In standard reactions, it cleaves DNA at this site several orders of magnitude more readily than at any alternative sequence. But in the presence of dimethyl sulphoxide and at high pH, the EcoRV enzyme cleaves DNA at several sites that differ from its recognition site by one nucleotide. Of the 18 (3 X 6) possible sequences that differ from GATATC by one base, all were cleaved readily except for the following 4 sites: TATATC, CATATC, GATATA and GATATG. However, two of the sites that could be cleaved by EcoRV in the presence of dimethyl sulphoxide, GAGATC and GATCTC, were only cleaved on DNA that lacked dam methylation: both contain the sequence GATC, the recognition site for the dam methylase of Escherichia coli.     

EcoRV restriction endonuclease binds all DNA sequences with equal affinity

In the presence of MgCl2, the EcoRV restriction endonuclease cleaves its recognition sequence on DNA at least a million times more readily than any other sequence. In this study, the binding of the EcoRV restriction enzyme to DNA was examined in the absence of Mg2+. With each DNA fragment tested, several DNA-protein complexes were detected by electrophoresis through polyacrylamide. No differences were observed between isogenic DNA molecules that either contained or lacked the EcoRV recognition site. The number of complexes with each fragment varied with the length of the DNA. Three complexes were formed with a DNA molecule of 55 base pairs, corresponding to the DNA bound to 1, 2, or 3 molecules of the protein, while greater than 15 complexes were formed with a DNA of 381 base pairs. A new method was developed to analyze the binding of a protein to multiple sites on DNA. The method showed that the EcoRV enzyme binds to all DNA sequences, including the EcoRV recognition site, with the same equilibrium constant, though two molecules of the protein bind preferentially to adjacent sites on the DNA in a cooperative fashion. All of the complexes with a substrate that contained the EcoRV site dissociated upon addition of competitor DNA, but when the competitor was mixed with MgCl2, a fraction of the substrate was cleaved at the EcoRV site. The fraction cleaved was due mainly to the translocation of the enzyme from nonspecific sites on the DNA to the specific site.     

Molecular enzymology of the EcoRV DNA-(Adenine-N (6))-methyltransferase: kinetics of DNA binding and bending, kinetic mechanism and linear diffusion of the enzyme on DNA

The EcoRV DNA-(adenine-N(6))-methyltransferase recognizes GATATC sequences and modifies the first adenine residue within this site. We show here, that the enzyme binds to the DNA and the cofactor S-adenosylmethionine (AdoMet) in an ordered bi-bi fashion, with AdoMet being bound first. M.EcoRV binds DNA in a non-specific manner and the enzyme searches for its recognition site by linear diffusion with a range of approximately 1800 bp. During linear diffusion the enzyme continuously scans the DNA for the presence of recognition sites. Upon specific M.EcoRV-DNA complex formation a strong increase in the fluorescence of an oligonucleotide containing a 2-aminopurine base analogue at the GAT-2AP-TC position is observed which, most likely, is correlated with DNA bending. In contrast to the GAT-2AP-TC substrate, a G-2AP-TATC substrate in which the target base is replaced by 2-aminopurine does not show an increase in fluorescence upon M.EcoRV binding, demonstrating that 2-aminopurine is not a general tool to detect base flipping. Stopped-flow experiments show that DNA bending is a fast process with rate constants >10 s(-1). In the presence of cofactor, the specific complex adopts a second conformation, in which the target sequence is more tightly contacted by the enzyme. M.EcoRV exists in an open and in a closed state that are in slow equilibrium. Closing the open state is a slow process (rate constant approximately 0.7 min(-1)) that limits the rate of DNA methylation under single turnover conditions. Product release requires opening of the closed complex which is very slow (rate constant approximately 0.05-0.1 min(-1)) and limits the rate of DNA methylation under multiple turnover conditions. M.EcoRV methylates DNA sequences containing more than one recognition sites in a distributive manner. Since the dissociation rate from non-specific DNA does not depend on the length of the DNA fragment, DNA dissociation does not preferentially occur at the ends of the DNA.     

The activity of the EcoRV restriction endonuclease is influenced by flanking DNA sequences both inside and outside the DNA-protein complex.

The EcoRV restriction endonuclease cleaves DNA not only at its recognition sequence but also at most other sequences that differ from the recognition site by one base pair. Compared to the reaction at the recognition site, the reactions at noncognate sites are slow but 1 out of the 12 noncognate sites on the plasmid pAT153 is cleaved more than 50 times faster than any other. The increase in the reaction rate at the preferred noncognate site, relative to other sites, was caused by the DNA sequences in the 4 base pairs from either side of the site. For enhanced activity by EcoRV, particular bases were needed immediately adjacent to the site, inside the DNA-protein complex. At these loci, the protein interacts with the phosphate groups in the DNA and the flanking sequence may control the activity of the enzyme by determining the conformation of the DNA, thus aligning the phosphate contacts. But the preferential cleavage also depended on sequences further away from the site, at loci outside the complex. At external positions, beyond the reach of the protein, the EcoRV enzyme required flanking sequences that give rise to flexibility in DNA conformation. These may facilitate the distortion of the DNA required for catalysis by EcoRV.     

Non-phenotypic selection of N-methyl-N-nitrosourea-induced mutations in human cells.

The distribution of mutations in a particular gene as detected by a selective mutation assay could be affected by the structural properties of the target protein. To investigate this, we have analysed N-methyl-N-nitrosourea (MNU)-induced mutations in two restriction recognition sequences of a target gene for mutation analysis and compared these data with what previously observed in a phenotypic mutation assay. DNA base changes in the Ncil and EcoRV sites of the gpt gene maintained in human cells by a shuttle vector system were measured by restriction fragment length polymorphism/polymerase chain reaction (RFLP/PCR) technique. After MNU-treatment of human cells, mutations were detected in the Ncil recognition sequence but not in the EcoRV site. DNA sequencing analysis revealed that all Ncil-resistant mutations were GC to AT transitions located over four bases of the Ncil recognition sequence. Only one of these mutations drastically affected the functionality of the GPT protein. The Ncil-resistant mutations were randomly distributed in both DNA strands of the gpt gene and were preferentially targeted at guanine residues flanked 5' by a guanine. Our results indicate that the structure of the GPT protein is the main contributor to the strand-specificity of MNU-induced mutations previously reported by using a phenotypic mutation assay. The potential use of the RFLP/PCR technique as a general tool for mutation detection is also discussed.     

Investigation of the inhibitory role of phosphorothioate internucleotidic linkages on the catalytic activity of the restriction endonuclease EcoRV

The inhibitory effect of phosphorothioate residues, located within one strand of double-stranded DNA, on the hydrolytic activity of the restriction endonuclease EcoRV was investigated. Specific incorporation of a phosphorothioate group at the site of cleavage yielded the sequence 5'-GATsATC-3'. This modified sequence was cleaved at a relative rate of 0.1 compared to the unmodified substrate. Substrates 5'-GATsAsTC-3' and 5'-GsATsATC-3', both containing one additional phosphorothioate substitution, were linearized at a rate of 0.04 relative to unmodified DNA. However, under the same conditions, fully dAMPS-substituted DNA was found to be virtually resistant to the hydrolytic activity of EcoRV. Further experiments showed that double-stranded DNA fragments generated by PCR containing phosphorothioate groups within both strands are potent inhibitors of EcoRV catalysis. The inhibition was independent of whether the inhibitor fragment contained an EcoRV recognition site. We concluded that substitution of the phosphate group at the site of cleavage by a phosphorothioate residue decreases the rate of EcoRV-catalyzed hydrolysis most significantly. Substitution of other phosphate groups within the recognition sequence plays a limited role in enzyme inhibition. The presence of multiple dNMPS residues at regions of the DNA removed from the EcoRV recognition site may decrease the amount of enzyme available for catalysis by nonspecific binding to EcoRV.     

PvuII endonuclease contains two calcium ions in active sites

Restriction endonucleases differ in their use of metal cofactors despite having remarkably similar folds for their catalytic regions. To explore this, we have characterized the interaction of endonuclease PvuII with the catalytically incompetent cation Ca(2+). The structure of a glutaraldehyde-crosslinked crystal of the endonuclease PvuII-DNA complex, determined in the presence of Ca(2+) at a pH of approximately 6.5, supports a two-metal mechanism of DNA cleavage by PvuII. The first Ca(2+) position matches that found in all structurally examined endonucleases, while the second position is similar to that of EcoRV but is distinct from that of BamHI and BglI. The location of the second metal in PvuII, unlike that in BamHI/BglI, permits no direct interaction between the second metal and the O3' oxygen leaving group. However, the interactions between the DNA scissile phosphate and the metals, the first metal and the attacking water, and the attacking water and DNA are the same in PvuII as they are in the two-metal models of BamHI and BglI, but are distinct from the proposed three-metal or the two-metal models of EcoRV.     

Sliding and jumping of single EcoRV restriction enzymes on non-cognate DNA

The restriction endonuclease EcoRV can rapidly locate a short recognition site within long non-cognate DNA using 'facilitated diffusion'. This process has long been attributed to a sliding mechanism, in which the enzyme first binds to the DNA via nonspecific interaction and then moves along the DNA by 1D diffusion. Recent studies, however, provided evidence that 3D translocations (hopping/jumping) also help EcoRV to locate its target site. Here we report the first direct observation of sliding and jumping of individual EcoRV molecules along nonspecific DNA. Using fluorescence microscopy, we could distinguish between a slow 1D diffusion of the enzyme and a fast translocation mechanism that was demonstrated to stem from 3D jumps. Salt effects on both sliding and jumping were investigated, and we developed numerical simulations to account for both the jump frequency and the jump length distribution. We deduced from our study the 1D diffusion coefficient of EcoRV, and we estimated the number of jumps occurring during an interaction event with nonspecific DNA. Our results substantiate that sliding alternates with hopping/jumping during the facilitated diffusion of EcoRV and, furthermore, set up a framework for the investigation of target site location by other DNA-binding proteins.     

Probing the DNA interface of the EcoRV DNA-(adenine-N6)-methyltransferase by site-directed mutagenesis,fluorescence spectroscopy,and UV cross-linking

The EcoRV DNA-(adenine-N6)-methyltransferase recognizes GATATC sites and methylates the DNA as indicated. It is related to the large family of dam methyltransferases which modify GATC sites. We have studied the interaction of DNA with M.EcoRV and 12 M.EcoRV variants using oligonucleotides containing 2-aminopurine as a fluorescence probe in equilibrium and stopped-flow DNA binding studies and 5-iododeoxyuracil for UV cross-linking. M.EcoRV binds to DNA in a multistep binding reaction, including two different conformations of the specific enzyme-DNA complex, and induces a strong conformational change of the DNA at the fourth position of the recognition site. Mutations at residues forming contacts to the GAT part of the recognition site reduce the stability of both specific enzyme-DNA complexes. Two enzyme variants which fail to recognize the ATC part do not induce the deformation of the DNA which explains why they cannot interact properly with the recognition site. Other mutations at residues which interact with the ATC part selectively reduce the stability of the second enzyme-DNA complex. These results show that when approaching the DNA M.EcoRV first contacts the GAT part of the target site. Since the residues mediating these contacts are conserved among M.EcoRV and dam MTases, the kinetics of formation of the enzyme-DNA complex correspond to the evolutionary history of the protein. Whether the observation that evolutionarily conserved contacts are formed early during complex formation is a general rule for DNA interacting enzymes or proteins that change their specificity during evolution remains to be seen.     

Fidelity of DNA recognition by the EcoRV restriction/modification system in vivo

The EcoRV restriction/modification system consists of two enzymes that recognize the DNA sequence GATATC. The EcoRV restriction endonuclease cleaves DNA at this site, but the DNA of Escherichia coli carrying the EcoRV system is protected from this reaction by the EcoRV methyltransferase. However, in vitro, the EcoRV nuclease also cleaves DNA at most sites that differ from the recognition sequence by one base pair. Though the reaction of the nuclease at these sites is much slower than that at the cognate site, it still appears to be fast enough to cleave the chromosome of the cell into many fragments. The possibility that the EcoRV methyltransferase also protects the noncognate sites on the chromosome was examined. The modification enzyme methylated alternate sites in vivo, but these were not the same as the alternate sites for the nuclease. The excess methylation was found at GATC sequences, which are also the targets for the dam methyltransferase of E. coli, a protein that is homologous to the EcoRV methyltransferase. Methylation at these sites gave virtually no protection against the EcoRV nuclease: even when the EcoRV methyltransferase had been overproduced, the cellular DNA remained sensitive to the EcoRV nuclease at its noncognate sites. The viability of E. coli carrying the EcoRV restriction/modification system was found instead to depend on the activity of DNA ligase. Ligase appears to proofread the EcoRV R/M system in vivo: DNA, cut initially in one strand at a noncognate site for the nuclease, is presumably repaired by ligase before the scission of the second strand.     

Discrimination between DNA sequences by the EcoRV restriction endonuclease

The EcoRV restriction endonuclease cleaves not only its recognition sequence on DNA, GATATC, but also, at vastly reduced rates, a number of alternative DNA sequences. The plasmid pAT153 contains 12 alternative sites, each of which differs from the recognition sequence by one base pair. The EcoRV nuclease showed a marked preference for one particular site from among these alternatives. This noncognate site was located at the sequence GTTATC, and the mechanism of action of EcoRV at this site was analyzed. The mechanism differed from that at the cognate site in three respects. First, the affinity of the enzyme for the noncognate site was lower than that for the cognate site, but, by itself, this cannot account for the specificity of EcoRV as measured from the values of kcat/Km. Second, the enzyme had a lower affinity for Mg2+ when it was bound to the noncognate site than when it was bound to its cognate site: this appears to be a key factor in limiting the rates of DNA cleavage at alternative sites. Third, the reaction pathway at the noncognate site differed from that at the cognate site. At the former, the EcoRV enzyme cleaved first one strand of the DNA and then the other while at the latter, both strands were cut in one concerted reaction. The difference in reaction pathway allows DNA ligase to proofread the activity of EcoRV by selective repair of single-strand breaks at noncognate sites, as opposed to double-strand breaks at the cognate site. The addition of DNA ligase to reactions with EcoRV made no difference to product formation at the cognate site, but products from reactions at noncognate sites were no longer detected.     

Reactions of BglI and other type II restriction endonucleases with discontinuous recognition sites

Type II restriction enzymes generally recognize continuous sequences of 4-8 consecutive base pairs on DNA, but some recognize discontinuous sites where the specified sequence is interrupted by a defined length of nonspecific DNA. To date, a mechanism has been established for only one type II endonuclease with a discontinuous site, SfiI at GGCCNNNNNGGCC (where N is any base). In contrast to orthodox enzymes such as EcoRV, dimeric proteins that act at a single site, SfiI is a tetramer that interacts with two sites before cleaving DNA. BglI has a similar recognition sequence (GCCNNNNNGGC) to SfiI but a crystal structure like EcoRV. BglI and several other endonucleases with discontinuous sites were examined to see if they need two sites for their DNA cleavage reactions. The enzymes included some with sites containing lengthy segments of nonspecific DNA, such as XcmI (CCANNNNNNNNNTGG). In all cases, they acted at individual sites. Elongated recognition sites do not necessitate unusual reaction mechanisms. Other experiments on BglI showed that it bound to and cleaved DNA in the same manner as EcoRV, thus further delineating a distinct group of restriction enzymes with similar structures and a common reaction mechanism.     

On the possibilities and limitations of rational protein design to expand the specificity of restriction enzymes: a case study employing EcoRV as the target

The restriction endonuclease EcoRV has been characterized in structural and functional terms in great detail. Based on this detailed information we employed a structure-guided approach to engineer variants of EcoRV that should be able to discriminate between differently flanked EcoRV recognition sites. In crystal structures of EcoRV complexed with d(CGGGATATCCC)(2) and d(AAAGATATCTT)(2), Lys104 and Ala181 closely approach the two base pairs flanking the GATATC recognition site and thus were proposed to be a reasonable starting point for the rational extension of site specificity in EcoRV [Horton,N.C. and Perona,J.J. (1998) J. Biol. Chem., 273, 21721-21729]. To test this proposal, several single (K104R, A181E, A181K) and double mutants of EcoRV (K104R/A181E, K104R/A181K) were generated. A detailed characterization of all variants examined shows that only the substitution of Ala181 by Glu leads to a considerably altered selectivity with both oligodeoxynucleotide and macromolecular DNA substrates, but not the predicted one, as these variants prefer cleavage of a TA flanked site over all other sites, under all conditions tested. The substitution of Lys104 by Arg, in contrast, which appeared to be very promising on the basis of the crystallographic analysis, does not lead to variants which differ very much from the EcoRV wild-type enzyme with respect to the flanking sequence preferences. The K104R/A181E and K104R/A181K double mutants show nearly the same preferences as the A181E and A181K single mutants. We conclude that even for the very well characterized restriction enzyme EcoRV, properties that determine specificity and selectivity are difficult to model on the basis of the available structural information.     

Mg2+ confers DNA binding specificity to the EcoRV restriction endonuclease.

The EcoRV mutant D90A which carries an amino acid substitution in its active center does not cleave DNA. Therefore, it is possible to perform DNA binding experiments with the EcoRV-D90A mutant both in the absence and in the presence of Mg2+. Like wild-type EcoRV [Taylor et al. (1991) Biochemistry 30, 8743-8753], it does not show a pronounced specificity for binding to its recognition site in the absence of Mg2+ as judged by the appearance of multiple shifted bands in an electrophoretic mobility shift assay with a 377-bp DNA fragment carrying a single EcoRV recognition sequence. In the presence of Mg2+, however, only one band corresponding to a 1:1 complex appears even with a high excess of protein over DNA. This complex most likely is the specific one, because its formation is suppressed much more effectively by a 13-bp oligodeoxynucleotide with an EcoRV site than by a corresponding oligodeoxynucleotide without an EcoRV site. The preferential interaction of the EcoRV-D90A mutant with specific DNA in the presence of Mg2+ was also demonstrated directly: a 20-bp oligodeoxynucleotide with an EcoRV site is bound with KAss = 4 x 10(8) M-1, while a corresponding oligodeoxynucleotide without an EcoRV site is bound with KAss less than or equal to 1 x 10(5) M-1. From these data it appears that Mg2+ confers DNA binding specificity to this mutant by lowering the affinity to nonspecific sites and raising the affinity to specific sites as compared to binding in the absence of Mg2+. It is concluded that this is also true for wild-type EcoRV.     

Structure-based sequence alignment of type-II restriction endonucleases

The type-II restriction endonucleases generally do not share appreciable amino acid sequence homology. The crystal structures of restriction endonucleases EcoRI and BamHI have shown these enzymes to possess striking 3D-structural resemblance, i.e., they have a similar overall fold and similar active sites, though they possess <23% sequence identity. Structural superimposition of EcoRI, BamHI, EcoRV, and PvuII based on active site residues led to sequence alignments which showed nine possible sequence motifs. EcoRV and PvuII show a more similar pattern than EcoRI and BamHI suggesting that they belong to a different subgroup. The motifs are characterized by charged and/or hydrophobic residues. From other studies on the structure of these endonucleases, three of the motifs could be implicated in DNA binding, three in forming the active site and one in dimer formation. However, the motifs were not identifiable by regular sequence alignment methods. It is found that motif IX in BamHI is formed by reverse sequence order and the motif IX in PvuII is formed from the symmetry related monomer of the dimer. The inter-motif distance is also quite different in these cases. Of the nine motifs, motif III has been earlier identified as containing the PD motif involving one of the active site residues. These motifs were used in a modified profile analysis procedure to identify similar regions in eight other endonuclease sequences for which structures are not known.     

Physical map of the Rhodobacter sphaeroides bacteriophage phi RsG1 genome and location of the prophage on the host chromosome.

We constructed a physical map of the 50-kilobase-pair (kb) DNA of the temperate Rhodobacter sphaeroides bacteriophage phi RsG1, with the relative positions of the cleavage sites for the nine restriction endonucleases KpnI, HindIII, XbaI, ClaI, BclI, EcoRV, EcoRI, BglII, and BamHI indicated. Using biotinylated phi RsG1 DNA as a probe in hybridization studies, we detected homologies with virus DNA and fragments of restriction endonuclease-digested host chromosomal DNA but not with plasmid DNA. This indicates that the prophage is integrated into the host chromosome. In addition, the use of specific probes such as the 10.4-kb BglII A fragment and the 2.65-kb BamHI H fragment allowed the determination of the position of phage attachment site (attP).