Interaction of EcoRII restriction and modification enzymes with synthetic DNA fragments. V. Study of single-strand cleavages.

Concatemer DNA duplexes which contain at the EcoRII restriction endonuclease cleavage sites (formula; see text) phosphodiester, phosphoamide or pyrophosphate internucleotide bonds have been synthesized. It has been shown that this enzyme did not cleave the substrate at phosphoamide bond. EcoRII endonuclease catalyzes single-strand cleavages both in dA- and dT-containing strands of the recognition site if the cleavage of the other strand has been blocked by modification of scissile bond or if the other strand has been cleaved. This enzyme interacts with both strands of the DNA recognition site, each of them being cleaved independently on the cleavage of another one. Nucleotide sequences flanking the EcoRII site on both sides are necessary for effective cleavage of the substrate.     

Interaction of restriction and modification enzyme EcoRII with synthetic DNA fragments. VII. The study of complex-formation of endonuclease EcoRII with substrates containing natural and modified recognition sites

As shown by a nitrocellulose filter binding assay, in the absence of Mg2+ EcoRII restriction endonuclease binds specifically to a set of synthetic concatemer DNA duplexes of varying chain length, containing natural and modified recognition sites of this enzyme. The binding of the substrates with the central AT, TT or AA-pair in the recognition site decreases at AT greater than TT much greater than AA. Substitution of the pyrophosphate bond at the cleavage site for the phosphodiester or phosphoramide bond produces little influence on the stability of the complexes. The affinity of the enzyme for nonspecific sites is two orders of magnitude less than that for the specific EcoRII sequences. Equilibrium association constant for a substrate with one recognition site is 3.9 X 10(8) M-1. Addition of Mg2+ leads to the destabilization of the EcoRII endonuclease complex with DNA duplex, containing pyrophosphate bonds. The dissociation rate constants and the lifetime of the EcoRII endonuclease--synthetic substrates complexes have been determined.     

Interaction of EcoRII restriction and modification enzymes with synthetic DNA fragments. VI. The binding and cleavage of substrates containing nucleotide analogs.

The present study deals with the binding and cleavage by EcoRII endonuclease of concatemer DNA duplexes containing EcoRII recognition sites (formula; see text) in which dT is replaced by dU or 5-bromodeoxyuridine, or 5'-terminal dC in the dT-containing strand is methylated at position 5. The enzyme molecule is found to interact with the methyl group of the dT residue of the DNA recognition site and to be at least in proximity to the H5 atom of the 5'-terminal dC residue in dT-containing strand of this site. Modification of any of these positions exerts an equal effects on the cleavage of both DNA strands. Endonuclease EcoRII was found to bind the substrate specifically. At the same time modification of the bases in recognized sequence may result in the formation of unproductive, though stable, enzyme-substrate complexes.     

Mechanism of the interaction of EcoRII restriction endonuclease with two recognition sites. Probing of modified DNA duplexes as activators of the enzyme.

The efficiency of cleavage of DNA duplexes with single EcoRII recognition sites by the EcoRII restriction endonuclease decreases with increasing substrate length. DNA duplexes of more than 215 bp are not effectively cleaved by this enzyme. Acceleration of the hydrolysis of long single-site substrates by EcoRII is observed in the presence of 11-14-bp substrates. The stimulation of hydrolysis depends on the length and concentration of the second substrate. To study the mechanism of EcoRII endonuclease stimulation, DNA duplexes with base analogs and modified internucleotide phosphate groups in the EcoRII site have been investigated as activators. These modified duplexes are cleaved by EcoRII enzyme with different efficiencies or are not cleaved at all. It has been discovered that the resistance of some of them can be overcome by incubation with a susceptible canonical substrate. The acceleration of cleavage of long single-site substrates depends on the type of modification of the activator. The modified DNA duplexes can activate EcoRII catalyzed hydrolysis if they can be cleaved by EcoRII themselves or in the presence of the second canonical substrate. It has been demonstrated that EcoRII endonuclease interacts in a cooperative way with two recognition sites in DNA. The cleavage of one of the recognition sites depends on the cleavage of the other. We suggest that the activator is not an allosteric effector but acts as a second substrate.     

Interaction of the MvaI restriction enzyme with synthetic DNA fragments

The cleavage of synthetic DNA duplexes by the restriction endonuclease MvaI has been studied. The main result of the cleavage experiments is that MvaI cleaves unmodified duplexes in two single strand scissions in separate events and that the two strands are cleaved at significantly different rates. One strand nicks within the recognition site do not affect the cleavage. Furthermore, neither a pyrophosphate internucleotide bond modification in one strand nor the absence of one phosphate group at the central dA-residue of the recognition site do inhibit the cleavage of the second strand.     

Activation of restriction endonuclease EcoRII does not depend on the cleavage of stimulator DNA.

The restriction endonuclease EcoRII is unable to cleave DNA molecules when recognition sites are very far apart. The enzyme, however can be activated in the presence of DNA molecules with a high frequency of EcoRII sites or by oligonucleotides containing recognition sites: Addition of the activator molecules stimulates cleavage of the refractory substrate. We now show that endonucleolysis of the stimulator molecules is not a necessary prerequisite of enzyme activation. A total EcoRII digest of pBR322 DNA or oligonucleotide duplexes with simulated EcoRII ends (containing the 5' phosphate group), as well as oligonucleotide duplexes containing modified bases within the EcoRII site, making them resistant to cleavage, are all capable of enzyme activation. For activation EcoRII requires the interaction with at least two recognition sites. The two sites may be on the same DNA molecule, on different oligonucleotide duplexes, or on one DNA molecule and one oligonucleotide duplex. The efficiency of functional intramolecular cooperation decreases with increasing distance between the sites. Intermolecular site interaction is inversely related to the size of the stimulator oligonucleotide duplex. The data are in agreement with a model whereby EcoRII simultaneously interacts with two recognition sites in the active complex, but cleavage of the site serving as an allosteric activator is not necessary.     

Oligonucleotide duplexes containing CC(A/T)GG stimulate cleavage of refractory DNA by restriction endonuclease EcoRII

Some DNA species are resistant towards the restriction endonuclease EcoRII despite the presence of unmodified recognition sites. We show that 14 base-pair oligonucleotide duplexes containing the EcoRII recognition site 5'-CC(A/T)GG are cleaved by this enzyme and are able to stimulate EcoRII cleavage of such resistant DNA molecules (e.g. DNA of bacterial virus T3). A direct correlation between the concentration of oligonucleotide duplex molecules and the degree of EcoRII digestion of the primarily resistant DNA is observed. This indicates a stoichiometric rather than a catalytic mode of enzyme activation. An excess of DNA devoid of EcoRII sites ('non-site' DNA, e.g. MvaI-digested T7 DNA) does not interfere with the activity of EcoRII.     

Interaction of EcoRII restriction and modification enzymes with synthetic DNA fragments. IX. Cleavage of substrates with point modifications in the recognition site and flanking sequences

Ability of the EcoRII restriction endonuclease to cleave 14-base-pair DNA duplexes with nucleotide substitutions in the recognition site CCA/TGG and in the adjacent base pair has been studied. Modifications leading to a local change in the substrate conformation (rU residue in and outside the recognition site, A.A- or A.C-pairs in the flanking sequence) reduce the rate of hydrolysis, the effect being maximal when the modified base pair is outside the recognition site. No digestion occurs when the internal dC-residue of the recognition site is 5-methylated in one or both strands. Replacement of dT residue in the EcoRII recognition site by dfl5U residue results in a dramatic inhibition of hydrolysis. Km and kcat for the cleavage of 14-base-pair DNA duplex have been determined. The cleavage rate of the dT-containing strand of the recognition site in 1.5 fold higher comparing with the dA-containing strand. The cleavage of both strands of the substrate by EcoRII endonuclease is confirmed to proceed in one enzyme-substrate complex.     

Modified DNA fragments activate NaeI cleavage of refractory DNA sites.

Endonuclease NaeI cleaves DNA using a two-site mechanism. The DNA-binding sites are nonidentical: they recognize different families of flanking sequences. A unique NaeI site that is resistant to cleavage resides in M13 double-stranded DNA. NaeI can be activated to cleave this site by small DNA fragments containing one or more NaeI sites. These activators are not practical for genetic engineering because unphosphorylated activators that are consumed during the cleavage of substrate give ends that may interfere with subsequent ligations. We show that a DNA fragment containing phosphorothioate linkages at the NaeI scissile bonds (S-activator) is not cleaved by NaeI, even though this S-activator binds to the substrate site. The S-activator activates NaeI to cleave M13 DNA under conditions that completely exhaust unsubstituted activator. These results demonstrate that activation is not coupled to cleavage of activator, that NaeI reverts to its inactive state soon after dissociation of the EA complex, and that S-activator makes for a nondepletable activator during prolonged incubations.     

Protection of particular cleavage sites of restriction endonucleases by distamycin A and actinomycin D.

It is shown here that distamycin A and actinomycin D can protect the recognition sites of endo R.EcoRI, EcoRII, HindII, HindIII, HpaI and HpaII from the attack of these restriction endonucleases. At proper distamycin concentrations only two endo R.EcoRI sites of phage lambda DNA are available for the restriction enzyme--sRI1 and sRI4. This phenomenon results in the appearance of larger DNA fragments comprising several consecutive fragments of endo R.EcoRI complete cleavage. The distamycin fragments isolated from the agarose gels can be subsequently cleaved by endo R.EcoRI with the yield of the fragments of complete digestion. We have compared the effect of distamycin A and actinomycin D on a number of restriction endonucleases having different nucleotide sequences in the recognition sites and established that antibiotic action depends on the nucleotide sequences of the recognition sites and their closest environment     

Interaction of EcoRII restriction and modification enzymes with synthetic DNA fragments. X. Hydrolysis of substrates with structural abnormalities

Interaction of the EcoRII restriction endonuclease with a set of 30-membered substrates having structural anomalies in the recognition site (decreases CCT/AGG) and in adjacent sequences has been studied. A nick in the centre of the EcoRII recognition site between dC and dA residues slows down hydrolysis of the nonmodified strand, whereas the modified one is not cleaved. Removal of the phosphate group from the nick in this substrate does not alter the rate of the cleavage. The absence of one of the phosphate groups in the flanking sequence at a two-base-pair "distance" from the recognition site slows down the enzymatic hydrolysis. Removal of dA or dT out of the EcoRII recognition site blocks the enzymatic reaction. It appears that EcoRII does not interact with the phosphate group between dC and dA residues in the recognition site. Suggestions are made concerning possible contacts of the EcoRII restriction endonuclease with dA- and dT-residues of the recognition site and with the sugar-phosphate backbone of the adjacent nucleotide sequences.     

Morphological and biochemical effects of endonucleases on isolated mammalian chromosomes in vitro

Endonuclease digestion of isolated and unfixed mammalian metaphase chromosomes in vitro was examined as a means to study the higher-order regional organization of chromosomes related to banding patterns and the mechanisms of endonuclease-induced banding. Isolated mouse LM cell chromosomes, digested with the restriction enzymes AluI, HaeIII, EcoRI, BstNI, AvaII, or Sau96I, demonstrated reproducible G- and/or C-banding at the cytological level depending on the enzyme and digestion conditions. At the molecular level, specific DNA alterations were induced that correlated with the banding patterns produced. The results indicate that: (1) chromatin extraction is intimately involved in the mechanism of endonuclease induced chromosome banding. (2) The extracted DNA fragments are variable in size, ranging from 200 bp to more than 4 kb in length. (3) For HaeIII, there appears to be variation in the rate of restriction site cleavage in G- and R-bands; HaeIII sites appear to be more rapidly cleaved in R-bands than in G-bands. (4) AluI and HaeIII ultimately produce banding patterns that reflect regional differences in the distribution of restriction sites along the chromosome. (5) BstNI restriction sites in the satellite DNA of constitutive heterochromatin are not cleaved intrachromosomally, probably reflecting an inaccessibility of the BstNI sites to enzyme due to the condensed nature of this chromatin or specific DNA-protein interactions. This implies that some enzymes may induce banding related to regional differences in the accessibility of restriction sites along the chromosome. (6) Several specific nonhistone protein differences were noted in the extracted and residual chromatin following an AluI digestion. Of these, some nonhistones were primarily detected in the extracted chromatin while others were apparently resistant to extraction and located principally in the residual chromatin. (7) The chromatin in constitutive heterochromatin is transiently resistant to cleavage by micrococcal nuclease.     

The reactions of the EcoRi and other restriction endonucleases.

The reaction of the EcoRI restriction endonuclease was studied with both the plasmid pMB9 and DNA from bacteriophage lambda as the substrates. With both circular and linear DNA molecules, the only reaction catalysed by the EcoRI restriction endonuclease was the hydrolysis of the phosphodiester bond within one strand of the recognition site on the DNA duplex. The cleavage of both strands of the duplex was achieved only after two independent reactions, each involving a single-strand scission. The reactivity of the enzyme for single-strand scissions was the same for both the first and the second cleavage within its recognition site. No differences were observed between the mechanism of action on supercoiled and linear DNA substrates. Other restriction endonucleases were tested against plasmid pMB9. The HindIII restriction endonuclease cleaved DNA in the same manner as the EcoRI enzyme. However, in contrast with EcoRI, the Sa/I and the BamHI restriction endonucleases appeared to cleave both strands of the DNA duplex almost simultaneously. The function of symmetrical DNA sequences and the conformation of the DNA involved in these DNA--protein interactions are discussed in the light of these observations. The fact that the same reactions were observed on both supercoiled and linear DNA substrates implies that these interactions do not involve the unwinding of the duplex before catalysis.     

Simultaneous binding of three recognition sites is necessary for a concerted plasmid DNA cleavage by EcoRII restriction endonuclease

According to the current paradigm type IIE restriction endonucleases are homodimeric proteins that simultaneously bind to two recognition sites but cleave DNA at only one site per turnover: the other site acts as an allosteric locus, activating the enzyme to cleave DNA at the first. Structural and biochemical analysis of the archetypal type IIE restriction enzyme EcoRII suggests that it has three possible DNA binding interfaces enabling simultaneous binding of three recognition sites. To test if putative synapsis of three binding sites has any functional significance, we have studied EcoRII cleavage of plasmids containing a single, two and three recognition sites under both single turnover and steady state conditions. EcoRII displays distinct reaction patterns on different substrates: (i) it shows virtually no activity on a single site plasmid; (ii) it yields open-circular DNA form nicked at one strand as an obligatory intermediate acting on a two-site plasmid; (iii) it cleaves concertedly both DNA strands at a single site during a single turnover on a three site plasmid to yield linear DNA. Cognate oligonucleotide added in trans increases the reaction velocity and changes the reaction pattern for the EcoRII cleavage of one and two-site plasmids but has little effect on the three-site plasmid. Taken together the data indicate that EcoRII requires simultaneous binding of three rather than two recognition sites in cis to achieve concerted DNA cleavage at a single site. We show that the orthodox type IIP enzyme PspGI which is an isoschisomer of EcoRII, cleaves different plasmid substrates with equal rates. Data provided here indicate that type IIE restriction enzymes EcoRII and NaeI follow different mechanisms. We propose that other type IIE restriction enzymes may employ the mechanism suggested here for EcoRII.     

DNA duplexes containing altered sugar residues as probes of EcoRII and MvaI endonuclease interactions with sugar-phosphate backbone

Oligonucleotides containing 1-(beta-D-2'-deoxy-threo-pentofuranosyl)cytosine (dCx) and/or 1-(beta-D-2'-deoxy-threo-pentofuranosyl)thymine (dTx) in place of dC and dT residues in the EcoRII and MvaI recognition site CC(A/T)GG were synthesized in order to investigate specific recognition of the DNA sugar-phosphate backbone by EcoRII and MvaI restriction endonucleases. In 2'-deoxyxylosyl moieties of dCx and dTx, 3'-hydroxyl groups were inverted, which perturbs the related individual phosphates. Introduction of a single 2'-deoxyxylosyl moiety into a dC x dG pair resulted in a minor destabilization of double-stranded DNA structure. In the case of a dA x dT pair the effect of a 2'-deoxyxylose incorporation was much more pronounced. Multiple dCx modifications and their combination with dTx did not enhance the destabilization effect. Hydrolysis of dCx-containing DNA duplexes by EcoRII endonuclease was blocked and binding affinity was strongly depended on the location of an altered sugar. A DNA duplex containing a dTx residue was cleaved by the enzyme, but kcat/K(M) was slightly reduced. In contrast, MvaI endonuclease efficiently cleaved both types of sugar-altered substrate analogs. However it did not cleave conformationally perturbed scissile bonds, when the corresponding unmodified bonds were perfectly hydrolyzed in the same DNA duplexes. Based on these data the possible contributions of individual phosphates in the recognition site to substrate recognition and catalysis by EcoRII were proposed. We observed strikingly non-equivalent inputs for different phosphates with respect to their effect on EcoRII-DNA complex formation.     

DNA-like duplexes containing repetitive sequences. VIII. Synthesis and properties of DNA fragments--substrates of restriction endonuclease EcoRII

The optimal way of constructing a family of restriction endonuclease EcoRII substrates has been developed. The substrates are DNA-like duplexes containing regularly repeated native or modified sites of this enzyme as well as those of EcoRI and AluI. Synthesis of substrates was performed by water-soluble carbodiimide-induced polycondensation of two nonanucleotides, d(C-C-T-G-G-A-A-T-Tp) and d(C-C-A-G-G-A-G-C-Tp), as constituents of different complementary complexes. The products of reaction (degree of polymerization, 2-20) were isolated by G-200 gel-filtration. The yield of polymers was about 70%. The main products of reaction were dimers when dephosphorylated nonanucleotides (terminators of polycondensation) were used. The thermal stability of DNA-like duplexes is very high. The structure of the polymers obtained has been confirmed by UV-spectroscopy and by CD data as well as by the results of cleavage by EcoRI and AluI restriction endonucleases.     

The EcoRI restriction endonuclease with bacteriophage lambda DNA. Equilibrium binding studies.

The EcoRI restriction endonuclease was found by the filter binding technique to form stable complexes, in the absence of Mg2+, with the DNA from derivatives of bacteriophage lambda that either contain or lack EcoRI recognition sites. The amount of complex formed at different enzyme concentrations followed a hyperbolic equilibrium-binding curve with DNA molecules containing EcoRI recognition sites, but a sigmoidal equilibrium-binding curve was obtained with a DNA molecule lacking EcoRI recognition sites. The EcoRI enzyme displayed the same affinity for individual recognition sites on lambda DNA, even under conditions where it cleaves these sites at different rates. The binding of the enzyme to a DNA molecule lacking EcoRI sites was decreased by Mg2+. These observations indicate that (a) the EcoRI restriction enzyme binds preferentially to its recognition site on DNA, and that different reaction rates at different recognition sites are due to the rate of breakdown of this complex; (b) the enzyme also binds to other DNA sequences, but that two molecules of enzyme, in a different protein conformation, are involved in the formation of the complex at non-specific consequences; (c) the different affinities of the enzyme for the recognition site and for other sequences on DNA, coupled with the different protein conformations, account for the specificity of this enzyme for the cleavage of DNA at this recognition site; (d) the decrease in the affinity of the enzyme for DNA, caused by Mg2+, liberates binding energy from the DNA-protein complex that can be used in the catalytic reaction.     

Changing endonuclease EcoRII Tyr308 to Phe abolishes cleavage but not recognition: possible homology with the Int-family of recombinases.

Endonuclease EcoRII is one of a group of type II restriction enzymes, including Nael, Narl, BspMI, HpaII, and SacII, that require binding of an enhancer sequence to cleave DNA. Comparison of the EcoRII amino-acid sequence with the amino-acid consensus motifs that differentiate between recombinase families uncovered similarity between a 29 amino-acid sequence in the carboxyl end of EcoRII and the motif defining the integrase family of recombinases. This similarity implied that EcoRII tyrosine 308 should be involved in catalyzing hydrolysis of the scissile bond. Site-directed mutagenesis was used to mutate Tyr308 to Phe. The phenylalanine-substituted enzyme could not cleave T5 DNA under conditions in which wild-type enzyme completely cleaved this DNA. The Tyr308 to Phe mutation abolished cleavage activity but not specific binding to DNA. No evidence was found for the existence during the cleavage reaction of a covalent linkage between Tyr308 and DNA.     

Interaction of EcoRII endonuclease with DNA substrates containing single recognition sites.

EcoRII is unusual among type II restriction enzymes in that, while it cleaves substrates such as pBR322 and bacteriophage lambda that contain several recognition sites for the enzyme efficiently, substrates such as the genomes of bacteriophages T3 and T7 which contain a small number of recognition sites are cut poorly by it. Interestingly, pBR322, or a short DNA duplex containing a single site for the enzyme, can activate the enzyme to cleave resistant substrates. We show here that, at low concentrations, activator short duplexes are themselves cleaved poorly by the enzyme. Further, the reaction shows substrate cooperativity, and at high concentrations, the duplexes are both activators and good substrates for the enzyme. This supports the model that the activation of EcoRII involves binding of more than one DNA molecule and provides a simple system to study the mechanism of activation. Using a gel mobility shift assay, we show that the enzyme forms sequence-specific, methylation-sensitive complexes with the duplexes in the absence of activating DNA. Therefore, resistance of the short duplexes to the enzyme at low concentrations cannot be due to an inability of the enzyme to bind the duplexes. Interestingly, these complexes are stable in the presence of Mg2+, the cofactor for the enzyme, and the complexes obtained in the presence of Mg2+ do not contain DNA that is cleaved by the enzyme. The inefficient step in the action of EcoRII on resistant substrates must occur subsequent to initial substrate binding and it is this step that the activating DNA must regulate.     

The EcoRI restriction endonuclease with bacteriophage lambda DNA. Kinetic studies.

The kinetics of the reactions of the EcoRI restriction endonuclease at individual recognition sites on the DNA from bacteriophage lambda were found to differ markedly from site to site. Under certain conditions of pH and ionic strength, the rates for the cleavage of the DNA were the same at each recognition site. But under altered experimental conditions, different reaction rates were observed at each recognition site. These results are consistent with a mechanism in which the kinetic stability of the complex between the enzyme and the recognition site on the DNA differs among the sites, due to the effect of interactions between the enzyme and DNA sequences surrounding each recognition site upon the transition state of the reaction. Reactions at individual sites on a DNA molecule containing more than one recognition site were found to be independent of each other, thus excluding the possibility of a processive mechanism for the EcoRI enzyme. The consequences of these observations are discussed with regard to both DNA-protein interactions and to the application of restriction enzymes in the study of the structure of DNA molecules.