Initiation of heteroduplex-loop repair by T4-encoded endonuclease VII in vitro.

Heteroduplex DNAs with single-stranded loops of 51 nt or 8 nt were constructed in vitro and used in reactions with purified endonuclease VII (endo VII) from phage T4. The enzyme makes double-strand breaks by introducing pairs of staggered nicks flanking the loops. Regardless of loop-size the nicking sites map exclusively at the 3' side of the loop in the looping strand and at the 3' side of the base of the loop in the non-looping strand. The number of potential cleavage sites is small (less than 5) and their distribution depends on DNA sequence. The two closest staggered nicks are 4 bp apart, 2 bp on either side of the loop. Nicking always occurs in the double-stranded part of the molecules; the single-stranded loops are not attacked by endo VII. The nicks are introduced in a stepwise fashion and selection of the strand for the first nick depends on the sequence of 31 base pairs flanking the loops.     

Detection of 81 of 81 Known Mouse β-Globin Promoter Mutations with T4 Endonuclease VII—The EMC Method

The enzyme mismatch cleavage (EMC) method relies on the use of the resolvase T4 Endonuclease VII to cleave and thus detect mismatches in heteroduplex DNA formed by annealing normal DNA with mutant DNA. Detection is based on cleavage 3′ to the mismatch within a few nucleotides. We report the detection of all 81 different homozygous single-basepair changes tested and present in the mouse β-globin promoter by using the EMC method with a single set of conditions. Efficiency of cleavage was rated as strong, medium, or weak based on the intensity of the cleavage product(s) compared with background bands on autoradiography. We expect this method to detect near 100% of mutations.     

T4 endonuclease VII resolves cruciform DNA with nick and counter-nick and its activity is directed by local nucleotide sequence.

Endonuclease VII of phage T4 resolves Holliday structures in vitro by nicking pairs of strands across the junction. We report here analyses of this reaction between endonuclease VII and a Holliday structure analogue, made in vitro from synthetic oligonucleotides. The enzyme cleaves the structure in a non-concerted way and nicks each strand independently. Combinations of nicks with counter-nicks in strands across the junction resolve the construct. The specificity of the enzyme for DNA secondary structures was tested with a series of branched molecules made from oligonucleotides with the same nucleotide sequence in one strand. Results show that the number, location and relative cleavage efficiencies depend largely on the local nucleotide sequence, rather than on the branch type. In particular, endonuclease VII cleaves a complete four-armed cruciform as efficiently as a three-armed Y-junction or its derivatives, a semi-Y, a fork with two single-strand overhangs, a single-strand overhang, and a nicked DNA. However, exchange or addition of one or more nucleotides within the cleavage area flanking the structural signal for endonuclease VII strongly affects the cleavage pattern as well as their relative efficiency of usage. Examples with a single-stranded overhang are presented and show in summary that the enzyme has a fivefold preference for pyrimidines rather than purines.     

Switching base preferences of mismatch cleavage in endonuclease V: an improved method for scanning point mutations

Endonuclease V (endo V) recognizes a broad range of aberrations in DNA such as deaminated bases or mismatches. It nicks DNA at the second phosphodiester bond 3′ to a deaminated base or a mismatch. Endonuclease V obtained from Thermotoga maritima preferentially cleaves purine mismatches in certain sequence context. Endonuclease V has been combined with a high-fidelity DNA ligase to develop an enzymatic method for mutation scanning. A biochemical screening of site-directed mutants identified mutants in motifs III and IV that altered the base preferences in mismatch cleavage. Most profoundly, a single alanine substitution at Y80 position switched the enzyme to essentially a C-specific mismatch endonuclease, which recognized and cleaved A/C, C/A, T/C, C/T and even the previously refractory C/C mismatches. Y80A can also detect the G13D mutation in K-ras oncogene, an A/C mismatch embedded in a G/C rich sequence context that was previously inaccessible using the wild-type endo V. This investigation offers insights on base recognition and active site organization. Protein engineering in endo V may translate into better tools in mutation recognition and cancer mutation scanning.     

P1 nuclease cleavage is dependent on length of the mismatches in DNA

P1 nuclease is one of the most extensively used single-strand DNA specific nucleases in molecular biology. In modern biology, it is used as an enzymatic probe to detect altered DNA conformations. It is well documented that P1 cleaves single-stranded nucleic acids and single-stranded DNA regions. The fact that P1 can act under a wide range of conditions, including physiological pH and temperature make it the most commonly used enzymatic probe in DNA structural studies. Surprisingly, to this date, there is no study to characterize the influence of length of mismatches on P1 sensitivity. Using a series of radioactively labeled oligomeric DNA substrates-containing mismatches, we find that P1 nuclease cleavage is dependent on the length of mismatches. P1 does not cleave DNA when there is a single-base mismatch. P1 cleavage efficiency is optimum when mismatch length is 3 nt or more. Changing the position of the mismatches also does not make any difference in cleavage efficacy. These novel findings on P1 properties have implications for its use in DNA structure and DNA repair studies.     

Resolution of Holliday junction analogs by T4 endonuclease VII can be directed by substrate structure

Endonuclease VII is an enzyme from bacteriophage T4 capable of resolving four-arm Holliday junction intermediates in recombination. Since natural Holliday junctions have homologous (2-fold) sequence symmetry, they can branch migrate, creating a population of substrates that have the branch point at different sites. We have explored the substrate requirements of endonuclease VII by using immobile analogs of Holliday junctions that lack this homology, thereby situating the branch point at a fixed site in the molecule. We have found that immobile junctions whose double-helical arms contain fewer than nine nucleotide pairs do not serve as substrates for resolution by endonuclease VII. Scission of substrates with 2-fold symmetrically elongated arms produces resolution products that are a function of the particular arms that are lengthened. We have confirmed that the scission products are those of resolution, rather than nicking of individual strands, by using shamrock junction molecules formed from a single oligonucleotide strand. A combination of end-labeled and internally labeled shamrock molecules has been used to demonstrate that all of the scission is due to coordinated cleavage of DNA on opposite sides of the junction, 3' to the branch point. Endonuclease VII is known to cleave the crossover strands of Holliday junctions in this fashion. The relationship of the long arms to the cleavage direction suggests that the portion of the enzyme which requires the minimum arm length interacts with the pair of arms containing the 3' portion of the crossover strands on the bound surface of the antiparallel junction.     

Hydration at the TD Damaged Site of DNA and its Role in the Formation of Complex with T4 Endonuclease V

Abstract

An analysis of the distribution of water around DNA surface focusing on the role of the distribution of water molecules in the proper recognition of damaged site by repair enzyme T4 Endonuclease V was performed. The native DNA dodecamer, dodecamer with the thymine dimer (TD) and complex of DNA and part of repair enzyme T4 Endonuclease V were examined throughout the 500 ps of molecular dynamics simulation. During simulation the number of water molecules close to the DNA atoms and the residence time were calculated. There is an increase in number of water molecules lying in the close vicinity to TD if compared with those lying close to two native thymines (TT). Densely populated area with water molecules around TD is one of the factors detected by enzyme during scanning process. The residence time was found higher for molecule of the complex and the six water molecules were found occupying the stabile positions between the TD and catalytic center close to atoms P, C3′ and N3. These molecules originate water mediated hydrogen bond network that contribute to the stability of complex required for the onset of repair process.     

Bacterial DNA topoisomerase I can relax positively supercoiled DNA containing a single-stranded loop

Using heteroduplex molecules formed from a pair of plasmids, one of which contains a small deletion relative to the other, it is shown that bacterial topoisomerase I can relax a positively supercoiled DNA if a short single-stranded loop is placed in the DNA. This result supports the postulate that the specificity of bacterial DNA topoisomerase I for negatively supercoiled DNA in its relaxation reaction derives from the requirement of a short single-stranded DNA segment in the active enzyme-substrate complex. Nucleolytic and chemical probing of complexes between bacterial DNA topoisomerase I and heteroduplex DNA molecules containing single-stranded loops ranging from 13 to 27 nucleotides in length suggests that the enzyme binds specifically to the region containing a single-stranded loop; the site of DNA cleavage by the topoisomerase appears to lie within the single-stranded loop, with the enzyme interacting with nucleotides on both sides of the point of cleavage.     

Biochemical analysis of the substrate specificity and sequence preference of endonuclease IV from bacteriophage T4, a dC-specific endonuclease implicated in restriction of dC-substituted T4 DNA synthesis

Endonuclease IV encoded by denB of bacteriophage T4 is implicated in restriction of deoxycytidine (dC)-containing DNA in the host Escherichia coli. The enzyme was synthesized with the use of a wheat germ cell-free protein synthesis system, given a lethal effect of its expression in E.coli cells, and was purified to homogeneity. The purified enzyme showed high activity with single-stranded (ss) DNA and denatured dC-substituted T4 genomic double-stranded (ds) DNA but exhibited no activity with dsDNA, ssRNA or denatured T4 genomic dsDNA containing glucosylated deoxyhydroxymethylcytidine. Characterization of Endo IV activity revealed that the enzyme catalyzed specific endonucleolytic cleavage of the 5′ phosphodiester bond of dC in ssDNA with an efficiency markedly dependent on the surrounding nucleotide sequence. The enzyme preferentially targeted 5′-dTdCdA-3′ but tolerated various combinations of individual nucleotides flanking this trinucleotide sequence. These results suggest that Endo IV preferentially recognizes short nucleotide sequences containing 5′-dTdCdA-3′, which likely accounts for the limited digestion of ssDNA by the enzyme and may be responsible in part for the indispensability of a deficiency in denB for stable synthesis of dC-substituted T4 genomic DNA.     

Recognition of single-stranded DNA by the bacteriophage T4-induced type II topoisomerase

The bacteriophage T4-induced type II DNA topoisomerase has been shown previously to make a reversible double strand break in DNA double helices. In addition, this enzyme is shown here to bind tightly and to cleave single-stranded DNA molecules. The evidence that the single-stranded DNA cleavage activity is intrinsic to the topoisomerase includes: 1) protein linkage to the 5' ends of the newly cleaved DNA; 2) coelution of essentially homogeneous topoisomerase and the DNA cleavage activity; 3) inhibition of both single-stranded DNA cleavage and double-stranded DNA relaxation by oxolinic acid; and 4) inhibition of duplex DNA relaxation by single-stranded DNA. The major cleavage sites on phi X174 viral DNA substrates have been mapped, and several cleavage sites analyzed to determine the exact nucleotide position of cleavage. Major cleavage sites are found very near the base of predicted hairpin helices in the single-stranded DNA substrates, suggesting that DNA secondary structure recognition is important in the cleavage reaction. On the other hand, there are also many weaker cleavage sites with no obvious sequence requirements. Many of the properties of the single-stranded DNA cleavage reaction examined here differ from those of the oxolinic acid-dependent, double-stranded DNA cleavage reaction catalyzed by the same enzyme.     

Endonuclease VII has two DNA-binding sites each composed from one N- and one C-terminus provided by different subunits of the protein dimer.

Endonuclease VII (endo VII) is a Holliday structure-resolving enzyme of bacteriophage T4. Its activity depends on dimerization, DNA binding and hydrolysis of two phosphodiester bonds flanking the Holliday junction. We analysed the DNA-binding activity of truncated monomeric and covalently linked dimeric endo VII proteins. We show that both ends of endo VII are involved in DNA binding. In particular, the C-terminus of one subunit interacts with the N-terminus of the other subunit, constituting one DNA-binding site; the other two termini form the second binding site of the dimer. One binding site is sufficient to bind cruciform DNA. The concerted mechanism involving termini from different subunits ensures that only dimers bind to Holliday structures, thus providing two catalytic centres which introduce two cleavages in opposite strands. This is a precondition for precise resolution of Holliday structures.     

The Ser176 of T4 endonuclease IV is crucial for the restricted and polarized dC-specific cleavage of single-stranded DNA implicated in restriction of dC-containing DNA in host Escherichia coli

Endonuclease (Endo) IV encoded by denB of bacteriophage T4 is an enzyme that cleaves single-stranded (ss) DNA in a dC-specific manner. Also the growth of dC-substituted T4 phage and host Escherichia coli cells is inhibited by denB expression presumably because of the inhibitory effect on replication of dC-containing DNA. Recently, we have demonstrated that an efficient cleavage by Endo IV occurs exclusively at the 5′-proximal dC (dC₁) within a hexameric or an extended sequence consisting of dC residues at the 5′-proximal and the 3′-proximal positions (dCs tract), in which a third dC residue within the tract affects the polarized cleavage and cleavage rate. Here we isolate and characterize two denB mutants, denB(W88R) and denB(S176N). Both mutant alleles have lost the detrimental effect on the host cell. Endo IV(W88R) shows no enzymatic activity (<0.4% of that of wild-type Endo IV). On the other hand, Endo IV(S176N) retains cleavage activity (17.5% of that of wild-type Endo IV), but has lost the polarized and restricted cleavage of a dCs tract, indicating that the Ser¹⁷⁶ residue of Endo IV is implicated in the polarized cleavage of a dCs tract which brings about a detrimental effect on the replication of dC-containing DNA.     

Recognition of GT mismatches by Vsr mismatch endonuclease

The Vsr mismatch endonuclease recognises the sequence CTWGG (W = A or T) in which the underlined thymine is paired with guanine and nicks the DNA backbone on the 5'-side of the mispaired thymine. By using base analogues of G and T we have explored the functional groups on the mismatch pair which are recognised by the enzyme. Removal of the thymine 5-methyl group causes a 60% reduction in activity, while removing the 2-amino group of guanine reduces cleavage by 90%. Placing 2-amino-purine or nebularine opposite T generates mis-matches which are cut at a much lower rate (0.1%). When either base is removed, generating a pseudoabasic site (1', 2'-dideoxyribose), the enzyme still produces site-specific cleavage, but at only 1% of the original rate. Although TT and CT mismatches at this position are cleaved at a low rate (approximately 1%), mismatches with other bases (such as GA and AC) and Watson-Crick base pairs are not cleaved by the enzyme. There is also no cleavage when the mismatched T is replaced with difluorotoluene.     

A hexanucleotide sequence (dC1-dC6 tract) restricts the dC-specific cleavage of single-stranded DNA by endonuclease IV of bacteriophage T4

Endonuclease (Endo) IV encoded by denB of bacteriophage T4 is an enzyme that cleaves single-stranded (ss) DNA in a dC-specific manner. Previously we have demonstrated that a dTdCdA is most preferable for Endo IV when an oligonucleotide substrate having a single dC residue is used. Here we demonstrate that Endo IV cleaves ssDNAs exclusively at the 5′-proximal dC where a sequence comprises dC residues both at the 5′ proximal and 3′ proximal positions (a dCs tract-dependent cleavage). The dCs tract-dependent cleavage is efficient and occurs when a dCs tract has at least 6 bases. Some dCs tracts larger than 6 bases behave as that of 6 bases (an extended dCs tract), while some others do not. One decameric dCs tract was shown to be cleavable in a dCs tract-dependent manner, but that with 13 dCs was not. The dCs tract-dependent cleavage is enhanced by the presence of a third dC residue at least for a 6 or 7 dCs tract. In contrast to the dCs tract-dependent cleavage, a dCs tract-independent one is generally inefficient and if two modes are possible for a substrate DNA, a dCs tract-dependent mode prevails. A model for the dCs tract-dependent cleavage is proposed.     

Specificity of the S1 nuclease from Aspergillus oryzae.

Conditions are described for digesting single-stranded DNA by S1 nuclease without introducing breaks in double-stranded DNA. The enzyme is inhibited by low concentrations of various compounds of phosphate. Under certain conditions S1 nuclease cleaves the strand opposite a nick in bacteriophage T5 DNA; under other conditions, the enzyme cleaves a loop in one strand of heteroduplex lambdaDNA while leaving the opposite strand intact. S1 nuclease makes many single strand breaks in ultraviolet-irradiated duplex lambdaDNA. Superhelical DNA of phiX174 (Form I) is converted first to a relaxed circular molecule (Form II), and then to a linear molecule (Form III) by cleavage at one site per molecule. Since the cleavage occurs at many sites in the population of molecules, the partially single-stranded regions in phiX174 superhelical DNA are not determined by specific nucleotide sequences.     

Purification of the T4 endonuclease V

A new purification protocol has been developed for the rapid isolation to physical homogeneity of T4 endonuclease V. The enzyme was purified from an Escherichia coli strain which harbors a plasmid containing the T4 denV structural gene downstream of the lambda rightward promoter. The purification of the enzyme was monitored by pyrimidine dimer-specific nicking activity, Western blot analysis and silver or Coomassie Blue staining of SDS-polyacrylamide gels. Milligram quantities of the enzyme have been purified by the following procedure. After sonication of cells and removal of major cell debris, total protein and nucleic acids were passed over a single-stranded DNA agarose column. Endonuclease V was eluted at 650 mM KCl with a linear salt gradient yielding enzyme of approximately 20% purity and following dialysis, was applied to a chromatofocusing column. The enzyme elutes at pH 9.4 and is greater than 90% homogeneous at this step. The final purification step is CM-Sephadex chromatography which attains greater than 98% homogeneity.     

Recognition sites of eukaryotic DNA topoisomerase I: DNA nucleotide sequencing analysis of topo I cleavage sites on SV40 DNA.

Eukaryotic DNA topoisomerase I introduces transient single-stranded breaks on double-stranded DNA and spontaneously breaks down single-stranded DNA. The cleavage sites on both single and double-stranded SV40 DNA have been determined by DNA sequencing. Consistent with other reports, the eukaryotic enzymes, in contrast to prokaryotic type I topoisomerases, links to the 3'-end of the cleaved DNA and generates a free 5'-hydroxyl end on the other half of the broken DNA strand. Both human and calf enzymes cleave SV40 DNA at the identical and specific sites. From 827 nucleotides sequenced, 68 cleavage sites were mapped. The majority of the cleavage sites were present on both double and single-stranded DNA at exactly the same nucleotide positions, suggesting that the DNA sequence is essential for enzyme recognition. By analyzing all the cleavage sequences, certain nucleotides are found to be less favored at the cleavage sites. There is a high probability to exclude G from positions -4, -2, -1 and +1, T from position -3, and A from position -1. These five positions (-4 to +1 oriented in the 5' to 3' direction) around the cleavage sites must interact intimately with topo I and thus are essential for enzyme recognition. One topo I cleavage site which shows atypical cleavage sequence maps in the middle of a palindromic sequence near the origin of SV40 DNA replication. It occurs only on single-stranded SV40 DNA, suggesting that the DNA hairpin can alter the cleavage specificity. The strongest cleavage site maps near the origin of SV40 DNA replication at nucleotide 31-32 and has a pentanucleotide sequence of 5'-TGACT-3'.     

Conversion of the FokI endonuclease to a universal restriction enzyme: cleavage of phage M13mp7 DNA at predetermined sites

Endonuclease FokI belongs to class IIS of restriction enzymes, for which the DNA cut points lie outside the enzyme-recognition sites. This permitted conferring new cleavage specificities by combining FokI with tailored oligodeoxynucleotide adapters. Such adapters carry a single-stranded (ss) target-recognition domain, complementary to the selected ss target DNA, and a double-stranded (ds) enzyme-recognition site. Neither enzyme nor adapter alone has endonucleolytic activity toward phage M13mp7 ss DNA, whereas the enzymeadapter complex cleaves this ss target DNA at the particular sites foreordained by the sequence of the ss domain of the adapter. Two kinds of adapters (32 and 34 nucleotides long), with opposing orientations of the asymmetric FokI recognition site, were constructed and shown to direct specific cleavage under a variety of conditions. In addition to FokI, other class IIS enzymes, HphI, MboII and BbvI, which alone do not cleave ss DNA, are suitable for construction of tailored enzyme-adapter complexes with predictable cleavage specificities.

This report provides a preliminary experimental confirmation for the proposal of Szybalski [Gene 40 (1985) 169-173] for the design of adapter-enzyme complexes with novel and predictable specificities. Theoretically, using this approach any sequence could be precisely cleaved at a predetermined point.     

Multiple cleavage activities of endonuclease V from Thermotoga maritima: recognition and strand nicking mechanism

Endonuclease V is a deoxyinosine 3'-endonuclease which initiates removal of inosine from damaged DNA. A thermostable endonuclease V from the hyperthermophilic bacterium Thermotoga maritima has been cloned and expressed in Escherichia coli. The DNA recognition and reaction mechanisms were probed with both double-stranded and single-stranded oligonucleotide substrates which contained inosine, abasic site (AP site), uracil, or mismatches. Gel mobility shift and kinetic analyses indicate that the enzyme remains bound to the cleaved inosine product. This slow product release may be required in vivo to ensure an orderly process of repairing deaminated DNA. When the enzyme is in excess, the primary nicked products experience a second nicking event on the complementary strand, leading to a double-stranded break. Cleavage at AP sites suggests that the enzyme may use a combination of base contacts and local distortion for recognition. The weak binding to uracil sites may preclude the enzyme from playing a significant role in repair of such sites, which may be occupied by uracil-specific DNA glycosylases. Analysis of cleavage patterns of all 12 natural mismatched base pairs suggests that purine bases are preferrentially cleaved, showing a general hierarchy of A = G > T > C. A model accounting for the recognition and strand nicking mechanism of endonuclease V is presented.