Purification and properties of 2-aminoadipate: 2-oxoglutarate aminotransferase from bovine kidney.

Escherichia coli endonuclease IV hydrolyses the C(3')-O-P bond 5' to a 3'-terminal base-free deoxyribose. It also hydrolyses the C(3')-O-P bond 5' to a 3'-terminal base-free 2',3'-unsaturated sugar produced by nicking 3' to an AP (apurinic or apyrimidinic) site by beta-elimination; this explains why the unproductive end produced by beta-elimination is converted by the enzyme into a 3'-OH end able to prime DNA synthesis. The action of E. coli endonuclease IV on an internal AP site is more complex: in a first step the C(3')-O-P bond 5' to the AP site is hydrolysed, but in a second step the 5'-terminal base-free deoxyribose 5'-phosphate is lost. This loss is due to a spontaneous beta-elimination reaction in which the enzyme plays no role. The extreme lability of the C(3')-O-P bond 3' to a 5'-terminal AP site contrasts with the relative stability of the same bond 3' to an internal AP site; in the absence of beta-elimination catalysts, at 37 degrees C the half-life of the former is about 2 h and that of the latter 200 h. The extreme lability of a 5'-terminal AP site means that, after nicking 5' to an AP site with an AP endonuclease, in principle no 5'----3' exonuclease is needed to excise the AP site: it falls off spontaneously. We have repaired DNA containing AP sites with an AP endonuclease (E. coli endonuclease IV or the chromatin AP endonuclease from rat liver), a DNA polymerase devoid of 5'----3' exonuclease activity (Klenow polymerase or rat liver DNA polymerase beta) and a DNA ligase. Catalysts of beta-elimination, such as spermine, can drastically shorten the already brief half-life of a 5'-terminal AP site; it is what very probably happens in the chromatin of eukaryotic cells. E. coli endonuclease IV also probably participates in the repair of strand breaks produced by ionizing radiations: as E. coli endonuclease VI/exonuclease III, it is a 3'-phosphoglycollatase and also a 3'-phosphatase. The 3'-phosphatase activity of E. coli endonuclease VI/exonuclease III and E. coli endonuclease IV can also be useful when the AP site has been excised by a beta delta-elimination reaction.     

Interaction of T4 endonuclease V with DNA: importance of the flexible loop regions in protein-DNA interaction

T4 endonuclease V (T4 endo V), a thymine dimer-specific DNA repair enzyme, and its interaction with DNA were investigated by nuclear magnetic resonance (NMR) spectroscopy. Backbone resonance assignment, chemical shift mapping, and 15N relaxation measurements were employed to the free and DNA-bound enzymes. The secondary structure and the tertiary fold of T4 endo V in solution were consistent with those from the crystallographic study. The backbone 1H and 15N chemical shift perturbation upon the addition of DNA without a lesion revealed that the residues including Arg3, Arg22-Arg26, Lys45-Phe60, and Lys86-Thr88 participate in DNA binding. However, when DNA with a lesion was added to the enzyme and concomitantly the catalytic reaction was completed, the resonances of Arg22, Glu23, and Arg26, which constitute the catalytic active site, and the resonance of Thr88, were perturbed in a different manner. The region around Lys45-Ser47 was found to be involved in DNA binding, which have not been reported elsewhere. The backbone relaxation measurements of the free and DNA-bound enzymes indicated that two loop regions, Lys45-Phe60 and Lys86-Asp92, show the high degree of backbone flexibility. These results imply that two flexible loop regions may play an important role in DNA binding and in scanning along DNA duplex to search the thymine dimer sites in UV-damaged DNA.     

Conversion of the bifunctional 8-oxoguanine/beta-delta apurinic/apyrimidinic DNA repair activities of Drosophila ribosomal protein S3 into the human S3 monofunctional beta-elimination catalyst through a single amino acid change

The Drosophila S3 ribosomal protein has important roles in both protein translation and DNA repair. In regards to the latter activity, it has been shown that S3 contains vigorous N-glycosylase activity for the removal of 8-oxoguanine residues in DNA that leaves baseless sites in their places. Drosophila S3 also possesses an apurinic/apyrimidinic (AP) lyase activity in which the enzyme catalyzes a beta-elimination reaction that cleaves phosphodiester bonds 3' and adjacent to an AP lesion in DNA. In certain situations, this is followed by a delta-elimination reaction that ultimately leads to the formation of a single nucleotide gap in DNA bordered by 5'- and 3'-phosphate groups. The human S3 protein, although 80% identical to its Drosophila homolog and shorter by only two amino acids, has only marginal N-glycosylase activity. Its lyase activity only cleaves AP DNA by a beta-elimination reaction, thus further distinguishing itself from the Drosophila S3 protein in lacking a delta-elimination activity. Using a hidden Markov model analysis based on the crystal structures of several DNA repair proteins, the enzymatic differences between Drosophila and human S3 were suggested by the absence of a conserved glutamine residue in human S3 that usually resides at the cleft of the deduced active site pocket of DNA glycosylases. Here we show that the replacement of the Drosophila glutamine by an alanine residue leads to the complete loss of glycosylase activity. Unexpectedly, the delta-elimination reaction at AP sites was also abrogated by a change in the Drosophila glutamine residue. Thus, a single amino acid change converted the Drosophila activity into one that is similar to that possessed by the human S3 protein. In support of this were experiments executed in vivo that showed that human S3 and the Drosophila site-directed glutamine-changed S3 performed poorly when compared with Drosophila wild-type S3 and its ability to protect a bacterial mutant from the harmful effects of DNA-damaging agents.     

The DNA scanning mechanism of T4 endonuclease V. Effect of NaCl concentration on processive nicking activity

T4 endonuclease V is a pyrimidine dimer-specific endonuclease which generates incisions in DNA at the sites of pyrimidine dimers by a processive reaction mechanism. A model is presented in which the degree of processivity is directly related to the efficacy of the one-dimensional diffusion of endonuclease V on DNA by which the enzyme locates pyrimidine dimers. The modulation of the processive nicking activity of T4 endonuclease V on superhelical covalently closed circular DNA (form I) which contains pyrimidine dimers has been investigated as a function of the ionic strength of the reaction. Agarose gel electrophoresis was used to separate the three topological forms of the DNA which were generated in time course reactions of endonuclease V with dimer-containing form I DNA in the absence of NaCl, and in 25, 50, and 100 mM NaCl. The degree of processivity was evaluated in terms of the mass fraction of form III (linear) DNA which was produced as a function of the fraction of form I DNA remaining. Processivity is maximal in the absence of NaCl and decreases as the NaCl concentration is increased. At 100 mM NaCl, processivity is abolished and endonuclease V generates incisions in DNA at the site of dimers by a distributive reaction mechanism. The change from the distributive to a processive reaction mechanism occurs at NaCl concentrations slightly below 50 mM. The high degree of processivity which is observed in the absence of NaCl is reversible to the distributive mechanism, as demonstrated by experiments in which the NaCl concentration was increased during the time course reaction. In addition, unirradiated DNA inhibited the incision of irradiated DNA only at NaCl concentrations at which processivity was observed.     

Stereochemical studies of the beta-elimination reactions at aldehydic abasic sites in DNA: endonuclease III from Escherichia coli, sodium hydroxide, and Lys-Trp-Lys.

The DNA strand cleavage reaction catalyzed by endonuclease III from Escherichia coli (endo III) on the 3'-side of aldehyde abasic sites proceeds by a syn beta-elimination involving abstraction of the 2'-pro-S proton and formation of a trans alpha,beta-unsaturated aldose product; we previously reported the same stereochemical course for the reaction catalyzed by UV endonuclease V from bacteriophage T4 (UV endo V) [Mazumder, A., Gerlt, J. A., Rabow, L., Absalon, M. J., Stubbe, J., & Bolton, P. H. (1989) J. Am. Chem. Soc. 111, 8029-8030]. Since the UV endo V does not contain an 4Fe-4S center, the 4Fe-4S center present in endo III need not be assigned a unique role in the beta-elimination reaction. The beta-elimination reactions that occur under alkaline conditions (0.1 N NaOH) and in the presence of the tripeptide Lys-Trp-Lys proceed by anti beta-elimination mechanisms involving abstraction of the 2'-pro-R proton and formation of a trans alpha,beta-unsaturated aldose product. The different stereochemical outcomes of the enzymatic and nonenzymatic beta-elimination reactions support the hypothesis that the enzyme-catalyzed reactions may involve general-base-catalyzed abstraction of the 2'-pro-S proton by the internucleotidic phosphodiester leaving group.     

Possible roles of beta-elimination and delta-elimination reactions in the repair of DNA containing AP (apurinic/apyrimidinic) sites in mammalian cells.

Histones and polyamines nick the phosphodiester bond 3' to AP (apurinic/apyrimidinic) sites in DNA by inducing a beta-elimination reaction, which can be followed by delta-elimination. These beta- and delta-elimination reactions might be important for the repair of AP sites in chromatin DNA in either of two ways. In one pathway, after the phosphodiester bond 5' to the AP site has been hydrolysed with an AP endonuclease, the 5'-terminal base-free sugar 5'-phosphate is released by beta-elimination. The one-nucleotide gap limited by 3'-OH and 5'-phosphate ends is then closed by DNA polymerase-beta and DNA ligase. We have shown in vitro that such a repair is possible. In the other pathway, the nicking 3' to the AP site by beta-elimination occurs first. We have shown that the 3'-terminal base-free sugar so produced cannot be released by the chromatin AP endonuclease from rat liver. But it can be released by delta-elimination, leaving a gap limited by 3'-phosphate and 5'-phosphate. After conversion of the 3'-phosphate into a 3'-OH group by the chromatin 3'-phosphatase, there will be the same one-nucleotide gap, limited by 3'-OH and 5'-phosphate, as that formed by the successive actions of the AP endonuclease and the beta-elimination catalyst in the first pathway.     

Methanobacterium thermoformicicum thymine DNA mismatch glycosylase: conversion of an N-glycosylase to an AP lyase.

The thymine DNA mismatch glycosylase from Methanobacterium thermoformicicum, a member of the endonuclease III family of repair proteins, excises the pyrimidine base from T-G and U-G mismatches. Unlike endonuclease III, it does not cleave the phosphodiester backbone by a beta-elimination reaction. This cleavage event has been attributed to a nucleophilic attack by the conserved Lys120 of endonuclease III on the aldehyde group at C1' of the deoxyribose and subsequent Schiff base formation. The inability of TDG to perform this beta-elimination event appears to be due to the presence of a tyrosine residue at the position equivalent to Lys120 in endonuclease III. The purpose of this work was to investigate the requirements for AP lyase activity. We replaced Tyr126 in TDG with a lysine residue to determine if this replacement would yield an enzyme with an associated AP lyase activity capable of removing a mismatched pyrimidine. We observed that this replacement abolishes the glycosylase activity of TDG but does not affect substrate recognition. It does, however, convert the enzyme into an AP lyase. Chemical trapping assays show that this cleavage proceeds through a Schiff base intermediate and suggest that the amino acid at position 126 interacts with C1' on the deoxyribose sugar.     

T4 endonuclease V exists in solution as a monomer and binds to target sites as a monomer

Endonuclease V, a N-glycosylase/lyase from T4 bacteriophage that initiates the repair of cyclobutane pyrimidine dimers in DNA, has been reported to form a monomer-dimer equilibrium in solution [Nickell and Lloyd (1991) Biochemistry 30, 8638], although the enzyme has only been crystallized in the absence of substrate as a monomer [Morikawa et al. (1992) Science 256, 523]. In this study, analytical gel filtration and sedimentation equilibrium techniques were used to rigorously characterize the association state of the enzyme in solution. In contrast to the previous report, at 100 mM KCl endonuclease V was found to exist predominantly as a monomer in solution by both of these techniques; no evidence for dimerization was seen. To characterize the oligomeric state of the enzyme at its target sites on DNA, the enzyme was bound to oligonucleotides containing a single site specific pyrimidine dimer or tetrahydrofuran residue. These complexes were analyzed by nondenaturing gel electrophoresis at various acrylamide concentrations in order to determine the molecular weights of the enzyme-DNA complexes. The results from these experiments demonstrate that endonuclease V binds to cyclobutane pyrimidine dimer and tetrahydrofuran site containing DNA as a monomer.     

Reaction intermediates in the catalytic mechanism of Escherichia coli MutY DNA glycosylase

The Escherichia coli adenine DNA glycosylase, MutY, plays an important role in the maintenance of genomic stability by catalyzing the removal of adenine opposite 8-oxo-7,8-dihydroguanine or guanine in duplex DNA. Although the x-ray crystal structure of the catalytic domain of MutY revealed a mechanism for catalysis of the glycosyl bond, it appeared that several opportunistically positioned lysine side chains could participate in a secondary beta-elimination reaction. In this investigation, it is established via site-directed mutagenesis and the determination of a 1.35-A structure of MutY in complex with adenine that the abasic site (apurinic/apyrimidinic) lyase activity is alternatively regulated by two lysines, Lys142 and Lys20. Analyses of the crystallographic structure also suggest a role for Glu161 in the apurinic/apyrimidinic lyase chemistry. The beta-elimination reaction is structurally and chemically uncoupled from the initial glycosyl bond scission, indicating that this reaction occurs as a consequence of active site plasticity and slow dissociation of the product complex. MutY with either the K142A or K20A mutation still catalyzes beta and beta-delta elimination reactions, and both mutants can be trapped as covalent enzyme-DNA intermediates by chemical reduction. The trapping was observed to occur both pre- and post-phosphodiester bond scission, establishing that both of these intermediates have significant half-lives. Thus, the final spectrum of DNA products generated reflects the outcome of a delicate balance of closely related equilibrium constants.     

AP lyases and dRPases: commonality of mechanism

Enzymes that release 5'-deoxyribose-5-phosphate (dRP) residues from preincised apurinic/apyrimidinic (AP) DNA have been collectively termed DNA deoxyribophosphodiesterases (dRPases), but they fall into two distinct categories: the hydrolytic dRPases and AP lyases. In order to resolve a number of conflicting reports in the dRPase literature, we examined two putative hydrolytic dRPases (Escherichia coli exonuclease I (exo I) and RecJ) and four AP lyases (E. coli 2, 6-dihydroxy-5N-formamidopyrimidine (Fapy) DNA glycosylase (Fpg) and endonuclease III (endo III), bacteriophage T4 endonuclease V (endo V), and rat polymerase beta (beta-pol)) for their abilities to (i) excise dRP from preincised AP DNA and (ii) incise AP DNA. Although exo I and RecJ exhibited robust 3' to 5' and 5' to 3' exonucleolytic activities, respectively, on appropriate substrates, they failed to demonstrate detectable dRPase activity. All four AP lyases possessed both dRPase and traditional AP lyase activities, albeit to varying degrees. Moreover, as best illustrated with Fpg, AP lyase enzymes could be trapped on both preincised and unincised AP DNA using NaBH(4) as the reducing agent. These results further support the assertion that the catalytic mechanism of the AP lyases, the beta-elimination reaction, does proceed through an imine enzyme-DNA intermediate and that the active site residues responsible for dRP release must contain primary amines. Further, these data indicate a biological significance for the beta-elimination reaction of DNA glycosylase/AP lyases in that they, in concert with hydrolytic AP endonucleases, can create appropriate gapped substrates for short patch base excision repair (BER) synthesis to occur efficiently.     

Mutation at active site lysine 212 to arginine uncouples the glycosylase activity from the lyase activity of human endonuclease III.

The human endonuclease III (hNTH1) is an important DNA glycosylase with associated abasic lyase activity. We previously demonstrated that the K212Q mutant was totally inactive, while the K212R mutant had reduced DNA glycosylase/lyase activity and could form a covalent complex with the substrate DNA upon reduction. We further characterized the biochemical properties of this K212R mutant protein. NH2- (N-) terminal sequencing in combination with mass spectrometry of the peptide-DNA adduct suggested that "opportunistic" lysine(s) in the lysine-rich N-terminal tail formed a Schiff base which might result in beta-elimination. However, simultaneous substitution of Lys-75 with Gln and deletion of first 72 residues in the N-terminal tail could not cause further alteration in the glycosylase reaction or beta-elimination event. Nonetheless, the time kinetics of K212R and its subsequent mutants showed glycosylase activity without any detectable AP-lyase activity during the first 10 min of the reaction. These results suggest that a single point mutation at the active site (K212R) uncoupled the glycosylase activity from the lyase activity. We propose that the uncoupled reaction carried out by K212R is a result of direct attack either by the nonionized form of the guanidino group of arginine which forms an unstable Schiff base that hydrolyzes prior to the beta-elimination event or by hydroxide ion to cleave the glycosylic bond. In either case this reaction is followed by a secondary beta-elimination event performed by random lysine residues primarily from the N-terminal tail region.     

Action of human endonucleases III and VIII upon DNA-containing tandem dihydrouracil

We have shown previously that endonuclease III from Escherichia coli, its yeast homolog Ntg1p and E. coli endonuclease VIII recognize single dihydrouracil (DHU) lesions efficiently. However, these enzymes have limited capacities for completely removing DHU, when the lesion is present on duplex DNA as a tandem lesion. A duplex 30-mer (duplex1920) containing tandem DHU lesions at positions 19 and 20 from the 5' terminus was used as a substrate for human endonuclease III (hNTH) and endonuclease VIII (NEIL1). Two cleavage products, 18beta and 19beta were formed, when duplex1920 was treated with hNTH. The 18beta corresponded to the expected beta-elimination product generated from duplex1920, when the 5'-DHU of the tandem DHU was processed by hNTH. Similarly, 19beta is the beta-elimination product generated, when the 3'-DHU of the tandem DHU was processed by hNTH; 19beta thus still contained a DHU lesion at the 3' terminus. When these hNTH reaction products were further treated with human APE1, a single new product that corresponded to an 18mer was observed. These data suggested that human APE1 can help to process the 3' terminals following the action of hNTH on DHU lesions. Similarly, when duplex1920 was treated with NEIL1, two cleavage products, 18p and 19p were observed. The 18p and 19p corresponded to the expected beta,delta-elimination products derived from NEIL1 induced cleavage at the 5'-DHU and 3'-DHU of the tandem DHU, respectively. The 3'-phosphoryl group present in 18p can be readily removed by T4 polynucleotide kinase (PNK) to yield an 18mer that is suitable for repair synthesis. However, 19p required the participation of both PNK and APE1 to generate the 18mer. Together, we suggest that the processing of DNA-containing tandem DHU lesions, initiated by hNTH and NEIL1 can be channeled into two sub-pathways, the PNK-independent, APE1-dependent and the PNK, APE1-dependent pathways, respectively.     

The function of Asp70, Glu77 and Lys79 in the Escherichia coli MutH protein

The MutH protein, which is part of the Dam-directed mismatch repair system of Escherichia coli, introduces nicks in the unmethylated strand of a hemi-methylated DNA duplex. The latent endonuclease activity of MutH is activated by interaction with MutL, another member of the repair system. The crystal structure of MutH suggested that the active site residues include Asp70, Glu77 and Lys79, which are located at the bottom of a cleft where DNA binding probably occurs. We mutated these residues to alanines and found that the mutant proteins were unable to complement a chromosomal mutH deletion. The purified mutant proteins were able to bind to DNA with a hemi-methylated GATC sequence but had no detectable endonuclease activity with or without MutL. Although the data are consistent with the prediction of a catalytic role for Asp70, Glu77 and Lys79, it cannot be excluded that they are also involved in binding to MutL.     

Escherichia coli endonuclease III is not an endonuclease but a beta-elimination catalyst.

The oligonucleotide [5'-32P]pdT8d(-)dTn, containing an apurinic/apyrimidinic (AP) site [d(-)], yields three radioactive products when incubated at alkaline pH: two of them, forming a doublet approximately at the level of pdT8dA when analysed by polyacrylamide-gel electrophoresis, are the result of the beta-elimination reaction, whereas the third is pdT8p resulting from beta delta-elimination. The incubation of [5'-32P]pdT8d(-)dTn, hybridized with poly(dA), with E. coli endonuclease III yields two radioactive products which have the same electrophoretic behaviour as the doublet obtained by alkaline beta-elimination. The oligonucleotide pdT8d(-) is degraded by the 3'-5' exonuclease activity of T4 DNA polymerase as well as pdT8dA, showing that a base-free deoxyribose at the 3' end is not an obstacle for this activity. The radioactive products from [5'-32P]pdT8d(-)dTn cleaved by alkaline beta-elimination or by E. coli endonuclease III are not degraded by the 3'-5' exonuclease activity of T4 DNA polymerase. When DNA containing AP sites labelled with 32P 5' to the base-free deoxyribose labelled with 3H in the 1' and 2' positions is degraded by E. coli endonuclease VI (exonuclease III) and snake venom phosphodiesterase, the two radionuclides are found exclusively in deoxyribose 5-phosphate and the 3H/32P ratio in this sugar phosphate is the same as in the substrate DNA. When DNA containing these doubly-labelled AP sites is degraded by alkaline treatment or with Lys-Trp-Lys, followed by E. coli endonuclease VI (exonuclease III), some 3H is found in a volatile compound (probably 3H2O) whereas the 3H/32P ratio is decreased in the resulting sugar phosphate which has a chromatographic behaviour different from that of deoxyribose 5-phosphate. Treatment of the DNA containing doubly-labelled AP sites with E. coli endonuclease III, then with E. coli endonuclease VI (exonuclease III), also results in the loss of 3H and the formation of a sugar phosphate with a lower 3H/32P ratio that behaves chromatographically as the beta-elimination product digested with E. coli endonuclease VI (exonuclease III). From these data, we conclude that E. coli endonuclease III cleaves the phosphodiester bond 3' to the AP site, but that the cleavage is not a hydrolysis leaving a base-free deoxyribose at the 3' end as it has been so far assumed. The cleavage might be the result of a beta-elimination analogous to the one produced by an alkaline pH or Lys-Trp-Lys. Thus it would seem that E. coli 'endonuclease III' is, after all, not an endonuclease.     

Comparison of the cleavage of pyrimidine dimers by the bacteriophage T4 and Micrococcus luteus UV-specific endonucleases

A comparison was made of the activity of the UV-specific endonucleases of bacteriophage T4 (T4 endonuclease V) and of Micrococcus luteus on ultravilet light-irradiated DNA substrates of defined sequence. The two enzymes cleave DNA at the site of pyrimidine dimers with the same frequency. The products of the cleavage reaction are the same, suggesting that the scission of DNA by T4 endonuclease V occurs via the combined actin of a pyrimidine dimer specific DNA glycosylase and an apyrimidinic-apurinic (AP) endonuclease as was recently shown for the M. luteus enzyme. The pyrimidine dimer DNA-glycosylase activity of both enzymes is more active on double-stranded DNA than it is on single-stranded DNA.     

The effect of Pot1 binding on the repair of thymine analogs in a telomeric DNA sequence

Telomeric DNA can form duplex regions or single-stranded loops that bind multiple proteins, preventing it from being processed as a DNA repair intermediate. The bases within these regions are susceptible to damage; however, mechanisms for the repair of telomere damage are as yet poorly understood. We have examined the effect of three thymine (T) analogs including uracil (U), 5-fluorouracil (5FU) and 5-hydroxymethyluracil (5hmU) on DNA–protein interactions and DNA repair within the GGTTAC telomeric sequence. The replacement of T with U or 5FU interferes with Pot1 (Pot1pN protein of Schizosaccharomyces pombe) binding. Surprisingly, 5hmU substitution only modestly diminishes Pot1 binding suggesting that hydrophobicity of the T-methyl group likely plays a minor role in protein binding. In the GGTTAC sequence, all three analogs can be cleaved by DNA glycosylases; however, glycosylase activity is blocked if Pot1 binds. An abasic site at the G or T positions is cleaved by the endonuclease APE1 when in a duplex but not when single-stranded. Abasic site formation thermally destabilizes the duplex that could push a damaged DNA segment into a single-stranded loop. The inability to enzymatically cleave abasic sites in single-stranded telomere regions would block completion of the base excision repair cycle potentially causing telomere attrition.     

Repair of Double-Strand Breaks in Bacteriophage T4 by a Mechanism That Involves Extensive DNA Replication

We investigated double-strand break (dsb) repair in bacteriophage T4 using a physical assay that involves a plasmid substrate with two inverted DNA segments. A dsb introduced into one repeat during a T4 infection induces efficient dsb repair using the second repeat as a template. This reaction is characterized by the following interesting features. First, the dsb induces a repair reaction that is directly coupled to extensive plasmid replication; the repaired/replicated product is in the form of long plasmid concatemers. Second, repair of the dsb site is frequently associated with exchange of flanking DNA. Third, the repair reaction is absolutely dependent on the products of genes uvsX, uvsY, 32, 46, and 59, which are also required for phage genomic recombination-dependent DNA replication. Fourth, the coupled repair/replication reaction is only partly dependent on endonuclease VII (gp49), suggesting that either another Holliday-junction-cleaving activity or an alternate resolution pathway is active during T4 infections. Because this repair reaction is directly coupled to extensive replication, it cannot be explained by the SZOSTAK et al. model. We present and discuss a model for the coupled repair/replication reaction, called the extensive chromosome replication model for dsb repair.     

DNA-sequence recognition by CAP: role of the adenine N6 atom of base pair 6 of the DNA site.

Two similar, but not identical, models have been proposed for the amino acid-base pair contacts in the CAP-DNA complex ('Model I,' Weber, I. and Steitz, T., Proc. Natl. Acad. Sci. USA, 81, 3973-3977, 1984; 'Model II,' Ebright, et al., Proc. Natl. Acad. Sci. USA, 81, 7274-7278, 1984). One difference between the two models involves Glu181 of CAP. Model I predicts that Glu181 of CAP makes two specificity determining contacts: one H-bond with the cytosine N4 atom of G:C at base pair 7 of the DNA half site, and one H-bond with the adenine N6 atom of T:A at base pair 6 of the DNA half site. In contrast, Model II predicts that Glu181 makes only one specificity determining contact: one H-bond with the cytosine N4 atom of G:C at base pair 7 of the DNA half site. In the present work, we show that replacement of T:A at base pair 6 of the DNA half site by T:N6-methyl-adenine has no, or almost no, effect on the binding of CAP. We conclude, contrary to Model I, that Glu181 of CAP makes no contact with the adenine N6 atom of base pair 6 of the DNA half site.     

Mutational analyses of restriction endonuclease-HindIII mutant E86K with higher activity and altered specificity

We have performed mutational analyses of restriction endonuclease HindIII in order to identify the amino acid residues responsible for enzyme activity. Four of the seven HindIII mutants, which had His-tag sequences at the N-termini, were expressed in Escherichia coli, and purified to homogeneity. The His-tag sequence did not affect enzyme activity, whereas it hindered binding of the DNA probe in gel retardation assays. A mutant E86K in which Lys was substituted for Glu at residue 86 exhibited high endonuclease activity. Gel retardation assays showed high affinity of this mutant to the DNA probe. Surprisingly, in the presence of a transition metal, Mo(2+) or Mn(2+), the E86K mutant cleaved substrate DNA at a site other than HindIII. Substitution of Glu for Val at residue 106 (V106E), and Asn for Lys at residue 125 (K125N) resulted in a decrease in both endonucleolytic and DNA binding activities of the enzyme. Furthermore, substitution of Leu for Asp at residue 108 (D108L) abolished both HindIII endonuclease and DNA binding activities. CD spectra of the wild type and the two mutants, E86K and D108L, were similar to each other, suggesting that there was little change in conformation as a result of the mutations. These results account for the notion that Asp108 could be directly involved in HindIII catalytic function, and that the substitution at residue 86 may bring about new interactions between DNA and cations.     

Binding of T4 endonuclease V to deoxyribonucleic acid irradiated with ultraviolet light

Endonuclease V of bacteriophage T4 binds to UV-irradiated deoxyribonucleic acid (DNA) but not to unirradiated DNA. We have developed an assay to detect this binding, based on the retention of enzyme--DNA complexes on nitrocellulose filters. The amount of complex retained, ascertained by using radioactive DNA, is a measure of T4 endonuclease V activity. The assay is simple, rapid, and specific, which makes it useful for detecting T4 endonuclease V activity both in crude lysates and in purified preparations. We have used it to monitor enzyme activity during purification and to study binding of the enzyme to DNA under conditions that minimize the ability of the enzyme to nick DNA. From our data we conclude that (1) T4 endonuclease V binds to UV-irradiated DNA but not to DNA that has been previously incised by the endonuclease, (2) equilibrium between the free and complexed form of the enzyme is attained under our reaction conditions, (3) dissociation of enzyme--DNA complexes is retarded by sodium cyanide, and (4) retention of enzyme--DNA complexes on nitrocellulose filters is enhanced by high concentrations of saline--citrate.