Utilization of DNA photolyase, pyrimidine dimer endonucleases, and alkali hydrolysis in the analysis of aberrant ABC excinuclease incisions adjacent to UV-induced DNA photoproducts.

ABC excinuclease of Escherichia coli removes 6-4 photoproducts and pyrimidine dimers from DNA by making two single strand incisions, one 8 phosphodiester bonds 5' and another 4 or 5 phosphodiester bonds 3' to the lesion. We describe in this communication a method, which utilizes DNA photolyase from E. coli, pyrimidine dimer endonucleases from M. luteus and bacteriophage T4, and alkali hydrolysis, for analyzing the ABC excinuclease incision pattern corresponding to each of these photoproducts in a DNA fragment. On occasion, ABC excinuclease does not incise DNA exclusively 8 phosphodiester bonds 5' or 4 or 5 phosphodiester bonds 3' to the photoproduct. Both the nature of the adduct (6-4 photoproduct or pyrimidine dimer) and the sequence of neighboring nucleotides influence the incision pattern of ABC excinuclease. We show directly that photolyase stimulates the removal of pyrimidine dimers (but not 6-4 photoproducts) by the excinuclease. Also, photolyase does not repair CC pyrimidine dimers efficiently while it does repair TT or TC pyrimidine dimers.     

Quantitative analysis of pyrimidine oligodeoxyribonucleotides in DNA: prevention of nonspecific degradation.

During isolation the long pyrimidine oligodeoxyribonucleotides in a diphenylamine-formic acid digest of DNA are subject to nonspecific degradation that results in poor recoveries of these tracts and interferes with quantitative analysis of their occurrence. Cytosine-rich sequences are preferentially degraded. The breakdown can be prevented by metal ion chelators and increased by addition of small amounts of some divalent and trivalent metal ions. Addition of sodium diethyldithiocarbamate to all solutions used in the isolation of the pyrimidine tracts prevented their nonspecific degradation and improved their recoveries.     

Distribution of pyrimidine sequences of different length and base composition in bacteriophage T5 DNA]

Distribution of pyrimidine tracts of different length (isopliths) with general formula PynPn+1 in bacteriophage T5 DNA was studied. The first seven isoplith fractions were subfractionated by the chain length and the quantity of the resulting non-isomeric oligonucleotides was determined. The pattern of distribution of pyrimidine tracts of various length and base composition in bacteriophage T5 DNA is different from that previously observed in the DNAs of bacteriophages T3 and T7. The observed differences in distribution of pyrimidine nucleotides are in accordance with the other peculiarities of bacteriophage T5 genome.     

Deoxyribonucleic acid-cytosine methylation by host- and plasmid-controlled enzymes.

Deoxyribonucleic acid (DNA)-cytosine methylation specified by the wild-type Escherichia coli K 12 mec+ gene and by the N-3 drug resistance (R) factor was studied in vivo and in vitro. Phage lambda and fd were propagated in the presence of L-[methyl-3H]methionine in various host bacteria. The in vivo labeled DNA was isolated from purified phage and depurinated by formic acid-diphenylamine treatment. The resulting pyrimidine oligonucleotide tracts were separated according to size and base composition by chromatography on diethylaminoethyl-cellulose in 7 M urea at pH 5.5 and 3.5, respectively. The distribution of labeled 5-methylcytosine in DNA pyrimidine tracts was identical for phage grown in mec+ and mec minus (N-3) cells. For phage lambda the major 5-methylcytosine containing tract was the tripyrimidine, C2T; for both fd-mec minus (N-3) DNA and fd-mec+DNA, C2T was the sole 5-methylcytosine-containing tract. When various lambda DNAs were methylated to saturation in vitro by crude extracts from mec+ and mec minus (N-3) cells, the extent of cytosine methylation was the same. This is in contrast to in vivo methylation where lambda-mec minus (N-3) DNA contains twice as many 5-methylcytosines per genome as lambda-mec+ DNA. Therefore, we suggest that the K12 met+ cytosine methylase and the N-3 plasmid modification methylase are capable of recognizing the same nucleotide sequences, but that the in vivo methylation rate is lower in mec+ cells.     

Nuclear ligation of RNA 5''-OH kinase products in tRNA.

Mouse L-cell nuclei incorporate gamma-32P from ATP in vitro predominantly in 5'-monophosphoryl termini and internal phosphodiester bonds with a nonrandom nearest-neighbor distribution. In the presence of 1 microgram of alpha-amanitin per ml the gamma-32P showed a time-dependent appearance in RNA bands which migrated with mature tRNA species but not with pre-tRNA and 5S RNA. The gamma-32P was found in internal phosphodiester bonds as shown by alkaline phosphatase resistance and was identified in 3'-monophosphates after RNase T2, T1, and A digestion. The specificity of this incorporation was indicated by a limited number of labeled oligonucleotides from a T1 digest and identification of 70 to 80% of the 32P label as Cp on complete digestion of the eluted tRNA band. We also observed transiently [gamma-32P]ATP-labeled RNA bands (in 5'-monophosphate positions) that were 32 to 45 nucleotides long. The results presented suggest splicing of several mouse L-cell tRNA species in isolated nuclei which involve the RNA 5'-OH kinase products as intermediates.     

The site-specific cleavage of synthetic Holliday junction analogs and related branched DNA structures by bacteriophage T7 endonuclease I

Various branched DNA structures were created from synthetic, partly complementary oligonucleotides combined under annealing conditions. Appropriate mixtures of oligonucleotides generated three specific branched duplex DNA molecules: (i) a Holliday junction analog having a fixed (immobile) crossover bounded by four duplex DNA branches, (ii) a similar Holliday junction analog which is capable of limited branch migration and, (iii) a Y-junction, with three duplex branches and fixed branch point. Each of these novel structures was specifically cleaved by bacteriophage T7 gene 3 product, endonuclease I. The cleavage reaction "resolved" the two Holliday structure analogs into pairs of duplex DNA products half the size of the original molecules. The point of cleavage in the fixed-junction molecules was predominantly one nucleotide removed to the 5' side of the expected crossover position. Multiple cleavage positions were mapped on the Holliday junction with the mobile, or variable, branch point, to sites consistent with the unrestricted movement of the phosphodiester crossover within the region of limited dyad symmetry which characterizes this molecule. Based on the cleavage pattern observed with this latter substrate, the enzyme displayed a modest degree of sequence specificity, preferring a pyrimidine on the 3' side of the cleavage site. Branched molecules that were partial duplexes (lower order complexes which possessed single-stranded as well as duplex DNA branches) were also substrates for the enzyme. In these molecules, the cleaved phosphodiester bonds were in duplex regions only and predominantly one nucleotide to the 5' side of the branch point. The phosphodiester positions 5' of the branch point in single-stranded arms were not cleaved. Under identical reaction conditions, individually treated oligonucleotides were completely refractory. Thus, cleavage by T7 endonuclease I displays great structural specificity with an efficiency that can vary slightly according to the DNA sequence.     

1H-NMR and (31)P-NMR analysis of energy metabolism of quiescent and motile turbot (Psetta maxima) spermatozoa

31P-NMR and (1)H-NMR were used to monitor changes of several compounds with high-energy bonds and metabolites prior to and after the initiation of motility of turbot spermatozoa (Psetta maxima). The obtained (31)P-NMR spectra revealed the presence of phosphomonoesters, phosphodiester, intracellular inorganic phosphate (Pi), phosphocreatine (PCr), and free nucleotide triphosphate. Following the activation of motility, the di- and tri-phosphate nucleotides, PCr, phosphomonoesters levels dropped while Pi levels increased. A significant increase of lactate was also seen at the end of the swimming phase. The compositions of seminal fluid and urine were also determined. Lipoproteins, formic acid, amino acid, and citric acid were detected in seminal fluid. Dimethyl amine, trimethylamine, and trimethylamine oxyde were found in urine. These data suggest that at least a part of the energy required during the swimming phase results from anaerobic fermentation and oxidative phosphorylation. J. Exp. Zool. 286:513-522, 2000.     

Effect of nucleotide analogs on the cleavage of DNA by the restriction enzymes AluI, DdeI, HinfI, RsaI, and TaqI

The cleavage of specific DNA sequences by the restriction endonucleases AluI, DdeI, HinfI, RsaI, and TaqI has been studied by monitoring the effect of various nucleotide modifications on the rate of DNA digestion. Bacteriophage fd DNA was completely substituted in one strand with a single nucleotide analog, using an in vitro primed DNA synthesis reaction on a single-stranded viral DNA template. Twelve deoxynucleotide analogs were incorporated into these DNA substrates: 2-aminopurine, 2,6-diaminopurine, deoxytubercidin, deoxyuridine, 5-bromodeoxyuridine, 5-allylamine deoxyuridine, 5-biotinyl deoxyuridine, deoxypseudouridine, deoxyinosine, 8-azadeoxyguanosine, 5-iododeoxycytidine, and 5-bromodeoxycytidine. The restriction enzymes tested varied considerably in their ability to digest hemi-substituted DNAs containing these modified nucleotides. Structural alterations in the base pairs immediately adjacent to the phosphodiester bonds cleaved by the enzyme reduced the rate of enzyme activity most dramatically, and in most cases more than a single determinant on each base pair altered activity. Interactions with nucleotides outside the recognition site seem to have little importance in the binding or catalytic activity of these enzymes.     

DNA curvature does not require bifurcated hydrogen bonds or pyrimidine methyl groups.

Short tracts of the homopolymer dA.dT confer intrinsic curvature on the axis of the DNA double helix. This phenomenon is assumed to be a consequence of such tracts adopting a stable B'-DNA conformation that is distinct from B-form structure normally assumed by other DNA sequences. The more stable B' structure of dA.dT tracts has been attributed to several possible stabilizing factors: (1) optimal base stacking interactions consequent upon the high propeller twist, (2) bifurcated hydrogen bonds between adjacent dA.dT base-pairs, (3) stacking interactions involving the dT methyl groups, and finally (4) a putative spine of ordered water molecules in the minor groove. DNA oligodeoxynucleotides have been synthesized that enable these hypotheses to be tested; of particular interest is the combination of effects due to bifurcation (2) and methylation of the pyrimidines nucleotides (3). The data indicate that neither bifurcated hydrogen bonds nor pyrimidine methyl groups nor both are essential for DNA curvature. The data further suggest that the influence of the minor groove spine of hydration on the B'-formation is small. The experiments favor the hypothesis that base stacking interactions are the dominant force in stabilizing the B'-form structure.     

Single-strand DNA triple-helix formation

Chemical modification studies provide evidence that single-stranded oligodeoxyribonucleotides can form stable intrastrand triple helices. Two oligonucleotides of opposite polarity were synthesized, each composed of a homopurine-homopyrimidine hairpin stem linked to a pyrimidine sequence which is capable of folding back on the hairpin stem and forming specific Hoogsteen hydrogen bonds. Using potassium permanganate as a chemical modification reagent, we have found that two oligodeoxyribonucleotides of sequence composition type 5'-(purine)8(N)4(pyrimidine)8(N)6(pyrimidine)8-3' and 5'-(pyrimidine)8N6(pyrimidine)8N4(purine)8-3' undergo dramatic structural changes consistent with intrastrand DNA triple-helix formation induced by lowering the pH or raising the Mg2+ concentration. The intrastrand DNA triple helix is sensitive to base mismatches.     

Physico-chemical studies on DNA triplexes containing an alternate third strand with a non-nucleotide linker

Differential scanning calorimetric (DSC), circular dichroism (CD) and molecular mechanics studies have been performed on two triple helices of DNA. The target duplex consists of 16 base pairs in alternate sequence of the type 5′-(purine)_m(pyrimidine)_m-3′. In both the triplexes, the third oligopyrimidine strand crosses the major groove at the purine–pyrimidine junction, with a simultaneous binding of the adjacent purine tracts on alternate strands of the Watson–Crick duplex. The switch is ensured by a non-nucleotide linker, the 1,2,3 propanetriol residue, that joins two 3′–3′ phosphodiester ends. The third strands differ from each other for a nucleotide in the junction region. The resulting triple helices were termed 14-mer-PXP and 15-mer-PXP (where P=phosphate and X=1,2,3-propanetriol residue) according to the number of nucleotides that compose the third strand. DSC data show two independent processes: the first corresponding to the dissociation of the third strand from the target duplex, the second to the dissociation of the double helix in two single strands. The two triple helices show the same stability at pH 6.6. At pH 6.0, the 15-mer-PXP triplex is thermodynamically more stable than the 14-mer-PXP triplex. Thermodynamic data are discussed in relation to structural models. The results are useful when considering the design of oligonucleotides that can bind in an antigene approach to the DNA for therapeutic purposes.     

Conformational analysis of canonical 2-deoxyribonucleotides. 1. Pyrimidine nucleotides

The molecular structure and relative stability of north and south conformers of 2'-deoxyribonucleotides containing pyrimidine nucleic acid bases ( 2'-deoxythymidilic (pdT), 2'-deoxycytidilic (pdC) acids and their mono- and dianions) have been obtained and analyzed at the DFT/B3LYP level using the standard 6-31G(d) basis set. We have revealed that, when the nucleobase moiety is incorporated into the nucleotides, it maintains a nonplanar and nonrigid conformation due to out-of-plane deformation of the amino group and pyrimidine ring. It has been demonstrated that an increase of negative charge of the phosphate group results in increase of amino group pyramidalization, discrimination between conformers with syn and anti orientation of base with respect to sugar, strengthening of intramolecular C-H.O hydrogen bonds leading to deformation and fixation of geometry of nucleotides, and weakening of phosphodiester bond. These results allow to make suggestions about sources of twist and buckle deformations of base pairs, mechanisms of repaire of DNA via change of base orientation, and conditions for breakage of the P-O bonds during hydrolysis.     

Phosphodiesterase I in human urine: purification and characterization of the enzyme

Phosphodiesterase I [EC 3.1.4.1] was purified from normal human urine in a highly purified state free from phosphodiesterase II, RNase, DNase I, DNase II, and phosphatase by column chromatographies of DEAE-Toyopearl, butyl-Toyopearl, Affi-Gel blue, and Sephadex G-150. The molecular weight of the enzyme was 1.9 x 10(5) and the pH optimum around 9.0 with p-nitrophenyl deoxythymidine 5'-phosphate as the substrate. The enzyme hydrolyzed the 3'-5' linkage of various dinucleoside monophosphates at approximately the same rate and the phosphodiester bonds of cyclic 3',5'-mononucleotides to produce mononucleoside 5'-phosphate. The enzyme also hydrolyzed ADP to 5'-AMP and Pi, ATP to 5'-AMP and PPi, and NAD+ to 5'-AMP and NMN. The enzyme activity was abolished by removal of metal ions with EDTA, and the metal-free enzyme was reactivated on the addition of Zn2+. The enzyme activity was also abolished by some reducing agents and the inhibition was reversed by Zn2+. The metal-free enzyme was less stable than the native enzyme, and Zn2+ and Co2+ restored the stability of the metal-free enzyme to the level of the native enzyme. The enzyme degraded oligonucleotides and high molecular nucleotides stepwise from the 3'-termini to give 5'-mononucleotides. The enzyme hydrolyzed single-stranded DNA more preferentially than double-stranded DNA. The enzyme also nicked superhelical covalently closed circular phi X174 DNA to yield first open circular DNA and then linear DNA.     

Positively charged oligonucleotides overcome potassium-mediated inhibition of triplex DNA formation.

The formation of triplex DNA using unmodified, purine-rich oligonucleotides (ODNs) is inhibited by physiologic levels of potassium. Changing negative phosphodiester bonds in a triplex forming oligonucleotide (TFO) to neutral linkages causes a small increase in triplex formation. When phosphodiester bonds in a TFO are converted to positively-charged linkages the formation of triplex DNA increases dramatically. In the absence of KCl, a 17mer TFO containing 11 positively-charged linkages at a concentration of 0.2 microM converts essentially all of a 30 bp target duplex to a triplex. Less than 15% of the target duplex is shifted by 2 microMolar of the unmodified TFO. In 130 mM KCl, triplex formation is undetectable using the unmodified TFO, while triplex formation is nearly complete with 2 microM positively-charged TFO. With increasing potassium, TFOs containing a higher proportion of modified linkages show enhanced triplex formation compared with those less modified. In contrast with unmodified TFOs, triplex formation with more heavily modified TFOs can occur in the absence of divalent cations. We conclude that replacement of phosphodiester bonds with positively-charged phosphoramidate linkages results in more efficient triplex formation, suggesting that these compounds may prove useful for in vivo applications.     

Pyrimidine morpholino oligonucleotides form a stable triple helix in the absence of magnesium ions

Oligonucleotides can be used as sequence-specific DNA ligands by forming a local triple helix. In order to form more stable triple-helical structures or prevent their degradation in cells, oligonucleotide analogues that are modified at either the backbone or base level are routinely used. Morpholino oligonucleotides appeared recently as a promising modification for antisense applications. We report here a study that indicates the possibility of a triple helix formation with a morpholino pyrimidine TFO and its comparison with a phosphodiester and a phosphoramidate oligonucleotide. At a neutral pH and in the presence of a high magnesium ion concentration (10 mM), the phosphoramidate oligomer forms the most stable triple helix, whereas in the absence of magnesium ion but at a physiological monovalent cation concentration (0.14 M) only morpholino oligonucleotides form a stable triplex. To our knowledge, this is the first report of a stable triple helix in the pyrimidine motif formed by a noncharged oligonucleotide third strand (the morpholino oligonucleotide) and a DNA duplex. We show here that the structure formed with the morpholino oligomer is a bona fide triple helix and it is destabilized by high concentrations of potassium ions or divalent cations (Mg(2+)).     

Measurement of repair patch size by quantitation of nucleotides excised during DNA repair in vivo.

Escherichia coli uvr- cells, prelabeled in their DNA, were infected with phage T4 denV+ or T4 denV- under conditions that preclude phage-mediated degradation of the bacterial chromosome. Measurement of the distribution of acid-soluble radioactivity between pyrimidine dimers and nondimer nucleotides in cell extracts yielded calculated estimates of the average size of excision repair tracts that are in good agreement with the size of repair patches determined by others using direct measurement of repair synthesis.     

A specific 3'' exonuclease activity of UvrABC.

Specific cutting of undamaged DNA by UvrABC nuclease is observed. It occurs seven nucleotides (nt) from the 3' terminus of oligonucleotides annealed to single-stranded M13 DNA circles. Although the location of the UvrABC cut on undamaged DNA is similar to that of the cut on the 5' side of a damaged DNA site during the dual incision reaction, the cut of undamaged DNA is not an intermediate in the dual incision step. On DNA duplexes with a single AAF adduct, the anticipated cut at the eighth phosphodiester bond 5' of the lesion is present, but extra cuts at 7-nt increments are observed at the 15th and 22nd phosphodiester bonds. We suggest that these additional cuts are made by the UvrABC activity observed on undamaged DNA; such activity is referred to as ABC 3' exonuclease and may play a significant role by providing a suitable gap for RecA-mediated recombinational exchanges during repair of interstrand crosslinks and closely opposed lesions. This ABC 3' exonuclease activity depends on higher concentrations of Uvr proteins as compared with dual incision and may be relevant to reactions that occur when UvrA and UvrB are increased during SOS induction.