Influence of streptozotocin upon the induction of tyrosine aminotransferase, the content of NAD and of 5-methyl cytosine in rat liver

The antibiotic, streptozotocin, has carcinostatic, carcinogenic, and diabetogenic properties. Moreover, it is capable of inducing the enzyme tyrosine aminotransferase in a permanent line of rat liver cells. In the present publication, the effects of streptozotocin upon the induction of tyrosine aminotransferase, NAD synthesis, and methylation of DNA in different organs were analyzed in vivo. If administered alone, streptozotocin slightly induced tyrosine aminotransferase. The induction of tyrosine aminotransferase caused by tryptophan or nicotinamide was inhibited by streptozotocin. Streptozotocin reduced the NAD content of the liver. NAD synthesis induced by tryptophan was reduced by streptozotocin, while that induced by nicotinamide was enhanced. DNA methylation in the form of 5-methyl cytosine was not influenced by streptozotocin.     

Reaction of bisulfite with the 5-hydroxymethyl group in pyrimidines and in phage DNAs.

5-Hydroxymethylcytosine reacted with bisulfite and, instead of undergoing usual deamination process, gave cytosine 5-methylenesulfonate as the product. The conversion was rapid and quantitative, and the optimum pH was 4.5. The product was isolated as crystals and characterized. Cytosine 5-methylenesulfonate was only very slowly deaminated by treatment with bisulfite. 5-Hydroxymethyl-2'-deoxycytidine 5'-phosphate reacted with bisulfite in the same way as 5-hydroxymethylcytosine. Residues of 5-hydroxymethylcytosine in native as well as denatured T2 DNA were convertible to those of cytosine 5-methylenesulfonate by treatment of the DNA with bisulfite. While it is known that the 5-hydroxy-methyl groups of T-even bacteriophage DNA can be enzymatically glucosylated, this observation offers chemical evidence that the 5-hydrozymethyl groups in DNA are situated in such a way that they can readily react with external agents. 5-Hydroxymethyluracil gave uracil 5-methylenesulfonate on treatment with bisulfite. This reaction was much slower than that of 5-hydroxymethylcytosine, and the optimum pH was between 6 and 7.     

Effect of O-hydroxylamine on the transforming DNA from Bacillus subtilis. Correlation of chemical modifications with genetic consequences

The action of methoxyamine (MA) on B. subtilis transforming DNA (50 degrees C, pH 4,5 and 6,0, 1 M MA) was studied. The rate of cytosine residues modification in DNA is 250 times less than in monomer (rate constants for DNA are 1,5 X 10(-1) min-1 at pH 4,5, and 2,5 X 10(-6) min-1 in the first 300 hours of treatment at pH 6,0). At pH 4,5 the rates of cytosine (I) conversion into N4-methoxycytosine (II) and into 6-methoxyamino-5,6-dihydro-N4-methoxycytosine (III) are constant (II/III ratio is about 2,1). At pH 6,0 the II/III ratio smoothly increases from 1,0 to 1,6 (200 and 900 hours of treatment) due to a decrease in the product III accumulation rate. The frequency of MA-induced mutations shows a bell-shaped dependence on time with maxima (approximately 10%) at 80 (pH 4,5) and 500 (pH 6,0) hours of treatment. In both cases approximately 10% of cytosine residues are modified. These results suggest that either compound III is efficiently removed from the transforming DNA, or its presence does not arrest the DNA replication.     

Hydrolysis of N3-methyl-2'-deoxycytidine: model compound for reactivity of protonated cytosine residues in DNA

Protonation of cytosine residues at physiological pH may occur in DNA as a consequence of both alkylation and aberrant base-pair formation. When cytosine derivatives are protonated, they undergo hydrolysis reactions at elevated rates and can either deaminate to form the corresponding uracil derivatives or depyrimidinate generating abasic sites. The kinetic parameters for reaction of protonated cytosine are derived by studying the hydrolysis of N3-methyl-2'-deoxycytidine (m3dC), a cytosine analogue which is predominantly protonated at physiological pH. Both deamination and depyrimidimation reaction rates are shown to be linearly dependent upon the fraction of protonated molecules. We present here thermodynamic parameters which allow determination of hydrolysis rates of m3dC as functions of pH and temperature. Protonation of cytosine residues in DNA, as induced by aberrant base-pair formation or base modification, may accelerate the rate of both deamination and depyrimidation up to several thousand-fold under physiological conditions.     

Studies on the conformation of protonated DNA

Experiments were made to demonstrate the predominant protonation effects and structural changes of the ordered double helical DNA structure and denatured state of DNA. Spectrophotometric titrations performed at different wavelengths indicate that cytosine can be protonated in the DNA double helical molecule to a high extent without breakdown of the secondary structure. With DNA heat-denatured under severe conditions the protonation of cytosine can be measured at 280, 295, and 300 mμ: the apparent pK value obtained was ～4.6. The protonated double helical conformation of the DNA molecule differs from the unprotonated state, which follows from the decrease of the thermal stability and from changes in the ORD curves. The ORD of a GC-rich DNA indicates a novel Cotton effect with positive rotations at ～260 mμ in 0.02M KCl below pH 4.0 to pH 3.3. The occurrence of the new peak parallels the extent of protonated cytosine measured by the spectrophotometric titrations. It is concluded that the protonated cytosine in the double helical structure is responsible for the difference between the protonated DNA conformation and the native state at neutral pH.     

A sensitive genetic assay for the detection of cytosine deamination: determination of rate constants and the activation energy

Previously it has not been possible to determine the rate of deamination of cytosine in DNA at 37 degrees C because this reaction occurs so slowly. We describe here a sensitive genetic assay to measure the rate of cytosine deamination in DNA at a single cytosine residue. The assay is based on reversion of a mutant in the lacZ alpha gene coding sequence of bacteriophage M13mp2 and employs ung- bacterial strains lacking the enzyme uracil glycosylase. The assay is sufficiently sensitive to allow us to detect, at a given site, a single deamination event occurring with a background frequency as low as 1 in 200,000. With this assay, we determined cytosine deamination rate constants in single-stranded DNA at temperatures ranging from 30 to 90 degrees C and then calculated that the activation energy for cytosine deamination in single-stranded DNA is 28 +/- 1 kcal/mol. At 80 degrees C, deamination rate constants at six sites varied by less than a factor of 3. At 37 degrees C, the cytosine deamination rate constants for single- and double-stranded DNA at pH 7.4 are 1 x 10(-10) and about 7 x 10(-13) per second, respectively. (In other words, the measured half-life for cytosine in single-stranded DNA at 37 degrees C is ca. 200 years, while in double-stranded DNA it is on the order of 30,000 years.) Thus, cytosine is deaminated approximately 140-fold more slowly when present in the double helix. These and other data indicate that the rate of deamination is strongly dependent upon DNA structure and the degree of protonation of the cytosine. The data suggest that agents which perturb DNA structure or facilitate direct protonation of cytosine may induce deamination at biologically significant rates. The assay provides a means to directly test the hypothesis.     

Reaction of cytidine with semicarbazide in the presence of bisulfite. A rapid modification specific for single-stranded polynucleotide.

Semicarbazide reacted rapidly with 5,6-dihydrocytidine-6-sulfonate, which was formed from cytidine by addition of bisulfite across the 5,6-double bond. The transaminated product, 5,6-dihydro-4-semicarbazido-2-ketotopyrimidine-6-sulfonate ribofuranoside, was identified by comparison with that formed by treatment of 4-semicarbazido-2-ketopyrimidine ribofuranoside with bisulfite. The progress of the transamination was monitored spectrophotometrically by use of a strong absorbance of the product in alkali. The reaction between cytidine and the semicarbazide-bisulfite mixture was optimal at pH 4.5. Complete transformation of cytidine into the product required only 5 min with the use of 3M semicarbazide-1M sodium bisulfite, pH 5.0, at the reaction temperature 37 degrees C. The product was stable in unbuffered solution but in phosphate buffers it underwent elimination of bisulfite to give 4-semicarbazido-2-ketopyrimidine ribofuranoside. The rate of the elimination at pH 7.0 and 37 degrees C increased proportionally with the increase of the phosphate concentration. Complete elimination was obtained by treatment with 1 M sodium phosphate for 2 h. When heat-denatured calf-thymus DNA was treated with 3 M semicarbazide-1 M bisulfite at 37 degrees C and pH 5.0 the transamination of reactive cytosine residues was completed by 10 min of incubation. At 20 degrees C, it required 85 min of incubation. Cytosine residues in native DNA did not react at all even by prolonged incubations. The modified DNA samples were further treated with a phosphate buffer at pH 7, producing 4-semicarbazido-2-ketopyrimidine residues in the DNA. Analysis of the base compositions of these samples by perchloric acid hydrolysis showed that the modification was selective to cytosine, which had been expected from studies with monomers. It also showed that the reactive cytosine residues in the denatured DNA, constitute about 80% of the total cytosine, which was consistent with the view that heat-denatured DNA still contains a considerable amount of secondary structure. The semicarbazide-bisulfite modification is expected to be a sensitive method to locate cytosine residues in single-stranded regions of polynucleotides.     

Triplex-forming properties and enzymatic incorporation of a base-modified nucleotide capable of duplex DNA recognition at neutral pH

The sequence-specific recognition of duplex DNA by unmodified parallel triplex-forming oligonucleotides is restricted to low pH conditions due to a necessity for cytosine protonation in the third strand. This has severely restricted their use as gene-targeting agents, as well as for the detection and/or functionalisation of synthetic or genomic DNA. Here I report that the nucleobase 6-amino-5-nitropyridin-2-one (Z) finally overcomes this constraint by acting as an uncharged mimic of protonated cytosine. Synthetic TFOs containing the nucleobase enabled stable and selective triplex formation at oligopurine-oligopyrimidine sequences containing multiple isolated or contiguous GC base pairs at neutral pH and above. Moreover, I demonstrate a universal strategy for the enzymatic assembly of Z-containing TFOs using its commercially available deoxyribonucleotide triphosphate. These findings seek to improve not only the recognition properties of TFOs but also the cost and/or expertise associated with their chemical syntheses.     

The secondary structure of bacteriophage DNA in situ. VIII. The reaction of sodium bisulphite with intraphage cytosine as a probe for studying the DNA-protein interaction

To obtain data on the viral nucleoprotein a study has been made of the reaction of sodium bisulphite with cytosine in the intraphage DNA of the phage Sd. The CHlO4 hydrolysates of the bisulphite-modified phage Sd have demonstrated a decrease of 18% in the cytosine content and the presence of the products with the properties of cytosyl-amino acids (the main amino acid responsible for the DNA-protein interaction involving cytosine is lysine). But when prior to hydrolysis the modified phage was disintegrated under mild conditions in 0.1--1 M NaCl solution or Tris-HCl buffer (pH 7), neither the decrease in the cytosine content nor cytosyl-amino acids have been found. An exception is the heating of the phage at 70 degrees C in a medium containing 0.05 M phosphate buffer (pH 7.9--8.5), when an 18% decrease in the cytosine content and subsequent appearance of cytosyl-amino acids have also been observed. The presence of cytosyl-amino acids which are the nucleotide-protein cross-links is confirmed by the results of viscometry, equilibrium centrifugation in cesium sulphate gradient and determinations of the survival percentage. It is suggested that the reaction between bisulphite and cytosine in the phage Sd stops at the stage of the intermediate product C5-C6-dihydro-C6-sulphopyrimidine whose amino group is shielded by interaction with protein (product VII). This product can exist only under in situ conditions: with disintegration of nucleoprotein (destruction of phage particles or ejection of the DNA) in phosphate-free media the product VII reverts into the initial cytosine. Under the conditions of acid hydrolysis or destruction of phage in the presence of phosphate ions product VII undergoes transamination with cleavage of SO3 and restoration of the C5-C6 double bond producing cytosyl-amino acids. The factors determining the stability of the product VII are discussed.     

Mode of action of the Spiroplasma CpG methylase M.SssI.

The cytosine DNA methylase from the wall-less prokaryote, Spiroplasma strain MQ1 (M.SssI) methylates completely and exclusively CpG-containing sequences, thus showing sequence specificity which is similar to that of mammalian DNA methylases. M.SssI is shown here to methylate duplex DNA processively as judged by kinetic analysis of methylated intermediates. The cytosine DNA methylases, M.HpaII and M.HhaI, from other prokaryotic organisms, appear to methylate in a non-processive manner or with a very low degree of processivity. The Spiroplasma enzyme interacts with duplex DNA irrespective to the presence of CpG sequences in the substrate DNA. The enzyme proceeds along a CpG-containing DNA substrate molecule methylating one strand of DNA at a time.     

Heat- and alkali-induced deamination of 5-methylcytosine and cytosine residues in DNA

5-Methylcytosine residues in DNA underwent deamination at high temperatures. Furthemore, their rate of deamination at neutral or alkaline pH was greater than that of cytosine residues in DNA. As sources of [¹⁴C]5-methylcytosine-containing DNA, we used bacteriophage XP-12 DNA, in which 5-methylcytosine residues completely replace C residues, and calf thymus DNA experimentally substituted with [¹⁴C]5-methylcytosine residues. Upon incubation at 95°C in a physiological buffer or at 60°C in 1 M NaOH, the respective rates of deamination of 5-methylcytosine residues were about 3- and 1.5-times those of cytosine residues. Under the same conditions, the free 5-methyldeoxycytidine was converted to thymidine more rapidly than deoxycytidine was converted to deoxyuridine. The reactions at physiological pH and elevated temperature suggest that deamination of 5-methylcytosine residues may yield a significant portion of spontaneous mutations in vivo, especially in view of the lack of thymine-specific mismatch repair systems with specificity and efficiency comparable to that of uracil excision repair systems.     

Chemical Display of Pyrimidine Bases Flipped Out by Modification-Dependent Restriction Endonucleases of MspJI and PvuRts1I Families

The epigenetic DNA modifications 5-methylcytosine (5mC) and 5-hydroxymethylcytosine (5hmC) in eukaryotes are recognized either in the context of double-stranded DNA (e.g., by the methyl-CpG binding domain of MeCP2), or in the flipped-out state (e.g., by the SRA domain of UHRF1). The SRA-like domains and the base-flipping mechanism for 5(h)mC recognition are also shared by the recently discovered prokaryotic modification-dependent endonucleases of the MspJI and PvuRts1I families. Since the mechanism of modified cytosine recognition by many potential eukaryotic and prokaryotic 5(h)mC “readers” is still unknown, a fast solution based method for the detection of extrahelical 5(h)mC would be very useful. In the present study we tested base-flipping by MspJI- and PvuRts1I-like restriction enzymes using several solution-based methods, including fluorescence measurements of the cytosine analog pyrrolocytosine and chemical modification of extrahelical pyrimidines with chloroacetaldehyde and KMnO₄. We find that only KMnO₄ proved an efficient probe for the positive display of flipped out pyrimidines, albeit the method required either non-physiological pH (4.3) or a substitution of the target cytosine with thymine. Our results imply that DNA recognition mechanism of 5(h)mC binding proteins should be tested using a combination of all available methods, as the lack of a positive signal in some assays does not exclude the base flipping mechanism.     

Evidence for a near UV-induced photoproduct of 5-hydroxymethylcytosine in bacteriophage T4 that can be recognized by endonuclease V

Summary Non-photoreactivable endonuclease V-sensitive sites have been detected in the DNA of wild type bacteriophage T4 irradiated with near UV light (320 nm). Such sites were not detected in the DNA of (a) wild type T4 irradiated with far UV (254 nm) or (b) in T4 mutants in which non-glucosylated 5-hydroxy-methylcytosine (5HMC) or cytosine replaces glucosylated 5HMC normally present in T4, irradiated with 320 nm or 254 nm light. Although the non-photoreactivable sites accounted for 50% of the endonuclease V-sensitive sites in the DNA of glucosylated T4 irradiated with near UV, there was very little difference in the sensitivities of T4 containing glucosylated 5HMC, non-glucosylated 5HMC and cytosine to near UV (313 nm). We propose that the photoproduct responsible for the non-photoreactivable, but endonuclease V-sensitive, sites in glucosylated DNA is formed from glucosylated 5HMC and that a similar photoproduct is formed from non-glucosylated 5HMC or cytosine in the appropriate phage strains. We further propose that the glucosylated 5HMC photoproduct is non-photoreactivable whereas the cytosine and non-glucosylated 5HMC photoproducts are photoreactivable and are therefore possibly cyclobutane dimers.AECL Refence No. 6370Communicated by B.A. Bridges     

Role of uracil-DNA glycosylase in the repair of deaminated cytosine residues of DNA in Escherichia coli.

Uracil-DNA glycosylase, which acts specifically on uracil-containing DNA, was purified 250-fold from an extract of Escherichia coli 1100. The enzyme releases free uracil from DNA, producing alkali-labile apyrimidinic sites in the DNA. The enzyme is active on both native and heat-denatured DNA of phage PBS1, which contains uracil in place of thymine. piX174 DNA which had been treated with bisulfite and then at alkaline pH was susceptible to the action of uracil-DNA glycosylase. Since DNA treated with bisulfite alone was less susceptible to the enzyme, it is likely that the enzyme recognizes deaminated cytosine, namely uracil, but not bisulfite adducts of uracil and cytosine in the treated DNA. DNA treated with nitrite or hydroxylamine was not attacked by the enzyme. Enzyme activity acting on bisulfite-treated DNA was absent from an extract of E. coli mutant BD10 (ung). The mutant exhibited higher sensitivity to bisulfite than did the wild-type strain and was unable to reactivate phage T1 pre-exposed to bisulfite and weak alkali.     

Dnmt2 is the most evolutionary conserved and enigmatic cytosine DNA methyltransferase in eukaryotes

Dnmt2 is the most strongly conserved cytosine DNA methyltransferase in eukaryotes. It has been found in all organisms possessing methyltransferases of the Dnmt1 and Dnmt3 families, whereas in many others Dnmt2 is the sole cytosine DNA methyltransferase. The Dnmt2 molecule contains all conserved motifs of cytosine DNA methyltransferases. It forms 3D complexes with DNA very similar to those of bacterial DNA methyltransferases and performs cytosine methylation by a catalytic mechanism common to all cytosine DNA methyltransferases. Catalytic activity of the purified Dnmt2 with DNA substrates is very low and could hardly be detected in direct biochemical assays. Dnmt2 is the sole cytosine DNA methyltransferase in Drosophila and other dipteran insects. Its overexpression as a transgene leads to DNA hypermethylation in all sequence contexts and to an extended life span. On the contrary, a null-mutation of the Dnmt2 gene leads to a diminished life span, though no evident anomalies in development are observed. Dnmt2 is also the sole cytosine DNA methyltransferase in several protists. Similar to Drosophila these protists have a very low level of DNA methylation. Some limited genome compartments, such as transposable sequences, are probably the methylation targets in these organisms. Dnmt2 does not participate in genome methylation in mammals, but seems to be an RNA methyltransferase modifying the 38th cytosine residue in anticodon loop of certain tRNAs. This modification enhances stability of tRNAs, especially in stressful conditions. Dnmt2 is the only enzyme known to perform RNA methylation by a catalytic mechanism characteristic of DNA methyltransferases. The Dnmt2 activity has been shown in mice to be necessary for paramutation establishment, though the precise mechanisms of its participation in this form of epigenetic heredity are unknown. It seems likely, that either of the two Dnmt2 activities could become a predominant one during the evolution of different species. The high level of the Dnmt2 evolutionary conservation proves its activity to have a significant adaptive value in natural environment.     

Raman microspectroscopic study of effects of Na(I) and Mg(II) ions on low pH induced DNA structural changes

In this work a confocal Raman microspectrometer is used to investigate the influence of Na(+) and Mg(2+) ions on the DNA structural changes induced by low pH. Measurements are carried out on calf thymus DNA at neutral pH (7) and pH 3 in the presence of low and high concentrations of Na(+) and Mg(2+) ions, respectively. It is found that low concentrations of Na(+) ions do not protect DNA against binding of H(+). High concentrations of monovalent ions can prevent protonation of the DNA double helix. Our Raman spectra show that low concentrations of Mg(2+) ions partly protect DNA against protonation of cytosine (line at 1262 cm(-1)) but do not protect adenine and guanine N(7) against binding of H(+) (characteristic lines at 1304 and 1488 cm(-1), respectively). High concentrations of Mg(2+) can prevent protonation of cytosine and protonation of adenine (disruption of AT pairs). By analyzing the line at 1488 cm(-1), which obtains most of its intensity from a guanine vibration, high magnesium salt protect the N(7) of guanine against protonation. A high salt concentration can prevent protonation of guanine, cytosine, and adenine in DNA. Higher salt concentrations cause less DNA protonation than lower salt concentrations. Magnesium ions are found to be more effective in protecting DNA against binding of H(+) as compared with calcium ions presented in a previous study. Divalent metal cations (Mg(2+), Ca(2+)) are more effective in protecting DNA against protonation than monovalent ions (Na(+)).     

Protection of DNA by alpha/beta-type small,acid-soluble proteins from Bacillus subtilis spores against cytosine deamination

Spores of Bacillus subtilis contain high levels of proteins, termed alpha/beta-type small, acid-soluble proteins (SASP), that protect the spore's DNA against different types of DNA damage. We tested one such protein, SspC, and two of its variants for their ability to protect plasmid DNA against hydrolytic deamination of cytosine to uracil. If unrepaired, such damage to DNA causes C to T mutations. We found that one SspC variant, SspC(Delta 11-D13K), protected DNA against cytosine deamination at two different temperatures (45 and 70 degrees C) and pH values (5.2 and 7.9), reducing the rate of deamination by as much as 10-fold. At 70 degrees C, pH 7.9, the wild-type SspC and its variant, SspC(Delta 11), provided little protection against deamination but were effective in protecting DNA at 45 degrees C, pH 7.9. Parallel studies of the abilities of these proteins to protect DNA against restriction digestion revealed that there was a good correlation between the abilities of the proteins to protect against restriction endonucleases and reductions in cytosine deaminations. These results show that the binding of SspC variants to DNA can prevent attack on DNA bases by water and suggest a new general mechanism by which DNA-binding proteins in cells may be able to protect chromosomes from endogenous and exogenous reactive chemicals by excluding them from the vicinity of DNA.     

The use of permanganate as a sequencing reagent for identification of 5-methylcytosine residues in DNA.

The use of permanganate as a reagent for DNA sequencing by chemical degradation has been studied with respect to its specificity for 5-methylcytosine residues. At weakly acidic pH and room temperature, 0.2 mM potassium permanganate reacts preferentially with thymine, 5-methylcytosine, and to a lesser extent with purine residues, while cytosine remains essentially intact. Permanganate oxidation is, therefore, a suitable DNA sequencing reaction for positive discrimination between 5-methylcytosine and unmethylated cytosine.     

i-Motif DNA: Structure,stability and targeting with ligands

i-Motifs are four-stranded DNA secondary structures which can form in sequences rich in cytosine. Stabilised by acidic conditions, they are comprised of two parallel-stranded DNA duplexes held together in an antiparallel orientation by intercalated, cytosine–cytosine⁺ base pairs. By virtue of their pH dependent folding, i-motif forming DNA sequences have been used extensively as pH switches for applications in nanotechnology. Initially, i-motifs were thought to be unstable at physiological pH, which precluded substantial biological investigation. However, recent advances have shown that this is not always the case and that i-motif stability is highly dependent on factors such as sequence and environmental conditions. In this review, we discuss some of the different i-motif structures investigated to date and the factors which affect their topology, stability and dynamics. Ligands which can interact with these structures are necessary to aid investigations into the potential biological functions of i-motif DNA and herein we review the existing i-motif ligands and give our perspective on the associated challenges with targeting this structure.     

Myxosporea (Myxozoa,Cnidaria) Lack DNA Cytosine Methylation

DNA cytosine methylation is central to many biological processes, including regulation of gene expression, cellular differentiation, and development. This DNA modification is conserved across animals, having been found in representatives of sponges, ctenophores, cnidarians, and bilaterians, and with very few known instances of secondary loss in animals. Myxozoans are a group of microscopic, obligate endoparasitic cnidarians that have lost many genes over the course of their evolution from free-living ancestors. Here, we investigated the evolution of the key enzymes involved in DNA cytosine methylation in 29 cnidarians and found that these enzymes were lost in an ancestor of Myxosporea (the most speciose class of Myxozoa). Additionally, using whole-genome bisulfite sequencing, we confirmed that the genomes of two distant species of myxosporeans, Ceratonova shasta and Henneguya salminicola, completely lack DNA cytosine methylation. Our results add a notable and novel taxonomic group, the Myxosporea, to the very short list of animal taxa lacking DNA cytosine methylation, further illuminating the complex evolutionary history of this epigenetic regulatory mechanism.