Effect of alkylation on the secondary structure of DNA

S1 nuclease hydrolysis and bezoylated naphthoylated DEAE-cellulose (BND-cellulose) chromatography have been used to demonstrate that alkylation of DNA by dimethyl sulfate at neutral pH leads to the production of partially denatured molecules under conditions where no significant depurination occurs. DNA was alkylated with increasing concentrations of the alkylating agent, and subjected to enzymatic degradation and binding to BND cellulose. An increasing degree of DNA hydrolysis and adherence to BND cellulose was seen. On hydroxyapatite chromatography the alkylated DNA still eluted at the position of double-stranded molecules suggesting the presence of partially denatured regions. The presence of salt had a preventive effect on such denaturation.     

Effect of alkylation with streptozotocin on the secondary structure of DNA

S₁ nuclease hydrolysis and hydroxyapatite chromatography were used to study the effect of the alkylating antibiotic, streptozotocin, on the secondary structure of DNA. Native calf thymus DNA was alkylatedin vitro with increasing concentrations of streptozotocin and subjected to S 1 nuclease hydrolysis. An increasing degree of DNA degradation was seen, suggesting a destabilization of the secondary structure. Indirect evidence, deduced from alkaline hydrolysis, effect of NaCl on S₁ nuclease hydrolysis, and hydroxyapatite chromatographic analysis of alkylated DNA, suggested a significant alkylation of DNA phosphates in addition to DNA bases. Nictotinamide has been reported to alter the cytotoxic and carcinogenic effects of streptozotocin. Our experiments indicate that in the presence of nicotinamide, streptozotocin causes the formation of a greater proportion of alkylated bases in relation to alkyl phosphotriesters. This may have significance in relation to the differential cytotoxicity of streptozotocin in the absence and presence of nicotinamide.     

Effect of riboflavin and light on the secondary structure of DNA

S1 nuclease hydrolysis and benzoylated naphthoylated DEAE cellulose (BND-cellulose) chromatography have been used to study the effect of riboflavin and visible light on DNA. Native calf thymus DNA was incubated with riboflavin in the presence of fluorescent light for various time periods and subjected to S1 nuclease hydrolysis. An increasing degree of DNA degradation was seen suggesting a destabilization of the secondary structure. A decrease in melting temperature was also observed. Incubation with riboflavin and illumination caused adherence to BND-cellulose indicating the production of single stranded regions or breaks in the native double stranded molecules. However, when incubation was done in dark and in the presence of triplet excited state quencher, potassium iodide, a reduced adherence of DNA to BND-cellulose was seen. Plasmid pBR322 DNA was also treated with riboflavin under these conditions and subjected to agarose gel electrophoresis. No degradation could be seen in dark incubated and potassium iodide treated samples. These results indicate that the adherence of DNA to BND-cellulose in dark is possibly due to the binding of aromatic residues to the resin suggesting the formation of a complex between riboflavin and DNA.     

S1 nuclease does not cleave DNA at single-base mis-matches

Three assays have been designed to detect the cleavage of duplex phi X174 DNA at single-base mis-matches. Studies with S1 nuclease failed to detect cleavage at mis-matches. S1 nuclease digestion at 37 and 55 degrees C failed to produce a preferential degradation of a multiply mis-matched heteroduplex when compared to a mis-match-free homo-duplex as analyzed by sedimentation on sucrose gradients. Other heteroduplex templates were not cleaved by S1 nuclease at a defined single-base mis-match when assayed by gel electrophoresis or by marker rescue. In all cases, the amount of S1 nuclease employed was at least 10-times more than that required to render a single-stranded phi X174 DNA molecule completely acid soluble. The rate of hydrolysis of single-base mis-matches by S1 nuclease was estimated to be less than 0.016% of the rate at a base in single-strand phi X174 DNA. In no instance did we detect activity by S1 nuclease directed at mis-matched sites in our template molecules. Similarly, the single-strand specific endonuclease from Neurospora crassa does not cleave heteroduplex templates at a defined single-base mis-match when assayed by marker rescue.     

In vitro studies on mild alkali induced lesions in DNA.

S1 nuclease hydrolysis, benzoylated naphthoylated DEAE cellulose (BND-cellulose) chromatography as well as certain immunological and genetic techniques have been used to evaluate the effect of mild alkali (pH10.0) on the DNA molecule. Native calf thymus DNA after exposure to alkaline pH10.0 when subjected to S1 nuclease hydrolysis released significant amount of acid soluble nucleotides as compared to the untreated control. With pBR322 DNA, the population of linear DNA species increased on S1 digestion with concomitant reduction in the supercoiled form. BND cellulose chromatographic studies also suggested the formation of single strandedness and/or distortions in the alkali treated DNA molecule. Antisera raised against the alkali treated DNA exhibited high cross-reactivity with both single stranded and Z DNA. Moreover, a significant reduction in transformation frequency of the treated DNA molecule compared with the untreated control further ascertained the structural alterations in DNA as a result of exposure to mild alkali.     

Elimination of double strand nuclease activity from S1 nuclease prepared from crude alpha amylase.

Single strand-specific s1 nuclease prepared as previously described from crude alpha amylase by DEAE-cellulose chromatography also contains nuclease which degrades double strand nucleic acid. The double strand activity can be removed by repeating the DEAE-cellulose chromatography procedure at least two additional times. S1 nuclease prepared by this procedure does not degrade double strand sheared DNA as measured by Sephadex chromatography. Under the same conditions single strand DNA is completely degraded. Thus, S1 nuclease prepared by this procedure is suitable for use in removing single strand regions in DNA/DNA duplexes and DNA/RNA hybrids.     

Kinetic studies of the hydrolysis of platinum-DNA complexes by nuclease S1

The antitumor agent cis-diamminedichloroplatinum(II) (cis-DDP) reacts covalently with DNA and disrupts its secondary structure. Damaged DNA, but not native DNA, is readily digested by S1 nuclease, an endonuclease specific for single stranded polynucleotides. We have measured S1 nuclease digestion of platinated DNA by the release of platinum-DNA adducts and compared it with digestion of unplatinated DNA. The rate of hydrolysis of damaged substrate from platinum-DNA complexes was less than the overall rate of digestion of nucleotides. Similar results were observed for platinum-DNA complexes in native, denatured or renatured conformations. The hydrolysis of denatured platinum-DNA complexes, rb = 0.075 platinum per nucleotide, obeyed Michaelis-Menten kinetics. Taking into account the level of DNA damage, Vm, for the release of platinated adducts was 0.6 times smaller than for digestion of unplatinated DNA. Km values and competition experiments indicated that the enzyme bound equally well to platinated and unplatinated substrates. Similar results were obtained for denatured DNA complexes with trans-DDP while [PtCl(diethylenetriamine)]Cl had no influence on nuclease digestion. These results suggest that bifunctional platinum-DNA lesions have contradictory effects on the hydrolysis of double stranded DNA by S1 nuclease. On one hand they create nuclease sensitive substrate by disrupting DNA secondary structure. On the other, they inhibit digestion of the damaged strand by increasing the activation energy for hydrolysis.     

Evidence for covalent binding between phosphopeptides and terminal deoxynucleotides in highly purified calf thymus DNA

Summary Highly purified DNA from calf thymus nuclei (N-DNA) was found to cleave after reaction with a chelating agent and subsequent dialysis. During the cleavage phosphopeptides (PPs) were released into the dialysates. At the end of the cleavage, approximately one half of the PP material remained with the DNA. Since it was so strongly bound, it was considered to be retained in the DNA structure by covalent bonding. In order to confirm this, a commercial DNA (S-DNA) was ultrasonicated and digested with pancreatic DNAase, exonuclease III, and S1 nuclease. DEAE Sephacel chromatography of the digested material yielded 5 fractions. The fraction 2, having the highest proportion of proteinaceous material, was digested with Pronase. Amino acid analysis of the hydrolysis mixture yielded phosphoserine (Pser), asp, thr, ser, glu, gly, ala, val, ile, leu, and arg. The mixture was chromatographed again on DEAE Sephacel. From this a single fraction, number 5, was found to contain both deoxynucleotides and the amino acids, Pser, asp, ser, glu, and gly in a molar ratio of > 7:3:2:2:5. The mixture obtained by hydrolysis of this fraction with snake venom diesterase was again chromatographed on DEAE Sephacel. This fractionation gave two main peaks, one corresponding to the same 5 amino acids and the other to deoxynucleotide material. From this it was concluded that the fraction used for diesterase digestion consisted of deoxynucleotide-amino acids, with covalent diester bonds between the deoxynucleotide and amino acid portions.Dedicated to Prof. L.E. Feinendegen on the occasion of his 60th birthday     

Purification and properties of a DNase inhibitor from Nicotiana tabacum cell cultures

Extraction of Nicotiana tabacum cell cultures, chromatography on DEAE-cellulose and gel filtration resulted in a homogeneous protein (Mr = 14500), which strongly reduces the hydrolysis of Escherichia coli DNA by DNase I. DNA degradation by micrococcal nuclease is not inhibited. The inhibitor protein interacts with DNase I in the absence of DNA, as determined by the partial quenching of protein intrinsic fluorescence; a 1:1 stoichiometry is deduced. From the reduction of DNase I activity with increasing inhibitor concentration apparent equilibrium constants for the inhibitor X DNase-I complex have been calculated. This interaction is strongly temperature-dependent; at 20 degrees C and 26 degrees C dissociation constants of 5 nM and 110 nM, respectively, were determined. As a consequence a rather high enthalpy of interaction can be estimated.     

The specificity of S1 nuclease toward RNA-DNA hybrids as studied using isotopes of phosphorus-32 and phosphorus-33.

Hybrids were formed from Bacillus cereus DNA and ribosomal RNA. They were treated with various combination of S1 nuclease and ribonuclease, and the molar ratios of the RNA and DNA moieties remaining in the treated hybrids were determined using a 32P-33P dual-label technique. It was found that both S1 nuclease and ribonuclease are required to give hybrid with RNA and DNA in a perfect 1:1 molar ratio. It was noted that the dual-label technique which employs orthophosphate as the sole phosphorus source for both labels gives unambiguous molar ratios and obviates the need to calculate specific activities, make quench corrections, or correct for base content.     

Phospholipids from Bacillus stearothermophilus

The lipids of Bacillus stearothermophilus strain 2184 were extracted with chloroform-methanol and separated into neutral lipid and three phospholipid fractions by chromatography on silicic acid columns. The phospholipids were identified by specific staining reactions on silicic acid-impregnated paper, by chromatography of alkaline and acid hydrolysis products, and by determination of acyl ester:glycerol:nitrogen:phosphorus molar ratios. The total extractable lipid was 8% of the dry weight of whole cells and consisted of 30 to 40% neutral lipid and 60 to 70% phospholipid. The phospholipid consisted of diphosphatidyl glycerol (23 to 42%), phosphatidyl glycerol (22 to 39%), and phosphatidyl ethanolamine (21 to 32%). The concentrations of diphosphatidyl glycerol and phosphatidyl glycerol were lower in 2-hr cells than in 4- and 8-hr cells. Whole cells were fractionated by sonic treatment and differential centrifugation. The total lipid content, expressed in per cent of dry weight of each fraction was: whole protoplasts, 10%; membrane fraction, 18%; 30,000 x g particulate fraction, 22%; and 105,000 x g particulate fraction, 26%. The relative phospholipid concentrations in each fraction were about the same. As had been previously reported, none of the phospholipid was stable to alkaline hydrolysis.     

The isolation and partial characterization of glycolipids of normal human leucocytes

1. The lipids of purified human leucocytes were extracted with chloroform-methanol and the extract was washed with water. Glycolipids, isolated by Florisil chromatography, were subjected to mild alkaline hydrolysis and the alkali-resistant fraction was fractionated on a silicic acid column. 2. Three classes of glycolipid were separated. The less polar, containing 3.6% of the total glycolipid hexose as galactose, was tentatively identified as ceramide monohexoside. The major glycolipid fraction was characterized as ceramide dihexosides. The more polar glycolipids comprised 1.6% of the total glycolipid hexose as galactose and glucose (in the molar ratio 2:1) and were non-acidic. This class was separated as a mixture containing ninhydrin-positive glycolipids. 3. The ceramide dihexosides taken from two leucocyte preparations accounted for 15.2% and 16.4% by weight of the total lipids. 4. The carbohydrate moiety of the ceramide dihexosides contained galactose and glucose in the molar ratio 2:1. Partial acid hydrolysis and paper chromatography indicated that the hexoses are present as disaccharides, lactose being identified as one of them. 5. Palmitic acid (C(16:0)) and nervonic acid (C(24:1)) were the major fatty acids of this glycolipid. Hydroxy fatty acids were not detected.     

Formation of strand breaks and interstrand cross-links in DNA by methylglyoxal

Methylglyoxal (MG), a dietary mutagen, is present in various frequently consumed beverages and foods and in cigarette smoke. A combination of S1 nuclease hydrolysis and alkaline unwinding assay was used to demonstrate the formation of single-strand breaks and interstrand cross-links in DNA upon treatment with MG. Calf thymus DNA, when treated with increasing concentrations of MG, showed an increasing degree of S1 nuclease hydrolysis. It also showed the formation of an increasing number of strand breaks per molecule as determined by an alkaline unwinding assay. Incubation of DNA with relatively higher concentrations of methylglyoxal or prolonged treatment gave increased thermal melting temperatures and an enhanced rate of reannealing after thermal denaturation. These results indicated the formation of interstrand cross-links. Upon treatment with MG, A-T base pair depleted DNA showed a reduced number of single-strand break formation. It also showed a significantly lower decrease in Tm as compared with MG-treated normal DNA. These results showed that under the conditions used, MG primarily reacts with A-T base pairs in duplex DNA.     

Caffeine enhancement of digestion of DNA by nuclease S1.

The activity of Aspergillus orzae nuclease S1 on DNA has been investigated under varying pH and metal ion conditions. Nuclease S1 was found to preferentially digest denatured DNA. With native DNA as substrate the enzyme could only digest the DNA when caffeine was added to the reaction mixture. The enzyme was more active in sodium acetate buffer (pH 4.5), than in either standard saline citrate (PH 7.0) or sodium phosphate buffer (pH 6.8). Caffeine was also found to affect the thermal stability of DNA, resulting in a melting profile characterized by two transitions. The first transition (poorly defined) was below the normal melting temperature of the DNA, while the next transition was at the normal melting temperature of the DNA, while the next transition was at the normal melting temperature of the DNA. The susceptibility of caffeine-treated DNA to nuclease digestion seems to be a result of the local unwinding that caffeine causes in the regions of DNA that melt in the first transition. This selective destabilization presumably sensitizes the unwound regions to nuclease hydrolysis. The hydrolysates of the DNA digested by nuclease S1 were subjected first to ion exchange chromatography followed by paper chromatography. The results from this partial characterization of the digestion products showed that they contain mononucleotides as well as oligonucleotides of varying lengths. The base composition of the mononucleotide digests suggests that caffeine has greater preference for interacting with A-T base-pairs in DNA.     

Identification and characterization of mannosyl retinyl phosphate occurring in rat liver and intestine invivo

A study was conducted to determine whether mannosyl retinyl phosphate occurred in rat liver and intestine in vivo, and, if so, to partially purify it and investigate its properties. After injection of [(3)H]retinol and [(14)C]mannose, a chloroform-methanol 2:1 extract of rat liver and small intestinal mucosa yielded two (3)H/(14)C-labeled peaks on DEAE-cellulose column chromatography: peak I eluted with 10 mM and peak II eluted with 29 mM ammonium acetate. Peak II, subjected to silicic acid column chromatography, gave principally two (3)H/(14)C-labeled fractions, one eluted with chloroform-methanol 2:1 and the other with chloroform-methanol 1:1. The latter showed, on thin-layer chromatography in a chloroform-methanol-water 60:25:4 system, an R(f) of 0.25 (with coincidence of the (3)H and (14)C radioactivity), which is identical to the R(f) of authentic mannosyl retinyl phosphate. The chloroform-methanol 1:1 peak, on mild acid hydrolysis, yielded [(3)H]retinol (identified by two thin-layer chromatography systems), [(14)C]mannose, and [(14)C]-mannose phosphate (identified by paper chromatography). On mild alkali hydrolysis, the peak yielded [(3)H]retinol and [(14)C]mannose phosphate. The substance eluted in the chloroform-methanol 1:1 peak from silicic acid was therefore concluded to be mannosyl retinyl phosphate. When chromatographed on silicic acid, peak I from the DEAE-cellulose column primarily showed a fraction eluted with chloroform-methanol 2:1. When chromatographed on thin-layer plates in the above solvent, this fraction showed an R(f) of 0.3, with coincidence of (3)H and (14)C radioactivity; it was resistant to mild acid hydrolysis, mild and strong alkali hydrolysis, and glucuronidase action. Mannosyl retinyl phosphate occurs, therefore, in vivo in liver and intestinal mucosa, and it is accompanied by a closely similar, though slightly less polar, compound that remains unidentified.     

Parameters influencing the flow cytometric analysis of DNA sensitivity to nuclease S1

Some parameters that influence the analysis in situ of DNA sensitivity to digestion with nuclease S1 have been studied in isolated HeLa nuclei with flow cytometry. DNA staining with the intercalating fluorochrome propidium iodide allowed the nucleolytic activity on double-stranded (ds) DNA to be determined by monitoring the relative reduction in nuclear fluorescence intensity. Nuclei isolated in buffer at low ionic strength in order to decondense chromatin fibres, showed a lower fluorescence intensity than nuclei with native chromatin, after digestion with nuclease S1 under identical conditions. Nuclei prepared with dispersed chromatin and digested with increasing amounts of enzyme showed a decrease in fluorescence intensity that reached a limit value at about 50% of the value of undigested control samples. On the other hand, in nuclei with native chromatin, fluorescence intensity decreased only about 18%. The NaCl concentration in the reaction buffer strongly influenced the DNA sensitivity to S1 nuclease. By increasing salt molarity from 5 mM to 200 mM, the digestion of dsDNA was significantly reduced as also shown by the amount of released nucleotides from purified calf thymus DNA. The detection of DNA sensitivity to nuclease S1, as assessed by the cytometric method, was shown to be more sensitive than a biochemical technique involving hydrolysis of purines. These results indicate that both the procedure for nuclei isolation and the digestion conditions have to be carefully controlled when evaluating in situ the presence of S1-sensitive sites.     

Characterization of a new phosphonocerebroside, N-methyl-2-aminoethylphosphonylglucosylceramide, from the antarctic krill, Euphausia superba

A novel phosphonglycosphingolipid was purified from the whole tissue of the antarctic krill, Euphausia superba by successive column chromatography on DEAE- and QAE-Sephadex and silicic acid (Iatrobeads). The structure was elucidated by means of IR, FAB-MS, 1H-NMR, GC and GC-MS analyses of the water-soluble products after complete and partial acid hydrolysis, and methylation analysis of a product of hydrogen fluoride degradation; it was identified to be a phosphonocerebroside, 6'-O-(N-methyl-2-aminoethylphosphonyl)Glcp beta 1----1ceramide. The ceramide moiety was composed of tetradecasphingenine and octadecasphingatriene as the main sphingoids, and monounsaturated C22- and C24-acids and their 2-hydroxy homologues as the major fatty acids.     

Interaction of intercalating and non-intercalating agents with DNA: use of hydroxyapatite chromatography and S1 nuclease

We have used hydroxyapatite (HA) chromatography and S1 nuclease hydrolysis to study the modification in the secondary structure of DNA caused by certain intercalating and non-intercalating ligands. The principal conclusions of HA experiments were as follows: (1) when native DNA, complexed with drugs believed to bind to DNA by intercalation (ethidium bromide, acridine orange, actinomycin D and acriflavin), is chromatographed on HA a lower affinity of DNA for HA is observed; also, the DNA elutes from HA columns as a drug-DNA complex; (ii) ligands that are known to interact with DNA by surface interactions do not show these effects; (iii) it may be possible to quantitate the binding of the intercalating drug to DNA and to determine its degree of binding by HA chromatography. Possibly, intercalation causes a change in the configuration of the sugarphosphate backbone of DNA, resulting in an altered steric orientation or 'burial' of phosphate groups with reduced availability for surface interactions with HA. S1 nuclease was used to determine the thermal melting profiles of DNA complexed with ethidium bromide and acridine orange. The melting profile in both cases was found to be biphasic with considerably reduced denaturation even at 95 degrees C. This is accounted for by the property of intercalating agents of stabilizing the secondary structure of DNA and the reported preference in binding to G-C base pairs.     

Isolation and comparison of two molecular species of the BAL 31 nuclease from Alteromonas espejiana with distinct kinetic properties

The extracellular nuclease from Alteromonas espejiana sp. BAL 31 can be isolated as two distinct proteins, the "fast" (F) and "slow" (S) species, both of which have been purified to homogeneity. The F and S species of the nuclease have molecular weights, respectively, of 109 X 10(3) and 85 X 10(3), and both are single polypeptide chains with an isoelectric pH near 4.2. Both species catalyze the degradation of single-stranded and linear duplex DNAs to 5'-mononucleotides. The degradation of linear duplex DNA occurs through a terminally directed hydrolysis mechanism that results in the removal of nucleotides from both the 3' and 5' ends. Apparent Michaelis constants (Km) have been obtained for the exonuclease activities of both species and for the activity against single-stranded DNA of the S species. The Km for the hydrolysis of single-stranded DNA catalyzed by the F species has not been obtained because the reaction velocity was maximal even at the lowest substrate concentrations accessible in the photometric assay. The ratio of the turnover numbers for the exonuclease activities of the two species indicates that the F species will shorten linear duplex DNA at a rate 27 +/- 5 (S.D.) times faster than an equimolar concentration of the S species in the limit of high substrate concentration, while the corresponding ratio for the activities against single-stranded DNA (1.2 +/- 0.1) shows that the two species are similar with respect to hydrolysis of this substrate. In the limit of high substrate concentrations, the F and S species break phosphodiester bonds in single-stranded DNA at rates 1.3 +/- 0.3 and 33 +/- 2 times those for the exonucleolytic degradation of linear duplex DNA, respectively. It has not been established whether the two species are physically related.     

Influence of nonhistone chromatin protein HMG-1 on the enzymatic digestion of purified DNA

The effect of chicken erythrocyte High Mobility Group protein 1 (HMG-1) on the enzymatic hydrolysis of purified double-stranded and single-stranded bacteriophage lambda DNA was studied. HMG-1 was found to inhibit the digestion of single- and double-stranded DNA by S1 nuclease and DNase I, respectively. HMG-I increased the rate of hydrolysis of double-stranded DNA by micrococcal nuclease, particularly at low HMG-1/DNA ratios, and had little effect on the hydrolysis of single-stranded DNA by micrococcal nucleases, even at high HMG-1 DNA ratios. We also present a semi-quantitative estimate that HMG-1 and HMG-2 occur in chromatin from rapidly dividing, cultured rat hepatoma cells at about 8 times the level that they occur in adult rat liver chromatin.