The fate of18O labelled phosphate in soil/plant systems

KH₂PO₄ labelled with¹⁸O and³²P was mixed with soil that was placed in pots in which grass seed was sown. Grass samples were taken after 5, 7, and 12 weeks. The dilution factor (DF) for¹⁸O in the first cut was much greater than the DF for³²P, indicating that the bulk of the¹⁸O in the absorbed phosphate was lost. The DFs for¹⁸O and³²P determined in phosphate extracted from the soil at the end of the pot experiment indicated that half the¹⁸O excess in the applied phosphate was lost.A succeeding experiment showed no loss of¹⁸O when the treated soil was shaken for 3 months with water to which a germicide was added. Thus, the loss of¹⁸O was presumably caused by biochemical processes which brought about the replacement of¹⁸O by¹⁶O. We suggest that the loss of¹⁸O from applied labelled phosphate may be used as a measure of biological activity in soil.     

Vibrational analysis of nucleic acids. IV. normal modes of the DNA phosphodiester structure modeled by diethyl phosphate

Raman and ir spectra are reported for diethyl phosphate [(CH₃CH₂O)₂PO^-₂] and diethyl phosphate isotopomers incorporating carbon-13 at methylene group sites [(CH¹³₃CH₂O)₂PO^-₂] and deuterium substituents on methyl and methylene carbons [(CH₃CD₂O)₂PO^-₂, (CD₃CH₂O)₂PO^-₂ (CD₃CD₂O)₂PO^-₂]. The vibrational spectra are analyzed to develop a consistent set of assignments for the C-C-O-P(O^-₂)-O-C-C network, which serves as a model for the nucleic acid phosphodiester backbone. The present study resolves previously conflicting vibrational assignments for the phosphodiester skeleton and provides a firm empirical basis for interpreting conformationally sensitive modes of DNA and RNA. Ab initio vibrational analyses have also been conducted on the above isotopomers of diethyl phosphate in the trans-gauche-gauche-trans conformation, optimized using the 3-21+G^* basis set at the restricted Hartree-Fock level. The ab initio calculations are in good agreement with the empirical results, thus strengthening the proposed assignment scheme for Raman and infrared spectra. The present study provides a basis for improvement of empirical force fields utilized in previous normal coordinate analyses of the nucleic acid phosphodiester group. © 1996 John Wiley & Sons, Inc.     

The replication of mouse skin epidermal DNA to which is bound 7,12-dimethylbenz(a)anthracene

Experiments were carried out to determine in the intact mouse whether or not mouse skin epidermal DNA to which the polycyclic hydrocarbon DMBA was bound could serve as a template for further DNA replication. Mice which were treated topically with [³H]7,12-dimethylbenz(a)anthracene ([³H]DMBA) received 5-bromodeoxyuridine (BUdR) and 5-fluorouracil (5-FU) in order to incorporate BUdR into replicating DNA which was stimulated to undergo synthesis one or two days later. Epidermal DNA was put on a neutral CsCl gradient and binding of [³H]DMBA was found to both replicated and non-replicated DNA. Separation of the BUdR substituted and non-substituted parental strands of newly replicated DNA an on alkaline CsCl, Cs₂SO₄ gradient showed that the great majority of DMBA was bound to parental strand DNA. The possibility that [³H]DMBA binding was taking place at the same time that labeling with BUdR occurred was eliminated. Thus, these experiments showed that in the intact mouse, skin epidermal DNA to which DMBA is bound can serve as a template for further DNA synthesis.     

Mechanism of replication of phichi174 single-stranded DNA. IV. The parental viral strand is not conserved in the replicating DNA structure

The role of the infecting viral strand in the replication of bacteriophage φX174 replicative form DNA was studied by [³H]thymidine pulse-labeling Escherichia coli cells infected with ²H¹⁵N density-labeled phage. The products of a round of semi-conservative replicative form replication (in light medium) do not contain the original heavy viral strand by 15 minutes after infection or later in the presence of chloramphenicol. Similar results were obtained at earlier times in the absence of chloramphenicol. We conclude that the parental viral strand need not be conserved in the replicating DNA structure in succeeding rounds of replication.     

Structure of F-actin needles from extracts of sea urchin oocytes

The mouse L-cell line LD maintains its mitochondrial DNA genome in the form of a head-to-tail unicircular dimer of the monomeric 16,000 base-pair species. This situation permits a comparison of the mechanism of replication of this dimeric molecule with our previous studies of replication of monomeric mouse L-cell mitochondrial DNA. Whereas monomeric mitochondrial DNA requires about one hour for a round of replication, the dimeric molecule requires almost three hours. Denaturing agarose gel electrophoretic analyses of replicative intermediates reveals several discrete size classes of partially replicated daughter strands of dimeric mitochondrial DNA. This suggests that replication occurs with specific discontinuities in the rate of daughter strand synthesis. The strand specificity of these daughter strands was determined by hybridization with ³²P-labeled DNA representing either the heavy or light strand mitochondrial DNA sequence. The sizes and strand specificities of these discrete daughter strands indicate that the same set of control sequences is functional in both dimer and monomer mitochondrial DNA replication.Immediately following a round of replication, the majority of dimeric mitochondrial DNA molecules contain displacement loops, as assessed by their sensitivity to nicking within the displaced DNA strand by single-strand DNA specific S₁ nuclease under conditions which leave supercoiled DNA intact. This result is in contrast with the conformation of newly replicated monomeric mitochondrial DNA molecules, which lack both superhelical turns and displacement loops. This indicates that dimeric mitochondrial DNA proceeds through a different series of post-replicative processing steps than does monomeric mitochondrial DNA. We postulate that intermediates at late stages of dimeric mitochondrial DNA replication contain displacement loops which remain intact following closure of the full-length daughter strands.     

Covalent attachment of RNA to nascent DNA in mammalian cells

We have used the technique of phosphate transfer analysis to test for the presence of phosphodiester bonds linking ribonucleotides (on the 5′ side) to deoxyribonucleotides (on the 3′ side) in DNA newly synthesized within lysates or purified nuclei of mammalian cells. We have found that such covalent junctions between RNA and DNA are present at a frequency of one junction per newly synthesized DNA strand. The junctions are located close to the ends of the nascent DNA strands. The stretches of RNA at the junction are very short compared to the stretches of DNA. These properties are consistent with the conclusion by Reichard, Eliasson, and Söderman (1974) that short stretches of RNA are present on the 5′ ends of nascent DNA strands produced during replication of polyoma virus.     

The termini of bacteriophage T7 DNA

The termini of Escherichia coli phage T7 DNA have been labeled with ³²P by the polynucleotide kinase reaction. The DNA was fragmented, denatured, and annealed to denatured T7 DNA embedded in agar; elution was measured as a function of temperature. The terminal fragments were eluted from the gel at temperatures well below that of the bulk of the DNA, suggesting that these regions have a very high adenine-plus-thymine content. However, when DNA doubly labeled throughout at random by growth of the phage in [³H]thymidine and ³²PO₄, was denatured, annealed to the gel, and eluted as a function of temperature, the material eluting from the gel in this low-temperature range was about 50% adenine and thymine. Hence the melting behavior of the terminal fragments is not a result of a high adenine plus thymine content. By electrophoretic analysis of exonucleolytic digests of the T7 DNA it was shown that no unusual bases were present. It is suggested that the low thermal stability of the annealed terminal fragments is a consequence of the high guanine·cytosine regions being unavailable for hybridization, possibly because they are involved in intra-strand hydrogen bonding.     

Investigation of a Proposed Mechanism for Genotoxic Effects Induced by 2-Hydroxyalkylating Agents. Kinetics of Intramolecular Transesterification in Dithymidine 2-Hydroxyethyl-and 2-Hydroxypropyl Phosphate

Abstract

Alkylation of DNA gives rise to adducts, not only at the bases, but also at the phosphate groups giving phosphotriesters^1–3. 2-Hydroxy-alkylation of phosphodiester functions in DNA causes considerable strand breakage already in neutral solution⁴. This effect has been suggested to be involved in the higher genotoxicity of 2-hydroxyalkylating agents as compared to, for instance, the corresponding methoxy compounds⁵.     

Diurnal water balance of the cowpea fruit

The vascular network of the cowpea (Vigna unguiculata [L.] Walp.) fruit exhibits the anatomical potential for reversible xylem flow between seeds, pod, and parent plant. Feeding of cut shoots with the apoplast marker acid fuchsin showed that fruits imported regularly via xylem at night, less frequently in early morning, and only rarely in the afternoon. The dye never entered seeds or inner dorsal pod strands connecting directly to seeds. Root feeding (early morning) of intact plants with ³²PO₄ or ³H₂O rapidly (20 min) labeled pod walls but not seeds, consistent with uptake through xylem. Weak subsequent (4 hours) labeling of seeds suggested slow secondary exchange of label with the phloem stream to the fruit. Vein flap feeding of subtending leaves with [¹⁴C]sucrose, ³H₂O, and ³²PO₄ labeled pod and seed intensely, indicating mass flow in phloem to the fruit. Over 90% of the ¹⁴C and ³H of fruit cryopuncture phloem sap was as sucrose and water, respectively. Specific ³H activities of transpired water collected from fruits and peduncles were assayed over 4 days after feeding ³H₂O to roots, via leaf flaps, or directly to fruits. The data indicated that fruits transpired relatively less xylem-derived (apoplastic) water than did peduncles, that fruit and peduncle relied more heavily on phloem-derived (symplastic) water for transpiration in the day than at night, and that water diffusing back from the fruit was utilized in peduncle transpiration, especially during the day. The data collectively support the hypothesis of a diurnally reversing xylem flow between developing fruit and plant.     

Asymmetric distribution of exogenous thymidine among pyrimidine isostichs suggests compartmentalization of replicative DNA synthesis during regeneration in rat liver

The distribution of radioactivity among pyrimidine isostichs (or isoplyths) of DNA from 24-h regenerating rat liver was studied with [³H]Thd, [¹⁴C]orotate or with inorganic ³²P_i. Expression of incorporated radioactivity as log₁₀% of total radioactivity recovered for each of the 11 pyrimidine isostichs detected showed that radioactivity from [³H]Thd was asymmetrically distributed among the isostichs, i.e., ³H radioactivity failed to access regions of DNA yielding lower molecular weight pyrimidine isostichs as efficiently as it accessed regions yielding higher molecular weight pyrimidine isostichs. The thymine (T) content of isostichs exceeded that of cytosine (C), i.e., ratios for the first 10 isostichs averaged 1.43 ± 0.08 and 1.28 ± 0.05, depending on the method of analysis; furthermore, the ratio for isostich 1 was significantly higher than ratios for isostichs 2 through 10. Asymmetric distributions of [³H]Thd radioactivity also were seen at 18 or 30 h post-partial hepatectomy. Thus, radioactivity from [³H]Thd, a DNA precursor from the salvage pathway, failed to efficiently access lower molecuar weight isostichs despite thymine enrichment, suggesting that thymine moieties were supplied from additional sources. Radioactivity from [¹⁴C]orotate accessed lower molecular weight pyrimidine tracts more efficiently than [³H]Thd, but less efficiently than it accessed higher molecular weight isostichs, resulting in an asymmetric distribution of ¹⁴C radioactivity. This result suggested that appreciable quantities of thymine and cytosine moieties utilized for DNA synthesis were supplied de novo, but other sources also were utilized. Radioactivity from ³²P_i, a de novo precursor, was distributed symmetrically, i.e., the slope among lower molecular weight isostichs increased enough that it was indistinguishable from slopes for intermediate and higher molecular weight isostichs. Since ³²P radioactivity among lower molecular weight isostichs reflects appreciable contributions of de novo phosphate moieties from both pyrimidine- and purine-containing deoxynucleoside triphosphates, opportunities for observing contributions of ³²P radioactivity from pathways other than the de novo pathways appeared to lie beyond limits of detectability. The distribution of radioactivity from labeled DNA precursors among lower molecular weight pyrimidine tracts (a) indicate that thymine moieties are contributed by both salvage and de novo pathways; (b) support the possibility that cytosine moieties also are contributed by both pathways; and (c) support the ‘replitase’ concept for channeling dNTPs to replicating forks.     

Replication of bacteriophage M13. 8. Differential effects of rifampicin and nalidixic acid on the synthesis of the two strands of M13 duplex DNA

Replication of bacteriophage M13 replicative forms is inhibited by rifampicin, an antibiotic that specifically inhibits the Escherichia coli RNA polymerase, and by nalidixic acid, an inhibitor of phage and bacterial DNA replication. Synthesis of the M13 complementary strand during RF³ replication was at least tenfold more sensitive to inhibition by rifampicin and by nalidixic acid than was that of the viral strand. Since M13 complementary strand synthesis is relatively insensitive to chloramphenicol, an inhibitor of protein synthesis, its inhibition by rifampicin suggests that complementary strands are initiated during RF replication by an RNA priming mechanism similar to that involved in parental RF formation. The nalidixic acid-sensitivity of complementary strand synthesis during RF replication clearly distinguishes this process from the nalidixic acid-resistant formation of the parental complementary strand in the conversion of the infecting single strand to RF.Production of progeny viral strands is indirectly affected by rifampiein in two ways. It prevents the conversion of supercoiled RF (RFI) to the open form (RFII), an essential step both in RF replication and in single-strand synthesis. In addition, rifampiein interferes with the expression of gene 5, an M13 gene function required for the accumulation of progeny viral strands.     

E. COLI RNASE HI AND THE PHOSPHONATE-DNA/RNA HYBRID: MOLECULAR DYNAMICS SIMULATIONS

A model for the complex between E. coli RNase HI and the DNA/RNA hybrid (previously refined by molecular dynamics simulations) was used to determine the impact of the internucleotide linkage modifications (either 3′–O–CH₂–P–O–5′ or 3′–O–P–CH₂–O–5′) on the ability of the modified-DNA/RNA hybrid to create a complex with the protein. Modified internucleotide linkages were incorporated systematically at different positions close to the 3′-end of the DNA strand to interfere with the DNA binding site of RNase H. Altogether, six trajectories were produced (length 1.5). Mutual hydrogen bonds connecting both strands of the nucleic acids hybrid, DNA with RNase H, RNA with RNase H, and the scissile bond with the Mg⁺⁺ · 4H₂O chelate complex (bound in the active site) were analyzed in detail. Many residues were involved in binding of the DNA (Arg88, Asn84, Trp85, Trp104, Tyr73, Lys99, Asn100, Thr43, and Asn16) and RNA (Gln76, Gln72, Tyr73, Lys122, Glu48, Asn44, and Cys13) strand to the substrate-binding site of the RNase H enzyme. The most remarkable disturbance of the hydrogen bonding net was observed for structures with modified internucleotide linkages positioned in a way to interact with the Trp104, Tyr73, Lys99, and Asn100 residues (situated in the middle of the DNA binding site, where a cluster of Trp residues forms a rigid core of the protein structure).     

Triplex formation of chemically modified homopyrimidine oligonucleotides: thermodynamic and kinetic studies.

We have investigated effects of chemical modifications of a third strand on the thermodynamic and kinetic properties of the triplex formation between a 23-bp duplex and each of four kinds of 15-mer chemically modified third strands using isothermal titration calorimetry and interaction analysis system. The chemical modifications of the third strand included one base modification, with replacement of thymine by uracil; two sugar moiety modifications, RNA and 2'-O-methyl-RNA; and one phosphate backbone modification, with replacement of phosphodiester by phosphorothioate backbone. The thermodynamic and kinetic parameters obtained were similar in magnitude at room temperature for the triplex formation with the base-modified and the sugar-modified third strands. By contrast, binding constant for the triplex formation with the third strand containing phosphorothioate backbone was much smaller by a factor of 10 than that for the other triplex formations. Kinetic analyses have also demonstrated that the third strand containing phosphorothioate backbone was much slower in the association step and much faster in the dissociation step than the other third strands, which resulted in the much smaller binding constant. The reason for the instability of the triplex with the third strand containing phosphorothioate backbone will be discussed. We conclude that, at least in the triplex formation with the chemically modified third strands studied in the present work, the modification of phosphate backbone of the third strand produces more significant effect on the triplex formation than the modifications of base and sugar moiety.     

Characterization of Simian virus 40 DNA component II during viral DNA replication

Replicating molecules of Simian virus 40 DNA labeled during a short pulse with [³H]thymidine have been fractionated by ultracentrifugation methods and the open circular form (DNA component II) has been characterized. The pulse-labeled DNA component II is a relatively small constituent (1 to 3%) of the pool of replicating molecules. Examination of the circular (18 S) and linear (16 S) strands of DNA component II by alkaline sedimentation and by degradation using exonuclease III of Escherichia coli reveals that the newly synthesized DNA is principally in the linear strand. Cleavage of pulse-labeled DNA component II by an fi⁺, R-factor restriction endonuclease from E. coli demonstrates that the interruption in the pulse-labeled strand is specifically located at the termination point for replication.During a chase period of 20 minutes the amount of DNA component II increases to about 6 to 8% of the total labeled viral DNA. The kinetics of formation of superhelical, DNA component I and disappearance of replicative intermediates are linear during the chase period. After several hours of continuous labeling of replicating viral DNA, the DNA component II pool consists mainly of molecules labeled in both strands with the interruption non-specifically located in either strand. These molecules probably arise by the random introduction of single-strand breaks in newly synthesized DNA component I. During short periods of continuous labeling with [³H]thymidine, the ratio of DNA components I to II increases as a function of the pulse duration. These results support a model for 8V 40 DNA replication in which the open circular form is a precursor of the superhelical form.     

Repair Replication and Degradation of Bromouracil-Substituted DNA in Mammalian Cells after Irradiation with Ultraviolet Light

Ultraviolet (UV) light irradiation of HeLa cells in which bromouracil (BU) is substituted for thymine in one strand of the DNA, elicits a number of responses that occur predominantly in the BU strand. A small amount of degradation of both strands occurs, but the BU strand is degraded to a greater extent than the normal strand. Large UV doses (1000 erg/mm²) induce degradation of about 1.7% of the DNA within 6 hr of irradiation of unsubstituted cells; in BU-substituted cells under these conditions about 1.9% of the normal strand is degraded but 17.5% of the BU strand. After irradiation fresh bases are inserted into the BU strands at infrequent intervals throughout the DNA and this is presumed to represent repair of UV damage in the BU strands. After 1000 erg/mm² the majority (70%) of the thymidine incorporated enters the BU strand. Inhibitors of normal DNA synthesis, hydroxyurea and arabinosyl cytosine, do not appear to inhibit the repair of DNA. The increased sensitivity of mammalian cells that contain BU to irradiation may consequently be due to damage of the BU strand. A specific interference between BU and repair of DNA which leads to large amounts of DNA degradation in bacteria, does not seem to be important in the sensitization of mammalian cells with BU.     

Phosphate- N base hydrogen bonds involving proton transfer with reference to the non-enzymic hydrolysis of ATP

IR spectra of aqueous solutions of 1:1 mixtures of H₂PO₄^? and various N bases have been studied as models for (POH?N) → (P^?O?H⁺N) hydrogen bonds. 50% proton transfer is observed when the pKa of the protonated N base is 1.1 smaller than that of the phosphate group. The hydrogen bonds are easily polarizable near this equilibrium. These results strongly support the conclusion that such bonds contribute 1) to the self-association of ATP and ADP and 2) to the association of the hydrolysis products ADP and inorganic phosphate.     

Formation of the parental replicative form DNA of bacteriophage phi-X174 and initial events in its replication

Intracellular φX174 DNA was studied under a variety of conditions that prevent the replication of the parental replicative form DNA. These conditions included treatment with 150 μg of chloramphenicol per ml., the use of the rep₃⁻ mutation of the host cell, amber mutation (am 8) in the viral gene responsible for RF replication (gene A) ^† and combinations thereof. In all cases the majority of the parental RF was in the covalently closed form (RFI). The relative amount of RF with a discontinuity in one strand (RFII) in these cases was between 2 and 10% of the total RF and independent of the multiplicity of infection. The only exception was seen in infections of rep₃ cells with φX am 3 (a mutant in the lysis gene, gene E, used as a wild-type representative). In this case a fairly constant absolute amount of RFII (1 to 4 per cell), independent of the multiplicity of infection, was formed, consisting almost exclusively of a closed complementary and an open parental viral strand. Since the formation of this type of RFII was dependent on protein synthesis and the presence of the product of φX gene A, it is concluded that the discontinuity in the parental viral strand represents the result of the action of the gene A product on the DNA. Possible mechanisms for the mode of action of the gene A product are discussed.     

Improved automated solid-phase microsequencing of peptides using DABITC

The methylated purines O⁶-methyl- and 7-methylguanine were isolated from mouse liver DNA hydrolysates by means of a column cleanup employing a Sep Pak C-18 reverse-phase cartridge. The purine bases were eluted from the cartridge with methanol, evaporated to dryness, and then dissolved in mobile phase for liquid chromatographic analysis by normalphase chromatography. The system consisted of a LiChrosorb Si 60 column with a watersaturated mobile phase of 20% methanol in chloroform containing 0.001% H₃PO₄. The two methylated bases eluted before adenine or guanine. For extremely low-level (<300 pmol) quantitation, the peaks corresponding to O⁶-methyl- and 7-methylguanine were collected and then analyzed by reverse-phase chromotography with a LiChrosorb RP-18 column and a mobile phase of 5% methanol in pH 7 phosphate buffer (for 7-methylguanine) or 9.5% methanol/buffer (for O⁶-methylguanine). Comparisons were made with fluorescence detection and with scintillation counting (in animal studies where [¹⁴C]dimethylnitrosamine was used). Minimum detectable levels at 254 nm were about 3 ng (3:1 signal to noise ratio) for each of the title compounds. As low as 10 pmol/mg of each could be detected in DNA hydrolysates. Recoveries of O⁶-methyl- and 7-methylguanine from DNA spiked at 750 pmol/mg were greater than 80%.     

Uptake of homologous single-stranded fragments by superhelical DNA. III. The product and its enzymic conversion to a recombinant molecule

When superhelical DNA (RFI)² of phages φX174 or G4 takes up a homologous single-stranded fragment, RF DNA and fragment are linked by as many as 300 base-pairs, and a corresponding length of one strand of the RFI is displaced, forming a displacement loop (D-loop). The length of the base-paired region was estimated from the fraction of the associated ³²P-labeled fragment that was resistant to digestion by exonuclease VII, as well as by electron microscopy. Dissociation of the fragment by heating was characterized by a sharp melting curve. The displaced strand of the RF DNA was digested by two endonucleases that act on single-stranded DNA, the S₁ nuclease of Aspergillus oryzae and the recBC DNAase of Escherichia coli. Acting on complexes, both enzymes converted the form I [³H]DNA into form II DNA, and left some of the associated ³²P-labeled fragment undigested. The remaining ³²P-labeled fragment could no longer be displaced by branch migration, as expected if the displaced strand of the RF DNA were digested. The action of S₁ nuclease also produced the amount of acid-soluble ³H expected from digestion of the D-loop. Treatment of such digested complexes with polynucleotide ligase covalently linked about 35% of the remaining ³²P-labeled fragment to ³H-labeled strands, which proves that S₁ nuclease digested the D-loop.