Intrinsic Enantioselectivity of Natural Polynucleotides Modulated by Copper Ions

Natural polynucleotides including Micrococcus lysodeikticus and calf thymus DNA exhibit enantioselective recognition to S‐ofloxacin regulated by Cu²⁺. This is the first report that ofloxacin and Cu²⁺ have cooperative effects on the local distortions of polynucleotides. At the [Cu²⁺]/[base] ratio of 0.1, S‐ofloxacin is more liable to induce the locally distorted structures of polynucleotides, of which the association constant of S‐ofloxacin toward DNA‐Cu(II) is three times higher than that of the R‐enantiomer. The apparent increase of adsorption capability and cooperativity, as well as the change of adsorption mechanism were detected in the adsorption of ofloxacin enantiomers on polynucleotides upon Cu(II)‐coordination. This study not only discloses the effect of the chiral drug on the structural transition of long double‐stranded DNA, but provides fundamental data to develop a novel enantioseparation method based on natural polynucleotides. Chirality 27:306‐313, 2015. © 2015 Wiley Periodicals, Inc.     

Iodination-deiodination. A radiochemical method for detection of structure and changes in structure in RNA.

Bound iodine is released from radioiodinated nucleotides in polymers exposed to sodium bisulfite. The rate of bisulfite-catalyzed deiodination of pyrimidines can be controlled both by change of temperature of pH and is also dependent on the molecular association of the nucleotide. The rate of release of iodine from iodocytidine in polycytidylate is greater than the rate of elimination from RNA. Experiments testing the influence of base-pairing of the iodopyrimidines in synthetic polynucleotides showed that pairing of the substituted nucleotide protected the iodine bond. The rates of bisulfite-catalyzed deiodination of several radioiodinated RNAs were measured. The action of bisulfite on all single stranded RNAs tested was multiphasic consisting of a rapid early deiodination reaction supplanted by a slower phase which was followed by reacceleration of release. The release of iodine from double stranded RNA and DNA-RNA duplexes was retarded in comparison with the release from ribosomal and messenger RNA fractions. The deiodination profiles of single and double stranded RNA suggested that the intermediate stage iodine release is governed by melting of paired zones of low stability. Late release may result from destablization of the molecule through the addition of bisulfite to the pyrimidine ring or deamination. The effect of several substances expected to complex with polynucleotides was tested. Acridine orange and ethidium bromide increased loss of iodine from ribosomal RNA but slightly decreased elimination from double stranded viral RNA. A basic protein fraction isolated from ribosomal particles accelerated the deiodination of ribosomal RNA. While the destabilization caused by this protein fraction was greater than that caused by an equal amount of albumin, as tested the effect was non-specific. The results show that a change in sensitivity to chemical deiodination may folow the interaction of small amounts of protein with polynucleotides.     

Recognition of polynucleotides by antibodies to poly(I), poly(C).

The binding of anti poly(I). poly (C) Fab fragments to double or triple stranded polynucletides has been studied by fluorescence. Association constants were deduced from competition experiments. The comparison of the association constants leads to the conclusion that several atoms of the base residues do not interact with the amino acid residues of the binding site of Fab fragment while the hydroxyl groups of furanose rings interact. These results suggest that the Fab fragments do not bind to the major groove of the double stranded polynucleotides. An interaction between the C(2)O group of pyrimidine residues and Fab fragments cannot be excluded. Circular dichroism of poly(I). poly(C) or poly(I). poly(br5C)-Fab fragments complexes are very different from the circular dichroism of free polynucleotides which suggests a deformation of the polynucleotides bound to the Fab fragments.     

Sister chromatid differentiation after in situ detection of ultraviolet-induced DNA breaks under electron microscopy

Summary— Chinese hamster DON cells with 5-bromodeoxyuridine (BrdU)-substituted chromosomes were ultraviolet (UV)-exposed and processed for in situ detection of induced DNA breaks under electron microscopy. For this purpose, UV-induced breaks were amplified by an exonuclease III digestion to obtain single stranded DNA motifs which could hybridize with oligonucleotides of random sequences. These reannealed motifs could be used as primers which were extended by the Klenow polymerase, incorporating biotinylated-dUTP that was detected by a gold-tagged streptavidin. After processing, the chromatid whose DNA was BrdU-substituted in one strand showed a higher electron density than the chromatid substituted in both strands. In contrast, the unifilarly substituted chromatid showed about twice the labelling of DNA breaks as the bifilarly substituted one. This result could be the consequence of a greater loss of chromatin tracts in the bifilarly substituted chromatid, as implied by an X-ray microanalysis which showed that the amount of phosphorous lost by the bifilarly substituted chromatid was higher than that of the unifilarly substituted chromatid.     

The detection and occurrence of multiple forms of D-ribose 5-phosphate ketol isomerase

The alkylating thiovinyl fragment released from S-(1,2-dichlorovinyl)-l-[³⁵S]-cysteine by a lyase reacted with about 12% of the amino acid residues in poly-l-lysine and about 6% in poly-l-arginine. The reaction of alkylating fragment with DNA was considerably reduced through complex formation of DNA with these polypeptides. When (alkylating fragment)-treated DNA interacted with either normal or (alkylating fragment)-treated polypeptides, the products had an abnormal biphasic melting profile. The first (lower) T_m is apparently due to (alkylating fragment)-substituted regions of DNA which are not complexed with polypeptide and have, like (alkylating fragment)-substituted DNA, a higher T_m than free, native DNA. A second, much higher T_m is due to (alkylating fragment)-substituted regions of DNA which are complexed with polypeptide. These complexes were, however, less stable and had lower T_m values than those prepared from normal, native DNA. The implications of complex formation with respect to susceptibility of tissues and species to toxic agents are discussed.     

Interaction of manganese with fragments, complementary fragment recombinations, and whole molecules of yeast phenylalanine specific transfer RNA

Binding of Mn²⁺ to the whole molecule, fragments and complementary fragment recombinations of yeast tRNA^Phe, and to synthetic polynucleotides was studied by equilibrium dialysis. The comparison of the binding patterns of the fragments, fragment recombinations and synthetic polynucleotides with that of intact tRNA^Phe permits reasonable conclusions concerning the nature and location of the various classes of sites on tRNA^Phe. Binding of Mn²⁺ to intact tRNA^Phe consists of a co-operative and a non-co-operative phase. There are about 17 “strong” sites and several “weak” ones. Five of the 17 strong sites are associated with the co-operative phase. This phase is completely lacking in the binding of Mn²⁺ to tRNA^Phe fragments (5′-$\text{1}\text{2}$, 3′-$\text{1}\text{2}$, 5′-$\text{3}\text{5}$, 3′-$\text{2}\text{5}$), poly-(A):poly(U) and poly(I):poly(C) helices, and single stranded poly(A) and poly(U). This argues that the co-operative sites arise from the tRNA tertiary structure. This conclusion is further strengthened by the observation that cooperativity is present in a tRNA^Phe molecule which has been split in the anticodon loop, but it is absent in one which has been split in the extra loop. It is in the vicinity of the latter loop, but not the former, that tertiary interactions are seen in the crystal structure. The remaining 12 strong sites are “independent” and appear to be associated with cloverleaf helical sections.     

Specificity of the Binding of Bacteriophage M13 Encoded Gene-5 Protein to DNA and RNA Studied by Means of Fluorescence Titrations

Abstract

The fluorescence quenching of the bacteriophage M13 encoded gene-5 protein was used to study its binding characteristics to different polynucleotides. Experiments were performed at different salt concentrations and in some instances at different temperatures. The affinity of the protein depends on the base and sugar composition of the polynucleotides involved and may differ appreciably, i.e. by orders of magnitude. The salt dependence of binding is within experimental accuracy equal for all single stranded polynucleotides. A method is presented to estimate values of the cooperativity constant from salt titration curves. These values are systematically higher than those obtained from titration experiments in which protein is added to a polynucleotide solution. A comparison is made between the binding constants of the gene-5 protein and the gene-32 protein encoded by the T4 phage. Possible implications of the binding characteristics of the gene-5 protein for an understanding of its role in vivo are discussed.     

Destabilization of the secondary structure of RNA by ribosomal protein S1 from escherichia coli

S1 is an acidic protein associated with the 3′ end of 16S RNA; it is indispensable for ribosomal binding of natural mRNA. We find that S1 unfolds single stranded stacked or helical polynucleotides (poly rA, poly rC, poly rU). It prevents the formation of poly (rA + rU) and poly (rI + rC) duplexes at 10–25 mM NaCl but not at 50–100 mM NaCl. Partial, salt reversible denaturation is also seen with coliphage MS2 RNA, $\text{E. coli}$ rRNA and tRNA. Generally, only duplex structures with a Tm greater than about 55° are formed in the presence of S1. The protein unfolds single stranded DNA but not poly d(A·T).     

Interactions des ions métalliques avec le DNA. I. Comportement de polyélectrolyte et liaison des ions compensateurs

The theory of polyelectrolyte solution of Alexandrowicz: and Katchalsky is used to calculate the electrostatic potential of single stranded polynucleotides for different ionic strength. We have considered the potential of double stranded DNA as the superposition of the different potentials produced by each chain, provided the average distance between the strands is higher than an ionic strength-dependent parameter b. For ionic strength lower than 5 × 10^?2M, the assumption is no longer valid, and a cylindrical model with a uniform charge density must be used. The continuity between the two models was tested, and thus we can calculate the electrical potential at the vicinity of a phosphate group in the whole range of ionic-strength where the double helix is stable. It was therefore possible to determine the theoretical number of ions bound electrostatically to DNA and we found an increase of ion binding with a decrease of ionic strength. Such a model was further applied to the change of specific volume in different salt solutions. Comparison is made with recent pycnometric data on Na^? and Cs^? salts of DNA. Agreement is good in the case of Cs⁺, but for Na⁺, cation binding is likely to be accompanied by a change of the hydration of DNA, which depends on ionic strength. With the same model we can see easily the ion-trapping properties of DNA which play an important role in any formation of complex between heavy ions and bases.     

A parallel stranded G‐quadruplex composed of threose nucleic acid (TNA)

G‐rich sequences can adopt four‐stranded helical structures, called G‐quadruplexes, that self‐assemble around monovalent cations like sodium (Na⁺) and potassium (K⁺). Whether similar structures can be formed from xeno‐nucleic acid (XNA) polymers with a shorter backbone repeat unit is an unanswered question with significant implications on the fold space of functional XNA polymers. Here, we examine the potential for TNA (α‐l ‐threofuranosyl nucleic acid) to adopt a four‐stranded helical structure based on a planar G‐quartet motif. Using native polyacrylamide gel electrophoresis (PAGE), circular dichroism (CD) and solution‐state nuclear magnetic resonance (NMR) spectroscopy, we show that despite a backbone repeat unit that is one atom shorter than the backbone repeat unit found in DNA and RNA, TNA can self‐assemble into stable G‐quadruplex structures that are similar in thermal stability to equivalent DNA structures. However, unlike DNA, TNA does not appear to discriminate between Na⁺ and K⁺ ions, as G‐quadruplex structures form equally well in the presence of either ion. Together, these findings demonstrate that despite a shorter backbone repeat unit, TNA is capable of self‐assembling into stable G‐quadruplex structures.     

The Specificity of Antibodies Elicited by Poly(dG)-Poly(dC)

Abstract

Antibodies have been raised to the synthetic DNA polymer poly(dG)·poly(dC). These antibodies have the ability to distinguish this right-handed polymer from natural mixed sequence DNA, as well as from other right- and left-handed synthetic DNA polymers. They show reduced but measurable binding to synthetic polymers which contain various combinations of guanine and cytosine polynucleotides suggesting that both helical shape and sequence are recognized by this antiserum.     

Inhibition of Leukaemia Virus Replication by Polyadenylic Acid

A PREVIOUS communication from this laboratory demonstrated that the DNA polymerase of the Rauscher leukaemia virus is strongly inhibited in vitro by unprimed, single stranded polyribonucleotides¹ as a result of competition between the polymers and the active template for the same enzyme binding site. This inhibition was apparently specific, since partially purified preparations of DNA polymerase from Escherichia coli and BALB/c mouse embryos were not inhibited in the same conditions. We attempted to determine therefore whether single stranded polyribonucleotides would have any effect on the activities of oncogenic RNA viruses in cultured cells.     

Nucleic acid binding properties of Escherichia coli ribosomal protein S1. I. Structure and interactions of binding site I.

Escherichia coli ribosomal protein S1 plays a central role in initiation of protein synthesis, perhaps via participation in the binding of messenger RNA to the ribosome. S1 protein has two nucleic acid binding sites with very different properties: site I binds either single-stranded DNA or RNA, while site II binds single-stranded RNA only (Draper et al., 1977). The nucleic acid binding properties of these sites have been explored using the quenching of intrinsic protein fluorescence which results from binding of oligo- and polynucleotides, and are reported in this and the accompanying paper (Draper &; von Hippel, 1978).Site I has been studied primarily using DNA oligomers and polymers, and has been found to have the following properties. (1) The intrinsic binding constant (K) of site I for poly(dA) and poly(dC) is ~3 × 10⁶m^?1 at 0.12 m-Na⁺, and the site size (n, the number of nucleotide residues covered per S1 bound) is 5.1 ± 1.0 residues. (2) Binding of site I to polynucleotides is non-co-operative. (3) The K value for binding of S1 to single-stranded polynucleotides is ~10³ larger than K for binding to double-stranded polynucleotides, meaning that S1 (via site I) is a potential “melting” or “double-helix destabilizing” protein. (4) The dependence of log K on log [Na⁺] is linear, and analysis of the data according to Record et al. (1976) shows that two basic residues in site I form charge-charge interactions with two DNA phosphates. In addition, a major part of the binding free energy of site I with the nucleic acid chain appears to involve non-electrostatic interactions. (5) Oligonucleotides bound in site II somewhat weaken the binding affinity of site I. (6) Binding affin is virtually independent of base and sugar composition of the nucleic acid ligand; in fact, the total absence of the base appears to have little effect on the binding, since the association constant for 2′-deoxyribose 5′-phosphate is approximately the same as that for dAMP or dCMP. (7) Two molecules of d(ApA) can bind to site I, suggesting the presence of two “subsites” within site I. (8) Iodide quenching experiments with S1-oligonucleotide complexes show differential exposure of tryptophans in and near the subsites of site I, depending upon whether neither, one, or both subsites are complexed with an oligonucleotide.     

Inhibition of Eco RI action by polynucleotides. A characterization of the non-specific binding of the enzyme to DNA.

The cleavage of the plasmid pBR322 by the restriction endonuclease Eco RI has been studied in the presence of various polynucleotides and the double stranded octanucleotide d-(GGAATTCC) in order to clarify whether there is a preferential interaction of Eco RI with DNA sequences other than -GAATTC-. The steady state kinetic analysis shows that all polynucleotides investigated with the possible exception of poly-dG.poly-dC inhibit the cleavage competitively with Ki values in the range of 10(-4) to 10(-5) [M nucleotides]. The Ki of d-(GGAATTCC) is 1.5.10(-6) [M nucleotides], indicating that the specific binding is approx. 2 orders of magnitude stronger than non-specific binding.     

The binding of Arg- and Lys-peptides to single standed polyribonucleotides and its effect on the polymer conformation

The interactions between basic oligopeptides (Lys₂, Lys₃, Arg₂, and Arg₃) and single stranded polynucleotides (poly(A), poly(C), poly(I) and poly(U) were investigated at low ion concentration by UV spectroscopy, circular dichroism and field jump relaxation. Various domains of binding were detected: 1) High concentrations (up to 1 mM) of some peptides induce opalescencs followed by coacervation- Arg₃ causes coacervation in all polynucleotides used, yet Lys₃ only in poly(I). In the case of poly(I) the threshold concentration for coacervation is much lower for Arg₃ (150 μM) than for Lys₃ (500 μM). 2) Medium concentrations (?10 μM) of Arg₃ and Lys₃ induce helix formation in poly(U). In the case of poly(I) cooperative helix formation is only induced by Lys₃, but not by Arg₃. 3) The onset of peptide association is observed at very low peptide concentrations (?1 μM) already by using the field jump method. The association is reflected by a relaxation process, that can be described by a single exponential within experimental accuracy. Measurements of relaxation time constants as a function of the peptide concentration provide information on the association constants K, the number of nucleotide residues per binding place n and the rate constants k_R and k_D. Using a simple model with independent and “separate” binding sites, K for Arg₃ and Lys₃ is found to be in the range of 10⁶ to 10⁷ M^?1. In the case of Arg₂ and K is lower by a factor of about 10. For various polynucleotides K_Arg3 is slightly higher than K_Lys3. except in the case of poly(I), where K_Arg3/K_Lys3 ≈ 5. Similar data are obtained by application of a “sphere model” (see below). These results provide quantitative evidence for specific hydrogen bonding between the guanidino group of Arg and inosine. They also explain the absence of helix formation for poly(I) + Arg₃: Arg blocks the hydrogen bonding sites of inosine. Thus cooperative coupling leads in this case to a considerable amplification of specificity in the peptide-polynucleotide interaction Both field jump and stopped flow data demonstrate a high mobility of the peptide lisands along the polymer, resulting in a redistribution being fast compared with the overall binding step. Based on this result the relaxation data are analysed by a “sphere” model, which considers a) excluded binding under the condition of fast Ugand distribution along the lattice and b) the connection of sites into a polymer sphere. The rate constants obtained by this model are in the range of 4 × 10¹¹ M^?1 s^?1. These high values reflect the large reaction distance for polymers of chain lengths around 1000. A comparison with rate constants obtained previously for oligomer complexes indicates that the recombination rate is approximately a function of the square root of the nucleotide chain length, which is directly related to the mean radius of coiled polymers.     

Specificity of the binding of bacteriophage M13 encoded gene-5 protein to DNA and RNA studied by means of fluorescence titrations

The fluorescence quenching of the bacteriophage M13 encoded gene-5 protein was used to study its binding characteristics to different polynucleotides. Experiments were performed at different salt concentrations and in some instances at different temperatures. The affinity of the protein depends on the base and sugar composition of the polynucleotides involved and may differ appreciably, i.e. by orders of magnitude. The salt dependence of binding is within experimental accuracy equal for all single stranded polynucleotides. A method is presented to estimate values of the cooperativity constant from salt titration curves. These values are systematically higher than those obtained from titration experiments in which protein is added to a polynucleotide solution. A comparison is made between the binding constants of the gene-5 protein and the gene-32 protein encoded by the T4 phage. Possible implications of the binding characteristics of the gene-5 protein for an understanding of its role in vivo are discussed.     

Induction of unscheduled DNA synthesis and micronucleus formation in Syrian hamster embryo fibroblasts treated with cysteine S-conjugates of chlorinated hydrocarbons

S-(chloroethyl)-cysteine (CEC) and S-(1,2-dichlorovinyl)cysteine (DCVO) have been proposed as intermediates in the metabolic transformation of the carcinogens 1,2-dichloroethane and 1,1,2-trichloroethylene. We have tested the ability of CEC and DCVC to induce DNA repair and genotoxic effects at the chromosomal level by comparative assessment of unscheduled DNA synthesis induction and micronucleus formation in Syrian hamster embryo fibroblasts. CEC induced a potent and dose-dependent response in both assays, whereas DCVC treatment resulted in a comparatively weak induction of DNA repair and failed to raise micronucleus formation above control rates. Inhibition of cysteine conjugate \gB-lyase diminished the effect of DCVC, but had no influence on the genotoxicity of CEC either in the unscheduled DNA synthesis or micronucleus assay.Abbreviations AOAA aminooxyacetic acid - CEC S-(chloroethyl)-cysteine; \gB-lyase, cysteine conjugate -lyase - DCE 1,2-dichloroethane - DCVC S(1,2-dichlorovinyl)-cysteine - GSH glutathione - HU hydroxyurea - IBR IBR-modified Dulbecco's Eagle's reinforced medium - MN2 micronuclei/2,000 cells - 4-NQO 4-nitroquinoline-1-oxide - SHE Syrian hamster embryo fibroblasts; ³H-Thd, ³H-thymidine - TCE 1,1,2-trichloroethylene - UDS unscheduled DNA synthesis     

Epimerization of Alanyl-Alanine Induced by γ-Rays Irradiation in Aqueous Solutions

Living organisms have homochiral L-amino acids in proteins and homochiral D-mononucleotides in nucleic acids. The chemical evolutionary process to protein homochirality has been discussed for many years. Although many scenarios have been proposed for homochirality in the monomeric compounds, homochirality in amino acids and mononucleotides does not always guarantee homochirality in polypeptides and polynucleotides. Integrated scenarios containing the pathways from monomer to polymer should be proposed because in the pathways oligomers and polymers as well as monomers racemize (or epimerize), degrade, and condense. This research addresses epimerization and degradation of dipeptides under γ-rays irradiation by a cobalt-60 (⁶⁰Co) radiation source. The different rate constants of epimerization between diastereomeric dipeptides in the research suggest that the potential pathway toward homochirality could be much more complex.