Effect of the protein product of phage f1, gene 5, on heat denaturation of synthetic polynucleotides

The influence of phage f1 gene 5 protein on melting of the synthetic polynucleotides has been investigated, using UV-spectroscopy. In our experiments we have varied the proteins concentration. It has been shown, that the protein lowers the melting temperature of the studied polynucleotides (d/A--Tn dAndTn, rAndTn, rAn.r n, dAn.rn). The melting temperatures and the shapes of melting curves of various polynucleotides differ when the same protein concentrations are used. We have shown that the protein binds to the double-stranded polynucleotides, containing ribo-ribo-, deoxyribo-ribo-chains. The difference in melting temperatures and shapes of melting curves was explained using the data about the differences in the secondary structure of these polynucleotides. Only for d/A-Tn renaturation was observed after sample cooling. It may reflect the single-stranded hairpin structure of this polynucleotide.     

Study of specific interactions of amino acid esters with the synthetic polynucleotides poly(A) x 2 poly(U), poly(A) x poly(U) and poly(A) by thermal denaturation

The interactions of amino acid esters with poly(A)x2poly(U) and poly(A)xpoly(U) have been investigated by means of thermal denaturation of these polynucleotides. The esters under consideration raised the melting point, revealing the preferable binding to helical polynucleotide structures. The melting point shifts demonstrate the following sequence of the stabilities of these complexes: Arg greater than Lys much greater than His greater than Met greater than Ser greater than Gly. The same stability order is observed when studying the polynucleotide renaturation in the presence of esters. This order coincides with that previously obtained for the nucleotide base--amino acid ester complexes excepting basic amino acid esters. The ester interactions with poly(A) and poly(U) also reveal the specificity of monomer--monomer interactions. Some dynamic contributions into the studied specificity are also discussed.     

Complex between single-stranded DNA and gene 5 protein of bacteriophage M13 studied with linear dichroism and ultraviolet absorption

We have studied complexes between the gene 5 protein (gp5) of bacteriophage M13 and various polynucleotides, including single-stranded DNA, using ultraviolet absorption and linear dichroism. Upon complex formation the absorption spectra of both the protein and the polynucleotides change. The protein absorption changes indicate that for at least two of the five tyrosine residues per protein monomer the environment becomes less polar upon binding to the polynucleotides but also to the oligonucleotide p(dT)8. All gp5-polynucleotide complexes give rise to intense linear dichroism spectra. These spectra are dominated by negative contributions from the bases, but also a small positive dichroism of the protein can be discerned. The spectra can be explained by polynucleotide structures, which are the same in all complexes. The base orientations are characterized by a substantial inclination and propellor twist. The number of possible combinations of inclination and propeller twist values, which are in agreement with the linear dichroism results, is rather limited. The base orientations with respect to the complex axis are essentially different from those in the complex with the single-stranded DNA-binding protein gp32 of bacteriophage T4.     

Thermal denaturation profiles of deoxypolynucleotide-ligand complexes: semiempirical studies

We have semiempirically studied the thermal denaturation profiles of complexes formed between double strand polynucleotides and pure stabilizer nonspecific binding ligands. By using the McGhee model (J. D. McGhee, (1976) Biopolymers 15, 1345-1375) we have found a simple, analytical relationship between the melting temperature (Tm) and the Kh (intrinsic association constant), nh (apparent site size), and wh (cooperativity constant) values of the interaction. The validity of this approach strongly depends on the sigma value (sigma being the nucleation parameter of the DNA). Through the equation so obtained it is possible to calculate the Kh, nh, and wh values from the melting temperature of three experimental thermal denaturation profiles at different r (ligand/polynucleotide ratio) values. The method has been checked by studying the thermal denaturation profiles of daunomycin-poly(d(A-T)).poly(d(A-T)) complexes in two different salt concentrations. The results so obtained are compared with those previously described using other techniques. The applicability of the method here developed is discussed in relation with both the nature of the ligands and the value of the nucleation parameter (sigma).     

The effect of the chain length of polynucleotides on their binding with platinum complexes.

The effect of the length of polynucleotides on their binding with platinum complexes was studied. The highest reaction rate was observed in the reaction with guanosine-containing polynucleotides, whereas cytidine- and adenosine-containing polynucleotides were much less efficient. The monoaqua-forms of the platinum complexes exhibited the highest reactivity in the interaction with polynucleotides in solution. The mechanism implies the formation of the monodentate complex at the first stage which is transformed into the corresponding bidentate complex of chelate type at the second stage. Increase in the length of the polynucleotide chain was shown to enhance its interaction with the platinum complexes.     

Na+ effects on transition of DNA and polynucleotides of variable linear charge density.

A range of linear charge densities of the ordered and disordered forms of DNA or polynucleotides can be obtained experimentally by acid or alkaline titration, or by the investigation of unusual complexes involving protonated bases or three-stranded helices. The variation of melting temperatures with Na⁺ concentration for various of these systems is known and in some cases is complemented by structural and thermodynamic information. We have extended the condensation–screening theory of Manning [Biopolymers, 11 , 937–955 (1972)] to these systems. The stabilizing and destabilizing effects of Na⁺ (condensation and screening, respectively) and be independently varied, and the theory is successful in predicting the qualitative (in some cases, quanittative) behaviour that is observed. Comparison of theory and experiment indicates that the axial phosphate distance b for single-stranded polynucleotides increases with increasing pH. Values of the critical parameter ξ are obtained for the various polynucleotide structures. These values are essential for an understanding of ionic effects on charged ligand–polynucleotide interactions.     

Synthesis and properties of poly 5-methylthiouridylic acid.

In an effort to search for good methods for the enzymatic synthesis of polynucleotide analogs with antitemplate activity, 5-methylthiouridine-5'-diphosphate (ms5UDP) has been synthesized and investigated as a substrate for polynucleotide phosphorylase. While ms5UDP was polymerized at a very low rate to give a 6% yield of polynucleotides by the polynucleotide phosphorylase of Micrococcus luteus, it was utilized more efficiently by the corresponding enzyme of Escherichia coli resulting in a 15% yield of poly (5-methylthiouridylic) acid. Results of the co-polymerization of ms5UDP and UDP revealed that the ratio of 5-methylthiouridylate to uridylate residues in the polynucleotide product was lower than the ratio of ms5UDP to UDP in the substrate mixture. The 5-methylthio group conferred only minute changes on the conformation of the modified polyuridylic acid, and the complexes formed between poly-(5-methylthiouridylic) acid and poly(adenylic) acid possessed slightly higher Tm values than did the unmodified counterparts. Poly(5-methylthiouridylic) acid was a potent inhibitor of calf thymus DNA polymerase alpha.     

Interaction of gene 5 protein of phage f1 with single and double-stranded DNA and polynucleotides

The fluorescence method was used to reveal some differences in the interaction of gene 5 protein of phage f1 with single- and double-stranded polynucleotides (DNA). The binding with the duplexes is non-cooperative and the Kapp is twice lower than that for the cooperative formation of the complex with single-stranded structures. In the complex with a double-stranded polynucleotide (DNA) the protein cover 3 nucleotide pairs. The complex dissociates with a lower concentration of salt and the contribution of the energy of nonelectrostatic interactions to the total energy of complex formation for it is lower than for the complex with single-stranded DNA. In the complex of protein with single-stranded structure the fluorescence of the tyrosine (Tyr) residues is quenched to a greater degree and their accessibility to the external quencher is lower than that of the complex with double-stranded polynucleotides (DNA). The suggestion is made that in destabilization of nucleic double helices by gene 5 protein of phage f1, a great role belongs to Tyr residues because of their high affinity to single-stranded structures and because of their different localization in the complexes with single- and double-stranded polynucleotides.     

Adsorption of single-stranded and double-helical polynucleotides on the mercury electrode

The adsorption of single-stranded polynucleotides and double-helical DNA on the dropping mercury electrode has been studied with the aid of Breyer's alternating current (a.c.) polarography. Our results indicate that all three constituents of polynucleotides (residues of bases, sugar, and phosphoric acid) are involved in the adsorption. At neutral pH their participation in adsorption depends on the ionic strength, the potential of the electrode, and the conformation of the polynucleotide in the solution. At an ionic strength of about 0.1, double-helical DNA is adsorbed electrostatically on a positively charged electrode surface by inadequately masked negative charges of the phosphate groups. At a higher ionic srength (about 0.5), this electrostatic adsorption is no longer detectable by using a.c. polarography; under these conditions it is probable that native DNA is adsorbed around the potential of the electrocapillary maximum with the aid of sugar residues and a few bases. Single-stranded polynucleotides, on the other hand, are primarily adsorbed by means of the bases. Desorption of double-helical DNA occurs around a potential of ?1.2 V against SCE. At this potential, the helical regions of single-stranded polynucleotides are also desorbed. Desorption of the disordered regions of single-stranded polynucleotides occurs at more negative potentials. Adsorption and desorption of a small number of bases released from double-helical DNA was evident in the a.c. polarograms only at elevated temperature, or at room temperature after degradation of DNA by sonication.     

Several properties of complexes of polynucleotides with aromatic amino acid amides of oligonucleotides

Residues of Phe, Tyr and Trp in the complexes of their oligonucleotide amidates and polynucleotides of A-U of G-C nucleotide composition are most likely localized in the minor groove of the Watson--Crick part of the triple helix where they interact with bases but do not intercalate into the helix. Formation of the complexes is accompanied with a change in the relative localization of amino acids and bases. The major geometrical parameters of the triple helices of the complexes are not changed by the residues of aromatic amino acids (according to CD data). A slight violation of stacking interactions between bases is observed along with an increase of the cooperativity of melting of the complexes of A-U composition (according to UV absorption data). The effect of the residues of aromatic amino acids on the stability of triple helices is determined by the nucleotide composition of the latter, i.e. complexes of A-U composition are destabilized with the Phe, Tyr and Trp residues, whereas the Trp residue does not affect the stability of the complexes of G-C composition. The hydrophobic character of aromatic amino acids and their different affinity for bases of different structure seem to account for this difference in stability. The dependence of the thermal stability of RNH-dp(An).2poly(U)-complexes on the structure of the amide radical (residues of glycin, aromatic amino acids, alkyl- and arylalkyl amines) testifies the ability of the radical to "regulate" the interaction between the oligomer and the complementary polynucleotide. This capacity for "regulation" is not observed in the system of G-C composition.     

Polysaccharide-polynucleotide complexes. Part 7. Hydrogen-ion and salt concentration dependence of complexation between schizophyllan and single-stranded homo RNAs

Schizophyllan belongs to a beta-1,3-D-glucan family, which exists as a random coil in dimethyl sulfoxide (DMSO) and as a triple helix in water, respectively. The schizophyllan single chain forms a complex with single-stranded homo RNAs in water/DMSO mixed solvents. Using circular dichroism, we studied the complexation and its stability as a function of apparent pH (pH(*)) in a mixed solvent system and as a function of the salt concentration. The complex is formed in the pH(*) range 6.5-10, and dissociated in the pH(*) range 4-6. Both poly(A) and poly(C) adopt a double strand in the pH(*) range 4-6 and a single strand in the pH(*) range 6.5-10. Therefore, the conformational change of each polynucleotide is responsible for dissociation/association of the complex, i.e., the single strand of the polynucleotides can form complexes, whereas the double one cannot. This result indicates that hydrogen bonding and similarity of the helix parameters are essential for the complex formation. The melting temperature of the complex reaches the maximum around 0.05 M of NaCl and KCl, and the value of the maximum temperature depends on the cation species.     

Binding of recA protein to Z-form DNA studied with circular and linear dichroism spectroscopy

Binding of RecA to poly(dG-m5dC) and poly(dG-dC) under B- and Z-form conditions was studied using circular dichroism (CD) and linear dichroism (LD). LD revealed a quantitative binding of RecA to Mg2+-induced Z-form poly(dG-m5dC) with a stoichiometry of 3.1 base pairs/RecA monomer, which is slightly larger than the 2.7 base pairs observed for the B-form. The LD spectra indicate a preferentially perpendicular orientation of DNA bases and a rather parallel orientation of the tryptophan residues relative to the fiber axis in both complexes. The association rate of RecA to Z-form DNA was found to be slower than to B-form. CD measurements showed that the polynucleotide conformation is retained upon RecA binding, and CD and LD confirm that RecA binds to both forms of DNA. The Mg2+-induced Z-form is shown to be retransformed into B-form, both in free and in RecA-complexed polynucleotides by addition of NaCl, whereas the B----Z transition cannot be induced by addition of Mg2+ when the polynucleotide is complexed with RecA. From this it is inferred that RecA does not stabilize the Z-conformation of the polynucleotide but that it can kinetically "freeze" the polynucleotide in its B-conformation. On all essential points, the same conclusions were also reached in a corresponding study of unmethylated poly(dG-dC) with the Z-form induced by Mn2+.     

Singular value decomposition of 3-D DNA melting curves reveals complexity in the melting process

The thermal denaturation of synthetic deoxypolynucleotides of defined sequence was studied by a three dimensional melting technique in which complete UV absorbance spectra were recorded as a function of temperature. The results of such an experiment defined a surface bounded by absorbance, wavelength, and temperature. A matrix of the experimental data was built, and analyzed by the method of singular value decomposition (SVD). SVD provides a rigorous, model-free analytical tool for evaluating the number of significant spectral species required to account for the changes in UV absorbance accompany-ing the duplex – to – single strand transition. For all of the polynucleotides studied (Poly dA – Poly dT; [Poly (dAdT)]₂; Poly dG – Poly dC; [Poly(dGdC)]₂), SVD indicated the existence of at least 4 – 5 significant spectral species. The DNA melting transition for even these simple repeating sequences cannot, therefore, be a simple two-state process. The basis spectra obtained by SVD analysis were found to be unique for each polynucleotide studied. Differential scanning calorimetry was used to obtain model free estimates for the enthalpy of melting for the polynucleotides studied, with results in good agreement with previously published values. Received: 16 April 1997 / Accepted: 9 July 1997     

The distance of manganese to phosphorus atoms of polynucleotides, and dynamics of binding

The structure of manganese - polynucleotide complexes is studied by phosphorous NMR. An average value for the phosphorus-manganese distance is derived from the longitudinal relaxation rate. It is larger than the distance for direct coordination and decreases as a funtion of temperature. An inner-sphere/outer sphere equilibrium is proposed. The outer-sphere dominates in the double-stranded polynucleotides, whereas the inner-sphere contribution is important in single-stranded species. The kinetic parameters of the model are derived from the transverse relaxation time. The similar properties of DNA fragments and tRNA argue strongly against entrapment of manganese in special sites of tRNA.     

Effects of polyamines on the degradation of ribonucleic acids by polynucleotide phosphorylase of Micrococcus luteus.

The effects of polyamines on the breakdown of synthetic polynucleotides [poly(A), poly(C), and poly(U)] by polynucleotide phosphorylase [polyribonucleotide: orthophosphate nucleotidyltransferase, EC 2.7.7.8] from Micrococcus luteus have been studied. Although the breakdown of all the synthetic polynucleotides tested was stimulated by polyamines, the degree of stimulation by polyamines was in the order poly(C) greater than poly(A) greater than poly(U) at pH 7.5. However, the difference in degree of stimulation among polynucleotides decreased as the pH or monovalent cation concentration was increased. In the presence of heparin, an inhibitor of polynucleotide phosphorylase hydrolysis of polynucleotides, spermidine clearly stimulated the breakdown of poly(C) and poly(A), while the breakdown of poly(U) was stimulated only slightly by the addition of spermidine. Although binding of [14C]spermine to polynucleotide phosphorylase was observed by gel filtration, the amount of spermine bound to the enzyme was much less than that to RNA.     

Polynucleotides XLVII. Synthesis and properties of poly(2-methylthio- and 2-ethylthioadenylic acid). Formation of non-Watson-Crick type complexes.

Poly(2-methyl- and 2-ethylthioadenylic acid) were prepared by polymerization of corresponding diphosphates with Escherichia coli polynucleotide phosphorylase. These polynucleotides have relatively large hypochromicity of 30-35%. Acid titration of these polymers showed abrupt transition at pH 5.34-5.4, which may indicate that the introduction of alkylthio group at 2-position of adenine bases reduced their basicity. Thermal melting of these polymers showed no clear transition points at neutral pH, but in acidic media they have Tm values of 57 and 56 degrees C, somewhat lower than that of poly(A). Upon complex formation with poly(U), these poly(A) analogs showed only one poly(rs2A) . poly(U) type double-strand complexes, similar to that found in the case of poly(m2A) . poly(U).     

Intercalation into the DNA double helix and in vivo biological activity of water-soluble planar [Pt(diimine)(N,N-dihydroxyethyl-N'-benzoylthioureato)]+Cl- complexes: a study of their thermal stability, their CD spectra and their gel mobility

The interaction of newly synthesised water-soluble planar complexes of general structure [Pt(diimine)(N,N-dihydroxyethyl-N'-benzoylthioureato)]+Cl- with DNA was investigated by means of DNA melting studies, CD spectroscopy, and DNA gel mobility studies. Addition of stoichometric amounts of [Pt(diimine)H2L-S,O]Cl complexes to polynucleotides caused a significant increase in the melting temperature of poly(dA-dT) and calf-thymus DNA, respectively, indicating that these complexes interacted with DNA and stabilised the double helical structure. The CD spectra confirmed the relatively strong binding of three related Pt(II) complexes ([Pt(2,2'-bipyridine)H2L-S,O]Cl, [Pt(4,4'-dimethyl-2,2'-bipyridine)H2L-S,O]Cl, and [Pt(1,10-phenanthroline)H2L-S,O]Cl), to DNA. Comparison with the published CD spectra of ethidium bromide/DNA complex suggests a similar intercalation mode of binding. cis-[(4,4'-di-tert-butyl-2,2'-bipyridyl)N,N-di(2-hydroxyethyl)-N'-benzoylthioureatoplatinum(II)] chloride, with its very bulky tert-butyl groups, did not intercalate into the polynucleotide double helix. In DNA mobility studies in the presence of the four [Pt(diimine)H2L-S,O]Cl complexes, only [Pt(2,2'-bipyridine)H2L-S,O]Cl affected the DNA mobility to any detectable extent. Finally, in vivo studies on the biological activity of the complexes, using an Escherichia coli DNA excision repair deficient uvrA mutant strain, indicated that only the [Pt(2,2'-bipyridine)H2L-S,O]Cl complex showed significant cellular toxicity and that this was, in part, linked to DNA damage.     

Differential binding of the enantiomers of chloroquine and quinacrine to polynucleotides: Implications for stereoselective metabolism

Interaction of the antimalarial drugs quinacrine and chloroquine with DNA has been studied extensively in order to understand the origin of their biological activity. These studies have shown that they bind to DNA through an intercalative mode and show little sequence specificity. All previous experiments were carried out using the racemic form of these drugs. We have investigated the binding of the enantiomeric forms of quinacrine and chloroquine to synthetic polynucleotides poly (dA-dT) · poly(dA-dT) and poly (dG-dC) · poly(dG-dC), and found interesting differences in their binding parameters. Quinacrine enantiomers have a much higher binding affinity for the two polynucleotides compared to those of chloroquine. The negative enantiomers were found to have higher binding affinity than the positive ones. The binding constant for the binding of quinacrine (?) to poly(dG-dC) · poly(dG-dC) was found to be about 3 times that of quinacrine (+). The differences in these binding affinities were further confirmed by equilibrium dialysis of the complexes of the polynucleotides with the racemic form of the drugs, which resulted in the enrichment of the dialysate with the positive enantiomer. CD spectra of the enantiomers and their polynucleotide complexes are reported. Changes in the fluorescence properties of quinacrine in the presence of the two polynucleotides are also described. Biological implications of these findings are discussed. © 1993 John Wiley & Sons, Inc.     

Laser temperature-jump, spectroscopic, and thermodynamic study of salt effects on duplex formation by dGCATGC

Salt effects on duplex formation by dGCATGC have been studied with spectroscopic, thermodynamic, and kinetic methods. Circular dichroism spectra indicate different salt conditions have little effect on the structures of the duplex and single strand. NMR chemical shifts indicate the structure of the duplex in 1 M NaCl is similar to that of the B-form determined previously in 0.5 M KCl [Nilges, M., Clore, G. M., Gronenborn, A. M., Brunger, A. T., Karplus, M., & Nilsson, L. (1987) Biochemistry 26, 3718-3733]. Optical melting experiments indicate the effect of Na+ concentration on melting temperature is similar to that expected for a polynucleotide with the same GC content. Laser temperature-jump experiments indicate the effect of Na+ concentration on the rate of duplex formation is much less than is observed for polynucleotides. The observations are consistent with expectations based on a counterion condensation model. This is surprising for a duplex with only 10 phosphates.     

Complex formation of spin-labeled 9-aminoacridine with DNA and polynucleotides

Complex formation between spin-labeled 9-aminoacridine and DNA or polynucleotides has been studied by differential spectrophotometry and ESR. The differential spectra of the strong type 9-aminoacridine-DNA complex showed characteristic absorption bands at 270 and 290 nm, and the intensity ratio of these bands varied according to the degree of DNA denaturation. The ESR spectra of this complex were characterized by slow rotation of the radical; as the macromolecule became increasingly denatured and in the polynucleotide complex, a rapid signal appeared in the ESR spectrum. The temperature at which DNA undergoes a structural transition in the premelting region could be determined from the temperature dependence of the ESR spectral form of the dye-DNA complex. The spectral characteristics of the complexes give additional information about structural disturbances in DNA.