Proton NMR investigation of the nucleosome core particle: evidence for regions of altered hydrogen bonding

Novel 1H nuclear magnetic resonance (NMR) resonances, arising from exchangeable protons and centered at approximately 11.2 and 10.1 parts per million (ppm), have been observed in the low-field spectrum (10-15 ppm) of the chicken erythrocyte core particle [145 +/- 2 base pairs (bp)]. These peaks are located upfield from the normal adenine-thymine (A-T) and guanine-cytosine (G-C) imino peaks characteristic of B-form deoxyribonucleic acid (DNA) and are not observed in free DNA under identical conditions. The appearance of the new peaks is ionic strength dependent and temperature-reversible below 75 degrees C. At 25 degrees C, the upfield peak area represents 5% of the DNA base pairs (7 bp), while between 45 and 55 degrees C, the area increases to 18%, affecting approximately 25 bp. Area increases in the upfield resonances result in a complementary decrease in the A-T and G-C imino peaks found between 12 and 14 ppm. We believe these novel proton signals represent a histone-induced DNA conformational change which involves localized alteration of base pairing in the core particle.     

Kinetics of renaturation of denatured DNA. I. Spectrophotometric results

The kinetics of renaturation of heat- or formamide-denatured DNA have been studied by following the change of optical density at a constant temperature. Solvents of different ionic strength and various DNA samples have been used. At the lower ionic strengths studied, the reaction follows second-order kinetics, substantiating the hypothesis that strands of native DNA separate upon denaturation and recombine during renaturation. As the ionic strength is increased at a constant temperature, the reaction deviates from simple second-order behavior. This appears to be the result of the inhibition to rewinding caused by short helical segments in the denatured DNA which are more stable at the higher ionic strenth.     

Renaturation of denatured, covalently closed circular DNA

The rate of renaturation of denatured, covalently closed, circular DNA (form Id DNA) of the phi X174 replicative form has been investigated as a function of pH, temperature, and ionic strength. The rate at a constant temperature is a sharply peaked function of pH in the range of pH 9 to 12. The position on the pH scale of the maximum rate decreases as the temperature is increased and as the ionic strength is increased. The kinetic course of renaturation is pseudo-first order: it is independent of DNA concentration, but falls off in rate from a first order relationship as the reaction proceeds. The rate of renaturation depends critically on the temperature at which the denaturation is carried out. Form Id, prepared at an alkaline pH at 0 degrees C, renatures from 5 to more than 100 times more rapidly than that similarly prepared at 50 degrees C. Both the heterogeneity in rate and the effect of the temperature of denaturation depend, in part, on the degree of supercoiling of the form I DNA from which the form Id is prepared. However, it is concluded that a much larger contribution to both arises from a configurational heterogeneity introduced in the denaturation reaction. The renaturation rate was determined by neutralization of the alkaline reaction and analytical ultracentrifugal analysis of the amounts of forms I and Id. The nature of the proximate renatured species at the temperature and alkaline pH of renaturation was investigated by spectrophotometric titration and analytical ultracentrifugation. It is concluded that the proximate species are the same as the intermediate species defined by an alkaline sedimentation titration of the kind first done by Vinograd et al. ((1965) Proc. Natl. Acad. Sci. U. S. A. 53, 1104-1111). Observations are included on the buoyant density of form Id and on depurination of DNA at alkaline pH values and high temperatures.     

The kinetics of the renaturation of deoxyribonucleic acid denatured in the presence of copper(II) ions

DNA which has been heat denatured in the presence of Cu⁺⁺ ions can be completely and rapidly renatured by increasing the ionic strength of the solution above a critical value. A kinetic study of this renaturation recation was carried out by following the associated UV absorbance change and also by following the change in free Cu⁺⁺ ion concentration by means of a specific Cu⁺⁺ ion activity electrode. The data obtained could be fitted to first-order kinetics for a considerable extent of the reaction and the rate constant was found to increase with temperature and ionic strength, but to decrease markedly as the bulk viscosity of the solution was increased. At temperatures greater than 5°C the reaction rate depended on the time elapsing between denaturation and the commencement of the renaturation reaction. As there was good agreement between the rate constants obtained by following the decrease in hyperchromism and by following the increase in free Cu⁺⁺ ion concentration, it is concluded that under the conditions employed, the rate of renaturation is determined by the rate of release of Cu⁺⁺ ions from the denatured DNA-Cu⁺⁺ complex.     

Ethidium bromide-mediated renaturation of denatured closed circular DNAs. The nature of denaturation-resistant fractions of bacteriophage PM2 closed circular DNA

Addition of the intercalating dye ethidium bromide (EtdBr) to a solution of alkali-denatured double-stranded closed circular PM2, ΦX174, or λb₂b₅c phage DNAs, under conditions such that the solution remains strongly alkaline, can result in the renaturation of up to 100% of the DNA upon neutralization of the solution. For a fixed time of incubation of the alkaline dye-containing solution before neutralization, there exists a minimum concentration of the dye below which no EtdBr-mediated renaturation is observed for each species of closed circular DNA examined. These minimum concentrations increase, for a given DNA, with increasing ionic strength and temperature. The kinetics of accumulation of forms renaturing upon neutralization of alkaline solutions, at fixed concentrations of dye and DNA, are dependent upon the molecular weight and superhelix density of the starting DNA. After extended periods of incubation at a fixed ionic strength and temperature, however, the profiles of percentage of DNA renatured as a function of ethidium concentration become very similar for all the closed circular DNAs tested and display a transition from an absence of dye-mediated renaturation to virtually 100% renaturation upon neutralization over a small range of dye concentration. Circular DNA containing one or more strand scissions remains strand-separated under all the conditions used to effect the renaturation of closed circular DNA. These findings indicate that configurations of closed circular DNA, in which at least some of the complementary bases are apposed, can be selectively stabilized and accumulate in the presence of ethidium in solutions containing 0.19 N hydroxide ion.     

Organization of nucleotide sequences in maize DNA

Nucleotide sequence organization in the genome of maize has been studied using renaturation kinetics of DNA and S-1 nuclease digestion of the renatured products. Approximately 40% of the genome consists of single copy sequences, and 15% of these sequences are interspersed between repeated sequences and are approximately 1100 nucleotide pairs long. About 54% of the genome consists of repeated sequences. Six per cent of the genome consists of foldback sequences. These sequences are distributed through at least 44% of the genome. It was found using renaturation kinetics that the sum of foldback and highly repeated DNA fractions of Dobrudzhanko maize and inbred lines differ in the amount of DNA composing the fractions. Comparison of the DNA of the Dobrudzhanko maize and inbred lines by the method of DNA-DNA hybridization indicates strong differences in the amount of polynucleotide homologies between the Dobrudzhanko maize and the D1 inbred line on one hand and the A619 inbred line on the other hand.     

Quantitative Aspects of Deoxyribonucleic Acid Renaturation: Base Composition, State of Chromosome Replication, and Polynucleotide Homologies

The base composition of a deoxyribonucleic acid (DNA) sample affects its intrinsic rate of renaturation. In agreement with the information of Wetmur and Davidson, it was established that high guanosine plus cytosine (GC) DNA renatures faster than expected from analytical measurement of its molecular weight. A calculated correction factor of 1.8% of the observed C(0)t(.5) is required for every mole per cent GC difference from 51% GC. The correction factor is now established in the range of 32 to 65% GC. Renaturation of DNA mixtures prepared from pairs of organisms has been studied. When no similarity existed between the two organisms, the observed C(0)t(.5) of the mixture was the sum of the independently determined C(0)t(.5) values. Lack of additivity was correlated with similarities in polynucleotide sequence of the reassociating DNA molecules. A quantitative relationship was formulated to relate C(0)t(.5) values of renatured DNA mixtures to per cent binding ("homology"). Finally, it was demonstrated that DNA prepared from log-phase cells renatures faster than stationary-phase DNA and also departs from theoretical second-order kinetics.     

Interaction of the antineoplastic agent mitoxantrone with double-stranded nucleic acids

The binding of mitoxantrone with double-helical nucleic acids was investigated by the methods of isothermal microcalorimetry, circular dichroism and absorption at the ionic strength mu = 0.11 and 0.011 M NaCl at temperature region of 30 divided by 60 degrees C. The investigation shows, that at mu = 0.11 M NaCl mitoxantrone interacts with double-helical nucleic acids in one way only. For such conditions using spectrophotometric titration data Scatchard plots for the binding of mitoxantrone with double-helical nucleic acids were constructed. The calculations show that the saturation stoichiometry is one mitoxantrone molecule per 2 divided by 3 base pairs DNA and 6 divided by 8 base pairs RNA. The dependence of binding constant from GC-content is observed. It is shown that the binding enthalpy of mitoxantrone with DNA and RNA increases linearly and reaches -(3.0 +/- 0.5) kkal per 1 mol mitoxantrone. It is shown that a binding mitoxantrone with double-helical nucleic acids, besides the intercalation of rings, a determinate contribution in the binding is given also by electrostatic interaction of side chains mitoxantrone with nucleic acids.     

Characteristics of palindromic sequences in DNA of the sea urchin Strongylocentrotus intermedius

Some properties of the palindromic sequences in the sea urchin Strongylocentrotus intermedius nuclear DNA have been studied. It was shown that the amount of "foldback HAP bound DNA" and the S1 nuclease resistant DNA depends on renaturation temperature and Na+ concentration in solution. The authentic fraction of inverted repeats comprises 10-15% of the total DNA. The complexity of the palindromic fraction is approximately 8,2 X 10(7) nucleotide pairs and the average number of inverted repeats approximates 5 X 10(5) per haploid genome. The renaturation kinetics of inverted repeats with excess of total homologous DNA indicates that these sequences are enriched with unique DNA. The possible function of palindromic sequences is discussed.     

Determination of the rate of renaturation of modified DNA by fluorescence depolarization

Fluorescence depolarization was used to measure the rate of renaturation of T2 DNA, which had been modified by chloroacetaldehyde. Rates were measured on DNA samples with 5–15% of the base pairs modified and were found to agree with rates determined by DNA absorbance kinetics at 260 nm. The renaturation rate of a modified T2 DNA was unchanged in the presence of a ninefold abundance of unlabeled calf thymus DNA.     

Cellular content of chloroplast DNA and chloroplast ribosomal RNA genes in Euglena gracilis during chloroplast development.

The cellular content of chloroplast DNA in Euglena gracilis has been quantitatively determined. DNA was extracted from Euglena cells at various stages of chloroplast development and renatured in the presence of trace amounts of 3H-labeled chloroplast DNA. From the kinetics of renaturation of the 3H-labeled chloroplast DNA, compared with the kinetics of renaturation of excess nonradioactive chloroplast DNA, the fraction of cellular DNA represented by chloroplast DNA was calculated. The content of chloroplast DNA was found to increase from 4.9 to 14.6% of cellular DNA during light-induced chloroplast development. Correcting for the change in DNA mass per cell, the number of copies of chloroplast DNA is found to vary from 1400 to 2900 per cell. During this developmental transition, the cellular content of the chloroplast ribosomal RNA genes varies from 1900 to 5200 copies per cell. The ratio of the number of copies of rRNA genes to chloroplast genomes per cell remains in the range of 1-2 throughout chloroplast development, ruling out selective amplification of chloroplast rRNA genes as a means of regulation of rRNA gene expression. Direct measurement of the number of rRNA cistrons per 9.2 X 10(7) dalton genome yields a value of 1 or 2.     

Transfection of Escherichia coli Spheroplasts II. Relative Infectivity of Native, Denatured, and Renatured Lambda, T7, T5, T4, and P22 Bacteriophage DNAs

The change of infectivity of phage DNAs after heat and alkali denaturation (and renaturation) was measured. T7 phage DNA infectivity increased 4- to 20-fold after denaturation and decreased to the native level after renaturation. Both the heavy and the light single strand of T7 phage DNA were about five times as infective as native T7 DNA. T4 and P22 phage DNA infectivity increased 4- to 20-fold after denaturation and increased another 10- to 20-fold after renaturation. These data, combined with other authors' results on the relative infectivity of various forms of phiX174 and lambda DNAs give the following consistent pattern of relative infectivity. Covalently closed circular double-stranded DNA, nicked circular double-stranded DNA, and double-stranded DNA with cohesive ends are all equally infective and also most highly infectious for Escherichia coli lysozyme-EDTA spheroplasts; linear or circular single-stranded DNAs are about 1/5 to 1/20 as infective; double-stranded DNAs are only 1/100 as infective. Two exceptions to this pattern were noted: lambda phage DNA lost more than 99% of its infectivity after alkaline denaturation; this infectivity could be fully recovered after renaturation. This behavior can be explained by the special role of the cohesive ends of the phage DNA. T5 phage DNA sometimes showed a transient increase in infectivity at temperatures below the completion of the hyperchròmic shift; at higher temperatures, the infectivity was completely destroyed. T5 DNA denatured in alkali lost more than 99.9% of its infectivity; upon renaturation, infectivity was sometimes recovered. This behavior is interpreted in terms of the model of T5 phage DNA structure proposed by Bujard (1969). The results of the denaturation and renaturation experiments show higher efficiencies of transfection for the following phage DNAs (free of single-strand breaks): T4 renatured DNA at 10(-3) instead of 10(-5) for native DNA; renatured P22 DNA at 3 x 10(-7) instead of 3 x 10(-9) for native DNA; and denatured T7 DNA at 3 x 10(-6) instead of 3 x 10(-7) for native DNA.     

The kinetics of DNA helix-coil subtransitions

The kinetic analysis of individual helix-coil subtransitions were performed by comparing melting and renaturation profiles obtained at different temperature change rates. The duration of the three transition stages and its dependence on temperature and ionic strength were determined for a T7 phage DNA fragment. The obtained temperature dependence of the melting time for a stretch flanked by melted regions is in quantitative agreement with that predicted by the theory of slow processes (V.V. Anshelevich, A.V. Vologodskii, A.V. Lukashin, M.D. Frank-Kamenetskii, Biopolymers 23, 39 (1984)). The reasons are discussed for the increasing relaxation time of this stretch in the middle of its transition with decreasing ionic strength. The zipping kinetics of a melted region under essentially nonequilibrium conditions was examined for T7 fragment and pAO3 DNAs. The obtained temperature dependence of the zipping time is in quantitative agreement with calculations based on the theory of slow processes. The renaturation times of stretches flanked by helical regions proved fairly small even at a low ionic strength. These times are several orders of magnitude smaller than the renaturation times of the same stretches with one helical boundary. A formal application of the theory of slow processes failed to account for the small renaturation times of stretches that are zipped from both ends. This is probably due to the non-allowance for the changing entropy of the loop linking two helix-coil boundaries migrating towards each other. Slow processes have been revealed in the intramolecular melting of Col E1 DNA at a high ionic strength. The reason for the long relaxation time of one subtransition is the large size of the loop that separates the melting stretch from the helical part of the molecule. This result can be accounted for by the theory of slow processes.     

Hidden in plain sight: subtle effects of the 8-oxoguanine lesion on the structure, dynamics, and thermodynamics of a 15-base pair oligodeoxynucleotide duplex

The base lesion 8-oxoguanine is formed readily by oxidation of DNA, potentially leading to G → T transversion mutations. Despite the apparent similarity of 8-oxoguanine-cytosine base pairs to normal guanine-cytosine base pairs, cellular base excision repair systems effectively recognize the lesion base. Here we apply several techniques to examine a single 8-oxoguanine lesion at the center of a nonpalindromic 15-mer duplex oligonucleotide in an effort to determine what, if anything, distinguishes an 8-oxoguanine-cytosine (8oxoG-C) base pair from a normal base pair. The lesion duplex is globally almost indistinguishable from the unmodified parent duplex using circular dichroism spectroscopy and ultraviolet melting thermodynamics. The DNA mismatch-detecting photocleavage agent Rh(bpy)(2)chrysi(3+) cleaves only weakly and nonspecifically, revealing that the 8oxoG-C pair is locally stable at the level of the individual base pairs. Nuclear magnetic resonance spectra are also consistent with a well-conserved B-form duplex structure. In the two-dimensional nuclear Overhauser effect spectra, base-sugar and imino-imino cross-peaks are strikingly similar between parent and lesion duplexes. Changes in chemical shift due to the 8oxoG lesion are localized to its complementary cytosine and to the 2-3 bp immediately flanking the lesion on the lesion strand. Residues further removed from the lesion are shown to be unperturbed by its presence. Notably, imino exchange experiments indicate that the 8-oxoguanine-cytosine pair is strong and stable, with an apparent equilibrium constant for opening equal to that of other internal guanine-cytosine base pairs, on the order of 10(-6). This collection of experiments shows that the 8-oxoguanine-cytosine base pair is incredibly stable and similar to the native pair.     

The Kinetics of DNA Helix-Coil Subtransitions

Abstract

The kinetic analysis of individual helix-coil subtransitions was performed by comparing melting and renaturation profiles obtained at different temperature change rates. The duration of the three transition stages and its dependence on temperature and ionic strength were determined for a T7 phage DNA fragment. The obtained temperature dependence of the melting time for a stretch flanked by melted regions is in quantitative agreement with that predicted by the theory of slow processes (V.V. Anshelevich, A.V. Vologodskii, A.V. Lukashin, M.D. Frank-Kamenetskii, Biopolymers 23, 39 (1984)). The reasons are discussed for the increasing relaxation time of this stretch in the middle of its transition with decreasing ionic strength.

The zipping kinetics of a melted region under essentially nonequilibrium conditions was examined for T7 fragment and pAO3 DNAs. The obtained temperature dependence of the zipping time is in quantitative agreement with calculations based on the theory of slow processes.

The renaturation times of stretches flanked by helical regions proved fairly small even at a low ionic strength. These times are several orders of magnitude smaller than the renaturation times of the same stretches with one helical boundary. A formal application of the theory of slow processes failed to account for the small renaturation times of stretches that are zipped from both ends. This is probably due to the non-allowance for the changing entropy of the loop linking two helix-coil boundaries migrating towards each other.

Slow processes have been revealed in the intramolecular melting of Col E1 DNA at a high ionic strength. The reason for the long relaxation time of one subtransition is the large size of the loop that separates the melting stretch from the helical part of the molecule. This result can be accounted for by the theory of slow processes.     

Characteristics of the binding of the anticancer agents mitoxantrone and ametantrone and related structures to deoxyribonucleic acids

The binding constants for interaction of the anticancer agents mitoxantrone and ametantrone and several congeners with calf thymus DNA and the effects of ionic strength changes have been determined spectrophotometrically. The agents show a preference for certain sequences, particularly those with GC base pairs, and the magnitude of the specificity depends on the specific substituents on the anthraquinone ring system. The binding constant for mitoxantrone with calf thymus DNA in 0.1 M Na+, pH 7, is approximately 6 X 10(6) M-1, and the rate constant for the sodium dodecyl sulfate driven dissociation of mitoxantrone from its calf thymus DNA complex under the same solution conditions and 20 degrees C was determined to be 1.3 s-1. The unwinding angle of mitoxantrone determined independently by viscosity measurements and by a novel assay employing calf thymus topoisomerase shows excellent agreement for a value of 17.5 degrees. The viscosity increase of sonicated calf thymus DNA varies considerably with the substituent on the anthraquinone ring system. Binding studies employing T4 and phi w-14 DNAs in which the major groove is occluded and the reverse experiment with anthramycin-treated calf thymus DNA indicate at least part of the mitoxantrone molecule may lie in the minor groove.     

Melting of short DNA fragments. Relation between the nucleation constant of a spiral region and the ionic strength

Melting of two DNA duplexes of known nucleotide sequences containing 14 and 36 base pairs has been investigated within the range of ionic strength from 0.2 to 0.02 M [Na+]. The values of melting enthalpy of base pair delta H were measured for the duplex of 14 base pairs in the solutions of varying ionic strength. The values of delta H were obtained from slopes of linear plots of reciprocal melting temperature versus logarithm of oligonucleotide chains concentration. In the aforementioned range the decrease of the ionic strength causes a 5% decrease of delta H. By fitting the theoretical profiles to the experimental ones the ionic strength dependence of the nucleation constant beta was measured for DNA fragments of various lengths. With the decrease of the ionic strength the value of beta drops 2 times for the short duplex and 8 times for the long one.     

Thermal stability of homologous and heterologous bacterial DNA duplexes

Thermal stability of homologous and heterologous DNA duplexes renatured according to the renaturation-rate method of De Ley et al. (1970) for 35 min or 17 hr, was estimated from the melting profiles of the duplexes. Comparison of the melting points of native and renatured DNA revealed that in the first 35 min of renaturation highly stable homologous duplexes were mainly formed, whereas up to 7% mismatching occurred in duplexes renatured for 17 hr. Up to 8% more mismatching was found in heterologous DNA duplexes of moderately related coryneform bacteria than in homologous ones after 35 min renaturation. It can be concluded that mismatching in heterologous hybrids of closely related DNAs had been restricted to a few % and of moderately related DNAs to approximately 10% in the initial renaturation phase.     

Microtubule assembly kinetics. Changes with solution conditions.

The assembly kinetics of microtubule protein are altered by ionic strength, temperature and Mg2+, but not by pH. High ionic strength (I0.2), low temperature (T less than 30 degrees C) and elevated Mg2+ (greater than or equal to 1.2 mM) induce a transition from biphasic to monophasic kinetics. Comparison of the activation energy obtained for the fast biphasic step at low ionic strength (I0.069) shows excellent agreement with the values obtained at high ionic strength, low temperature and elevated Mg2+. From this observation it can be implied that the tubulin-containing reactant of the fast biphasic event is also the species that elongates microtubules during monophasic assembly. Second-order rate constants for biphasic assembly are 3.82(+/- 0.72) x 10(7) M-1.s-1 and 5.19(+/- 1.25) x 10(6) M-1.s-1, and for monophasic assembly the rate constant is 2.12(+/- 0.56) x 10(7) M-1.s-1. The microtubule number concentration is constant during elongation of microtubules for biphasic and monophasic assembly.     

Physiochemical studies on interactions between DNA and RNA polymerase. Ultraviolet absorption measurements.

The interaction between Escherichia coli RNA polymerase and a restriction fragment of coliphage T7 DNA containing four promoter sites for the coli enzyme has been studied by difference uv absorption spectroscopy in a low ionic strength buffer containing 10 mm MgCl2 and 50 mM KCl. The binding of the enzyme to the DNA is accompanied by a hyperchromic shift which shows a maximum around 260 nm, and increases with increasing temperature in the temperature range studied (4-40 degrees C). Measurements were also carried out with whole T7 DNA and a restriction fragment containing no promoter site. A comparison of the results obtained with the various DNAs suggests that the binding of an RNA polymerase to a promoter site in the low ionic strength medium causes the disruption of a short segment of the DNA helix, of the order of ten pairs; the binding of an enzyme molecule to a promotor site appears to have a cooperative effect on the binding of the enzyme molecules to adjacent non-promoter sites with concomitant disruption of DNA base pairs.