High resolution thermal denaturation of DNA: thermalites of bacteriophage DNA.

High resolution thermal denaturation profiles are presented for the DNAs of bacteriophages lambda and T7. It is concluded that the temperature increment in data gathering and the method of calculating results meet the requirements for quantitative recording of the large amount of information found in the thermal transitions of both DNAs. The high resolution derivative denaturation profiles of these bacteriophage DNAs demonstrate that individual subtransitions (thermalites) of natural DNA are Gaussian in form and have narrow transition widths. Curve resolution performed on these profiles indicates that the mean thermalite width (2 sigma) is 0.33 degrees C and that this breadth is relatively invariant. Transition widths are not influenced by the position of thermalites in the profile or by cation concentration in the range from 5 to 30 mM Na+. However, the relative position of thermalites within a denaturation profile is a function of the solution ionic strength. The distribution of lengths of the DNA sequences which these thermalites represent is broad, with a number average length of 900 base pairs. Although we find an approximate similarity between the number of thermalites in the denaturation profile of T7 DNA and the number of looping regions in the electron microscopic partial denaturation map of Gomez and Lang ((1972), J. Mol. Biol. 70, 239-251) we conclude that free solution thermal denaturation experiments can be compared only superficially to the mapping results.     

Structural organization of double-stranded RNA from killer yeasts Saccharomyces cerevisiae by the thermal denaturation method

The thermal denaturation method for studying the structural organization of double-stranded RNA (dsRNA) from virus-like particles of killer yeasts Saccharomyces cerevisiae was used. High resolution derivative denaturation profiles of total dsRNA and its L- and M-types were obtained. Comparative analysis of these data with those on phage DNA denaturation demonstrated that the processes of denaturation of dsRNA and phage DNA were identical in quality. Increase of thermostability, interval of thermal denaturation and width of local helix-to-coil transitions in dsRNA as compared with phage DNA are caused by the differences of corresponding thermodynamic parameters. Derivative denaturation profiles of L- and M-types of yeasts dsRNA were shown to have certain identical local transitions. Low melting transition, consisting of three local thermalites, is due to the denaturation of AU-rich region (about 200 n.b.p.) in M-dsRNA.     

High-resolution thermal denaturation of DNA. I. Theoretical and practical considerations for the resolution of thermal subtransitions.

The fidelity achieved in first derivative profiles of DNA thermal denaturation is shown to depend on a number of factors including the thermal increment of data gathering, the precision of absorbance readings, and the manner in which data are smoothed prior to calculating the derivative of hyperchromicity. The closeness with which thermal denaturation data can be fitted by a cubic polynomial is carefully considered, and a derivation is presented for the estimated error in calculated values of the derivative of hyperchromicity with respect to temperature. After reviewing both theoretical and experimental evidence for the expected minimum width of a thermal transition in DNA, we conclude that thermal increments of 0.05°C or less are required for an adequate representation of transitions in naturally occurring DNA's. Data gathered under conditions meeting the requirements suggested here for quantitative recording of thermal denaturation profiles (Vizard and Ansevin, submitted for publication) show that virtually all of the high-resolution thermal denaturation profile of a simple, naturally occuring DNA may consist of small subtransitions, which we call thermalites. The finding of substransitions is consistent with current theories of DNA melting. A particularly well-resolved thermalite of λ bacteriophage DNA has a breadth of only 0.30°C (2σ width), and thus is narrower than previously reported thermal transitions for DNA. For this thermalite, the combination of width, shape, and position in the profile suggests that the substransitions observed in accurately recorded DNA thermal denaturation profiles are not described satisfactorily by existing theories. Knowledge of the requirements for the quantitative recording of thermal denaturation profiles should greatly favor the usefulness of denaturation experiments for physical genomic analysis.     

Specific DNA binding of the cAMP receptor protein within the lac operon stabilizes double-stranded DNA in the presence of cAMP

The effects of varying amounts of cAMP receptor protein (CRP) in the presence and absence of cAMP on the melting and differential melting curves of a 301-bp fragment containing the lac control region in 5 mM Na+ have been investigated. The native 301-bp fragment consists of three cooperatively melting thermalites. At 5 mM Na+, thermalite I (155 bp) has a Tm of 66.4 degrees C and the melting transitions of thermalites II (81 bp) and III (65 bp) are superimposed with a Tm of 61.9 degrees C. The specific DNA target site for CRP and the lac promotor are located within thermalite II. CRP alone exerts no specific effects on the melting of the 301-bp fragment, non-specific DNA binding of CRP resulting in a progressive stabilization of the double-stranded DNA by increasing the number of base pairs melting at a higher Tm in a non-cooperative transition. The cAMP-CRP complex, however, exerts a specific effect with a region of approximately 36 bp, comprising the specific CRP binding site and a neighbouring region of DNA, being stabilized. The appearance of this new cooperatively melting region, known as thermalite IV, is associated with a corresponding decrease in the area of thermalites II/III. The Tm of thermalite IV is 64.4 degrees C, 2.5 degrees C higher than that of thermalites II/III. With two or more cAMP-CRP complexes bound per 301-bp fragment, the stabilization also affects the remaining 110 bp now making up thermalites II/III whose Tm is increased by 1 degrees C to 62.9 degrees C. The implications of these findings for various models of the mode of action of the cAMP-CRP complex are discussed.     

Cucumber mosaic virus-associated RNA 5. VI. Characterization and denaturation-renaturation behavior of the double-stranded form.

The double-stranded form of cucumber mosaic virus-associated RNA 5 has been purified and further characterized. Its molecular weight determined by sedimentation equilibrium is 2.15 . 10(5). The buoyant density calculated from its symmetrical distribution in Cs2SO4, following isopycnic ultracentrifugation, is 1.615 g/cm3. The sedimentation rate of double-stranded cucumber mosaic virus-associated RNA 5 is slightly greater than that of cucumber mosaic virus-associated RNA 5; its electrophoretic mobility in polyacrylamide gel (2.4%) is less than that of cucumber mosaic virus-associated RNA 5. By the above standards the double-stranded cucumber mosaic virus-associated RNA 5 preparations used were found to be nomogeneous in size as well as density. Thermal denaturation monitored by means of ultraviolet light absorption produced multitransitional denaturation profiles. The average melting temperature (Tm) was 88 degrees C in 0.1 x SSC. Monotransitional denaturation profiles and slightly higher Tm values were obtained when resistance against ribonuclease digestion was measured. These denaturation experiments and other propertied led to the conclusion that double-stranded cucumber mosaic virus-associated RNA 5 and the double-stranded form of peanut stunt virus-associated RNA 5 are small double-stranded nucleic acids with several homostable base-pair regions, characterized by distinct G + C contents and Tm values.     

Stacking energies in DNA

Variations in base mono- and dipoles result in variations in stacking energies for the 10 unique neighbor pairs in DNA. Stacking energies for pair M on N, expressed as TMN, were derived by matrix decomposition of a large set of linear algebraic expressions relating the measured Tm for subtransitions emanating from large polymeric DNAs, and the fractional neighbor frequencies, fMN, for the domains responsible for the transitions, Tm = sigma fMNTMN. Tm were determined for subtransitions that dissociate in approximately all-or-none fashion in high resolution melting profiles of partially deleted and recombinant forms of pBR322 DNA. Three different analytical maneuvers were undertaken to resolve subtransitions: site-specific cleavage of domains; deletion of domains; and addition of domains. Three dozen domains of widely divergent, quasi-random neighbor frequencies were identified and assigned, resulting in a unique set of values for TMN with standard deviation, sigma = +/- 0.23 degree C. The average difference between calculated and experimental Tm for domains is only +/- 0.17 degree C, indicating that the thermodynamic properties of these domains are not in any way unusual. Assuming delta S to be constant for all pairs, the corresponding delta HMN are found to have a precision of +/- 10 calories.mol-1 and an accuracy of +/- 606 calories.mol-1. TMN used to calculate melting curves by statistical mechanical analysis of sequences of the different plasmid specimens in this study were in quantitative agreement with observed curves for most sequences. These TMN differ significantly from those determined previously and also correlate poorly with values determined by quantum chemical analysis. Stabilities of neighbor pairs, expressed as the difference in free energy between that for a given pair (MN) and that for the average of like pairs (M, N), depend on the relationship of stacked purines and pyrimidines as follows. delta delta Gpu-py(-466 cal) greater than delta delta Gpu-pu(+52 cal) greater than delta delta Gpy-pu(+335 cal) Differences between experimental Tm and Tm calculated with TMN for the isolated neighbor pairs in the B-conformation are useful in the identification of altered structures and unusual modes of dissociation of helixes. A significantly higher Tm is observed for the highly biased repeated sequence synthetic helixes dA.dT, d(AGC).d(GCT), and d(GAT).d(ATC), reflecting auxiliary sources of stability such as bifurcated hydrogen bonds and/or altered structures for these helixes.     

A thermal denaturation study of genomic DNAs from North American minnows (Cyprinidae: Teleostei)

Base compositions and differential melting rate profiles of genomic DNAs from twenty species of North American cyprinid fishes were generated via thermal denaturation. Base pair composition expressed as % GC values ranged among the twenty species from 36.1–41.3%. This range is considerably broader than that observed at comparable taxonomic levels in other vertebrate groups. Both the range and average difference in base pair composition between species in the diverse and rapidly evolving genus Notropis were considerably greater than those between species in other North American cyprinid genera. This may indicate that genomic changes at the level of base pair composition are frequent and possibly important events in cyprinid evolution. Compositional heterogeneity and asymmetry values among the twenty species were uniform and low, respectively, suggesting that most of the species lacked DNA components in their genomes which differed substantially from their main-band DNAs in base pair composition. The melting rate profiles revealed a prominent and distinct heavy or GC-rich DNA component in the genomes of three species belonging to the subgenus Cyprinella of Notropis. These and other data suggest that the heavy melting component may reflect a large, comparatively GC-rich family of highly repeated or satellite DNA sequences common to all three genomes.     

Advantages of 2'-O-methyl oligoribonucleotide probes for detecting RNA targets.

We have compared various kinetic and melting properties of oligoribonucleotide probes containing 2'-O-methylnucleotides or 2'-deoxynucleotides with regard to their use in assays for the detection of nucleic acid targets. 2'-O-Methyl oligoribonucleotide probes bound to RNA targets faster and with much higher melting temperatures (Tm values) than corresponding 2'-deoxy oligoribonucleotide probes at all lengths tested (8-26 bases). Tm values of both probes increased with length up to approximately 19 bases, with maximal differences in Tm between 2'-O-methyl and 2'-deoxy oligoribonucleotide probes observed at lengths of 16 bases or less. In contrast to RNA targets, 2'-O-methyl oligoribonucleotide probes bound more slowly and with the same Tm to DNA targets as corresponding 2'-deoxy oligoribonucleotide probes. Because of their greatly enhanced Tm when bound to RNA, 2'-O-methyl oligoribonucleotide probes can efficiently bind to double-stranded regions of structured RNA molecules. A 17 base 2'-O-methyl oligoribonucleotide probe was able to bind a double-stranded region of rRNA whereas the same 17 base 2'- deoxy oligoribonucleotide probe did not. Due to their enhanced Tm when bound to RNA targets, shorter 2'-O-methyl oligoribonucleotide probes can be used in assays in place of longer 2'-deoxy oligoribonucleotide probes, resulting in enhanced discrimination between matched and mismatched RNA targets. A 12 base 2'-O-methyl oligoribonucleotide probe had the same Tm as a 19 base 2'-deoxy oligoribonucleotide probe when bound to a matched RNA target but exhibited a much larger decrease in Tm than the 2'-deoxy oligoribonucleotide probe when bound to an RNA target containing either 1 or 2 mismatched bases. The increased Tm, faster kinetics of hybridization, ability to bind to structured targets and increased specificity of 2'-O-methyl oligoribonucleotide probes render them superior to corresponding 2'-deoxy oligoribonucleotides for use in assays that detect RNA targets.     

Melting and reassociation of double-stranded RNA of the encephalomyocarditis virus]

The processes of melting and reassociation of double-stranded RNA in dimethylsulfoxide were studied. The addition of a small amount of LiCl results in great results in great reduction of Tm (temperature of melting), whereas the NaCl produces the opposite effect. It is suggested, that LiCl coordinates the molecules of H2O, reducing their activity, and consequently destabilises dsRNA. Mild conditions for melting and reassociation of RNA can be created. It was found that under optimal conditions for dsRNA melting, the degree of strand separation depends on the overall concentration of RNA, irrespective of the type of RNA added to the dsRNA preparation. Reassociation of dsRNA of EMC virus proceeds much faster than that of dsRNA of a related poliovirus. Addition of poly(C) to an annealing mixture slows down the rate of reassociation of EMC dsRNA, producing no effect on the poliovirus dsRNA reassociation. It is suggested that the presence of large poly(C) and poly(G) tracts in the complementary strands of the RNA determines its anomalous fast reassociation. Upon incubation of completely separated strands of EMC dsRNA in a water solution with high ionic strength partially double-stranded aggregates are formed. The formation of aggregates is prevented by addition of poly(A), which indicates that they are produced by "zippening" of a molecule starting with poly(A):poly(U) region. The significance of homopolymeric regions for stability of dsRNA of the EMC virus as well as their role in viral multiplication are discussed.     

High resolution derivative denaturation profiles of DNA in the presence of copper(II) ions

Derivative denaturation profiles of calf thymus DNA in the presence of copper(II) ions have been directly obtained from high resolution thermal denaturation profiles recorded in an isoabsorbance wavelength of the AT and GC hyperchromic spectra. The analysis of the very sensitive profiles provides further evidence that the melting temperature (Tm) of DNA decreases in the presence of stoichiometric ratio of copper(II) ions to nucleotide. Also, evidence is given of peculiar behaviour at higher temperatures where a new melting transition is observed. This phenomenon could be in line with the presence of bridging of DNA single strands by copper ions which are disrupted when the temperature is raised.     

The evolutionary transition from RNA to DNA in early cells

Summary The evolution of genetic material can be divided into at least three major phases: first, genomes of nucleic acid-like molecules; secondly, genomes of RNA; and finally, double-stranded DNA genomes such as those present in all contemporary cells. Using properties of nucleic acid molecules, we attempt to explain the evolutionary transition from RNA alone as a cellular informational macromolecule prior to the evolution of cell systems based on double-stranded DNA. The idea that ribonucleic acid-based cellular genomes preceded DNA is based on the following: (1) protein synthesis can occur in the absence of DNA but not of RNA; (2) RNA molecules have some catalytic properties; (3) the ubiquity of purine and pyridine nucleotide coenzymes as well as other similar ribonucleotide cofactors in metabolic pathways; and (4) the fact that the biosynthesis of deoxyribonucleotides always proceeds via the enzymatic reduction of ribonucleotides.The RNA prior to DNA hypothesis can be further developed by understanding the selective pressures that led to the biosynthesis of deoxyribose, thymine, and proofreading DNA polymerases. Taken together these observations suggest to us that DNA was selected as an informational molecule in cells to stabilize earlier RNA-protein replicating systems. These arguments include the facts that (1) the 2-deoxy-containing phosphodiester backbone is more stable in aqueous conditions and in the presence of transition metal ions (such as Zn²⁺) than its ribo-equivalents; (2) the absence of proofreading activity in RNA polymerases leads to a higher rate of mutation in RNA genomes relative to DNA; (3) information in RNA degrades because of the tendency of cytosine to deaminate to uracil and the lack of a correcting enzyme; and (4) UV irradiation produces a larger number of photochemical changes in RNA molecules relative to double-stranded DNA. The absence of atmospheric UV attenuation during the early Earth environment (Hadean and early Archean) would have imposed an intense selection pressure favoring duplex DNA over other genetic information storage systems.If RNA preceded DNA as a reservior of cellular genetic information, then an RNA-replicating oligopeptide must have been one of the earliest protoenzymes from which RNA polymerase presumably evolved. We conclude that RNA polymerases are among the oldest classes of enzymes.     

Ionic strength effects on the stability and conformation of Penicillium chrysogenum mycophage double stranded RNA.

The effect of [Na+] on the stability and conformation of penicillium chrysogenum mycophage dsRNA (PCMdsRNA) was investigated using CD and UV optical techniques. Thermal melting profiles reveal prominent fine structure attributed to at least four regions of structural dissimilarity. A constant increased thermal stability of the dsRNA compared to DNA of the same base composition was observed over a concentration range of 1.5 times 10- minus 4 M to 4.5 times 10- minus 2 M Na+. At low ionic strengths ([Na+] less than 10- minus 3 M) Tm becomes independent of further decrease in [Na+] unless the dsRNA is exposed to high concentrations of EDTA, suggesting the involvement to tightly bound divalent cation. At relatively high ionic strengths ([Na+] greater than 0.1 M) a postulated A leads to A' ... conformation change occurs.     

The effects of tetraalkylammonium salts on helix-coil transition parameters in natural and synthetic ribo- and deoxyribo-polynucleotides

Thermal transition profiles were recorded for a variety of natural and synthetic DNA and double-stranded RNA preparations in the presence of tetramethylammonium (TMA+) and tetraethylammonium (TEA+) cations. Double-stranded RNAs of natural origin, with GC contents of 50% exhibited the same profiles and Tm values as native DNA containing normal bases. Hence the tetraalkylammonium cations liquidate not only the effects of base composition, and the difference in stability between A-T and A-U base pairs (further confirmed by measurements with uracil-containing DNA from phage PBS-2), but also that of the 2'OH. In the presence of TMA+ cations, there is very marked enhancement of the stability of U-U base pairs in poly(rU) and poly(Um). In 2.4 M TEA, the 1:1 complex of poly(G) with poly (C) formed readily and melted reversibly with a Tm as low as 87 degrees C. At concentrations of TMA and TEA for which dTm/dXGC = 0, the Tm values for various phage DNA preparations containing atypical bases (phages T2, T4, phi e, phi W-14, PBS-2) differ appreciably from those with 'normal bases'. Analysis of these findings indicates that the selective interaction of TMA and TEA cations with A-T base pairs occurs in the minor groove of the DNA helix. The overall results show that the action of these quaternary ammonium cations is not due exclusively to preferential binding to A-T base pairs, but must involve other factors, including modifications of solvent structure. They also underline the utility of TMA and TEA solvent systems for placing in evidence transition profiles not accessible in other solvent systems.     

Increasing the analytical sensitivity by oligonucleotides modified with para- and ortho-twisted intercalating nucleic acids--TINA

The sensitivity and specificity of clinical diagnostic assays using DNA hybridization techniques are limited by the dissociation of double-stranded DNA (dsDNA) antiparallel duplex helices. This situation can be improved by addition of DNA stabilizing molecules such as nucleic acid intercalators. Here, we report the synthesis of a novel ortho-Twisted Intercalating Nucleic Acid (TINA) amidite utilizing the phosphoramidite approach, and examine the stabilizing effect of ortho- and para-TINA molecules in antiparallel DNA duplex formation. In a thermal stability assay, ortho- and para-TINA molecules increased the melting point (Tm) of Watson-Crick based antiparallel DNA duplexes. The increase in Tm was greatest when the intercalators were placed at the 5' and 3' termini (preferable) or, if placed internally, for each half or whole helix turn. Terminally positioned TINA molecules improved analytical sensitivity in a DNA hybridization capture assay targeting the Escherichia coli rrs gene. The corresponding sequence from the Pseudomonas aeruginosa rrs gene was used as cross-reactivity control. At 150 mM ionic strength, analytical sensitivity was improved 27-fold by addition of ortho-TINA molecules and 7-fold by addition of para-TINA molecules (versus the unmodified DNA oligonucleotide), with a 4-fold increase retained at 1 M ionic strength. Both intercalators sustained the discrimination of mismatches in the dsDNA (indicated by ΔTm), unless placed directly adjacent to the mismatch--in which case they partly concealed ΔTm (most pronounced for para-TINA molecules). We anticipate that the presented rules for placement of TINA molecules will be broadly applicable in hybridization capture assays and target amplification systems.     

Rates of formation and thermal stabilities of RNA:DNA and DNA:DNA duplexes at high concentrations of formamide.

The thermal stabilities of RNA:DNA hybrids are substantially greater than those of DNA:DNA duplexes in aqueous electrolyte solutions containing high concentrations of formamide. Association rates to form DNA:DNA duplexes and DNA:RNA hybrids have been measured in these solvents. There is a temperature range in which DNA:DNA rates are negligible and RNA:DNA rates close to optimal.     

Influence of hydrogen bonding in DNA and polynucleotides on reaction of nitrogens and oxygens toward ethylnitrosourea.

The reactivity of ethylnitrosourea toward hydrogen-bonded sites in double-stranded DNA or oly(rA).poly(rU) was compared with those sites in single-stranded DNA, RNA, or poly(rA). Alkylation of the N-1 of A in poly(rA).poly(rU) was almost suppressed at 5 degrees C but could be markedly increased by raining the reaction temperature to 25 degrees C, well below the Tm of 56 degrees C. In contrast, the N-7 and N-6 of A, which are not hydrogen bonded, reacted to the same extent at temperatures ranging from 5 to 65 degrees C. The extent of reaction at the N-3 of A varied inversely with the reactivity of the N-1 of A, indicating that of these two nitrogens the N-1 of A is the most reactive. The proportion of reaction at the various nitrogens in poly(rA) was not affected by temperature. Hydrogen-bonded oxygens in double-stranded DNA are the O-6 of G, the O-4 of T, and the O2 of C. All are equally reactive at 5, 25, and 51 degrees C. It is concluded that the observed temperature independence is due to these oxygens having an electron pair not involved in hydrogen bonding and, thus, available for reaction. In contrast, the electron pair of the N-1 of A (or the N-3 of C) is involved in hydrogen bonding, and the extent of their reactivity is dependent on thermal fluctuation providing transiently open base pairs at temperatures far below the Tm.     

Mechanisms for RNA Capture by ssDNA Viruses: Grand Theft RNA

Viruses contain three common types of packaged genomes; double-stranded DNA (dsDNA), RNA (mostly single and occasionally double stranded) and single-stranded DNA (ssDNA). There are relatively straightforward explanations for the prevalence of viruses with dsDNA and RNA genomes, but the evolutionary basis for the apparent success of ssDNA viruses is less clear. The recent discovery of four ssDNA virus genomes that appear to have been formed by recombination between co-infecting RNA and ssDNA viruses, together with the high mutation rate of ssDNA viruses provide possible explanations. RNA–DNA recombination allows ssDNA viruses to access much broader sequence space than through nucleotide substitution and DNA–DNA recombination alone. Multiple non-exclusive mechanisms, all due to the unique replication of ssDNA viruses, are proposed for this unusual RNA capture. RNA capture provides an explanation for the evolutionary success of the ssDNA viruses and may help elucidate the mystery of integrated RNA viruses in viral and cellular DNA genomes.     

Renaturation kinetics and thermal stability of DNA in aqueous solutions of formamide and urea.

This paper reports the results of a systematic study of the effects of formamide and urea on the thermal stability and renaturation kinetics of DNA. Increasing concentrations of urea in the range 0 to 8 molar lower the Tm by 2.25 degrees C per molar, and decreases the renaturation rate by approximately 8 percent per molar. Increasing concentrations of formamide in the range from 0 to 50 percent lowers the Tm by 0.60 degrees C per percent formamide for sodium chloride concentrations ranging from 0.035M to 0.88M. At higher salt concentrations the dependence of Tm on percent formamide was found to be slightly greater. Increasing formamide concentration decreases the renaturation rate linearly by 1.1% per percent formamide such that the optimal rate in 50% formamide is 0.45 the optimal rate in an identical solution with no formamide. The effects of urea and formamide on the renaturation rates of DNA are explained by consideration of the viscosities of the solutions at the renaturation temperatures.     

Hybridization properties of nucleolar ribonucleic acid.

Rat liver nuclei were fractionated into chromatin and nucleolar fractions. Chromatin DNA, which does not form hybrids with rRNA, was, nevertheless, able to hybridize with 32P-labelled total nucleolar RNA. The optimal temperature for this hybridization was 55 degrees C when the reaction was carried out in 2 X SSC (0.3 MnaCl + 0.3 M-sodium citrate). The hybrids formed were specific, as judged by analysis of thermal elution profiles. The low Tm (73 degreesC) observed could be explained by the low amount of DNA in the filters. The lenth of the hybridized sequences was extimated as 54 mucleotide pairs. Contamination to nucleolar RNA by nucleoplasmic RNA was ruled out by showing the former was able to form more hybrids than the latter. Competition experiments showed that hybridization of nucleolar RNA, although not competed with by rRNA, suffered pronounced competition from total microsomal RNA, even though the levels of competition obtained did not equal thsoe with cold nucleolar RNA as competitor.