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

The hot-wire concept: Towards a one-element thermal biosensor platform

In this work, the 3ω hot-wire concept is explored as a prospective biosensing platform with a single sensing element that can detect analytes based on a change in the thermal interface conductance. A uniform receptor layer such as single-stranded DNA is immobilized on a thin aluminium wire, which serves not only as an immobilization platform but also as a heating element and temperature sensor together. The wire is heated periodically with an alternating current (angular frequency ω) and the third harmonic (frequency 3ω) of the voltage across the wire renders the efficiency of heat transfer from the wire to the surrounding medium. The amplitude of the 3ω voltage depends sensitively on the composition and conformation of the biofunctional interface layer. We illustrate this with a model system that includes blank aluminium wires, wires with silanes bound covalently to the native surface oxide, and with single-, respectively double-stranded DNA tethered to the silanes. The difference in heat-transfer due to these coatings is significant and measurable not only in a liquid but also in air. Based on this proof-of-concept, various applications come in sight such as mutation analysis and analyte detection with aptamers or molecularly-imprinted polymers as receptors. Wire materials other than aluminium are possible as well and the concept is suitable for miniaturization and parallelization.

Metastable hybridization-based DNA information storage to allow rapid and permanent erasure

The potential of DNA as an information storage medium is rapidly growing due to advances in DNA synthesis and sequencing. However, the chemical stability of DNA challenges the complete erasure of information encoded in DNA sequences. Here, we encode information in a DNA information solution, a mixture of true message- and false message-encoded oligonucleotides, and enables rapid and permanent erasure of information. True messages are differentiated by their hybridization to a "truth marker” oligonucleotide, and only true messages can be read; binding of the truth marker can be effectively randomized even with a brief exposure to the elevated temperature. We show 8 separate bitmap images can be stably encoded and read after storage at 25 °C for 65 days with an average of over 99% correct information recall, which extrapolates to a half-life of over 15 years at 25 °C. Heating to 95 °C for 5 minutes, however, permanently erases the message.

The chemical stability of DNA makes complete erasure of DNA-encoded data difficult. Here the authors mix true and false messages, differentiated by whether a truth marker oligo is bound to it, and show that brief exposure to elevated temperatures randomizes the binding of truth markers preventing data recovery.

Electrostatically PEGylated DNA enables salt-free hybridization in water

Chemically modified nucleic acids have long served as a very important class of bio-hybrid structures. In particular, the modification with PEG has advanced the scope and performance of oligonucleotides in materials science, catalysis and therapeutics. Most of the applications involving pristine or modified DNA rely on the potential of DNA to form a double-stranded structure. However, a substantial requirement for metal-cations to achieve hybridization has restricted the range of applications. To extend the applicability of DNA in salt-free or low ionic strength aqueous medium, we introduce noncovalent DNA-PEG constructs that allow canonical base-pairing between individually PEGylated complementary strands resulting in a double-stranded structure in salt-free aqueous medium. This method relies on grafting of amino-terminated PEG polymers electrostatically onto the backbone of DNA, which results in the formation of a PEG-envelope. The specific charge interaction of PEG molecules with DNA, absolute absence of metal ions within the PEGylated DNA molecules and formation of a double helix that is significantly more stable than the duplex in an ionic buffer have been unequivocally demonstrated using multiple independent characterization techniques.

Role of Melt Curve Analysis in Interpretation of Nutrigenomics' MicroRNA Expression Data

This article illustrates the importance of melt curve analysis (MCA) in interpretation of mild nutrogenomic micro(mi)RNA expression data, by measuring the magnitude of the expression of key miRNA molecules in stool of healthy human adults as molecular markers, following the intake of Pomegranate juice (PGJ), functional fermented sobya (FS), rich in potential probiotic lactobacilli, or their combination. Total small RNA was isolated from stool of 25 volunteers before and following a three-week dietary intervention trial. Expression of 88 miRNA genes was evaluated using Qiagen's 96 well plate RT² miRNA qPCR arrays. Employing parallel coordinates plots, there was no observed significant separation for the gene expression (Cq) values, using Roche 480® PCR LightCycler instrument used in this study, and none of the miRNAs showed significant statistical expression after controlling for the false discovery rate. On the other hand, melting temperature profiles produced during PCR amplification run, found seven significant genes (miR-184, miR-203, miR-373, miR-124, miR-96, miR-373 and miR-301a), which separated candidate miRNAs that could function as novel molecular markers of relevance to oxidative stress and immunoglobulin function, for the intake of polyphenol (PP)-rich, functional fermented foods rich in lactobacilli (FS), or their combination. We elaborate on these data, and present a detailed review on use of melt curves for analyzing nutigenomic miRNA expression data, which initially appear to show no significant expressions, but are actually more subtle than this simplistic view, necessitating the understanding of the role of MCA for a comprehensive understanding of what the collective expression and MCA data collectively imply.

Recent developments in reversible photoregulation of oligonucleotide structure and function

There is a growing interest in the photoregulation of biological functions, due to the high level of spatiotemporal precision achievable with light. Additionally, light is non-invasive and waste-free. In particular, the photoregulation of oligonucleotide structure and function is a rapidly developing study field with relevance to biological, physical and material sciences. Molecular photoswitches have been incorporated in oligonucleotides for 20 years, and the field has currently grown beyond fundamental studies on photochemistry of the switches and DNA duplex stability, and is moving towards applications in chemical biology, nanotechnology and material science. Moreover, the currently emerging field of photopharmacology indicates the relevance of photocontrol in future medicine. In recent years, a large number of publications has appeared on photoregulation of DNA and RNA structure and function. New strategies are evaluated and novel, exciting applications are shown. In this comprehensive review, the key strategies for photoswitch inclusion in oligonucleotides are presented and illustrated with recent examples. Additionally the applications that have emerged in recent years are discussed, including gene regulation, drug delivery and materials design. Finally, we identify the challenges that the field currently faces and look forward to future applications.

Small-Molecule-Based Self-Assembled Ligands for G-Quadruplex DNA Surface Recognition

Most drugs are small molecules because of their attractive pharmacokinetics, manageable development and manufacturing, and effective binding into the concave crevices of bio-macromolecules. Despite these features, they often fall short when it comes to effectively recognizing the surfaces of bio-macromolecules. One way to overcome the challenge of biomolecular surface recognition is to develop small molecules that become self-assembled ligands (SALs) prior to binding. Herein, we report SALs made from 8-aryl-2'-deoxyguanosine derivatives forming precise hydrophilic supramolecular G-quadruplexes (SGQs) with excellent size, shape, and charge complementarity to G-quadruplex DNA (QDNA). We show that only those compounds forming SGQs act as SALs, which in turn differentially stabilize QDNAs from selected oncogene promoters and the human telomeric regions. Fluorescence resonance energy-transfer melting assays are consistent with spectroscopic, calorimetric, and light scattering studies, showing the formation of a "sandwichlike" complex QDNA·SGQ·QDNA. These results open the door for the advent of SALs that recognize QDNAs and potentially the surfaces of other bio-macromolecules such as proteins.

Thermophoretic melting curves quantify the conformation and stability of RNA and DNA

Measuring parameters such as stability and conformation of biomolecules, especially of nucleic acids, is important in the field of biology, medical diagnostics and biotechnology. We present a thermophoretic method to analyse the conformation and thermal stability of nucleic acids. It relies on the directed movement of molecules in a temperature gradient that depends on surface characteristics of the molecule, such as size, charge and hydrophobicity. By measuring thermophoresis of nucleic acids over temperature, we find clear melting transitions and resolve intermediate conformational states. These intermediate states are indicated by an additional peak in the thermophoretic signal preceding most melting transitions. We analysed single nucleotide polymorphisms, DNA modifications, conformational states of DNA hairpins and microRNA duplexes. The method is validated successfully against calculated melting temperatures and UV absorbance measurements. Interestingly, the methylation of DNA is detected by the thermophoretic amplitude even if it does not affect the melting temperature. In the described setup, thermophoresis is measured all-optical in a simple setup using a reproducible capillary format with only 250 nl probe consumption. The thermophoretic analysis of nucleic acids shows the technique’s versatility for the investigation of nucleic acids relevant in cellular processes like RNA interference or gene silencing.

Comparison of the thermal denaturation behaviour of DNA-solutions and metaphase chromosome preparations in suspension

Hyperchromicity measurements are well established to analyse the thermal denaturation behaviour of pure DNA sequences in solution. Here, we show that under appropriate experimental conditions this technique can also be applied to study thermally controlled conformation changes of higher order DNA-protein complexes as for instance metaphase chromosome preparations in suspension. A computer controlled sensitive, upright double beam photometer with a heatable cuvette was constructed. Measurements of the temperature dependent extinction of both, solutions and particle suspensions are possible, since sedimentation effects of particles can be neglected due to the vertical optical axis in the probe cuvette. Thermal denaturation of metaphase chromosome preparations of human and Chinese hamster cells was investigated and compared to melting profiles of DNA solutions for two excitation wavelengths, 256 and 313 nm. The influence of neutral and low pH was considered. The results indicate that metaphase chromosome preparations show a thermal denaturation behaviour different from pure DNA. Whereas DNA solutions showed one pH dependent melting peak at 256 nm only, the peak pattern of metaphase chromosome preparations showed a large variability both at 256 and 313 nm. At neutral pH, in two temperature regions (40-55 degrees C and 75-82 degrees C) peaks were found indicating chromosome typical conformation changes independently from the mammalian cell species (Chinese hamster, human). In contrast to pure DNA, no typical reduction in the temperatures of peak maxima with decreasing pH was found for metaphase chromosome preparations of both cell types. These results may be relevant for further systematic studies of efficient thermal probe/target denaturation procedures in non enzymatic DNA-chromosome in situ hybridisation.

Inverted repeat sequences can influence the melting transitions of linear DNAs

The influence of inverted repeat sequences on the melting transitions of linear DNAs has been examined. Derivative melting curves (DMC) of a 514 base pair (bp) DNA, seven subfragments of this DNA, and four other DNAs have been compared to predictions of DNA melting theory. The 514-bp DNA contains three inverted repeat sequences that can form cruciform structures in supercoiled DNA. We refer to these sequences as c-inverted repeats. Previous work showed that the DMC of this DNA, unlike a number of other DNAs, is not accurately predicted by DNA melting theory. Since the theoretical model does not include hairpin-like structures, it was suggested that hairpin or cruciform formation in these inverted repeats may be responsible for this discrepancy. Our results support this hypothesis. Predicted DMCs are in good agreement with DNAs with no inverted repeats, or inverted repeats not evident in supercoiled DNA. Differences between the theoretical and experimental Tm's are less than or equal to 0.3 degrees C. DNA molecules that contain one or more of the three c-inverted repeats are not as accurately predicted. Experimental Tm values are lower than predicted values by 0.7-3.8 degrees C. It is concluded that some inverted repeat sequences can form hairpin-like structures during the melting of linear DNAs. These structures appear to lower overall DNA stability.

Plaque-media rewelding with reversible tissue optical property changes during receptive cw Nd:YAG laser exposure

Laser dosimetry for thermal fusion of plaque-wall separations during laser balloon angioplasty (LBA) is dependent upon the optical properties of the atheromatous arterial wall during one or more exposures to cw Nd:YAG laser radiation. An integrating sphere technique was used to measure relative transmission and reflection continuously during irradiation of human postmortem atheromatous aortic sections. Tissue luminal surface temperature was recorded continuously with a thermographic video imager during repetitive 20-30-sec, 8-15-watt exposure of a 3-mm nominal spot. In all specimens, transmission fell progressively during each exposure by 10-70% of baseline values. This effect was reversible with normalization of transmission during the initial phase of each subsequent exposure. Changes in transmission were inversely related to temperature over a 50-170 degrees C range, whereas relative reflection remained constant. Accompanying reversible transmission changes was the observation that the weld strength of plaque-aortic wall separations was unchanged by repetitive laser welding and tissue separation of individual sections. In conclusion, temperature-dependent reversible optical and physical properties of plaque occur during exposure to 1.06 microns cw laser radiation.

Cooperative thermal denaturation of the assembly origin region of TMV RNA

The assembly origin (AO) region of the tobacco mosaic virus RNA melts in an usually narrow (2.5 degrees C) temperature range. In an 0.01 M phosphate buffer the melting temperature of AO was found to be 41.5 degrees C. This value corresponds to the regions with the most stable secondary/tertiary structure of the whole TMV RNA molecule. It is assumed that the AO region has a specific tertiary structure, which is maintained by the long-range interactions as well as by interactions of the pseudoknot type.

Molecular relatedness of Staphylococcus aureus typing phages measured by DNA hybridization and by high resolution thermal denaturation analysis

Fifteen bacteriophages representative of the serological and lytic groups of the International Typing Set for Staphylococcus aureus were examined for genomic homology by DNA hybridization and by analysis of high resolution thermal denaturation profiles. Phages 11 and 80 alpha, not part of the set, were also examined. DNA homology measured by filter hybridization showed values ranging from near zero to 88 per cent in pair-wise comparisons. Cluster analysis of these data by standard numerical taxonomical methods yielded clusters which closely reflect the subdivision of the international set on the basis of serological reactions. High resolution thermal denaturation analysis yielded characteristic profiles for each phage DNA, with members closely related by hybridization analysis showing only minor differences. Quantitative analysis of the extent of overlap of these profiles generated relational values which were subjected to the same numerical taxonomic analysis as for the DNA hybridization data. The resultant dendrogram was qualitatively different only in minor respects from that derived from the hybridization analyses, but quantitatively homology was greater by 80 per cent or more for the DNAs which were least related according to the hybridization analyses. This upward shift in measured homology appears to reflect the similar base composition of the DNAs from these phages. Statistical comparison of the homology data obtained by the two methods showed them to be significantly correlated. These results indicate that the International Typing Set consists of phages which all appear to be related to a greater or lesser extent. If, as the history of the collection of these phages indicates, they are a random sample of aureophages, then this group of phages may represent a common genetic pool within which recombination, mutation, and genome rearrangement occur to generate unique individual phages.

Genetic distance in fungus genus Fusarium measured by comparative computer analysis of DNA thermal denaturation profiles

High resolution thermal denaturation profiles of different members of fungus genus Fusarium were compared with respect to the shape of their DNA melting curves. Quantitative comparison of the shape (areas under differential curves) of all thermal denaturation profiles was made. Thermal denaturation profiles can be used to derive the quantitative parameter, genetic distance, defined by Soumpasis (12). Based on such data of genetic distance a dendrogram and a genetic distance tree was constructed.

An analysis of repeated sequence heterogeneity

High-resolution thermal denaturation was used to measure the heterogeneity within repeated DNA sequences. An analysis of combined denaturation/redenaturation experiments on mouse satellite DNA suggests the existence of two minor components, one of which does not appear in the prepared EcoRII monomer. The resolving power of the denaturation/redenaturation experiment is estimated and contrasted with that of the reassociation experiment, often used to estimate repeated sequence heterogeneity. A mathematical model of the redenaturation experiment was developed and applied to mouse satellite data; the results suggest that only one-fourth of the mismatched base pairs are energetically significant in the reduction of heteroduplex stability.

Dual-mode computer processing for high resolution DNA thermal denaturation experiments

Two modes of data processing are appropriate in conducting high resolution thermal denaturation experiments (thermal increments of 0.05 degrees or closer). In the first mode, a general purpose microcomputer provides on-line services important to the control and monitoring of the initial experiment, including control of the spectrophotometer and heater, the recording of data, and the display of current hyperchromicities and approximate first derivatives. A subsequent microcomputer program then reads the recorded data files and carries out accurate calculations of derivative denaturation profiles and the estimate of the statistical error of the first derivative at each point. The data collection program handles three samples at a time and was designed to provide optimal results in thermal denaturation experiments with a single-beam spectrophotometer.

Similarity of genetic distance determined from DNA thermal denaturation profiles to standard estimates of bacteriophage relatedness

High resolution thermal denaturation profiles of a series of potentially related bacteriophages of Bacillus subtilis contain a multitude of distinctive features that permit them to be divided into at least four groups. In addition, the profiles can be used to derive the quantitative parameter, genetic distance, defined by Soumpasis (Soumpasis, D. (1980) J. Theor. Biol. 86, 137-147). Both the quantitative and the qualitative intercomparisons of profiles are in general agreement with the results of standard techniques for estimating genetic relatedness.

Localization of low-melting regions in phage T7 DNA

Specific fragmentation of T7 DNA at glyoxal-fixed denatured regions by the S1 endonuclease followed by restriction analysis made it possible to localize four low-melting regions in phage T7 DNA. These regions have the following coordinates:0.5-1.2;14.8+/-0.3;46.3+/-0.5; 98.4+/-0.3 (in T7 DNA length units). The location of the low-melting regions was refined by means of electron-microscopic denaturation mapping and gel electrophoresis of partially denatured DNA. The obtained localization of the low-melting regions is consistent with the available data on the sequence of T7 DNA. The map of low-melting regions was compared with the genetic map of T7 DNA.Images

Polydispersity and chain break effects on DNA intramolecular renaturation

The influences of sample polydispersity and of internal chain breaks are introduced in the formal description of intramolecular renaturation phenomenology, enhancing the usefulness of the involved methodology. In our method, renaturation is induced not by cooling but by increasing the sodium concentration. The single-stranded size distributions for the two types of samples employed (haplotomic and diplotomically degraded) are discussed. In the case of haplotomic cleavage, the variable is the strand size in the 'segment' between consecutive nicks in either of the native DNA strands. Our equations have been obtained by considering that the arrangement of DNA sequences may be approximately taken as random. These equations provide a good description of experimental data and a reasonable value (about 1000 base-pairs) for the size of the thermalite sequence, but show low sensitivity to departures from the random arrangement of sequences.

Precision method to determine denaturation temperature of collagen using ultraviolet difference spectroscopy

Ultraviolet difference spectroscopy was used to measure the thermal stability of molecular collagen under nonequilibrium conditions. A method using equipment commonly found in many laboratories and procedures for data gathering and data treatment are described. The melting temperature (Tm) was determined with high precision (S.D.: 0.10 degrees C) by means of close thermal spacing of recorded datas. Application of curve fitting procedures on the denaturation data enhanced the recognition of details in the thermal transition. Small transitions could be discriminated and thermally located with an accuracy of +/- 0.3 degrees C.

The mitochondrial genomes of Ustilago cynodontis and Acanthamoeba castellanii

Mitochondrial DNA from Ustilago cynodontis has been investigated in several of its properties. Its dG + dC content is equal to 33.5%; its buoyant density (1.698 g/cm3) is higher, by 5 mg/cm3, and its melting temperature (82.5 degrees C) is lower than expected for a bacterial DNA having the same base composition; the first derivative of its melting curve indicates a large compositional heterogeneity, its molarity of elution from hydroxyapatite is high, 0.28 M phosphate, and allows its partial separation from nuclear DNA. Degradation by micrococcal nuclease indicates that about 25% of the DNA is formed by stretches having no more than 15% dG + dC. Finally, the unit size of mitochondrial genome is about 50 X 10(6). In most of its properties, the mitochondrial genome of U. cynodontis presents strong analogies with that of Saccharomyces cerevisiae. A parallel investigation on mitochondrial DNA from Acanthamoeba castellanii which has as genome unit size of only 27 X 10(6), has shown that this shares with the former the dG + dC content (32.9%), the melting temperature (82.5 degrees C), a large compositional heterogeneity and a very similar pattern of micrococcal nuclease degradation; its buoyant density (1.692 g/cm3) and its molarity of elution from hydroxyapatite (0.25 M phosphate) are, however, normal, probably because of a different short-sequence pattern and the fact that its dA + dT-rich stretches are shorter, on the average.

Salt dependence and thermodynamic interpretation of the thermal denaturation of small DNA restriction fragments

The influence of cation concentration on the thermal denaturation of DNA restriction fragments from the E. coli lac regulatory region and from pVH51, ranging in size from 43- to 880- bp, is described. Upon increasing the ionic strength, the melting transitions broaden in a cooperative manner at salt concentrations characteristic for the specific fragment. For three fragments studied in detail, the salt concentration dependence at the midpoint varied between 0.03 and 0.19 M Na+. Along with the broadening, the melting transitions become more symmetrical. This result is discussed with respect to the irreversibility of melting transitions at low ionic strength. After a cooperative broadening, the shape of the melting curves remains constant up to salt concentrations of 0.5 M Na+. The dTM/dlog[Na+] values for three fragments fall between 15.7 and 16.7. An easily applicable approximation of the van't Hoff equation is used to evaluate the enthalpies of 13 transitions arising from the denaturation of 43 to 600 bp. The results of this analysis are compared to calculations of the expected enthalpies based on calorimetric measurements. The TMs of most transitions were directly related to the base composition, but several deviations from the predicted behavior were observed. The possible influences of fragment length and sequence on the thermal stability are discussed. The experimental and mathematical procedure to resolve a thermal denaturation transition with a width f 0.17 +/- 0.01 degrees and its distinction from another preceeding transition only approximately 0.15 degrees away in an 880-bp Hae III fragment from pVH51 is described. This transition is about half as wide as the smallest one reported to date.

EcoRI-generated reiterated components of the rat genome. I. Sequence of two (92 and 93 bp) related DNA fragments

The sequence of the 92 and 93 bp long, highly repetitive DNA fragments, isolated from EcoRI digested rat liver DNA, were determined. These fragments, designated 92 and 93, are found in equal abundance, 6.5 x 10(5) copies per haploid genome. J92 and J93 can be distinguished by their differential sensitivity to cleavage by HaeIII and HindIII, respectively, which cut the fragments at 75 and 57 bp from their mutually homologous 5'-ends. J92 and J93 are 38% and 35.4% G + C, respectively, and contain a disproportionate number of triplets complementary to stop codons in all reading frames. Three methylated sites were found in J92 while none could be detected in J93. The sequences around the m5C sites were 5'-Py-Py-m5C-G-Pu-Pu, except for one case where the second Py was replaced by an A. This site appeared to be hemimethylated. When J92 and J93 are placed in register from their mutually homologous 5'-ends, homology is 73% for the first 30 bp region and 63.5% for the total molecule. Thermal melting studies indicate sequence heterogeneity within J92 and J93 from substantial internal base mismatches. The sequences derived are therefore composite averages for the whole molecules. The Cot1/2 for the sequence was measured spectrophotometrically to be 2 x 10(-2) M/s on a DNA phosphorus basis and 2.15 x 10(-4) M/s on a mole fragment basis.

Melting fine structure of filamentous fungus nuclear DNA

Melting fine structure of the nuclear DNA isolated from the filamentous fungus Fusarium graminearum Schwabe is presented. Optical melting profiles of nuclear DNA were analyzed by using a combination of curve fitting and derivative techniques. The "melting components" were obtained from the derivative curve by a simple decomposition technique. Differential optical melting curves of unsheared nuclear DNA indicate the presence of 15 "melting components" in filamentous fungus nuclear genome. It should be emphasized that the "melting components" observed here are different from the "thermalites" which can be observed in bacteriophage DNA. The "melting components" reported here represent the separately melting of large "blocks" of fungus nuclear DNA.

Restriction endonuclease and molecular analyses of three rat genomes with special reference to chromosome rearrangement and speciation problems

When differences are found between related species of organisms, it is often assumed that the differences themselves are causal factors either in speciation itself or in processes related to speciation. Two recent proposals on the functions of satellite DNA (Hatch et al., 1976 and Fry and Salser 1977) are that (a) large amounts of satellite DNA are important in facilitating chromosome rearrangements and hence cytogenetic evolution, and (b) satellite DNA differences between homologous chromosomes lead to pairing difficulties and are important in generating infertility barriers and hence speciation. If these proposals were to have some generality, one could expect organisms with very low amounts of highly repeated DNA to exhibit few chromosome rearrangements and to be evolutionarily conservative in a cytogenetic sense.--We have chosen two very closely related species of rat which are phenotypically almost indistinguishable and which have undergone massive genome reorganization. They differ by 11 major centric rearrangements (2n = 32, 2n = 50). We have characterised their genomes by restriction endonuclease digestions, thermal denaturations, analytical ultracentrifugations and reassociation techniques, and have found that they have virtually no highly repeated DNA. Thus the 11 major chromosomal rearrangements have been fixed in present day genomes with hardly any highly repeated DNA, centric or otherwise.--It appears therefore, that a large amount of highly repeated DNA is not obligatory for the formation and fixation of chromosome rearrangements. In addition, the existing literature reveals that one can find almost any situation at all, from species groups with high amounts of satellite DNA and no gross chromosomal rearrangements, to ones such as those described here, with tiny amounts of highly repeated DNA and massive chromosomal reorganisation. Since direct experimental data indicates that satellite DNA differences per se between homologous chromosomes do not cause infertility, speculations concerning modes of speciation based on satellite DNA differences between otherwise homologous chromosomes would appear to be ill founded.

Fine structure in the thermal denaturation of DNA: high temperature-resolution spectrophotometric studies

Fine structures which appear in the optical melting profile of DNA are examined from both the experimental and theoretical aspects. After a brief historical survey of the DNA melting experiments during the pre-fine-structure era in Section II, the high temperature-resolution experimental techniques which are essential to the investigation of fine structure are described in Section III. Then, the current status of the high-resolution study is reviewed first by a phenomenological description of the melting profile (Section IV) and then of the refolding profile (Section V), where a general idea about the cooperatively melting region and several factors affecting it is given. Sections VI and VII are devoted to the review of current theoretical works. Several well-established theoretical frameworks which correlate the base sequence with the melting phenomena are examined in terms of their rigorousness and usefulness. The molecular thermodynamic parameters concerning the DNA melting which have been evaluated by several research groups are compared and discussed. Finally, in Section VIII, current ideas on the correlation between the fine structure and genetic functions and genetic maps are reviewed. Some future problems relating to the fine structure are also discussed.

The 1360 bp long basic repeat unit of calf satellite I DNA contains GC rich nucleus of about 140 bp

Fine melting profiles of calf satellite I DNA and its fragments obtained after digestion with endoR.EcoRI and endoR.AluI nucleases were investigated. It is shown that the 1360 bp basic repeat unit of calf satellite I DNA contains an about 140 bp long GC rich nucleus. It is localized on the 600 bp restriction fragment obtained after digestion of 1360 bp fragment with endoR.AluI nuclease. The main part of satellite I DNA melts as loops between such GC rich nuclei which strongly influence the melting properties of this satellite. There exist significant differences between the thermal stabilities of fragments containing many nuclei, one nucleus and those in which such nucleus is absent.

Numerical analysis of thermal denaturation of nucleic acids

Denaturation of DNA molecules by stepwise incrementation of the temperature leads to melting profiles showing a fine structure, composed of individual melting modes. A method is described by which quantitative physical information brought by the modes can be extracted from the melting profile. Related problems such as data editing and smoothing are also discussed.

Saltatory thermal denaturation of double-stranded viral RNAs

The double-stranded RNAs from bacteriophage phi6 and the replicative form of mengovirus denature upon heating in a series of abrupt steps which resemble the subtransitions (thermalites) observed within the high resolution profiles of small, naturally occurring DNA molecules. Such RNA thermalites are approximately an order of magnitude narrower than typical thermal subtransitions of nominally single-stranded RNA. We conclude that the same features of nucleotide sequence that give rise to cooperative denaturation in DNA genomes are to be found also in RNA genomes. Thus, high resolution thermal denaturation profiles are useful for characterizing double-stranded RNA molecules as well as native DNA in the size range of common viruses. A medium containing dimethylsulfoxide was required to lower the Tm of the RNA samples to a satisfactory temperature range. For double-stranded RNA in 50% dimethylsulfoxide, the dependence of Tm on G . C composition was greater than that of DNA in the same medium and also greater than that of double-stranded RNA in an aqueous medium. The fact that RNA thermalites are broader than DNA thermalites and that the melting temperature of double-stranded RNA has a greater dependence on base composition than that of DNA, indicates that at least one of the thermodynamic parameters for double helix formation in RNA is different from that in DNA.

Spectral analysis of high resolution direct-derivative melting curves of DNA for instantaneous and total base composition

Derivative melting profiles of DNA have been obtained directly by recording the difference in absorbance between two identical solutions maintained at a small constant temperature differential. This deltaA is monitored continuously with increasing temperature in a ratio recording spectrophotometer. Resolution of complex hyperfine structure in the profiles of small homogeneous viral DNAs appears to be significantly better than has been produced by various numerical methods of differentiation. In addition, a spectral method has been modified that permits easy analysis for DNA base composition from the ratio of derivative melting curves obtained at 282 and 260 nm. Eight bacterial and three vertebrate DNAs have been analyzed for total base composition from the product of the instantaneous base composition at small temperature intervals (0.05 degrees C) throughout the entire melting region and the integrated area of the 282 nm profile. The results are in excellent agreement with values determined by traditional methods.

Direct comparison of theoretical and experimental melting profiles for RF II phiX174 DNA

The determination by Sanger et al. of the comple nucleotide sequence for phiX174 DNA has made it possible for the first time to compare directly theoretical and experimental DNA melting profiles. The comparison shows that the theory predicts the observed shape of the differential melting curve surprisingly well. Calculation of the denaturation maps allows the peaks on the curve to be correlated with cooperative melting out of concrete regions on the sequence of nucleotides.

Specific fragmentation of T7 phage DNA at low-melting sites

A method has been developed for selective fragmentation of T7 DNA at AT-rich regions. The molecules have been subjected to complete digestion with single-strand-specific SI endonuclease after fixation of DNA AT-rich regions in the denatured state by glyoxal. The treatment resulted in three fragments having molecular weights of 13.6 +/- 0.4, 8.2 +/- 0.4 and 3.5 +/- 0.16 megadaltons as determined by electron microscopy. The position of these fragments along the T7 DNA molecule has been determined by means of analysis of the intermediates during SI-cleavage.

Intramolecular base composition heterogeneity of human DNA

The intramolecular base composition heterogeneity of human DNA has been investigated by electron microscopic observations of partially denatured structures and by equilibrium solution thermal denaturation techniques. DNA sequences having an average length of less than 2000 base pairs are found to be heterogeneous in base composition. These heterogeneous sequences occupy a minimum of 67 to 81% of the human genome.