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.     

Electron microscopy of the melting of sequenced DNA

Differential melting curves (DMCs) of DNAs pA03 and pBR322 in solutions of different ionic strength (0.02 and 0.2M Na⁺) were obtained. A previously developed procedure of glyxal fixation of partially denatured DNA molecules at temperatures within the melting range was used to construct electron-microscopic melting maps for pBR322 and pAO3 plasmid DNA and for the replicative form of bacteriophage ?X174 DNA, allowing the melting of these DNA molecules to be followed in solutions of low (0.1 × SSC) and high (1 × SSC) ionic strength. In spite of the fact that the melting was at nonequilibrium at the low ionic strength, the melting maps for the two kinds of solutions practically coincided. Experimental data are compared with theoretical calculations based on the Fixman-Freire algorithm. The conclusion is that the melting pattern of these DNAs is, on the whole, correctly described by the theory, although there are appreciable differences between the theoretical and experimental differential melting curves. We have also determined the relation between the melting temperature of a region and its GC content, with allowances made for the boundary conditions of melting in 0.1 × SSC and 1 × SSC solutions, and have analyzed the theoretical shape of peaks of the DMCs.     

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

Summary 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.     

Influence of base-pair changes and cooperativity parameters on the melting curves of short DNAs

Theoretical melting curves were calculated for four DNA restriction fragments, 157–257 base pairs (bp), and a series of hypothetical block DNAs with sequences d(C_2xA_xC_2x). d(C_2xT_xG_2x), 5 ? x ? 40. These DNAs provided a mixture of A·T/G·C sequence distributions with which to investigate the effects of parameters and base-pair changes on the melting of short DNAs. The sensitivity of DNA melting curves to changes in internal loop melting parameters σ and κ was examined. As Expected, theoretical melting curves of short DNAs with a quasirandom base-pair sequence vary little with changes in internal loop parameters. End melting dominates the transition behaviour of these moleucles. This was also observed for the block DNAs up to x = 22. Beyond this length, melting curves are highly sensitive to the internal loop parameters. Sensitivity is also predicted for a 157-bp fragment with a block distribution of A·T and G·C pairs. These results indicate that accurate evaluation of internal loop parameters is possible with short DNAs (100–200 bp) containing a G·C/A·T/G·C block distribution with at least 22 bp in each block. Duplex-to-single-strands dissociation parameters were reevaluated form experimental melting curve data of eight DNA fragments using a least squares fit approach. This analysis confirmed parameter values previously found with a simplified dissociation model. A Priori predictions are made on the effects of base-pair changes on the melting curves of three characterized DNA restriction fragments. Single base-pair changes are predicted to induce small but measurable changes in the melting curves. The characteristics of the altered melting curves depend on the location of the base-pair change.     

Monitoring of fluorescence during DNA melting as a method for discrimination and detection of PCR products in variety identification

DNA melting curves of genotype-specific PCR fragments were used to differentiate between species and amongst varieties of cereals. Melting curves were generated by ramping the temperature of PCR fragments through their dissociation temperature in the presence of a double-stranded DNA binding dye. Genotypes were discriminated by differences in the position and shape of the melting curve which is a function of the fragment's sequence, length and GC content. Amplification of 5S ribosomal RNA genes generated species-specific fragments for six of the major cereal crops. Of the 15 possible pairwise comparisons, 13 distinctions could be reliably made using melting curve position data. Wheat varieties were identified by the melting profiles of PCR products generated using microsatellite primers. DNA melting curve analysis was conveniently coupled with capillary-PCR using a LightCycler instrument to provide a rapid method of genotyping in cereals.     

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.     

Salt-concentration dependence of thermal denaturation of restriction fragment DNAs from phi X174

High-resolution differential melting curves of phi X174 Y1 and Y2 restriction fragment DNAs, for which the base sequences were known, were measured at various sodium ion concentrations ranging from 195 to 2.3 mM. The curves were resolved into component peaks, and the change in the melting temperature, the change in the area, and the change in the breadth of each peak with change in salt concentration were examined. The locations of the melting regions corresponding to the peaks in the melting curves were assigned based on theoretical calculations of melting curves and stability maps. It was found that as the salt concentration was decreased from the high to the intermediate range, the breadths of the peaks on the low-temperature side decreased whereas those on the high-temperature side remained almost constant, and also the separation between the peaks along the temperature axis increased. Changes in the positions of peaks relative to one another were interpreted in terms of the difference in the free energy increase between a loop state and an end-coil state as the salt concentration decreased.     

Salt-concentration dependence of melting profiles of lambda phage DNAs: evidence for long-range interactions and pronounced end effects.

Melting profiles of DNAs from wild-type λ phage and a deletion mutant phage λb2 were examined in a wide range of salt concentration. The fine structure of the melting profiles changed sharply with salt concentration, especially in the range [Na⁺] ? 10 mM. A comparison of the melting profiles between the wild-type and the deletion mutant DNAs provided good evidence for extremely high melting cooperativity under low salt conditions, which is clearly manifested as the long-range interactions and the pronounced end effects; a large melting peak appeared as a result of the b2 deletion without any inserted sequence in the salt range [Na⁺] ? 2.8 mM. It was also suggested that in the further reduced salt range [Na⁺] ? 2.0 mM, melting of a λ DNA molecule starts from its right end rather than the most (A + T)-rich central region. The molecular basis of the high melting cooperativity at low salt concentrations can be explained in terms of the increased free energy associated with loop formation in the double-helical structure of DNA.     

The four-state model of a linear lattice: application to ligand-controlled hybridization of short duplex DNAs

An algorithm for calculating the order-disorder transition of a four-state linear lattice is presented. Recursion schemes for the probabilities of each site along the lattice occupying one of the four possible states were derived following the work of D. Poland (Biopolymers, 1974, Vol. 13, pp. 1859-1871) and H. Tachibana and A. Wada (Biopolymers, 1982, Vol. 21, pp. 1873-1885). The algorithm was parameterized to consider melting of short duplex DNA in the presence of duplex and single-strand binding ligands. Model calculations were performed for two 31 base-pair duplex DNAs with very different percent guanine-cytosine base pairs, and thus very different thermodynamic stabilities. In the absence of ligands, calculated melting curves of the two DNAs under identical solvent conditions and identical concentrations were separated by over 15 degrees C. In the presence of either duplex or single-strand binding ligands, if a sequence dependence to ligand binding is assumed, the melting curves of the two DNAs can be made to coalesce, i.e., stability of the two DNAs can be normalized! This example demonstrates the feasibility of controlling hybridization of short DNAs by sequence specific ligand binding.     

Denaturation of mouse satellite and ribosomal DNA during hydroxyapatite thermal chromatography of chromatin

Mouse DNA and chromatin were melted on hydroxyapatite and the denaturation profiles of ribosomal and satellite DNAs were followed by hybridization with their complementary RNAs. Neither ribosomal nor bulk DNA had significantly different melting profiles in chromatin as compared to DNA. However, most of satellite DNA eluted at higher temperature from chromatin than from purified DNA. One explanation for the higher melting temperature of mouse satellite DNA in chromatin suggests that the complex between this particular DNA component and at least some proteins in chromatin is more stable than the average DNA-protein interaction.     

Fine structures in denaturation curves of bacteriophage lambda DNA. Their relation to the intramolecular heterogeneity in base compositon.

Precise recording of polyphasic optical melting curves was carried out for three kinds of bacteriophage lambda DNA differing in length (lambdac1857s7, lambdacIb2 and lambdacIb2b5). Each of denaturation steps in melting profiles was characterized by two parameters, the melting temperature and the relative size. Any difference in fine structures in melting profiles was not recognized between the intact lambdacI857s7DNA and the DNA fragmented into halves. The change in fine structures in melting profiles caused by the deletions of the b2 and b5 region agreed qualitatively well with the prediction based on the physical and the genetical maps of phage lambda chromosome. The combined results indicate that, first, the well-known linear relationship between melting temperature and G+C content may apply also to each of denaturation steps in polyphasic melting curves due to heterogeneity of nucleotide distribution in a single DNA species, and, second, the effect of molecular ends on melting fine structures can be neglected at moderate salt concentration (0.01 M less than or equal to Na+ less than or equal to 0.2 M) for such a high molecular weight DNA. The heterogeneous distribution of nucleotides was derived for lambdaDNA and for its b2 and b5 regions.     

Thermodynamic stability of DNA tandem mismatches

The thermodynamics of nine hairpin DNAs were evaluated using UV-monitored melting curves and differential scanning calorimetry (DSC). Each DNA has the same five-base loop and a stem with 8-10 base pairs. Five of the DNAs have a tandem mismatch in the stem, while four have all base pairs. The tandem mismatches examined (ga/ga, aa/gc, ca/gc, ta/ac, and tc/tc) spanned the range of stability observed for this motif in a previous study of 28 tandem mismatches. UV-monitored melting curves were obtained in 1.0 M Na(+), 0.1 M Na(+), and 0.1 M Na(+) with 5 mM Mg(2+). DSC studies were conducted in 0.1 M Na(+). Transition T(m) values were unchanged over a 50-fold range of strand concentration. Model-independent enthalpy changes (DeltaH degrees ) evaluated by DSC were in good agreement (+/-8%) with enthalpy values determined by van't Hoff analyses of the melting curves in 0.1 M Na(+). The average heat capacity change (DeltaC(p)) associated with the hairpin to single strands transitions was estimated from plots of DeltaH degrees and DeltaS degrees with T(m) and ln T(m), respectively, and from profiles of DSC curves. The average DeltaC(p) values (113 +/- 9 and 42 +/- 27 cal x K(-1) x mol(-1) of bp), were in the range of values reported in previous studies. Consideration of DeltaC(p) produced large changes in DeltaH degrees and DeltaS degrees extrapolated from the transition region to 37 degrees C and smaller but significant changes to free energies. The loop free energy of the five tandem mismatches at 37 degrees C varied over a range of approximately 4 kcal x mol(-1) for each solvent.     

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.     

Statistical mechanical simulation of polymeric DNA melting with MELTSIM.

MOTIVATION: MELTSIM is a windows-based statistical mechanical program for simulating melting curves of DNAs of known sequence and genomic dimensions under different conditions of ionic strength with great accuracy. The program is useful for mapping variations of base compositions of sequences, conducting studies of denaturation, establishing appropriate conditions for hybridization and renaturation, determinations of sequence complexity, and sequence divergence. RESULTS: Good agreement is achieved between experimental and calculated melting curves of plasmid, bacterial, yeast and human DNAs. Denaturation maps that accompany the calculated curves indicate non-coding regions have a significantly lower (G+C) composition than coding regions in all species examined. Curves of partially sequenced human DNA suggest the current database may be heavily biased with coding regions, and excluding large (A+T)-rich elements. AVAILABILITY: MELTSIM 1.0 is available at: //www.uml.edu/Dept/Chem/UMLBIC/Apps/MEL TSIM/MELTSIM-1.0-Win/meltsim. zip. Melting curve plots in this paper were made with GNUPLOT 3.5, available at: http://www.cs.dartmouth.edu/gnuplot_inf o.html Contact : blake@maine.maine.edu;     

A study of the reversibility of helix-coil transition in DNA.

The reversibility of DNA melting has been thoroughly investigated at different ionic strengths. We concentrated on those stages of the process that do not involve a complete separation of the strands of the double helix. The differential melting curves of pBR 322 DNA and a fragment of T7 phage DNA in a buffer containing 0.02M Na+ have been shown to differ substantially from the differential curves of renaturation. Electron-microscopic mapping of pBR 322 DNA at different degrees of unwinding (by a previously elaborated technique) has shown that the irreversibility of melting under real experimental conditions is connected with the stage of forming new helical regions during renaturation. In a buffer containing 0.2M Na+ the melting curves of the DNAs used (pBR322, a fragment of T7 phage DNA, a fragment of phage Lambda DNA, a fragment of phiX174 phage DNA) coincide with the renaturation curves, i.e. the process is equilibrium. We have carried out a semi-quantitative analysis of the emergence of irreversibility in the melting of a double helix. The problem of comparing theoretical and experimental melting curves is discussed.     

A thermal denaturation study of the genomic DNAs from the North American genera of the fish family Percidae

The genomic DNAs of 1 1 species of percid fishes representing the five recognized North American genera are characterized using data from thermal denaturation assays. Base compositions were estimated from the transitional melting temperature of native and sonicated DNA and expressed as per cent guanine-cytosine (%GC) values. Among genera, %GC values for native DNAs (c, 23,000 base pairs in length) range between 38.3% GC for yellow perch, Perca flavescens (Mitchill), to 43.2% GC for sauger, Stizostedion cunadense (Smith). Significant variation in %GC values was observed among surveyed genera of the subfamily Percinae, which include Perca, Percinu, Etheostoma and Ammocrypfa . Melting profiles were generated for each species, and distinct GC rich regions were identified within the genomes of walleye, Sfizostcdion virreum (Mitchill) and Etheostoma spp. Compositional heterogeneity (CH) and asymmetry values were calculated from melting profile data. Patterns of variation in genomic characters differed among the genera surveyed. Members of the speciose genus Etheostomu showed relatively little variation in genomic characters, whereas Stizosredion exhibited significant interspecific variation.     

Comparative differential scanning calorimetric analysis of vegetable oils: I. Effects of heating rate variation

The melting curves of 11 vegetable oils have been characterised. Vegetable oil samples that were cooled at a constant rate (5 degrees C/min) from the melt showed between one and seven melting endotherms upon heating at four different heating rates (1, 5, 10 and 20 degrees C/min) in a differential scanning calorimeter (DSC). Triacylglycerol (TAG) profiles and iodine value analyses were used to complement the DSC data. Generally, the melting transition temperature shifted to higher values with increased rates of heating. The breadth of the melting endotherm and the area under the melting peak also increased with increasing heating rate. Although the number of endothermic peaks was dependent on heating rate, the melting curves of the oil samples were not straightforward in that there was no correlation between the number of endothermic peaks and heating rates. Multiple melting behaviour in DSC experiments with different heating rates could be explained by: (1) the melting of TAG populations with different melting points; and (2) TAG crystal reorganisation effects. On the basis of the corollary results obtained, vegetable oils and fats may be distinguished from their offset-temperature (Toff) values in the DSC melting curves. The results showed that Toff values of all oil samples were significantly (p < 0.01) different in the melting curves scanned at four different scanning rates. These calorimetric results indicate that DSC is a valuable technique for studying vegetable oils.     

Ligand-induced melting reaction of specific-sequence DNA molecules

An algorithm for the calculation of ligand-induced helix–coil transitions of macromolecules of any specific sequence was derived. The probabilities of each residue to be in helix and ligand-free, helix and ligand-bound, coil and ligand-free, and coil and ligand-bound states can be calculated by extending the recursion relation formula proposed by D. Poland [(1974) Biopolymers 13 , 1859–1871]. Calculations using hypothetical DNAs having block heterogeneities for melting reactions showed that cooperative binding specific to single strands weakens the effect of the heterogeneity. Fine structures in the melting profiles or cooperatively melting regions, which have so far been found in thermal melting experiments, were predicted to exist in ligand-induced melting reactions for natural DNA fragments.     

Differential scanning calorimetric and theoretical studies of ColE1 DNA

The differential scanning calorimetry (DSC) of plasmid ColE1 DNA was carried out. The DSC curve under the solvent condition of 1.0 X SSC buffer gave eleven clear peaks over the temperature range of 83 to 98 degrees C. The DSC curves obtained here were essentially in good agreement with the optical melting curves of ColE1 DNA reported previously. The theoretical melting profiles of ColE1 DNA calculated from its entire nucleotide sequence showed a good agreement with the DSC curves. The theoretical analysis made by constructing the thermal stability map showed that there was the positional correlation between the boundaries of the cooperatively melting regions and the ends of the protein coding regions of genes of ColE1. It was shown that the helix-coil transition of many of the small genes had a single cooperatively melting region. However, the large genes such as cea and mob3 had two or more cooperatively melting regions. It was suggested that this is closely related to the domain structures of the proteins encoded by such genes.     

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.