Sequence analysis of end-labeled DNA fragments by solvolysis in aqueous solutions of different amines.

Cleavage of 3'-end-labeled DNA in hot aqueous solutions of different amines is comparatively examined for overall rate of DNA scission as well as for potential differences in the preference of the various amines for cleavage at the different bases. Under comparable conditions (0.5 M amine, 0.3 M NaCl, 90 degrees C), piperidine, diethylamine, morpholine, and ethylenediamine produce the same set of labeled fragments, at approximately equal overall cleavage rates. The same set of fragments is also obtained with diisopropylamine, triethylamine, and 1,4-diazabicyclo[2.2.2]octane, but at markedly lower overall cleavage rates. Solvolysis in aqueous piperidine or aqueous diethylamine leads to DNA scission predominantly at A sites, followed by G and C sites, and least frequently at T sites. In contrast, morpholine, ethylenediamine, diisopropylamine, triethylamine, and diazabicyclo[2.2.2]octane cleave the DNA predominantly at G sites. Therefore, use of one of the latter amines allows clear distinction of G bands and C bands, which could not be distinguished by the criterion of band intensity in the original one-lane sequencing method based on cleavage in hot aqueous piperidine (B. Ambrose and R. Pless (1985) Biochemistry 24, 6194-6200). The effect of varying the salt concentration on the cleavage distribution obtained with various amines is also examined, and a rationale is given for the influence of salt concentration and amine basicity on the relative rate of cleavage at G sites.     

Sites of gamma radiation-induced DNA strand breaks after alkali treatment

When DNA is gamma-irradiated in aerated aqueous solution, strand breaks are produced during irradiation or the next few hours. Subsequent piperidine treatment gives rise to further DNA strand ruptures at alkali-labile sites. These different types of DNA chain breaks provoked by gamma-irradiation have been studied with oligonucleotides having defined sequences. The breaks selectively developed inside the DNA chain at alkali-labile sites by piperidine treatment appeared at lower doses preferentially at guanine positions and the order G greater than A greater than T greater than or equal to C was observed. The total contribution of the direct DNA chain ruptures, formed during irradiation and the next few hours, and those obtained by piperidine treatment was studied at doses ranging from 10 to 120 Gy. The chain breaks appeared preferentially at thymine positions and the order T greater than G greater than A greater than or equal to C was shown for the higher doses.     

Studies on interaction between histone V (f2c) and deoxyribonucleic acids.

Histone V (2fc) from chick erythroctes was used in the study of its interaction with DNA from various sources. Complexes between this histone and DNA were formed using the procedure of continuous NaCl gradient dialysis in urea. Two physical methods, namely thermal denaturation and circular dichroism (CD), were used as analytical tools. Thermal denaturation of nucleohistone V with chick or calf thymus DNA shows three melting bands: band I at 45-50 degrees corresponds to free base pairs; band II at 75-79 degrees, and band III at 90-93 degrees correspond to histone-bound base pairs. In histone-bound regions, there are 1.5 amino acid residues/nucleotide in nucleohistone V. In contrast, a value between 2.9 and 3.3 was determined for nucleohistone I (fl) (H. J. Li (1973), Biopolymers 12, 287). Similar melting properties have been observed for histone V complexed with bacterial DNA from Micrococcus luteus. Histone V binding to DNA induces a slight transition from a B-type CD spectrum to a C-type spectrum. Trypsin treatment of nucleohistone V reduces melting band III much more effectively than band II. Such a treatment also restores DNA to B conformation in the free state. Reduction of the melting bands of nucleohistone V by polylysine binding follows the order of I greater than II greater than III, accompanied by the increase of a new band at 100 degrees. When two bacterial DNAs of varied A + T (adenine + thymine) content simultaneously compete for the binding of histone V, the more (A " T)-rich DNA is selectively favored. Under experimental conditions described here, Clostridium perfringens DNA with 69% A + T is bound by histone V in preference to chicken DNA with 56% A + T although the latter has natural sequences for histone V binding.     

The synthesis and properties of oligodeoxyribonucleotides containing N6-methoxyadenine.

Oligodeoxyribonucleotides containing N6-methoxyadenine (M) have been synthesized. The order of stability of duplexes consisting of synthesized oligodeoxyribonucleotides, 5'd(CCTGGTAXCAGGTCC)3'-5'd(GGACCTGNTACCAGG)3' (X = M, A, G. N = A, G, T, C), was M: A (Tm = 52 degrees C) greater than M: T (50 degrees C) greater than M: G (48 degrees C) greater than M: C (46 degrees C) observed by thermal denaturation in a buffer of 0.01 M Na cacodylate, and 0.1 M NaCl at pH 7.0. The Tms are within a range of 6 degrees of difference, which is smaller than those of Tms of the duplexes containing A:N pairs (11 degrees) and G:N pairs (11 degrees). DNA replication study on a template-primer system, 5'd(32p-CAGCTTTCGC)3' 3'd(GTCGAAAGCGMAGTCG)5', showed that TTP and dCTP were incorporated into DNA strands at a site opposite to M by Klenow DNA polymerase, but dATP and dGTP were not.     

A photoinduced cleavage of DNA useful for determining T residues.

Irradiation of 5'-[32P]-phosphate labeled DNA fragments with ultraviolet light in the presence of primary amines followed by piperidine treatment resulted in base-specific cleavage of the DNA chain at T residues, accompanied by a less intensive G reaction. This simple, T greater than G cleavage offers an alternative method for determining T residues in chemical DNA sequencing.     

A new procedure for determining thymine residues in DNA sequencing. Photoinduced cleavage of DNA fragments in the presence of spermine

A new procedure for T specific cleavage of DNA fragments utilizing photoreaction with spermine has been described. Irradiation of 3'-[32P]-end-labeled DNA fragments for 10-20 min with a germicidal lamp emitting mainly 254-nm light in the presence of 1 M spermine in distilled water resulted in a T specific cleavage of the DNA chains. This method does not require piperidine treatment. By contrast, when the DNA fragments were irradiated in the presence of methylamine under similar conditions, both G and T bands with the intensity of G greater than T have appeared. A similar but less selective T cleavage has also been observed in the irradiation of 5'-[32P]-end-labeled DNA fragments in the presence of spermine followed by brief heating of the photolysate in a loading buffer for gel electrophoresis. The T specific photoreaction with spermine and the G greater than T reaction with methylamine described here may be conveniently used in combination with the standard Maxam-Gilbert's reactions to provide independent confirmatory readings.     

Photocleavage of DNA and photofootprinting of E. coli RNA polymerase bound to promoter DNA by azido-9-acridinylamines.

The long-wavelength ultraviolet (lambda approximately 420 nm) radiation induced reaction between 6-azido-2-methoxy-9-acridinylamines and supercoiled plasmid DNA results in single strand scissions and formation of covalent adducts (ratio approximately 1:10). By treating azidoacridine-photomodified DNA with piperidine at 90 degrees C, additional strand scissions are observed in a complex sequence dependent manner with an overall preference for T greater than or equal to G greater than C much greater than A. The resulting DNA fragments migrate as 5'-phosphates in polyacrylamide gels. Photofootprinting of the binding site of RNA-polymerase on promoter DNA is demonstrated with an azido-9-acridinylamino-octamethylene-9-aminoacridine. Similar experiments using 9-amino-6-azido-2-methoxyacridine indicate that this reagent recognizes changes in the DNA conformation induced by RNA polymerase binding, in relation to open complex formation.     

Optimized conditions for solid-phase sequencing: simultaneous chemical cleavage of a series of long DNA fragments immobilized on CCS anion-exchange paper

A solid-phase method for simultaneous sequencing of ten or more long DNA fragments has been developed, using as support the cellulose matrix for chemical sequencing (CCS), anion-exchange paper [Rosenthal et al., Nucl. Acids Res. 13 (1985) 1173-1184]. We optimized several of the seven steps which include: (i) immobilization; (ii) washing; (iii) modification; (iv) washing; (v) sorting of the paper segments; (vi) piperidine reaction and chemical elution, and (vii) lyophilization. During carrier-supported chemical cleavage with dimethylsulfate (DMS) (G), HCOOH (A + G), KMnO4 (T greater than Pu) and NH2OH (C), losses of immobilized DNA are very low. DNA fragments ranging in length from several hundred bp up to 6 kb can be effectively chemically eluted from CCS paper during the piperidine reaction with an efficiency of more than 90%. Because no DNA salt elution and ethanol precipitation steps are necessary the method is rapid, convenient and allows complete automation.     

A new, convenient method for determining T residues in chemical DNA sequencing by using photoreaction with spermine

Irradiation of 3'-[32p]-labeled DNA fragments with 254-nm light in the presence of spermine resulted in a T specific cleavage of the DNA chain without piperidine treatment. In the presence of methylamine G + T reactions (G greater than T) were observed under the same irradiation conditions. The T reaction with spermine and the G greater than reaction with methylamine may be combined with the standard Maxam-Gilbert's C + T reaction to provide confirmatory determination of DNA sequences.     

Synthesis and properties of defined DNA oligomers containing base mispairs involving 2-aminopurine.

DNA heptamers containing the mutagenic base analogue 2-aminopurine (AP) have been chemically synthesized and physically characterized. We report on the relative stabilities of base pairs between AP and each of the common DNA bases, as determined from heptamer duplex melts at 275 and 330 nm. Base pairs are ranked in order of decreasing stability: AP.T greater than AP.A greater than AP.C greater than AP.G. It is of interest that AP.A is more stable than AP.C even though DNA polymerase strongly favors the formation of AP.C over AP.A base pairs. Comparisons of melting profiles at 330 nm and 275 nm indicate that AP.T, AP.A, and AP.C base pairs are annealed in heptamer duplexes and melt 2-3 degrees prior to surrounding base pairs, whereas AP.G appears not to be annealed.     

Mapping the binding site of aflatoxin B1 in DNA: systematic analysis of the reactivity of aflatoxin B1 with guanines in different DNA sequences

The mutagenic and carcinogenic chemical aflatoxin B1 (AFB1) reacts almost exclusively at the N(7)-position of guanine following activation to its reactive form, the 8,9-epoxide (AFB1 oxide). In general N(7)-guanine adducts yield DNA strand breaks when heated in base, a property that serves as the basis for the Maxam-Gilbert DNA sequencing reaction specific for guanine. Using DNA sequencing methods, other workers have shown that AFB1 oxide gives strand breaks at positions of guanines; however, the guanine bands varied in intensity. This phenomenon has been used to infer that AFB1 oxide prefers to react with guanines in some sequence contexts more than in others and has been referred to as "sequence specificity of binding". Herein, data on the reaction of AFB1 oxide with several synthetic DNA polymers with different sequences are presented, and (following hydrolysis) adduct levels are determined by high-pressure liquid chromatography. These results reveal that for AFB1 oxide (1) the N(7)-guanine adduct is the major adduct found in all of the DNA polymers, (2) adduct levels vary in different sequences, and, thus, sequence specificity is also observed by this more direct method, and (3) the intensity of bands in DNA sequencing gels is likely to reflect adduct levels formed at the N(7)-position of guanine. Knowing this, a reinvestigation of the reactivity of guanines in different DNA sequences using DNA sequencing methods was undertaken. The reactivities of 190 guanines were determined quantitatively and considered in a pentanucleotide context, 5'-WXGYZ-3', where the central, underlined G represents the reactive guanine and W, X, Y, and Z can be any of the nucleotide bases. Methods are developed to determine that the X (5'-side) base and the Y (3'-side) base are most influential in determining guanine reactivity. The influence of the bases in the 5'-position (X) is 5'-G (1.0) greater than C (0.8) greater than A (0.3) greater than T (0.2), while the influence of the bases in the 3'-position (Y) is 3'-G (1.0) greater than T (0.8) greater than C (0.4) greater than A (0.3). These rules in conjunction with molecular modeling studies (to be published elsewhere) were used to assess the binding sites that might be utilized by AFB1 oxide in its reaction with DNA.     

Automated sequencing of fluorescently labelled DNA by chemical degradation

A new general method for sequencing fluorescently labelled DNA by chemical degradation has been developed. It is based on the observation that fluorescein attached via a mercaptopropyl or aminopropyl linker arm to the 5'-phosphate of an oligonucleotide is stable during the reactions commonly used in chemical cleavage procedures. DNA to be degraded is first enzymatically synthesized in vitro by annealing and extending a fluorescently labelled primer thereby introducing the fluorescent label at the 5'-end of the fragment. The newly synthesized fluorescently labelled DNA is then chemically degraded using: (a) a set of four different cleavage reactions; or (b) only one reaction comprising methylation of G-residues followed by a partial cleavage with piperidine in the presence of sodium chloride. The fluorescent degradation products are loaded on either four lanes or one lane of the gel, respectively, and the emitted fluorescence detected online during electrophoresis. In the 'four reactions/four lanes' method 200-350 bp (base pairs) can be read from the labelled end. The 'one reaction/one lane' method, in which the nucleotide sequence is determined by measuring different signal intensities following the rule G greater than A greater than C greater than T, currently yields around 100-200 bp of sequence per sample.     

A duplex of the oligonucleotides d(GGGGGTTTTT) and d(AAAAACCCCC) forms an A to B conformational junction in concentrated salt solutions

The coexistence of both A form and B form tracts and formation of an A-B junction in the oligomer d(GGGGGTTTTT).d(AAAAACCCCC) in saturated sodium chloride solution have been detected by Raman spectroscopy. The entire duplex adopts the familiar B-form conformation in aqueous solution at low salt concentrations (0.1M NaCl). In 6M NaCl the adoption of an A form is observed within the G,C tract while a B-form is maintained in the A.T tract. The experimental results indicate that two different helical forms can co-exist in a rather short oligonucleotide and that formation of an A-B junction can occur over a fairly small span of bases. This is in agreement with recent rules governing the relation between base sequence and secondary structure of DNA published from this laboratory. The conformational preferences of each of the individual oligomers d(AAAAACCCCC) and d(GGGGGTTTTT) have also been investigated. The oligomer d(AAAAACCCCC) is single stranded but some evidence for base stacking is observed at 2 degrees C. In contrast, a double stranded B-form structure characterized by wobble G-T base pairing is observed for d(GGGGGTTTTT) in 0.1M and 6M NaCl.     

The determination of the sequences present in the shadow bands of a dinucleotide repeat PCR.

A Polymerase Chain Reaction (PCR) of a DNA sequence containing a CA repeat produces a main band but also several shadow bands that differ by 2 base pairs below the main band. In the experiments described in this paper, these shadow bands were excised from a DNA sequencing gel and directly sequenced. It was found that the sequence in the CA repeat was ambiguous. However, the sequence 5' and 3' to the CA repeat was clear and unambiguous. It is proposed that the shadow bands are generated by 2 base pair random deletions in the CA repeat region. During this process the sequence becomes 'scrambled' only in the CA repeat region. The shadow bands were shown to occur during the PCR since the genomic DNA template did not contain the shadow bands. It is probable that the shadow bands arise by slippage during the PCR. It is predicted that a thermostable DNA polymerase with a high processivity would greatly reduce the occurrence of shadow bands.     

DNA sequence analysis with a modified bacteriophage T7 DNA polymerase. Effect of pyrophosphorolysis and metal ions

Pyrophosphorolysis by bacteriophage T7 DNA polymerase leads to the degradation of specific dideoxynucleotide-terminated fragments on DNA sequencing gels. This reaction can be prevented by pyrophosphatase. It is also inhibited by a high concentration of dNTPs; only the dNTP complementary to the next base in the template is an effective inhibitor, suggesting the formation of a stable polymerase-primer-template-nucleotide complex despite the absence of a 3' hydroxyl group on the primer. The use of pyrophosphatase, a genetically modified T7 DNA polymerase that lacks exonuclease activity, and Mn2+ rather than Mg2+ to eliminate discrimination between dideoxynucleotides and deoxynucleotides (Tabor, S., and Richardson, C. C. (1989) Proc. Nat. Acad. Sci. U. S. A. 86, 4076-4080) generates bands of uniform intensity on a DNA sequencing gel. Uniform band intensities simplify the analysis of a DNA sequence, particularly with automated procedures. For example, when genomic DNA is sequenced directly, heterozygotic sequences are readily detected because their bands have half the intensity of homozygotic sequences. A procedure for automated DNA sequencing is described that exploits the uniformity. A single reaction with a single labeled primer is carried out using four different ratios of dideoxynucleotides to deoxynucleotides; after gel electrophoresis in a single lane, the sequence is determined by the relative intensity of each band.     

Sequence analysis of end-labeled DNA fragments by solvolysis in hot aqueous piperidine solutions

One-lane DNA sequencing by solvolysis in hot aqueous piperidine solutions, originally described for 5'-32P-labeled DNA (B. Ambrose and R. Pless (1985) Biochemistry 24, 6194-6200), is extended to 3'-labeled fragments. A salt-free sample for electrophoresis can be obtained by using 1 M LiCl in the solvolysis mixture and removing this salt from the dried hydrolysate by washing with ethanol. Rate and distribution of DNA cleavage in hot aqueous piperidine, containing 0.3 M NaCl, are studied in dependence of temperature, solvent, amine concentration, and reaction time. An increase in temperature strongly accelerates overall DNA degradation, but leaves the distribution of cleavage essentially unchanged. When 50% aqueous ethanol is substituted for water as the reaction solvent, the overall cleavage is slower, and scission at G-sites is enhanced relative to cleavage at the other bases. A rise in the piperidine concentration strongly accelerates the reaction, except at very high amine concentration. Cleavage at A-, G-, and C-sites increases steadily with reaction time, while the T-cleavage observed takes place primarily at the very beginning of the solvolysis.     

Characteristics and variations of B-type DNA conformations in solution: a quantitative analysis of Raman band intensities of eight DNAs

Raman spectra were obtained from four bacterial DNAs varying in GC content and four periodic DNA polymers in 0.1 M NaCl at 25 degrees C. A curve fitting procedure was employed to quantify and compare Raman band characteristics (peak location, height, and width) from 400 to 1600 cm-1. This procedure enabled us to determine the minimum number of Raman bands in regions with overlapping peaks. Quantitative comparison of the Raman bands of the eight DNAs provided several new results. All of the DNAs examined required bands near 809 (+/- 7) and 835 (+/- 5) cm-1 to accurately reproduce the experimental spectra. Since bands at these frequencies are associated with A-family and B-family conformations, respectively, this result indicates that all DNAs in solution have a mixture of conformations on the time scale of the Raman scattering process. Band characteristics in the 800-850-cm-1 region exhibited some dependence on CG content and base pair sequence. As previously noted by Thomas and Peticolas [Thomas, G. A., & Peticolas, W. L. (1983) J. Am. Chem. Soc. 105, 993], the poly[d(A)].poly[d(T)] spectra were qualitatively distinct in this region. The A-family band is clearly observed at 816 cm-1. The intensity of this band and that of the B-family band at 841 cm-1 were similar, however, to intensities in the natural DNA spectra. Three bands at 811, 823, and 841 cm-1 were required to reproduce the 800-850-cm-1 region of the poly[d(A-T)].poly[d(A-T)] spectra. This may indicate the presence of three backbone conformations in this DNA polymer. Analysis of intensity vs. GC content for 42 Raman bands confirmed previous assignments of base and backbone vibrations and provided additional information on a number of bands.     

Analysis of DNA sequences using a single chemical cleavage procedure

A novel approach to sequence analysis of end-labeled, defined DNA fragments, using a single chemical cleavage procedure and electrophoretic separation in a single lane, has been developed. Prolonged treatment with hot aqueous piperidine results in partial cleavage of the DNA at all positions; the relative propensity for this cleavage is different for the various bases in the DNA. The hydrolysate is resolved on a DNA sequencing gel, and the distribution of radioactivity in the electrophoretic lane is analyzed (a) in terms of differential peak heights of the radioactive bands and (b) in terms of the spacings between successive bands. Simultaneous application of these two base-characteristic criteria allows the deduction of the nucleotide sequence with an accuracy approaching that of the established four-lane methods of DNA sequencing.     

Taxonomy of alkaliphilic Bacillus strains

The DNA base compositions of 78 alkaliphilic Bacillus strains were determined. These strains were grouped as follows: DNA group A, guanine-plus-cytosine (G+C) content of 34.0 to 37.5 mol% (17 strains); DNA group B, G+C content of 38.2 to 40.8 mol% (33 strains); and DNA group C, G+C content of 42.1 to 43.9 mol% (28 strains). DNA group A includes the type strain of Bacillus alcalophilus Vedder 1934. DNA-DNA hybridization studies with DNA group A strains revealed that only one strain, strain DSM 2526, exhibited a high level of DNA homology with B. alcalophilus DSM 485T (T = type strain). Neither strain DSM 485T nor any other DNA group A strain is homologous to any of the Bacillus type strains with comparable base compositions. Six strains formed a distinct group containing three highly homologous strains and three strains exhibiting greater than 50% DNA homology.     

Effect of DNA base composition on the intercalation of proflavine. A kinetic study.

The effect of DNA base composition on the kinetics of the association between DNA and proflavine has been investigated using the temperature jump relaxation method. It is found that, regardless of the G + C base composition the results fit a two step mechanism, the second of which exhibits characteristics of intercalation of proflavine into DNA. However, they two equilibrium constants corresponding to these steps, KI and KII, depend on the nature of the DNAs. The constant KI is found to be an order of magnitude greater for M. lysodeikticus DNA (72% G + C) than for calf thymus DNA (48% G + C). Increasing G-C content thus appears to favor the intermediate non-intercalated complex of proflavine with DNA. Methylation of M. lysodeikticus DNA with dimethyl sulfate, preferentially yielding N7 methyl guanine as the modified base, again leads to an apparent two step mechanism, with the value of KI unchanged with respect to untreated DNA, while the affinity of proflavine for the intercalated complex measured by the value of KII increases for methylated DNA.