Distamycin-stabilized antiparallel-parallel combination (APC) DNA.

The formation of Antiparallel-Parallel-Combination (APC) DNA, a liner duplex with a segment of parallel-stranded (ps) helix flanked by conventional B-DNA, was tested with a number of synthetic oligonucleotides. The groove-binding ligand distamycin A (DstA) was used to stabilize the ps segment comprising five A x T base pairs. Two drug molecules bound per APC, one in each of the two equivalent grooves characteristic of ps-DNA. APC-DNA, reference molecules and their complexes with DstA were analysed by several methods: circular dichroism and absorption spectroscopy, thermal denaturation, chemical modification, and molecular modeling. The dye binding stoichiometry differed significantly due to inherent structural differences in the groove geometries of ps-DNA (trans base pairs, similar grooves) and conventional antiparallel-stranded (aps) B-DNA (cis base pairs, distinct major and minor grooves). The data support the existence of APC folding in solution.

The detection of B-form/A-form junction in a deoxyribonucleotide duplex.

The transition of the 14-meric deoxyoligonucleotide duplex d-(ACCCCCTTTTTTTG).d-(CAAAAAAAGGGGGT) from the B- to the A-conformation in water/trifluorethanol (TFE) solution was studied with the use of circular dichroism. An increase in the fraction of TFE induces a two-step B-A transition. In the first step, up to 73% TFE, the A-form is generated from the GC-rich part; in the second step, 73-82% TFE, the AT-rich part shifts to the A-form. By this we suggest the existence of a B/A junction near 73% TFE. Emergence of the B/A junction has been directly confirmed with the use of distamycin A and netropsin, ligands known to selectively bind to AT stretches of B-DNA. It can be shown that both ligands suppress formation of the A-form in the B-philic part. The free energy value for the B/A junction was estimated to be 2.1 kcal/mol, which agrees well with known data for polymeric DNAs. The obtained results may have biological relevance in connection with recently published x-ray data about the occurrence of the B/A junction in the complex of DNA with reverse transcriptase of HIV.

CRP-DNA complexes: inducing the A-like form in the binding sites with an extended central spacer.

The consensus DNA sequence for binding of the Escherichia coli cyclic AMP receptor protein (CRP) has two symmetrically related inverted recognition elements TGTGA:TCACA, separated by a variable spacer, normally 6 bp long. We have shown that the CRP-cAMP complex, when bound to synthetic binding sites with an extended 8 bp spacer segment, induces an increase in the DNA circular dichroism (CD). The CD change at lambda > 275 nm agrees with the shift of approximately one helical turn of DNA into A-like form. The B-conformation is preserved for CRP binding sites similar to that in the lac and uxaCA promoters with 6 bp spacers. Another effect accompanying DNA binding is a dramatic increase of the negative CD magnitude in the spectral region of the ligand cAMP, at lambda < 272 nm. This effect is observed when CRP binds to specific sites with 6 or 8 bp spacers as well as to non-specific DNA. We reason that the A-like form arises by compressing and unwinding the DNA in CRP-DNA complexes having 8 bp central spacers. This serves to maintain a fixed length and twisting angle and is controlled by the protein's relatively rigid frame. This model is consistent with the observation that some binding sites with 6 bp spacers may also show the CD increase inherent to the sites with the extended 8 bp spacers. These 6 bp spacers are characterized by an increased twisting angle that requires their unwinding to bind to CRP. We propose that a mutual adaptation between CRP and binding sites by local untwisting and a B-->A-like transition in the DNA is of general importance and may occur in other protein-DNA complexes, such as the complex of RNA polymerase with promoter DNA.

[The A-form of DNA: in search of the biological role]. / A-forma DNK: v poiskakh biologicheskoi roli.

Only recently first direct evidence for the involvement of the A-DNA in the biological processes and structures has been obtained. This was preceded by numerous studies during four decades, which revealed structural features of this second, next to the B-form, DNA conformation, the conditions for the B to A transition to occur in a tube, the requirements to nucleotide sequence. Due to these works the B-A cooperative transition in DNA is now understood as good as the DNA melting. The above physico-chemical studies forced one to think on the "biology" of the A-conformation and at the same time provided experimental possibilities for finding it in biological processes.

[B-A and B-Z transitions in deoxyoligoduplexes containing 4- and 5- methylcytosine]. / Perekhody B-A i B-Z dezoksioligodupleksakh, soderzhashchikh 4- i 5-metiltsitozin.

Self-complementary oligodeoxynucleotides: GGACCCGGGTCC, GGA4mCCCGGGTCC, GGA5mCCCGGGTCC, CGCGCGCG, CG4mCGCGCG, CG5mCGCGCG were synthetized to study the contribution of methyl groups into the energetics of the three known cooperative transitions in DNA: helix-coil, B-A and B-Z With the use of circular dichroism and absorbtion methods the profiles of the above transitions were obtained by variation of temperature (helix-coil), trifluoroethanol fraction (B-A), NaCl and trifluorethanol contents (B-Z). On the basis of the transition widths and shifts of the transition points due to the methylations the energetics of the methyl groups was estimated. 5mC stabilizes the B form relatively the A form by 0.33 kcal/mol; while 4mC by 0.5 kcal/mol. In the B-Z transition 5 mC stabilizes the Z form by 0.28 kcal/mol relatively the B form; 4mC stabilizes also the Z form although by 0.14 kcal/mol only. Thus, these naturally occurring modifications could modulate substantially the ability of a DNA piece to shift into the A or Z form.

Synthesis and physical characterization of DNA fragments containing N4-methylcytosine and 5-methylcytosine.

The synthesis of N4-methyl-2'-deoxycytidine and its fully protected mononucleotide, suitable for the oligonucleotide synthesis by phosphotriester method is described. A set of octanucleotides - d(CGCGCGCG), d(CG5mCGCGCG), d(CG4mCGCGCG) and dodecanucleotides - d(GGACCCGGGTCC), d(GGA5mCCCGGGTCC), d(GGA4mCCCGGGTCC) has been synthesized in a solution. Physical characterization of the oligonucleotide duplexes by means of UV and CD spectrometry provides the evidence that 4mC similarly to 5mC favours the B--greater than Z transition, although both of these methylated cytosines inhibit the B--greater than A conformational change. N4-Methylcytosine in contrast to 5-methylcytosine reduces the DNA double helix thermal stability.

CC/GG contacts facilitate the B to A transition of DNA in solution.

Self-complementary decadeoxynucleotides, CCGATATCGG, CCAGATCTGG, CCCTGCAGGG, GGGGGCCCCC, were designed and synthesized to estimate the A-philic free energy of CC/GG contacts. First, regions of temperature-stability of the double-stranded conformation were determined for each 10-mer. Then, circular dichroism spectra were recorded for the B-family forms at different temperatures, counter-ion concentrations and trifluoroethanol contents. A cooperative change typical of the B-A transition is observed in the CD spectra at a trifluoroethanol content specific for each duplex. The positions of half-transition points were functions not only of the nucleotide sequence but of the duplex length as well: the B to A transitions were hindered in these 10-mers in comparison with a lengthy DNA. The B-phility value was estimated to be 3 kcal/mol of 10-mer. The B-A transition point was shown to drop with an increase in the number of CC/GG contacts in a duplex. The designed 10-mers made it possible to estimate quantitatively the A-phility of CC/GG contact as compared with an average DNA: (FA-FB)CC = 0.2 Kcal/mol, (FA-FB)DNA = 0.7 Kcal/mol.

Peculiarities of the B to A transition of the lambda phage regulatory site OR3 and of its fragment.

Conformations of the synthetic deoxyoligonucleotide 17 base pairs long, which is an OR3 operator of lambda phage, and of its 9-b.p. fragment were studied by the circular dichroism method (CD). The regions of stability of the double-stranded state were determined for these duplexes. A comparison of the CD spectra for these oligonucleotides with the CD for a lengthy DNA showed the conformation of these short DNA pieces to belong to the B-family. A cooperative change in the CD spectra is observed in trifluoroethanol (TFE) solutions at a TFE concentration specific for each oligonucleotide, which is supposed to stem from a B to A transition. The length of the fragment was found to affect the ability for the B-A transition. The transition into the A form is hindered by 13% TFE for the short 9-nucleotide in comparison with the 17-nucleotide. We suggest that this is due to the B form stabilization by terminal base pairs (B-phility of the ends).

The absence of non-local conformational changes in OR3 operator DNA on complexing with the cro repressor.

The Interaction of the cro protein of lambda phage with a synthetic OR3 operator having 17 base pairs in length and with its 9 bp fragment has been studied using the circular dichroism (CD) method. In both cases, a considerable change in the CD of the samples was found in the region 260-300 nm upon the addition of the cro protein. The stoichiometry obtained by the CD titration was identical for OR3 and its 9 bp fragment: one duplex per dimeric cro. NaCl addition makes the complexes dissociate so that the 9 bp fragment becomes free at [NaCl] greater than 0.2 M while the whole OR3 becomes free at [NaCl] greater than 0.5 M. The CD spectra of both the free duplexes show a typical B-form conservative pattern with a positive CD band (270 nm) and a negative one (250 nm). The specific complexing of both the duplexes results in a substantial CD depression in the positive band. The most pronounced effect occurs at 280 nm. This spectral change is quite distinct from those in the B to A transition and in the non-cooperative winding of the DNA within the B-family of forms. The interaction of the cro protein with the non-operator DNAs, calf thymus DNA and a synthetic 10 bp duplex, reveals no visible CD changes at all. An inference is drawn that the CD change in the specific complexes is mainly due to the induced CD in tyr-26 upon its interaction with a specific base pair in the operator or its fragment, the operator DNA conformation being conserved in a B-like form as a whole.(ABSTRACT TRUNCATED AT 250 WORDS)

B-A transition in DNA.

The B-A transition is characterized by two main physical parameters which might be biologically important: the cooperativity length and free energy difference between the B and A states under physiological conditions. Earlier these values were determined by us in an experiment over the B-A shift in water-non-electrolyte solutions in the presence of small molecules ("ties") affecting the B-A equilibrium. Now we report a new method of determining the cooperativity length which utilizes a phase diagram (B,A, coil). The coordinates are the fraction of non-electrolytes and temperature. Application of the Ising model for joint description of the B-A and helix-coil transitions makes possible to find the cooperativity length using the known thermodynamic parameters of the DNA melting and the appearance of the phase diagram near the triple point (A,B,coil). The value thus found (approximately 10(1) base pairs) is in accord with the values obtained with ties. In the new method the junctions between the A and B segments actually play the role of ties, stabilizing the double-stranded state. A considerable effect of the melting curve widening within the B-A transition range was discovered. A possible explanation suggests the presence of the A-philic sequences in the natural DNA. The A-phility of the oligo G oligo C sequence was estimated from the B-A transition curves of the synthetic decanucleotide duplexes.

[Unfolding of nucleosome cores induced by chemical acetylation of histones]. / Razvorachivanie korovykh nukleosom, vyzvannoe khimicheskim atsetilirovaniem gistonov.

Relative accessibility of nucleosomal histones to acetic anhydride during acetylation has been studied as a function of concentration, pH and ionic strength of the solution using high-resolution gel-electrophoresis. It was shown that about 80% of lysine residues in nucleosomal histones and 100% of the same residues in histone complexes without DNA in 2 M NaCl are accessible to the modification, which is proved by the localization of the majority of lysine residues in nucleosomes near the surface of the histone octamer, by their participation in ionic interactions with DNA and, probably, in histone-histone contacts. Gel-electrophoretic experiments with nucleosomes and studies of the histone resistance to mild trypsinolysis indicated that neither nucleosomes themselves nor histone octamers are affected even though 50% of lysine residues in histones have been acetylated. The process of acetylation is accompanied by the growing tendency of histones to participate in mild trypsinolysis and by a gradual decline in electrophoretic mobility and in the value of the sedimentation constant. The circular dichroism spectra and the microscopic appearance of nucleosomes are also markedly changed. These results suggest that a gradual unfolding of nucleosomes occurs when 5 or more lysine residues in the nucleosomal histones have been acetylated.

Circular dichroism anisotrophy of DNA with different modifications at N7 of guanine.

The complexex DNA-Ag1+, DNA-Cu1+, protonated DNA and DNA methylated at N7 of guanine were oriented by pumping the solutions through a multicapillary cell in the direction of a light beam. The CD components along the DNA axis, delta epsilon parallel, and normal to it, 2 delta epsilon perpendicular, were calculated from the CD spectra of the oriented samples by the method of Chung and Holzwarth, (1975) J. Mol. Biol. 92, 449--466. It was shown that in most cases, except that of the protonated DNA, the degree of orientation was only slightly less than that for pure DNA. This demonstrated the absence of aggregation and of appreciable denaturation. In all cases the modifications of DNA give rise to a negative component 2 delta epsilon perpendicular, whose magnitude increased as the extent of modification increased. From both the CD spectra of non-oriented samples and the absorption spectra, an inference is drawn that Ag1+ and Cu1+ are attached to the same site as CH3 groups i.e., to the N7 atom of guanine. Proton transfer along the H-bond from the N1 atom of G to the N3 atom of the complementary cytosine is suggested to be a result of the modifications, although the case of H+-DNA may differ from the others. Based on the CD spectra for the anisotropic components, delta epsilon parallel and 2 delta epsilon perpendicular, it is proposed that ligand binding is accompanied by winding of the DNA helix.

On the flexibility of the boundaries between the A-form and B-form sections in DNA molecule.

The degree of orientation of DNA in a flow has been studied within the interval of the B - A transition induced by ethanol. The orientation of the B DNA (60-65% ethanol, v/v) and that of the A DNA (80-82% ethanol) are nearly identical. This means that both conformations have similar persistence lengths and that there is no aggregation in the course of formation of the A form. Within the transition range (65-78% ethanol) the orientation attains a sharp minimum which coincides with the half-transition point (73% ethanol). The cooperative character of the B - A transition presupposes the existence of boundaries between the alternating sections of the A and B conformations that may entail an increased flexibility of the DNA molecule and a corresponding drop of orientation. Theory predicts an elliptical dependence of the number of boundaries on the proportion of the A form. The experimental degree of orientation follows the same pattern. Quantitative evaluation shows that the flexibility of a boundary is small, so that several dozen of boundaries are required to simulate free rotation.

[Conformational transition of DNA within the B-family as revealed by anisotropy circular dichroism]. / Issledovanie konformatsionnogo perekhoda DNK v predelakh B-semeistva metodom anizotropii krugovogo dikhroizma.

The native T2 DNA in solutions with different LiCl concentrations was oriented by pumping through a capillary device similar to that described in rf. 1. The change of the parallel, deltaepsilon parallel, and perpendicular, 2 delta epsilon perpendicular, components of circular dichroism tensor was studied as a function of salt concentration. Positive (delta epsilon parallel 280) and negative (2 delta epsilon perpendicular 280) components were shown to increase in absolute magnitude, so that there was a monotonous drop in the longwave band magnitude of the isotropic delta epsilon 280 as a result of compensation; the shortwave band magnitude of the isotopic delta 245 and its anisotropic components were constant. It is proposed that while the helix is winding as a result of LiCl rise progressive tilting of base pairs takes place. It was also shown that the glucosylated T2 DNA in solution is wound to a greater extent than the non-glucosylated DNA of the same GC-content.

Circular dichroism of DNA--proflavine, DNA--ethidium and DNA--distamycine flow--oriented complexes.

The circular dichroism (CD) spectra of flow-oriented complexes of DNA with proflavine (PF), ethidium (ET) and distamycine (DS) have been studied in the ultraviolet region. The CD spectra with light propagating in parallel to the flow direction were measured by the method of Chung and Holzwarth [1]. Delta epsilon and delta epsilon values have been obtained by this method. It was shown that all the complexes studied exhibit a strong CD anisotropy so that "isotropic" CD spectra measured with a conventional procedure can be attributed to the mutual compensation of the two components of opposite signs.