Conformation of 145 base pair length poly (dG-dC) . poly (dG-dC) in solution and in association with histones.

We have studied the conformation of poly (dG-dC) . poly (dG-dC) in three conditions; i) associated with histones octamers, ii) alone at ionic strength 0.1, and ii) in solutions of over 2.5 M NaCl. The circular dichroism spectrum for the polymer bound to histones differs from that for the free polymer; the difference spectrum is similar to those for native and poly (dA-dT) . poly (dA-dT) core particles. Under the first two conditions, the 31P NMR spectrum is symmetric with line widths of 91 and 41 Hz, respectively, at 109.3 MHz. In high salt, two 31P peaks of equal intensity are observed, confirming recent results of Patel et al. (1) and indicating an alternating geometry for the phosphodiester backbone. Using this highly homogeneous DNA, we confirm that the Pohl-Jovin transition (2) is an intramolecular rearrangement, not requiring complete strand separation.     

Cromatin and core particles formed from the inner histones and synthetic polydeoxyribonucleotides of defined sequence.

Chicken erythrocyte inner histones (H2A, H2B, H3 and H4) were associated with the two complementary homopolymeric polydeoxyribonucleotides and the two alternating copolymeric polydeoxyribonucleotides. No evidence for formation of chromatin-like structures was obtained for the complexes with poly(dG) . poly(dC) or poly(dA) . poly(dT). Both poly (dGdC) . poly(dGdC) and poly(dAdT) . poly(dAdT) could be folded by histones to yield material digested by DNAase I to multiples of about 10 and by staphylococcal nuclease to 146 bp core particles. Due to the lack of sequence heterogeniety in the complex of histones with poly(dAdT) . poly(dAdT), core particles with remarkable fine structural detail are obtained. The internal organization of DNA in the AT-containing and GC-containing core particles appears not to be identical.     

An alternating conformation characterizes the phosphodiester backbone of poly(dA-dT) in solution.

A highly homogeneous 145-base-pair fragment of double helical poly(dA-dT) . poly(dA-dT) was obtained by micrococcal nuclease digestion of a semisynthetic chromatin prepared from the nucleosome core histones (H2A, H2B, H3, H4) and the synthetic polydeoxyribonucleotide. In contrast to higher molecular weight alternating copolymers, this fragment displayed two resolved 31P NMR signals, separated by 24 Hz at 10.93 MHz. The two signals were of equal intensity at all temperatures less than the Tm for the fragment. Analyses of the possible origins for the two reasonances leads to the conclusion that the phosphodiester backbone of this DNA contains two distinct phosphorus environments, probably in an alternating array. We suggest that this may indicate the presence of sequence-dependent local variation in the helical structure of DNA in general.     

Studies on a thermophilic RNA polymerase which is active only on poly d(A-T) and poly dAdT.

Two types of RNA polymerases [EC 2.7.7.6], polymerases A and B, exist in thermophilic bacteria, Thermus thermophilus HB8. Polymerase B is apparently like the core enzyme of polymerase A but is active only when an alternating copolymer of deoxyadenylic and deoxythymidylic acids (poly d(A-T)) or a mixture of homopolymers of deoxyadenylic acid and deoxythymidylic acid (poly dAdT) is used as a template. Polymerase B was further characterized to elucidate its relation to polymerase A and to determine why it is inactive on natural DNA's. 1. Polymerase B did not show pyrophosphate exchange activity. Dinucleoside monophosphates did not activate the RNA-synthesizing activity. The results suggested that polymerase B had no initiation and presumably no elongation activities. 2. Polymerase B had about 6 times greater affinity to DNA than polymerase A. The binding of polymerase B to DNA was, however, reversible. The complex of DNA with polymerase A was stable and the polymerase was not removed from the initial complex even when a large amount of DNA was added. 3. E. coli sigma subunit could not stimulate the activity of polymerase B toward DNA's. 4. Polymerase B could utilize poly d(A-T) and poly dAdT as templates, but could not use Bacillus cereus DNA though the structure is reported to be similar to that of poly d(A-T).     

Salt- and sequence-dependence of the secondary structure of DNA in Solution by 31P-nmr spectroscopy

We examined three sonicated, specific-seqiemce polydeoxynucleotides in solution over a wide range of concentrations of several salts by ¹³P-nmr spectroscopy, and we found that the alternating copolymer poly(dAdT)·poly(dAdT) exhibits a dinucleotide repeat unit in all five salts and at all concentrations studied, as indicated by the presence of a doubled in its ³¹P-nmr spectra. The two components of the doublet show selective shift effects. The upfield component is assigned to dApdT in the gauche^?-gauche^? conformation and shifts upfield in all four monovalent salts used, relative to a single-stranded oligonucleotide control. The downfield component is assigned to dTpdA in the trans-gauche^? conformation and shifts downfield with increasing CsF concentration but remains essentially constant in LiCl, NaCl, and CsCl. These changes indicate a fast noncooperative transition for poly(dAdT)·poly-(dAdT) from a presumed right-handed dinucleotide-repeat B-form to another conformation with a dinucleotide-repeat structure, via a continuum of structures that may differ in the extent of the winding of the double helix. Ethanol causes the upfield component to collapse into the other component, indicating conversion to a structure with a mononucleotide repeat unit and a trans-gauche^? conformation. Up to 1M Mg²⁺ appears to have no significant effect on the phosphodiester conformations of poly(dAdT)·poly(dAdT). By contrast, poly-(dGdC)·poly(dGdC) gives a slow cooperative transition from what is considered to be a right-handed regular B-form to a left-handed Z-form on increasing MgCl₂ and NaCl concentrations, although we observed no changes in chemical shifts below the transition points. The homopolymer poly(dA)·poly(dT) exhibits no unusual shift effects or transitions upon the addition of salts when compared to the oligonucleotide control and is considered to be a regular B-form with a gauche^?-gauche^? phosphodiester backbone conformation. These differences emphasize the distinct secondary structures of DNAs of different sequences and their selective responses to changes in solution conditions.     

The assembly of an H2A2,H2B2,H3,H4 hexamer onto DNA under conditions of physiological ionic strength

A novel nucleohistone particle is generated in high yield when a complex of DNA with the four core histones formed under conditions that are close to physiological (0.15 M NaCl, pH 8) is treated with micrococcal nuclease. The particle was found to contain 102 base pairs of DNA in association with six molecules of histones in the ratio 2H2A:2H2B:1H3:1H4 after relatively brief nuclease treatment. Prolonged nuclease digestion resulted in a reduction in the DNA length to a sharply defined 92-base pair fragment that was resistant to further degradation. Apparently normal nucleosome core particles containing two molecules each of the four core histones in association with 145 base pairs of DNA and a particle containing one molecule each of histones H2A and H2B in association with approximately 40 base pairs of DNA were also generated during nuclease treatment of the histone-DNA complexes formed under physiological ionic strength conditions. Kinetic studies have shown that the hexamer particle is not a subnucleosomal fragment produced by the degradation of nucleosome core particles. Furthermore, the hexamer particle was not found among the products of nuclease digestion when histones and DNA were previously assembled in 0.6 M NaCl. The high sedimentation coefficient of the hexameric complex (8 S) suggests that the DNA component of the particle has a folded conformation.     

Methylated poly(L-lysine): conformational effects and interactions with polynucleotides

Methylated lysine, arginine and histidine residues are found in a number of proteins (for example, histones, non-histone chromosomal proteins, ribosomal proteins, calmodulin, cytochrome C, etc.). We are studying the effects of methylation on the conformations of poly(lysine) and of the effects of methylation of poly(lysine) and poly(arginine) on interactions with polynucleotides. The conformational properties of epsilon-amino-methylated poly(lysine) differ from those of unmodified poly(lysine). Methylation increases resistance to thermally-induced and NaCl-induced changes in the CD spectrum. Guanidinium chloride increases (proportional to the degree of methylation) the extent of approach to the conformation in dispute as to its being a random coil or an extended helix. Methylation enhances aggregation in the helix-inducing solvent 0.5 M Ca(ClO4)2. With increasing methylation of poly(lysine), the conformation in dodecyl sulfate changes from beta, to 50% alpha, to random coil at the maximum methylation. Increasing methylation of poly(lysine) weakens the interaction with polynucleotides in respect to dissociation by salt, linearly with methyl content. Complexes of (dAdT)n.(dAdT)n with the polypeptides are increasingly stabilized to heat denaturation by progressive methylation. However, with a series of synthetic double-stranded RNA's and DNA's a more complex situation exists, Tm increasing or decreasing, depending on the base composition, sequence and type of sugar. Methylation of poly(lysine) and poly(arginine) can have opposite effects on Tm based on results with complexes with (dI)n.(dC)n. Methylated poly(lysine) affects the CD spectrum of polynucleotides, in a manner dependent on base composition and sequence. In some cases large positive or negative psi-spectra are induced, which, in the case of (dGdC)n.(dGdC)n, can be positive or negative depending on the degree of methylation of the polypeptide and the salt concentration. It is suggested that the biological effects of methylation proteins may be evoke by salt changes in the cell cycle, and that methylation can affect local interactions with nucleic acids and larger scale structure, and interactions with lipids.     

Structural modification of DNA by a DNA-binding motif SPKK: Detection of changes in base-pair hydrogen bonding and base stacking by uv resonance Raman spectroscopy

Interactions of a DNA-binding motif SPKK with polynuclcotides have been investigated by uv resonance Raman spectroscopy. Analysis of the Raman spectra has shown that the tetrapeptide SPKK weakens the adenine-thymine base-pair hydrogen bonding in poly (dA-dT)·poly (dAdT) and reduces the adenine-adeninc base stacking interactions in poly (dA)·poly (dT), both effects being indicative of destabilization of the DNA double helical structure. On the other hand, poly(dG-dC)·poly(dG-dC) and poly(dG)·poly(dC) do not show any structural change in the presence of SPKK. The present observations confirm that the SPKK motif, which is frequently found in historic H1 proteins, specifically binds to A/T-rich regions of DNA and loosens the DNA double-helical structure. One of the roles of the SPKK motifs in histones may be to increase DNA flexibility so that DNA can wrap around core histones and be assembled into chromosomes more easily. © 1995 John Wiley & Sons, Inc.     

Laser Raman spectra of calf thymus chromatin and its constituents.

Extensive Raman measurements have been made on calf thymus chromatin, core chromatin, the (H3,H4)/DNA complex, and isolated DNA. The results indicate that the alpha-helical content of the nucleosomal histones gradually increases as they form the heterocomplexes that lead to the formation of the octameric nucleosome core. The secondary structure of the latter is not modified as it binds to DNA. The spectra indicate that the DNA essentially retains its B conformation in nucleosomes, although slight changes probably occur in the ribose-phosphate backbone. No specific interactions between the nucleosomal histones and DNA can be established from the spectra, but histone H1 possibly interacts selectively with the thymine bases.     

Poly(ADP-ribosylated) histones in chromatin replication

Poly(ADP-ribosylation) of histones and several other nuclear proteins seem to participate in nuclear processes involving DNA strand breaks like repair, replication, or recombination. This is suggested from the fact that the enzyme poly(ADP-ribose) polymerase responsible for this modification is activated by DNA strand breaks produced in these nuclear processes. In this article I provide three lines of evidence supporting the idea that histone poly(ADP-ribosylation) is involved in chromatin replication. First, cellular lysates from rapidly dividing mouse or human cells in culture synthesize a significant number of oligo- in addition to mono(ADP-ribosylated) histones. Blocking the cells by treatment of cultures with 5 mM butyrate for 24 h or by serum or nutrient depletion results in the synthesis of only mono- but not of oligo(ADP-ribosylated) histones under the same conditions. Thus, the presence of oligo(ADP-ribosylated) histones is related to cell proliferation. Second, cellular lysates or nuclei isolated under mild conditions in the presence of spermine and spermidine and devoid of DNA strand breaks mainly synthesize mono(ADP-ribosylated) histones; introduction of a small number of cuts by DNase I or micrococcal nuclease results in a dramatic increase in the length of poly(ADP-ribose) attached to histones presumably by activation of poly(ADP-ribose) polymerase. Free ends of DNA that could stimulate poly(ADP-ribosylation) of histones are present at the replication fork. Third, putatively acetylated species of histone H4 are more frequently ADP-ribosylated than nonacetylated H4; the number of ADP-ribose groups on histone H4 was found to be equal or exceed by one the number of acetyl groups on this molecule. Since one recognized role of tetraacetylated H4 is its participation in the assembly of new nucleosomes, oligo(ADP-ribosylation) of H4 (and by extension of other histones) may function in new nucleosome formation. Based on these results I propose that poly(ADP-ribosylated) histones are employed for the assembly of histone complexes and their deposition on DNA during replication. Modified histones arise at the replication fork by activation of poly(ADP-ribose) polymerase by unligated Okazaki fragments.     

Methylated Polyl(L-lysine): Conformational Effects and Interactions with Polynucleotides

Abstract

Methylated lysine, arginine and histidine residues are found in a number of proteins (for example, histones, non-histone chromosomal proteins, ribosomal proteins, calmodulin, cytochrome C, etc.). We are studying the effects of methylation on the conformations of poly(lysine) and of the effects of methylation of poly(lysine) and poly(arginine) on interactions with polynucleotides. The conformational properties of e-amino-methylated poly(lysine) differ from those of unmodified poly(lysine). Methylation increases resistance to thermally- induced and NaCl-induced changes in the CD spectrum. Guanidinium chloride increases (proportional to the degree of methylation) the extent of approach to the conformation in dispute as to its being a random coil or an extended helix. Methylation enhances aggregation in the helix-inducing solvent 0.5 M Ca(ClO₄)₂. With increasing methylation of poly(lysine), the conformation in dodecyl sulfate changes from β, to 50% α, to random coil at the maximum methylation.

Increasing methylation of poly(lysine) weakens the interaction with polynucleotides in respect to dissociation by salt, linearly with methyl content. Complexes of (dAdT)_n·(dAdT)_n with the polypeptides are increasingly stabilized to heat denaturation by progressive methylation. However, with a series of synthetic double-stranded RNA's and DNA's a more complex situation exists, Tm increasing or decreasing, depending on the base composition, sequence and type of sugar. Methylation of poly(lysine) and poly(arginine) can have opposite effects on Tm based on results with complexes with (dI)_n·(dC)_n. Methylated poly(lysine) affects the CD spectrum of polynucleotides, in a manner dependent on base composition and sequence. In some cases large positive or negative ψ-spectra are induced, which, in the case of (dGdC)_n·(dGdC)_n, can be positive or negative depending on the degree of methylation of the polypeptide and the salt concentration.

It is suggested that the biological effects of methylated proteins may be evoked by salt changes in the cell cycle, and that methylation can affect local interactions with nucleic acids and larger scale structure, and interactions with lipids.     

Conformational variability of poly(dA-dT).poly(dA-dT) and some other deoxyribonucleic acids includes a novel type of double helix

The article reviews data indicating that poly(dA-dT).poly(dA-dT) is able of adopting three distinct double helical structures in solution, of which only the A form conforms to classical notions. The other two structures have dinucleotides as double helical repeats. At low salt concentrations poly(dA-dT).poly(dA-dT) adopts a B-type alternating conformation which is exceptionally variable. Its architecture can gradually move in the limits demarcated by the CD spectra with inverted long wavelength CD bands and the 31P NMR spectra with a very low and a 0.6 ppm separation of two resonances. Contrary to Z-DNA, the 31P NMR spectrum of the limiting alternating B conformation of poly(dA-dT).poly(dA-dT) is characterized by an upfield shift of one resonance. We attribute the exceptional conformational flexibility of the alternating B conformation to the unequal tendency of bases in the dA-dT and dT-dA steps to stack. However, by assuming the limiting alternating B conformation, the variability of the synthetic DNA is not exhausted. Specific agents make it isomerize into another conformation by a fast, two-state mechanism, which is reflected by a further deepening of the negative long wavelength CD band and a downfield shift of the 31P NMR resonance of poly(dA-dT).poly(dA-dT) that was constant in the course of the gradual alterations of the alternating B conformation. These changes are, however, qualitatively different from the way poly(dG-dC).poly(dG-dC) behaves in the course of the B-Z isomerization. Poly(dG-dC).poly(dG-dC) displays purine-pyrimidine (dGpdC) resonance in the characteristic downfield position, while the downfield resonance of poly(dA-dT).poly(dA-dT) belongs to the pyrimidine-purine (dTpdA) phosphodiester linkages. Consequently, phosphodiester linkages in the purine-pyrimidine steps play a similar role in the appearance of the Z form to the pyrimidine-purine phosphodiesters in the course of the isomerization of poly(dA-dT).poly(dA-dT). This excludes that the high-salt structures of poly(dA-dT).poly(dA-dT) and poly(dG-dC).poly(dG-dC) are members of the same conformational family. We call the high-salt conformation of poly(dA-dT).poly(dA-dT) X-DNA. It furthermore follows from the review that synthetic molecules of DNA with alternating purine-pyrimidine sequences of bases can adopt either the Z form or the X form, or even both, depending on the environmental conditions. This introduces a new dimension into the DNA double helix conformational variability. The possible biological relevance of the X form is suggested by experiments with linear molecules of natural DNA.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nucleosome cores reconstituted from poly (dA-dT) and the octamer of histones.

In this paper we describe a detailed investigation of the reconstitution of nucleosome cores from poly (dA-dT) and the octamer of histones. We also attempted the reconstitution from the copolymers poly dA.poly dT, poly dG.poly dC and poly (dG-dC). The repeat of the reconstituted chromatin fibre is discussed. The micrococcal nuclease released poly (dA-dT) core particle is found to contain a considerably narrower DNA size distribution that of the native random DNA nucleosome core (12). In addition we have succeeded in obtaining small crystals of the poly (dA-dT) nucleosome core. The DNAase I digestion pattern of the poly (dA-dT) containing nucleosome core is presented. The periodicity of DNAase I cutting sites is found to be about 10.5 bases and is similar to that of the native nucleosome core (12, 13).     

Phosphorus-31 nuclear magnetic resonance of highly oriented DNA fibers. 1. Static geometry of DNA double helices

The static geometry of the phosphodiesters in oriented fibers of DNA and a variety of polynucleotides was investigated by solid-state 31P nuclear magnetic resonance (NMR) spectroscopy. The structural parameters of the phosphodiester backbone expressed by two Euler angles beta and gamma were estimated on the basis of the NMR spectra of natural DNA, poly(dA).poly(dT), poly(rA).poly(dT), and poly-(rA).poly(rU). The Euler angles were calculated by using the known single crystal structures of a decamer, r(GCG)d(TATACGC), and a dodecamer, d(CGCGAATTCGCG). The distribution pattern of the Euler angles was quite different between these two oligonucleotides due to the different types of conformation, and it was fully consistent with the 31P NMR results, showing that the conformation of the B form DNA is very heterogeneous while that of the A or A' form is much more invariable with regard to the base composition. The structural parameters were also calculated by using various structures determined by the X-ray fiber diffraction studies, and they were evaluated on the basis of the 31P NMR data. Notably, poly(dA).poly(dT) fibers exhibited abnormal 31P NMR spectra which were very broad in line width and were not appreciably perturbed by hydration; a coiled double-helical structure is proposed as the most plausible model for this polymer.     

Limitations of the poly(glutamic acid) reconstitution method in the reassembly of mono- and dinucleosomes

Reconstitution of mononucleosomes and dinucleosomes at physiological ionic strength by means of poly(glutamic acid) is not efficient at physiological histone octamer:DNA ratios, unlike that with the salt dialysis method. The shorter the DNA is, the less transfer of octamers from poly(glutamic acid) to DNA occurs. By increasing the octamer:DNA ratio it is possible to involve all the DNA in the assembly, but for DNA longer than core particle length, nucleoprotein particles containing extra histones are concomitantly generated. Except for core particle and chromatosome lengths of DNA reassembled at 0.6:1 or 1:1 octamer:DNA ratio (and thus with low yield), reconstituted nucleoprotein particles proved to be different from native nucleosomes by their insolubility upon isolation. In the aggregates, DNA ends seemed to be sufficiently loose to allow exonuclease III digestion up to a certain limit. This resulted in patterns that for some cloned DNA fragments could give the impression, without knowledge of the above, of resulting from a unique octamer position. In view of the small range of length of DNA and the low yield of faithful reconstitution, the assembly method using poly(glutamic acid) is only of limited use in mono- or dinucleosome reconstitution experiments, at least in our hands.     

Structure of subnucleosomal particles. Tetrameric (H3/H4)2 146 base pair DNA and hexameric (H3/H4)2(H2A/H2B)1 146 base pair DNA complexes

The tetrameric (H3/H4)2 146 base pair (bp) DNA and hexameric (H3/H4)2(H2A/H2B)1 146 bp DNA subnucleosomal particles have been prepared by depletion of chicken erythrocyte core particles using 3 or 4 M urea, 250 mM sodium chloride, and a cation-exchange resin. The particles have been characterized by cross-linking and sedimentation equilibrium. The structures of the particles, particularly the tetrameric, have been studied by sedimentation velocity, low-angle neutron scattering, circular dichroism, optical melting, and nuclease digestion with DNase I, micrococcal nuclease, and exonuclease III. It is concluded that since the radius of gyration of the DNA in the tetramer particle and its maximum dimension are very close to those of the core particle, no expansion occurs on removal of all the H2A and H2B. Nuclease digestion results indicate that histones H3/H4 in the tetramer particle protect a total of 70 bp of DNA that are centrally located within the 146 bp. Within the 70 bp DNA length, the two terminal regions of 10 bp are, however, not strongly protected from digestion. The optical melting profile of both particles can be resolved into three components and is consistent with the model of histone protection of DNA proposed from nuclease digestion. The structure proposed for the tetrameric histone complex bound to DNA is that of a compact particle containing 1.75 superhelical turns of DNA, in which the H3 and H4 histone location is the same as found for the core particle in chromatin by histone/DNA cross-linking [Shick, V. V., Belyavsky, A. V., Bavykin, S. G., & Mirzabekov, A. D. (1980) J. Mol. Biol. 139, 491-517]. Optical melting of the hexamer particle shows that each (H2A/H2B)1 dimer of the core particle protects about 22 base pairs of DNA.     

Conformational effects of histones H1 on DNA structure. Comparative study between H1-1, H1(0), H5 and sperm holothuria phi 0

Interactions of mammalian histones, H1-1 and H1(0), phi 0 from holothuria sperm and H5 with poly(dA-dT), poly(dG-dC) and poly(dG-me5dC) were measured by a nitrocellulose filter binding assay and circular dichroism. All of the proteins bound to every one of the polymers, but differed in the extent of binding, which depended on the polynucleotide/protein ratios and ionic strength. The order of retention of all polymers was phi 0 greater than H1-1 greater than H1(0). The binding of H1(0) to poly(dG-me5dC) was remarkably sensitive to ionic strength. The proteins caused changes in the spectral features of the polynucleotides, but differed in the type and extent of the change. Complexes prepared with H1-1 and H1(0) with all polymers showed a strongly negative psi spectrum. Complexes of poly(dA-dT) and phi 0, at a protein/polynucleotide ratio of 0.4, displayed a distinctive spectrum, giving the appearance of a Z-like DNA spectrum, at low ionic strength. At higher ionic strength the complexes showed a psi spectrum. Complexes of poly(dG-me5dC) in the Z or B conformation with phi 0 showed spectral features characteristic of a mixture of a Z-like and a psi spectrum. In contrast, H5 reduced the Z-DNA spectral features in the presence of Mg, and produced an inversion of the B spectrum up to a polynucleotide/protein ratio of 0.24. These findings demonstrate the ability of different proteins to produce changes in the conformation of DNA. This may reflect the ability of chromatin to undergo differential condensation, depending on both the base composition of DNA and the type of H1 histone bound to it.     

1H NMR investigation of the conformational states of DNA in nucleosome core particles.

In this study 1H NMR has been used to investigate the conformational state of DNA in nucleosome core particles. The nucleosome core particles exhibit partially resolved low field (10-15 ppm) spectra due to imino protons in Watson-Crick base pairs (one resonance per GC or AT base pair). To a first approximation, the spectrum is virtually identical with that of protein-free 140 base pair DNA, and from this observation we draw two important conclusions: (i) Since the low field spectra of DNA are known to be sensitive to conformation, the conformation of DNA in the core particles is essentially the same as that of free DNA (presumably B-form), (ii) since kinks occurring at a frequency at 1 in 10 or 1 in 20 base pairs would result in a core particle spectrum different from that of free DNA we find no NMR evidence supporting either the Crick-Klug or the Sobell models for kinking DNA around the core histones. Linewidth considerations indicate that the rotational correlation time for the core particles is approximately 1.5 X 10(-7) sec, whereas the end-over-end tumbling time of the free 140 base pair DNA is 3 X 10(-7) sec.     

A solution structure for poly(rA).poly(dT) with different furanose pucker and backbone geometry in rA and dT strands and intrastrand hydrogen bonding of adenine 8CH

Equilibrium Raman spectra show that A- and B-form phosphodiester backbone geometries are both present in the solution structure of the RNA.DNA hybrid poly(rA).poly(dT) and that these arise from C3'-endo-rA and C2'-endo-dT nucleosides, respectively. Raman dynamic measurement of deuterium exchange of adenine 8CH groups reveals (i) a single kinetic class of rA conformers and (ii) extraordinary retardation of 8CH exchange in this class--more than 100-fold slower than in canonical DNA structures. The equilibrium and kinetic results, in conjunction with model building, indicate an unusual intrastrand hydrogen bond involving adenosine donor (8C-H) and acceptor (5'O) groups and a double-helical conformation in solution similar to that proposed for fibers at high relative humidity [Zimmerman, S. B., & Pheiffer, B. H. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 78-82]. In fibers of poly(rA).poly(dT) at low relative humidity, the Raman spectra indicate a conventional A-helix structure.     

Differential promotion and suppression of Z leads to B transitions in poly[d(G-C)] by histone subclasses,polyamino acids and polyamines.

The right-handed (B) conformation of poly[d(G-C)] in 7.5 mM sodium cacodylate and 25% ethylene glycol can be readily converted to the left-handed (Z) conformation by the addition of 250 microM MnCl2 and this transition can be reversed by chelation of the Mn ions with EDTA or by addition of NaCl. This ability to obtain such reversible transitions in solvent and solute conditions which allow DNA-protein interactions and their assessment by c.d. permitted an analysis of the effect of purified histones, polyamino acids, protamine and polyamines on these transitions. Individual core histones H3, H4, H2a and H2b or protamine stabilised the Mn-induced Z form and prevented the transition to B DNA normally observed after chelation with EDTA or on dialysis to physiological salt concentrations. A similar suppression of Z leads to B transition was also achieved with poly-L-arginine (but not with poly-L-lysine). In contrast, histones H1 and H5 promoted the Z leads to B transition. Polyamines (spermine and spermidine) converted the B form to another right-handed (A) form which transformed to the Z form after the addition of EDTA and this Z form was restored to the B conformation on the addition of NaCl. These results suggest that sequence-dependent variations in the conformation of natural DNA may be modulated by interaction with histones and other basic cellular components and may provide a conformational basis for nucleosome formation and possibly for the control of gene expression.