NMR studies of the interaction of bleomycin with (dC-dG)3.

The interaction of bleomycin A2 and Zn(II)-bleomycin A2 with the oligonucleotide (dC-dG)3 has been monitored by nuclear magnetic resonance spectroscopy. Binding of the drug to the oligonucleotide is indicated by an upfield shift of the bithiazole proton resonances consistent with partial intercalation of this group between base pairs. The effect of temperature and ionic strength on the binding of both free bleomycin and the Zn(II) complex has been studied. Consistent with earlier studies on polynucleotides, the rate of exchange between the free drug and the drug-oligonucleotide complex is rapid on the 1H NMR chemical shift time scale. Binding of the oligonucleotide induced changes in resonances assigned to protons in the metal-binding region of Zn(II)-bleomycin. Intermolecular nuclear Overhauser effect enhancements between bleomycin and the oligonucleotide have not been detected.     

Conformation and dynamics of short DNA duplexes: (dC-dG)3 and (dC-dG)4

Natural abundance 13C NMR spectra of duplexed (dC-dG)3 and (dC-dG)4 exhibit resolved resonances for most of the carbons at 0.1M NaCl in aqueous solution. Large transitions in chemical shift for many of the hexamer carbons (up to 1.8 ppm) are observed in variable temperature measurements. Determination of spin-lattice relaxation times and nuclear Overhauser enhancements in 0.1M NaCl indicate that the duplexes tumble almost isotropically, with overall correlation times near 5 nsec; the sugar carbons experience more rapid local motions than do the base carbons. The relaxation data are also consistent with the most rapid local motions occurring at the chain-terminal residues, especially in the Cyd(1) sugar. 4M NaCl causes changes in the 13C chemical shifts of most of the guanine base carbons, and rearrangements in the deoxyribose carbon shifts; this is consistent with changes predicted by a salt-induced B to Z transition, viz. conversion of the guanylates from the anti to syn range about the glycosyl bond, and from the S to N pseudorotational state of the deoxyribose ring.     

Conformation and Dynamics of Short DNA Duplexes: (dC-dG)3 and (dC-dG)4

Abstract

Natural abundance ¹³C NMR spectra of duplexed (dC-dG)₃ and (dC-dG)₄ exhibit resolved resonances for most of the carbons at 0.1M NaCl in aqueous solution. Large transitions in chemical shift for many of the hexamer carbons (up to 1.8 ppm) are observed in variable temperature measurements. Determination of spin-lattice relaxation times and nuclear Overhauser enhancements in 0.1M NaCl indicate that the duplexes tumble almost isotropically, with overall correlation times near 5 nsec; the sugar carbons experience more rapid local motions than do the base carbons. The relaxation data are also consistent with the most rapid local motions occurring at the chain-terminal residues, especially in the Cyd(l) sugar. 4M NaCl causes changes in the ¹³C chemical shifts of most of the guanine base carbons, and rearrangements in the deoxyribose carbon shifts; this is consistent with changes predicted by a salt-induced B to Z transition, viz. conversion of the guanylates from the and to syn range about the glycosyl bond, and from the S to N pseudorotational state of the deoxyribose ring.     

Interaction of DNA methyltransferase with aminofluorene and N-acetylaminofluorene modified poly(dC-dG)

Poly(dC-dG) was reacted in vitro to yield templates containing similar amounts of aminofluorene (AF) or acetylaminofluorene (AAF) adducts. These modified poly(dC-dG) templates were tested in an in vitro DNA methylation system utilizing 1500-fold purified rat liver methyltransferase (DMase) to compare and quantitate the effects of these adducts on the kinetics of methylation and the interaction of DMase with such templates. Enzymatic methylation is severely impaired by arylamine adducts, with bound AF inhibiting more than AAF (relative Vmax 0.24 for AAF-poly(dC-dG) and 0.066 for AF-poly(dC-dG). The apparent km for the reaction is not appreciably altered by AAF modification: 10 microM for dCdG dinucleotide units, but it is threefold lower (3 microM) for AF-poly(dC-dG). In competition experiments it was demonstrated that a translocational block is imposed by the adducts. From differential salt inhibition assays and preincubation assays, no change in the ionic binding to the altered templates could be detected, which suggests that the enzyme interacts very strongly through hydrophobic interactions with the fluorene ring. Evidence that the fluorene ring is exposed is supported by circular dichroism spectra of the templates under the conditions of the assay, which indicated that the AF adducts do not appreciably change the normal B conformation of the template, while the template with 9.5% modification by AAF adducts adopted a Z form. These results suggest that the inhibitory effects of AAF and, in particular, AF upon DMase-catalyzed methylation reactions are not dependent upon helix conformation. Instead, they appear to depend upon DMase recognition of an altered dG base configuration, which is responsible for altered binding and methylation kinetics.     

31P-NMR analysis of the B to Z transition in double-stranded (dC-dG)3 and (dC-dG)4 in high salt solution

In 4M NaCl solutions (dC-dG)n (n = 3,4; approximately 9 mM) exist as a mixture o +/- B and Z forms. The low and high field components of two 31P NMR resonances originating from internal phosphodiester groups are assigned to the GpC and CpG linkages, respectively. Low temperatures stabilize the Z-forms, which completely disappear above 50 degrees C (n = 3) and 65 degrees C (n = 4). delta H = -44 and -17 kJ/mol for B to Z transition in the hexamer and octamer duplexes, respectively. Temperature dependent changes (0-50 degrees C range) in the spin-lattice relaxation times at 145.7 MHz are distinctly different for the 31P nuclei o +/- GpC and CpG groups. The relaxation data can be explained by assuming that the GpC phosphodiester groups undergo more local internal motion than do the CpG groups.     

A one- and two-dimensional NMR study of the B to Z transition of (m5dC-dG)3 in methanolic solution

The deoxyribose hexanucleoside pentaphosphate (m5dC-dG)3 has been studied by 500 MHz 1H NMR in D2O (0.1 M NaCl) and in D2O/deuterated methanol mixtures. Two conformations, in slow equilibrium on the NMR time scale, were detected in methanolic solution. Two-dimensional nuclear Overhauser effect (NOE) experiments were used to assign the base and many of the sugar resonances as well as to determine structural features for both conformations. The results were consistent with the an equilibrium in solution between B-DNA and Z-DNA. The majority of the molecules have a B-DNA structure in low-salt D2O and a Z-DNA structure at high methanol concentrations. A cross-strand NOE between methyl groups on adjacent cytosines is observed for Z-DNA but not B-DNA. The B-DNA conformation predominates at low methanol concentrations and is stabilized by increasing temperature, while the Z-DNA conformation predominates at high methanol concentrations and low temperatures. 31P NMR spectra gave results consistent with those obtained by 1H NMR. Comparison of the 31P spectra with those obtained on poly(dG-m5dC) allow assignment of the lower field resonances to GpC in the Z conformation.     

B-Z conformational transition and hydration of poly (dC-dG).poly (dC-dG) in fibres.

The B-Z transition of poly(dC-dG).poly(dC-dG) has been studied by fibre X-ray diffraction and measurement of fibre dimensions. The polymorphism of the Z form is well observed as a function of variations of the r.h. (relative humidity). The Z to B transition is obtained at very high r.h. values. The cooperative transition from B to Z is associated with a disorganization of the fibre. Details about the hydration of the polynucleotide during conformational transitions are presented and it is shown that a nucleotide in Z form can be associated with up to 16 water molecules and up to 22 when in the B form.     

NMR Studies of Tris-Intercalation: Solution Structure and Interaction of d(CTTCGCGCGAAG) with an Acridine Trimer

Abstract

Tris-intercalation of an acridine trimer into the self-complementary dodecanucleotide d(CTTCGCGCGAAG) has been studied, in solution, by means of ¹H and ³¹P nuclear magnetic resonance. In a first step all the non-exchangeable protons (except H₅', H_5”), the imino protons and seven of the eleven phosphorus have been assigned. The dodecanucleotide is shown to adopt a double helical B-type structure. Most of the sugar puckers are in the O_1′ endo range, those of the internal guanosines being closer to C_2′endo. Deviations from the canonical B structure are observed in the base stacking and the phosphodiester torsional angles at the ³T⁴C⁵G stretch. The addition of an acridine trimer to the base-paired dodecanucleotide leads to the conclusion that the trimer, which is in slow exchange at the NMR time scale, tris-intercalates into the three C(3′-5′)G sites of the central core, according to the excluded site model. This is evidenced by the large (1.4 ppm) upfield shift experienced by the imino protons of the three internal guanines and the shielding undergone by the acridine ring protons. Tris-intercalation is also supported by the downfield shift experienced by 6 out of the 22 phosphorus. Two of them are shifted by nearly 2 ppm, a shift range reported for oligonucleotides complexed to actinomycin D; this suggests that the structure of the backbone of the dodecanucleotide is altered.     

Spectroscopic studies of (m5dC-dG)3: thermal stability of B- and Z-forms.

The hexanucleoside pentaphosphate d(m5CpGpm5CpGpm5CpG) has been studied in solution by ultra-violet absorption, circular dichroism and 31P nuclear magnetic resonance under various experimental conditions. In 0.2 M NaClO4 at low temperature, an hexamer duplex is formed which has a B or B-like conformation. As the salt concentration is increased, a transition from a B-form to the Z-form occurs and is complete in 3 M NaClO4. In 3 M NaClO4, the behavior of the Z double helix is complex as a function of temperature. The variation of the circular dichroism at 295 nm is biphasic. A first transition occurs over a large range of temperature and corresponds to a conformational change due to a non-cooperative intramolecular process. Ultra-violet absorption and 31P nuclear magnetic resonance show that the new conformation arising from a distortion of the backbone is not similar to that observed in low salt conditions (B-form). At high hexanucleotide concentration, aggregates are formed. The second transition is cooperative and corresponds to the melting of a double stranded helix into single strands.     

Two-Dimensional NMR Study of Bleomycin and Its Zinc(II) Complex: Reassignment of 13C Resonances

Abstract

Two-dimensional NMR experiments-one bond ¹H- ¹³C correlation spectroscopy and hetero- nuclear multiple bond correlation spectroscopy, both performed in the reverse detection mode-have been employed to unambiguously assign all of the ¹³C resonances of the antibiotic bleomycin and its zinc(II) complex. Previous ¹H resonance assignments of bleomycin (Chen et al. (1977) Biochemistry 16, 2731–2738) were confirmed on the basis of homonuclear Hartmann-Hahn and homonuclear COSY experiments. The ¹³C assignments differ substantially from those previously obtained by other investigators (Naganawa et al., (1977) J. Antibiot. 30, 388–396; Dabrowiak et al., (1978) Biochemistry 17, 4090–4096) but are in agreement with those reported by Akkerman et al.(1988) (Magn. Reson. Chem. 26, 793–802). The more recent study employed similar two-dimensional correlation experiments (performed in the direct detection mode) in conjunction with attached proton tests. Their study often required model compound data to identify carbonyls adjacent to aliphatic moieties. Previous ¹³C NMR studies of the structure, pH titration, and molecular dynamics of bleomycin and its zinc complex have been reinterpreted in terms of the revised assignments.     

Interaction of the Water-Soluble Protein Aprotinin with Liposomes: Gel-Filtration,Turbidity Studies,and 31P NMR Studies

Abstract

The interactions of a water-soluble nonmembrane protein aprotinin with multilamellar vesicles (MLV) and small unilamellar vesicles (SUV) from soybean phospholipids were studied using Sephadex G-75 gel chromatography combined with different methods of the analysis of the eluate fractions (fluorescence, light-scattering, turbidity; ³¹P NMR spectroscopy). The composition of the liposomes mainly containing soybean phosphatidylcholine (PC) was varied by the addition of phosphatidylethanolamine (PE), phosphatidylinositol (PI) and lyso-phosphatidylcholine (lyso-PC). To evaluate the lipid-protein interactions, the amount of aprotinin in the MLV–aprotinin complexes was determined. Lipid–protein interactions were found to strongly depend on the liposome composition, medium pH and ionic strength. These dependencies point to the electrostatic nature of the aprotinin-lipid interactions. ³¹P NMR spectroscopy of the MLV–aprotinin complexes indicated that aprotinin influences the phospholipid structure in MLV at pH 3.0. In the case of PC:PE:PI and PC:PE:PI:lyso-PC vesicles, aprotinin induced liposome aggregation and a lamellar-to-isotropic phase transition of the phospholipids.     

Thermal stability of the Z-conformation of the tetranucleoside triphosphate (m5dC-dG)2

The tetranucleoside triphosphate d(m5C-G)2 has been studied in solution by circular dichroism and 31P nuclear magnetic resonance as a function of temperature, in presence of 3 M NaClO4. It is shown that in such high ionic strength d(m5C-G)2 may adopt a Z-like conformation for temperatures lower than 5 degrees C. At these temperatures, another conformation, in slow equilibrium with the Z-like one, is also detected. Increasing the temperature leads to a transition from the Z-like conformation to intermediate forms before melting. It is demonstrated that these intermediates are not the B form.     

Interaction of berenil with the EcoRI dodecamer d(CGCGAATTCGCG)2 in solution studied by NMR

The conformation of the EcoRI dodecamer d(CGCGAATTCGCG)2 has been examined in solution by 1H and 31P NMR. Spin-spin coupling constants and nuclear Overhauser (NOE) enhancement spectroscopy show that all deoxyriboses lie in the south domain, with a small admixture of the north conformation (0-20%). The time dependence of the nuclear Overhauser enhancements also reveals a relatively uniform conformation at the glycosidic bonds (average angle, chi = -114 degrees). The average helical twist is 36.5 degrees (9.8 base pairs per turn). Tilt angles are small (in the range 0 to -10 degrees), and roll angles are poorly determined. Unlike single-crystal X-ray studies of the same sequence, there is no evidence for asymmetry in the structure. Both the NOE intensities and 31P relaxation data imply conformational anomalies at the C3-G4/C9-G10 and the A5-A6/T7-T8 steps. Berenil binds in 1:1 stoichiometry to the dodecamer with high affinity (Kd = 1 microM at 298 K) and causes substantial changes in chemical shifts of the sugar protons of nucleotides Ado 5-Cyt 9 and of the H2 resonances of the two Ado residues. No significant asymmetry appears to be induced in the DNA conformation on binding, and there is no evidence for intercalation, although the binding site is not centrosymmetric. NOEs are observed between the aromatic protons of berenil and the H1' of both Thy 7 and Thy 8, as well as to Ado 5 and Ado 6 H2. These results firmly establish that berenil binds via the minor groove and closely approaches the nucleotides Ado 6, Thy 7, and Thy 8. On the basis of quantitative NOE spectroscopy and measurements of spin-spin coupling constants, changes in the conformations of the nucleotides are found to be small. Using the observed NOEs between the ligand and the DNA together with the derived glycosidic torsion angles, we have built models that satisfy all of the available solution data. The berenil molecule binds at the 5'-AAT (identical to 5'-ATT on the complementary strand) site such that (i) favorable hydrogen bonds are formed between the charged amidinium groups and the N3 atoms of Ado 6 and Ado 18 and (ii) the ligand is closely isohelical with the floor of the minor groove.     

博安霉素与DNA相互作用的分子机理研究

通过光谱分析、粘度测定及~１ＨＮＭＲ研究证实：博安霉素（ＢｌｅｏｍｙｃｉｎＡ_６,ＢＬＭＡ_６）是通过双噻唑基嵌插入碱基对之间与ＤＮＡ结合的。同时测定了ＢＬＭＡ_６与ＤＮＡ的结合常数、结合位点数并与博莱霉素Ａ_２（ＢＬＭＡ_２）、Ａ_５（ＢＬＭＡ_５）进行了比较,证实了末端胺基对ＢＬＭＡ_６与ＤＮＡ结合的贡献,琼脂糖凝胶电泳对ＢＬＭＡ_６及其Ｃｕ（Ⅱ）、Ｆｅ（Ⅱ）络合物断裂ＤＮＡ的研究表明,在ＤＮＡ断裂中某种氧自由基的存在及金属螯合部位与ＤＮＡ嵌插部位之间的相互影响,对于ＢＬＭＡ_６及同系物对小鼠肺毒性的差异与不同尾链结构的关系进行了探讨。     

A study of the thermal stability of the Z form of (m5dC-dG)3 by resonance Raman spectroscopy.

The thermal stability of the hexanucleoside pentaphosphate m5dCpdGpm5dCpdGpm5 dCpdG has been studied by resonance Raman spectroscopy with 257 nm excitation wavelength. At low temperature and in 3M NaClO4, the Raman spectrum resembles that of poly(dG-dC).poly(dG-dC) in the Z conformation. As the temperature is increased, the position and the intensity of several bands (1312 cm-1, 1482 cm-1, 1584 cm-1 and 1632 cm-1) are modified. The variation of intensity versus temperature is biphasic. Analysis of the results suggests that the increase of temperature induces first a transition from the Z form to an intermediate stable form which then melts. These results and those previously obtained by circular dichroism and 31P nuclear magnetic resonance suggest that the intermediate form belongs to the left family but with changes in the stacking of the bases and the geometry of the phosphate groups as compared to the canonical Z form.     

Interaction of local anesthetics with lipid bilayers investigated by (1)H MAS NMR spectroscopy

The membrane location of the local anesthetics (LA) lidocaine, dibucaine, tetracaine, and procaine hydrochloride as well as their influence on phospholipid bilayers were studied by (31)P and (1)H magic-angle spinning (MAS) NMR spectroscopy. The (31)P NMR spectra of the LA/lipid preparations confirmed that the overall bilayer structure of the membrane remained preserved. The relation between the molecular structure of the LAs and their membrane localization and orientation was investigated quantitatively using induced chemical shifts, nuclear Overhauser enhancement spectroscopy, and paramagnetic relaxation rates. All three methods revealed an average location of the aromatic rings of all LAs in the lipid-water interface of the membrane, with small differences between the individual LAs depending on their molecular properties. While lidocaine is placed in the upper chain/glycerol region of the membrane, for dibucaine and procaine the maximum of the distribution are slightly shifted into the glycerol region. Finally for tetracaine the aromatic ring is placed closest to the aqueous phase in the glycerol/headgroup region of the membrane. The hydrophobic side chains of the LA molecules dibucaine and tetracaine were located deeper in the membrane and showed an orientation towards the hydrocarbon core. In contrast the side chains of lidocaine and procaine are oriented towards the aqueous phase.     

Molecular structure of (m5 dC-dG)3: the role of the methyl group on 5-methyl cytosine in stabilizing Z-DNA.

The hexamer (m5 dC-dG)3 has been synthesized and its three-dimensional structure determined by a single crystal X-ray diffraction analysis. The structure has been refined to a final R value of 15.6% at 1.3 A resolution. The molecule forms a left-handed Z-DNA helix which is similar to the unmethylated Z-DNA structure. The presence of the methyl group has resulted in slight changes in the twist angle between successive base pairs and modification of some of the interatomic contacts. Methylation of cytosine in the C5 position is associated with a relative destabilization of the B-DNA structure and a stabilization through hydrophobic bonding of the Z-DNA structure.     

Interaction of the fluorescent probe diS-C3-(5) with lecithin-cholesterol membranes

Behaviour of fluorescent carbocyanine probe disS-C3(5) in the egg lecithin-cholesterol membrane suspension was studied in relation to the lecithin/cholesterol ratio. The partition coefficient of the probe between aqueous and lipid phases decreases unlinearly with increase of cholesterol molar part in a bilayer. This parameter over molar part units was estimated to be (2.4 +/- 0.1) X 10(6) for egg lecithin membranes and (1.8 +/- 0.2) X 10(6) for 10 mol% cholesterol, (1.2 +/- 0.1) X 10(6) for 20, (0.8 +/- 0.1) X 10(6) for 30, and (0.48 +/- 0.02) X 10(6) for 50 mol% cholesterol. It is suggested that the probe partition coefficient value consists of two components: one caused by pure lecithin bilayer regions and another by local lecithin concentration fluctuations in the mixed lecithin-cholesterol regions.