Raman spectroscopic study of the effects of Ca2+, Mg2+, Zn2+, and Cd2+ ions on calf thymus DNA: binding sites and conformational changes

The interaction of Mg2+, Ca2+, Zn2+, and Cd2+ with calf thymus DNA has been investigated by Raman spectroscopy. These spectra reveal that all of these ions, and particularly Zn2+, bind to phosphate groups of DNA, causing a slight structural change in the polynucleotide at very small metal: DNA (P) concentration ratio (ca. 1:30). This results in increased base-stacking interactions, with negligible change of the B conformation of DNA. Contrary to Zn2+ and Cd2+, which interact extensively with the nucleic bases (particularly at the N7 position of guanine), the alkaline-earth metal ions are bound almost exclusively to the phosphate groups. The affinity of both the Zn2+ and Cd2+ ions for G.C base pairs is comparable, but the Cd2+ ions interact more extensively with A.T pairs than Zn2+ ions. Interstrand cross-linking through the N3 atom of cytosine is suggested in the presence of Zn2+, but not Cd2+.     

Raman spectroscopy of DNA-metal complexes. II. The thermal denaturation of DNA in the presence of Sr2+, Ba2+, Mg2+, Ca2+, Mn2+, Co2+, Ni2+, and Cd2+.

Differential scanning calorimetry, laser Raman spectroscopy, optical densitometry, and pH potentiometry have been used to investigate DNA melting profiles in the presence of the chloride salts of Ba2+, Sr2+, Mg2+, Ca2+, Mn2+, Co2+, Ni2+, and Cd2+. Metal-DNA interactions have been observed for the molar ratio [M2+]/[PO2-] = 0.6 in aqueous solutions containing 5% by weight of 160 bp mononucleosomal calf thymus DNA. All of the alkaline earth metals, plus Mn2+, elevate the melting temperature of DNA (Tm > 75.5 degrees C), whereas the transition metals Co2+, Ni2+, and Cd2+ lower Tm. Calorimetric (delta Hcal) and van't Hoff (delta HVH) enthalpies of melting range from 6.2-8.7 kcal/mol bp and 75.6-188.6 kcal/mol cooperative unit, respectively, and entropies from 17.5 to 24.7 cal/K mol bp. The average number of base pairs in a cooperative melting unit (<nmelt>) varied from 11.3 to 28.1. No dichotomy was observed between alkaline earth and transition DNA-metal complexes for any of the thermodynamic parameters other than their effects on Tm. These results complement Raman difference spectra, which reveal decreases in backbone order, base unstacking, distortion of glycosyl torsion angles, and rupture of hydrogen bonds, which occur after thermal denaturation. Raman difference spectroscopy shows that transition metals interact with the N7 atom of guanine in duplex DNA. A broader range of interaction sites with single-stranded DNA includes ionic phosphates, the N1 and N7 atoms of purines, and the N3 atom of pyrimidines. For alkaline earth metals, very little interaction was observed with duplex DNA, whereas spectra of single-stranded complexes are very similar to those of melted DNA without metal. However, difference spectra reveal some metal-specific perturbations at 1092 cm-1 (nPO2-), 1258 cm-1 (dC, dA), and 1668 cm-1 (nC==O, dNH2 dT, dG, dC). Increased spectral intensity could also be observed near 1335 cm-1 (dA, dG) for CaDNA. Optical densitometry, employed to detect DNA aggregation, reveals increased turbidity during the melting transition for all divalent DNA-metal complexes, except SrDNA and BaDNA. Turbidity was not observed for DNA in the absence of metal. A correlation was made between DNA melting, aggregation, and the ratio of Raman intensities I1335/I1374. At room temperature, DNA-metal interactions result in a pH drop of 1.2-2.2 units for alkaline earths and more than 2.5 units for transition metals. Sr2+, Ba2+, and Mg2+ cause protonated sites on the DNA to become thermally labile. These results lead to a model that describes DNA aggregation and denaturation during heating in the presence of divalent metal cations; 1) The cations initially interact with the DNA at phosphate and/or base sites, resulting in proton displacement. 2) A combination of metal-base interactions and heating disrupts the base pairing within the DNA duplex. This allows divalent metals and protons to bind to additional sites on the DNA bases during the aggregation/melting process. 3) Strands whose bases have swung open upon disruption are linked to neighboring strands by metal ion bridges. 4) Near the midpoint of the melting transition, thermal energy breaks up the aggregate. We have no evidence to indicate whether metal ion cross-bridges or direct base-base interactions rupture first. 5) Finally, all cross-links break, resulting in single-stranded DNA complexed with metal ions.     

Neutron-induced free radicals in oriented DNA

Samples of oriented DNA containing 30 per cent water were irradiated with neutrons at 77 K. The electron spin resonance (e.s.r.) spectra obtained from these irradiated DNA samples show that the formation of radicals is different when the incident neutrons are parallel or perpendicular to the DNA helix. When the incident neutrons are perpendicular to the DNA helix the e.s.r. spectra of thymine and guanine ionic radicals (T-., G+.) are observed. An additional e.s.r. spectrum corresponding to the hydrogen addition radical on thymine (TH.) is observed when the incident neutrons are parallel to DNA helix. The TH. radical appears to be formed by protonation of T-. .     

Interaction between delta and epsilon subunits of F1-ATPase from pig heart mitochondria. Circular dichroism and intrinsic fluorescence of purified and reconstituted delta epsilon complex

A delta epsilon complex has been purified as a molecular entity from pig heart mitochondrial F1-ATPase. This delta epsilon complex has also been reconstituted from purified delta and epsilon subunits. Both isolated and reconstituted delta epsilon complexes have delta 1 epsilon 1 stoichiometry and are indistinguishable by their chromatographic behavior, their circular dichroism spectra (CD spectra), and their intrinsic fluorescence features. The content of secondary structures deduced from CD spectra of the delta epsilon complex appears to be the sum of the respective contributions of purified delta and epsilon subunits. All intrinsic fluorescence studies carried out on isolated epsilon subunit and delta epsilon complex show that the single tryptophan residue located on epsilon is involved in the interaction between delta and epsilon subunits. Results obtained with F1-ATPase are in favor of the same delta epsilon interaction in the entire enzyme.     

Alkylation of nucleic acid components with ethylenimine and its derivatives. IV. Alkylation of homopolynucleotides and DNA]

Alkylation of homopolynucleotides and DNA by thio TEPA and monoaziridine diethyl phosphate was studied. The modification affected nucleic bases and terminal phosphate groups but not internucleotide phosphate groups. It was shown that the main center of modification in poly(A) was the N1 atom, whereas the products of N6- and N3-alkylations were formed in smaller amounts. In poly(G), the alkylation proceeded predominantly at the N7 and, insignificantly, at the N1 atom of guanine; the pyrimidine N3 atom is alkylated poorly in poly(C) and even worse in poly(U). In the case of DNA, the major alkylated sites are the guanine N7 and the adenine N3; this results in DNA denaturation and the subsequent formation of products modified at N1 and N6 of adenine, N1 of guanine, and N3 of cytosine. An increase in the pH and ionic strength of the solution as well as the DNA denaturation decrease the reaction rate, whereas ultrasonic fragmentation enhances it. Upon alkylation, melting temperatures decrease, CD and UV spectra change, and DNA luminescence appears. To separate the reaction mixtures and identify the DNA alkylation products, chemical hydrolysis, ion-exchange and reverse-phase HPLC, and UV spectroscopy were used.     

Characterization of heme-coordinating histidyl residues of cytochrome b5 based on the reactivity with diethylpyrocarbonate: a mechanism for the opening of axial imidazole rings

We investigated the reactivity of heme-coordinating imidazole with diethylpyrocarbonate using a soluble domain of cytochrome b(5). Analyses with various spectroscopic methods including MALDI-TOF-MS indicated that two axial His residues (His44 and His68) of cytochrome b(5) were protected from the modification by several factors, i.e., limited steric exposure of the axial imidazole to the solvent, the Fe-N(epsilon2) coordination bond, and protonation of the N(delta1) position by forming a hydrogen bond with its immediate surroundings. However, once N-carbethoxylation at the N(epsilon2) position of the axial His residues occurred with a higher concentration of diethylpyrocarbonate, displacement of heme prosthetic group from the protein moiety continued. Simultaneously, it facilitated the second N-carbethoxylation to take place at the N(epsilon1) position of the same imidazole ring, leading to a bis-N-carbethoxylated derivative and further to a ring-opened derivative. A similar mechanism seemed in operation for one non-axial His residue (His85), in which the N(delta1) atom works as a hydrogen acceptor in a strong hydrogen-bond and the other N(epsilon2) atom is in a protonated form, resulting in a formation of the ring-opened derivative upon treatment with a higher concentration of diethylpyrocarbonate. These results suggested that the use of diethylpyrocarbonate for MALDI-TOF-MS analysis might provide a unique method to characterize the protonation state of His residues and the strength of their hydrogen-bondings at the active site of enzymes.     

Influence of Ca2+ cations on low pH-induced DNA structural transitions

A confocal Raman microspectrometer was used to investigate the influence of Ca2+ cations on low pH-induced DNA structural changes. The effects of Ca2+ cations on the protonation mechanism of opening AT and changing the protonation of GC base pairs in DNA are discussed. Based on the observation that the midpoint of the transition of Watson-Crick GC base pairs to protonated GC base pairs lies at around pH 3 (analyzing the 681 cm(-1) line), measurements were carried out on calf thymus DNA at neutral pH and pH 3 in the presence of low and high concentrations of Ca2+ cations. Raman spectra show that low concentrations of Ca2+ cations partially protect DNA against protonation of cytosine (characteristic line at 1262 cm(-1)) and do not protect adenine (characteristic line at 1304 cm(-1)) and the N(7) of guanine (line at 1488 cm(-1)) against binding of H+. High Ca2+ concentrations can prevent protonation of cytosine and protonation of adenine (little disruption of AT pairs). Analyzing the line at 1488 cm(-1), which obtains most of its intensity from a guanine vibration, high salt was also found to protect the N(7) of guanine against protonation.     

NMR studies of metal ion binding to the Zn-finger-like HNH motif of colicin E9

The 134 amino acid DNase domain of colicin E9 contains a zinc-finger-like HNH motif that binds divalent transition metal ions. We have used 1D 1H and 2D 1H-15N NMR methods to characterise the binding of Co2+, Ni2+ and Zn2+ to this protein. Data for the Co2+-substituted and Ni2+-substituted proteins show that the metal ion is coordinated by three histidine residues; and the NMR characteristics of the Ni2+-substituted protein show that two of the histidines are coordinated through their N(epsilon2) atoms and one via its N(delta1). Furthermore, the NMR spectrum of the Ni2+-substituted protein is perturbed by the presence of phosphate, consistent with an X-ray structure showing that phosphate is coordinated to bound Ni2+, and by a change in pH, consistent with an ionisable group at the metal centre with a pKa of 7.9. Binding of an inhibitor protein to the DNase does not perturb the resonances of the metal site, suggesting there is no substantial conformation change of the DNase HNH motif on inhibitor binding. 1H-15N NMR data for the Zn2+-substituted DNase show that this protein, like the metal-free DNase, exists as two conformers with different 1H-15N correlation NMR spectra, and that the binding of Zn2+ does not significantly perturb the spectra, and hence structures, of these conformers beyond the HNH motif region.     

Influence of reductants upon optical characteristics of the DNA-Cu2+ complex

The addition of reducing agents, i.e., ascorbic acid or sodium borohydride, to a DNA solution containing Cu²⁺ ions causes changes in the DNA absorption spectra which are due to a new absorption band with a maximum at 280 mμ assigned to a DNA base–Cu¹⁺ complex. The stoichiometry of the complex is one Cu¹⁺ ion per four bases of DNA. The DNA–Cu¹⁺ complex has an increased melting temperature and rather different circular dichroism curve as compared with DNA itself. It is inferred that the above effects are caused by proton transfer along the hydrogen bond from guanine to cytosine under complexing of Cu¹⁺ ions with the N₇ atom of the guanine of DNA.     

CD spectra of isoionic DNA solutions

The ion-exchange transition of Na-DNA----H-DNA in concentrated salt-free solutions is accompanied by strong variations in CD spectra. The rotational force of the negative band magnitude of delta epsilon 249 decreases when going to H-DNA by about 4 times, and the value of delta epsilon 279, by 1.2 times. These changes are irreversible to a considerable extent, which is evident because the spectra of Na-DNA obtained by neutralizing isoionic H-DNA solutions with NaOH or by the ion-exchange method significantly differ from those of Na-DNA taken by dissolving solid Na-DNA in deionized water. It has been shown that additions of NaCl to an isoionic solution of DNA leads to variations of spectra, typical for deprotonation processes as well as for an increase in DNA hydration.     

Circular dichroism of flow-oriented nucleic acids. II. Comparison between observed and calculated spectra.

The ultraviolet circular dichroism (CD) of oriented DNA and RNA molecules is calculated by an extension of Johnson and Tinoco's theory [(1969) Biopolymers 7 , 727–749] for unoriented molecules. The calculations are carried out for molecular models of A-DNA, B-DNA, planar B-DNA, C-DNA, and RNA-11-α. The calculated curves are compared to measured spectra [(1975) J. Mol. Biol. 92 , 449–466] Chung and Holzwarth, for oriented solutions of DNA in buffer, DNA in 6 M LiCl or in ethylene glycol, and double-stranded viral RNA. The calculation, which considers only base–base interactions, predicts that the CD of B-DNA, measured with light propagating parallel to the helix axis, should be large and semiconservative, whereas the CD for light propagating perpendicular to the helix axis should be nonconservative. These predictions agree qualitatively with the experimental observations for DNA in buffer; agreement improves if one assumes the bases to be exactly perpendicular to the helix axis. For the other geometries, agreement is less satisfactory, but qualitative agreement with experiment is obtained and the signs of the specific CD spectra are in accord with observations.     

The role of molecular conformation in ion capture by carboxylic ionophores: a circular dichroism study of narasin A in single-phase solvents and liposomes

Conformational and thermodynamic aspects of cation binding by the carboxylic ionophore narasin A were studied by circular dichroism (CD). In single-phase solvents, dramatic increases in the maximum differential absorption (delta epsilon) of the C-11 carbonyl were observed upon the binding of K+, Na+ and protons to the free anionic form. These changes were associated with major shifts in the conformation equilibrium between extended and pseudocyclic conformers of narasin. Similar CD changes observed upon the binding of K+ to narasin A in dimyristoylphosphatidylcholine vesicles provided evidence that in the membrane environment, comparable conformation changes were associated with ion binding. Variation of the polar and protic properties of single-phase solvents was also found to influence the delta epsilon of the cation bound species of narasin A, supporting previous evidence for polarity-mediated modulation of conformation. Comparison of cation binding affinities indicated that in both single-phase solvents and liposomes, narasin had a marked equilibrium selectivity for K+ over Na+.     

The infrared spectrum and structure of the type I complex of silver and DNA.

Infrared spectroscopy was used to study films of the type I complex of Ag+ and DNA as a function of hydration with the following conclusions. Ag+ binds to guanine residues but not to cytosine or thymine residues. Cytosine becomes protonated as Ag+ binds to guanine. (These conclusions confirm previous models.) The type I complex remains in the B family of structures with slight modifications of the sugar-phosphate geometry. This modified B structure remains stable at lower values of hydration for which pure DNA is in the A form. Binding of Ag+ to PO2-, O-P-O or the deoxyribose oxygen is excluded.     

Electron-spin-resonance studies of a chlorpromazine derivative bound to DNA fibres.

Solutions of DNA, spin-labelled with the radical cation of chlorpromazine, were used to produce oriented species of fibres pulled from a gel obtained by ultracentrifugation. The electron spin resonance spectra, recorded at X and Q band frequencies, are given for both gel and fibres; 14N hyperfine coupling parameters were obtained by computer fitting. The spectra are explained in terms of a strongly immobilized label having one principal hyperfine tensor axis parallel to the axis of the DNA helix, and the preferential orientation of the chlorpromazine ions with their planes perpendicular to the DNA helical axis.     

Interaction of DNA with divalent metal ions

The interaction between the native DNA macromolecules and Ca2+, Mn2+, Cu2+ ions in solutions of low ionic strength (10(-3) M Na+) is studied using the methods of differential UV spectroscopy and CD spectroscopy. It is shown that the transition metal ions Mn2+ exercise binding to the nitrogen bases of DNA at concentrations approximately 5 x 10(-6) M and form chelates with guanine of N7-Me(2+)-O6 type. Only at high concentrations in solution (5 x 10(-3) M) do Ca2+ ions interact with the nitrogen bases of native DNA. In the process of binding to Ca2+ and Mn2+ the DNA conformation experiences some changes under which the secondary structure of the biopolymer is within the B-form family. The DNA transition to the new conformation is revealed by its binding to Cu2+ ions.     

The distal residue-CO interaction in carbonmonoxy myoglobins: a molecular dynamics study of two distal histidine tautomers.

Four independent 90 ps molecular dynamics simulations of sperm-whale wild-type carbonmonoxy myoglobin (MbCO) have been calculated using a new AMBER force field for the haem prosthetic group. Two trajectories have the distal 64N delta nitrogen protonated, and two have the 64N epsilon nitrogen protonated; all water molecules within 16 A of the carbonyl O are included. In three trajectories, the distal residue remains part of the haem pocket, with the protonated distal nitrogen pointing into the active site. This is in contrast with the neutron diffraction crystal structure, but is consistent with the solution phase CO stretching frequencies (upsilon CO) of MbCO and various of its mutants. There are significant differences in the "closed" pocket structures found for each tautomer: the 64N epsilon H trajectories both show stable distal-CO interactions, whereas the 64N delta H tautomer) has a weaker interaction resulting in a more mobile distal side chain. One trajectory (a 64N delta H tautomer) has the distal histidine moving out into the "solvent", leaving the pocket in an "open" structure, with a large unhindered entrance to the active site. These trajectories suggest that the three upsilon CO frequencies observed for wild-type MbCO in solution, rather than representing significantly different Fe-C-O geometries as such, arise from three different haem pocket structures, each with different electric fields at the ligand. Each pocket structure corresponds to a different distal histidine conformer: the A3 band to the 64N epsilon H tautomer, the A1,2 band to the 64N delta H tautomer, and the A0 band to the absence of any significant interaction with the distal side chain.     

Characterization of an unusual folding pattern in a catalytically active guanine quadruplex structure

In the presence of certain metal ions, DNA and RNA can form guanine quadruplex structures, which have been proposed to play a functional role in a variety of biological processes. An 18-nucleotide DNA oligomer, PS2.M, d(GTG3TAG3CG3T2G2), was previously reported to bind hemin and the resulting complex exhibited peroxidase activity. It was proposed that PS2.M folds unimolecularly into an antiparallel quadruplex with unusual, single-base loops and terminal guanines positioned in adjacent quartets. Here we describe structural and stability properties of PS2.M alone in different buffers and metal ions, using gel electrophoresis, circular dichroism (CD), ultraviolet (UV)-visible spectroscopies, and one-dimensional 1H nuclear magnetic resonance (NMR). Native gel behavior of PS2.M in the presence of either Na+ or Pb2+ suggests the formation of unimolecular structures but, in the presence of K+, both unimolecular and multistranded structures are observed. In the presence of Pb2+ ions, PS2.M forms a unimolecular quadruplex containing three guanine quartets. CD titrations reveal that binding of Pb2+ ions to PS2.M is stoichiometric, and a single lead cation suffices to fully fold PS2.M. The PS2.M-Na+ system also forms a similar unimolecular quadruplex. In the presence of K+, the PS2.M-K+ system forms mixed species. With increasing time and PS2.M concentration, the contribution of unimolecular species decreases while that of multimolecular species increases, and this behavior is independent of buffer media. These results suggest that the catalytically active form, studied in the presence of K+, may be a parallel, multistranded quadruplex rather than an antiparallel, unimolecular quadruplex.     

Chemical reactivity of protonated aziridine with nucleophilic centers of DNA bases

A series of molecular orbital calculations, using MINDO/3 and CNDO/2L methods, have been used to characterize the chemical reaction of protonated aziridine with DNA nucleophilic base sites. The N-7 atom of guanine is found to be the preferred alkylation site only when the O-6 atom of guanine is involved in base-pair hydrogen bonding. Otherwise O-6 is the predicted major site of alkylation. This indirectly suggests that protonated aziridine alkylation processes involve base-paired DNA structures, since N-7 guanine is the observed major site of alkylation. Alkylation of N-3 adenine is predicted to be more favorable than chemical attack of the N-7 adenine position. Both of these sites, however, are predicted to be less reactive than N-7 of guanine. These chemical reactivity studies resolve alkylation specifically not achieved in the DNA–alkylator physical association calculations reported in the preceding paper.     

Phenotypic and functional analysis of murine CD3+,CD4-,CD8- TCR-gamma delta-expressing peripheral T cells

Murine CD3+,CD4-,CD8- peripheral T cells, which express various forms of the TCR-gamma delta on their cell surface, have been characterized in terms of their cell-surface phenotype, proliferative and lytic potential, and lymphokine-producing capabilities. Three-color flow cytofluorometric analysis demonstrated that freshly isolated CD3+,CD4-, CD8- TCR-gamma delta lymph node cells were predominantly Thy-1+,CD5dull,IL-2R-,HSA-,B220-, and approximately 70% Ly-6C+ and 70% Pgp-1+. After CD3+,CD4-,CD8-splenocytes were expanded for 7 days in vitro with anti-CD3-epsilon mAb (145-2C11) and IL-2, the majority of the TCR-gamma delta cells expressed B220 and IL-2R, and 10 to 20% were CD8+. In comparison to CD8+ TCR-alpha beta T cells, the population of CD8+ TCR-gamma delta-bearing T cells exhibited reduced levels of CD8, and about 70% of the CD8+ TCR-gamma delta cells did not express Lyt-3 on the cell surface. Functional studies demonstrated that splenic TCR-gamma delta cells proliferated when stimulated with mAb directed against CD3-epsilon, Thy-1, and Ly-6C, but not when incubated with an anti-TCR V beta 8 mAb, consistent with the lack of TCR-alpha beta expression. In addition, activated CD3+,CD4-,CD8- peripheral murine TCR-gamma delta cells were capable of lysing syngeneic FcR-bearing targets in the presence of anti-CD3-epsilon mAb and the NK-sensitive cell line, YAC-1, in the absence of anti-CD3-epsilon mAb. Finally, activated CD3+, CD4-,CD8-,TCR-gamma delta+ splenocytes were also capable of producing IL-2, IL-3, IFN-gamma, and TNF when stimulated in vitro with anti-CD3-epsilon mAb.