Nitrogen-15 NMR spectroscopy of N-metallated nucleic acids: insights into 15N NMR parameters and N-metal bonds

It was recently demonstrated spectroscopically that RNA/DNA nucleobases can bind to metal cations in aqueous solution through coordination bonds and covalent bonds. Nitrogen-15 ((15)N) NMR spectroscopy was employed and shown to be a powerful tool for determining the mode of metal ion binding to nitrogen atoms in RNA/DNA molecules. This review describes (15)N NMR spectroscopic characteristics in accordance with the mode of metal ion binding to nitrogen atoms. The general rules for (15)N chemical shift changes, which are applicable to the determination of the metal ion binding mode of N-metallated compounds, are also described.     

Pulse-polarographic analysis of nucleic acids and proteins

Nucleic acids and proteins were studied by means of derivative and normal pulse polarography, and d.c. and a.c. polarography in connection with the dropping mercury electrode. It was shown that natural ribonucleic acids, as transfer, ribosomal and viral RNAs yield derivative pulse-polarographic peaks; from their heights and potentials conclusions can be made about their content of ordered structure in solution, similarly as in the case of deoxyribonucleic acids studied earlier. Synthetic single-stranded polyribo-cytidylic acid yields a well developed peak, whereas in the double-helical complex with polyriboguanylie acid it is inactive when using either derivative pulse polarography or d.c. polarography. Well developed peaks were obtained also with albumin (a protein containing reducible?S?S? groups), while only an inflex was observed on the d.c. polarogram. Proteins were also studied in media containing cobalt (Brdi?ka's solution) or nickel and it was shown that derivative pulse polarography due to its high sensitivity and accuracy enables us to carry out the measurements even in less common media than Brdi?ka's solution. This fact could be exploited in clinical chemistry as well as in the investigation of the nature of catalytic currents of proteins. The currents of double-helical polynucleotides obtained by means of normal pulse polarography exhibit a marked dependence on the initial potential and cannot represent a reliable indicator of structural changes of biopolymers in solution. They can however, be used in studies of the influence of the polynucleotide adsorption at different potentials on the subsequent reduction.     

High-resolution NMR spectroscopy of membrane proteins in aligned bicelles

High-resolution solid-state NMR spectra can be obtained from uniformly (15)N-labeled membrane proteins in magnetically aligned bicelles. Fast uniaxial diffusion about the axis of the bilayer normal results in single-line spectra that contain the orientational information necessary for protein structure determination.     

Polymeric fluorescent dyes for labeling of proteins and nucleic acids

In order to increase the sensitivity of fluorescence labeling in biochemical reactions and diagnostic procedures a labeling technique with polymeric fluorescence dyes was established and tested for its applicability. The fluorescence dye is based on the fluorophor coumarine and was covalently linked to the model proteins strepavidine and IgG. The dye was synthesized by radical polymerization of three different types of functional monomers to ensure water solubility, covalent coupling to proteins, and fluorescence. The molecular weight range was between 20 and 200 kDa. Fractions of narrow molecular weight distribution were prepared by gel filtration on Superdex 200. The relationship between size and charge of the different fractions was analyzed by gel electrophoresis. Covalent conjugation to proteins was carried out by formation of a peptide bond between a carboxylic group of the functional monomers and an amino group of the protein mediated by 1-ethyl-3-(3-dimethylamino-propyl)-carbodiimide (EDC). A novel type of gel electrophoresis was developed in order to analyze and optimize the conjugation reaction; the results were in agreement with those from analytical ultracentrifugation with fluorescence detection. Hydrodynamic studies of the uncoupled dye and the protein-dye conjugates exhibited a drastic decrease of Stokes radius of the dye due to the coupling to the protein. Under optimum conditions the fluorescence intensity of a protein-polymeric dye conjugate was enhanced 40-fold compared to a monomeric dye. Biotin binding to the protein streptavidin was not affected significantly by the conjugation with the polymeric dye. At present, the applicability of the polymeric dye in biochemical and diagnostic reactions seems to be limited due to strong but unspecific hydrophobic interactions which might be overcome by using fluoresceine as monomeric dye.     

Shape, flexibility and packing of proteins and nucleic acids in complexes

Determining the change in topological properties like shape, flexibility and packing of proteins and nucleic acids on complexation is important in characterizing the role of induced structural changes and various interactions which control the functional specificity of proteins and nucleic acids. To this end, we have analyzed and compared the three dimensional structures of several protein-protein, protein-DNA and protein-RNA complexes available in the Protein Data Bank (PDB) and the Nucleic Acid Data Bank (NDB). The size of complexed proteins and nucleic acids, as measured by the radius of gyration, follows Flory's scaling law. The change in the scaling exponents for proteins, RNA and DNA reflects the changes in their respective sizes due to complexation. The anisotropy in the shape of proteins, DNA and RNA in complexes is measured by considering the asphericity and shape parameter, which are calculated from the eigenvalues of the moment of inertia tensor. The distribution of asphericity and shape shows that complexed proteins are mostly spherically symmetrical, while DNA and RNA in complexed states are largely prolate and considerably more aspherical compared to the proteins. Persistence length characterizes the intrinsic flexibility/rigidity of proteins and nucleic acids. The flexibility of all biomolecules decreases with the chain length. For small DNA molecules (6-147 base pairs), persistence length is larger compared to RNA and proteins in protein-protein and protein-RNA complexes. The flexibility of DNA increases, while RNA decreases, in their respective complexed states as compared to that of proteins which remain almost unchanged. The two body contact analysis confirms that the side-chain-backbone contacts are predominant compared to sidechain-sidechain and backbone-backbone contacts in the complexed proteins. The average packing density of proteins decreases in their complexed states, which is measured by the mean value of the contact density of their alpha carbon atoms. The average number of hydrogen bonds are found to be less in the interface region of protein-protein complexes compared to that in protein-DNA and protein-RNA complexes.     

13C NMR spectroscopy of new amino protective groups

The ¹³C data of several new amino protecting groups of the urethane structure are reported. The speeds of acidolytic cleavage are correlated with the ¹³C parameters.     

Thermo-biolithography: a technique for patterning nucleic acids and proteins

We describe a "biolithographic" technique in which the unique properties of biopolymeric materials and the selective catalytic activities of enzymes are exploited for patterning surfaces under simple and bio-friendly conditions. We begin by coating a reactive film of the polysaccharide chitosan onto an inorganic surface (glass or silicon wafer). Chitosan's pH-responsive solubility facilitates film deposition, while the nucleophilic properties of this polysaccharide allow simple chemistries or biochemistries to be used to covalently attach species to the film. The thermally responsive protein gelatin is then cast on top of the chitosan film, and the gelatin gel serves as a sacrificial "thermoresist". Pattern transfer is accomplished by applying a heated stamp to melt specific regions of the gelatin thermoresist and selectively expose the underlying chitosan. Finally, molecules are conjugated to the exposed chitosan sublayer and the sacrificial gelatin layer is removed (either by treating with warm water or protease). To demonstrate the concept, we patterned a reactive dye (NHS-fluorescein), a model 20-base oligonucleotide (using standard glutaraldehyde coupling chemistries), and a model green fluorescent protein (using tyrosinase-initiated conjugation). Because gelatin can be applied and removed under mild conditions, sequential thermo-biolithographic steps can be performed without destroying previously patterned biomacromolecules. These studies represent the first step toward exploiting nature's exquisite specificity for lithographic patterning.     

Ab initio force field for simulations of proteins and nucleic acids

We present a new self-consistent set of ab initio analytical pair potential to predict specific nonbonded interactions of protein with nucleic acid, of protein with protein, and of nucleic acid with nucleic acid. The purpose of this study is to represent the interaction between biological molecules with an accuracy equivalent to the ab initio molecular orbital calculations, which are used as reference data to obtain the pair potentials. Atoms in nucleic acids and proteins are classified according to their chemical environments. An “effective charge,” a modification of a charge obtained from the Mulliken population analysis, is introduced and used to represent the electrostatic energy. More than 30,000 SCF interaction energies have been calculated to provide the reference data for the fitting procedure that we have adopted in the parameterization of the potentials. The standard deviation is 1.61 kcal/mol for interaction energies spanning the range from about ?220 kcal/mol to +20 kcal/mol. Molecular dynamics simulations, using the above new set of force field, have been performed successfully for the systems where adequate treatments of specific interactions are required: The stability of α-helix of C-peptide and the interaction of spermine with oligonucleotide are examined as preliminary examples.     

Vitamin B12-derivatives-enzyme cofactors and ligands of proteins and nucleic acids

B(12)-cofactors play important roles in the metabolism of microorganisms, animals and humans. Microorganisms are the only natural sources of B(12)-derivatives, and the latter are "vitamins" for other B(12)-requiring organisms. Some B(12)-dependent enzymes catalyze complex isomerisation reactions, such as methylmalonyl-CoA mutase. They need coenzyme B(12), an organometallic B(12)-derivative, to induce enzymatic radical reactions. Another group of widely relevant enzymes catalyzes the transfer of methyl groups, such as methionine synthase, which uses methylcobalamin as cofactor. This tutorial review covers structure and reactivity of B(12)-derivatives and structural aspects of their interactions with proteins and nucleotides, which are crucial for the efficient catalysis by the important B(12)-dependent enzymes, and for achieving and regulating uptake and transport of B(12)-derivatives.     

NMR spectroscopy can characterize proteins encapsulated in a sol-gel matrix

Proteins encapsulated within sol-gel matrices (SG) have the potential to fill many scientific and technological roles, but these applications are hindered by the limited means of probing possible structural consequences of encapsulation. We here present the first demonstration that it is possible to obtain high-resolution, solution NMR measurements of proteins encapsulated within a SG matrix. With the aim of determining the breadth of this approach, we have encapsulated three paramagnetic proteins with different overall charges: the highly acidic human Fe3+ cytochrome b5 (cyt b5); the highly basic horse heart cytochrome c (cyt c); and the nearly neutral, sperm whale cyanomet-myoglobin. The encapsulated anionic and neutral proteins (cyt b5; myoglobin) undergo essentially free rotation, but show minor conformational perturbations as revealed by shifts of contact-shifted peaks associated with the heme and nearby amino acids.     

Conformation analysis of nucleic acids and proteins adsorbed on single-shell carbon nanotubes

This paper presents a concise review of the experimental and calculated data reported in the literature on the noncovalent interactions of DNA and proteins with the nonfunctionalized carbon nanotubes. Our Raman scattering and electron microscopy data on carbon nanotubes and SEIRA spectral data on changes in the conformational state of the main biological polymers (DNA, Poly, BSA, and RNase) in reactions with single-shell carbon nanotubes allowed us to define the character of noncovalent interactions in the tube biomolecule system. An analysis of the data showed that reactions of DNA with nanotubes lead to the binding on the surface of the nanotube and form stable complexes with van der Waals interactions, in which stacking plays the major role and which changes the hydrogen bonds in the biological molecule with structure rearrangements. Albumin and RNase are presumably adsorbed at the conventional binding sites of these proteins on the nanotube with participation of hydrophobic interaction and π stacking, as indicated by structure rearrangements in proteins.     

A convenient tool for studying the stability of proteins and nucleic acids

The aim of this work is to discuss the thermodynamic properties, obtained by differential scanning calorimetry (DSC), of the thermal transition of proteins and nucleic acids and to analyze these data using statistical thermodynamic relations. The denaturation of the ordered, specific structures of biological macromolecules is a cooperative process and in many cases the macromolecules undergo a two-state transition. Differential scanning calorimetry, giving direct thermodynamic information, has proved to be very useful in clarifying the energetics of macromolecule transitions and in characterizing their thermal stability. Here, various examples are discussed: i) the equilibrium thermal denaturation of ribonuclease A, a model for the use of DSC by following the temperature-unfolding of the proteins, a monomolecular transition; ii) the equilibrium thermal dissociation of a DNA double helix in two strands, an example of how DSC is used to follow a bimolecular process; iii) an example of the use of DSC for studying the melting of unimolecular and tetramolecular DNA quadruple-helices.     

Methyl groups as probes for proteins and complexes in in-cell NMR experiments

Studying protein components of large intracellular complexes by in-cell NMR has so far been impossible because the backbone resonances are unobservable due to their slow tumbling rates. We describe a methodology that overcomes this difficulty through selective labeling of methyl groups, which possess more favorable relaxation behavior. Comparison of different in-cell labeling schemes with three different proteins, calmodulin, NmerA, and FKBP, shows that selective labeling with [(13)C]methyl groups on methionine and alanine provides excellent sensitivity with low background levels at very low costs.     

Luminescence spectroscopic studies of trimethinecyanines substituted in polymethine chain with nucleic acids and proteins

The series of symmetrical beta-substituted and alpha,gamma-substituted trimethinecyanine dyes were studied for their absorption and fluorescent characteristics in unbound state and in the presence of nucleic acids and proteins. It was shown that beta-substituted and alpha,gamma-bridged trimethinecyanines containing extended heterocyclic systems or N-phenyl as well as N-cyclohexyl substituents demonstrate increased affinity to proteins. At the same time the presence of both N-phenyl and N-cyclohexyl substituents leads to the decrease of the dye fluorescence intensity in complexes with nucleic acids. For trimethinecyanines similarly to unsymmetrical monomethines the presence of N-omega-hydroxy alkyl substituents results in the increase of fluorescence intensity of dye-DNA complex and the emission decrease of dye-RNA complex.