Determination of the complete correlation between the sugar ring puckers and 5'-exocyclic group rotamers in conformationally-flexible nucleic acid components from NMR study

Inspection of stereochemical models suggests a possible correlation between the proportion (Yg-/Yt) of the g- and t rotamers and the S pucker populations irrespective of the anti-syn conformational composition of the base. Interpretation of the NMR vicinal coupling constants in terms of conformational populations shows a decline of Yg-/Yt with XS approaching zero, consistent with high unfavorability of the Ng- conformational combination in solution, a result supported by a X-ray crystallographic data survey. Hence, the underlying assumption introduced into the present study is that the g- rotamer and the N pucker do not coexist together in solution. Therefore, the limiting value of Yg-/Yt corresponding to the S pucker could be determined for each compound individually. Finally, populations and relative free energies of all conformational combinations of Ng+, Nt, Sg+, St and Sg- (except Ng- which is not important) have been estimated. Results of the present study suggest several interesting regularities concerning the syn-anti effect on populations and energies of the conformational combinations in ribo- and deoxyribo-nucleosides. (a) In the anti-type nucleosides, the Ng+ conformation is about 2 kJ/mol more stable than Nt, but in the syn-type, the Ng+ and Nt have comparable energy. (b) No important changes are observed in the Ng+ population comparing the anti-type and syn-type of ribo- and deoxyribo-nucleosides separately. (c) The Nt is considerable stabilized and simultaneously the Sg+ is strongly destabilized in the syn-type nucleosides relative to the anti-type. (d) Irrespective of the syn-anti composition the St is always more stable (1-2 kJ/mol) than the Sg- conformational combination.     

Raman studies of nucleic acids. XII. Conformations of oligonucleotides and deuterated polynucleotides

Laser Raman spectra of the trinucleoside diphoshate ApApA and dinucleoside phosphates ApU, UpA, GpC, CpG, and GpU are reported and discussed. Assignments of conformationally sensitive frequencies are-facilitated by comparison with spectra reported here of poly(rA), poly(rC), and poly(rU) in deuterium oxide solutions. The significant spectral differences between ApU and UpA, and between GpC and CpG, reveal that the sequence isomers have nonidentical conformations in aqueous solution. In UpA at low temperature the bases are stacked and the backbone conformation is similar to that found in ordered polynucleotide structures and RNA. In ApU no base stacking can be detected and the backbone conformation differs from that found in UpA, both in the orientation of phosphodiester linkages and in the internal conformation of ribose. At the conditions employed neither ApU nor UpA exhibits base pairing in aqueous solutions. In both GpC and CpG the bases are stacked and the phosphodiester conformations are similar to those encountered for UpA and RNA. However, major differences between spectra of GpC and CpG indicate that the geometries of stacking and ribosyl conformations are different. In GpC the Raman data favor the formation of hydrogen bonded dimers containing GC pairs. Protonation of C in GpC is sufficient to eliminate the ordered conformation detected by Raman spectroscopy. Despite the ordered backbone conformation evident in GpU, this dinucleoside apparently contains neither stacked nor hydrogen bonded bases at the conditions employed here. The Raman data also confirm the stacking interactions in ApApA, poly(rA), and poly(rC) but suggest that the backbone conformation in poly(rC) differs qualitatively from that found in most ordered polynucleotide structures and is thermally more stable. The present results demonstrate the sensitivity of the Raman technique to sequence-related structural differences in oligonucleotides and provide additional spectra–structure correlations for future conformational studies of RNA by laser Raman spectroscopy.     

Stereochemical Criteria for Polypeptide and Protein Chain Conformations: II. Allowed Conformations for a Pair of Peptide Units

The conformation of a polypeptide or protein chain may be specified by stating the orientations of the two linked peptide residues at each alpha carbon atom in the chain, namely the two dihedral angles ϕ, ϕ′ about the single bonds N—αC and αC—C′ from a defined standard conformation. By using certain criteria of minimum contact distances between the various atoms, the allowed anges of (ϕ, ϕ′) have been worked out for three values of the angle N-αC-C′ (τ), namely 105, 110, and 115° for non-glycyl, and 110 and 115° for glycyl residues. The theory is compared with all the available crystallographic data (up to early 1965) on simple (di- and tri-) peptides, cyclic peptides, polypeptide and protein structures, and the observed data fully support the conclusions from theory. The effect of the gamma carbon atom, in its three possible positions, is also discussed, and is found to alter the outer limits of the allowed region of (ϕ, ϕ′) only slightly. The paper contains exhaustive references to the published data on these structures, using x-ray diffraction.     

Nonionic nucleic acid analogues. Synthesis and characterization of dideoxyribonucleoside methylphosphonates.

A series of dideoxyribonucleoside methylphosphonate analogues, dNpN and dNpNp, which contain a nonionic 3'--5' methylphosphonyl internucleoside linkage were prepared. The two diastereoisomers, designated isomers 1 and 2, of each dimer differ in configuration of the methylphosphonate group and were separated by column chromatography. The diastereoisomers of each dimer have different conformations in solution as shown by ultraviolet hypochromicity data and their circular dichroism spectra. For example, dApA isomer 1 is more highly stacked than isomer 2, although both isomers are less stacked than the dinucleoside monophosphate, dApA. The circular dichroism spectrum of isomer 1 is very similar to that of dApA, while the CD spectrum of isomer 2 shows a loss of molecular ellipticity, [theta], at 270 nm and a greatly diminished [theta] at 250 nm. These results suggest that the stacked bases of dApA isomer 1 tend to orient in an oblique manner, while those in isomer 2 tend to orient in a parallel manner. This interpretation is verified by the 1H NMR study of these dimers (L. S. Kan, D. M. Cheng, P. S. Miller, J. Yano, and P. O. P. Ts'o, unpublished experiments). Both diastereoisomers of dAaA form 2U:1A and 2T:1A complexes with poly(U) and poly(dT), respectively. The higher Tm (Tm of poly(U)--isomer 1, 15.4 degrees C; Tm of poly(U)--isomer 2, 19.8 degrees C; Tm of poly(dT)--isomer 1, 18.7 degrees C; Tm of poly(dT)--isomer 2, 18.4 degrees C) values of these complexes vs. those of the corresponding dApA--polynucleotide complexes (Tm of poly(U)--dApA, 7.0 degrees C; Tm of poly(dT)--DApA, 9.2 degrees C) result from decreased charge repulsion between the nonionic dimer backbone and the negatively charged polymer backbone. The difference in conformations between dApA isomer 1 and dApA isomer 2 is reflected in the Tm of the isomer 1-poly(U) complex which is 4.4 degrees C lower than that of the isomer 2-poly(U) complex. Since these nonionic oligonucleotide analogues are taken up by cells in culture, they show promise as molecular probes for the function and structure of nucleic acids inside living cells.     

Theoretical studies on protein-nucleic acid interactions. I. Interaction of positively charged amino acids with nucleic acid fragments

Coulombic interactions between the side chains of charged amino acids (Arg⁺, Lys⁺, and His⁺) and negatively charged phosphate groups of nucleic acid fragments have been studied theoretically. Diribose monophosphate and dideoxyribose monophosphate are chosen as model systems for single-stranded RNA and DNA, respectively. The interaction energies have been calculated by second-order perturbation theory using simplified formulas for individual terms. The interaction energy in this formalism is a sum of electrostatic, polarization, dispersion, and repulsive energies. Our results show that about 90% of the total interaction energy is contributed by the electrostatic term alone. Contribution from the repulsive term exceeds that from the dispersion term. Calculated interaction energies suggest that Lys⁺ and His⁺ form more stable complexes with RNA than with single-stranded DNA. On the other hand, Arg⁺ has a higher affinity for DNA than for RNA. The affinity of nucleic acids for the three amino acids is in the order Lys⁺ > His⁺ > Arg⁺. Further, the basic amino acid residues form more stable complexes with A-DNA than with B-DNA. The role of the Coulombic interactions in the specific recognition of nucleic acids by proteins is discussed.     

Theoretical studies of nucleic acid interactions. I. Estimates of conformational mobility in intercalated chains

A combined geometric and potential-energy analysis has been carried out to identify the torsional arrangements of the nucleic acid chain that can accommodate the intercalation of small planar moieties. In contrast to previous theoretical efforts, which detail local conformations after adjacent bases are positioned in space, the likely geometries are found here on the basis of the base orientations that result from all feasible combinations of the nine torsional variables of the basic dinucleotide intercalation unit. The relatively mobile nature of the sugar-phosphate backbone, together with the fairly long stretches of chemical bonds between adjacent units, is apparently responsible for the large number of feasible binding geometries. Some previously overlooked conformations with unusual sugar-puckering combinations and various phosphodiester arrangements are found in the survey. A large proportion of the energetically favored intercalation states are closely related to the backbone conformations of familiar double-helical models such as A-, B-, and Z-DNA, as well as the Watson-Crick model. Moreover, the intercalated forms are found to interconvert smoothly along a continuous conformational pathway. The intercalation structures derived from x-ray crystallographic analyses of drug-oligonucleotide complexes, in contrast, are stiff three-dimensional forms essentially frozen in a single domain of conformation space. Specific ligand-nucleic acid interactions that may be responsible for the experimental observations are not included in this study. The classical intramolecular potential energies reported here are highly approximate, providing only rough gauges of the relative importance of the many competing conformations.     

Stereochemical Criteria for Polypeptide and Protein Chain Conformations: III. Helical and Hydrogen-Bonded Polypeptide Chains

The previous study, for a pair of peptide units, of the conformations which are allowed on the basis of stereochemical criteria of van der Waals contacts has been extended to the analysis of possible conformations of helical polypeptide chains. Computer methods have been developed which select conformations on the basis of both satisfactory interatomic contacts as well as the formation of good intramolecular hydrogen bonds. Such programs have been used to map the allowed dihedral angle pairs (varphi, psi) for helical polypeptide chains. This survey has been made for values of the N-C(a)-C' angle (tau) of 105 degrees , 110 degrees , and 115 degrees , from which the significant influence of this angle in determining allowed helical conformations can be demonstrated. Calculations have also been carried out using potential energy functions for the interaction between nonbonded atoms. The potential energy contour maps obtained in this manner are basically similar to the conformational maps calculated by the first method.     

Synthesis of some fully 3' and 4'-C-branched-chain sugar nucleoside analogues.

The synthesis of some new 3'-azido-3'-C-substituted pyrimidine nucleoside analogues is described. The key step is the geminal disubstitution of an appropriated ketone carbohydrate, via the regioselective ring opening of the corresponding tosyl-epoxide derivative.     

Conformational studies of nucleic acids: III. Empirical multiple correlation functions for nucleic acid torsion angles

There are seven significantly variable torsion angles in each monomer unit of a polynucleotide. Because of this, it is computationally infeasible to consider the energetics of all conformations available to a nucleic acid without the use of simplifications. In this paper, we develop functions suggested by and regression fit to crystallographic data which allow three of these torsion angles, alpha (O3'-P-O5'-C5'), delta (C5'-C4'-C3'-O3') and epsilon (C4'-C3'-O3'-P), to be calculated as dependent variables of those remaining. Using these functions, the seven independent torsions are reduced to four, a reduction in complexity sufficient to allow an examination of the global conformational energetics of a nucleic acid for the remaining independent torsion angles. These functions are the first to quantitatively relate a dependent nucleic acid torsion angle to several different independent angles. In all three cases the data are fit reasonably well, and in one case, alpha, the fit is exceptionally good, lending support for the suitability of the functions in conformational searches. In addition, an examination of the most significant terms in each of the correlation functions allows insight into the physical basis for the correlations.