The effect of (2''-5'') and (3''-5'') phosphodiester linkages on conformational and stacking properties of cytidylyl-cytidine in aqueous solution.

Conformational properties of (2'-5') and (3'-5') CpC have been determined by proton magnetic resonance spectroscopy at 220 MHz. The ribose ring structures are predominantly 3E with the exception of the ring from the 2'-phosphate fragment of C(2'-5')pC which exhibits an 2E pucker. Bases are oriented anti with respect to the ribose and the conformations about C4'-C5', C5'-O5', C3'-O3' (C2'-O2') are gg, g'g', and g+ in equilibrium g-, respectively. The dimers exist as mixtures of stacked (g+g+ and g-g- about the P-O(C) bonds) and unstacked species at 20 degrees C. Stacking is estimated to be 35% in both dimers.     

Visualisation of a 2'-5' parallel stranded double helix at atomic resolution: crystal structure of cytidylyl-2',5'-adenosine

X-ray crystallographic studies on 3'-5' oligomers have provided a great deal of information on the stereochemistry and conformational flexibility of nucleic acids and polynucleotides. In contrast, there is very little information available on 2'-5' polynucleotides. We have now obtained the crystal structure of Cytidylyl-2',5'-Adenosine (C2'p5'A) at atomic resolution to establish the conformational differences between these two classes of polymers. The dinucleoside phosphate crystallises in the monoclinic space group C2, with a = 33.912(4)A, b = 16.824(4)A, c = 12.898(2)A and beta = 112.35(1) with two molecules in the asymmetric unit. Spectacularly, the two independent C2'p5'A molecules in the asymmetric unit form right handed miniature parallel stranded double helices with their respective crystallographic two fold (b axis) symmetry mates. Remarkably, the two mini duplexes are almost indistinguishable. The cytosines and adenines form self-pairs with three and two hydrogen bonds respectively. The conformation of the C and A residues about the glycosyl bond is anti same as in the 3'-5' analog but contrasts the anti and syn geometry of C and A residues in A2'p5'C. The furanose ring conformation is C3' endo, C2' endo mixed puckering as in the C3'p5'A-proflavine complex. A comparison of the backbone torsion angles with other 2'-5' dinucleoside structures reveals that the major deviations occur in the torsion angles about the C3'-C2' and C4'-C3' bonds. A right-handed 2'-5' parallel stranded double helix having eight base pairs per turn and 45 degrees turn angle between them has been constructed using this dinucleoside phosphate as repeat unit. A discussion on 2'-5' parallel stranded double helix and its relevance to biological systems is presented.     

Advanced nuclear magnetic resonance lanthanide probe analyses of short-range conformational interrelations controlling ribonucleic acid structures

An advanced method was developed for lanthanide-probe analyses of the conformations of flexible biomolecules such as nucleotides. The new method is to determine structure parameters (such as internal-rotation angles) and population parameters for local conformational equilibria of flexible sites, together with standard deviations of these parameters. As the prominent advantage of this method, the interrelations among local conformations of flexible sites may be quantitatively elucidated from the experimental data of lanthanide-induced shifts and relaxations and vicinal coupling constants. As a structural unit of ribonucleic acids, the molecular conformations and conformational equilibria of uridine 3'-monophosphate in aqueous solution were analyzed. The stable local conformers about the C3'-O3' bond are the G+ (phi' = 281 +/- 11 degrees) and G- (phi' = 211 +/- 8 degrees) forms. The internal rotation about the C3'-O3' bond and the ribose-ring puckering are interrelated; 97 +/- 5% of the C3'-endo ribose ring is associated with the G- form while 70 +/- 22% o the C2'-endo ribose ring is associated with the G+ form. An interdependency also exists between the internal rotation about the C4'-C5' bond and the ribose-ring puckering. These short-range conformational interrelations are probably important in controlling the dynamic aspects of ribonucleic acid structures.     

DFT studies of the disaccharide, alpha-maltose: relaxed isopotential maps

The disaccharide, alpha-maltose, forms the molecular basis for the analysis of the structure of starch, and determining the conformational energy landscape as the molecule oscillates around the glycosidic bonds is of importance. Thus, it is of interest to determine, using density functionals and a medium size basis set, a relaxed isopotential contour map plotted as a function of the phi(H) and psi(H) dihedral angles. The technical aspects include the method of choosing the starting conformations, the choice of scanning step size, the method of constraining the specific dihedral angles, and the fitting of data to obtain well defined contour maps. Maps were calculated at the B3LYP/6-31+G( *) level of theory in 5 degrees intervals around the (phi(H),psi(H))=(0 degrees ,0 degrees ) position, out to approximately +/-30 degrees or greater, for gg-gg'-c, gg-gg'-r, gt-gt'-c, gt-gt'-r, tg-tg'-c, and tg-tg'-r conformers, as well as one-split gg(c)-gg'(r) conformer. The results show that the preferred conformation of alpha-maltose in vacuo depends strongly upon the hydroxyl group orientations ('c'/'r'), but the energy landscape moving away from the minimum-energy position is generally shallow and transitions between conformational positions can occur without the addition of significant energy. Mapped deviations of selected parameters such as the dipole moment; the C1-O1-C4', H1-C1-O1, and H4'-C4'-O1 bond angles; and deviations in hydroxymethyl rotamers, O5-C5-C6-O6, O5'-C5'-C6'-O6', C5-C6-O6-H, and C5'-C6'-O6'-H', are presented. These allow visualization of the structural and energetic changes that occur upon rotation about the glycosidic bonds. Interactions across the bridge are visualized by deviations in H(O2)...O3', H(O3')...O2, and H1...H4' distances and the H(O2)-O2-C2-C1 and H'(O3')-O3'-C3'-C4' hydroxyl dihedral angles.     

Conformational properties of adenylyl-3' leads to 5'-adenosine in aqueous solution.

A detailed 220-MHz NMR study has been made of the conformational properties for the homodinucleotide adenylyl-3' leads to 5'-adenosine, ApA, in D2O. Unambiguous signal assignments of all proton signals were made with the aid of selectively deuterated nucleotidyl units, ApA, ApA, and D-8ApA, and complete, accurate sets of NMR parameters were derived by simulation-iteration methods. Sets of limiting chemical shifts and coupling values were also obtained for ApA and constituent monomers 3'-AMP and 5'-AMP at infinite dilution and at identical ionization states for assessment of dimerization effects. Conformational properties were evaluated quantitatively for most of the conformational bonds of ApA and these are consistent with two compact folded dynamically averaged structures, a base-stacked right helical structure, I, characterized as anti, C3'-endo, g-, w,w' (320,330 degrees), g'g', gg, C3'-endo, anti, and a more loosely base-stacked loop structure, II, with anti, C3'-endo, g-, w,w' (80 degrees, 50 degrees), g'g', gg, C3'-endo, anti orientations. Dimerization produces a number of nucleotidyl conformational changes including a shift in ribose equilibrium C2'-endo (S) in equilibrium C3'-endo (N) in favor of C3'-endo in both Ap- and -pA (60:40 vs. 35:65 in monomers), a change in glycosidic torsion angle chiCN toward 0 degrees, and a greater locking-in of rotamers along bonds involved in the phosphodiester backbone. Moreover, there is clear evidence that the transitions from S leads to N forms and chiCN leads to 0 degrees are directly related to base stacking in ApA. Finally, ApA exists in solution as an equilibrium between I, II and an unstacked form(s) with as yet undetermined conformational features. Since C4'-C5', C5'-O5', and C3'-O3' bonds possess exceptional conformational stabilities, it is proposed that destacking occurs primarily by rotation about P-O5' and/or O3'-P. Predominant factors influencing the overall ApA conformation are thus base-base interaction and flexibility about P-O5' and O3'-P, with change of ribose conformation occurring in consequence of an alteration of chiCN, the latter in turn being governed by the need for maximum eta overlap of stacked adenine rings.     

Conformational analysis of the trinucleoside diphosphate 3'd(A2'-5'A2'-5'A). An NMR and CD study.

A 500 MHz and 300 MHz NMR study of the trinucleoside diphosphate 3'd(A2'-5'A2'-5'A) is presented. In addition, circular dichroism is used to study base stacking in the title compound. The complete 1H-NMR spectral assignment of the sugar ring proton signals is given. Information about the sugar ring (N- or S-type conformation) and about the backbone geometry along C4'-C5' and C5'-O5' bonds is obtained from the NMR coupling constants. It is shown that the trimer mainly occurs in the N-N-N stacked state at low temperatures; the presence of a minor amount of N-N-S conformational sequence is indicated.     

A comparative conformational study of thymidylyl(3'----5')-thymidine, thymidylyl(3'----5')-5'-thio-5'- deoxythymidine and thymidinylacetamido-[3'(O)----5'(C)]-5'-deoxythymidine

A comparative 270 MHz NMR spectroscopic study on the solution structure of the dimer d(TpT) 1, and its two analogues, namely, d(TpST) 2, and NH2d(TcmT) 4 has been reported. Analysis of chemical shifts and coupling constants indicate that: (i) The sugar moieties of the constituent nucleotides are not affected by modification of the internucleotide linkages and adopt preferentially an S-type conformation. (ii) The C4'-C5' bond in the pT part of the modified dimers 2 and 4 shows a large conformational freedom (gamma+ = 32% and 35%, respectively) compared to 1 (gamma+ = 75%). (iii) The population of the trans conformer about C5'-O5' is less important in d(TpST) 2 compared to d(TpT) 1. (iv) The C3'-O3' bond in 2 adopts a trans conformation as in 1. (v) The glycosidic bonds in the modified dimers 2 and 4 showed preferential syn conformation. UV and CD data show that the modified dimers 2 and 4 have poor tendency to stack intramolecularly, they also base pair less efficiently with d(ApA) as compared to d(TpT) 1.     

Molecular and crystalline structure of 3'-methylamino-2',3'-dideoxyribosylthymine--a potential inhibitor of HIV]

The structure of 3'-methylamino-2',3'-dideoxyribosylthymine [ddT(3'NHMe)] was determined by X-ray analysis. The space group is P2(1)2(1)2(1). Cell dimensions are: a 5.132(1), b 13.718(1), c 16.947(2) A, V 1193.2 A3, Z 4. The structure was solved by directed methods and refined by the full-matrix least square method to R 4.8%. The molecule of ddT(3'NHMe) has anti-conformation with respect to the glycosidic bond (chi (O4'-C1'-N1-C2) = -106.7 degrees), C3'-endo-C4'-exo puckering of the sugar moiety (P -28.8 degrees, psi m -31.5 degrees) and gauche-gauche conformation about exocyclic C4'-C5' bond (psi(C3'-C4'-C5'-O5') 45.8 degrees). The structure of ddT(3'NHMe) was compared with those of 3'-amino-3'-deoxythymidine, 3'-azido-3'-deoxythymidine and natural thymidine.     

Carbon-13 NMR in conformational analysis of nucleic acid fragments. 3. The magnitude of torsional angle epsilon in d(TpA) from CCOP and HCOP NMR coupling constants.

Carbon-13 NMR spectra of the deoxyribonucleotide d(TpA), 3',5'-cyclic AMP and 3',5'-cyclic dAMP were measured. It is shown that the different substitution of C2' in deoxyribonucleotides versus ribonucleotides does not affect the vicinal C2'-C3'-O3'-P coupling to a measurable extent. Therefore, the same set of Karplus parameters may be used for the C2'-C3-O3'-P couplings in ribonucleotides and in deoxyribonucleotides. Vicinal carbon-phosphorus and proton-phosphorus coupling constants are used to calculate the magnitude of the torsion angle epsilon (C4'-C3'-O3'-P), which amounts to 195(0) in the trans conformer and to 261(0) in the gauche(-) conformer.     

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.     

Nuclear magnetic resonance studies of the solution conformation of nucleoside diphosphohexoses and their components.

The solution conformations of UDPG, UDPGN, UDPGal, UDPM, UDPGluc, UDPGalc, ADPG, ADPM, GDPG, GDPM, and CDPG and their components Glu-1-P, Gal-1-P, Man-1-P, Gluc-1-P, Galc-1-P, ADP, GDP, UDP, and CDP are studied by high resolution fast Fourier transform nuclear magnetic resonance spectroscopy with iterative computer line shape simulation. The following results were observed. (1) The six-membered ring is in 4C1 chair form with the C(5')-C(6') bond in gg equilibrium tg equilibrium for the derivatives of glucose and mannose and gt equilibrium tg for those of galactose. (2) No conformational preference can be detected for C(1')-O(1') bond in hexose-1'-P moiety. (3) Chemical shift dependencies for the pyranoid ring protons and their structural and conformational relations are: (a) axial proton is at higher field than equatorial: (b) the shielding effect of a gauche vicinal hydroxyl group is stronger than a trans vicinal; (c) the vicinity of a hydroxyl group located more than three bonds away tends to shift the proton downfield. (4) The conformation of the nucleoside 5'-diphosphate part is [anti, 2E equilibrium 3E, g'g' equilibrium g't', g'g' equilibrium g'/t'], with slight variation of each conformation occuring for individual compounds. (5) No significant interactions are detected between the hexose and nucleoside parts in the nucleoside diphosphohexoses, and the hexose and nucleoside components display the same conformational preference as they become integrated to form nucleoside diphosphohexoses.     

Conformational studies of nucleic acids: IV. The conformational energetics of oligonucleotides: d(ApApApA) and ApApApA

Utilizing a new method for modeling furanose pseudorotation (D. A. Pearlman and S.-H. Kim, J. Biomol. Struct. Dyn. 3, 85 (1985)) and the empirical multiple correlations between nucleic acid torsion angles we derived in the previous report (D. A. Pearlman and S.-H. Kim, previous paper in this issue), we have made an energetic examination of the entire conformational spaces available to two nucleic acid oligonucleotides: d(ApApApA) and ApApApA. The energies are calculated using a semi-empirical potential function. From the resulting body of data, energy contour map pairs (one for the DNA molecule, one for the RNA structure) have been created for each of the 21 possible torsion angle pairs in a nucleotide repeating unit. Of the 21 pairs, 15 have not been reported previously. The contour plots are different from those made earlier in that for each point in a particular angle-angle plot, the remaining five variable torsion angles are rotated to the values which give a minimum energy at this point. The contour maps are overall quite consistent with the experimental distribution of oligonucleotide data. A number of these maps are of particular interest: delta (C5'-C4'-C3'-O3')-chi (O4'-C1'-N9-C4), where the energetic basis for an approximately linear delta-chi correlation can be seen: zeta (C3'-O3'-P-O5')-delta, in which the experimentally observed linear correlation between zeta and delta in DNA(220 degrees less than zeta less than 280 degrees) is clearly predicted; zeta-epsilon (C4'-C3'-O3'-P), which shows that epsilon increases with decreasing zeta less than 260 degrees; alpha (O3'-P-O5'-C5')-gamma (O5'-C5'-C4'-C3') where a clear linear correlation between these angles is also apparent, consistent with experiment; and several others. For the DNA molecule studied here, the sugar torsion delta is predicted to be the most flexible, while for the RNA molecule, the greatest amount of flexibility is expected to reside in alpha and gamma. Both the DNA and RNA molecules are predicted to be highly polymorphic. Complete energy minimization has been performed on each of the minima found in the energy searches and the results further support this prediction. Possible pathways for B-form to A-form DNA interconversion suggested by the results of this study are discussed. The results of these calculations support use of the new sugar modeling technique and torsion angle correlations in future conformational studies of nucleic acids.     

The structure and antiviral activity of ribavirin analogs. III. Molecular and crystal structure of 1-(2-hydroxyethoxymethyl)-1,2,4-triazole-carboxamide

The crystal and molecular structure of a ribavirin acyclic analogue, 1-(2-hydroxyethoxymethyl)-1,2,4-triazole-3-carboxamide, has been determined by X-ray diffraction method. The space group is P1, unit cell parameters: a = 5,237, b = 6,960, c = 11,483 A, alpha = 93,89, beta = 97,43, gamma = 94,26 degrees; Z = 2. The structure was solved by the direct method and refined by least-squares procedure to R = 3.7%. Two molecular conformers statistically coexist in the unit cell, differing in the hydroxyethoxymethyl group conformation. Trans-conformation about O4'-C4' bond and gauche about C4'-C5' bond are observed in both molecules. C1'-O4' bond is approximately perpendicular to the aglicon.     

Conformational studies of 13 trinucleoside bisphosphates by 360-MHz 1H-NMR spectroscopy. 1. Ribose protons

The ribose protons of 13 trinucleoside bisphosphates (trimers) were studied, using 360-MHz proton nuclear magnetic resonance spectroscopy. Complete assignments and analyses of the NMR signals of these protons were carried out by the methods of homonuclear decoupling and computer line-shape simulations. It was shown that the trinucleotides preferred the anti, 3' endo, gamma +, beta t and epsilon t/epsilon- conformations for the glycosidic torsions, the ribose rings, the C4'-C5' bonds, the C5'-O5' bonds, and the C3'-O3' bonds, respectively. It was also found that the trimers, especially those which had noticeable population of 'bulged' structures, did not necessarily have a higher population of these preferred local conformations than their component dimers. The overall conformations of the trinucleotides are classified into two categories. The conformations in the first category involve the nearest-neighbor interactions. Each dinucleotide moiety can assume one of the four stable conformations (I, I', II and III) or the open forms of dinucleoside monophosphates. However, due to steric hindrance, there are only four cases in which both dinucleotide moieties can assume one of the four stable conformations at the same time. These four combinations of conformations are I-I, I'-I', I-II and III-I', where the first Roman numeral represents the conformation of the NpN'p-moiety and the second one, that of the -pN'pN' moiety of the trimers. Among them, I-I and I'-I' are helical structures, capable of forming a double helix. The second category contains conformations with bulged structures which have the two dinucleotide moieties in open forms (i.e. no nearest-neighbor interactions) and the bases of the two terminal residues stacking on each other while the middle residue is bulged out. These bulged conformations may serve as structural models for frame-shift mutations.     

Remote mutations alter transition-state structure of human purine nucleoside phosphorylase

Purine nucleoside phosphorylase (PNP) catalyzes the reversible phosphorolysis of purine (2'-deoxy)ribonucleosides to give the corresponding purine base and (2'-deoxy)ribose 1-phosphate as products. Human and bovine PNPs (HsPNP and BtPNP) form distinct transition states despite 87% identity in amino acid sequence. A PNP hybrid was produced by replacing K22 and H104 in HsPNP with the corresponding Glu and Arg residues found in BtPNP. We solved the transition-state structure of E:R-HsPNP (K22E:H104R mutant of HsPNP) using competitive kinetic isotope effects (KIE) and global density functional calculations. An array of PNP transition states was generated from optimized structure candidates with varied C1'-N9, C1'-Ophosphate distances, ribosyl pucker configurations and N7-protonation states. Isotopically labeled [1'-3H], [2'-3H], [1'-14C], [9-15N], [1'-14C, 9-15N] and [5'-3H2]inosines gave intrinsic KIE values of 1.210, 1.075, 1.035, 1.024, 1.065, 1.063 with E:R-HsPNP, respectively. The suite of E:R-HsPNP KIEs match a single structure from the array of PNP transition-state candidates. The transition state of E:R-HsPNP is fully dissociative, N7-protonated hypoxanthine (C1'-N9 distance >or= 3.0 A) with partial participation of phosphate (C1'-Ophosphate distance = 2.26 A), 2'-C-exo-ribosyl ring pucker and the O5'-C5'-C4'-O4' dihedral angle near 60 degrees . The transition state of E:R-HsPNP is altered from the fully dissociative DN*AN character for HsPNP to a late phosphate-associative character. E:R-HsPNP differs from native HsPNP by only two residues over 25 A away from the active site. New interactions caused by the mutations increase the catalytic efficiency of the enzyme for formation of a late transition state with increased participation of the phosphate nucleophile. Dynamic coupling motions from the remote mutations to the catalytic sites are proposed.     

The occurence of the syn-C3' endo conformation and the distorted backbone conformations for C4'-C5' and P-O5' in oligo and polynucleotides.

The nucleoside constituents of nucleic acids prefer the anti conformation (1). When the sugar pucker is taken into account the nucleosides prefer the C2'endo-anti conformation. Of the nearly 300 nucleosides known, about 250 are in the anti conformation and 50 are in the syn-conformation, i.e., anti to syn conformation is 5:1. The nucleotide building blocks of nucleic acids show the same trend as nucleosides. Both the deoxy-guanosine and riboguanosine residues in nucleosides and nucleotides prefer the syn-C2'endo conformation with an intra-molecular hydrogen bond (for nucleosides) between the O5'-H and the N3 of the base and, a few syn-C3'endo conformations are also observed. Evidence is presented for the occurrence of the C3'endo-syn conformation for guanines in mis-paired double helical right-handed structures with the distorted sugar phosphate C4'-C5' and P-O5' bonds respectively, from g+ (gg) and g- to trans. Evidence is also provided for guanosine nucleotides in left-handed double-helical (Z-DNA) oligo and polynucleotides which has the same syn-C3'endo conformation and the distorted backbone sugar-phosphate bonds (C4'-C5' and P-O5') as in the earlier right-handed case.     

Biological activities of phosphodiester linkage isomers of 2-5A

To determine the relative importance of the 2',5'-phosphodiester bond of 2-5A in its binding to and activation of the 2-5A-dependent ribonuclease (RNase L, RNase F), a number of phosphodiester linkage isomers of 2-5A were prepared. These isomers were obtained either by lead ion-catalyzed polymerization of adenosine 5'-phosphorimidazolidate or by T4 polynucleotide kinase-catalyzed 5'-phosphorylation of adenylyl(3' leads to 5')adenylyl(3' leads to 5')adenosine followed by reaction of the corresponding phosphorimidazolidates with tri(n-butylammonium)pyrophosphate. The following 2-5A isomers thus were prepared: ppp5'A2'p5'A3'p5'A, ppp5'A3'p5'A2'p5'A, ppp5'A3'p5'A3'p5'A("3-5A"), ppp5'A2'p5'A3'p5'A2'p5'A,and ppp5'A3'p5'A2'p5'-A2'p5'A. The ability of these isomeric 2-5As to interact with the 2-5A-dependent endonuclease was ascertained by three different criteria: (i) ability to prevent the protein synthesis inhibitory effects of 2-5A, (ii) activity as an inhibitor of translation in encephalomyocarditis RNA-programmed L cell extracts, and (iii) ability to prevent binding of the radiolabeled probe, ppp5'A2'p5'A2'p5'A2'p5'A3'[32P]p5'Cp, to the endonuclease of L cell extracts. In certain experiments, degradation of oligonucleotide was minimized or eliminated by altering assay conditions, providing alternate phosphodiesterase substrates, or by using purified endoribonuclease of Ehrlich ascites cells. By all criteria, replacement of 2',5'-bond by a 3',5'-bond led to a substantial decrease in biological activity. Generally, replacement of just one 2',5'-phosphodiester bond with a 3',5'-linkage led to at least a one order of magnitude loss of activity. In accord with this trend, ppp5'A3'p5'A3'p5'A(3-5A) was greater than 10,000 less active than 2-5A in binding to the endonuclease or as an inhibitor of protein synthesis.     

Nucleic acid model building: the multiple backbone solutions associated with a given base morphology

A constrained model building procedure is used to generate nucleic acid structures of the familiar A-, B-, and Z-DNA duplexes. Attention is focused upon the multiple structural solutions associated with the arrangements of nucleic acid base pairs rather than the optimum sugar-phosphate structure. The glycosyl (chi) and sugar torsions (both the ring puckering and the exocyclic C5'-C4' (psi) torsion) are treated as independent variables and the resulting O3'...O5' distances are used as closure determinants. When such distances conform to the known geometry of phosphate chemical bonding, an intervening phosphorus atom with correct C-O-P valence angles can be located. Four sequential torsion angles--phi', omega', omega and phi--about the C3'-O3'-P-O5'-C5' bonds are then obtained as dependent variables. The resulting structures are categorized in terms of conformation, ranked in potential energy, and analyzed for torsional correlations. The numerical results are quite interesting with implications regarding nucleic acid models constructed to fit less than ideal experimental data. The multiple solutions to the problem are useful for comprehending the conformational complexities of the local sugar-phosphate backbone and for understanding the transitions between different helical forms. According to these studies, unique characterization of a nucleic acid duplex involves more than the determination of its base pair morphology, its sugar puckering preferences, or its groove binding features.