Crystal structure of a naturally occurring dinucleoside phoaphate: uridylyl 3',5'-adenosine phosphate model for RNA chain folding

Conformational characteristics of mixed sugar puckered deoxydinucleoside triphosphate units d-pCpGp and d-pGpCp from energy minimization studies

The deoxydinucleoside triphosphate units d-pCpGp and d-pGpCp were subjected to a rigorous theoretical investigation with a view to describing their distinctive conformational characteristics. For each unit 216 probable three-dimensional forms defined by the backbone-base dihedral angles and sugar pucker modes were considered for conformational energy minimization process and scrutinized with reference to properties, such as base-stacking, hydrogen-bonding, internal flexibility and base sequence-phosphate influence. The P-O bond torsions and the phosphate groups were treated with special attention. The results reveal a number of preferred conformational states other than the known helical forms, such as, A-, B-, C-, Z-, and Watson-Crick conformation. Many interesting one-step (change in only one of the dihedral angles or sugar puckers) conformational transitions which involve just about a kcal/mol of energy came to light. The two base sequences CG and GC were noted to differ strikingly in many of their conformational characteristics.

Crystal and molecular structure of the ammonium salt of the dinucleoside monophosphate d(CpG)

The crystal and molecular structure of the ammonium salt of deoxycytidylyl-(3'-5')-deoxyguanosine has been determined from 0.85 A resolution single crystal X-ray diffraction data. The crystals obtained by acetone diffusion technique at -20 degrees C, are orthorhombic, P212121, a = 12.880(2), b = 17444(2) and c = 27.642(2) A. The structure was solved by high resolution Patterson and Fourier methods and refined to R = 0.136. There are two d(CpG) molecules in the asymmetric unit forming a mini left handed Z-DNA helix. This is in contrast to the earlier reported forms of d(CpG) where the molecules form self base paired duplexes. There are two ammonium ions in the asymmetric unit. The major groove NH+4 ion interacts with N7 of guanines through water bridges besides making H-bonded interactions directly with the phosphate oxygen atoms. A second NH+4 ion is found in the minor groove interacting directly with the phosphate oxygen atoms. Symmetry related molecules pack in such a way that the cytosine base stacks on cytosine and guanine base on guanine. Our structure demonstrates that alternating d(CpG) sequences have the ability to adopt the left handed Z-DNA structure even at the dimer level i.e., in a sequence which is only two base pairs long.

Crystal and molecular structure of the sodium salt of the dinucleotide duplex d(CpG)

The crystal and molecular structure of the sodium salt of deoxycytidylyl-(3H-5H)-deoxyguanosine has been determined from X-ray diffraction data. The crystal, obtained from an aqueous gamma-butyrolactone solution at pH = 5.3 are orthorhombic, P212121, a = 10.640(2), b = 11.184(2) and c = 44.618(4)A. The structure was refined to an R = 0.041. The d(CpG) structure is similar to the ammonium salt solved by Cruse et al.(1). Both structures form a parallel self base paired mini-double helix. In d(CpG).Na+ one of the two paired cytosines is protonated on N(3). The cytosines form 3 hydrogen bonds while the guanines form only 2. The Na+ ion is coordinated with five groups: two water molecules, O(6) of guanine A, N(7) of guanine B and 0(5') of cytosine B, forming a square pyramid. The hydration shell around the mini-helix is analysed and compared with that of the ammonium salt, d(CpG).Na+ is the second d(CpG) oligonucleotide found with a self base pairing arrangement despite of the fact that the crystallization conditions and counterion were different in both cases. The hypothesis that self base pairing is not only a crystallization artifact but may play a role under physiological conditions as a source of transversion mutations is discussed.

Carbon-13 NMR in conformational analysis of nucleic acid fragments. 2. A reparametrization of the Karplus equation for vicinal NMR coupling constants in CCOP and HCOP fragments

13C-31P coupling constants of 10 oligoribonucleoside phosphates, measured at a number of temperatures, are presented. The combination of these data with 1H-31P couplings of the same compounds leads to the derivation of two new and mutually consistent sets of Karplus parameters: J(CCOP) = 6.9cos2 phi--3.4cos phi + 0.7 J(HCOP) = 15.3cos2 phi--6.1cos phi + 1.6 At the same time new values for the base sequence dependent magnitude of the trans conformer of the backbone angle epsilon (C4'-C3'-O3'-P) are calculated. The present results show that the magnitude of epsilon(t) in right-handed ribo helices is confined to the range 214 degrees-226 degrees (average 219 degrees), which is in much better agreement with single crystal X-ray studies (average 218 degrees) than were previous deductions from NMR spectroscopic results (average 208 degrees).

Local mobility of nucleic acids as determined from crystallographic data. I. RNA and B form DNA

The local mobility of DNA and RNA can be described well by a segmented rigid body model in which the phosphates, riboses and bases are treated as independent groups. We have developed a computer program for extracting information about the translational and rotational mobility of these groups from X-ray diffraction data of single crystals of DNA and RNA fragments. We plan to extend our studies from the B DNA helix studied here to A and Z form helices for which diffraction data are available. The mobilities described here may be important in allowing the flexibility necessary for interaction of nucleic acids with proteins, ligands or other nucleic acids, and are crucial to our understanding of the factors governing both structural stability and motion of nucleic acids on a larger scale.

Antisera specific for the oligoribonucleotide sequences AAU and A2U2 and their recognition of oligonucleotide conformation

Antisera specific for two synthetic oligoribonucleotide sequences, AAU and A2U2, were elicited in rabbits. The oligonucleotides were synthesized using polynucleotide phosphorylase under high salt conditions. Each oligomer was isolated by ion exchange chromatography, and was conjugated to bovine serum albumin, and injected into rabbits as an emulsion with complete Freund's adjuvant. The specificities of the resulting sera were analyzed using a modified Farr-type radioimmunoassay employing homologous oligonucleotide-protein conjugates radiolabeled with [3H]acetic anhydride and unlabeled free oligonucleotides as inhibitors. The antiserum elicited by AAU-BSA reacted well with AAU-RSA but a major fraction of the antibodies was directed to determinants of the conjugate that were not present on the free hapten. With respect to the haptenic determinants, AAU was a better inhibitor than any of the constituent mono- or dinucleotides, implying that features of the entire trinucleotide were being recognized. The other members of the A2Un family reacted to about the same extent as AAU, while other trinucleotides required an up to 21-fold higher concn in order to achieve similar inhibition. The most striking aspect of this antiserum was its failure to bind free ApA, although it could bind the ApA-containing oligonucleotides A3, AAG, AAC and A2Un. It seems likely that the ApA sequence in solution does not contain a significant proportion of a conformation present to a great extent in the ApA-containing oligomers. The antiserum elicited by A2U2-BSA was like anti-AAU-BSA in that some of the antibodies were directed against determinants not present on the free hapten. The most striking result of the inhibition experiments was the specificity of the antiserum for members of the A2Un series. When the A2Un series was compared with AA, AMP or any member of the Un series, approximately four orders of magnitude separated the inhibition curves. The poor binding of component mono- and dinucleotides implies that the conformation recognized by the antibody is present only to a significant extent in the trimeric sequence; the equality of binding of AAU with A2U2, A2U3 and A2U4 suggests that this conformation of the triplet is preserved in the longer sequences. These studies demonstrate the utility of immunochemical procedures for the study of oligonucleotide conformation in solution.

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.

Crystal structure of O4-methyl uridine: stacking induced changes in the geometry of the pyrimidine ring and its mutagenic role

The geometric properties of the pyrimidine ring of O4-methyl uridine more closely resemble those of cytidine than diketo uridine. Differences between the independent molecules of O4-methyl uridine are observed in the C(7)-O(4)-C(4)-C(5)-C(6) bond orders and the planarity of the pyrimidine rings. These differences are attributed to the monopole-induced dipole interactions between the ribose ring oxygen atom and a neighboring base of molecule A. A survey of the literature reveals that similar stacking-induced effects occur in other structures, involving both pyrimidine and purines. Finally, two base pairing schemes between O4-methyl uridine and guanosine, in which two hydrogen bonds can form, have been presented. Of these two the mispair with Watson-Crick geometry is favored.

A nuclear magnetic resonance study of the ribotrinucleoside diphophate UpUpC

500 MHz 1H, 67.89 MHz 13C and 80.97 MHz 31P-NMR studies are reported on the ribotrinucleoside diphosphate UpUpC, the triplet codon corresponding to the amino acid phenylalanine. Complete spectral assignments are given and conformational parameters for the backbone and the furanose rings are determined. All three nucleotide units show a near-balance for the N/S equilibrium with a slight preference for the N-type ribose (approximately 60%). The backbone conformation around the C3'-03' bonds show a preference for the trans domain, while the orientation around the C5'-05' bonds is predominantly trans.

Conformations of oligonucleotides in solution as determined by sequence-specific antibodies

The conformations of some related oligoribonucleotides in solution were investigated immunochemically with antisera specific for two synthetic oligonucleotide sequences, A-A-U and A-A-U-U. Radioimmunoassay showed differences of as much as three or more orders of magnitude in binding among oligonucleotides with commonly shared sequences. These large differences, which reflect the loss of many points of contact with antibody because of changes in overall conformation, allow the following conclusions: (1) A-A-U and A-A-U-U have conformations distinct from any present in the Un family of oligomers. (2) Conformations of A-A-U and A-A-U-U differ markedly from those of oligomers of A. The dinucleotide A-A, in particular, bears little resemblance in conformation to the A-A sequence in A-A-U and A-A-U-U. (3) The recognizable conformational unit appears to be the triplet A-A-U, which binds as well as A-A-U-U and far better than its component dimers. Interactions between non-adjacent bases may be a factor here, as well as in codon recognition. The immunological data support the conclusion that, in oligonucleotides, as in polypeptides, primary sequence can determine conformation in solution.

Conformational flexibility in single-stranded oligonucleotides: crystal structure of a hydrated calcium salt of adenylyl-(3'--5')-adenosine

The crystal and molecular structure of a hydrated calcium salt of adenylyl-(3'--5')-adenosine(ApA) was determined from X-ray diffraction data collected on an automated diffractometer. Crystals of the salt are orthorhombic, space group P21212, with a = 30.614 (3), b = 17.894 (2), and c = 5.373 (1) A. The structure was solved by a combination of Patterson and direct methods and refined by least squares. The final value of the R index is 0.08. The 5'-terminal adenosine residue has a C(2')-endo ribose and assumes a syn conformation, which is stabilized by an O(5')-H...N(3) hydrogen bond within the nucleoside. The 3'-terminal nucleoside has a C(3')-endo ribose and is in the anti conformation. Both omega and omega', the torsion angles within the phosphodiester group, are approximately 60 degrees. Adenine bases from adjacent anions are joined by pairs of N(6)-H...N(1) hydrogen bonds and are stacked with symmetry-related bases. The calcium ion is bound to the dinucleoside phosphate by a direct interaction with the phosphate group and by outer-sphere, ligand-mediated interactions with O(2') of the 5'-terminal nucleoside and N(7) of the 3'-terminal nucleoside. This tridentate interaction of the ApA anion with the calcium coordination sphere probably enhances the stability of the observed ApA conformation. When combined with other crystallographic studies of ApA conformations, the crystal structure of this calcium salt provides additional evidence that dinucleoside phosphates have considerable conformational flexibility.

Theoretical calculations of conformational preferences in dinucleoside monophosphates Up-U and Ap-A. Significance of intramolecular base-backbone interaction

Conformational preferences of dinucleoside monophosphates Up-U and Ap-A have been studied theoretically using the Quantum Chemical PCILO (Perturbative Configuration Interaction Using Localized Orbitals) method. The importance of intramolecular interactions between the bases and ribose phosphate backbone has been indicated. Additionally, a close similarity is predicted between overall Up-U and Ap-A conformational structures. Specific prefrences about the key conformation bonds are C4'-C5' (psi = 60 degrees), C5'-O5' (phi = 180 degrees), O5'-P (omega = 110 degrees), P-O3' (omega' = 310 degrees), O3'-C3' (phi' = 210 degrees), C1'-N (chi = 20 degrees), C2'-O2' (theta = 300 degrees) for nucleotidyl units with C3' -endo ribose pucker. Except for the O5'-P torsion angles (omega = 110 degrees), the remaining values fall in ranges observed for monomers and polynucleotides. Stabilization for this unique omega = 110 degrees preference is provided by intramolecular hydrogen bonding between the 3'-OH (hydroxyl group) and O2 (in uracil) or N3 (in adenine) of the second base from the 3'-terminal. The possibility of such interaction mechanisms at 3'-terminals of ribonucleic acids and polynucleotides is also discussed.

Yeast tRNAPhe conformation wheels: a novel probe of the monoclinic and orthorhombic models

A series of conformation wheels is constructed from the recently refined X-ray crystallographic data of monoclinic and orthorhombic yeast tRNAPhe. These circular plots relate the primary chemical structure (i.e., base sequence) directly to the secondary and tertiary structure of the molecule. The circular sequence of backbone torsion angles displays a unique pattern that is useful both in distinguishing the ordered and disordered regions of the molecule and in comparing the three sets of experimental data. Composite conformation wheels describe the fluctuations in the "fixed" parameters (phi', phi, chi) and independent conformation wheels reveal the changes in the "variable" parameters (omega', omega, psi, psi') of the three different yeast tRNAPhe models. Additional plots of base-stacking parameters help to visualize the intimate interrelationship between chemical sequence and three-dimensional folding of yeast tRNAPhe. The composite data illustrate several conformational schemes that position the bases of adjacent nucleosides in a parallel stacked array and reveal an even larger number of conformations that introduce bends or turns in the polynucleotide chain.

X-ray-structure of a cytidylyl-3',5'-adenosine-proflavine complex: a self-paired parallel-chain double helical dimer with an intercalated acridine dye

The non-self-complementary dinucleoside monophosphate cytidylyl-3',5'-adenosine (CpA) forms a base-paired parallel-chain dimer with an intercalated proflavine. The dimer complex possesses a right-handed helical twist. The dimer helix has an irregular girth with a neutral adenine-adenine (A-A) pair, hydrogen-bonded through the N6 and N7 sites (C1'...C1' separation of 10.97 A), and a triply hydrogen-bonded protonated cytosine-cytosine (C-C) pair with a proton shared between the base N3 sites (Cl'...Cl' separation of 9.59 A). The torsion angles of the sugar-phosphate backbone are within their most preferred ranges and the sugar puckering sequence (5' leads to 3') is C3'-endo, C2'-endo. There is also a second proflavine molecule sandwiched between CpA dimers on the 21-axis. Both proflavines are necessarily disordered, being on dyad axis, and this suggests possible insights into the dynamics of intercalation of planar drugs. This structure shows that intercalation of planar drugs in nucleic acids may not be restricted to antiparallel complementary Watson-Crick pairing regions and provides additional mechanisms for acridine mutagenesis.

A 1:2 crystalline complex of ApA:proflavine: a model for binding to single-stranded regions in RNA

The structure of a 1"2 complex of adenylyl-(3',5')-adenosine phosphate and proflavine hemisulfate has been determined using the methods of x-ray crystallography. Since the ApA does not form a mini double helix, it may serve as a model for the interaction of planar molecules with single stranded nucleic acids. The dinucleotide adopts an extended conformation with the adenines in adjacent molecules forming base pairs. A most unusual feature of the molecule is that it does not obey the "rigid nucleotide" concept although none of the torsion angles occur in energetically unfavourable regions. This is most probably due to the strong interactions between the proflavine and the oligonucleotide.

Zwitterionic character of nucleotides: possible significance in the evolution of nucleic acids

X-ray crystallography has shown that the free acids of adenosine 5'- and 3'-monophosphates and of cytidine 5'- and 3'-monophosphates exist as zwiterions in the solid state with protonation of the adenine base at the N(1) site and of the cytosine base at the corresponding site N(3) and the phosphate group negatively charged. In this paper, evidence is presented for the zwitterionic character of the free acids of the monomeric nucleotides guanosine 5'-monophosphate and inosine 5'-monophosphate with protonation of the base at the N(7) site of the imidazole moiety.

Why do nucleic acids have 3'5' phosphodiester bonds?

Details of the stereochemistry of the 2'5' and 3'5' dinucleoside monophosphates of polynucleotides have been delineated in aqueous solution using nuclear magnetic resonance spectroscopy. Incorporation of these experimentally determined geometries into the structure of polynucleotides reveals that the intrinsic spatial configurations of the 2'5' bonds cannot support helical structures whereas the geometries of 3'5' bonds allow the formation of helical configurations for RNA.

Structure of a dinucleoside phosphate--drug complex as model for nucleic acid--drug interaction

The crystal structure of a 3:2 complex of the frameshift mutagen proflavine with the dinucleoside phosphate cytidylyl-3'5'-guanosine has been determined. The complex has one drug molecule intercalated between Watson--Crick base pairs of the nucleotide duplex. The other two proflavine molecules are bound to the exterior of the miniature double helix. The orientation of the base pairs in this miniature double helix has aspects similar to that found in RNA 11.

Structure of poly 8-bromoadenylic acid; conformational studies by CPF energy calculations

Poly 8-bromoadenylic acid [poly(BBrA)] is the only known all-syn polynucleotide. It shows a helix-coil transition with a melting curve centred around 55 degrees C. Energy calculations based on classical potential functions have been used to explore the three-dimensional structure of this polymer in helix and random coil. It is concluded that the ordered state is a helix of two parallel strands with a two-fold rotation axis, and the duplex is stabilised by hydrogen bonds involving N1 and H6. Each strand has a conformation with C3' endo geometry, phi' = 216 degrees, omega' = 280 degrees, omega = 294 degrees, phi = 179 degrees, chi = 243 degrees and psi = 57 degrees. Such a conformation leads to approximately 8 nucleotide units per turn of the helix and an axial rise of 3.9A degrees. The structure of poly(8BrA) has been compared with that of the related polymer poly(A) which forms a double helical structure in acidic conditions with bases in the anti conformation and with interstrand hydrogen-bonds between N7 and H6. This is the first time that a specific geometrical model of a novel polynucleotide structure has been produced initially by potential energy calculations, though such calculations on a number of known structures have been reported previously.

RNA structure

This review is concerned primarily with the physical structure and changes in the structure of RNA molecules. It will be evident that we have not attempted comprehensive coverage of what amounts to a vast literature. We have tried to stay away from particular areas that have been recently reviewed elsewhere. Citations to and information from them are included, however, so that access to the literature is available. Much of what we treat in depth deals with the crystal structures and solution behaviour of model RNA compounds, including synthetic polymers and molecular fragments such as dinucleoside phosphates. Sequence data on natural RNA are cited, but not in detail. Similarly, apart from tRNA, natural RNAs the structural determinations of which are presently not so far advanced, are not dwelt upon. We have tried to present in detail the available structural data with scaled drawings that permit facile comparisons of molecular geometries.

Phosphorus-31 Fourier transform nuclear magnetic resonance study of mononucleotides and dinucleotides. 1. Chemical shifts

A phosphorus-31 nuclear magnetic resonance (NMR) study of adenine, uracil, and thymine mononucleotides, their cyclic analogues, and the corresponding dinucleotides is reported. From the pH dependence of phosphate chemical shifts, pKa values of 6.25-6.30 are found for all 5'-mononucleotides secondary phosphate ionization, independently from the nature of the base and the presence of a hydroxyl group at the 2' position. Conversely, substitution of a hydrogen atom for a 2'-OH lowers the pKa of 3'-monoribonucleotides from 6.25 down to 5.71-5.85. This indication of a strong influence of the 2'-hydroxyl group on the 3'-phosphate is confirmed by the existence of a 0.4 to 0.5 ppm downfield shift induced by the 2'-OH on the phosphate resonance of 3'-monoribonucleotides, and 3',5'-cyclic nucleotides and dinucleotides with respect to the deoxyribosyl analogues. Phosphate chemical shifts and titration curves are affected by the ionization and the type of the base. Typically, deviations from the theoretical Henderson-Hasselbalch plots are observed upon base titration. In addition, purine displays a more deshielding influence than pyrimidine on the phosphate groups of most of the mononucleotides (0.10 to 0.25 ppm downfield shift) with a reverse situation for dinucleotides. These effects together with the importance of stereochemical arrangement (furanose ring pucker, furanose-phosphate backbone conformation, O-P-O bond angle) on the phosphate chemical shifts are discussed.

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.