A proton magnetic resonance study of the interaction of adenylyl (3' is greater than 5') adenosine with polyuridylic acid

The interaction of adenylyl (3′ → 5′) adenosine (ApA) with polyuridylic acid in D₂O solution at neutral pD has been studied by high resolution proton magnetic, resonance spectroscopy. At temperatures above ～32°C, no evidence was obtained for the interaction of ApA with poly U. Below this temperature, a rigid triple-stranded complex involving a stoichiometry of 1 adenine to 2 uracil bases is formed, presumably via specific adenine–uracil base-pairing and cooperative base stacking of the adenine bases in a manner similar to that previously reported for the adenosine–poly U complex.     

Sequence and conformational effects on imino proton exchange in A.T- and A.U-containing DNA and RNA duplexes

¹H-nmr relaxation has been used to study the effect of sequence and conformation on imino proton exchange in adenine–thymine (A · T) and adenine–uracil (A · U) containing DNA and RNA duplexes. At low temperature, relaxation is caused by dipolar interactions between the imino and the adenine amino and AH2 protons, and at higher temperature, by exchange with the solvent protons. Although room temperature exchange rates vary between 3 and 12s^?1, the exchange activation energies (E_α) are insensitive to changes in the duplex sequence (alternating vs homopolymer duplexes), the conformation (B-form DNA vs A-form RNA), and the identity of the pyrimidine base (thymine vs uracil). The average value of the activation energy for the five duplexes studied, poly[d(A-T)], poly[d(A) · d(T)], poly[d(A-U)], Poly[d(A) · d(U)], and poly[r(A) · r(U)], was 16.8 ± 1.3 kcal/mol. In addition, we find that the average E_α for the A.T base pairs in a 43-base-pair restriction fragment is 16.4 ± 1.0 kcal/mol. This result is to be contrasted with the observation that the E_α of cytosine-containing duplexes depends on the sequence, conformation, and substituent groups on the purine and pyrimidine bases. Taken together, the data indicate that there is a common low-energy pathway for the escape of the thymine (uracil) imino protons from the double helix. The absolute values of the exchange rates in the simple sequence polymers are typically 3–10 times faster than in DNAs containing both A · T and G · C base pairs.     

The Structure of Triple Helical Poly(U)·Poly(A)·Poly(U) Studied by Raman Spectroscopy

Abstract

Using Raman spectroscopy, we examined the ribose-phosphate backbone conformation, the hydrogen bonding interactions, and the stacking of the bases of the poly(U)·poly(A) ·poly(U) triple helix. We compared the Raman spectra of poly(U)·poly(A)·poly(U) in H₂O and D₂O with those obtained for single-stranded poly(A) and poly(U) and for double-stranded poly(A)·poly(U). The presence of a Raman band at 863 cm^?1 indicated that the backbone conformations of the two poly(U) chains are different in the triple helix. The sugar conformation of the poly(U) chain held to the poly(A) by Watson-Crick base pairing is C3′ endo; that of the second poly(U) chain may be C2′ endo. Raman hypochromism of the bands associated with base vibrations demonstrated that uracil residues stack to the same extent in double helical poly(A)·poly(U) and in the triple-stranded structure. An increase in the Raman hypochromism of the bands associated with adenine bases indicated that the stacking of adenine residues is greater in the triple helix than in the double helical form. Our data further suggest that the environment of the carbonyls of the uracil residues is different for the different strands.     

Microbial Synthesis of Purine Arabinosides and Their Biological Activity

A simple method for the synthesis of various purine arabinosides from purine bases and uracil arabinoside by microbial transarabinosylation is described. A wet cell paste of Enterobacter aerogenes AJ 11125 showed a wide substrate specificity range for purine bases. Not only naturally occurring purine bases such as adenine and hypoxanthine but also unnatural bases such as 6-thioguanine and 2-chlorohypoxanthine were catalyzed to give the corresponding purine arabinosides. The enzymatically synthesized purine arabinosides were isolated from the reaction mixtures and identified by physicochemical means. The biological activities of the compounds were investigated and it was found that thioguanine arabinoside and 2-methyladenine arabinoside have potent activity against Hela cells, and their ED₅₀ were 10.5 and 21.5 μg/ml, respectively.     

NMR study of nitrogen-15-labeled Escherichia coli valine transfer RNA.

1,3-15N-Labeled uracil was synthesized chemically and used to prepare labeled Escherichia coli tRNA(Val) biosynthetically. 500-MHz measurements of 15N and proton chemical shift were obtained, for all uridine and uridine-related bases, by heteronuclear multiple-quantum coherence spectroscopy. All the uracil NH group resonances were assigned and were in agreement with previous proton-only assignments. The temperature dependence of intensities of resonances was used to infer the relative stability of parts of the molecule. The acceptor stem was the least thermally stable structural feature, while the anticodon and T loop were relatively more stable.     

Interaction of nucleic acids. VI. Interaction of purine with nucleic acids

The interaction of purine with DNA, tRNA, poly A, poly C, and poly A. poly U complex was investigated. In the presence of purine, the nucleic acids in coil form (such as denatured DNA, poly A and poly C in neutral solutions, or tRNA) have lower optical rotations. In addition, hydrodynamic studies indicate that in purine solutions the denatured DNA has a higher viscosity and a decreased sedimentation coefficient. These findings indicate that through interaction with purine, the bases along the poly-nucleotide chain are unstacked and are separated farther from each other, resulting in increased assymmetry (and possibly volume) of the whole polymer. Thus, the de-naturation effect of purine reported previously can be explained by this preferential interaction of purine with the bases of nucleic acids in coil form through a hydrophobic-costacking mechanism. Results from studies on optical rotation and helix-coil transition show that the interaction of purine is greater with poly A than with poly C. The influence of temperature, Mg⁺⁺ concentration, ionic strength, and purine concentration on the effect of purine on nucleic acid conformation has also been investigated. In all these situations the unraveling of nucleic acid conformation occurs at much lower temperatures (20–40°C lower) in the presence of purine (0.2–0.6M).     

1H-15N NMR studies of Escherichia coli tRNA(Phe) from hisT mutants: a structural role for pseudouridine

Escherichia coli tRNA(Phe)U39 was isolated from a specially constructed bacterial strain (DD1003/pRK3) carrying mutations in the hisT gene (the structural gene for tRNA pseudouridine synthase I) and in the pyrB gene (uracil auxotrophy). The pheU gene for tRNA(Phe) under control of the native tRNA promoter was on a multicopy plasmid and gave up to 40-fold overproduction of tRNA(Phe)U39. The double mutant permitted efficient incorporation of [3-15N]uracil, resulting in greater than 95% 15N enrichment of uracil-derived bases. 1H and 1H-15N NMR experiments were used to assign the low-field proton resonances to specific hydrogen-bonding interactions. 1H NMR assignments indicate that tRNA(Phe)U39 has a structure similar to that of native tRNA(Phe) except in the anticodon region where replacement of pseudouridine (psi) at position 39 with uridine (U) destabilizes hydrogen-bonding interactions at the base of the anticodon stem. We propose that U----psi modifications further stabilize interactions normally available to U by providing an additional locus for hydrogen bonding to the pyrimidine ring.     

Mammalian cell processing of a unique uracil residue in simian virus 40 DNA.

The processing of a unique uracil in DNA has been studied in mammalian cells. A synthetic oligodeoxyribonucleotide carrying a potential Bgl II restriction site, where one base has been substituted with a uracil, was inserted in the early intron of SV40 genome. Various heteroduplexes were constructed in such a manner that the restitution of an active Bgl II restriction site corresponds in each case to the specific substitution of the uracil by one of the four bases normally present in the DNA. DNA cuts by this restriction enzyme in one or several constructed heteroduplexes immediately determine the type of base pair substitution produced at the site of the U residue. When the uracil is inserted opposite a purine it is fully repaired; when facing a guanine it is replaced by a cytosine and opposite an adenine it is replaced by a thymine. These results indicate the error-free repair of uracil when it appears in the cell with the usual mechanisms such as cytosine deamination or incorporation of dUTP in place of dTTP during replication. When the uracil is inserted opposite a pyrimidine no error free repair at all is detected for U:C or U:T mismatches. It appears, moreover, that in approximately 18% of the cases U:T mismatch leads to a C:G base pairing. In the majority of the U:pyrimidine mismatches, mutations occur in the vicinity of the uracil, including base substitutions and frameshifts by addition of one or several bases.     

Three-stranded helix-coil equilibrium in polyuridylic acid-adenosine complex

Interaction of poly U (polyuridylic acid) and adenosine is studied by following the changes in ultraviolet absorbance in the wavelength region near the isochromic wave-length for the complex formation. The interaction is studied as a function of temperature, concentration of adenosine, and ionic strength, while the concentration of poly U was held constant. It is confirmed that only the three-stranded complex with the stoichiometry 1A to 2U is formed and that it dissociates directly into free poly U and adenosine. No discontinuity of any kind was apparent in the melting curves, and poly U was found to possess no ordered structure above 10°C under the conditions used. The results were, therefore, analyzed in terms of an exact helix–coil equilibrium theory using the mismatching model, i.e., assuming that either completely formed base triplet or completely free unbonded bases only exist, and that the two sections of the polymer chains forming closed loops need not contain the same number of unbonded bases. Self-association of free adenosine was taken into consideration. (Base triplet is analog of base pair for a three-stranded helical complex. It refers to a unit of three coplanar bases, in this case two uracils and one adenine, hydrogen bonded to one another to form a triplet. Such triplets may stack over one another along the helical axis, and when they are so stacked the bases of two triplets next to each other may have stacking interactions between them.) The values for enthalpy and entropy changes, both per mole of base triplets, were obtained for the following processes at neutral pH and moderate to high salt concentrations. (1) Growfh: Binding of one adenosine molecule to two uracil residues (one from each poly U strand) to form a base triplet next to an already formed base triplet with which it has stacking interactions, a process that involves both hydrogen bonding and base stacking interactions, ΔH_s, = ?19 ± 2 kcal, ΔS_s = ?55 ± 6 clausius; (2) Initiation: Binding of one adenosine molecule to two uracil residues (one from each poly U strand) to form an isolated base triplet, a process that involves only hydrogen bonding interactions, ΔH_b* = 4.5 ± 2 kcal, ΔS_b* = 6.6 ± 3 clausius; and (3)Interruption: Unstacking of two stacked base triplets initially next to each other by formation of an interruption (viz. a closed loop) between them, a process that involves only base stacking interactions, ΔH_b = 23.5 ± 3 kcal, ΔS_b = 61.6 ± 7 clausius, where the entropy changes include contributions other than the configurational entropy of closed loops. The discrepancy between our results and the calorimetric ΔH_s of ?13 kcal is attributed to (i) the possible effects of salt arid polymer on the self-association of free adenosine, (ii) the uncertainty in the value of the parameter for the probability of ring closure, and (iii) the contributions due to the partial molal enthalpy of the solvent and the unstacking of any poly U structure to the calorimetric enthalpy.     

Structure of Poly (U).poly (A).poly (U)

The molecular structure of poly (U).poly (A).poly (U) has been determined and refined using the continuous x-ray intensity data on layer lines in the diffraction pattern obtained from an oriented fiber of the RNA. The final R-value for the preferred structure is 0.24, far lower than that for the plausible alternatives. The polymer forms an 11-fold right-handed triple-helix of pitch 33.5A and each base triplet is stabilized by Crick-Watson-Hoogsteen hydrogen bonds. The ribose rings in the three strands have C3'-endo, C2'-endo and C2'-endo conformations, respectively. The helix derives additional stability through systematic interchain hydrogen bonds involving ribose hydroxyls and uracil bases. The relatively grooveless cylindrical shape of the triple-helix is consistent with the lack of lateral organization.     

Cleavage of the glycosidic linkage of pyrimidine ribonucleosides by the bisulfite-oxygen system

When a solution containing 2 mM uridine, 20 mM sodium bisulfite, 0.1 mM MnCl₂, and 100 mM sodium phosphate buffer of pH 7.0 was incubated aerobically at 37° or 0°, partial cleavage of the glycosidic linkage of uridine took place. About 20% of the uridine was converted to uracil by the incubation for 4 hrs. Cytosine was produced from cytidine by similar treatment with bisulfite. These reactions were caused by free radicals generated by Mn²⁺-catalyzed autoxidation of bisulfite. Glycosidic bond cleavage by the bisulfite-oxygen system was not detected for adenosine, AMP, guanosine, GMP, thymidine, TMP, deoxyuridine, dCMP, dAMP, and dGMP. When poly(U) and poly(C) were treated with 20 mM sodium bisulfite in the same manner, chain fission of the polymer occurred as judged by the elution-pattern change in gel filtration through Sephadex columns. No change in the elution pattern was observed for bisulfite-treated poly(A), poly(U)· poly(A) or tRNA.     

Secondary structure in polyuridylic acid: Non-classical hydrogen bonding and the function of the ribose 2′-hydroxyl group

The role of non-classical hydrogen bonding in RNA structure has been investigated using polyuridylic acid, which has a labile ordered structure at temperatures near 0 °C, as a model system. By comparing the proton nuclear magnetic resonance spectrum of poly(U) in the transition region with that of uridine and the dimer UpU we find evidence that both the imino N(₃)-H and the ribosyl 2′-OH protons are hydrogen bonded. The characteristics of the former are consistent with participation in N(₃)-HOC bonding primarily between residues in the same strand. As yet we cannot unambiguously assign the acceptor for the 2′-OH in ordered poly(U): because of its apparent stability and the acceptable stereochemistry, we presently favor a bond between ribose 2′-OH and O(1′) connecting adjacent nucleotides of the same strand. This arrangement could contribute to the co-operativity of the poly(U) helix formation. The recently proposed 2′-OHO(1′) interactions in crystalline yeast transfer RNA^Phe suggest similar interactions might play a role in the conformational stability of natural RNAs. A second conformational transition below the major transition in the ultraviolet can be detected in poly(U) by monitoring the H(₆) proton of uracil.     

Microbiological assay of purines

A sensitive microbiological assay for purine bases and derivatives is described which depends on purine-limited incorporation of [³H]uracil into E. coli double auxotrophs for uracil and specific bases.     

Purine and pyrimidine metabolism in cultured white spruce (Picea glauca) cells: Metabolic fate of 14C-labeled precursors and activity of key enzymes

In order to examine the biosynthesis, interconversion, and degradation of purine and pyrimidine nucleotides in white spruce cells, radiolabeled adenine, adenosine, inosine, uracil, uridine, and orotic acid were supplied exogenously to the cells and the overall metabolism of these compounds was monitored. [8‐¹⁴C]adenine and [8‐¹⁴C]adenosine were metabolized to adenylates and part of the adenylates were converted to guanylates and incorporated into both adenine and guanine bases of nucleic acids. A small amount of [8‐¹⁴C]inosine was converted into nucleotides and incorporated into both adenine and guanine bases of nucleic acids. High adenosine kinase and adenine phosphoribosyltransferase activities in the extract suggested that adenosine and adenine were converted to AMP by these enzymes. No adenosine nucleosidase activity was detected. Inosine was apparently converted to AMP by inosine kinase and/or a non‐specific nucleoside phosphotransferase. The radioactivity of [8‐¹⁴C]adenosine, [8‐¹⁴C]adenine, and [8‐¹⁴C]inosine was also detected in ureide, especially allantoic acid, and CO₂. Among these 3 precursors, the radioactivity from [8‐¹⁴C]inosine was predominantly incorporated into CO₂. These results suggest the operation of a conventional degradation pathway. Both [2‐¹⁴C]uracil and [2‐¹⁴C]uridine were converted to uridine nucleotides and incorporated into uracil and cytosine bases of nucleic acids. The salvage enzymes, uridine kinase and uracil phosphoribosyltransferase, were detected in white spruce extracts. [6‐¹⁴C]orotic acid, an intermediate of the de novo pyrimidine biosynthesis, was efficiently converted into uridine nucleotides and also incorporated into uracil and cytosine bases of nucleic acids. High activity of orotate phosphoribosyltransferase was observed in the extracts. A large proportion of radioactivity from [2‐¹⁴C]uracil was recovered as CO₂ and β‐ureidopropionate. Thus, a reductive pathway of uracil degradation is functional in these cells. Therefore, white spruce cells in culture demonstrate both the de novo and salvage pathways of purine and pyrimidine metabolism, as well as some degradation of the substrates into CO₂.     

Mechanism of Purine Arabinoside Synthesis by Bacterial Transarabinosylation Reaction

The mechanism of purine arabinoside synthesis from uracil arabinoside and purine bases via the bacterial transarabinosylation reaction was investigated. Arabinose-1-phosphate was isolated from the reaction mixture in the form of the barium salt and proved to be the intermediate of the reaction. Two enzyme fractions were obtained from Enterobacter aerogenes by means of heat treatment, ammonium sulfate fractionation and DEAE-cellulose column chromatography. One enzyme split uracil arabinoside into uracil and arabinose-1-phosphate in the presence of inorganic phosphate and the other synthesized hypoxanthine arabinoside from arabinose-1-phosphate and hypoxanthine. The substrate specificity of these enzymes indicated that the former was uridine phosphorylase and the latter was purine nucleoside phosphorylase, respectively. Hypoxanthine arabinoside was synthesized from uracil arabinoside and hypoxanthine only in the presence of both enzymes and inorganic phosphate.     

The alternating conformation of analogues of poly[d(AT)].

Synthetic DNAs were prepared containing 6-methyl adenine (m6A) in place of adenine and 5-ethyl uracil (Et5U) or 5-methoxymethyl uracil (Mm5U) in place of thymine. All three modifications destabilized duplex DNAs to varying degrees. The binding of ethidium was studied to analogues of poly[d(AT)]. There was no evidence of cooperative binding and the "neighbour exclusion rule" was obeyed in all cases although the binding constant to poly[d(m6AT)] was approximately 6 fold higher than to poly[d(AT)]. 31P NMR spectra were recorded in increasing concentrations of CsF. Poly[d(AEt5U)] showed two well-resolved signals separated by 0.55 ppm in 1 M CsF compared to 0.32 ppm for poly[d(AT)] under identical conditions. In contrast, poly[d(AMm5U)] and poly[d(m6AT)] showed two signals separated by 0.28 ppm and 0.15 ppm respectively, only when the concentration of CsF was raised to 2 M. The signals for poly[d(AT)] in 2 M CsF were better resolved and were separated by 0.41 ppm. These results suggest that minor modifications to the bases may have conformational effects which could be recognized by DNA-binding proteins.     

Nearest-neighbor and next-nearest-neighbor effects in the proton NMR spectra of the oligoribonucleotides ApGpX and CpApX

The variable-temperature proton nmr spectra of the oligoribonucleotides in the series CpApX and the series ApGpX, X = A, G, C, U, together with the parent dimers CpA and ApG have been measured. A complete analysis of all the nonexchangeable base proton resonances and ribose H-1′ proton resonances was made. The presence of trends in the shielding abilities of the various bases at both the nearest-neighbor and next-nearest-neighbor positions were identified. The observed shieldings could be used to predict the chemical shifts of protons in related systems. Based on the empirical results from ribodinucleoside monophosphates, the temperature-dependent behavior of the J_1′2′ coupling constants of the triribonucleotides suggested that the compounds in the CpApX series stacked from the 5′-end to the 3′-end, while those in the ApGpX series stacked from the 3′-end to the 5′-end.     

The structure of triple helical poly(U).poly(A).poly(U) studied by Raman spectroscopy

Using Raman spectroscopy, we examined the ribose-phosphate backbone conformation, the hydrogen bonding interactions, and the stacking of the bases of the poly(U).poly(A).poly(U) triple helix. We compared the Raman spectra of poly(U).poly(A).poly(U) in H2O and D2O with those obtained for single-stranded poly(A) and poly(U) and for double-stranded poly(A).poly(U). The presence of a Raman band at 863 cm-1 indicated that the backbone conformations of the two poly(U) chains are different in the triple helix. The sugar conformation of the poly(U) chain held to the poly(A) by Watson-Crick base pairing is C3' endo; that of the second poly(U) chain may be C2' endo. Raman hypochromism of the bands associated with base vibrations demonstrated that uracil residues stack to the same extent in double helical poly(A).poly(U) and in the triple-stranded structure. An increase in the Raman hypochromism of the bands associated with adenine bases indicated that the stacking of adenine residues is greater in the triple helix than in the double helical form. Our data further suggest that the environment of the carbonyls of the uracil residues is different for the different strands.     

The effects of thioketo substitution upon uracil-adenine interactions in polyribonucleotides. Synthesis and properties of the alternating polynucleotides poly(r(A-s2U)) and poly(r(A-s2s4U)).

The polynucleotides poly[r(A-s-2U)] and poly]r(A-s2s4U)] have been synthesized and characterized by nearest-neighbour analysis, sedimentation analysis as well as spectroscopic techniques. Absorption-temperature profile and absorption-pH profile of poly[r(A-s-2U)] did not reveal a structural transition between 10 and 95 degrees C even at low ionic strength, although a variety of properties indicated a helical structure of poly[r(A-s-2U)]: remarkable hyperchromicity of the absorption spectrum, circular dichroic spectrum displaying extrema of large amplitudes, resistance against hydrolysis by ribonuclease and interaction with ethidium bromide in a manner which is characteristic of helical polynucleotides. Our results show that interactions of the type A-s-2U and A-s-2s-4U do in fact exist in helical polynucleotides. The properties of poly]r(As-2U)] furthermore demonstrate the general stabilizing effect of 2-thioketopyrimidine bases in helical polynucleotides by virtue of vertical stacking interactions with neighbouring pyrimiding and purine bases.     

Biphasic helix–coil transition of the ethidium bromide·poly(dA-dT) and the propidium diiodide·poly(dA-dT) Complexes. Stabilization of base-pair regions centered about the intercalation site

The nonexchangeable base and sugar proton nmr resonances and the 260 and 278-nm uv-absorbance bands of the nucleic acid were utilized to monitor the temperature-dependent duplex-to-strand transition of the alternating purine–pyrimidine deoxyribopolynucleotide poly(dA-dT) in the absence and presence of ethidium bromide (EB) at phosphate/drug = 50, 28, and 15 and propidium diiodide (PI) at P/D = 50, 25, 15, 10, and 5 in 0.1 M salt between 50° and 100°C. The nmr and optical methods monitor a biphasic duplex-to strand transition for the drug–poly(dA-dT) complexes. We have monitored the dissociation of the drug from the complex at the ethidium bromide phenanthridine ring and side-chain proton nmr resonances and the propidium diiodide 494 and 535-nm uv-absorbance bands and demonstrate that dissociation of the drug corresponds to the higher temperature transition in the biphasic nucleic acid melting curves. The lower temperature cooperative transition is assigned to the opening of drug-free AT base-pair regions in the drug–poly(dA-dT) complex and exhibits an increase in transition midpoint and a decrease in cooperativity with increasing drug concentration. The higher temperature cooperative transition is assigned to the opening of AT base-pair regions centered about the bound drug in the complex and exhibits an increase in the transition midpoint on raising the drug concentration. The large upfield shifts of the phenanthridine ring (but not side chain) protons of ethidium bromide on complex formation demonstrate intercalation of the drug between base pairs of the poly(dA-dT) duplex. The nucleic acid base and sugar resonances of poly(dA-dT) in 0.1 M phosphate undergo chemical shift changes between 0° and 50°C indicative of premelting conformational transition(s).