Sequence and structure in double-stranded ribonucleic acid: (A-G-C-U)2 and (A-C-G-U)2

Comparative studies of the thermally induced helix--coil transition in ribosyl (A-G-C-U)2 and (A-C-G-U)2 are described. Ordered structures form at low temperatures where the ribofuranose rings adopt the 3'-endo conformation and both oligomer helices have base-paired stacking arrangements qualitatively similar to the A-RNA family configuration. Especially for (A-C-G-U)2, there is a lack of quantitative agreement between the A-family base overlap and the 1H NMR data; ring-current and atomic diamagnetic anisotropies using A-form structures fail to predict five of the seven aromatic C--H resonances within 0.2 ppm. The NMR results are in better agreement with the A form for (A-G-C-U)2. For both oligomers, the changes in chemical shift for the anomeric (H1') resonances indicate substantial (greater than or equal to 20 degrees) changes in the average glycosidic torsion angle upon base pairing and stacking for the adenosine and cytidine residues; this angle in uridine and guanosine residues must change only slightly.

Synthesis of oligoguanylates on oligocytidylate templates

Short oligocytidylates can act as templates for the self-condensation of guanosine 5'-phosphorimidazolide. In the absence of a catalytic metal ion or in the presence of Pb2+ a noticeable template effect is already observed with the dimer and the yield of long oligomers reaches a plateau with a hexamer template. Short templates give oligomers longer than the template length. The products are predominantly 2'-5' linked for the Pb2+-catalyzed reaction while mixed linkages are observed in the uncatalyzed reaction. In the presence of Zn2+, a template effect is first observed with the pentamer and is maximal by the heptamer. The products are predominantly 3'-5' linked. Oligomers shorter than or as long as the template are obtained in substantial yield, and longer products in much lower yields.

Comparative study of ribonucleotide, deoxyribonucleotide, and hybrid oligonucleotide helices by nuclear magnetic resonance

The nonexchangeable base protons and the hydrogen-bonding NH--N imino protons were used to study the conformations and the helix--coil transitions in the following oligonucleotides: (I) dCT5G + dCA5G, (II) rCU5G + rCA5G, (III) dCT5 G + rCA5G, (IV) rCU5G + dCA5G. The first three mixtures all form stable double-helical structures at 5 degrees C, whereas IV forms a triple strand with an rCU5G:dCA5G 2:1 ratio. The chemical shifts of the imino protons in the double strands indicate that I, II, and III have different conformations in solution. For example, the hydrogen-bonded proton of one of the C.G base pairs is more deshielded (a 0.4-ppm downfield shift) in helix I than in helix II or III. This implies a significant change in helical parameters, such as the winding angle, the distance between base pairs, or overlap of the bases. The coupling constants of the H1' sugar protons show that helix I has 90% 2'-endo sugar conformation, whereas helix III has greater than 85% 3'-endo conformation for the observed sugar rings. The sugar pucker data are consistent with helix I having B-family geometry; III has A-family geometry. The chemical shifts of the nonexchangeable base protons in system I were followed with increasing temperature. The midpoints for the transitions, Tm's, for all the base protons were 28--30 degrees C; this indicates an all-or-none transition.

Rapid cataloging of ribonuclease T1 resistant oligonucleotides from ribosomal RNAs for phylogenetic studies

A rapid and simple method of oligonucleotide cataloging for phylogenetic studies is presented. It involves in vitro 5'-32P-labelling of RNase T1 - resistant oligonucleotides of ribosomal 16S RNA and finger-printing by high voltage electrophoresis and gradient thinlayer chromatography. Oligonucleotide sequences are established by the mobility shift method, using controlled alkali cleavage, high voltage electrophoresis and homochromatography. These procedures facilitate in particular the analysis of long RNase T1 - resistant oligonucleotides. Oligonucleotide catalogs are established fo three Actinomycetes, namely Oerskovia turbata, Actinoplanes philippinensis and Ampullariella regularis. These catalogs are equivalent to those obtained by methods which were described by Sanger and Woese.

Terminal uridylyl transferase of Vigna unguiculata: purification and characterization of an enzyme catalyzing the addition of a single UMP residue to the 3'-end of an RNA primer

An enzyme which catalyzes the addition of a single UMP residue from UTP to the 3'-end of an RNA primer and which is referred to as terminal uridylyl transferase (TUT) has been extensively purified from the membrane fraction of vigna unguiculata leaves. The purification procedure involved (i) solubilization by cation depletion (ii) DEAE-Sepharose CL-6B column chromatography (iii) affinity chromatography of poly(U)-Sepharose 4B and (iv) glycerol gradient centrifugation. The molecular weight of the native enzyme was approximately 50,000 as determined by velocity sedimentation. Under conditions that were optimal for UMP-incorporation (5 mM Mg2+, low salt, 30 degrees C) TUT displayed a marked specificity for UTP as substrate, was unable to incorporate deoxyribonucleoside triphosphates and required a single-stranded oligo- or polyribonucleotide as primer. When oligoA20, tRNAasp of E. coli or alfalfa mosaic virus RNA 4 were used as primers at various substrate to primer ratio's, the vast majority of the product appeared to consist of primer molecules elongated with a single UMP residue as shown by polyacrylamide gelelectrophoresis and nearest neighbour analysis. We believe TUT to be a novel enzyme which has not been reported before and which may be a feasible tool in RNA sequencing as it enables the specific 3'-terminal labeling of RNA molecules.

Unusual structures in single-stranded ribonucleic acid: proton nuclear magnetic resonance of AUCCA in deuterium oxide

Conformational features of the oligoribonucleic acid (oligo-RNA) A1-U2-C3-C4-A5 are explored by proton nuclear magnetic resonance (NMR). The sequence is a molecular cognate of a portion of the T psi C loop and stem regions of yeast tRNAPhe. The molecule forms at least two classes of flexible yet ordered structures. Class I states are similar in spectral properties to the component oligomers, AU, AUC, and AUCC, and are likely to be standard right-helical structures. Class II states are characterized by a 2'-endo pucker at A1 and unusually large shielding of several C3 and U2 protons. Most of these features are consistent with identifying the class II solution structures with the "arch" conformation for the T psi C region determined by X-ray crystallography of yeast tRNAPhe.

Molecular mechanical studies of proflavine and acridine orange intercalation

Previous workers have reported that proflavine and acridine orange form various structurally different complexes with the dinucleoside phosphates rCpG and dCpG, with uniform C3'-endo and mixed C3'-endo (3'-5') C2'-endo sugar puckers being observed. We present theoretical calculations, based on the method of molecular mechanics, which support the experimental observations. The results suggest that the mixed C3'-edo (3'-5') C2'-endo pucker conformation isi intrinsically more stable than the uniform C3'-endo conformation, but that the additional stabilisation gained from specific, hydrogen bonding, interactions between nucleic acid and solvent, or intramolecularly within the nucleic acid, can lead to the adoption of the latter conformation, or of variants between the two. The role played by hydrogen bonding between amino-groups and nucleic acid phosphate appears more subtle than previously supposed.

Conformational analysis of a modified ribotetranucleoside triphosphate: m6(2)A-U-m6(2)A-U studied in aqueous solution by nuclear magnetic resonance at 500 MHz

The complete and unequivocal assignment of the 24 ribose proton signals of m6(2)A(1)-U(2)-m6(2)(3)-U(4) by means of 500 MHz NMR spectroscopy at 17 degrees C is given. this assignment is based on scrupulous decoupling experiments carries out at various temperatures. Analysis of the observed chemical shifts and coupling constants of the tetramer shows that the two fragments -m6(2)A(3)-U(4) comprising the 3'-end occur mainly in the classical right-handed stack conformation, whereas the 5'-end the -U(2)- residue appears bulged out in favour of a less well-defined stacking interaction between the bases m6(2)A(1)-and -m6(2)A(3)-. Conformational populations about each of the torsional degrees of freedom along the backbone are discussed. A modernized version of pseudorotation analysis is used to delineate the conformational behaviour of the four ribose rings.

Early steps in the path of nascent ribonucleic acid across the surface of ribonucleic acid polymerase, determined by photoaffinity labeling

The photoaffinity probes beta-(4-azidophenyl) adenosine 5'-diphosphate (N3PhppA) and beta-(4-azidophenyl) adenylyl-(3'--5')-uridine 5'-diphosphate (N3PhppApU) were used to determine the RNA polymerase subunit contacts made by the 5' ends of three nascent RNA chains. Ternary enzyme-poly[d(A-T)].oligonucleotide complexes were prepared in which the nascent oligonucleotide contained a photoaffinity label at the 5' end and a 32P radiolabel only at the 3' end. The length of the RNA was fixed at two, three, or four nucleotides. Photolysis of the ternary complexes was followed by dissociation, polyacrylamide gel electrophoresis, autoradiography, and scintillation counting. With a dinucleotide probe, the enzyme subunits labeled were beta' (71%) and sigma (21%). Photolysis of the ternary complex containing trinucleotide RNA also resulted in labeling of the beta' (64%) and sigma (35%) subunits. With a tetranucleotide, the beta' subunit was very heavily labeled (88%), and a small amount of labeling of the beta (7%) and sigma (4%) subunits was observed. The alpha subunit was not labeled with any of the probes. These results imply that a conformational change, possibly involving dissociation of the sigma subunit, occurs in the enzyme as the ribonucleotide is elongated from a tri- to a tetranucleotide.

A general method for detection and characterization of an mRNA using an oligonucleotide probe

A general method for the detection and characterization of an mRNA using an oligodeoxynucleotide probe is described. The results presented indicate that a G-dT or a dG-U base pair within a short DNA-RNA hybrid does not significantly reduce the stability of the hybrid. On this basis, we propose that 11 amino acids, including Trp and Met, can be used in selecting a peptide sequence suitable for use in designing an oligodeoxynucleotide probe complementary to a given mRNA. To test this hypothesis, we have synthesized an oligodeoxynucleotide (oligo II) complementary to the region of gastrin mRNA coding for Trp-Met-Asp-Phe and have compared its effectiveness as a hybridization probe and as a primer for the synthesis of gastrin-specific cDNA with another oligonucleotide (oligo I) complementary to the region of gastrin mRNA coding for Trp-Met-Glu-Glu. Unlike oligo I, oligo II functions as a primer in specific cDNA synthesis only when the mRNA is denatured prior to initiation of synthesis. Similarly, oligo II can be used as a specific hybridization probe for gastrin mRNA only when the RNA is denatured and partially cleaved with NaOH before hybridization. A simple procedure for denaturing gastrin mRNA to ensure efficient interaction with oligodeoxynucleotide probes is described. This procedure should be useful in studies with other oligonucleotides and mRNAs as well.

Nucleotide sequences of wheat-embryo cytosol 5-S and 5.8-S ribosomal ribonucleic acids

The nucleotide sequences of wheat embryo 5.8-S and 5-S rRNAs have been determined with the use of several techniques, including classic analysis of oligonucleotides generated by ribonuclease T1 and resolution on gels of terminally labelled RNA partially degraded with ribonucleases or with chemical reagents. The sequence of wheat embryo 5.8-S rRNA was found to be (formula: see text). This sequence is compared to 5-S rRNA sequences previously published for wheat and several other angiosperms.

Oligo(U)- and poly(U)-containing RNA of wheat embryo

A UMP-rich RNA fraction was separated from the bulk cellular RNA by affinity chromatography of wheat embryo total RNA. The obtained preparation was heterogeneous and contained polyribonucleotide chain segments which were resistant to RNAase T1 and consisted mainly of UMP residues (87 mol%). The UMP-rich segments were of various sizes, including large oligonucleotides and polynucleotides (up to approx. 150 nucleotides in length). The oligo(U)- and poly(U)-containing RNA fraction occurred in a low amount (approx. 1% of total RNA) both in dry and germinating wheat embryos. However, at the onset of germination, labelled precursors were preferentially incorporated into the UMP-rich RNA species. The early-synthesized RNA appeared and underwent a considerable degradation within the cell nuclei. It is assumed that both delayed maturation of structural gene transcripts and rapid transcription of regulatory gene units during initial germination stages contribute to the transient abundance of newly made UMP-rich RNA in the early wheat embryos.

The ribosome binding sites recognized by E. coli ribosomes have regions with signal character in both the leader and protein coding segments

Oligonucleotide analysis, by a novel computerized procedure, was first applied to determine the sequence of an ideal E. coli promoter (Scherer et al., Nucl. Acids Res. 1978, 5:3759-3773) and has now been used to obtain the sequence of nucleotides that should be present in a messenger RNA for optimum binding to the E. coli ribosome. This sequence is: UU.UUAAAAAUUAAGGAGGUAUAUUAUGAAAAAAAUUAAAAAACUCAA AA U A AUA A CUC G. Comparison of this sequence with each of the 68 ribosome binding site sequences used to generate it shows a preference rather than an absolute requirement for a specific base in any given position. The preference for certain bases persists along the whole length of the RNA within the ribosome binding domain even though nearly half of that length includes translated codons. Thus messages without leader sequences (like lambda CI mRNA) can still have some affinity for the ribosome. Part of the model sequence is complementary to the 3'end of 16S rRNA.

[Affinity labeling of ribosomes from Escherichia coli with 4-(N-2-chloroethyl, N-methylamino)-benzaldehyde actyl derivatives of oligouridylates]

4-(N-2-chloroethyl-N-methylamino)-benzaldehyde acetyl derivatives of penta-., hexa, hepta-, octauridylates were used for localization of the structures organizing the mRNA-binding centre of ribosomes. These derivatives, alike free oligonucleotides, stimulate the binding of phenylalanyl-tRNA to ribosomes. Within the specific complex all the oligonucleotide derivatives alkylated the 30S ribosomal subunit. Octauridylate and hexauridylate derivatives specifically alkylated also the 50S subunit of ribosomes. Polyuridylic acid protected ribosomal subunits from alkylation. In the 30S subunit the derivatives modify 16S RNA and proteins: S4, S5, S7, S9, S13, S15, S18, S21. It was found that oligouridylate derivatives of different length alkylate different proteins.

Nucleotide sequence of the simian virus 40 HindII + III restriction fragment I (fourth part of the T antigen gene)

The HindII + III restriction fragment I (Hind-I) from simian virus 40 DNA represents 4.96% of the genome and maps in the early transcription region. Hind-I is an internal segment of the A gene and its information is expressed as part of the early 19-S mRNA, which codes for T antigen. We report here the nucleotide sequence of the 259-base-pair Hind-I fragment. The sequence was determined and confirmed by RNA and DNA sequencing methods: by analysis of oligonucleotides resulting from T1 and pancreatic RNase digestion of labeled RNA transcribed from SV40 DNA with Escherichia coli DNA-dependent RNA polymerase, by partial degradation of RNA transcripts with snake venom phosphodiesterase, and by base-specific chemical degradation of 5'-end-labeled subfragments of Hind-I according to the procedure of Maxam and Gilbert. Multiple triplets corresponding to termination codons occur in two of the three reading frames of the DNA strand that has the same polarity as early mRNA. The open reading frame connects in phase with the one of the Hind fragments flanking Hind-I, and the amino acid sequence specified by Hind-I lies in the middle part of the large-T antigen. Some features of the primary nucleotide sequence and of early transcription are discussed.

Purification and characterization of a Saccharomyces cerevisiae exoribonuclease which yields 5'-mononucleotides by a 5' leads to 3' mode of hydrolysis

An exoribonuclease producing 5'-mononucleotides has been purified from ribosomes of Saccharomyces cerevisiae. The enzyme has a broad pH optimum around 8.0, requires divalent cation, and is stimulated by monovalent cation with the cation and degree of stimulation being dependent on the substrate used. With either poly(A) or rRNA as substrate, the enzyme has a processive mode of hydrolysis. The oligonucleotides, (pA)3-5, are hydrolyzed by the enzyme, and the hydrolysis is dependent on a 5'-phosphate end group. Phosphorylation of the 3' end has little effect on the rate of hydrolysis. With [3H]poly(A) or [3H]rRNA, labeled differentially at the 5' termini, a more rapid release of 5'-terminal label can be shown, providing evidence that the enzyme hydrolyzes in a 5' leads to 3' direction. Further evidence for a 5' leads to 3' mode of hydrolysis is provided by a study of the products of the hydrolysis of [3H](pA)5 labeled at the 5' termini with 32P. No 32P label is found in (pA)2 which accumulates as an intermediate.

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.

Stable RNA-DNA-RNA polymerase complexes can accompany formation of a single phosphodiester bond

Incubation of RNA polymerase with poly[d(A-T)n] template results in a binary enzyme-DNA complex. Further addition of the dinucleotide UpA and [alpha-32P]UTP results in catalytic formation of the labeled trinucleotide UpApU until substrate exhaustion. In contrast, incubation of binary enzyme-DNA complexes with ApU and [alpha-32P]ATP results in labeled ApUpA formation to an extent that is stoichiometric with the amount of enzyme present despite an excess of substrates. The occurrence of ApUpA in a stable DNA-enzyme-RNA ternary complex is shown by gel exclusion chromatography, Millipore filtration, and the ability of ternary complexes to support subsequent RNA chain elongation. Radioactivity is not bound to Millipore filters when purified, labeled ApUpA is added to enzyme-DNA binary complexes. Hence, phosphodiester bond formation is required for stable ternary complex formation. The absence of the delta subunit of RNA polymerase or the addition of rifampicin to the reaction before ribonucleotide substrates results in catalytic ApUpA formation instead of stable ternary complexes.

Effect of ultraviolet irradiation on 30-S ribosomal subunits. Identification of the RNA region crosslinked to protein S7

The effects of ultraviolet irradiation on Escherichia coli 30-S ribosomal subunits were studied. At the doses of radiation used in this work (0-4.5 x 10(5) quanta/30-S subunit), only protein S7 was found to be significantly crosslinked to the 16-S RNA. In conditions where 25% of the protein was covalently crosslinked, the ability of the irradiated 30-S subunits to reassociate with 50-S subunits and their activity in polyphenylalanine synthesis decreased strongly. Similar results were obtained by irradiation with a germicide lamp (254 nm) or with a monochromatic ultraviolet light at 248 nm. No additional proteins were crosslinked to the 16-S RNA by irradiating 30-S subunits depleted in protein S1 or 70-S ribosomes. The covalent complex of 16-S RNA and protein S7 was isolated and digested by T1 ribonuclease. The oligonucleotide remaining attached to the crosslinked protein was characterised as A-C-C-U-C-G [position 1261 - 1266, see the sequence published by Carbon et al. (1979) Eur. J. Biochem. 160, 399-410]. Analysis of this fragment suggests that protein S7 was linked to the cytosine at position 1265 in the RNA sequence.

Studies on interactions between immobilized lysine residues and oligomers of thymidylic and deoxyadenylic acids

Two groups of crosslinked polyacrylic gels with immobilized lysine and lysine peptides (Lys)5 and (Lys)5-Pro have been used as models for the chromatographic investigation of lysine-peptide-oligonucleotide interactions. One group carries carboxylic groups in addition to the peptide residues in the gel matrix; the other gel type contains no such carboxylic groups in the gel matrix. Nucleotides of the series (dT)2-5, p(dT)1-4, p(dT)1-4p, (dA)2-5, p(dA)1-5 and p(dA)1-4p were chromatographed on these gels under various conditions in an aqueous buffer. On the gels of the first group the nucleotides were retarded only slightly, the positive charges of the epsilon-amino groups being compensated partially or totally by the negatively charged carboxyl groups of the polymer matrix. On the gels of the second group, however, the oligonucleotides underwent specific interactions. These interactions were based primarily upon electrostatic forces between the positively charged epsilon-amino groups of the immobilized peptides and the negatively charged phosphate groups of the oligonucleotides. Our results indicate that, in addition to the electrostatic interaction, the conformation plays a crucial role. We explain the selectivity of the interaction with a conformation-fit mechanism. The origin of this mechanism, which creates specific interactions from unspecific forces, is discussed.

In vitro 32P-labelling of viroid RNA for hybridization studies

A method is described for the in vitro labelling of viroid RNA for use in hybridization studies. The citrus exocortis viroid (approximately 350 nucleotides) is degraded by hot formamide hydrolysis to fragments ranging from small oligonucleotides to near full lengths, and subsequently labelled to high specific activity by enzymatically attaching 32P to the 5'-end of each molecule. The cleavage step leaves 5' hydroxyl groups which allows the polynucleotide kinase to directly label the RNA fragments without prior enzymatic dephosphorylation. The method is simple, requires no special equipment, and provides a radioactive RNA probe sufficient for most types of hybridization studies.

Analysis of large specific T1 oligonucleotides of 17S and 25S ribosomal RNAs from Saccharomyces cerevisiae

The primary structure of 17S and 25S ribosomal RNAs from Saccharomyces cerevisiae has been analysed by two-dimensional fractionation of T1 oligonucleotides. This method consists of an electrophoresis at pH 3.5 followed by a homochromatography on DEAE-cellulose plates. After the second dimension, the large T1 oligonucleotides were hydrolyzed by pancreatic RNAse, followed by alkaline hydrolysis of the pancreatic products. By fractionating a mixture of tritiated HeLa cell ribosomal RNAs and 32 P yeast cell ribosomal RNAs, two autoradiographs were obtained; one corresponding to the 32P labelled material and the other to the tritiated labelled material. By superposition of the two autoradiographs, the mobility of the various T1 oligonucleotides can be accurately compared and it is shown that yeast 17S rRNA and human 18S rRNA have in common 5 large oligonucleotides and that yeast 25S rRNA and human 28S rRNA have 4 identical oligonucleotides.

Conformations of dinucleoside phosphates in aqueous solution

The conformations of dinucleoside phosphates have been reexamined by semiempirical potential energy calculations. Conformations I, II, and III, proposed by Lee & Tinoco [Lee, C. H., & Tinoco, I., Jr. (1977) Biochemistry 16, 5403], are possible species after refinement of their structures by potential energy minimization. These three conformers can represent three types of dinucleoside phosphate species in solution. Dhingra et al. [Dhingra, M. M., Sarma, R. H., Giessner-Prettre, C., & Pullman, B. (1978) Biochemistry 17, 5815] had concluded that conformations of type II and III were unlikely or impossible. They favored conformations g-g- (equivalent to I), g+g+,g+t, and tg+; the last three conformations have little stacking and are calculated to be energetically less favorable by more than 5 kcal/mol. Common structures of the types I, II, and III are found for dinucleoside phosphates with different purine-pyrimidine sequences. The sequence dependence of the potential energy of these three conformers has been calculated. The experimental nuclear magnetic resonance data of dinucleoside phosphates are consistent with these three conformations.

Thermal perturbation differential spectra of ribonucleic acids. II. Nearest neighbour interactions

Dinucleoside monophosphates are used here as models for studying sequence dependence of the hypochromic effect correlated with base stacking. It was shown that once the contribution due to the temperature dependent hydration change of the bases is substracted from the thermal perturbation difference spectra of dinucleoside monophosphates, the absorbance change of the dimer only due to unstacking of the bases could be obtained. In order to be able to use these corrected thermal perturbation difference spectra as models for studying nearest neighbour interactions in nucleic acids, it was necessary to normalize them to 100% unstacking of the bases. To perform this normalization, apparent thermodynamic parameters were extracted from the corrected transition curves by means of the two-state model.

Thermal perturbation differential spectra of ribonucleic acids. I. Hydration effects

A relatively important change in UV absorption is observed upon thermal perturbation of nucleotide solutions. Comparison of these thermal perturbation spectra of nucleic acid residues with solvent perturbation spectra of the same compounds suggests that this spectral change can most probably be attributed to temperature induced hydration change of the bases. This conclusion is confirmed by the results obtained from acid-base perturbation spectra of these nucleotides as well as thermal perturbation spectra of nucleotides containing modified bases. It is shown that this temperature dependent change in UV absorption is also present in dinucleoside monophosphates. In that case, this effect is superimposed upon the well known change in absorbance due to the unstacking of the bases during heating.

Self-condensation of activated dinucleotides on polynucleotide templates with alternating sequences

We have prepared substantial quantities of the alternating polymers poly(U-G) and poly(C-A) and have used them as templates for the self-condensation of ImpApC, ImpCpA, ImpGpU and ImpG. We find that the condensation of ImpGpU and ImpUpG on poly(C-A) is efficient, the condensation of ImpCpA on poly(U-G) is moderately efficient, while the condensation of ImpApC on poly(U-C) proceeds poorly. In many cases, the product is predominantly 3'-5'-linked. These reactions demonstrate unequivocally, for the first time, that template-directed reactions occur in double-helical structures. Furthermore, they describe for the first time a pair of reactions in which each of two complementary polymers facilitates the synthesis of the other. The prebiotic significance of these findings is discussed.

Affinity labeling of the 3'-OH terminal binding site of the ribonucleic acid chain on deoxyribonucleic acid dependent ribonucleic acid polymerase from Escherichia coli

Nucleoside triphosphates modified at the 3'-OH are chain terminators for RNA polymerase. They form inactive ternary complexes with the enzyme, poly(dT), and oligoadenylate, the stabilities of which depend upon the length of the oligonucleotide. Employing [5'-32P]p(Ap)10A, together with the reactive analogues 3'-(bromoacetamide)-3'-deoxyadenosine triphosphate or 3'-(isothiocyanato)-2',3'-dideoxyadenosine triphosphate, as well as 3'-amino-3'-deoxyadenosine triphosphate, followed by cross-linking with glyoxal, we labeled RNA polymerase primarily at the beta' subunit. The latter therefore appears to contain at least in part the 3'-OH terminus of the nascent RNA chain when the enzyme is in the form of the ternary complex.

Effects of internal nonbonded bases and a G.U base pair on the stability of a short ribonucleic acid helix

Proton nuclear magnetic resonance has been used to examine the effect of both noncomplementary and G.U oppositions in the duplexes formed by the synthetic pentaribonucleotides CpApApUpG, CpApUpUpG, CpApGpUpG, and CpApCpUpG. The lack of any sigmoidal behavior in the chemical shift vs. temperature plots of the base protons in the individual pentaribonucleotides indicates that duplexes with noncomplementary base oppositions of the type: formula: (see text), (where X = A, U, G, or C) do not form. Variable temperature spectra of the mixture of CpApGpUpG and CpApUpUpG were recorded over the range of 70--10 degrees C. The chemical shift vs. temperature plot of the purine aromatic protons displayed sigmoidal curves. This demonstrated both duplex formation and the presence of a G.U. base pair. The average Tm of the duplex was found to be 23.4 +/- 2.0 degrees C. This is similar to that of the duplex formed by CpApUpG (24.0 +/- 1.0 degrees C) but less than the Tm of the following duplexes: CpApApUpG:CpApUpUpG (Tm = 28.5 +/- 2.1 degrees C), CpApGpUpG:CpApCpUpG (Tm = 38.4 +/- 0.6 degrees C) and CpApUpApUpG (Tm = 41.5 +/- 1.1 degrees C). The G.U base pair has a Tm (20.0 degrees C) significantly lower than the rest of the duplex (24 +/- 1 degree C) and is a region of local instability within the double helix. This 1H NMR study is the first to investigate both the formation and relative stability of an internal G.U. base pair neighboring regular Watson--Crick base pairs.

Interferon enhances 2-5A synthetase in embryonal carcinoma cells

Mouse teratocarcinomas provide a useful model of mammalian differentiation, because the malignant embryonal carcinoma (EC) stem cells of such tumours may produce various differential cell types in vivo or in vitro. Many EC cell lines have now been established and classified on the basis of their ability to differentiate in vivo into cell types characteristically derived from any of the three germ layers. There is convincing evidence that EC cells can neither produce interferon, nor respond to it by becoming resistant to virus, whereas differentiated cells derived from EC lines behave normally in both respects. We investigated the lack of responsiveness of EC cells towards interferon by measuring the levels of two double-stranded RNA-dependent enzyme activities recently shown to be enhanced by interferon. We report here that on treatment with interferon, EC cells show increased 2-5A synthetase levels comparable to those found in differentiated cells, while there is little or no effect on kinase activity in EC cells, in contrast to their differentiated counterparts.

Influence of terminal 3' phosphates or 2',3'-cyclic phosphates on the conformations of oligoriboadenylates, oligoribocytidylates, and the corresponding monomers

The circular dichroism spectra of chemically synthesized adenylate and cytidylate dinucleotides and trinucleotides bearing terminal 3' phosphates have been compared under a variety of conditions with the spectra obtained from the corresponding oligomers with 2',3'-terminal cyclic phosphate groups. Similar comparisons for the mononucleotides are also presented. Although the base stacking of an oligomer with a terminal cyclic phosphate might be expected to be greater than that of the corresponding oligomer with a 3' phosphate from charge repulsion considerations, the magnitudes of the Cotton effects in the former class are always considerably smaller than those in the latter class. This suggests a decreased stacking. The implications of these observations are discussed in light of the compelling crystallographic evidence that cytidine 2',3'-cyclic phosphate adopts an unusual sugar puckering and the syn conformation.

The nucleotide sequence of tRNA tyrosine from the fission yeast Schizosaccharomyces pombe

The sequence of tRNA tyrosine from the fission yeast Schizosaccharomyces pombe is pCUCCUGAUm1 GGUG psi AGDDGGDDAUCACACor (psi) CCGGUG psi Ai6 AACCGGUUGm7 GUm5C GCUAGT psi CGm1 AUUCUGGUCAGGAGACCAOH. This sequence differs in 30 nucleotides from the tRNA-Tyr seqence of the budding yeast Saccharomyces cerevisiae. It has a unique anticodon stem of only four GC base pairs. The normal fifth pair position of nucleotide 28-44 is occupied by a C-U and in 20% of the tRNA-Tyr molecules it is psi-U. This unusual feature and its implications are considered in the discussion.