An improved rapid enzymatic method of RNA sequencing using chemical modification.

A version of rapid gel sequencing procedure based on the analysis of partial endonuclease hydrolizates of chemically modified 5'-32P-labelled RNA is suggested. Complete and selective modification of cytidilic residues by a methoxyamine-bisulfite mixture leads to the unfolding of the RNA secondary structure and, due to this effect, to the generation of a more uniform set of fragments after partial RNAase hydrolysis. The position of cytidines in an RNA sequence can be determined by restricting the hydrolysis of phosphodiester bonds between the modified CMP residues and their 3'-neighbours with T2 and A RNAases. The method was verified with tRNATrp (yeast) and 5S RNA (rat liver and yeast).     

Cleavage of RNA in hybrid duplexes by ribonuclease H ofE. coli: I. Substrate properties of complexes formed by RNA and a tandem of short oligodeoxyribonucleotides

We studied theE. coli RNase H cleavage of a 5′-labeled RNA fragment within two hybrid duplexes with identical sequences, one of which is formed by RNA and a 20-mer oligodeoxyribonucleotide (RNA/p20) whereas the second, by RNA and a tandem of short oligodeoxyribonucleotides (octanucleotide : tetranucleotide : octanucleotide) (RNA/tandem). It was shown that RNA in the RNA/p20 complex is hydrolyzed from the 3′-end to yield consecutively the 17-, 14-, 11-, 8-, and 5-mer 5′-labeled fragments. On hydrolysis of RNA in complex RNA/tandem, the same products were registered but their accumulation rates in this case differed. Thus, the initial rates of accumulation of the 17- and 8-mer were close. Moreover, the accumulation of the final 5-mer differed considerably: in the RNA/tandem complex it appeared within first minutes of the reaction but only after a considerable lag period in complex RNA/p20. These data testify that the tandem is involved not only in the consecutive accumulation of the shortened products (which is characteristic of complexes including extended oligonucleotides) but also in the parallel accumulation. This results from hydrolysis of each duplex segment formed by RNA and the short oligonucleotide of the tandem. Although the order of recognition and cleavage of RNA target by ribonuclease H at certain bonds depends on the type of the hybrid duplex, the destruction of RNA target within complex RNA/tandem and in complex with the full-size oligonucleotide occurs with a close effectiveness.     

Zn2+ Promoted Hydrolysis of RNA

Abstract

The Zn²⁺ promoted hydrolysis of phosphodiester bonds of RNA has been studied by using a series of model compounds from dinucleoside monophosphates to oligo- and polynucleotides. The results will be discussed with respect to complex formation between the metal ion catalysts and substrates.     

Nuclear ribonucleases and post-transcriptional changes of RNA. Specificity and other properties of rat liver nuclear endonuclease]

Some physico-chemical properties, specificity and the character of action of rat liver nuclear ribonuclease are studied. The enzyme maximal activity was observed at pH 7.5--8.0, ionic strength 0.02--0.3, Mg2+ being necessary. Nuclease is an oligomer, having molecular weight is 160000--180000 daltons and containing separate associates. Purified enzyme is free of contaminating activities (polynucleotidephosphorylase, DNAse; 5'-nucleotidase, and alkaline phosphatases). It is shown to hydrolyse polyA and RNA for endonuclease type, degradation products being oligonucleotides terminating with 5'-phosphate and 3'-hydroxyl groups. RNAse hydrolyses all phosphodiester bonds in polynucleotides, developing no specificity to the nature of bases. Relative hydrolysis rate for different substrates decreased as follows: polyA greater than yeast RNA greater than polyC greater than polyU greater than 28S rRNA greater than greater than 18S rRNA greater than polyA-polyU. The enzyme may be classified as ribonucleate-5'-nucleotidehydrolase (EC 3.1.4.9.).     

Crystal structure and nucleotide binding of the Thermus thermophilus RNA helicase Hera N-terminal domain

DEAD box RNA helicases use the energy of ATP hydrolysis to unwind double-stranded RNA regions or to disrupt RNA/protein complexes. A minimal RNA helicase comprises nine conserved motifs distributed over two RecA-like domains. The N-terminal domain contains all motifs involved in nucleotide binding, namely the Q-motif, the DEAD box, and the P-loop, as well as the SAT motif, which has been implicated in the coordination of ATP hydrolysis and RNA unwinding. We present here the crystal structure of the N-terminal domain of the Thermus thermophilus RNA helicase Hera in complex with adenosine monophosphate (AMP). Upon binding of AMP the P-loop adopts a partially collapsed or half-open conformation that is still connected to the DEAD box motif, and the DEAD box in turn is linked to the SAT motif via hydrogen bonds. This network of interactions communicates changes in the P-loop conformation to distant parts of the helicase. The affinity of AMP is comparable to that of ADP and ATP, substantiating that the binding energy from additional phosphate moieties is directly converted into conformational changes of the entire helicase. Importantly, the N-terminal Hera domain forms a dimer in the crystal similar to that seen in another thermophilic prokaryote. It is possible that this mode of dimerization represents the prototypic architecture in RNA helicases of thermophilic origin.     

Differentiation of Nucleic Acids by Staining at Controlled pH and by A Schiff-Methylene Blue Sequence

Fixation with Bouin's fluid preserves cytoplasmic and nucleolar ribonucleic acid (UNA) particularly well. RNA may be demonstrated preferentially in Bouin fixed tissue by staining with 0.02% thiazine dye in aqueous McIIvaine phosphate-citrate buffer between pH 3 and 4. Methylation blockage of basophilia other than that of nucleic acids permits staining of RNA with thiazine dyes near neutrality. The deoxyribonucleic acid (DNA) of chromatin undergoes a Feulgen type hydrolysis in the tissue block during 24 hr fixation with Bouin's fluid. This hydrolysis by picric acid permits Schiff staining of the DNA wthout further acid hydrolysis. Consequently after Bouin fixation it is possible to demonstrate DNA and RNA specifically by a Schiff-methylene blue sequence. Thus a Schiff stain without further acid hydrolysis followed by 0.02% methylene blue in phosphate-citrate buffer at pH 3.0 to 3.5 colors DNA magenta in contrast to the blue of RNA.     

On the use of polyacrylamide gel electrophoresis in the analysis of the action of free and insolubilized nucleases on bacteriophage RNA

Electrophoresis in vertical polyacrylamide gel slabs containing 8 m urea was used to examine the products of incomplete hydrolysis of bacteriophage f2 RNA generated by a number of nucleases. Oligonucleotide patterns were reproducible and characteristic of each nuclease; even closely related enzymes (i.e., with the same primary specificity) produced bands which were unique. Enzymes which were covalently bound to agarose generated band patterns which were indistinguishable from those produced by the soluble enzymes, suggesting their use in RNA sequence analysis. Agents which modify secondary structure in the RNA substrate significantly affected the oligonucleotide patterns resulting from the action of a given nuclease. The results indicate that both gross enzyme specificity and RNA secondary structure determine which bonds are hydrolyzed in early stages of the enzyme catalyzed breakdown of RNA. Secondary aspects of nuclease specificity are demonstrable but appear to be much less significant.     

Hydrolysis kinetics of trisaccharides consisting of glucose, galactose, and fructose residues in subcritical water

The hydrolysis kinetics of trisaccharides consisting of glucose, galactose, and fructose residues with different glycosidic bonds, 1-kestose, d-melezitose, d-raffinose, and lactosucrose, in subcritical water were conducted over the temperature range of 150-230 degrees C and at a constant pressure of 10 MPa. The hydrolysis of trisaccharides in subcritical water proceeded consecutively, i.e., one cleavage of the two bonds antedated the other. The preceding cleavage was not expressed by the first-order kinetics, but by the kinetics considering the concentration of the acidic compounds, which were produced by the degradation of the constituent monosaccharides. The hydrolysis of the constituent disaccharides, except sucrose composed of the alpha-Glc-(1-->2)-beta-Fru bond, obeyed first-order kinetics. All of the rate constants of the hydrolytic kinetics were determined, and the values were found to depend on the type of bond.     

Purification and properties of a light-inducible nuclease from Euglena gracilis.

The nuclease described by Carell, E.F., Egan, J.M. and Pratt, E.A. [Arch. Biochem. Biophys. (1970) 138, 26-31] has been purified 1000-fold from Euglena gracilis strain Z. The enzyme catalyzes the hydrolysis of both polyribonucleotides and polydeoxyribonucleotides. The relative rates of hydrolysis of synthetic and natural polynucleotides was found to be: poly (U) 100, poly (dT) 33, denatured calf-thymus DNA 33, yeast tRNA 9, E. coli total RNA 6, poly (dA dT) 5, poly (A) less than 1, poly (C) less than .05, and poly (G) less than .05. The enzyme attacks polynucleotides in an endonucleolytic fashion, yielding products terminated with a 3'-phosphate. Poly (U) appears to be hydrolyzed completely to 3'-UMP; both RNA and DNA appear to have some phosphodiester bonds resistant to enzyme catalyzed hydrolysis. Because of its mode of action and its inducibility by light, we propose the name endonuclease L for this enzyme.     

Ribozyme inhibitors: deoxyguanosine and dideoxyguanosine are competitive inhibitors of self-splicing of the Tetrahymena ribosomal ribonucleic acid precursor

The intervening sequence (IVS) of the Tetrahymena rRNA precursor catalyzes its own splicing. During splicing the 3'-hydroxyl of guanosine is ligated to the 5' terminus of the IVS. One catalytic strategy of the IVS RNA is to specifically bind its guanosine substrate. Deoxyguanosine (dG) and dideoxyguanosine (ddG) are found to be competitive inhibitors of self-splicing. Comparison of the kinetic parameters (Ki = 1.1 mM for dG; Ki = 5.4 mM for ddG; Km = 0.032 mM for guanosine) indicates that the ribose hydroxyls are necessary for optimal binding of guanosine to the RNA. dG is not a substrate for the reaction even at very high concentrations. Thus, in addition to aiding in binding, the 2'-hydroxyl is necessary for reaction of the 3'-hydroxyl. A second catalytic strategy of the IVS RNA is to enhance the reactivity of specific bonds. For example, the phosphodiester bond at the 3' splice site is extremely labile to hydrolysis. We find that dG and ddG, as well as 2'-O-methylguanosine and 3'-O-methylguanosine, reduce hydrolysis at the 3' splice site. These data are consistent with an RNA structure that brings the 5' and 3' splice sites proximal to the guanosine binding site.     

Zn2+ -Promoted Hydrolysis of 3′,5′-Dinucleoside Monophosphates and Polyribonucleotides. The Effect of Nearest Neighbours on the Cleavage of Phosphodiester Bonds

Abstract

Pseudo first-order rate constants for the Zn²⁺ -promoted cleavage of 15 different dinucleoside monophosphates, 4 different ribo homopogmers and RNA III from baker's yeast have been determined. Furthermore, the distribution of various nucleosides at the 3′-and 5′-terminus of the oligomeric hdrolysls products of RNA has been quantified. On these bases, the effect of nearest neighbours on the metal-ion-promoted hydrolysis of the internucleosidic phosphodiester bonds of RNA is discussed.     

Hydrostatic and osmotic pressure study of the RNA hydration

The tertiary structure of nucleic acids results from an equilibrium between electrostatic interactions of phosphates, stacking interactions of bases, hydrogen bonds between polar atoms and water molecules. Water interactions with ribonucleic acid play a key role in its structure formation, stabilization and dynamics. We used high hydrostatic pressure and osmotic pressure to analyze changes in RNA hydration. We analyzed the lead catalyzed hydrolysis of tRNA^Phe from S. cerevisiae as well as hydrolytic activity of leadzyme. Pb(II) induced hydrolysis of the single phosphodiester bond in tRNA^Phe is accompanied by release of 98 water molecules, while other molecule, leadzyme releases 86.     

Generation of Oligonucleotides Under Hydrothermal Conditions by Non-enzymatic Polymerization

We previously reported that 5′-mononucleotides organized within a multilamellar lipid matrix can produce oligomers in the anhydrous phase of hydration–dehydration (HD) cycles. However, hydrolysis of oligomers can occur during hydration, and it is important to better understand the steady state in which ester bond synthesis is balanced by hydrolysis. In order to study condensation products of mononucleotides and hydrolysis of their polymers, we established a simulation of HD cycles that would occur on the early Earth when volcanic land masses emerged from the ocean over 4 billion years ago. At this stage on early Earth, precipitation produced hydrothermal fields characterized by small aqueous pools undergoing evaporation and refilling at elevated temperatures. Here, we confirm that under these conditions, the chemical potential made available by cycles of hydration and dehydration is sufficient to drive synthesis of ester bonds. If 5′-mononucleotides are in solution at millimolar concentrations, then oligomers resembling RNA are synthesized and exist in a steady state with their monomers. Furthermore, if the mononucleotides can form complementary base pairs, then some of the products have properties suggesting that secondary structures are present, including duplex species stabilized by hydrogen bonds.     

Investigation of the kinetics of degradation of hexopyranosylated cytosine nucleosides using liquid chromatography

Liquid chromatography was used to follow the degradation of hexopyranosylated cytosine nucleosides in buffers of acid, neutral and alkaline pH and of constant ionic strength. The compounds were found to degrade by hydrolysis to cytosine and/or by deamination to the corresponding uracil nucleosides. Degradation in acid is influenced by the number of sugar hydroxyl groups, presence of sugar double bonds and the type of anomer. Stability of some of the compounds was compared with that of related thymine nucleosides. Temperature studies support a unimolecular mechanism of hydrolysis at pH 1.22.     

Substrate specificity of collagenolytic proteases from the hepatopancreas of the of the Kamchatka crab]

The substrate specificity of two isozymes of collagenolytic protease of the crab (Paralithodes camtschatica) was studied. It was found that both proteases can effectively hydrolyze type I and III collagens, as well as gelatin, the set of products yielded by enzymatic hydrolysis being different for isozymes A and C. Hydrolysis of some well-known peptides revealed that isozyme A predominantly cleaves the peptide bonds containing arginine and lysine residues, whereas isozyme C predominantly hydrolyzes bonds containing hydrophobic amino acids. The catalytic constants for the hydrolysis of several low molecular weight substrates in the presence of P. camtschatica proteases were determined, which allowed to attribute isozyme A to trypsin-like, and isozyme C to chymotrypsin-like proteinases. The peptide substrates of collagenase, Pz-Pro-Leu-Gly-Pro-D-Arg and Z-Gly-Pro-Ala-Gly-Pro-Ala are not hydrolyzed isozymes of crab collagenolytic protease.     

RNA hydrolysis and inhibition of translation by a Co(III)-cyclen complex

Metal ion-chelator catalysts based on main-group, lanthanide, or transition metal complexes have been developed as nonenzymatic alternatives for the hydrolysis of the phosphodiester bonds in DNA and RNA. Cobalt (III), with its high-charge density, is known for its ability to hydrolyze phosphodiesters with rate constants as high as 2 x 10(-4) s(-1). We have developed a kinetically inert Co(III)-cyclen-based complex, Co(III)-cycmmb that is very potent in inhibiting the translation of RNA into protein. Contact time as short as 10 min is sufficient to achieve the complete inhibition of the translation of a concentrated luciferase RNA solution into the enzyme in a cell-free translation system. The inhibition appears to proceed through two pathways. The first pathway involves the kinetic or substitutional inertness of Co(III) for the RNA template at short contact times. This interaction is mediated through the kinetic inertness of Co(III) for the phosphate groups of the nucleotides, as well as coordination of Co(III) to the nitrogenous bases. The second pathway occurs at longer contact times and is mediated by the hydrolysis of the phosphodiester backbone. This report represents the first demonstrated use of a metal-chelate complex to achieve the inhibition of the translation of RNA into protein. This Co(III) system can be useful in its present nonsequence-specific form as a novel viral decontamination agent. When functionalized to recognize specific nucleic acid sequences, such a system could potentially be used in gene-silencing applications as an alternative to standard antisense or RNAi technologies.