Nature of the effect on RNA and substrate specificity of RNAase of Bacillus amylozyma 9a]

Extracellular RNAase from Bac. amylozyma 9a has endonucleolytic character of the action on RNA, it splits in RNA 5'-phosphodiester bonds of GpXp type (where X is any nucleoside). The hydrolysis proceeds in two steps by the intramolecular transphosphorylation type of reaction to form guanosine-2',3'-phosphates and with the subsequent hydrolysis of cyclic bonds. The enzyme shows a preferable specificity to the single-stranded structure of the polyribonucleotides.     

The double helix is dehydrated: evidence from the hydrolysis of acridinium ester-labeled probes

A highly chemiluminescent reporter molecule, acridinium ester (AE), was tethered to single-stranded oligonucleotide probes and hybridized to complementary as well as mismatched target sequences. When tethered to single-stranded probes, AE was readily hydrolyzed by water or hydroxide ion. In contrast, when hybridized to a complementary target, hydrolysis of the AE probe was markedly inhibited. Mismatches near AE eliminated the ability of the double helix to strongly inhibit AE hydrolysis. To establish the molecular basis for these remarkable hydrolysis properties of AE-labeled probes, the binding and hydrolysis mechanisms of AE-labeled probes were examined. When tethered to single- or double-stranded nucleic acids, hydrolysis of AE was found to proceed by generalized base catalysis in which a base abstracts a proton from water and the resulting hydroxide ion then hydrolyzes AE. Analysis of the hydrolysis rates of AE bound to DNA revealed that AE binds the minor groove of DNA and that its hydrolysis is inhibited by low water activity within the minor groove of the helix. Depending upon the sequence of the DNA, the water activity of the minor groove was estimated to be at least 2-4-fold lower than bulk solution. Hydrolysis measurements of AE tethered to RNA as well as RNA/DNA hybrids argued that the grooves of these double helices are also dehydrated relative to bulk solution. Remarkably, mismatched bases, regardless of their structure or sequence context, enhanced hydrolysis of AE by inducing hydration of the double helix that spread approximately five base pairs on either side of the mismatch.     

Reovirus protein sigmaNS binds in multiple copies to single-stranded RNA and shares properties with single-stranded DNA binding proteins

Reovirus nonstructural protein sigmaNS interacts with reovirus plus-strand RNAs in infected cells, but little is known about the nature of those interactions or their roles in viral replication. In this study, a recombinant form of sigmaNS was analyzed for in vitro binding to nucleic acids using gel mobility shift assays. Multiple units of sigmaNS bound to single-stranded RNA molecules with positive cooperativity and with each unit covering about 25 nucleotides at saturation. The sigmaNS protein did not bind preferentially to reovirus RNA over nonreovirus RNA in competition experiments but did bind preferentially to single-stranded over double-stranded nucleic acids and with a slight preference for RNA over DNA. In addition, sigmaNS bound to single-stranded RNA to which a 19-base DNA oligonucleotide was hybridized at either end or near the middle. When present in saturative amounts, sigmaNS displaced this oligonucleotide from the partial duplex. The strand displacement activity did not require ATP hydrolysis and was inhibited by MgCl(2), distinguishing it from a classical ATP-dependent helicase. These properties of sigmaNS are similar to those of single-stranded DNA binding proteins that are known to participate in genomic DNA replication, suggesting a related role for sigmaNS in replication of the reovirus RNA genome.     

The hepatitis C virus NS3 protein: a model RNA helicase and potential drug target

The C-terminal portion of hepatitis C virus (HCV) nonstructural protein 3 (NS3) forms a three domain polypeptide that possesses the ability to travel along RNA or single-stranded DNA (ssDNA) in a 3' to 5' direction. Fueled byATP hydrolysis, this movement allows the protein to displace complementary strands of DNA or RNA and proteins bound to the nucleic acid. HCV helicase shares two domains common to other motor proteins, one of which appears to rotate upon ATP binding. Several models have been proposed to explain how this conformational change leads to protein movement and RNA unwinding, but no model presently explains all existing experimental data. Compounds recently reported to inhibit HCV helicase, which include numerous small molecules, RNA aptamers and antibodies, will be useful for elucidating the role of a helicase in positive-sense single-stranded RNA virus replication and might serve as templates for the design of novel antiviral drugs.     

Study of the secondary and tertiary structure of phage MS2 RNA using nucleases and fluorescent dyes specific for secondary structure

The binding of ethidium bromide (EtBr) and acridine orange (AO) to RNA in native state or after hydrolysis by S1 and SV nucleases that specifically split single-stranded and double-stranded segments was studied. Nuclease S1 hydrolysis of RNA does not increase the number of EtBr strong binding sites, Tm and hyperchromic effect being also unchanged. Hydrolysis by double-stranded segments accessible to EtBr is followed by the diminishing of Tm and hyperchromism. A supposition is put forward that the main role in stabilization of the RNA tertiary structure is played by double-stranded segments arranged so that some of them are hidden and do not interact with dyes. One of the possible models may be parallel oriented intramolecular "hair-pins" forming compact "rod-like" structures.     

Characterization of the NTPase, RNA-binding, and RNA helicase activities of the DEAH-box splicing factor Prp22

The DEAH protein Prp22 is important for the second transesterification step of pre-mRNA splicing, and it is essential for releasing mature mRNA from the spliceosome. Recombinant Prp22 has RNA-stimulated ATPase and ATP-dependent unwinding activities, which are crucial for the mRNA release step. In this study, we characterize the RNA-binding, NTP hydrolysis, and RNA unwinding functions of Prp22. Using nitrocellulose filter binding assays, we determined that the apparent affinity of Prp22 is approximately 20-fold greater for single-stranded RNA than for single-stranded DNA or duplex nucleic acids. Inclusion of hydrolyzable ATP in binding reactions increased the apparent K(D) for RNA by 3-4-fold. The Prp22-RNA interaction is influenced by the length of the RNA chain, and the apparent K(D) values for poly(A)(40) and poly(A)(10) are 17 and 140 nM, respectively. RNA-stimulated ATP hydrolysis is similarly affected by chain length, and optimal activity requires RNA oligomers of >or=20 nt. We show that Prp22 can hydrolyze all common NTPs and dNTPs with comparable efficiencies and that Prp22 unwinds RNA duplexes with 3' to 5' directionality.     

A study of the hydrolysis of unfractionated reticulocyte ribosomal ribonucleic acid by pancreatic ribonuclease and its relevance to secondary structure

1. Unfractionated RNA from reticulocyte ribosomes was hydrolysed with pancreatic ribonuclease at 25 degrees . The molecular weight decreased rapidly to about 3s when about 6% of the residues were soluble in 0.5n-perchloric acid. In the early stages 60-80% of the hydrolysed linkages were ;hidden'. The denaturation spectrum was affected. Continued hydrolysis led to slow changes in S value, in the electrophoresis pattern in polyacrylamide gels and in the denaturation spectrum. 2. Hydrolysis of RNA with alkali to fragments of between 2.8s and 5.9s led to changes in the denaturation spectrum similar to those observed in the early stages of enzymic hydrolysis. 3. A theory was developed to relate changes in secondary structure with main-chain scission. 4. The results agree with the ;hairpin-loop' model for RNA. The denaturation studies are consistent with the presence of more than one species of hairpin loop that differ in their denaturation spectra. The average length of the hairpin loop was estimated to be 10-20 residues and an upper limit of 35 residues was established. 5. It is inferred, on the basis of studies with model compounds, that the stability of single-stranded stacked structures is hardly dependent on salt concentration. 6. The denaturation spectrum of the fragments obtained on hydrolysis became less dependent on ionic strength, suggesting that double-helical structures revert to a single-stranded stacked form on denaturation.     

The replicative helicases of bacteria, archaea, and eukarya can unwind RNA-DNA hybrid substrates

Replicative helicases are hexameric enzymes that unwind DNA during chromosomal replication. They use energy from nucleoside triphosphate hydrolysis to translocate along one strand of the duplex DNA and displace the complementary strand. Here, the ability of a replicative helicase from each of the three domains, bacteria, archaea, and eukarya, to unwind RNA-containing substrate was determined. It is shown that all three helicases can unwind DNA-RNA hybrids while translocating along the single-stranded DNA. No unwinding could be observed when the helicases were provided with a single-stranded RNA overhang. Using DNA, RNA, and DNA-RNA chimeric oligonucleotides it was found that whereas the enzymes can bind both DNA and RNA, they could translocate only along DNA and only DNA stimulates the ATPase activity of the enzymes. Recent observations suggest that helicases may interact with enzymes participating in RNA metabolism and that RNA-DNA hybrids may be present on the chromosomes. Thus, the results presented here may suggest a new role for the replicative helicases during chromosomal replication or in other cellular processes.     

Purification and characterization of the Upf1 protein: a factor involved in translation and mRNA degradation.

mRNA degradation is an important control point in the regulation of gene expression and has been shown to be linked to the process of translation. One clear example of this linkage is the observation that nonsense mutations in a gene can accelerate the decay of the corresponding mRNA. In the yeast Saccharomyces cerevisiae, the product of the UPF1 gene, harboring zinc finger, NTP hydrolysis, and helicase motifs, was shown to be a trans-acting factor in this decay pathway. A UPF1 gene disruption results in stabilization of nonsense-containing mRNAs and leads to a nonsense suppression phenotype. As a first step toward understanding the molecular and biochemical mechanism of nonsense-mediated mRNA decay, we have purified Upf1p from a yeast extract and characterized its nucleic acid-dependent NTPase activity, helicase activity, and nucleic acid binding properties. The results presented in this paper demonstrate that Upf1p contains both RNA- and DNA-dependent ATPase activities and RNA and DNA helicase activities. In the absence of ATP, Upf1p binds to single-stranded RNA or DNA, whereas hydrolysis of ATP facilitates its release from single-stranded nucleic acid. Based on these results, the role of Upf1p's biochemical activities in mRNA decay and translation are discussed.     

Structural basis for processivity and single-strand specificity of RNase II

RNase II is a member of the widely distributed RNR family of exoribonucleases, which are highly processive 3'-->5' hydrolytic enzymes that play an important role in mRNA decay. Here, we report the crystal structure of E. coli RNase II, which reveals an architecture reminiscent of the RNA exosome. Three RNA-binding domains come together to form a clamp-like assembly, which can only accommodate single-stranded RNA. This leads into a narrow, basic channel that ends at the putative catalytic center that is completely enclosed within the body of the protein. The putative path for RNA agrees well with biochemical data indicating that a 3' single strand overhang of 7-10 nt is necessary for binding and hydrolysis by RNase II. The presence of the clamp and the narrow channel provides an explanation for the processivity of RNase II and for why its action is limited to single-stranded RNA.     

Adenosine 5'-O-(3-thio)triphosphate (ATPgammaS) is a substrate for the nucleotide hydrolysis and RNA unwinding activities of eukaryotic translation initiation factor eIF4A

Whereas ATPgammaS is often considered a nonhydrolyzable substrate for ATPases, we present evidence that ATPgammaS is a good substrate for the RNA-stimulated nucleotide hydrolysis and RNA unwinding activities of eIF4A. In the presence of saturating single-stranded poly(U) RNA, eIF4A hydrolyzes ATPgammaS.Mg and ATP.Mg with similar steady-state parameters (KM(NTP.Mg) = 66 and 58 microM and kcat = 1.0 and 0.97 min(-1), respectively). ATPgammaS.Mg also supports catalysis of RNA unwinding within 10-fold of the rate supported by ATP.Mg. The identical steady-state rate parameters, in comparison with the expected difference in the intrinsic rate of hydrolysis for ATP and ATPgammaS, suggest a nonchemical rate-limiting step for nucleotide hydrolysis. These results raise caution concerning the assumption that ATPgammaS is a nonhydrolyzable ATP analog and underscore the utility of thio-substituted NTPs as mechanistic probes.     

The ATPase, RNA unwinding, and RNA binding activities of recombinant p68 RNA helicase

p68 RNA helicase, a nuclear RNA helicase, was identified 2 decades ago. The protein plays very important roles in cell development and organ maturation. However, the biological functions and enzymology of p68 RNA helicase are not well characterized. We report the expression and purification of recombinant p68 RNA helicase in a bacterial system. The recombinant p68 is an ATP-dependent RNA helicase. ATPase assays demonstrated that double-stranded RNA (dsRNA) is much more effective than single-stranded RNA in stimulating ATP hydrolysis by the recombinant protein. Consistently, RNA-binding assays showed that p68 RNA helicase binds single-stranded RNA weakly in an ATP-dependent manner. On the other hand, the recombinant protein has very high affinity for dsRNA. Binding of the protein to dsRNA is ATP-independent. The data indicate that p68 may directly target dsRNA as its natural substrate. Interestingly, the recombinant p68 RNA helicase unwinds dsRNA in both 3' --> 5' and 5' --> 3' directions. This is the second example of a Asp-Glu-Ala-Asp (DEAD) box RNA helicase that unwinds RNA duplexes in a bi-directional manner.     

A neutral pH thermal hydrolysis method for quantification of structured RNAs

Riboswitch aptamers adopt diverse and complex tertiary structural folds that contain both single-stranded and double-stranded regions. We observe that this high degree of secondary structure leads to an appreciable hypochromicity that is not accounted for in the standard method to calculate extinction coefficients using nearest-neighbor effects, which results in a systematic underestimation of RNA concentrations. Here we present a practical method for quantifying riboswitch RNAs using thermal hydrolysis to generate the corresponding pool of mononucleotides, for which precise extinction coefficients have been measured. Thermal hydrolysis can be performed at neutral pH without reaction quenching, avoids the use of nucleases or expensive fluorescent dyes, and does not require generation of calibration curves. The accuracy of this method for determining RNA concentrations has been validated using quantitative ³¹P-NMR calibrated to an external standard. We expect that this simple procedure will be generally useful for the accurate quantification of any sequence-defined RNA sample, which is often a critical parameter for in vitro binding and kinetic assays.     

Differences in the red fluorescence of acridine orange bound to single-stranded RNA and DNA.

Fluorescence of acridine orange bound to RNA or DNA in the single-stranded form including single-stranded synthetic polyribo- or polydeoxyribonucleotides was measured in the expectation that some distinct structural characteristic between single-stranded RNA and DNA might be reflected by a specific fluorescent behaviour of bound dyes. It was found that the complex of the dye with single-stranded RNA emits a weaker red fluorescence around 650 nm than the complex with single-stranded DNA at low phosphate-to-dye ratios. The fact could be explained neither by a direct interaction of bound dyes with the 2′-hydroxyl group of ribose in RNA nor by the difference in the G-C content of the nucleic acids. On the basis of the character of dye molecules emitting the red fluorescence, it was suggested that the bases in single-stranded RNA might be buried in some hydrophobic environment that would make the dyes less likely to interact with them, compared with the bases in single-stranded DNA. It was further inferred that some conformational rigidity of single-stranded RNA may partially be responsible for the weaker red fluorescence.     

Substrate specificity of the Rad3 ATPase/DNA helicase of Saccharomyces cerevisiae and binding of Rad3 protein to nucleic acids.

Rad3 protein from the yeast Saccharomyces cerevisiae is a single-stranded DNA-dependent ATPase which catalyzes the unwinding of DNA.DNA duplexes. In the present studies we have demonstrated that the purified enzyme additionally catalyzes the displacement of RNA fragments annealed to complementary DNA. Quantitative comparisons using otherwise identical partially duplex DNA.DNA and DNA.RNA substrates indicate a significant preference for the latter. Competition for ATPase or DNA helicase activity by various homopolymers suggests that Rad3 protein does not discriminate between ribonucleotide and deoxyribonucleotide homopolymers with respect to binding. However, neither single-stranded RNA nor various ribonucleotide homopolymers supported the hydrolysis of nucleoside 5'-triphosphates. Additionally, Rad3 protein was unable to catalyze the displacement of oligo(dA) annealed to poly(U), suggesting that the catalytic domain of the enzyme is exquisitely sensitive to chemical and/or or conformational differences between DNA and RNA. Hence, it appears that Rad3 protein is not an RNA helicase.     

Coupled 5' nucleotide recognition and processivity in Xrn1-mediated mRNA decay

Messenger RNA decay plays a central role in the regulation and surveillance of eukaryotic gene expression. The conserved multidomain exoribonuclease Xrn1 targets cytoplasmic RNA substrates marked by a 5' monophosphate for processive 5'-to-3' degradation by an unknown mechanism. Here, we report the crystal structure of an Xrn1-substrate complex. The single-stranded substrate is held in place by stacking of the 5'-terminal trinucleotide between aromatic side chains while a highly basic pocket specifically recognizes the 5' phosphate. Mutations of residues involved in binding the 5'-terminal nucleotide impair Xrn1 processivity. The substrate recognition mechanism allows Xrn1 to couple processive hydrolysis to duplex melting in RNA substrates with sufficiently long single-stranded 5' overhangs. The Xrn1-substrate complex structure thus rationalizes the exclusive specificity of Xrn1 for 5'-monophosphorylated substrates, ensuring fidelity of mRNA turnover, and posits a model for translocation-coupled unwinding of structured RNA substrates.     

The nonenzymatic hydrolysis of oligoribonucleotides. VII. Structural elements affecting hydrolysis

Several elements of oligoribonucleotide structure are important for efficient hydrolysis. We have found that the following factors influence oligoribonucleotide hydrolysis: (i) single-stranded structure of RNA flanking the scissile phosphodiester bond, (ii) the substituent on atom C-5 of the uridine adjacent to the cleaved internucleotide bond, (iii) the position of the scissile UA phosphodiester bond within a hairpin loop, (iv) the concentration of formamide, urea, ethanol and sodium chloride.     

Virus-Specific Ribonucleic Acid in Cells Producing Rous Sarcoma Virus: Detection and Characterization

Cells producing Rous sarcoma virus contain virus-specific ribonucleic acid (RNA) which can be identified by hybridization to single-stranded deoxyribonucleic acid (DNA) synthesized with RNA-directed DNA polymerase. Hybridization was detected by either fractionation on hydroxyapatite or hydrolysis with single strand-specific nucleases. Similar results were obtained with both procedures. The hybrids formed between enzymatically synthesized DNA and viral RNA have a high order of thermal stability, with only minor evidence of mismatched nucleotide sequences. Virus-specific RNA is present in both nuclei and cytoplasm of infected cells. This RNA is remarkably heterogeneous in size, including molecules which are probably restricted to the nucleus and which sediment in their native state more rapidly than the viral genome. The nature of the RNA found in cytoplasmic fractions varies from preparation to preparation, but heterogeneous RNA (ca. 4-50S), smaller than the viral genome, is always present in substantial amounts.     

The determination of secondary structure in the poly(C) tract of encephalomyocarditis virus RNA with sodium bisulphite.

The degree of secondary structure in the poly(C) tract of encephalomyocarditis virus (EMCV) RNA has been investigated using sodium bisulphite, which brings about the hydrolysis of non-base-paired cytidylic acid to uridylic acid in RNA. The percentage conversion of C to U in the poly(C) region of native EMCV RNA was similar to that found in a synthetic polynucleotide lacking secondary structure [poly(C)]. When poly(I) was annealed to either native or denatured EMCV RNA, it protected the poly(C) tract from the action of bisulphite. It is concluded that the poly(C) tract of EMCV RNA in solution is very largely single-stranded.