Spectrophotometric analysis of RNA and DNA using cetyltrimethylammonium bromide

A versatile procedure is described for the analysis of RNA and DNA in brain using cetyltrimethylammonium bromide as the initial precipitant. Optimal conditions are described for the precipitation, hydrolysis, and effective separation of the RNA and DNA fractions from contaminating protein. The RNA and DNA fraction can now be accurately estimated by uv absorbance without a two wavelength correction. This method has also been used for the analysis of other mammalian organs and for mammalian cells obtained from tissue culture. The method may also be used for the simultaneous determination of radioactivity in nucleic acids. The orcinol reaction is shown to give high values for brain RNA.     

Correlation of RNA Secondary Structure Statistics with Thermodynamic Stability and Applications to Folding

The accurate prediction of the secondary and tertiary structure of an RNA with different folding algorithms is dependent on several factors, including the energy functions. However, an RNA higher-order structure cannot be predicted accurately from its sequence based on a limited set of energy parameters. The inter- and intramolecular forces between this RNA and other small molecules and macromolecules, in addition to other factors in the cell such as pH, ionic strength, and temperature, influence the complex dynamics associated with transition of a single stranded RNA to its secondary and tertiary structure. Since all of the factors that affect the formation of an RNAs 3D structure cannot be determined experimentally, statistically derived potential energy has been used in the prediction of protein structure. In the current work, we evaluate the statistical free energy of various secondary structure motifs, including base-pair stacks, hairpin loops, and internal loops, using their statistical frequency obtained from the comparative analysis of more than 50,000 RNA sequences stored in the RNA Comparative Analysis Database (rCAD) at the Comparative RNA Web (CRW) Site. Statistical energy was computed from the structural statistics for several datasets. While the statistical energy for a base-pair stack correlates with experimentally derived free energy values, suggesting a Boltzmann-like distribution, variation is observed between different molecules and their location on the phylogenetic tree of life. Our statistical energy values calculated for several structural elements were utilized in the Mfold RNA-folding algorithm. The combined statistical energy values for base-pair stacks, hairpins and internal loop flanks result in a significant improvement in the accuracy of secondary structure prediction; the hairpin flanks contribute the most.     

Effect of the "RNA control" locus in Escherichia coli on RNA bacteriophage R23 replication.

The effect of the rel gene of Escherichia coli on the RNA synthesis induced by phage R23 was studied. This RNA phage has the property of inhibiting ribosomal RNA formation and completely dominating the RNA synthesis of the host. Phage-specific RNA formation was found to be dependent on the allelic state of the rel gene. Determinations of RNA synthesis were made by both cumulative and short-term incorporations of uracil and adenine. Variations in labeling of nucleotide pools were compensated for by determining specific activities of ATP and UTP and using these values to obtain true, relative rates of RNA synthesis.     

The sensitivity of RNA polymerases I and II from Novikoff hepatoma (N1S1) cells to 3''-deoxyadenosine 5''-triphosphate.

The synthesis of ribosomal precursor RNA in Novikoff hepatoma (N1S1) cells is very sensitive to cordycepin (3'-dA). The synthesis of hnRNA, however, is resistant to inhibition concentrations of 3'-dA that completely block the synthesis of 45S ribosomal RNA precursor. We have examined the RNA polymerases present in these cultured cells with regard to their sensitivity to cordycepin 5'-triphosphate (3'-dATP) in an effort to explain the differential inhibition of RNA synthesis observed in vivo. RNA polymerases I and II were characterized on the basis of their chromatographic behavior on DEAE-Sephadex, as well as the response of their enzymatic activities to ionic strength, the divalent metal ions Mn2+ and Mg2+, and the toxin alpha-amanitin. For both enzymes the inhibition of in vitro RNA synthesis by 3'-dATP was competitive for ATP. The km values for ATP and the K1 values for 3'-dATP for the two enzymes were quite similar. RNA polymerase II, the enzyme presumed responsible for hnRNA synthesis, was actually slightly more sensitive to 3'-dATP than RNA polymerase I, the enzyme presumed responsible for ribosomal precursor RNA synthesis. Similar data were obtained when the RNA polymerases were assayed in isolated nuclei. These results indicate that the differential inhibition of RNA synthesis caused by 3'-dA in vivo cannot be simply explained by differential sensitivity of RNA polymerases I and II to 3'-dATP.     

Direct observation of the temperature-induced melting process of the Salmonella fourU RNA thermometer at base-pair resolution

In prokaryotes, RNA thermometers regulate a number of heat shock and virulence genes. These temperature sensitive RNA elements are usually located in the 5′-untranslated regions of the regulated genes. They repress translation initiation by base pairing to the Shine–Dalgarno sequence at low temperatures. We investigated the thermodynamic stability of the temperature labile hairpin 2 of the Salmonella fourU RNA thermometer over a broad temperature range and determined free energy, enthalpy and entropy values for the base-pair opening of individual nucleobases by measuring the temperature dependence of the imino proton exchange rates via NMR spectroscopy. Exchange rates were analyzed for the wild-type (wt) RNA and the A8C mutant. The wt RNA was found to be stabilized by the extraordinarily stable G14–C25 base pair. The mismatch base pair in the wt RNA thermometer (A8–G31) is responsible for the smaller cooperativity of the unfolding transition in the wt RNA. Enthalpy and entropy values for the base-pair opening events exhibit linear correlation for both RNAs. The slopes of these correlations coincide with the melting points of the RNAs determined by CD spectroscopy. RNA unfolding occurs at a temperature where all nucleobases have equal thermodynamic stabilities. Our results are in agreement with a consecutive zipper-type unfolding mechanism in which the stacking interaction is responsible for the observed cooperativity. Furthermore, remote effects of the A8C mutation affecting the stability of nucleobase G14 could be identified. According to our analysis we deduce that this effect is most probably transduced via the hydration shell of the RNA.     

Length dependence of RNA-RNA annealing

The association of complementary nucleic acids can be described by a second order rate constant k. For extended molecules, including complex nucleic acids, values of k were shown to be proportional to the square root of the chain length L of the shorter nucleic acid strand at temperatures between tm and tm-30 degrees C. For homopolymers this is true over a wider temperature range. Below temperatures of tm-30 degrees C, annealing rate constants may sharply decrease due to the formation of intramolecular structures. It seems to be reasonable to assume that the formation of intramolecular structures of nucleic acids reduces the density of nucleation sites for annealing and, thereby, lowers the rates of association. Here, we examined the relationship between RNA chain length and the kinetics of RNA-RNA annealing at physiological ionic strength and temperature. We used a complete sequence space derived from chloramphenicol acetyltransferase (cat) sequences to average over all structures for each given length. For groups of progressively longer antisense RNA species and a 800 nucleotides long complementary RNA, the observed annealing rate constants kobs were measured in vitro. The structure-averaged values for kobs of RNA-RNA annealing were not related to the square root of the chain length. Instead, they were found to be proportional to 10(alphaL) (alpha=0.0017). Here, a theoretical model is suggested in which the observed length dependence is mainly influenced by ionic interactions between complementary RNA strands. The observed length dependence has substantial implications for the biological behavior of long-chain complementary RNA including the design of antisense RNA. The efficacy of antisense RNA in living cells is known to be related to annealing kinetics in vitro. Thus, on a statistical basis and independent of individual structures, long-chain rather than short-chain antisense RNA should lead to stronger inhibition.     

Determination of thermodynamics and kinetics of RNA reactions by force

Single-molecule methods have made it possible to apply force to an individual RNA molecule. Two beads are attached to the RNA; one is on a micropipette, the other is in a laser trap. The force on the RNA and the distance between the beads are measured. Force can change the equilibrium and the rate of any reaction in which the product has a different extension from the reactant. This review describes use of laser tweezers to measure thermodynamics and kinetics of unfolding/refolding RNA. For a reversible reaction the work directly provides the free energy; for irreversible reactions the free energy is obtained from the distribution of work values. The rate constants for the folding and unfolding reactions can be measured by several methods. The effect of pulling rate on the distribution of force-unfolding values leads to rate constants for unfolding. Hopping of the RNA between folded and unfolded states at constant force provides both unfolding and folding rates. Force-jumps and force-drops, similar to the temperature jump method, provide direct measurement of reaction rates over a wide range of forces. The advantages of applying force and using single-molecule methods are discussed. These methods, for example, allow reactions to be studied in non-denaturing solvents at physiological temperatures; they also simplify analysis of kinetic mechanisms because only one intermediate at a time is present. Unfolding of RNA in biological cells by helicases, or ribosomes, has similarities to unfolding by force.     

Procedure for the base composition of RNA especially suited for samples containing relatively large amounts of DNA and protein

An inexpensive procedure suitable for determining the base composition of RNA in a sample containing large amounts of DNA and protein is presented. The method involves cold acid precipitation, mild alkaline hydrolysis, acid hydrolysis, ion-exchange separation, and spectral analysis. At least 70 μg RNA is required, which for accuracy within 7% should be no less than 4% dry weight in a chromatin sample or 2% dry weight in a ribonucleoprotein sample. Purine-pyrimidine ratios may be obtained on samples with relatively even less RNA. The precision is approximately ±2% for the values of the individual bases, and the over-all RNA recovery is 90%. Despite the multiple steps involved, three samples may be carried through the entire procedure in one day.     

A method for enzymic extraction and the measurement of chloroplast RNA

A method is described for measuring RNA associated with chloroplast thylakoid membranes. Washed thylakoids are incubated with ribonucleases A and T(1), under low Mg(2+) conditions, to release hydrolyzed RNA into solution. After removing the membranes by centrifugation, the mono- and oligonucleotides are adsorbed by Dowex 1-X2 in miniature columns made from Pasteur pipettes, and then eluted with 2 n HCl. RNA is estimated from the absorbance of the eluate at 260 nanometers, with corresponding values obtained by the orcinol reaction for pentose. Polyacrylamide gel electrophoresis patterns of extracted RNA indicate that our current procedures for preparation of thylakoids results in material containing variable and often significant levels of RNA from 80S ribosomes. Thus values for total RNA cannot be used as a valid estimate for the level of 70S ribosomes associated with these membranes, unless an additional procedure is used to estimate the per cent contamination by 80S ribosomes.Recoveries of digested RNA from the Dowex resin of 94 to 98% were obtained with 2 milliliters of HCl eluant, making possible the analysis of thylakoid samples with as little as 4 micrograms of RNA. The procedure involves small columns and only one centrifugation, so that it is useful for obtaining reliable measurements from multiple samples.     

Joint use of light, X-ray and neutron scattering for investigation of RNA and protein mutual distribution within the 50S subparticle of E. coli ribosomes.

The values of the RNA and protein radius of gyration obtained in these studies corroborate the conclusion reported earlier [1] that on average the RNA is nearer to the center of the particle than is the protein. (It should be noted for comparison that the minimal Rg value of the RNA corresponding to its dense packing as a sphere in the center of the 52S subparticle is 49 A.) Moreover, such a great difference in the radii of gyration of RNA and protein implies a definite scheme of mutual RNA and protein arrangement in the 50S subparticle -- namely the distribution of the greater mass of proteins on the RNA surface.     

Improved thermodynamic parameters and helix initiation factor to predict stability of DNA duplexes.

To improve the previous DNA/DNA nearest-neighbor parameters, thermodynamic parameters (deltaH degrees, deltaS degrees and deltaG degrees) of 50 DNA/DNA duplexes were measured. Enthalpy change of a helix initiation factor is also considered though the parameters reported recently did not contain the factor. A helix initiation factor for DNA/DNA duplex determined here was the same as that of RNA/RNA duplex (deltaG degrees(37) = 3.4 kcal/mol). The improved nearest-neighbor parameters reproduced not only these 50 experimental values used here but also 15 other experimental values obtained in different studies. Comparing deltaG degrees(37) values of DNA/DNA nearest-neighbor parameters obtained here with those of RNA/RNA and RNA/DNA, RNA/RNA duplex was generally the most stable of the three kinds of duplexes with the same nearest-neighbor sequences. Which is more stable between DNA/DNA and RNA/DNA duplexes is sequence dependent.     

Simulated bacterial growth

A mathematical model system for the simulation of bacterial growth is presented, based on eight observable growth parameters used as input. These parameters reflect the chain elongation rates of DNA, RNA and protein, the control of stable RNA and RNA polymerase genes, the functional activities of ribosomes and RNA polymerase, and the control of DNA replication and cell division. With observed values for these parameters, the model system simulates the exponential increase in the number of ribosomes and RNA polymerase molecules, as well as in the amounts of DNA, RNA and protein and in the cell number. The doubling time of this exponential increase and the simulated cell composition (DNA, RNA and protein per cell, or RNA and protein per genome) assume the correct values typical for the culture in which the input parameters were observed, and independent of the zero time conditions of the system which can be arbitrarily chosen. The simulation can be used to check the consistency of observed growth parameters, or to indirectly find the kinetic behavior of growth parameters which cannot be readily observed, or to analyze experiments involving a perturbation of steady-state growth. As examples of the latter, the simulation of a “step-up” experiment is presented in which the effects of a step-wise increase in the DNA replication velocity are analyzed, and the simulation of a nutritional shift-up, in which the kinetic changes in the gene activities for rRNA and rprotein genes are examined.     

Stability of nuclear RNA in mammalian cells

The kinetics of entry of [³H]adenosine into ATP, cellular RNA, and nuclear RNA of mouse L cells were determined and analyzed. A molar accumulation curve for RNA was estimated from the specific radioactivities of RNA and ATP; this curve was resolved graphically into stable and unstable components. The stability of the unstable component (mostly heterogeneous nuclear RNA) was estimated by applying first-order decay analysis. Heterogeneous, nuclear RNA decays with an apparently uniform half-life of 23 minutes, considerably greater than some previous estimates. It is synthesized at an instantaneous rate of 5.4 × 10^?2 pg/cell per minute and reaches a steady-state level of 1.8 pg/cell in the nucleus, or 7% of the total cellular RNA. Only about 2% of the heterogeneous RNA synthesized in L cells enters polysomes as messenger RNA. The implications of these values are discussed with reference to similarly determined values for sea urchin embryos.     

Thermodynamic characterization of RNA 2 × 3 nucleotide internal loops

To better elucidate RNA structure-function relationships and to improve the design of pharmaceutical agents that target specific RNA motifs, an understanding of RNA primary, secondary, and tertiary structure is necessary. The prediction of RNA secondary structure from sequence is an intermediate step in predicting RNA three-dimensional structure. RNA secondary structure is typically predicted using a nearest neighbor model based on free energy parameters. The current free energy parameters for 2 × 3 nucleotide loops are based on a 23-member data set of 2 × 3 loops and internal loops of other sizes. A database of representative RNA secondary structures was searched to identify 2 × 3 nucleotide loops that occur in nature. Seventeen of the most frequent 2 × 3 nucleotide loops in this database were studied by optical melting experiments. Fifteen of these loops melted in a two-state manner, and the associated experimental ΔG°(37,2×3) values are, on average, 0.6 and 0.7 kcal/mol different from the values predicted for these internal loops using the predictive models proposed by Lu, Turner, and Mathews [Lu, Z. J., Turner, D. H., and Mathews, D. H. (2006) Nucleic Acids Res. 34, 4912-4924] and Chen and Turner [Chen, G., and Turner, D. H. (2006) Biochemistry 45, 4025-4043], respectively. These new ΔG°(37,2×3) values can be used to update the current algorithms that predict secondary structure from sequence. To improve free energy calculations for duplexes containing 2 × 3 nucleotide loops that still do not have experimentally determined free energy contributions, an updated predictive model was derived. This new model resulted from a linear regression analysis of the data reported here combined with 31 previously studied 2 × 3 nucleotide internal loops. Most of the values for the parameters in this new predictive model are within experimental error of those of the previous models, suggesting that approximations and assumptions associated with the derivation of the previous nearest neighbor parameters were valid. The updated predictive model predicts free energies of 2 × 3 nucleotide internal loops within 0.4 kcal/mol, on average, of the experimental free energy values. Both the experimental values and the updated predictive model can be used to improve secondary structure prediction from sequence.     

Synthesis and properties of fluorescent nucleotide substrates for DNA-dependent RNA polymerases.

A new class of fluorescent nucleotide analogs which contain the fluorophore 1-aminonaphthalene-5-sulfonate attached via a gamma-phosphoamidate bond has been synthesized. Both the purine and pyrimidine analogs have fluorescence emission maxima at 460 nm. Cleavage of the alpha-beta-phosphoryl bond produces change in both the absorption and fluorescence emission spectra. The fluorescence of the pyrimidine analogs is quenched; cleavage of the alpha-beta-phosphoryl bond of the UTP analog produces about a 14-fold increase in fluorescence intensity at 500 nm. Under the same conditions the fluorescence of the CTP analog increases about 8-fold, whereas the fluorescence of the purine analogs shows only a slight change. These derivatives are good substrates for Escherichia coli RNA polymerase with only slightly increased Km values and with Vmax values about 50 to 70% that of the normal nucleotides. They are used less efficiently by wheat germ RNA polymerase II. The ATP analog can be used by E. coli RNA polymerase to initiate RNA chains.