Ionic conditions for the cleavage of the tRNA-like structure of turnip yellow mosaic virus by the catalytic RNA of RNase P

The 3'-end of the RNA genome of turnip yellow mosaic virus can form a pseudoknotted tRNA-like structure that can be recognized by several tRNA-specific enzymes. We have found that the catalytic RNA component of Bacillus subtilis RNase P can cleave this structure in unusually low ionic strength buffers at a site analogous to the 5'-end of an aminoacyl stem of a tRNA. Most other precursors can only be processed under low ionic strength conditions if the RNase P holoenzyme is used; processing by the catalytic RNA component alone requires a higher ionic strength buffer. The cleavage of the turnip yellow mosaic virus tRNA-like structure demonstrates the importance of the substrate in determining the optimal buffer conditions for this reaction and also shows that high ionic strength buffers are not always necessary for cleavage by the catalytic RNA.     

A 2H-NMR study of the A-DNA conformation in films of oriented Na-DNA: evidence of a disordered B-DNA contribution

Solid-state ²H-nmr spectra have been obtained from folded films of oriented Li- and Na-DNA molecules with the purine bases selectively deuterium labeled at the 8 position. From line shape simulations, we find that the Na-DNA sample at 75% relative humidity (rh) contains both A-DNA and surprisingly large amounts of B-DNA

1 Here, B-DNA refers to “B-DNA family” (i.e. B- or C-DNA).

(57%). For the A-DNA component the average base tilt is 23°, and the total distribution width of tilt angles and helix axis orientations is ～ 4° (standard deviation). In the B-DNA component the base tilt is ～ 0° and the total distribution width is ～ 20°. In contrast, films of Li-DNA only exhibit the B-form line shape, consistent with a base tilt of ～ 0° and a total distribution width of base tilt angles and helix axis orientations of 9°. The nmr results that demonstrate the presence of large amounts of B-DNA in the Na-DNA sample contrast with the x-ray diffraction measurements that indicated mainly A-form. The nmr spectra are used to monitor the B-DNA content in the Na-films and to evaluate procedures for increasing the A-DNA fraction.     

Effects of hydration on purine motion in solid DNA

Deuterium quadrupole echo spectra and spin-lattice relaxation rates measured at 76.8 and 38.4 MHz as a function of relative humidity are reported for calf thymus DNA deuterated at positions A8 and G8. The amplitude of base pair motion is observed to increase slightly with increasing degree of hydration (up to approximately 20 mol of H2O/nucleotide), and the onset of motion is associated with a more than 100-fold drop in T1. This observed decrease in T1 parallels that observed previously for the phosphate backbone and appears to be characteristic of collective modes of motion. Above approximately 20 mol of H2O/nucleotide, the amplitude of the base motion increases substantially up to a point where slow components of motion lead to a complete loss of the quadrupole echo.     

Antibodies to N6-(delta2-isopentenyl) adenosine and its nucleotide: interaction with purified tRNAs and with bases, nucleosides and nucleotides of the isopentenyladenosine family.

The interaction of antibodies directed toward N6-(delta2-isopentenyl)adenosine, i6Ado, or its nucleotide with related bases, nucleosides, nucleotides and purified tRNAs is described. The selectivity of the antibody preparation was tested in inhibition experiments utilizing a sensitive radioimmunoassay to quantitate the binding of [3H]i6Ado to the antibody. Purified tRNAs containing various modified nucleosides adjacent to the 3'-end of the anticodon were tested to provide information about the selectivity of the antibody preparation toward nucleotides in this position of the tRNA chain. Antibodies directed against the nucleotide hapten were used to purify tRNAs which contain i6Ado and to quantitate the amount of that nucleotide. The same order of selectivity was expressed whether the nucleotides were free or in a tRNA molecule. Interaction of the antibody with compounds from the i6Ado family demonstrated dominance of the hydrophobic isopentenyl group and the importance of positional differences of modifications.     

A cluster of nine tRNA genes between ribosomal gene operons in Bacillus subtilis.

A cluster of nine tRNA genes located in the 1-kb region between ribosomal operons rrnJ and rrnW in Bacillus subtilis has been cloned and sequenced. This cluster contains the genes for tRNA(UACVal), tRNA(UGUThr), tRNA(UUULys), tRNA(UAGLeu). tRNA(GCCGly), tRNA(UAALeu), tRNA(ACGArg), tRNA(UGGPro), and tRNA(UGCAla). The newly discovered tRNA gene cluster combines features of the 3'-end of trnI, a cluster of 6 tRNA genes between ribosomal operons rrnI and rrnH, and of the 5'-end of trnB, a cluster of 21 tRNA genes found immediately 3' to rrnB. Neither the tRNA(UAGLeu) gene nor its product has been found previously in B. subtilis. With the discovery of this new set of tRNA genes, a total of 60 such genes have now been found in B. subtilis. These known genes account for almost all of the tRNA hybridizing restriction fragments of the B. subtilis genome. The 60 known tRNA genes of B. subtilis code for only 28 different anticodons, compared with a total of 41 different anticodons for 78 tRNA genes in Escherichia coli. This may indicate that B. subtilis does not need as many anticodons because of more flexible translation rules, similar to the situation in Mycoplasma capricolum.     

Thiolation and 2-methylthio- modification of Bacillus subtilis transfer ribonucleic acids.

Six thionucleosides found in Bacillus subtilis transfer ribonucleic acids were investigated: N6-(delta 2-isopentenyl)-2-methylthioadenosine, 5-carboxymethylaminomethyl-2-thiouridine, 4-thiouridine, 2-methylthioadenosine, N-[(9-beta-D-ribofuranosyl-2-methylthiopurin-6-yl)carbamoyl]threonine, and one unknown (X1). The presence of N-[(9-beta-D-ribofuranosyl-2-methylthiopurin-6-yl)carbamoyl]threonine was demonstrated based on the affinity of the transfer ribonucleic acid containing it for an immunoadsorbent made with the antibody directed toward N-[9-(beta-D-ribofuranosyl)purin-6-ylcarbamoyl]-L-threonine. The existance of N-[(9-beta-D-ribofuranosyl-2-methylthiopurin-6-yl)carbamoyl]threonine in two species of lysine transfer ribonucleic acids was also confirmed by high-resolution mass spectrometry. Four of these thionucleosides--N6-(delta 2-isopenenyl)-2-methylthioadenosine, 2-methylthioadenosine, 5-carboxymethylaminomethyl-2-thiouridine, and the unknown designated X1--occurred only in specific areas in the elution profile of an RPC-5 column and probably affect the chromatographic properties of the transfer ribonucleic acids containing them. In contrast with Escherichia coli, where 4-thiouridine is the most frequent type of sulfur-containing modification, approximately one-third of the sulfur groups in B. subtilis transfer ribonucleic acid are present as thiomethyl groups on the 2 position of an adenosine or modified adenosine residue.     

Radioimmunoassays for the modified nucleosides N[9-(beta-D-ribofuranosyl)purin-6-ylcarbamoyl]-L-threonine and 2-methylthioadenosine.

Radioimmunoassays were established for the modified nucleosides N-[9-(beta-D-ribofuranosyl)purin-6-ylcarbamoyl]-L-threonine, t6A, and 2-methylthioadenosine, ms2A. The assays depended on the production of antisera specific for t6A and ms2A that have not been previously reported. The nitrocellulose membrane filtration and saturated ammonium sulfate RIA techniques were compared for efficiency. Various radioactive antigens were employed to establish which type of antigen would give the best binding. The tritium post-labeling procedure of Randerath and Randerath was used to obtain labeled nucleosides of high enough specific activity to be useful for RIAs when the labeled nucleoside was not available commerically. The specificity of the antibodies toward nucleosides and purified tRNAs is reported. Although the titer of the t6A antiserum was low, the specificity was very sharp. An interesting finding was that threonine, a major structural component of the side-chain modification of t6A, was completely infective as an inhibitor.     

Modified nucleosides of Bacillus subtilis transfer ribonucleic acids.

An analysis of the kinds and amounts of minor nucleosides of transfer ribonucleic acids (tRNA's) from Bacillus subtilis 168 trpC2 is presented. Identification and quantitation were accomplished using ion exclusion chromatography, thin-layer and paper chromatography, and ultraviolet absorption properties. Nucleosides and their amount in moles per 80 residues are as follows: guanosine (25.7), cytidine (22.0), adenosine (15.2), uridine (13.1), 5-methyluridine (0.98), pseudouridine (1.54), 1-methyladenosine (0.15), N6-methyladenosine (0.01), 7-methyladenosine (0.10), 2-methyladenosine (0.03), 7-methylguanosine (0.20), N2-methylguanosine (0.14), 1-methylguanosine (0.14), a methylated pyrimidine (0.17), a methylated derivative of N6-(delta 2-isopentenyl)adenosine (0.02), ribose methylated nucleosides (0.02), 4-thiouridine (0.12), 2-thio-5-(N-methylaminomethyl) (0.09), and an unknown thionucleoside (0.12). Although the composition is similar to that of Escherichia coli in the proportion of major nucleosides, the content of pseudouridine and 5-methyluridine, and the degree of base and ribose methylation, the composition is more similar to that of the tRNA's of yeast and higher organisms in its lower degree of thiolation, the presence of significant amounts of 1-methyladenosine, and the low levels of 2-methyladenosine and 6-methyladenosine. Therefore, the nucleoside composition of B. subtilis presents some different aspects from those usually given as characteristic for bacterial tRNA's. It is not known whether these differences are due to variation between bacterial species in general or related to the process of differentiation.