Identification and assignment of base pairs in four helical segments of Bacillus megaterium ribosomal 5S RNA and its ribonuclease T1 cleavage fragments by means of 500-MHz proton homonuclear Overhauser enhancements.

Three different fragments of Bacillus megaterium ribosomal 5S RNA have been produced by enzymatic cleavage with ribonuclease T1. Fragment A consists of helices II and III, fragment B contains helix IV, and fragment C contains helix I of the universal 5S rRNA secondary structure. All (eight) imino proton resonances in the downfield region (9-15 ppm) of the 500-MHz proton FT NMR spectrum of fragment B have been identified and assigned as G80.C92-G81.C91-G82.C90-A83.++ +U89-C84.G88 and three unpaired U's (U85, U86, and U87) in helix IV by proton homonuclear Overhauser enhancement connectivities. The secondary structure in helix IV of the prokaryotic loop is completely demonstrated spectroscopically for the first time in any native or enzyme-cleaved 5S rRNA. In addition, G21.C58-A20.U59-G19.C60-A18.U61 in helix II, U32.A46-G31.C47-C30.G48-C29.G49 in helix III, and G4.C112-G5.C111-U6.G110 in the terminal stem (helix I) have been assigned by means of NOE experiments on intact 5S rRNA and its fragments A and C. Base pairs in helices I-IV of the universal secondary structure of B. megaterium 5S RNA are described.     

Identification of three G.U base pairs in Bacillus subtilis ribosomal 5S RNA via 500-MHz proton homonuclear Overhauser enhancements

Three distinct G.U base pairs in Bacillus subtilis 5S RNA have been identified via homonuclear Overhauser enhancements (NOE) of their low-field (9-15 ppm) proton Fourier transform nuclear magnetic resonances at 11.75 T. With these G.U resonances as starting points, short segments of NOE connectivity can be established. One G.U-G.C-G.C segment (most probably G4.C112-G5.C111-U6.G110) can definitely be assigned to the terminal helix. The existence of at least part of the terminal helical stem of the secondary structure of a Gram-positive bacterial 5S RNA has thus been established for the first time by direct experimental observation. Addition of Mg2+ produces almost no conformational changes in the terminal stem but results in major conformational changes elsewhere in the structure, as reflected by changes in the 1H 500-MHz low-field NMR spectrum. Assignment of the two remaining G.U base pairs will require further experiments (e.g., enzymatic-cleavage fragments). Finally, the implications of these results for analysis of RNA secondary structure are discussed.     

Identification and assignment of base pairs in three helical stems of Torulopsis utilis ribosomal 5S RNA and its RNase T1 and RNase T2 cleaved fragments via 500-MHz proton homonuclear overhauser enhancements

Imino proton resonances in the downfield region (10-14 ppm) of the 500-MHz 1H NMR spectrum of Torulopsis utilis 5S RNA are identified (A X U, G X C, or G X U) and assigned to base pairs in helices I, IV, and V via analysis of homonuclear Overhauser enhancements (NOE) from intact T. utilis 5S RNA, its RNase T1 and RNase T2 digested fragments, and a second yeast (Saccharomyces cerevisiae) 5S RNA whose nucleotide sequence differs at only six residues from that of T. utilis 5S RNA. The near-identical chemical shifts and NOE behavior of most of the common peaks from these four RNAs strongly suggest that helices I, IV, and V retain the same conformation after RNase digestion and that both T. utilis and S. cerevisiae 5S RNAs share a common secondary and tertiary structure. Of the four G X U base pairs identified in the intact 5S RNA, two are assigned to the terminal stem (helix I) and the other two to helices IV and V. Seven of the nine base pairs of the terminal stem have been assigned. Our experimental demonstration of a G X U base pair in helix V supports the 5S RNA secondary structural model of Luehrsen and Fox [Luehrsen, K. R., & Fox, G.E. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 2150-2154]. Finally, the base-pair proton peak assigned to the terminal G X U in helix V of the RNase T2 cleaved fragment is shifted downfield from that in the intact 5S RNA, suggesting that helices I and V may be coaxial in intact T. utilis 5S RNA.     

500-MHz proton homonuclear Overhauser evidence for additional base pair in the common arm of eukaryotic ribosomal 5S RNA: wheat germ

A "common-arm" fragment from wheat germ (Triticum aestivum) 5S RNA has been produced by enzymatic cleavage with RNase T1 and sequenced via autoradiography of electrophoresis gels for the end-labeled fragments obtained by further RNase T1 partial digestion. The existence, base pair composition, and base pair sequence of the common arm are demonstrated for the first time by means of proton 500-MHz nuclear magnetic resonance. From Mg2+ titration, temperature variation, ring current calculations, sequence comparisons, and proton homonuclear Overhauser enhancement experiments, additional base pairs in the common arm of the eukaryotic 5S RNA secondary structure are detected. Two base pairs, G41 X C34 and A42 X U33 in the hairpin loop, could account for the lack of binding between the conserved GAAC segment of 5S RNA and the conserved Watson-Crick-complementary GT psi C segment of tRNAs.     

Demonstration of the GC-rich common arm in yeast ribosomal 5.8S RNA via 500-MHz proton nuclear magnetic resonance and Overhauser enhancements

In this paper we report the first 1H NMR study of the base-paired secondary structure of yeast 5.8S RNA. On the basis of a combination of homonuclear Overhauser enhancements and temperature dependence of the proton 500-MHz NMR spectrum, we are able to identify and assign eight of the nine base pairs in the most thermally stable helical arm: G116.C137-C117.G136-C118.G135- C119.G134-C120.G133-U121.G132- U122.A131-G123.C130. This arm contains an unusually temperature-stable (to 71 degrees C) segment of four consecutive G.C base pairs. This work constitutes the most direct evidence to date for the existence and base-pair sequence of the GC-rich helix, which is common to most currently popular secondary structural models for eukaryotic 5.8S ribosomal RNA.     

Morpholino spin-labeling for base-pair sequencing of a 3'-terminal RNA stem by proton homonuclear Overhauser enhancements: yeast ribosomal 5S RNA

Base-pair sequences for 5S and 5.8S RNAs are not readily extracted from proton homonuclear nuclear Overhauser enhancement (NOE) connectivity experiments alone, due to extensive peak overlap in the downfield (11-15 ppm) proton NMR spectrum. In this paper, we introduce a new method for base-pair proton peak assignment for ribosomal RNAs, based upon the distance-dependent broadening of the resonances of base-pair protons spatially proximal to a paramagnetic group. Introduction of a nitroxide spin-label covalently attached to the 3'-terminal ribose provides an unequivocal starting point for base-pair hydrogen-bond proton NMR assignment. Subsequent NOE connectivities then establish the base-pair sequence for the terminal stem of a 5S RNA. Periodate oxidation of yeast 5S RNA, followed by reaction with 4-amino-2,2,6,6-tetramethylpiperidinyl-1-oxy (TEMPO-NH2) and sodium borohydride reduction, produces yeast 5S RNA specifically labeled with a paramagnetic nitroxide group at the 3'-terminal ribose. Comparison of the 500-MHz 1H NMR spectra of native and 3'-terminal spin-labeled yeast 5S RNA serves to identify the terminal base pair (G1 . C120) and its adjacent base pair (G2 . U119) on the basis of their proximity to the 3'-terminal spin-label. From that starting point, we have then identified (G . C, A . U, or G . U) and sequenced eight of the nine base pairs in the terminal helix via primary and secondary NOE's.     

500-MHz proton NMR evidence for two solution structures of the common arm base-paired segment of wheat germ 5S ribosomal RNA

The base-pair protons of the common arm duplex fragment of wheat germ (Triticum aestivum) ribosomal 5S RNA have been identified and assigned by means of 500-MHz proton NMR spectroscopy. The two previously reported extra base pairs within the fragment [Li et al. (1987) Biochemistry 26, 1578-1585] are now explained by the presence of two distinct solution structures of the common arm fragment (and its corresponding base-paired segment in intact 5S rRNA). The present conclusions are supported by one- and two-dimensional proton homonuclear Overhauser enhancements in H2O and by temperature variation and Mg2+ titration of the downfield 1H NMR spectrum. The difference between the two conformers is most likely due to difference in helical tightness. Some additional amino proton resonances have also been assigned.     

Sequence analysis of T1 ribonuclease fragments of 18S ribosomal RNA by 5''-terminal labeling, partial digestion, and homochromatography fingerprinting.

The method employed to determine the sequence of a T1 RNase fragment, A-A-A-A-A-U-A-A-C-A-A-U-A-C-A-Gp, from Novikoff rat hepatoma 18S ribosomal RNA is described. This method is applicable to any oligoribonucleotide produced by specific endonucleases that leave the newly cleaved 5'-end free for labeling with polynucleotide kinase and gamma-(32p)-ATP. The (32p)-labeled oligoribonucleotide is subjected to partial endonucleolytic digestion and fractionated by two-dimensional homochromatography fingerprinting. The nucleotide sequence is determined by following mobility shifts of the labeled and partially digested oligoribonucleotides in homochromatography fingerprinting.