Sequence and conformation of 5 S RNA from Chlorella cytoplasmic ribosomes: comparison with other 5 S RNA molecules

The sequence of Chlorella cytoplasmic 5 S RNA has been determined by fingerprinting techniques. Partial digests were fractionated by a two-dimensional acrylamide gel electrophoretic technique, which indicates whether specific fragments are paired in the molecule. In this way, the four main base-paired regions of the molecule were located. The sequence of Chlorella cytoplasmic 5 S RNA is related to, but different from, that of other eukaryotic 5 S RNAs: it shows approximately 60% homology with vertebrate 5 S RNA and 40% homology with yeast 5 S RNA. In some respects the conformation of the molecule in solution is quite different from that of other sequenced 5 S RNAs: in particular, the highly accessible region found around position 40 in all other 5 S RNAs (prokaryotic and eukaryotic) does not exist in this molecule.     

Nucleotide sequence of Dictyostelium small nuclear RNA Dd8 not homologous to any other sequenced small nuclear RNA

The cellular slime mold Dictyostelium discoideum, a lower eukaryote, was shown to contain several species of small nuclear RNA (Takeishi, K., and Kaneda, S. (1981) J. Biochem. (Tokyo) 90, 299-308; Wise, J. A., and Weiner, A. M. (1981) J. Biol. Chem. 256, 956-963). One of these RNAs, Dd9 or D2, was sequenced and found to be homologous to mammalian nucleolar U3 RNA. In the present study, the nucleotide sequence of another Dictyostelium small nuclear RNA Dd8 was determined by direct analysis. The sequence is: (formula; see text) Dd8 RNA contains high proportions of A (34%) and U (30%). No modified nucleotide could be detected in the internal region. Computer-assisted analysis of sequence homology indicated that Dd8 RNA is not homologous to any other small nuclear RNA species sequenced so far.     

The structure of the yeast ribosomal RNA genes. I. The complete nucleotide sequence of the 18S ribosomal RNA gene from Saccharomyces cerevisiae.

The cloned 18 S ribosomal RNA gene from Saccharomyces cerevisiae have been sequenced, using the Maxam-Gilbert procedure. From this data the complete sequence of 1789 nucleotides of the 18 S RNA was deduced. Extensive homology with many eucaryotic as well as E. coli ribosomal small subunit rRNA (S-rRNA) has been observed in the 3'-end region of the rRNA molecule. Comparison of the yeast 18 S rRNA sequences with partial sequence data, available for rRNAs of the other eucaryotes provides strong evidence that a substantial portion of the 18 S RNA sequence has been conserved in evolution.     

Plant small nuclear RNAs. V. U4 RNA is present in broad bean plants in the form of sequence variants and is base-paired with U6 RNA.

U4 RNA, which is known to play an indispensable role in pre-mRNA splicing, is present in plant nuclei, has a canonical m3 2,2,7 G cap at its 5' end and is associated with U6 RNA in snRNP particles. It occurs in broad bean in the form of a number of sequence variants. Two of these were sequenced: U4A RNA is 154 and U4B RNA is 152 nucleotides long. Sequence similarity of broad bean U4B RNA is 94 per cent to broad bean U4A RNA, 65 per cent to rat U4A RNA, 61 per cent to Drosophila U4A RNA and 50 per cent to snR14, the U4 RNA equivalent of the yeast Saccharomyces cerevisiae. Sequence conservation is much more pronounced in the 5' half of the molecule than in its 3' half. The secondary structure of both variants of broad bean U4 RNA perfectly fits with that of all other U4 RNAs sequenced so far. Nucleotide changes between broad bean U4A and U4B RNAs are restricted to molecular regions that affect the thermodynamic stability of these molecules. A model is proposed for the base pairing interaction of broad bean U4 RNA with broad bean U6 RNA. This is the first report on the structure of a plant U4 RNA.     

Identification of the major spliceosomal RNAs in Dictyostelium discoideum reveals developmentally regulated U2 variants and polyadenylated snRNAs

Most eukaryotic mRNAs depend upon precise removal of introns by the spliceosome, a complex of RNAs and proteins. Splicing of pre-mRNA is known to take place in Dictyostelium discoideum, and we previously isolated the U2 spliceosomal RNA experimentally. In this study, we identified the remaining major spliceosomal RNAs in Dictyostelium by a bioinformatical approach. Expression was verified from 17 small nuclear RNA (snRNA) genes. All these genes are preceded by a putative noncoding RNA gene promoter. Immunoprecipitation showed that snRNAs U1, U2, U4, and U5, but not U6, carry the conserved trimethylated 5' cap structure. A number of divergent U2 species are expressed in Dictyostelium. These RNAs carry the U2 RNA hallmark sequence and structure motifs but have an additional predicted stem-loop structure at the 5' end. Surprisingly, and in contrast to the other spliceosomal RNAs in this study, the new U2 variants were enriched in the cytoplasm and were developmentally regulated. Furthermore, all of the snRNAs could also be detected as polyadenylated species, and polyadenylated U1 RNA was demonstrated to be located in the cytoplasm.     

Isolation and partial characterization of U1-U6 small RNAs from Bombyx mori

We have used a variety of techniques to characterize the U-series small nuclear RNAs from the posterior silk gland of Bombyx mori. Six molecular species have been identified which correspond to the vertebrate U1-U6 RNAs by the following criteria: (a) presence of the RNAs in ribonucleoprotein particles which can be immunoprecipitated by lupus Sm antisera; (b) presence of a 2,2,7-trimethylguanosine cap, as assayed by immunoprecipitation with anti-2,2,7-trimethylguanosine IgG; (c) size, as assayed by acrylamide/urea gel electrophoresis using HeLa cell U-RNA markers; and (d) primary nucleotide sequence, as determined by chemical/enzymatic cleavage of end-labeled molecules. The high conservation of primary sequence (66-81% homology based on partial sequences) relative to the corresponding vertebrate U-RNAs has permitted unambiguous identification of each molecule. With the exception of two subspecies of U3 RNA, the U-snRNAs of Bombyx exhibit a striking conservation of secondary structure relative to the proposed structures of the U-RNAs of vertebrates. This conservation is best exemplified by several compensatory base alterations that result in the maintenance of hairpin structures. These are particularly evident in U1 and U5 RNAs. Bombyx U3 is interesting in that two subspecies (of a total of four that were sequenced) diverge considerably in sequence (and presumably in structure) relative to the U3 RNA of vertebrates. The most abundant U-RNAs in the posterior silk gland appear to be U1 and U2, while U3-U6 are present in relatively small amounts.     

Recent developments in methods for RNA sequencing using in vitro 32P-labeling

A variety of approaches that utilize in vitro 32P-labeling of RNA and of oligonucleotides in the sequence analysis of RNAs are described. These include 1) methods for 5'- and 3'- end labeling of RNAs; 2) end labeling and sequencing of oligonucleotides present in complete T1 RNase or pancreatic RNase digests of RNA; 3) use of random endonucleases, such as nuclease P1, for terminal sequence analysis of end labeled RNAs; and 4) use of base specific enzymes or chemical reagents in the sequence analysis of end-labeled RNAs. Also described is an approach to RNA sequencing, applied so far to tRNAs, which is based on partial and random alkaline cleavage of an RNA to generate a series of overlapping oligonucleotide fragments, all containing the original 3'-end of the RNA. Analysis of the 5'- end group of each of these oligonucleotides (following 5'-end labeling with 32P) provides the sequence of most of the tRNA. The above methods have been used to derive the sequences of several tRNAs, the ribosomal 5S and 5 x 8S RNAs, a viroid RNA, and large segments of both prokaryotic and eukaryotic ribosomal and messenger RNAs.     

An essential domain in Saccharomyces cerevisiae U14 snoRNA is absent in vertebrates, but conserved in other yeasts.

U14 is a small nucleolar RNA (snoRNA) required for early cleavages of eukaryotic precursor rRNA. The U14 RNA from Saccharomyces cerevisiae is distinguished from its vertebrate homologues by the presence of a stem-loop domain that is essential for function. This element, known as the Y-domain, is located in the U14 sequence between two universal sequences that base pair with 18S rRNA. Sequence data obtained for the U14 homologues from four additional phylogenetically distinct yeasts showed the Y-domain is not unique to S.cerevisiae. Comparison of the five Y-domain sequences revealed a common stem-loop structure with a conserved loop sequence that includes eight invariant nucleotides. Conservation of these features suggests that the Y-domain is a recognition signal for an essential interaction. Several plant U14 RNAs were found to contain similar structures, though with an unrelated consensus sequence in the loop portion. The U14 gene from the most distantly related yeast, Schizosaccharomyces pombe, was found to be active in S.cerevisiae, showing that Y-domain function is conserved and that U14 function can be provided by variants in which the essential elements are embedded in dissimilar flanking sequences. This last result suggests that U14 function may be determined solely by the essential elements.     

The 3'-terminal primary structure of five eukaryotic 18S rRNAs determined by the direct chemical method of sequencing. The highly conserved sequences include an invariant region complementary to eukaryotic 5S rRNA.

The 3'-terminal sequences of 18S rRNA from chicken reticulocyte, mouse sarcoma, rat liver, rabbit reticulocyte and barley embryo were determined by the direct chemical sequencing method. The regions sequenced show complete homology for the first 73 nucleotides. A sequence 5'-proximal to the m6(2)Am6(2)A residues that is complementary to eukaryotic 5S RNAs is totally conserved. This supports the hypothesis that base-paired interaction between 5S and 18S rRNA, which are present in the large and small ribosomal subunits respectively, may be involved in the reversible association of ribosomal subunits during protein synthesis.     

The nucleotide sequence of 5S rRNA from an extreme thermophile, Thermus thermophilus HB8

Using 3'- and 5'-end labelling sequencing techniques, the following primary structure for Thermusthermophilus HB8 5S RNA could be determined: pAA (U) CCCCCGUGCCCAUAGCGGCGUGGAACCACCCGUUCCCAUUCCGAACACGGAAGUGAAACGCGCCAGCGCC GAUGGUACUGGCGGACGACCGCUGGGAGAGUAGGUCGGUGCGGGGGA (OH). This sequence is most similar to Thermusaquaticus 5S RNA with which it shows 85% homology.     

U2 RNA from yeast is unexpectedly large and contains homology to vertebrate U4, U5, and U6 small nuclear RNAs

I have determined the structure of the gene from Saccharomyces cerevisiae coding for the yeast homolog of vertebrate U2 snRNA. Surprisingly, the RNA is 1175 nucleotides long, six times larger than U2 RNAs from other organisms, including Schizosaccharomyces pombe. Nearly 100 nucleotides of the large RNA share sequence homology and potential secondary structure with metazoan U2. The large RNA also contains homology to vertebrate U4, U5, and U6 snRNAs, implying a "poly-snRNP" structure for the RNP containing the large RNA. The gene LSR1, encoding the large RNA, is essential for growth, suggesting that the yeast spliceosome can be dissected using genetic approaches. The different organization of spliceosomal RNA may underlie differences in splicing between yeast and metazoans.     

Isolation from rat liver and sequence of a RNA fragment containing 32 nucleotides from position 5 to 36 from the 3'' end of ribosomal 18S RNA.

Crude tRNA isolated from rat liver by the method of Rogg et al. (Biochem. Biophys. Acta 195, 13-15 1969) contains N6-dimethyladenosine (m6-2A) and was therefore fractionated in order to identify the m6-2A-containing RNAs. A unique species of RNA was purified which contained all the m62A present in the crude tRNA. Sequence analysis by postlabeling with gamma-32p-ATP and polynucleotide kinase revealed that this RNA represents the 32 nucleotides AAGGUUUC(C)U GUAGGUGm62Am62ACCUGCGGAAGGAUC from position 5 to 36 of the 3' terminus of ribosomal 18S RNA. The 36 nucleotide long sequence from the 3' end of rat liver 18S rRNA exhibits extensive homology with the corresponding sequence of E. coli 16S rRNA and with the 21 nucleotide long 3' terminal sequence so far known from Saccharomyces carlsbergensis 17S rRNA. A heterogeneity in this sequence provides the first evidence on the molecular level for the existence of (at least) two sets of redundant ribosomal 18S RNA genes in the rat.