Gene heterogeneity: a basis for alternative 5.8S rRNA processing

Two bands of 5.8S rRNA were observed when the total RNA isolated from rat or mouse tissue was separated by electrophoresis on high-resolution polyacrylamide gels under denaturing conditions. The minor form, with a lower mobility, represented 15-35% of the total 5.8S rRNA, depending on the source of the tissue. Sequence analysis and the kinetics of formation showed that this minor form is elongated at the 5' end and is not a precursor. The sequence of the minor form was found to be p(C)CGAUA[CG-, five or six nucleotides longer than the major form. The minor 5.8S rRNA constituent also formed a more stable junction complex with 28S rRNA than the shorter major sequence. The rat DNA sequence that corresponds to the additional nucleotides at the 5' end of 5.8S rRNA has been reported to be -CCGTACG-[Subrahmanyam, C. S., Cassidy, B., Busch, H., & Rothblum, L. I. (1982) Nucleic Acids Res. 10, 3667-3680], a sequence which does not contain the extra adenylic acid residue at position 4 found in the minor form. This suggests that the rodent rRNA genes are heterogeneous and that the insertion of an A residue in the ribosomal precursor RNA can generate an alternate processing site.     

Non-ribosomal nucleotide sequences in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA in yeast.

The topography and the length of the non-ribosomal sequences present in 7-S RNA, the immediate precursor of 5.8-S ribosomal RNA, from the yeast Saccharomyces carlsbergensis were determined by analyzing the nucleotide sequences of the products obtained after complete digestion of 7-S RNA with RNase T1. The results show that 7-S RNA contains approximately 150 non-ribosomal nucleotides. The majority (90%) of the 7-S RNA molecules was found to have the same 5'-terminal pentadecanucleotide sequence as mature 5.8-S rRNA. The remaining 10% exhibited 5'-terminal sequences identical to those of 5.9-S RNA, which has the same primary structure as 5.8-S rRNA except for a slight extension at the 5' end [Rubin, G.M. (1974) Eur. J. Biochem. 41, 197--202]. These data show that the non-ribosomal nucleotides present in 7-S RNA are all located 3'-distal to the mature 5.8-S rRNA sequence. Moreover, it can be concluded that 5.9-S RNA is a stable rRNA rather than a precursor of 5.8-S rRNA. The 3'-terminal sequence of 5.8-S rRNA (U-C-A-U-U-UOH) is recovered in a much longer oligonucleotide in the T1 RNase digest of 7-S RNA having the sequence U-C-A-U-U-U-(C-C-U-U-C-U-C)-A-A-A-C-A-(U-U-C-U)-Gp. The sequences enclosed in brackets are likely to be correct but could not be established with absolute certainty. The arrow indicates the bond cleaved during processing. The octanucleotide sequence -A-A-A-C-A-U-U-C- located near the cleavage site shows a remarkable similarity to the 5'-terminal octanucleotide sequence of 7-S RNA (-A-A-A-C-U-U-U-C-). We suggest that these sequences may be involved in determining the specificity of the cleavages resulting in the formation of the two termini of 5.8-S rRNA.     

Some characteristics of processing sites in ribosomal precursor RNA of yeast.

The DNA sequences of the intergenic region between the 17S and 5.8S rRNA genes of the ribosomal RNA operon in yeast has been determined. In this region the 37S ribosomal precursor RNA is specifically cleaved at a number of sites in the course of the maturation process. The exact position of these processing sites has been established by sequence analysis of the terminal fragments of the respective RNA species. There appears to be no significant complementarity between the sequences surrounding the two termini of the 18S secondary precursor RNA nor between those surrounding the two termini of 17S mature rRNA. This finding implies that the processing of yeast 37S ribosomal precursor RNA is not directed by a double-strand specific ribonuclease previously shown to be involved in the processing of E. coli ribosomal precursor RNA [see Refs 1,2]. The processing sites of yeast ribosomal precursor RNA described in the present paper are all flanked at one side by a very [A+T]-rich sequence. In addition, sequence repeats are found around the processing sites in this precursor RNA. Finally, sequence homologies are present at the 3'-termini [6 nucleotides] and the 5'-termini [13 nucleotides] of a number of mature rRNA products and intermediate ribosomal RNA precursors. These structural features are discussed in terms of possible recognition sites for the processing enzymes.     

Sequence of the 3''-terminal 21 nucleotides of yeast 17S ribosomal RNA.

The sequence of the 3'-terminal 21 nucleotides of 17S ribosomal RNA from the yeast Saccharomyces carlsbergensis has been determined to be (Y)G-m62A-m62A-C-U-C-G-C-G-G-A-A-G-G-A-U-C-A-U-U-AOH. This sequence shows extensive homology with the 3'-terminal sequence of 16S rRNA from Escherichia coli including the presence of the two adjacent N6-,N6-dimethyladenosines observed in the small subunit rRNA of eukaryotes as well as of many prokaryotes.     

Nucleotide sequence of an exceptionally long 5.8S ribosomal RNA from Crithidia fasciculata.

In Crithidia fasciculata, a trypanosomatid protozoan, the large ribosomal subunit contains five small RNA species (e, f, g, i, j) in addition to 5S rRNA [Gray, M.W. (1981) Mol. Cell. Biol. 1, 347-357]. The complete primary sequence of species i is shown here to be pAACGUGUmCGCGAUGGAUGACUUGGCUUCCUAUCUCGUUGA ... AGAmACGCAGUAAAGUGCGAUAAGUGGUApsiCAAUUGmCAGAAUCAUUCAAUUACCGAAUCUUUGAACGAAACGG ... CGCAUGGGAGAAGCUCUUUUGAGUCAUCCCCGUGCAUGCCAUAUUCUCCAmGUGUCGAA(C)OH. This sequence establishes that species i is a 5.8S rRNA, despite its exceptional length (171-172 nucleotides). The extra nucleotides in C. fasciculata 5.8S rRNA are located in a region whose primary sequence and length are highly variable among 5.8S rRNAs, but which is capable of forming a stable hairpin loop structure (the "G+C-rich hairpin"). The sequence of C. fasciculata 5.8S rRNA is no more closely related to that of another protozoan, Acanthamoeba castellanii, than it is to representative 5.8S rRNA sequences from the other eukaryotic kingdoms, emphasizing the deep phylogenetic divisions that seem to exist within the Kingdom Protista.     

Secondary structure of the 5'-terminal region of the 18S ribosomal RNA5.3S fragment from the rat liver

Two small RNA fragments, 5,3S and 4,7S, were observed in gel electrophoretic analysis of RNA of the 40S ribosomal subunit of rat liver. 5,3S RNA (134-136 nucleotides long) proved to be 5'-terminal fragment of 18S ribosomal RNA, whereas 4,7 RNA is the degradation product of 5,3S RNA with 27-28 5'-terminal nucleotides lost. The secondary structure of 5,3S RNA was probed with two structure-specific nucleases, S1 nuclease and the double-strand specific cobra venom endoribonuclease. The nuclease digestion data agree well with the computer generated secondary structure model for 5,3S RNA. This model predicts that the 5'-terminal part of rat liver ribosomal 18S RNA forms an independent structural domain. The affinity chromatography experiments with the immobilized 5,3S fragment show that 5,3S RNA does not bind rat liver ribosomal proteins.     

Study of a cloned ribosomal operon region coding for 5.8S rRNA in the loach Misgurnus fossilis L

A fragment of the loach (Misgurnus fossilis L.) ribosomal operon containing 5.8S rDNA and adjacent regions of the internal transcribed spacer (ITS-1, and ITS-2) was sequenced. The 5'-terminal sequencing in 5.8S rDNA was corrected by analysing the primary structure of the loach 5.8S rRNA. This RNA was shown to be presented by three types of molecules; one of these was shorter by 4 nucleotides at the 5'-end because of the processing site being shifted in the rRNA precursor. The two other types differed in the 5'-terminal nucleotide (UMP or AMP). In the cloned fragment under study, the sequence of 5.8S rDNA has TMP at the 5'-terminus. The known nucleotide sequences of 5.8S rRNAs were compared in eukaryotes; as a result, conservative regions were revealed at the sites of molecule modification. All the 5.8S rRNAs of the vertebrates studied were found to have coincidences in the localization of nucleotide substitutions and other mutations (inversions and deletions). The authors propose a model for the secondary structure of ITS-1 and ITS-2 in the region of 5.8S rRNA processing.     

The 5.8S RNA gene sequence and the ribosomal repeat of Schizosaccharomyces pombe

We have characterized the rRNA gene repeat in Schizosaccharomyces pombe. This repeat, which does not contain the 5S RNA gene, is found in a 10.4 kb HindIII DNA fragment. We have determined the nucleotide sequences of the S. pombe 5.8S RNA gene and intergenic spacers from two different 10.4 kb DNA fragments. Analysis of isolated total cellular 5.8S RNA revealed the presence of eight species of 5.8S RNA, differing in the number of nucleotides at the 5'-end. The eight 4.8S RNA species vary in length from 158 to 165 nucleotides. Apart from the heterogeneity observed at the 5'-end, the sequence of the eight 5.8S RNA species appears to be identical and is the same sequence as coded for by the 5.8S genes. The gene sequence shows great homology to the 5.8S RNA genes or S. cerevisiae and N. crassa. Most of the base differences are confined to the highly variable stem though to be involved in co-axial helix stacking with the 25S RNA, where base pairing is nearly identical despite the sequence differences. Secondary structure models are examined in light of 5.8S RNA oligonucleotide conservation across species from yeasts to higher eukaryotes.     

Sequence and secondary structure of Drosophila melanogaster 5.8S and 2S rRNAs and of the processing site between them.

Drosophila melanogaster 5.8S and 2S rRNAs were end-labeled with 32p at either the 5' or 3' end and were sequenced. 5.8S rRNA is 123 nucleotides long and homologous to the 5' part of sequenced 5.8S molecules from other species. 2S rRNA is 30 nucleotides long and homologous to the 3' part of other 5.8S molecules. The 3' end of the 5.8S molecule is able to base-pair with the 5' end of the 2S rRNA to generate a helical region equivalent in position to the "GC-rich hairpin" found in all previously sequenced 5.8S molecules. Probing the structure of the labeled Drosophila 5.8S molecule with S1 nuclease in solution verifies its similarity to other 5.8S rRNAs. The 2S rRNA is shown to form a stable complex with both 5.8S and 26S rRNAs separately and together. 5.8S rRNA can also form either binary or ternary complexes with 2S and 26S rRNA. It is concluded that the 5.8S rRNA in Drosophila melanogaster is very similar both in sequence and structure to other 5.8 rRNAs but is split into two pieces, the 2S rRNA being the 3' part. 2S anchors the 5.8S and 26S rRNA. The order of the rRNA coding regions in the ribosomal DNA repeating unit is shown to be 18S - 5.8S - 2S - 26S. Direct sequencing of ribosomal DNA shows that the 5.8S and 2S regions are separated by a 28 nucleotide spacer which is A-T rich and is presumably removed by a specific processing event. A secondary structure model is proposed for the 26S-5.8S ternary complex and for the presumptive precursor molecule.     

Ribosomal RNA of the primitive eukaryote Giardia lamblia: large subunit domain I and potential processing signals

The cytoplasmic ribosomal RNA (rRNA) from the intestinal protozoan, Giardia lamblia, is unusually short; the large subunit (LS) and small subunit RNA and the 5.8S RNA are only 70-80% of the length found in typical protozoa, and are even smaller than most of their prokaryotic counterparts. Flanking regulatory DNA and processed rRNA sequences are similarly compact in size. To shed light on the origins and implications of this 'minimal' rRNA, the nucleotide sequence encoding the 5.8S RNA and domain I of LS RNA was determined. Secondary structure analysis revealed that an evolutionarily variable internal hairpin is partially 'deleted' in G. lamblia 5.8S RNA; the 3'-terminal pairing with LS RNA is conserved. Previously characterized eukaryotic 'expansion' regions are extensively shortened within the LS RNA; in one case, a hairpin is precisely 'deleted'. The short sequences flanking the mature 5.8S RNA that are removed by RNA processing (ITS1 and ITS2) are C-rich; our analysis suggests that the sequence GCGCCCC, in a hairpin configuration, may function as the processing signal.     

Molecular cloning and characterization of ribosomal RNA genes from the brine shrimp: Nucleotide sequence analysis and evolution of the 5.8 S rRNA gene region and its flanking nucleotides

A detailed restriction endonuclease map was prepared for the cloned 5.8 S ribosomal RNA (rRNA) gene region of the brine shrimp Artemia. The nucleotide sequence of the 5.8 S rRNA gene and its flanking nucleotides was determined. This sequence differs in two positions from that of the previously reported 5.8 S rRNA. The primary structure of the Artemia 5.8 S rRNA gene, which, unlike in dipteran insects, is shown to contain no insertion sequence, is conserved according to the relatedness of the species compared. The 5.8 S rRNA gene flanking nucleotides, which were sequenced 176 nucleotide pairs upstream and 70 nucleotide pairs downstream from the gene, show no evidence of sequence conservation between evolutionarily diverse species by computer analysis. Direct nucleotide repeats are present within the flanking sequences at both ends of the gene at about the same distance upstream and downstream, which could serve as processing signals.     

Intermolecular hybridization of 5S rRNA with 18S rRNA: identification of a 5'-terminally-located nucleotide sequence in mouse 5S rRNA which base-pairs with two specific complementary sequences in 18S rRNA.

Eukaryotic 5S rRNA hybridizes specifically with 18S rRNA in vitro to form a stable intermolecular RNA:RNA hybrid. We have used 5S rRNA/18S rRNA fragment hybridization studies coupled with ribonuclease digestion and primer extension/chain termination analysis of 5S rRNA:18S rRNA hybrids to more completely map those mouse 5S rRNA and 18S rRNA sequences responsible for duplex formation. Fragment hybridization analysis has defined a 5'-terminal region of 5S rRNA (nucleotides 6-27) which base-pairs with two independent sequences in 18S rRNA designated Regions 1 (nucleotides 1157-1180) and 2 (nucleotides 1324-1339). Ribonuclease digestion of isolated 5S rRNA:18S rRNA hybrids with both single-strand- and double-strand-specific nucleases supports the involvement of this 5'-terminal 5S rRNA sequence in 18S rRNA hybridization. Primer extension/chain termination analysis of isolated 5S rRNA:18S rRNA hybrids confirms the base-pairing of 5S rRNA to the designated Regions 1 and 2 of 18S rRNA. Using these results, 5S rRNA:18S rRNA intermolecular hybrid structures are proposed. Comparative sequence analysis revealed the conservation of these hybrid structures in higher eukaryotes and the same but smaller core hybrid structures in lower eukaryotes and prokaryotes. This suggests that the 5S rRNA:16S/18S rRNA hybrids have been conserved in evolution for ribosome function.     

Effect of point mutations on 5.8S ribosomal ribonucleic acid secondary structure and the 5.8S--28S ribosomal ribonucleic acid junction

Naturally occurring differences in the nucleotide sequences of 5.8S ribosomal ribonucleic acids (rRNAs) from a variety of organisms have been used to study the role of specific nucleotides in the secondary structure and intermolecular interactions of this RNA. Significant differences in the electrophoretic mobilities of free 5.8S RNAs and the thermal stabilities of 5.8S--28S rRNA complexes were observed even in such closely related sequences as those of man, rat, turtle, and chicken. A single base transition from a guanylic acid residue in position 2 in mammalian 5.8S rRNA to an adenylic acid residue in turtle and chicken 5.8S rRNA results both in a more open molecular conformation and in a 5.8S--28S rRNA junction which is 3.5 degrees C more stable to thermal denaturation. Other changes such as the deletion of single nucleotides from either the 5' or the 3' terminals have no detectable effect on these features. The results support secondary structure models for free 5.8S rRNA in which the termini interact to various degrees and 5.8S--28S rRNA junctions in which both termini of the 5.8S molecule interact with the cognate high molecular weight RNA component.     

Ribosomal RNA genes of Saccharomyces cerevisiae. I. Physical map of the repeating unit and location of the regions coding for 5 S, 5.8 S, 18 S, and 25 S ribosomal RNAs.

The organization of the ribosomal DNA repeating unit from Saccharomyces cerevisiae has been analyzed. A cloned ribosomal DNA repeating unit has been mapped with the restriction enzymes Xma 1, Kpn 1, HindIII, Xba 1, Bgl I + II, and EcoRI. The locations of the sequences which code for 5 S, 5.8 S, 18 S, and 25 S ribosomal RNAs have been determined by hybridization of the purified RNA species with restriction endonuclease generated fragments of the repeating unit. The position of the 5.8 S ribosomal DNA sequences within the repeat was also established by sequencing the DNA which codes for 83 nucleotides at the 5' end of 5.8 S ribosomal RNA. The polarity of the 35 S ribosomal RNA precursor has been established by a combination of hybridization analysis and DNA sequence determination and is 5'-18 S, 5.8 S, 25 S-3'.     

Independent binding sites in mouse 5.8S ribosomal ribonucleic acid for 28S ribosomal ribonucleic acid

Limited digestion of mouse 5.8S ribosomal RNA (rRNA) with RNase T2 generates 5'- and 3'-terminal "half-molecules". These fragments are capable of independently and specifically binding to 28S rRNA, so there exist at least two contacts in the 5.8S rRNA for the 28S rRNA. The dissociation constants for the 5.8S/28S, 5' 5.8S fragment/28S, and 3' 5.8S fragment/28S complexes are 9 x 10(-8) M, 6 x 10(-8) M, and 13 x 10(-8) M, respectively. Thus, each of the fragment binding sites contributes about equally to the overall binding energy of the 5.8S/28S rRNA complex, and the binding sites act independently, rather than cooperatively. The dissociation constants suggest that the 5.8S rRNA termini from short, irregular helices with 28S rRNA. Thermal denaturation data on complexes containing 28S rRNA and each of the half-molecules of 5.8S rRNA indicate that the 5'-terminal binding site(s) exist(s) in a single conformation while the 3'-terminal site exhibits two conformational alternatives. The functional significance of the different conformational states is presently indeterminate, but the possibility they may represent alternative forms of a conformational switch operative during ribosome function is discussed.