Cytoplasmic particles and aminoacyl transferase I activity.

It has been possible to show by electron microscopy of samples selected from sucrose gradients that particles of specific size and shape are present in supernatant fluids derived from nucleated animal and plant cells, but not in extracts from Escherichia coli. Aminoacyl transferase I activity in these same gradients sediments in two peaks representing material of approximately 5-7S and 18-20S. A rectangular particle, 100 x 145 A in size, sediments at 19S and coincides with the second peak of transferase I activity. The possibility that the rectangular particle may be a "carrier" particle associated with transferase I is discussed.

The nucleolar snRNAs: catching up with the spliceosomal snRNAs.

Despite their early discovery, research into the small RNAs associated with the eukaryotic nucleolus (snoRNAs) has lagged behind that of their cousins, the small nuclear RNAs which are known to function in mRNA splicing (spliceosomal snRNAs). Recent progress has now shown that the snoRNAs also occupy a vital niche in the RNA world, participating in the processing of ribosomal RNA. Like the spliceosomal snRNAs, the snoRNAs exist as ribonucleoprotein (RNP) particles which appear to assemble into a large multi-RNA RNP complex for pre-rRNA maturation.

A well-connected and conserved nucleoplasmic helicase is required for production of box C/D and H/ACA snoRNAs and localization of snoRNP proteins.

Biogenesis of small nucleolar RNA-protein complexes (snoRNPs) consists of synthesis of the snoRNA and protein components, snoRNP assembly, and localization to the nucleolus. Recently, two nucleoplasmic proteins from mice were observed to bind to a model box C/D snoRNA in vitro, suggesting that they function at an early stage in snoRNP biogenesis. Both proteins have been described in other contexts. The proteins, called p50 and p55 in the snoRNA binding study, are highly conserved and related to each other. Both have Walker A and B motifs characteristic of ATP- and GTP-binding and nucleoside triphosphate-hydrolyzing domains, and the mammalian orthologs have DNA helicase activity in vitro. Here, we report that the Saccharomyces cerevisiae ortholog of p50 (Rvb2, Tih2p, and other names) is required for production of C/D snoRNAs in vivo and, surprisingly, H/ACA snoRNAs as well. Point mutations in the Walker A and B motifs cause temperature-sensitive or lethal growth phenotypes and severe defects in snoRNA accumulation. Notably, depletion of p50 (called Rvb2 in this study) also impairs localization of C/D and H/ACA core snoRNP proteins Nop1p and Gar1p, suggesting a defect(s) in snoRNP assembly or trafficking to the nucleolus. Findings from other studies link Rvb2 orthologs with chromatin remodeling and transcription. Taken together, the present results indicate that Rvb2 is involved in an early stage of snoRNP biogenesis and may play a role in coupling snoRNA synthesis with snoRNP assembly and localization.

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.

Nuclear ribonucleoprotein complexes of amphibian liver. I. Characterization of the complex and its small molecular weight RNA moiety.

Nuclear RNA-protein complexes containing small molecular weight RNAs were isolated from hepatic nuclei of Rana catesbeiana tadpoles and frogs according to a procedure normally used for the isolation of heterogeneous nuclear ribonucleoprotein complexes from other eukaryotic tissues. Preliminary characterization of the tadpole nuclear RNP indicated a particle size of 50--70 S in sucrose density gradients and a buoyant density of 1.40 gm/ml in CsCl gradients. When analyzed on SDS-polyacrylamide gels, this complex was observed to contain at least 40 polypeptides ranging in molecular weight from 15,000 to 200,000. Nuclear RNA-protein complexes were also isolated from adult frog hepatic nuclei by the same protocol and the RNA moiety which had been purified from the frog complex was compared with the nuclear RNA isolated from the tadpole particles. Electrophoretic analysis of the nuclear RNA-protein-associated RNA revealed minor qualitative and quantitive differences in the more than 25 discrete bands (4--9 S) associated with each particle. Base analysis of tadpole and frog nuclear RNA revealed a nucleotide composition of approximately 50% adenosine plus uridine nucleotides, with an unusually high content of cytosine residues (approximately 30%). Comparison of the two RNA samples demonstrated a large increase in the adenosine content of frog unclear RNA, and the presence of a minor base in frog nuclear RNA which was absent in the tadpole sample. These results indicated that changes in the RNA content of the amphibian nuclear RNP complex had occurred during bullfrog development.

Nuclear ribonucleoprotein complexes of amphibian liver. II. Changes in the protein moiety during development.

Ribonucleoprotein complexes composed of small molecular weight nuclear RNA (4--9 S) and proteins were isolated from hepatic nuclei of Rana catesbeiana (bullfrog) and the protein moiety of this nuclear ribonucleoprotein complex compared during different stages of development. SDS-polyacrylamide gel analysis of premetamorphic tadpoles and adult frog nuclear ribonucleoprotein complexes revealed that while the protein profiles of these two particles were very similar polypeptides of 47,000, 70,000, and 11,000 molecular weight were present in significantly higher concentrations in the frog ribonucleoprotein complexes. Comparison of the chromatin proteins isolated from these two developmental stages demonstrated that these three polypeptides of frog ribonucleoprotein were not contaminants from chromatin. Since these three polypeptides could not be preferentially extracted from the frog ribonucleoprotein complex by 0.5 M KCl or 1 M urea, it was unlikely that these polypeptides were bound nonspecifically to the ribonucleoprotein particle. Polypeptide analysis of the nuclear ribonucleoprotein complexes isolated from tadpoles immersed in the thyroid hormone L-thyroxine revealed an increase in two polypeptides of 37,000 and 45,000 molecular weight during metamorphosis. The absence of reduced amount of these two polypeptides in either the premetamorphic tadpole or adult frog demonstrated that their presence in Rana catesbeiana nuclear ribonucleoprotein was transient during development and specifically associated with tadpole metamorphosis. We conclude from these experiments that the nuclear ribonucleoprotein complex is a dynamic structure during Rana catesbeiana development and that specific changes in its protein composition are associated with discrete stages of amphibian development.

Evidence for a Competitive-Displacement Model for the initiation of protein synthesis involving the intermolecular hybridization of 5 S rRNA, 18 S rRNA and mRNA.

We have previously shown that a 5'-terminal region of mouse 5 S rRNA can base-pair in vitro with two distinct regions of 18 S rRNA. Further analysis reveals that these 5 S rRNA-complementary sequences in 18 S rRNA also exhibit complementarity to the Kozak consensus sequence surrounding the mRNA translational start site. To test the possibility that these 2 regions in 18 S rRNA may be involved in mRNA binding and translational initiation, we have tested, using an in vitro translation system, the effects of DNA oligonucleotides complementary to these 18 S rRNA sequences on protein synthesis. Results show that an oligonucleotide complementary to one 18 S rRNA region does inhibit translation at the step of initiation. We propose a Competitive-Displacement Model for the initiation of translation involving the intermolecular base-pairing of 5 S rRNA, 18 S rRNA and mRNA.

A low-molecular-weight RNA from mouse ascites cells that hybridizes to both 18S rRNA and mRNA sequences.

A low-molecular-weight RNA species from mouse ascites cells has been selected and purified by its intermolecular RNA X RNA hybridization capabilities. This 4.5S RNA is able to base pair with poly(A)+ mRNA sequences and with 18S rRNA. Melting experiments have shown that the intermolecular hybrids formed with this complementary low-molecular-weight RNA are of comparable stability to other RNA X RNA interactions. Analysis has shown that this hybridizing RNA is 87 nucleotides long and has an unusual sequence structure. Located near the 3' terminus is an alternating pyrimidine dinucleotide region of UUCCUUCCUU. This region along with the 3'-adjacent nucleotides form a 14-nucleotide sequence that exhibits perfect complementarity with 18S rRNA. An additional region of 10 nucleotides at the 3' terminus is perfectly homologous to a similarly located sequence in 5.8S rRNA. An obvious RNA polymerase III binding site is not found internally in this low-molecular-weight RNA sequence. The complementary and homologous character of hybridizing RNA with respect to rRNA and mRNA sequences suggests a potential regulatory role for this RNA in the coupling of ribosome and mRNA functions.

A simple and rapid method for the preparation of homologous DNA oligonucleotide hybridization probes from heterologous gene sequences and probes.

We describe a simple and rapid method for the preparation of homologous DNA oligonucleotide probes for hybridization analysis and/or cDNA/genomic library screening. With this method, a synthetic DNA oligonucleotide derived from a known heterologous DNA/RNA/protein sequence is annealed to an RNA preparation containing the gene transcript of interest. Any unpaired 3'-terminal oligonucleotides of the heterologous DNA primer are then removed using the 3' exonuclease activity of the DNA Polymerase I Klenow fragment before primer extension/dideoxynucleotide sequencing of the annealed RNA species with AMV reverse transcriptase. From the determined RNA sequence, a completely homologous DNA oligonucleotide probe is then prepared. This approach has been used to prepare a homologous DNA oligonucleotide probe for the successful library screening of the yeast hybRNA gene starting with a heterologous mouse hybRNA DNA oligonucleotide probe.

Determination of the nucleotide sequences in mouse U14 small nuclear RNA and 18S ribosomal RNA responsible for in vitro intermolecular base-pairing.

U14 small nuclear RNA (snRNA) is an evolutionarily conserved RNA species that plays a role in rRNA processing. The conserved ability of fungal, amphibian and mammalian U14 snRNAs to hybridize with both homologous and heterologous eukaryotic 18S rRNAs indicates a potential role for this intermolecular RNA/RNA interaction in U14 snRNA function. To understand better the possible role of this intermolecular base-pairing in rRNA processing, we have defined those nucleotide sequences in mouse U14 snRNA and 18S rRNA responsible for the observed in vitro hybridization. We have constructed, using synthetic DNA oligonucleotides, a U14 snRNA gene which has been positioned behind a T7 RNA polymerase promoter site and then inserted into a plasmid. The presence of natural or engineered restriction endonuclease sites within this construct has permitted the in vitro transcription of full-length mouse U14 snRNA transcripts (an 87-nucleotide mouse U14 snRNA minus 5' or 3' leader sequences) or 3' terminally truncated U14 snRNA fragments. Hybridization of full-length or truncated fragments of U14 snRNA to mouse 18S rRNA demonstrated the utilization of a previously proposed 18S rRNA complementary sequence located near the 3' end of mouse U14 snRNA (nucleotides 65-78) for intermolecular hybridization. Conversely, RNase-T1-generated fragments of 18S rRNA capable of hybrid-selection by U14 snRNA have been isolated and sequenced. A nested set of hybrid-selected 18S rRNA fragments define a mouse 18S rRNA sequence (nucleotides 459-472) which exhibits perfect complementarity to the defined U14 snRNA sequence 65-78. Primer-extension/chain-termination mapping of mouse U14-snRNA.18S-rRNA hybrids has confirmed the formation of the proposed hybrid structure. A second set of observed complementary sequences in mouse U14 snRNA (nucleotides 25-38) and mouse 18S rRNA (nucleotides 82-95) are not used for the in vitro hybridization of these two RNAs. Presumably the involvement of this second 18S-rRNA-complementary sequence in the secondary/tertiary folding of mouse U14 snRNA prevents its base-pairing with 18S rRNA. However, the strong evolutionary conservation of both U14-snRNA.18S-rRNA hybrid structures and their juxtapositioning within the folded secondary structure of 18S rRNAs argues for a biological role for each in U14 snRNA function.

Proposed secondary structure of eukaryotic U14 snRNA.

U14 snRNA is a small nuclear RNA that plays a role in the processing of eukaryotic ribosomal RNA. We have investigated the folded structure of this snRNA species using comparative analysis of evolutionarily diverse U14 snRNA primary sequences coupled with nuclease digestion analysis of mouse U14 snRNA. Covariant nucleotide analysis of aligned mouse, rat, human, and yeast U14 snRNA primary sequences suggested a basic folding pattern in which the 5' and 3' termini of all U14 snRNAs were base-paired. Subsequent digestion of mouse U14 snRNA with mung bean (single-strand-specific), T2 (single-strand-preferential), and V1 (double-strand-specific) nucleases defined the major and minor cleavage sites for each nuclease. This digestion data was then utilized in concert with the comparative sequence analysis of aligned U14 snRNA primary sequences to refine the secondary structure model suggested by computer-predicted folding. The proposed secondary structure of U14 snRNA is comprised of three major hairpin/helical regions which includes the helix of base-paired 5' and 3' termini. Strict and semiconservative covariation of specific base-pairs within two of the three major helices, as well as nucleotide changes that strengthen or extend base-paired regions, support this folded conformation as the evolutionary conserved secondary structure for U14 snRNA.

The small nucleolar RNAs.

The present review summarizes key progress made in characterizing the small nucleolar RNAs (snoRNAs) of eukaryotic cells. Recent studies have shown snoRNA populations to be substantially more complex than anticipated initially. Many newly discovered snoRNAs are synthesized by an intron-processing pathway, which provides a potential mechanism for coordinating nuclear RNA synthesis. Several snoRNAs and snoRNP proteins are known to be needed for processing of ribosomal RNA, but precise functions remain to be defined. In principle, snoRNAs could have several roles in ribosome synthesis including: folding of pre-rRNA, formation of rRNP substrates, catalyzing RNA cleavages, base modification, assembly of pre-ribosomal subunits, and export of product rRNP particles.

Mouse U14 snRNA is encoded in an intron of the mouse cognate hsc70 heat shock gene.

Mouse U14 snRNA (previously designated mouse 4.5S hybRNA) is an evolutionarily conserved eukaryotic low molecular weight RNA capable of intermolecular hybridization with both homologous and heterologous 18S rRNA (1). A single genomic fragment of mouse DNA containing the U14 snRNA gene(s) has been isolated from a Charon 4A lambda phage mouse genomic library and sequenced. Results have surprisingly revealed the presence of three U14 snRNA-homologous regions positioned within introns 5, 6, and 8 of the mouse cognate hsc70 heat shock gene. Comparative analysis with the previously reported rat and human cognate hsc70 genes revealed a similar positioning of U14 snRNA-homologous sequences within introns 5, 6 and 8 of the respective rat and human genes. The U14 sequences contained in all three introns of all three organisms are highly homologous to each other and well conserved with respect to the diverging intron sequences flanking each U14-homologous sequence. Comparison of the mouse U14 snRNA sequence with the U14 DNA sequences contained in the three mouse hsc70 introns indicates that intron 5 is utilized for U14 snRNA synthesis in normally growing mouse ascites cells. Analysis of the determined mouse, rat, and human U14-homologous sequences and the upstream and downstream flanking regions did not reveal the presence of any previously defined RNA polymerase I, II, or III binding sites. This suggests that either higher eukaryotic U14 snRNA is transcribed from a unique transcriptional promoter sequence, or alternatively, is generated by intron processing of the hsc70 pre-mRNA transcript.

Homologous genes for mouse 4.5S hybRNA are found in all eukaryotes and their low molecular weight RNA transcripts intermolecularly hybridize with eukaryotic 18S ribosomal RNAs.

Previous work has reported the isolation and sequencing of a mouse low molecular weight RNA species designated 4.5S hybridizing RNA or hybRNA because of its ability to intermolecularly hybridize with mouse mRNA and 18S rRNA sequences. Using synthetic DNA oligonucleotide probes we have examined the conservation of this gene sequence and its expression as a lmwRNA transcript across evolution. Southern blot analysis has shown that homologous genes of single or low copy number are found in all eukaryotes examined as well as in E. coli. Northern blot analysis has demonstrated 4.5S hybRNA transcription in all mouse tissues as well as expression in yeast and Xenopus laevis as lmwRNAs of approximately 130 and 100 nucleotides, respectively, as compared with mouse/rat/hamster species of approximately 87 nucleotides. Yeast and X. laevis 4.5S hybRNA homologs, isolated by hybrid-selection, were shown by Northern blot analysis to intermolecularly hybridize with homologous as well as heterologous 18S rRNA sequences. The conservation of 4.5S hybRNA homologous genes and their expression as lmwRNA transcripts with common intermolecular RNA:RNA hybridization capabilities in fungi, amphibians, and mammals argues for a common, conserved and required biological function for this lmwRNA in all eukaryotes and potential utilization of its intermolecular RNA:RNA hybridization capabilities to carry out this function.

Complementarity of sequences in low molecular weight RNAs to regions of messenger and ribosomal RNAs.

Total low molecular weight nuclear RNAs of mouse ascites cells have been labeled in vitro and used as probes to search for complementary sequences contained in nuclear or cytoplasmic RNA. From a subset of hybridizing lmw RNAs, two major species of 58,000 and 35,000 mol. wt. have been identified as mouse 5 and 5.8S ribosomal RNA. Mouse 5 and 5.8S rRNA hybridize not only to 18 and 28S rRNA, respectively, but also to nuclear and cytoplasmic poly(A+) RNA. Northern blot analysis and oligo-dT cellulose chromatography have confirmed the intermolecular base-pairing of these two small rRNA sequences to total poly(A+) RNA as well as to purified rabbit globin mRNA. 5 and 5.8S rRNA also hybridize with positive (coding) but not negative (noncoding) strands of viral RNA. Temperature melting experiments have demonstrated that their hybrid stability with mRNA sequences is comparable to that observed for the 5S:18S and 5.8S:28S hybrids. The functional significance of 5 and 5.8S rRNA base-pairing with mRNAs and larger rRNAs is unknown, but these interactions could play important coordinating roles in ribosome structure, subunit interaction, and mRNA binding during translation.

Nucleotide sequences of Cyanophora paradoxa cellular and cyanelle-associated 5S ribosomal RNAs: the cyanelle as a potential intermediate in plastid evolution.

The 5S ribosomal RNAs from the cell cytoplasm and cyanelle (photosynthetic organelle) of Cyanophora paradoxa have been isolated and sequenced. The cellular and cyanelle 5S rRNAs were 119 and 118 nucleotides in length, respectively. Both RNAs exhibited typical 5S secondary structure, but the primary sequence of the cellular species was clearly eukaryotic in nature, while that of the organellar species was prokaryotelike. The primary sequence of the cyanellar 5S rRNA was most homologous to cyanobacterial 5S sequences, yet possessed secondary-structural features characteristic of higher-plant chloroplast 5S rRNAs. Both sequence comparison and structural analysis indicated an evolutionary position for cyanelle 5S rRNA intermediate between blue-green alga and chloroplast 5S rRNAs.

Mouse U14 snRNA is a processed intron of the cognate hsc70 heat shock pre-messenger RNA.

U14 snRNA is a small nucleolar RNA species essential for eukaryotic pre-rRNA processing. We have previously shown that the mouse U14 snRNA genes are positioned within introns 5, 6, and 8 on the coding strand of the constitutively expressed cognate hsc70 heat shock gene. This genomic organization suggested the possibility that U14 snRNAs are transcribed as part of the hsc70 pre-mRNA and then excised from the intron to yield mature U14 snRNA species. To test this hypothesis directly, we have microinjected Xenopus oocytes with hsc70 pre-mRNA transcripts possessing intron 5 and the encoded U14 snRNA sequence. Processing results demonstrate that, in addition to the splicing of upstream and downstream exons, a mature 87 nt U14 snRNA is excised from the intron. Accurate excision of U14 snRNA from hsc70 intron 5 can occur in the absence of splicing. These results demonstrate a biosynthetic pathway for an snRNA species and provide a novel example of a eukaryotic pre-mRNA intron that is processed to produce a stable, biologically functional RNA species.