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

Deletion mapping of tumor promotion-susceptibility gene pro1 implicates an RNA polymerase III transcription unit

The murine gene pro1 has been cloned from JB6 epidermal cell lines that are sensitive to neoplastic transformation by tumor promoters. Insensitive JB6 variants acquire susceptibility to neoplastic transformation by tumor promoters when transfected with pro1. The repetitive nature of pro1 was indicated by sequence and Southern analysis. In contrast, northern analysis of RNA from promotion-sensitive cells revealed the presence of a small pro1-hybridizing transcript. Strand-specific RNA probes implicated an RNA polymerase III (RNAPIII) coding domain in pro1 as the source of this hybridization signal. Ribonuclease protection of gel-purified pro1 RNA from JB6 variant cell lines identified a 130-nucleotide transcript. The size of this transcript is compatible with in vitro RNAPIII transcription of pro1. Deletion mapping of pro1 by exonuclease III demonstrated that the biologically active domain included the RNAPIII transcription unit. RNA probes map pro1 RNA within the activity domain. These results delineate an activity domain of 597 nucleotides and suggest that a small RNA is the product of promotion-sensitivity gene pro1.

Box C/D snoRNA-associated proteins: two pairs of evolutionarily ancient proteins and possible links to replication and transcription

The eukaryotic nucleolus contains a diverse population of small nucleolar RNAs (snoRNAs) essential for ribosome biogenesis. The box C/D snoRNA family possesses conserved nucleotide boxes C and D that are multifunctional elements required for snoRNA processing, snoRNA transport to the nucleolus, and 2'-O-methylation of ribosomal RNA. We have previously demonstrated that the assembly of an snoRNP complex is essential for processing the intronic box C/D snoRNAs and that specific nuclear proteins associate with the box C/D core motif in vitro. Using a box C/D motif derived from mouse U14 snoRNA, we have now affinity purified and defined four mouse proteins that associate with this minimal RNA substrate. These four proteins consist of two protein pairs: members of each pair are highly related in sequence. One protein pair corresponds to the essential yeast nucleolar proteins Nop56p and Nop58p. Affinity purification of mouse Nop58 confirms observations made in yeast that Nop58 is a core protein of the box C/D snoRNP complex. Isolation of Nop56 using this RNA motif defines an additional snoRNP core protein. The second pair of mouse proteins, designated p50 and p55, are also highly conserved among eukaryotes. Antibody probing of nuclear fractions revealed a predominance of p55 and p50 in the nucleoplasm, suggesting a possible role for the p50/p55 pair in snoRNA production and/or nucleolar transport. The reported interaction of p55 with TATA-binding protein (TBP) and replication A protein as well as the DNA helicase activity of p55 and p50 may suggest the coordination of snoRNA processing and snoRNP assembly with replication and/or transcriptional events in the nucleus. Homologs for both snoRNA-associated protein pairs occur in Archaea, strengthening the hypothesis that the box C/D RNA elements and their interacting proteins are of ancient evolutionary origin.

In vitro assembly of the mouse U14 snoRNP core complex and identification of a 65-kDa box C/D-binding protein

The eukaryotic nucleolus contains a diverse population of small nucleolar RNAs (snoRNAs) that have been categorized into two major families based on evolutionarily conserved sequence elements. U14 snoRNA is a member of the larger, box C/D snoRNA family and possesses nucleotide box C and D consensus sequences. In previous studies, we have defined a U14 box C/D core motif that is essential for intronic U14 snoRNA processing. These studies also revealed that nuclear proteins that recognize boxes C/D are required. We have now established an in vitro U14 snoRNP assembly system to characterize protein binding. Electrophoretic mobility-shift analysis demonstrated that all the sequences and structures of the box C/D core motif required for U14 processing are also necessary for protein binding and snoRNP assembly. These required elements include a base paired 5',3' terminal stem and the phylogenetically conserved nucleotides of boxes C and D. The ability of other box C/D snoRNAs to compete for protein binding demonstrated that the box C/D core motif-binding proteins are common to this family of snoRNAs. UV crosslinking of nuclear proteins bound to the U14 core motif identified a 65-kDa mouse snoRNP protein that requires boxes C and D for binding. Two additional core motif proteins of 55 and 50 kDa were also identified by biochemical fractionation of the in vitro-assembled U14 snoRNP complex. Thus, the U14 snoRNP core complex is a multiprotein particle whose assembly requires nucleotide boxes C and D.

Processing of U14 small nucleolar RNA from three different introns of the mouse 70-kDa-cognate-heat-shock-protein pre-messenger RNA

U14 is a small nucleolar RNA required for the processing of eukaryotic rRNA precursors. The U14 genes of mouse as well as rat, hamster, human, Xenopus and trout are encoded within introns of the constitutively expressed 70-kDa-cognate-heat-shock protein gene (hsc70). We demonstrate here that U14.6 and U14.8 snRNAs, in addition to the previously characterized U14.5, are processed from their respective introns when hsc70 pre-mRNA transcripts containing these intronic snRNAs are injected into Xenopus oocyte nuclei. Identical intermediates are observed in the processing of all three mouse U14 snRNAs indicating similar processing pathways. The production of U14 snRNA processing intermediates possessing either mature 5' or 3' termini demonstrated that processing can occur at either end independent of maturation at the other terminus. Processing of U14.6 from hsc70 intron 6 is not dependent upon the base pairing of intron sequences flanking the 5' and 3' termini of the encoded U14 snRNA molecule. Therefore, excision of an intronic snRNA does not require extending the 5',3' terminal helix of U14 snRNA secondary structure into flanking intron regions as originally suggested. Microinjection of the plasmid vector containing the mouse hsc70/U14.5 snRNA coding region revealed that undetermined plasmid sequences can serve as non-specific promoters to generate spurious RNA transcripts. The processing of these transcripts and examination of the plasmid-initiated transcriptional-start sites indicated that a U14-specific promoter is not present in or around the intron-encoded U14.5 gene. These results strongly suggest that biosynthesis of mouse U14 snRNA results from an intron-processing pathway.

Molecular characterisation of plant U14 small nucleolar RNA genes: closely linked genes are transcribed as polycistronic U14 transcripts

U14snoRNAs are highly conserved eukaryotic nucleolar small RNAs involved in precursor ribosomal RNA processing. In vertebrates, U14snoRNAs and a number of other snoRNAs are transcribed within introns of protein coding genes and are released by processing. We have isolated potato and maize genomic U14 clones using PCR-amplified plant U14 probes. Plant U14s show extensive homology to those from yeast and animals but contain plant-specific sequences. One of the isolated maize clones contains a cluster of four U14 genes in a region of only 761 bp, confirming the close linkage of U14 genes in maize, potato and barley as established by PCR. The absence of known plant promoter elements, the proximity of the genes and the detection of transcripts containing linked U14s by RT-PCR indicates that some plant U14snoRNAs are transcribed as precursor RNAs which are then processed to release individual U14s. Whether plant U14snoRNAs are intron-encoded or transcribed from novel promoter sequences, remains to be established.

A novel RNA gene in the tobacco plastid genome: its possible role in the maturation of 16S rRNA

A small plastid-encoded RNA (spRNA, 218 nt) has been detected in tobacco. The corresponding locus (sprA) does not contain any open reading frame and is actively transcribed from its own promoter, as shown by ribonuclease protection assays using in vitro capped RNAs. Gel-shift and UV-crosslinking experiments showed the formation of a specific complex between spRNA and chloroplast polypeptides. The mobility of the complex was further shifted when a transcript bearing part of the 16S rRNA leader sequence was added to the incubation mixture. Glycerol gradient fractionation of a chloroplast lysate indicated a preferential sedimentation of spRNA at 15-20S and 70S. These observations, and the potential base-pairing with the leader sequence of pre-16S rRNA, suggest a role for spRNA in chloroplast ribosome biogenesis, i.e. 16S rRNA maturation. By sequencing of tomato plastid DNA and heterologous northern hybridizations, the presence of sprA homologs and their expression in a number of dicot plants have also been shown.

Two different snoRNAs are encoded in introns of amphibian and human L1 ribosomal protein genes

We previously reported that the third intron of the X.laevis L1 ribosomal protein gene encodes for a snoRNA called U16. Here we show that four different introns of the same gene contain another previously uncharacterized snoRNA (U18) which is associated with fibrillarin in the nucleolus and which originates by processing of the pre-mRNA. The pathway of U18 RNA release from the pre-mRNA is the same as the one described for U16: primary endonucleolytic cleavages upstream and downstream of the U18 coding region produce a pre-U18 RNA which is subsequently trimmed to the mature form. Both the gene organization and processing of U18 are conserved in the corresponding genes of X.tropicalis and H.sapiens. The L1 gene thus has a composite structure, highly conserved in evolution, in which sequences coding for a ribosomal protein are intermingled with sequences coding for two different snoRNAs. The nucleolar localization of these different components suggests some common function on ribosome biosynthesis.

Three small nucleolar RNAs of unique nucleotide sequences

Three small RNA species were detected in human cells, and their cDNAs were synthesized and cloned. These RNAs are nucleolar, are 207, 154, and 135 nucleotides long, and are named E1, E2, and E3, respectively, and their unique nucleotide sequences suggest that they may belong to an additional family of small nucleolar RNAs. The 5' ends of these three RNAs do not appear to have a trimethylguanosine cap or another type of cap. Apparent homologs of these three RNAs were detected in mouse, rabbit, and frog cells, suggesting their universal importance. They are housekeeping RNA species, since they are present in all rabbit tissues analyzed.

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.

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.

Depletion of U14 small nuclear RNA (snR128) disrupts production of 18S rRNA in Saccharomyces cerevisiae

Repression of an essential nucleolar small nuclear RNA (snRNA) gene of Saccharomyces cerevisiae was shown to result in impaired production of 18S rRNA. The effect, observed for an snRNA species of 128 nucleotides (snR128), was evident within one generation after the onset of SNR128 gene repression and correlated well with depletion of the snRNA. The steady-state mass ratio of 18S RNA to 25S RNA decreased eightfold over the course of the analysis. Results from pulse-chase assays revealed the basis of the imbalance to be underaccumulation of 18S RNA and its 20S precursor. This effect appears to result from impairment of processing of the 35S rRNA transcript at sites that define the 20S species coupled with rapid turnover of unstable intermediates. Possible bases for the effects observed are discussed. A common U14 designation is proposed for the structurally related yeast snRNA and 4.5S hybRNAs from amphibians and mammals.

Depletion of U14 small nuclear RNA (snR128) disrupts production of 18S rRNA in Saccharomyces cerevisiae

Repression of an essential nucleolar small nuclear RNA (snRNA) gene of Saccharomyces cerevisiae was shown to result in impaired production of 18S rRNA. The effect, observed for an snRNA species of 128 nucleotides (snR128), was evident within one generation after the onset of SNR128 gene repression and correlated well with depletion of the snRNA. The steady-state mass ratio of 18S RNA to 25S RNA decreased eightfold over the course of the analysis. Results from pulse-chase assays revealed the basis of the imbalance to be underaccumulation of 18S RNA and its 20S precursor. This effect appears to result from impairment of processing of the 35S rRNA transcript at sites that define the 20S species coupled with rapid turnover of unstable intermediates. Possible bases for the effects observed are discussed. A common U14 designation is proposed for the structurally related yeast snRNA and 4.5S hybRNAs from amphibians and mammals.

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.

Identification of the proteins in direct contact with duck globin mRNA

Proteins in direct contact with translationally active and repressed duck globin mRNA were determined by irradiating blood or lysates with ultraviolet light. Cross-linked proteins from polyribosomes and free mRNP particles were 14C-labeled by reductive methylation and identified on SDS-polyacrylamide gels upon autoradiography. Results indicate that ten cross-linked proteins are common to both polysomal and free mRNP, however, a 44 kDa protein appears to be specific for repressed mRNP particles. Furthermore, the notable lack of cross-linked proteins in the 20-30 kDa range in free mRNP supports the view that the characteristic low molecular mass 'prosomal' proteins, previously found associated with translationally repressed duck globin free mRNP [(1984) EMBO J. 3, 29-34], do not interact directly with the mRNA molecule.