Processing of intron-encoded box C/D small nucleolar RNAs lacking a 5',3'-terminal stem structure

The C and D box-containing (box C/D) small nucleolar RNAs (snoRNAs) function in the nucleolytic processing and 2'-O-methylation of precursor rRNA. In vertebrates, most box C/D snoRNAs are processed from debranched pre-mRNA introns by exonucleolytic activities. Elements directing accurate snoRNA excision are located within the snoRNA itself; they comprise the conserved C and D boxes and an adjoining 5',3'-terminal stem. Although the terminal stem has been demonstrated to be essential for snoRNA accumulation, many snoRNAs lack a terminal helix. To identify the cis-acting elements supporting the accumulation of intron-encoded box C/D snoRNAs devoid of a terminal stem, we have investigated the in vivo processing of the human U46 snoRNA and an artificial snoRNA from the human beta-globin pre-mRNA. We demonstrate that internal and/or external stem structures located within the snoRNA or in the intronic flanking sequences support the accumulation of mammalian box C/D snoRNAs lacking a canonical terminal stem. In the intronic precursor RNA, transiently formed external and/or stable internal base-pairing interactions fold the C and D boxes together and therefore facilitate the binding of snoRNP proteins. Since the external intronic stems are degraded during snoRNA processing, we propose that the C and D boxes alone can provide metabolic stability for the mature snoRNA.     

Metal resistance in yeast mediated by the expression of a maize 20S proteasome alpha subunit

A novel 72 nt small nucleolar RNA (snoRNA) called U87 was found in rat liver cells. This RNA possesses the features of C/D box snoRNA family: boxes C, D', C', D, and 11 nt antisense element complementary to 28S ribosomal RNA (rRNA). The vast majority of C/D box snoRNAs direct site-specific 2'-O-ribose methylation of rRNAs. U87 RNA is suggested to be involved in 2'-O-methylation of a G(3468) residue in 28S rRNA. U87 RNA was detected in different mammalian species with slight length variability. Rat and mouse U87 RNA gene was characterized. Unlike the majority of C/D box snoRNAs U87 RNA lacks the terminal stem required for snoRNA processing. However, U87 gene is flanked by 7 bp inverted repeats potentially able to form a terminal stem in U87 RNA precursor.     

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.     

Identification of specific nucleotide sequences and structural elements required for intronic U14 snoRNA processing.

Vertebrate U14 snoRNAs are encoded within hsc70 pre-mRNA introns and U14 biosynthesis occurs via an intron-processing pathway. We have shown previously that essential processing signals are located in the termini of the mature U14 molecule and replacement of included boxes C or D with oligo C disrupts snoRNA synthesis. The experiments detailed here now define the specific nucleotide sequences and structures of the U14 termini that are essential for intronic snoRNA processing. Mutagenesis studies demonstrated that a 5', 3'-terminal stem of at least three contiguous base pairs is required. A specific helix sequence is not necessary and this stem may be extended to as many as 15 base pairs without affecting U14 processing. The spatial positioning of boxes C and D with respect to the terminal stem is also important. Detailed analysis of boxes C and D revealed that both consensus sequences possess essential nucleotides. Some, but not all, of these critical nucleotides correspond to those required for the stable accumulation of nonintronic yeast U14 snoRNA. The presence of box C and D consensus sequences flanking a terminal stem in many snoRNA species indicates the importance of this "terminal core motif" for snoRNA processing.     

Release of U18 snoRNA from its host intron requires interaction of Nop1p with the Rnt1p endonuclease.

An external stem, essential for the release of small nucleolar RNAs (snoRNAs) from their pre-mRNAs, flanks the majority of yeast intron-encoded snoRNAs. Even if this stem is not a canonical Rnt1p substrate, several experiments have indicated that the Rnt1p endonuclease is required for snoRNA processing. To identify the factors necessary for processing of intron-encoded snoRNAs, we have raised in vitro extracts able to reproduce such activity. We found that snoRNP factors are associated with the snoRNA- coding region throughout all the processing steps, and that mutants unable to assemble snoRNPs have a processing-deficient phenotype. Specific depletion of Nop1p completely prevents U18 snoRNA synthesis, but does not affect processing of a dicistronic snoRNA-coding unit that has a canonical Rnt1p site. Correct cleavage of intron-encoded U18 and snR38 snoRNAs can be reproduced in vitro by incubating together purified Nop1p and Rnt1p. Pull-down experiments showed that the two proteins interact physically. These data indicate that cleavage of U18, snR38 and possibly other intron-encoded snoRNAs is a regulated process, since the stem is cleaved by the Rnt1p endonuclease only when snoRNP assembly has occurred.     

Elements essential for processing intronic U14 snoRNA are located at the termini of the mature snoRNA sequence and include conserved nucleotide boxes C and D.

Essential elements for intronic U14 processing have been analyzed by microinjecting various mutant hsc70/Ul4 pre-mRNA precursors into Xenopus oocyte nuclei. Initial truncation experiments revealed that elements sufficient for U14 processing are located within the mature snoRNA sequence itself. Subsequent deletions within the U14 coding region demonstrated that only the terminal regions of the folded U14 molecule containing con- served nucleotide boxes C and D are required for processing. Mutagenesis of either box C or box D completely blocked U14 processing. The importance of boxes C and D was confirmed with the excision of appropriately sized U3 and U8 fragments containing boxes C and D from an hsc7O pre-mRNA intron. Competition studies indicate that a trans-acting factor (protein?) is binding this terminal motif and is essential for U14 processing. Competition studies also revealed that this factor is common to both intronic and non-intronic snoRNAs possessing nucleotide boxes C and D. Immunoprecipitation of full-length and internally deleted U14 snoRNA molecules demonstrated that the terminal region containing boxes C and D does not bind fibrillarin. Collectively, our results indicate that a trans-acting factor (different from fibrillarin) binds to the box C- and D-containing terminal motif of U14 snoRNA, thereby stabilizing the intronic snoRNA sequence in an RNP complex during processing.     

Conserved boxes C and D are essential nucleolar localization elements of U14 and U8 snoRNAs.

Sequences necessary for nucleolar targeting were identified in Box C/D small nucleolar RNAs (snoRNAs) by fluorescence microscopy. Nucleolar preparations were examined after injecting fluorescein-labelled wild-type and mutated U14 or U8 snoRNA into Xenopus oocyte nuclei. Regions in U14 snoRNA that are complementary to 18S rRNA and necessary for rRNA processing and methylation are not required for nucleolar localization. Truncated U14 molecules containing Boxes C and D with or without the terminal stem localized efficiently. Nucleolar localization was abolished upon mutating just one or two nucleotides within Boxes C and D. Moreover, the spatial position of Boxes C or D in the molecule is essential. Mutations in Box C/D of U8 snoRNA also impaired nucleolar localization, suggesting the general importance of Boxes C and D as nucleolar localization sequences for Box C/D snoRNAs. U14 snoRNA is shown to be required for 18S rRNA production in vertebrates.     

U21, a novel small nucleolar RNA with a 13 nt. complementarity to 28S rRNA, is encoded in an intron of ribosomal protein L5 gene in chicken and mammals.

Following a search of sequence data bases for intronic sequences exhibiting structural features typical of snoRNAs, we have positively identified by Northern assays and sequence analysis another intron-encoded snoRNA, termed U21. U21 RNA is a 93 nt. long, metabolically stable RNA, present at about 10(4) molecules per HeLa cell. It is encoded in intron 5 of the ribosomal protein L5 gene, both in chicken and in the two mammals studied so far, human and mouse. U21 RNA is devoid of a 5'-trimethyl-cap and is likely to result from processing of intronic RNA. The nucleolar localization of U21 has been established by fluorescence microscopy after in situ hybridization with digoxigenin-labeled oligonucleotide probes. Like most other snoRNAs U21 contains the box C and box D motifs and is precipitated by anti-fibrillarin antibodies. By the presence of a typical 5'-3' terminal stem, U21 appears more particularly related to U14, U15, U16 and U20 intron-encoded snoRNAs. Remarkably, U21 contains a long stretch (13 nt.) of complementarity to a highly conserved sequence in 28S rRNA. Sequence comparisons between chicken and mammals, together with Northern hybridizations with antisense oligonucleotides on cellular RNAs from more distant vertebrates, point to the preferential preservation of this segment of U21 sequence during evolution. Accordingly, this complementarity, which overlaps the complementarity of 28S rRNA to another snoRNA, U18, could reflect an important role of U21 snoRNA in the biogenesis of large ribosomal subunit.     

Role of the box C/D motif in localization of small nucleolar RNAs to coiled bodies and nucleoli.

Small nucleolar RNAs (snoRNAs) are a large family of eukaryotic RNAs that function within the nucleolus in the biogenesis of ribosomes. One major class of snoRNAs is the box C/D snoRNAs named for their conserved box C and box D sequence elements. We have investigated the involvement of cis-acting sequences and intranuclear structures in the localization of box C/D snoRNAs to the nucleolus by assaying the intranuclear distribution of fluorescently labeled U3, U8, and U14 snoRNAs injected into Xenopus oocyte nuclei. Analysis of an extensive panel of U3 RNA variants showed that the box C/D motif, comprised of box C', box D, and the 3' terminal stem of U3, is necessary and sufficient for the nucleolar localization of U3 snoRNA. Disruption of the elements of the box C/D motif of U8 and U14 snoRNAs also prevented nucleolar localization, indicating that all box C/D snoRNAs use a common nucleolar-targeting mechanism. Finally, we found that wild-type box C/D snoRNAs transiently associate with coiled bodies before they localize to nucleoli and that variant RNAs that lack an intact box C/D motif are detained within coiled bodies. These results suggest that coiled bodies play a role in the biogenesis and/or intranuclear transport of box C/D snoRNAs.     

Processing of the intron-encoded U16 and U18 snoRNAs: the conserved C and D boxes control both the processing reaction and the stability of the mature snoRNA.

A novel class of small nucleolar RNAs (snoRNAs), encoded in introns of protein coding genes and originating from processing of their precursor molecules, has recently been described. The L1 ribosomal protein (r-protein) gene of Xenopus laevis and its human homologue contain two snoRNAs, U16 and U18. It has been shown that these snoRNAs are excised from their intron precursors by endonucleolytic cleavage and that their processing is alternative to splicing. Two sequences, internal to the snoRNA coding region, have been identified as indispensable for processing the conserved boxes C and D. Competition experiments have shown that these sequences interact with diffusible factors which can bind both the pre-mRNA and the mature U16 snoRNA. Fibrillarin, which is known to associate with complexes formed on C and D boxes of other snoRNAs, is found in association with mature U16 RNA, as well as with its precursor molecules. This fact suggests that the complex formed on the pre-mRNA remains bound to U16 throughout all the processing steps. We also show that the complex formed on the C and D boxes is necessary to stabilize mature snoRNA.     

Nop58p is a common component of the box C+D snoRNPs that is required for snoRNA stability

Eukaryotic nucleoli contain a large family of box C+D small nucleolar RNA (snoRNA) species, all of which are associated with a common protein Nop1p/fibrillarin. Nop58p was identified in a screen for synthetic lethality with Nop1p and shown to be an essential nucleolar protein. Here we report that a Protein A-tagged version of Nop58p coprecipitates all tested box C+D snoRNAs and that genetic depletion of Nop58p leads to the loss of all tested box C+D snoRNAs. The box H+ACA class of snoRNAs are not coprecipitated with Nop58p, and are not codepleted. The yeast box C+D snoRNAs include two species, U3 and U14, that are required for the early cleavages in pre-rRNA processing. Consistent with this, Nop58p depletion leads to a strong inhibition of pre-rRNA processing and 18S rRNA synthesis. Unexpectedly, depletion of Nop58p leads to the accumulation of 3' extended forms of U3 and U24, showing that the protein is also involved in snoRNA synthesis. Nop58p is the second common component of the box C+D snoRNPs to be identified and the first to be shown to be required for the stability and for the synthesis of these snoRNAs.     

Accumulation of U14 small nuclear RNA in Saccharomyces cerevisiae requires box C, box D, and a 5'', 3'' terminal stem.

U14 is one of several nucleolar small nuclear RNAs required for normal processing of rRNA. Functional mapping of U14 from Saccharomyces cerevisiae has yielded a number of mutants defective in U14 accumulation or function. In this study, we have further defined three structural elements required for U14 accumulation. The essential elements include the U14-conserved box C and box D sequences and a 5', 3' terminal stem. The box elements are coconserved among several nucleolar small nuclear RNAs and have been implicated in binding of the protein fibrillarin. New mutational results show that the first GA bases of the box C sequence UGAUGA are essential, and two vital bases in box D have also been identified. An intragenic suppressor of a lethal box C mutant has been isolated and shown to contain a new box C-like PyGAUG sequence two bases upstream of normal box C. The importance of the terminal stem was confirmed from new compensatory base changes and the finding that accumulation defects in the box elements can be complemented by extending the terminal stem. The results suggest that the observed defects in accumulation reflect U14 instability and that protein binding to one or more of these elements is required for metabolic stability.     

U24, a novel intron-encoded small nucleolar RNA with two 12 nt long, phylogenetically conserved complementarities to 28S rRNA.

Following computer searches of sequence banks, we have positively identified a novel intronic snoRNA, U24, encoded in the ribosomal protein L7a gene in humans and chicken. Like previously reported intronic snoRNAs, U24 is devoid of a 5'-trimethyl-cap. U24 is immunoprecipitated by an antifibrillarin antibody and displays an exclusively nucleolar localization by fluorescence microscopy after in situ hybridization with antisense oligonucleotides. In vertebrates, U24 is a 76 nt long conserved RNA which is metabolically stable, present at approximately 14,000 molecules per human HeLa cell. U24 exhibits a 5'-3' terminal stem-box C-box D structure, typical for several snoRNAs, and contains two 12 nt long conserved sequences complementary to 28S rRNA. It is, therefore, strikingly related to U14, U20 and U21 snoRNAs which also possess long sequences complementary to conserved sequences of mature 18S or 28S rRNAs. In 28S rRNA the two tracts complementary to U24 are adjacent to each other, they involve several methylated nucleotides and are surprisingly close, within the rRNA secondary structure, to complementarities to snoRNAs U18 and U21. Identification of the yeast Saccharomyces cerevisiae U24 gene directly confirms the outstanding conservation of the complementarity to 28S rRNA during evolution, suggesting a key role of U24 pairing to pre-rRNA during ribosome biogenesis, possible in the control of pre-rRNA folding. Yeast S.cerevisiae U24 is also intron-encoded but not in the same host-gene as in humans or chicken.     

The box C/D motif directs snoRNA 5'-cap hypermethylation

The 5′-cap structure of most spliceosomal small nuclear RNAs (snRNAs) and certain small nucleolar RNAs (snoRNAs) undergoes hypermethylation from a 7-methylguanosine to a 2,2,7-trimethylguanosine structure. 5′-Cap hypermethylation of snRNAs is dependent upon a conserved sequence element known as the Sm site common to most snRNAs. Here we have performed a mutational analysis of U3 and U14 to determine the cis-acting sequences required for 5′-cap hypermethylation of Box C/D snoRNAs. We have found that both the conserved sequence elements Box C (termed C′ in U3) and Box D are necessary for cap hypermethylation. Furthermore, the terminal stem structure that is formed by sequences that flank Box C (C′ in U3) and Box D is also required. However, mutation of other conserved sequences has no effect on hypermethylation of the cap. Finally, the analysis of fragments of U3 and U14 RNAs indicates that the Box C/D motif, including Box C (C′ in U3), Box D and the terminal stem, is capable of directing cap hypermethylation. Thus, the Box C/D motif, which is important for snoRNA processing, stability, nuclear retention, protein binding, nucleolar localization and function, is also necessary and sufficient for cap hypermethylation of these RNAs.     

Identification of discrete classes of small nucleolar RNA featuring different ends and RNA binding protein dependency

Small nucleolar RNAs (snoRNAs) are among the first discovered and most extensively studied group of small non-coding RNA. However, most studies focused on a small subset of snoRNAs that guide the modification of ribosomal RNA. In this study, we annotated the expression pattern of all box C/D snoRNAs in normal and cancer cell lines independent of their functions. The results indicate that C/D snoRNAs are expressed as two distinct forms differing in their ends with respect to boxes C and D and in their terminal stem length. Both forms are overexpressed in cancer cell lines but display a conserved end distribution. Surprisingly, the long forms are more dependent than the short forms on the expression of the core snoRNP protein NOP58, thought to be essential for C/D snoRNA production. In contrast, a subset of short forms are dependent on the splicing factor RBFOX2. Analysis of the potential secondary structure of both forms indicates that the k-turn motif required for binding of NOP58 is less stable in short forms which are thus less likely to mature into a canonical snoRNP. Taken together the data suggest that C/D snoRNAs are divided into at least two groups with distinct maturation and functional preferences.