A second base pair interaction between U3 small nucleolar RNA and the 5'-ETS region is required for early cleavage of the yeast pre-ribosomal RNA

In eukaryotes, U3 snoRNA is essential for pre-rRNA maturation. Its 5'-domain was found to form base pair interactions with the 18S and 5'-ETS parts of the pre-rRNA. In Xenopus laevis, two segments of U3 snoRNA form base-pair interactions with the 5'-ETS region and only one of them is essential to the maturation process. In Saccharomyces cerevisiae, two similar U3 snoRNA-5' ETS interactions are possible; but, the functional importance of only one of them had been tested. Surprisingly, this interaction, which corresponds to the non-essential one in X. laevis, is essential for cell growth and pre-rRNA maturation in yeast. In parallel with [Dutca et al. (2011) The initial U3 snoRNA:pre-rRNA base pairing interaction required for pre-18S rRNA folding revealed by in vivo chemical probing. Nucleic Acids Research, 39, 5164-5180], here we show, that the second possible 11-bp long interaction between the 5' domain of S. cerevisiae U3 snoRNA and the pre-rRNA 5'-ETS region (helix VI) is also essential for pre-rRNA processing and cell growth. Compensatory mutations in one-half of helix VI fully restored cell growth. Only a partial restoration of growth was obtained upon extension of compensatory mutations to the entire helix VI, suggesting sequence requirement for binding of specific proteins. Accordingly, we got strong evidences for a role of segment VI in the association of proteins Mpp10, Imp4 and Imp3.     

Nuclear retention elements of U3 small nucleolar RNA

The processing and methylation of precursor rRNA is mediated by the box C/D small nucleolar RNAs (snoRNAs). These snoRNAs differ from most cellular RNAs in that they are not exported to the cytoplasm. Instead, these RNAs are actively retained in the nucleus where they assemble with proteins into mature small nucleolar ribonucleoprotein particles and are targeted to their intranuclear site of action, the nucleolus. In this study, we have identified the cis-acting sequences responsible for the nuclear retention of U3 box C/D snoRNA by analyzing the nucleocytoplasmic distributions of an extensive panel of U3 RNA variants after injection of the RNAs into Xenopus oocyte nuclei. Our data indicate the importance of two conserved sequence motifs in retaining U3 RNA in the nucleus. The first motif is comprised of the conserved box C' and box D sequences that characterize the box C/D family. The second motif contains conserved box sequences B and C. Either motif is sufficient for nuclear retention, but disruption of both motifs leads to mislocalization of the RNAs to the cytoplasm. Variant RNAs that are not retained also lack 5' cap hypermethylation and fail to associate with fibrillarin. Furthermore, our results indicate that nuclear retention of U3 RNA does not simply reflect its nucleolar localization. A fragment of U3 containing the box B/C motif is not localized to nucleoli but retained in coiled bodies. Thus, nuclear retention and nucleolar localization are distinct processes with differing sequence requirements.     

Depletion of U3 small nucleolar RNA inhibits cleavage in the 5'' external transcribed spacer of yeast pre-ribosomal RNA and impairs formation of 18S ribosomal RNA.

Multiple processing events are required to convert a single eukaryotic pre-ribosomal RNA (pre-rRNA) into mature 18S (small subunit), 5.8S and 25-28S (large subunit) rRNAs. We have asked whether U3 small nucleolar RNA is required for pre-rRNA processing in vivo by depleting Saccharomyces cerevisiae of U3 by conditional repression of U3 synthesis. The resulting pattern of accumulation and depletion of specific pre-rRNAs indicates that U3 is required for multiple events leading to the maturation of 18S rRNA. These include an initial cleavage within the 5' external transcribed spacer, resembling the U3 dependent initial processing event of mammalian pre-rRNA. Formation of large subunit rRNAs is unaffected by U3 depletion. The similarity between the effects of U3 depletion and depletion of U14 small nucleolar RNA and the nucleolar protein fibrillarin (NOP1) suggests that these could be components of a single highly conserved processing complex.     

The rRNA-processing function of the yeast U14 small nucleolar RNA can be rescued by a conserved RNA helicase-like protein.

The phylogenetically conserved U14 small nucleolar RNA is required for processing of rRNA, and this function involves base pairing with conserved complementary sequences in 18S RNA. With a view to identifying other important U14 interactions, a stem-loop domain required for activity of Saccharomyces cerevisiae U14 RNAs (the Y domain) was first subjected to detailed mutational analysis. The mapping results showed that most nucleotides of the Y domain can be replaced without affecting function, except for loop nucleotides conserved among five different yeast species. Defective variants were then used to identify both intragenic and extragenic suppressor mutations. All of the intragenic mutations mapped within six nucleotides of the primary mutation, suggesting that suppression involves a change in conformation and that the loop element is involved in an essential intermolecular interaction rather than intramolecular base pairing. A high-copy extragenic suppressor gene, designated DBP4 (DEAD box protein 4), encodes an essential, putative RNA helicase of the DEAD-DEXH box family. Suppression by DBP4 (initially CA4 [T.-H. Chang, J. Arenas, and J. Abelson, Proc. Natl. Acad. Sci. USA 87:1571-1575, 1990]) restores the level of 18S rRNA and is specific for the Y domain but is not allele specific. DBP4 is predicted to function either in assembly of the U14 small nucleolar RNP or, more likely, in its interaction with other components of the rRNA processing apparatus. Mediating the interaction of U14 with precursor 18S RNA is an especially attractive possibility.     

Precursors to the U3 small nucleolar RNA lack small nucleolar RNP proteins but are stabilized by La binding

Almost all small eukaryotic RNAs are processed from transiently stabilized 3'-extended forms. A key question is how and why such intermediates are stabilized and how they can then be processed to the mature RNA. Here we report that yeast U3 is also processed from a 3'-extended precursor. The major 3'-extended forms of U3 (U3-3'I and -II) lack the cap trimethylation present in mature U3 and are not associated with small nucleolar RNP (snoRNP) proteins that bind mature U3, i.e., Nop1p, Nop56p, and Nop58p. Depletion of Nop58p leads to the loss of mature U3 but increases the level of U3-3'I and -II, indicating a requirement for the snoRNP proteins for final maturation. Pre-U3 is cleaved by the endonuclease Rnt1p, but U3-3'I and -II do not extend to the Rnt1p cleavage sites. Rather, they terminate at poly(U) tracts, suggesting that they might be bound by Lhp1p (the yeast homologue of La). Immunoprecipitation of Lhp1p fused to Staphylococcus aureus protein A resulted in coprecipitation of both U3-3'I and -II. Deletion of LHP1, which is nonessential, led to the loss of U3-3'I and -II. We conclude that pre-U3 is cleaved by Rnt1p, followed by exonuclease digestion to U3-3'I and -II. These species are stabilized against continued degradation by binding of Lhp1p. Displacement of Lhp1p by binding of the snoRNP proteins allows final maturation, which involves the exosome complex of 3'-->5' exonucleases.     

Isolation and characterization of a human U3 small nucleolar RNA gene

U3 RNA is an abundant, capped, small nucleolar RNA, implicated in the processing of preribosomal RNA. In this study, a DNA clone coding for U3 RNA (clone U3-1) was isolated from a human genomic library and characterized. The DNA sequence was identical to that of human U3 RNA isolated from HeLa cells. The flanking regions showed homology to the enhancer, promoter, and 3'-processing signal found in U1 and U2 snRNA genes. Further, the recently identified "U3 box" (GATTGGCTGCN10TATGTTAATTATGG) of rat U3 genes (Stroke and Weiner, (1985) J. Mol. Biol. 184, 183-193), was also found in the human U3 gene. This gene was transcribed in Xenopus oocytes; it is the first cloned true human U3 gene.     

Identification of molecular contacts between the U1 A small nuclear ribonucleoprotein and U1 RNA.

We recently determined the crystal structure of the RNP domain of the U1 small nuclear ribonucleoprotein A and identified Arg and Lys residues involved in U1 RNA binding. These residues are clustered around the two highly conserved segments, RNP1 and RNP2, located in the central two beta strands. We have now studied the U1 RNA binding of mutants where potentially hydrogen bonding residues on the RNA binding surface were replaced by non-hydrogen bonding residues. In the RNP2 segment, the Thr11----Val and Asn15----Val mutations completely abolished, and the Tyr13----Phe and Asn16----Val mutations substantially reduced the U1 RNA binding, suggesting that these residues form hydrogen bonds with the RNA. In the RNP1 segment Arg52----Gln abolished, but Arg52----Lys only slightly affected U1 RNA binding, suggesting that Arg52 may form a salt bridge with phosphates of U1 RNA. Ethylation protection experiments of U1 RNA show that the backbone phosphates of the 3' two-thirds of loop II and the 5' stem are in contact with the U1 A protein. The U1 A protein-U1 RNA binding constant is substantially reduced by A----G and G----A replacements in loop II, but not by C----U or U----C replacements. Based on these biochemical data we propose a structure for the complex between the U1 A ribonucleoprotein and U1 RNA.     

Characterization of the intron-encoded U19 RNA, a new mammalian small nucleolar RNA that is not associated with fibrillarin.

We have characterized a new member (U19) of a group of mammalian small nuclear RNAs that are not precipitable with antibodies against fibrillarin, a conserved nucleolar protein associated with most of the small nucleolar RNAs characterized to date. Human U19 RNA is 200 nucleotides long and possesses 5'-monophosphate and 3'-hydroxyl termini. It lacks functional boxes C and D, sequence motifs required for fibrillarin binding in many other snoRNAs. Human and mouse RNA are 86% homologous and can be folded into similar secondary structures, a finding supported by the results of nuclease probing of the RNA. In the human genome, U19 RNA is encoded in the intron of an as yet not fully characterized gene and could be faithfully processed from a longer precursor RNA in HeLa cell extracts. During fractionation of HeLa cell nucleolar extracts on glycerol gradients, U19 RNA was associated with higher-order structures of approximately 65S, cosedimenting with complexes containing 7-2/MRP RNA, a conserved nucleolar RNA shown to be involved in 5.8S rRNA processing in yeast cells.     

A model for the involvement of the small nucleolar RNA (U3) in processing eukaryotic ribosomal RNA

The nucleotide sequence of chick pre-rRNA between 5.8S and 28S rRNAs is 85% G + C and has the potential to form many different secondary structures. A model is presented in which a small nucleolar RNA, U3, and its associated proteins act as an RNA isomerase to position the pre-rRNA for processing. Cleavage could be performed either by a nuclease present in the U3RNP or by a ribonuclease directed to the proper form of the pre-rRNA.     

A yeast small nuclear RNA is required for normal processing of pre-ribosomal RNA.

In Saccharomyces cerevisiae, seven snRNAs (snR3, 4, 5, 8, 9, 10 and 17) are retained in the nucleus under conditions in which nucleoplasmic RNAs are lost, and may be nucleolar. All of these snRNAs show properties consistent with hydrogen bonding to pre-ribosomal RNAs; snR5 and 8 with 20S pre-rRNA, snR3, 4, 10 and 17 with 35S pre-rRNA and snR9 with 20-35S RNA. Strains lacking snR10 are impaired in growth and specifically defective in the processing of 35S RNA. Processing is slowed, leading to 35S RNA accumulation and most cleavage occurs, not at the normal sites, but at sites which in wild-type strains are used for subsequent steps in rRNA maturation.     

A small nucleolar guide RNA functions both in 2'-O-ribose methylation and pseudouridylation of the U5 spliceosomal RNA

In eukaryotes, two distinct classes of small nucleolar RNAs (snoRNAs), namely the fibrillarin-associated box C/D snoRNAs and the Gar1p-associated box H/ACA snoRNAs, direct the site-specific 2'-O-ribose methylation and pseudouridylation of ribosomal RNAs (rRNAs), respectively. We have identified a novel evolutionarily conserved snoRNA, called U85, which possesses the box elements of both classes of snoRNAs and associates with both fibrillarin and Gar1p. In vitro and in vivo pseudouridylation and 2'-O-methylation experiments provide evidence that the U85 snoRNA directs 2'-O-methylation of the C45 and pseudouridylation of the U46 residues in the invariant loop 1 of the human U5 spliceosomal RNA. The U85 is the first example of a snoRNA that directs modification of an RNA polymerase II-transcribed spliceosomal RNA and that functions both in RNA pseudouridylation and 2'-O-methylation.     

Probing RNA in vivo with methylation guide small nucleolar RNAs

Most box C/D small nucleolar RNAs (snoRNAs) direct the formation of 2'-O-methylated nucleotides in ribosomal RNA and, apparently, other RNAs present in the nucleolar complex. Sites to be modified are selected by a long (>10-nt) antisense guide sequence in the snoRNA and a distance measurement from a box D or D' element that follows the snoRNA guide sequence. Modification of the substrate occurs in the region of complementarity, at a position five nucleotides upstream from box D/D'. Methylation can be targeted to novel sites by expressing a snoRNA with a new guide sequence. In some cases methylation impairs the growth rate of the cell, indicating that a functionally important nucleotide has been altered. With a view to harnessing snoRNA-directed methylation for functional mapping, we have developed a method for constructing libraries of snoRNA genes that, in principle, can introduce methylation point mutations into any rRNA segment of interest. The strategy and procedures are described here, and preliminary results are presented that show the feasibility of using this technology to probe a region of the yeast large subunit rRNA that includes the core of the peptidyltransferase center.     

Distribution of U3 small nucleolar RNA and fibrillarin during early embryogenesis in Caenorhabditis elegans

U3 small nucleolar RNA (snoRNA) is one of the members of the box C/D class of snoRNA and is essential for ribosomal RNA (rRNA) processing to generate 18S rRNA in the nucleolus. Although U3 snoRNA is abundant, and is well conserved from yeast to mammals, the genes encoding U3 snoRNA in C. elegans have long remained unidentified. A recent RNomics study in C. elegans predicted five distinct U3 snoRNA genes. However, characterization of these candidates for U3 snoRNA has yet to be performed. In this study, we isolated and characterized four candidate RNAs for U3 snoRNA from the immunoprecipitated RNAs of C. elegans using an antibody against the 2,2,7-trimethylguanosine (TMG) cap. The sequences were identical to the predicted U3 sequences in the RNomics study. Here, we show the several lines of evidence that the isolated RNAs are the true U3 snoRNAs of C. elegans. Moreover, we report the novel expression pattern of U3 snoRNA and fibrillarin, which is an essential component of U3 small nucleolar ribonucleoprotein complex, during early embryo development of C. elegans. To our knowledge, this is the first observation of the inconsistent localization U3 snoRNA and fibrillarin during early embryogenesis, providing novel insight into the mechanisms of nucleologenesis and ribosome production during early embryogenesis.