Ribosomal RNA: small nucleolar RNAs make their mark

Crystal structures of U8 snoRNA decapping nudix hydrolase, X29, and its metal and cap complexes

X29, a 25 kDa Nudix hydrolase from Xenopus laevis that cleaves 5' caps from U8 snoRNA, crystallizes as a homodimeric apoenzyme. Manganese binds crystals of apo-X29 to form holo-X29 only in the presence of nucleot(s)ide. Structural changes in X29 on nucleo-t(s)ide-assisted Mn(+2) uptake account for the observed cooperativity of metal binding. Structures of X29 with GTP or m7GpppA show a different mode of ligand binding from that of other cap binding proteins and suggest a possible three- or four-metal Nudix reaction mechanism. The X29 dimer has no known RNA binding motif, but its striking surface dipolarity and unique structural features create a plausible RNA binding channel on the positive face of the protein. Because U8 snoRNP is essential for accumulation of mature 5.8S and 28S rRNA in vertebrate ribosome biogenesis, and cap structures are required for U8 stability in vivo, X29 could profoundly influence this fundamental cellular pathway.

Xenopus U8 snoRNA binding protein is a conserved nuclear decapping enzyme

U8 snoRNP is required for accumulation of mature 5.8S and 28S rRNA in vertebrates. We are identifying proteins that bind U8 RNA with high specificity to understand how U8 functions in ribosome biogenesis. Here, we characterize a Xenopus 29 kDa protein (X29), which we previously showed binds U8 RNA with high affinity. X29 and putative homologs in other vertebrates contain a NUDIX domain found in MutT and other nucleotide diphosphatases. Recombinant X29 protein has diphosphatase activity that removes m(7)G and m(227)G caps from U8 and other RNAs in vitro; the putative 29 kDa human homolog also displays this decapping activity. X29 is primarily nucleolar in Xenopus tissue culture cells. We propose that X29 is a member of a conserved family of nuclear decapping proteins that function in regulating the level of U8 snoRNA and other nuclear RNAs with methylated caps.

Ribosome biogenesis: ribosomal RNA synthesis as a package deal

Ribosome biogenesis encompasses a complicated series of events involving hundreds of transiently interacting components. Insight into a mechanism for coordinating some of these events may come from characterization of a functional processing complex.

Xenopus LSm proteins bind U8 snoRNA via an internal evolutionarily conserved octamer sequence

U8 snoRNA plays a unique role in ribosome biogenesis: it is the only snoRNA essential for maturation of the large ribosomal subunit RNAs, 5.8S and 28S. To learn the mechanisms behind the in vivo role of U8 snoRNA, we have purified to near homogeneity and characterized a set of proteins responsible for the formation of a specific U8 RNA-binding complex. This 75-kDa complex is stable in the absence of added RNA and binds U8 with high specificity, requiring the conserved octamer sequence present in all U8 homologues. At least two proteins in this complex can be cross-linked directly to U8 RNA. We have identified the proteins as Xenopus homologues of the LSm (like Sm) proteins, which were previously reported to be involved in cytoplasmic degradation of mRNA and nuclear stabilization of U6 snRNA. We have identified LSm2, -3, -4, -6, -7, and -8 in our purified complex and found that this complex associates with U8 RNA in vivo. This purified complex can bind U6 snRNA in vitro but does not bind U3 or U14 snoRNA in vitro, demonstrating that the LSm complex specifically recognizes U8 RNA.

The U8 snoRNA gene family: identification and characterization of distinct, functional U8 genes in Xenopus

U8 snoRNA is the RNA component of a small nucleolar ribonucleoprotein (U8 snoRNP) required for accumulation of mature 5.8S and 28S rRNAs, components of the large ribosomal subunit. We have identified two putative U8 genes in Xenopus laevis. Sequence analysis of the coding regions of these two genes indicate that both differ at several positions from the previously characterized U8 RNA and that the two differ from each other. Functional analysis of these genes indicates that both are transcribed in vivo, produce stable U8 transcripts, and are capable of facilitating pre-rRNA processing in vivo. These data demonstrate that natural sequence variation exists among the U8 snoRNA genes in Xenopus. Alignment of these three Xenopus U8 sequences with the previously described mammalian U8 homologues in mouse, rat and human has provided information about evolutionarily conserved sequence and structural elements in U8 RNA. Identification and functional characterization of these naturally occurring variants in Xenopus has helped identify regions in U8 RNA that may be critical for function.

Non-coding snoRNA host genes in Drosophila: expression strategies for modification guide snoRNAs

Modification guide snoRNAs either are encoded within introns and co-transcribed with the host gene pre-mRNA or are independently transcribed as mono- or polycistronic units. Different eukaryotic kingdoms utilize these coding strategies to various degrees. Intron-encoded and polycistronic snoRNAs are released from primary transcripts as pre-snoRNAs by the spliceosome or by an RNase III-like activity, respectively. In the spliceosomal pathway, the resulting intron lariat is then linearized by a debranching activity. The leader and trailer sequences of pre-snoRNAs are removed by exonucleolytic activities. The majority of snoRNA host genes encode proteins involved in the synthesis, structure or function of the translational apparatus. Several vertebrate snoRNA host genes do not appear to code for functional proteins. We have identified two unusually compact box C/D multi-snoRNA host genes in D. melanogaster, dUHG1 and dUHG2, similar in their organization to the corresponding vertebrate non-protein-coding host genes. In dUHG1 and dUHG2, the snoRNA sequences are located within introns at a conserved distance of about 75 nucleotides upstream of the 3' splice sites. Both genes initiate transcription with TOP-like sequences that share unique features with previously reported Drosophila snoRNA host genes. Although the spliced dUHG RNAs are relatively stable, they exhibit little potential for protein coding.

Fibrillarin-associated box C/D small nucleolar RNAs in Trypanosoma brucei. Sequence conservation and implications for 2'-O-ribose methylation of rRNA

We report the identification of 17 box C/D fibrillarin-associated small nucleolar RNAs (snoRNAs) from the ancient eukaryote, Trypanosoma brucei. To systematically isolate and characterize these snoRNAs, the T. brucei cDNA for the box C/D snoRNA common protein, fibrillarin, was cloned and polyclonal antibodies to the recombinant fibrillarin protein were generated in rabbits. Immunoprecipitations from T. brucei extracts with the anti-fibrillarin antibodies indicated that this trypanosomatid has at least 30 fibrillarin-associated snoRNAs. We have sequenced seventeen of them and designated them TBR for T. brucei RNA 1-17. All of them bear conserved box C, D, C', and D' elements, a hallmark of fibrillarin-associated snoRNAs in eukaryotes. Fourteen of them are novel T. brucei snoRNAs. Fifteen bear potential guide regions to mature rRNAs suggesting that they are involved in 2'-O-ribose methylation. Indeed, eight ribose methylations have been mapped in the rRNA at sites predicted by the snoRNA sequences. Comparative genomics indicates that six of the seventeen are the first trypanosome homologs of known yeast and vertebrate methylation guide snoRNAs. Our results indicate that T. brucei has many fibrillarin-associated box C/D snoRNAs with roles in 2'-O-ribose methylation of rRNA and that the mechanism for targeting the nucleotide to be methylated at the fifth nucleotide upstream of box D or D' originated in early eukaryotes.

Identification of a U8 snoRNA-specific binding protein

Eukaryotic nucleoli contain a large and diverse population of small nucleolar ribonucleoprotein particles (snoRNPs) that play diverse and essential roles in ribosome biogenesis. We previously demonstrated that U8 snoRNP is essential for processing of both 5.8 and 28 S rRNA. The RNA component of the U8 RNP particle is necessary but not sufficient for processing. Using an electrophoretic mobility sift assay, we enriched for U8-specific binding proteins from Xenopus ovary extracts. UV cross-linking reactions with partially purified fractions implicated a 29-kDa protein directly binding to U8 RNA. This protein interacted specifically and with high affinity with U8 snoRNA; it did not bind other snoRNAs and is probably not a common component of all snoRNPs. This is the first report of a protein component specific to an snoRNP essential for processing of the large ribosomal subunit in vertebrates.

Elements essential for accumulation and function of small nucleolar RNAs directing site-specific pseudouridylation of ribosomal RNAs

During site-specific pseudouridylation of eukaryotic rRNAs, selection of correct substrate uridines for isomerization into pseudouridine is directed by small nucleolar RNAs (snoRNAs). The pseudouridylation guide snoRNAs share a common 'hairpin-hinge- hairpin-tail' secondary structure and two conserved sequence motifs, the H and ACA boxes, located in the single-stranded hinge and tail regions, respectively. In the 5'- and/or 3'-terminal hairpin, an internal loop structure, the pseudouridylation pocket, selects the target uridine through formation of base-pairing interactions with rRNAs. Here, essential elements for accumulation and function of rRNA pseudouridylation guide snoRNAs have been analysed by expressing various mutant yeast snR5, snR36 and human U65 snoRNAs in yeast cells. We demonstrate that the H and ACA boxes that are required for formation of the correct 5' and 3' ends of the snoRNA, respectively, are also essential for the pseudouridylation reaction directed by both the 5'- and 3'-terminal pseudouridylation pockets. Similarly, RNA helices flanking the two pseudouridylation pockets are equally essential for pseudouridylation reactions mediated by either the 5' or 3' hairpin structure, indicating that the two hairpin domains function in a highly co-operative manner. Finally, we demonstrate that by manipulating the rRNA recognition motifs of pseudouridylation guide snoRNAs, novel pseudouridylation sites can be generated in yeast rRNAs.

Evolution of U24 and U36 snoRNAs encoded within introns of vertebrate rpL7a gene homologs: unique features of mammalian U36 variants

U24 and U36 are members of the box C/D-containing group of antisense snoRNAs which possess long (9-21 nucleotide) conserved stretches of sequence complementarity to 18S and 28S rRNA and act as guides for the site-specific ribose methylation of rRNA. Both U24 and two variants of U36 are encoded within introns of the human and chicken rpL7a genes. We now report that an additional U36 variant is encoded within intron 4 of the human rpL7a gene and that murine homologs of the three human U36 variants are encoded within the same adjacent introns (4, 5, and 6) of the mouse rpL7a gene. We also show that, like that of the chicken, the Fugu rubripes rpL7a gene possesses only two U36-like sequences within introns 4 and 5. Whereas the two U36 variants in chicken and Fugu possess stretches of complementarity to both 18S and 28S rRNAs, it is noted that only one mammalian variant (U36b) possesses both. Unusually, the stretch of complementarity to 18S rRNA in the mammalian U36a variants and the stretch of complementarity to 28S rRNA in the mammalian U36c variants are not present, appearing to have diverged extensively from their consensus sequence. Additionally, the mammalian U36 variants show a unique heterogeneity in their potential to form a terminal stembox structure predicted for many other box C/D-containing antisense snoRNAs. Finally, the Saccharomyces cerevisiae small nuclear RNA, snR47, is shown to be homologous to the vertebrate U36 snoRNA.

The snoRNA box C/D motif directs nucleolar targeting and also couples snoRNA synthesis and localization

Most small nucleolar RNAs (snoRNAs) fall into two families, known as the box C/D and box H/ACA snoRNAs. The various box elements are essential for snoRNA production and for snoRNA-directed modification of rRNA nucleotides. In the case of the box C/D snoRNAs, boxes C and D and an adjoining stem form a vital structure, known as the box C/D motif. Here, we examined expression of natural and artificial box C/D snoRNAs in yeast and mammalian cells, to assess the role of the box C/D motif in snoRNA localization. The results demonstrate that the motif is necessary and sufficient for nucleolar targeting, both in yeast and mammals. Moreover, in mammalian cells, RNA is targeted to coiled bodies as well. Thus, the box C/D motif is the first intranuclear RNA trafficking signal identified for an RNA family. Remarkably, it also couples snoRNA localization with synthesis and, most likely, function. The distribution of snoRNA precursors in mammalian cells suggests that this coupling is provided by a specific protein(s) which binds the box C/D motif during or rapidly after snoRNA transcription. The conserved nature of the box C/D motif indicates that its role in coupling production and localization of snoRNAs is of ancient evolutionary origin.

Functional mapping of the U3 small nucleolar RNA from the yeast Saccharomyces cerevisiae

The U3 small nucleolar RNA participates in early events of eukaryotic pre-rRNA cleavage and is essential for formation of 18S rRNA. Using an in vivo system, we have developed a functional map of the U3 small nucleolar RNA from Saccharomyces cerevisiae. The test strain features a galactose-dependent U3 gene in the chromosome and a plasmid-encoded allele with a unique hybridization tag. Effects of mutations on U3 production were analyzed by evaluating RNA levels in cells grown on galactose medium, and effects on U3 function were assessed by growing cells on glucose medium. The major findings are as follows: (i) boxes C' and D and flanking helices are critical for U3 accumulation; (ii) boxes B and C are not essential for U3 production but are important for function, most likely due to binding of a trans-acting factor(s); (iii) the 5' portion of U3 is required for function but not stability; and, (iv) strikingly, the nonconserved hairpins 2, 3, and 4, which account for 50% of the molecule, are not required for accumulation or function.

Sequence and structural elements of methylation guide snoRNAs essential for site-specific ribose methylation of pre-rRNA

Site-specific 2'-O-ribose methylation of eukaryotic rRNAs is guided by small nucleolar RNAs (snoRNAs). The methylation guide snoRNAs carry long perfect complementaries to rRNAs. These antisense elements are located either in the 5' half or in the 3' end region of the snoRNA, and are followed by the conserved D' or D box motifs, respectively. An uninterrupted helix formed between the rRNA and the antisense element of the snoRNA, in conjunction with the adjacent D' or D box, constitute the recognition signal for the putative methyltransferase. Here, we have identified an additional essential box element common to methylation guide snoRNAs, termed the C' box. We show that the C' box functions in concert with the D' box and plays a crucial role in the methyltransfer reaction directed by the upstream antisense element and the D' box. We also show that an internal fragment of U24 methylation guide snoRNA, encompassing the upstream antisense element and the D' and C' box motifs, can support the site-specific methylation of rRNA. This strongly suggests that the C box of methylation guide snoRNAs plays an essential role in the methyltransfer reaction guided by the 3'-terminal antisense element and the D box of the snoRNA.

RNA processing: pocket guides to ribosomal RNA

The functional role of a recently identified class of small nucleolar (sno) RNAs has been elucidated: the 'box H/ACA' snoRNAs act as guide RNAs, specifying the position of evolutionarily conserved pseudouridines in ribosomal (r)RNA via an rRNA-snoRNA base-pairing interaction that forms a 'pseudouridine pocket'.

Small nucleolar RNAs direct site-specific synthesis of pseudouridine in ribosomal RNA

Ten ACA yeast small nucleolar RNAs (snoRNAs) were shown to be required for site-specific synthesis of pseudouridine psi in ribosomal RNA. A common secondary folding motif for the snoRNAs and rRNA target segments predicts that site selection involves: (1) base pairing of the snoRNA with complementary rRNA elements flanking the site of modification, and (2) identification of a uridine located at a near-constant distance from the snoRNA ACA box. The model is supported by mutations showing that: (1) reducing the complementarity between the snoRNA and rRNA disrupts psi formation, and (2) altering the distance between the ACA box and target uridine causes an adjacent uridine to be modified. This discovery implies that most snoRNAs function in targeting nucleotide modification in rRNA: ribose methylation for the box C/D snoRNAs and psi formation for the ACA snoRNAs.