Several snoRNAs are essential for the sequence of cleavage events required to produce the mature forms of 18S, 5.8S, and 28S rRNA from the large precursor molecule. In the absence of U22, mature 18S rRNA fails to accumulate; U8 snoRNA is essential for accumulation of both 5.8S and 28S rRNA. The mechanisms by which snoRNAs facilitate these cleavage events is not known and might include direct cleavage or assisting the rate or efficiency of ribosome assembly. To learn more about the mechanisms of snoRNA-mediated pre-rRNA processing, an examination of the kinetics of pre-rRNA processing in Xenopus oocytes was undertaken. Correct pre-rRNA processing can be restored in snoRNA-depleted oocytes following cytoplasmic injection of the corresponding in vitro-synthesized snoRNA. Analysis of the kinetics of pre-rRNA processing in these snoRNA-rescue experiments demonstrated that the rate of accumulation of mature rRNAs was slower than that seen in untreated oocytes. The snoRNAs were imported into the nucleus at a rate and overall efficiency less than that of U1 snRNA, used as a control for import. However, sufficient levels of snoRNA were present in the nucleus to yield a functional phenotype (rescue of rRNA processing) several hours before the snoRNAs were directly detectable in the nucleus via autoradiography. This indicated that very low amounts of the snoRNA in the nucleus were sufficient for rescue. Finally, transcriptional inhibitors were used to separate transcription and processing. Failure to rescue snoRNA-mediated processing of pre-accumulated precursors is consistent with a scenario in which U8 and U22 must be present during transcription of pre-rRNA.

The yeast nucleolar protein Rrp5p is the only known trans-acting factor that is essential for the synthesis of both 18S rRNA and the major, short form of 5.8S (5.8SS) rRNA, which were thought to be produced in two independent sets of pre-rRNA processing reactions. To identify domains within Rrp5p required for either processing pathway, we have analyzed a set of eight deletion mutants that together cover the entire RRP5 sequence. Surprisingly, only one of the deletions is lethal, indicating that regions encompassing about 80% of the protein can be removed individually without disrupting its essential biological function. Biochemical analysis clearly demonstrated the presence of two distinct functional domains. Removal of each of three contiguous segments from the N-terminal half specifically inhibits the formation of 5.8SS rRNA, whereas deleting part of the C-terminal region of the protein only blocks the production of 18S rRNA. The latter phenotype is also caused by a temperature-sensitive mutation within the same C-terminal region. The two functional regions identified by the mutational analysis appear to be correlated with the structural domains detected by computer analysis. They can even be physically separated, as demonstrated by the fact that full Rrp5p activity can be supplied by two contiguous protein fragments expressed in trans.

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.

Accurate and efficient processing of pre-rRNA is critical to the accumulation of mature functional ribosomal subunits for maintenance of cell growth. Processing requires numerous factors which act in trans as well as RNA sequence/structural elements which function in cis. To examine the latter, we have used directed mutagenesis and expression of mutated pre-rRNAs in yeast. Specifically, we tested requirements for formation of an ITS2-proximal stem on processing, a structure formed by an interaction between sequences corresponding to the 3′ end of 5.8S rRNA and the 5′ end of 25S. Pre-rRNA processing is inhibited in templates encoding mutations that prevent the formation of the ITS2-proximal stem. Compensatory, double mutations, which alter the sequence of this region but restore the structure of the stem, also restore processing, although at lower efficiency. This reduction in efficiency is reflected in decreased levels of mature 5.8S and 25S rRNA and increased levels of 35S pre-rRNA and certain processing intermediates. This phenotype is reminiscent of the biochemical depletion of U8 snoRNA in vertebrates for which the ITS2-proximal stem has been proposed as a potential site for interaction with U8 RNP. Thus, formation of the ITS2-proximal stem may be a requirement common to yeast and vertebrate pre-rRNA processing.

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.