Selection of a preribosomal RNA processing site by a nucleolar endoribonuclease involves formation of a stable complex.

A nucleolar endoribonuclease from mouse Ehrlich ascites tumor cells, that has been implicated in the endonucleolytic cleavage of mouse precursor ribosomal RNA, specifically and stably binds an in vitro-derived rRNA transcript containing the +650 early processing site. The specificity of binding was demonstrated by mobility shift analysis, glycerol gradient velocity sedimentation analysis, and UV-crosslinking studies. Binding did not require Mg2+ and therefore was not dependent on cleavage; however, binding was dependent on the presence of the early +650 processing site since a pre-rRNA transcript with the +650 processing site deleted failed to compete in binding. A small nucleolar RNA component was not required for the formation of this stable complex or for the specific cleavage of a processing competent pre-rRNA transcript. UV crosslinking studies using 32P-labeled 5-azidouridine-substituted pre-rRNA with bound nucleolar endoribonuclease identified three closely sized polypeptides of approximately 50, approximately 48, and approximately 45 kDa, respectively, that specifically crosslinked to the processing competent rRNA transcript. These three polypeptides species were identified following ribonuclease digestion and electrophoresis on a SDS-polyacrylamide gel. An identical pattern of labeled polypeptides was also identified from gel mobility shift analysis where the specifically shifted material was U.V. crosslinked. The largest of these polypeptides corresponded to the estimated size of the nucleolar endoribonuclease, while the lower molecular weight species may represent partially proteolyzed enzyme. Overall, these results suggest that the unique specificity of the nucleolar endoribonuclease may, in part, be attributed to the formation of a stable complex at the +650 processing site for mouse preribosomal RNA, and that formation of this unique stable complex affords a means to specifically label the limited amount of available partially purified enzyme for sequence analysis.

In vitro processing at the 3'-terminal region of pre-18S rRNA by a nucleolar endoribonuclease.

In an investigation of the possible involvement of a highly purified nucleolar endoribonuclease in processing of pre-rRNA at the 3' end of the 18S rRNA sequence, an in vitro synthesized pre-18S rRNA transcript containing the 3' end region of 18S rRNA and the 5' region of the first internal transcribed spacer (ITS1) was used as a substrate for the enzyme. Cleavages generated by the nucleolar RNase were localized by S1 nuclease protection analysis and by the direct release of labeled rRNA products. Precise determination of the specificity of cleavage was achieved by RNA sequence analysis with end-labeled rRNA transcripts. These data demonstrated that the purified nucleolar RNase cleaved the pre-18S rRNA transcript at three specific sites relative to the 3' region of 18S rRNA. The first two sites included the mature 3'-end 18S rRNA sequence and a site approximately 55 nucleotides downstream of the 3'-end 18S rRNA sequence, both of which corresponded directly to recent results (Raziuddin, R. D. Little, T. Labella, and D. Schlessinger, Mol. Cell. Biol. 9:1667-1671, 1989) obtained with transfected mouse rDNA in hamster cells. The other cleavage occurred approximately 35 nucleotides upstream from the mature 3' end in the 18S rRNA sequence. The results from this study mimic the results obtained from in vivo studies for processing in the 3' region of pre-18S rRNA, supporting the proposed involvement of this nucleolar endoribonuclease in rRNA maturation.

Ribosomal RNA processing. Limited cleavages of mouse preribosomal RNA by a nucleolar endoribonuclease include the early +650 processing site.

A highly purified nucleolar associated endoribonuclease was tested for possible involvement in the processing of precursor ribosomal RNA at a primary cleavage site approximately 650 nucleotides downstream from the transcription initiation site. Preribosomal RNA sequences containing the +650 region were synthesized in vitro and subsequently digested over a range of concentrations of the nucleolar endoribonuclease. Cleavages generated by the nucleolar endoribonuclease were localized both by S1 nuclease protection analysis and primer extension analysis. A more precise determination of the specificity of cleavage was achieved by chemical cleavage DNA sequence analysis. These data demonstrated that the purified nucleolar endoribonuclease specifically cleaved the precursor ribosomal RNA transcript at the +650 site. Additional enzyme-dependent cleavages were observed upstream to the +650 site in a region which is rapidly degraded following processing at the +650 site in vivo. No major cleavages were observed for a distance of approximately 250 nucleotides downstream from the +650 site in a conserved region of sequence previously shown to be important in specifying processing at the +650 site. As a control, pancreatic ribonuclease, a single strand-specific endoribonuclease, was shown not to produce similar cleavages in the +650 region, indicating that cleavage by the nucleolar RNase was not simply due to accessibility of the RNA at the +650 site. Taken together, these results suggest that the nucleolar endoribonuclease may be necessary and sufficient to catalyze one of the initial endonucleolytic cleavages in preribosomal RNA processing.

Isolation and characterization of a nucleolar 2'-O-methyltransferase from Ehrlich ascites tumor cells.

A 2'-O-methyltransferase that transfers the methyl group from S-adenosylmethionine to the 2'-hydroxyl group of ribose moieties of RNA has been purified from Ehrlich ascites tumor cell nucleoli. The partially purified enzyme is devoid of other RNA methylase activities and is free of ribonucleases. The enzyme has optimal activity in tris(hydroxymethyl)aminomethane buffer, pH 8.0, in the presence of 0.4 mM ethylenediaminetetraacetic acid, 2 mM dithiothreitol, and 50 mM KCl, and has an apparent Km for S-adenosylmethionine of 0.44 microM. Gel filtration studies of this enzyme gave a Stokes radius of 43 A. Sedimentation velocity measurements in glycerol gradients yield an S20,w of 8.0 S. From these values, a native molecular weight of 145,000 was calculated. The enzyme catalyzes the methylation of synthetic homoribopolymers as well as 18S and 28S rRNA; however, poly(C) is the preferred synthetic substrate, and preference for unmethylated sequences of rRNA was observed. For each RNA substrate examined, only methylation of the 2'-hydroxyl group of the ribose moieties was detected.