Determination of nucleotide sequences from double-stranded regions of HeLa cell nuclear RNA

Localisation of an endonuclease specific for double-stranded RNA within the nucleolus and its implication in processing ribosomal transcripts

Nucleoli of both chick embryos and mouse Ehrlich ascites cells contain an enzymatic activity that is very similar to RNase DII, an enzyme isolated from total chick embryos for its ability to degrade double-stranded RNA. The enzyme can be extracted by low salt/EDTA from nucleoli and is associated with pre-ribosomal 80-S and 55-S particles. Under ionic conditions which are inhibitory for the nucleolytic activity the transcript in vitro of nucleoli is not processed and sediments around 45 S. Under salt conditions which are optimal for the nucleolar enzyme the nucleolar transcripts are cleaved to distinct intermediate-sized molecules. Addition of the chicken RNase DII or RNase III to the nucleolar transcription system results in a similar shift of the chain length of the RNA molecules. It is concluded that a nucleolar RNase recognizing double-stranded regions in the pre-ribosomal RNA is involved in the maturation of ribosomal RNA.

Oligonucleotides in heterogeneous nuclear RNA: similarity of inverted repeats and RNA from repetitious DNA sites

A comparison has been made by oligonucleotide analysis of three fractions of HeLa cell hnRNA: (1) the "snap-back" fraction (ds-hnRNA, 5% of the total); (2) the fraction that self-anneals during prolonged incubation (25% of total); and (3) the fraction that hybridizes most rapidly to an excess of HeLa cell DNA (rep-hnRNA, 10% of the total). T1 fingerprints of each of these hnRNA fractions were similar to one another and featured the largest T1 oligonucleotides of known sequence previously isolated from ds-hnRNA (Robertson, H.D., et al. (1977) J. Mol. Biol. 115, 571--590; Jelinek, W. (1977 J. Mol. Biol. 115, 591--602). When hybridized to DNA either in solution or immobilized on filters, the isolated ds-hnRNA and the rep-hnRNA fractions showed similar hybridization kinetics in the COt range of "intermediate" repetitive DNA sequences; the ds-hnRNA and the rep-hnRNA also self-annealed to equal extents in the absence of any DNA. DNA of all buoyant density classes contained the T1 oligonucleotides diagnostic of the ds-hnRNA and the rep-hnRNA. While hnRNA is rich in inverted repeated sequences, cytoplasmic mRNA contains far fewer such sequences.

The precursor of mouse beta-globin messenger RNA contains two intervening RNA sequences

We have investigated the locations of the poly(A), the mRNA-specific sequences and the RNA sequences that are eventually cleaved from the 1860 nucleotide precursor of mouse beta-globin mRNA. Biochemical and electron microscopic data demonstrate that there are two intervening RNA moieties in the precursor which separate the beta-globin mRNA sequences into three portions containing 480, 205 and 155 nucleotides. One of the two intervening RNA moieties contains 780 nucleotides. The size of the smaller intervening RNA has not been determined precisely, but it is 125 nucleotides or less. The largest mRNA-specific fragment is derived from the 3' terminus of the precursor, and contains the 3' terminal poly (A) and 330 mRNA-specific transcribed nucleotides. At least one, and probably both, intervening RNAs occur within the coding portion of the mRNA sequences. The larger of the intervening RNAs is located next to the 480 nucleotide mRNA-specific fragment, and the smaller intervening RNA is located between the 205 and 155 nucleotide mRNA-specific fragments. These experiments are consistent with the notion that the intervening sequences in the DNA of mouse beta-globin genes are transcribed into the mRNA precursor and are excised from the RNA by post-transcriptional events.