Secondary structure maps of ribosomal RNA and DNA: I. Processing of Xenopus laevis ribosomal RNA and structure of single-stranded ribosomal DNA

Precursor and mature ribosomal RNA molecules from Xenopus laevis were examined by electron microscopy. A reproducible arrangement of hairpin loops was observed in these molecules. Maps based on this secondary structure were used to determine the arrangement of sequences in precursor RNA molecules and to identify the position of mature rRNAs within the precursors. A processing scheme was derived in which the 40 S rRNA is cleaved to 38 S RNA, which then yields 34 S plus 18 S RNA. The 34 S RNA is processed to 30 S, and finally to 28 S rRNA. The pathway is analogous to that of L-cell rRNA but differs from HeLa rRNA in that no 20 S rRNA intermediate was found. X. laevis 40 S rRNA (M_r = 2.7 × 10⁶) is much smaller than HeLa or L-cell 45 8 rRNA (M_r = 4.7 × 10⁶), but the arrangement of mature rRNA sequences in all precursors is very similar. Experiments with ascites cell 3′-exonuclease show that the 28 S region is located at or close to the 5′-end of the 40 S rRNA.Secondary structure maps were obtained also for single-stranded molecules of ribosomal DNA. The region in the DNA coding for the 40 S rRNA could be identified by its regular structure, which closely resembles that of the RNA. Regions corresponding to the 40 S RNA gene alternate with non-transcribed spacer regions along strands of rDNA. The latter have a large amount of irregular secondary structure and vary in length between different repeating units. A detailed map of the rDNA repeating unit was derived from these experiments.Optical melting studies are presented, showing that rRNAs with a high (G + C) content exhibit significant hypochromicity in the formamide/urea-containing solution that was used for spreading.     

Secondary structure maps of ribosomal RNA. II. Processing of mouse L-cell ribosomal RNA and variations in the processing pathway

Secondary structure mapping in the electron microscope was applied to ribosomal RNA and precusor ribosomal RNA molecules isolated from nucleoli and the cytoplasm of mouse L-cells. Highly reproducible loop patterns were observed in these molecules. The polarity of L-cell rRNA was determined by partial digestion with 3′-exonuclease. The 28 S region is located at the 5′-end of the 45 S rRNA precursor. Together with earlier experiments on labeling kinetics, these observations established a processing pathway for L-cell rRNA. The 45 S rRNA precursor is cleaved at the 3′-end of the 18 S RNA sequence to produce a 41 S molecule and a spacer-containing fragment (24 S RNA). The 41 S rRNA is cleaved forming mature 18 S rRNA and a 36 S molecule. The 36 S molecule is processed through a 32 S intermediate to the mature 28 S rRNA. This pathway is similar to that found in HeLa cells, except that in L-cells a 36 S molecule occurs in the major pathway and no 20 S precusor to 18 S RNA is found. The processing pathway and its intermediates in L-cells are analogous to those in Xenopus laevis, except for a considerable size difference in all rRNAs except 18 S rRNA.The arrangement of gene and transcribed spacer regions and of secondary structure loops, as well as the shape of the major loops were compared in L-cells, HeLa cell and Xenopus rRNA. The over-all arrangement of regions and loop patterns is very similar in the RNA from these three organisms. The shapes of loops in mature 28 S RNA are also highly conserved in evolution, but the shapes of loops in the transcribed spacer regions vary greatly. These observations suggest that the sequence complementarity that gives rise to this highly conserved secondary structure pattern may have some functional importance.     

A comparison of the structural organization of amplified ribosomal DNA from Xenopus mulleri and Xenopus laevis.

Secondary structure maps of long single strands of amplified ribosomal DNA from two closely related species of frogs, Xenopus laevis and X. mulleri, have been compared. The secondary structure pattern of the gene region is identical in both ribosomal DNAs while the patterns in the non-transcribed spacers² differ. In X. mulleri, the spacer shows an extended region without any secondary structure adjacent to the 28 S ribosomal RNA sequence. In contrast, the same region in the X. laevis spacer has extensive secondary structure. A comparison of secondary structure maps and denaturation maps of these two ribosomal DNAs (Brown et al., 1972) reveals that the portion without secondary structure in the X. mulleri spacer corresponds to an early melting A + T-rich region. As in X. laevis ribosomal DNA, Escherichia coli restriction endonuclease (EcoRI) makes two cuts in each repeating unit of amplified ribosomal DNA from X. mulleri. The position of the cleavage sites is identical in the two species as judged from secondary structure mapping of the two classes of EcoRI fragments generated. The small fragments of X. mulleri ribosomal DNA are homogeneous in size with a duplex molecular weight of 3.0 × 10⁶, and contain about 85% of the 28 S ribosomal RNA gene and about 17% of the 18 S ribosomal RNA gene. The large fragments are heterogeneous in size with molecular weights ranging from 4.2 to 4.9 × 10⁶, and contain the remaining portions of the gene regions and the nontranscribed spacer. Heteroduplexes made between large fragments of different lengths show only deletion loops. The position of these loops indicates that the length heterogeneity resides in the non-transcribed spacer region. Electrophoretic analysis of EcoRI digests of chromosomal ribosomal DNA from X. mulleri demonstrates that this DNA is heterogeneous in length as well.     

Ribosomal RNA synthesis in mitochondria of Neurospora crassa

Ribosomal RNA synthesis in Neurospora crassa mitochondria has been investigated by continuous labeling with [5-³H]uracil and pulse-chase experiments. A short-lived 32 S mitochondrial RNA was detected, along with two other short-lived components; one slightly larger than large subunit ribosomal RNA, and the other slightly larger than small subunit ribosomal RNA. The experiments give support to the possibility that 32 S RNA is the precursor of large and small subunit ribosomal RNA's. Both mature ribosomal RNA's compete with 32 S RNA in hybridization to mitochondrial DNA. Quantitative results from such hybridization-competition experiments along with measurements of electrophoretic mobility have been used to construct a molecular size model for synthesis of mitochondrial ribosomal RNA's. The large molecular weight precursor (32 S) of both ribosomal RNA's appears to be 2.4 × 10⁶ daltons in size. Maturation to large subunit RNA (1.28 × 10⁶ daltons) is assumed to involve an intermediate ~1.6 × 10⁶ daltons in size, while cleavage to form small subunit RNA (0.72 × 10⁶ daltons) presumably involves a 0.9 × 10⁶ dalton intermediate. In the maturation process ~22% of the precursor molecule is lost. As is the case for ribosomal RNA's, the mitochondrial precursor RNA has a strikingly low G + C content.     

An electron microscope heteroduplex study of the ribosomal DNAs of Xenopus laevis and Xenopus mulleri

The arrangement of the genes and spacers has been analyzed in ribosomal DNA of Xenopus laevis and Xenopus mulleri by heteroduplex mapping and visualization of ribosomal RNA-DNA hybrids. Heterologous reassoeiated molecules show a characteristic pattern in which two perfectly duplexed regions, whose lengths are those predicted by the known lengths of the 18 S and 28 S genes, are separated by a small substitution loop of about 0.23 × 10⁶ daltons and a large region of partial homology which averages 3.24 × 10⁶ daltons. These mismatched regions are entirely consistent with the known sequence divergence previously described (Brown et al., 1972) for the transcribed and non-transcribed spacer regions of the two rDNAs, respectively. Hybrids of X. laevis rDNA with 18 S and 28 S rRNA contain two duplex regions of the expected lengths for the 18 S and 28 S genes separated by 0.49 × 10⁶ daltons of single-strand DNA. This latter value is the length of the transcribed spacer region between the 18 S and 28 S RNAs that has been measured within the 40 S RNA precursor molecule by secondary structure mapping (Wellauer &; Dawid, personal communication). There is also a longer single-strand region separating one 18 S + 28 S gene set from the next; this is considered to be mainly non-transcribed spacer.We conclude that the 18 S and 28 S genes are separated by about 0.5 × 10⁶ daltons of DNA of which about half is homologous in the two Xenopus species. This region is part of the transcribed spacer. In addition, the longer non-transcribed spacer can be seen to have some homology between the two species; the location of this homology is fairly reproducible between molecules and has been carefully documented by contour length measurements.     

Isolation of ribosomal RNA precursors from Physarum polycephalum

Ribosomal RNA synthesis in Physarum polycephalum was studied by labeling intact microplasmodia with [³H]uridine. Labeled, high-molecular-weight RNA species were found in a 30,000 S structure released by phenol extraction at room temperature. RNA was released from the structure by further phenol extraction at 65–70 °C. If the labeling period was 15 min or longer, the labeled RNA was seen by polyacrylamide gel electrophoresis to be of two major types, a heterodisperse collection of 45-35 S molecules and a 26 S species. If the labeling was carried out for 30 min in the presence of cycloheximide, the major labeled species had an electrophoretic mobility corresponding to 40 S. Studies of the labeling kinetics, methylation, and base composition of these RNA molecules indicate that they are precursors to ribosomal RNA. The molecular weights of the homogeneous 40 and 26 S precursors are 3.0 × 10⁶ and 1.45 × 10⁶ daltons, respectively, in comparison with molecular weights of 1.29 × 10⁶ and 0.68 × 10⁶ daltons for the completed ribosomal RNA's.     

Distinct Transcription Products of Ribosomal Genes in Two Different Tissues

MOST organisms contain multiple copies of the genes which code for ribosomal RNA (rRNA), the number varying from about 160 to 28,000 per nucleus in different eukaryotic species¹; these genes are clustered in the nucleolus. The repeating unit is a DNA sequence containing the structural genes for the 18S and 28S rRNA together with spacer DNA, only a part of which is transcribed². Ribosomal RNA is transcribed from these genes as a polycistronic precursor molecule (pre-rRNA) which contains the rRNA sequences of the larger and smaller ribosomal subunits together with some additional sequences that are discarded during the maturation to rRNA³. The multiple gene copies are identical in the ribosomal regions within the limits detectable by present methods¹, although there is some evidence that regions of non-transcribed spacer DNA vary in length and may therefore not all be identical². We have suggested that the pre-rRNA may also be heterogeneous in molecular weight⁴.