Isolation and characterization of Chinese hamster ribosomal DNA clones

We have examined the ribosomal RNA (rRNA) genes of the Chinese hamster ovary (CHO) cell line. A partial EcoRI library of genomic CHO DNA was prepared using lambda Charon-4A. We isolated two recombinants containing the region transcribed as 45S pre-rRNA and 13 kb of external spacer flanking 5' and 3' to the transcribed region. These sequences show restriction site homology with the vast majority of the genomic sequences complementary to rRNA. In addition to this form of rDNA, Southern blot analysis of EcoRI-cut CHO genomic DNA reveals numerous minor fragments ranging from 2 to 19 kb which are complementary to 18S rRNA. We isolated one clone which contains the 18S rRNA gene and sequences 5' which appear to contain length heterogeneity within the non-transcribed spacer region. We have nine additional cloned EcoRI fragments in which the homology with 18S rRNA is limited to a 0.9-kb EcoRI-HindIII fragment. This EcoRI-HindIII fragment is present in each of the cloned EcoRI fragments, and is flanked on both sides by apparently nonribosomal sequences which bear little restriction site homology with each other or the major cloned rDNA repeat.     

Organization of ribosomal RNA gene repeats of the mouse.

The organization of the ribosomal RNA (rRNA) genes of the mouse was determined by Southern blot hybridization using cloned rDNA fragments as probes, which could encompass the entire spacer region between two rRNA gene regions. The rRNA genes are organized into tandem repeats of nearly uniform length of about 44 kb. The heterogeneity detected in the nontranscribed spacer appears to be caused by its sequence rather than its length difference. At least three kinds of repetitive sequences are present in the non-transcribed spacer region; two of them are located 13 kb upstream from the 5'-end of 18S RNA gene and the other located 1 to 4 kb downstream from the 3'-end of 28S RNA gene.     

Isolation and sequence organization of human ribosomal DNA.

The genes coding for 28 S and 18 S ribosomal RNA have been purified from leukemic leukocytes of one human individual by density gradient centrifugation. The purified ribosomal DNA was analyzed by restriction endonuclease digestion and electron microscopy. The location of cleavage sites for the restriction endonuclease EcoRI was established by R-loop mapping of restriction fragments by electron microscopy. The results are in agreement with gel analysis and gel transfer hybridization. One type of ribosomal DNA repeating unit contains four cleavage sites for EcoRI. Two of these cuts are located in the genes coding for 28 S and 18 S rRNA, while the other two are in the non-transcribed spacer. Thus, one of the restriction fragments generated contains non-transcribed spacer sequences only and is not detected by gel transfer hybridization if labeled rRNA is used as the hybridization probe. A second type of repeating unit lacks one of the EcoRI cleavage sites within the non-transcribed spacer. This indicates that sequence heterogeneity exists in human rDNA spacers. R-loop mapping of high molecular weight rDNA in the electron microscope reveals that the majority of repeats are rather uniform in length. The average size of 22 repeats was 43.65(±1.27) kb. Two repeats were found with lengths of 28.6 and 53.9 kb, respectively. This, and additional evidence from gels, indicates that some length heterogeneity does exist in the non-transcribed spacer. The structure of the human rDNA repeat is summarized in Figure 10.     

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.     

Human ribosomal RNA gene spacer sequences are found interspersed elsewhere in the genome

A cloned EcoRI fragment containing human 18 S rRNA gene sequences was used to screen a gene library to obtain a set of 8 overlapping cloned DNA segments extending into the non-transcribed spacer region of the human ribosomal RNA gene cluster. 19.4 kb of the approx. 43-kb rDNA repeat was obtained in cloned form and mapped with restriction endonucleases. None of the clones obtained extended into 28 S rRNA sequences. A 7-kb region of non-transcribed spacer DNA shared in common between five independent clones was subjected to comparative restriction digests. It was estimated that sequences among the five different spacer isolated varied by not more than 1.0%, if all the observed differences are assumed due to point mutation. HaeII-restriction fragments from within this same 7-kb region contain sequences carried not only within the tandem repeats of the gene cluster but interspersed elsewhere in the genome. Some of these sequences correspond to the Alu family of highly repeated interspersed sequences.     

Characterization of a cloned ribosomal fragment from mouse which contains the 18S coding region and adjacent spacer sequences.

The large EcoRI fragment of mouse ribosomal genes containing parts of the non-transcribed spacer, the external transcribed spacer located at the 5' end of the precursor molecule and about two thirds of the 18S sequence has been cloned in bacteriophage lambda gtWES. A physical map of the DNA was constructed by cleavage with several restriction endonucleases and hybridization of the restriction fragments of the recombinant DNA with labelled 18S and 45S rRNA. The orientation of the inserted fragment as well as the length of the 18S sequence was determined by electron microscopy of R-loop containing molecules. The absence of hybridization of the cloned fragment to other fragments in the genome shows that the non-transcribed spacer does not have a significant length of sequences in common with other sequences in the genome.     

Conformation change of cytochrome c. II. Ferricytochrome c refinement at 1.8 A and comparison with the ferrocytochrome structure

The X chromosomal nucleolus organizer of Drosophila hydei contains about 500 ribosomal RNA genes. The 28 S rRNA coding region of about 50% of these genes is interrupted by an intervening sequence of 6.0 × 10³ base-pairs. Restriction enzyme analysis revealed that more than 90% of the rRNA genes with intervening sequences are present as one or a few clusters within the X chromosomal nucleolus organizer. Furthermore, even though X chromosomal rRNA genes show several distinct size classes of non-transcribed spacers, the cluster of repeating units containing an intervening sequence has major spacer lengths of 4.4 × 10³ and 4.6 × 10³ base-pairs; spacers 5.1 × 10³ base-pairs in length are mainly linked with genes lacking the intervening sequence.     

Molecular analysis of the heterogeneity region of the human ribosomal spacer

The human ribosomal non-transcribed spacers are 30 X 10(3) base-pairs (or 30 kb) in length with a limited length heterogeneity localized in a specific region downstream from the 3' end of the transcribed region. Total DNA digested with EcoRI and BamHI and hybridized with a probe containing the 3' end of the 28 S ribosomal RNA coding region shows four major bands of 3.9 kb, 4.6 kb, 5.4 kb and 6.2 kb. The 5.4 kb band is the most abundant in every individual, followed by the 4.6 kb band. The longest and the shortest size classes are less well-represented and may even be absent. Every individual shows his own pattern of relative abundance of non-transcribed spacer length classes that can be followed through generations. We decided to investigate the molecular structure of the heterogeneity region, in order to cast light onto the mechanisms underlying the origin and maintenance of this length heterogeneity. Pertinent spacer regions of eight ribosomal clones from two human genomic libraries were subcloned and analyzed by restriction mapping and nucleotide sequencing. In the minimal length class, there is a sequence of 700 base-pairs that appears to be tandemly duplicated once, twice or three times in the other length classes. This repeated DNA module contains a region consisting of repetitions of simple pyrimidine groups like C-T, C-T-T-T or C-C-C-T. DNA module repeats may differ by the length of this pyrimidine-rich region. However, these length variations are not continuous, as revealed by Southern transfer analysis of several individuals and different cloned gene units: instead, the repeated modules fall into two discrete length classes of about 700 base-pairs and 800 base-pairs. An imperfect duplication of a short sequence of 86/89 base-pairs is present at the boundary between the heterogeneity region and the upstream flanking region, representing a very ancient duplication event.     

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.     

A new copia-like transposable element found in a Drosophila rDNA gene unit.

We have discovered a member of a new family of copia-like transposable elements inserted into the non-transcribed spacer between two ribosomal genes (rDNA). This family, which we call 3S18, consists of at least 15 elements which are scattered throughout the Drosophila melanogaster genome. The elements of this family are approximately 6.5 kb long and have 0.5 kb terminal direct repeats. All of the elements appear to have the same restriction sites. The element is mobile as the size pattern of homologous fragments varies among different strains. In situ hybridization results confirm the scattered location and transposable qualities of 3S18. The element is not transcribed into abundant RNA.     

tRNA genes are found between 16S and 23S rRNA genes in Bacillus subtilis.

There are at least nine, and probably ten, ribosomal RNA gene sets in the genome of Bacillus subtilis. Each gene set contains sequences complementary to 16S, 23S and 5S rRNAs. We have determined the nucleotide sequences of two DNA fragments which each contain 165 base pairs of the 16S rRNA gene, 191 base pairs of the 23S rRNA gene, and the spacer region between them. The smaller space region is 164 base pairs in length and the larger one includes an additional 180 base pairs. The extra nucleotides could be transcribed in tRNAIIe and tRNA Ala sequences. Evidence is also presented for the existence of a second spacer region which also contains tRNAIIe and tRNA Ala sequences. No other tRNAs appear to be encoded in the spacer regions between the 16S and 23S rRNA genes. Whereas the nucleotide sequences corresponding to the 16S rRNA, 23S rRNA and the spacer tRNAs are very similar to those of E. coli, the sequences between these structural genes are very different.     

Methidiumpropyl-EDTA-iron(II) cleavage of ribosomal DNA chromatin from Dictyostelium discoideum.

We have used methidiumpropyl-EDTA-iron(II) [MPE.Fe(II)] in parallel with micrococcal nuclease to investigate the chromatin structure of the extrachromosomal palindrome ribosomal RNA genes of Dictyostelium. Confirming our earlier results with micrococcal nuclease (1,2), MPE.Fe(II) digested the coding region of rapidly transcribing rRNA genes as a smear, indicating the absence or severe disruption of nucleosomes, whereas in slowly transcribing rRNA genes, a nucleosomal ladder was produced. In the central non-transcribed spacer region of the palindrome, MPE.Fe(II) digestion resulted in a normal nucleosomal repeat, whereas micrococcal nuclease gave a complex banding pattern. The difference is attributed to the lower sequence specificity of MPE.Fe(II) compared to micrococcal nuclease. In the terminal region of the palindrome, however, both substances gave a complex chromatin digestion pattern. In this region the DNA appears to be packaged in structures strongly positioned with respect to the underlying DNA sequence.     

The structure of a single unit of ribosomal RNA gene (rDNA) including intergenic subrepeats in the Australian bulldog ant Myrmecia croslandi (Hymenoptera: Formicidae)

A complete single unit of a ribosomal RNA gene (rDNA) of M. croslandi was sequenced. The ends of the 18S, 5.8S and 28S rRNA genes were determined by using the sequences of D. melanogaster rDNAs as references. Each of the tandemly repeated rDNA units consists of coding and non-coding regions whose arrangement is the same as that of D. melanogaster rDNA. The intergenic spacer (IGS) contains, as in other species, a region with subrepeats, of which the sequences are different from those previously reported in other insect species. The length of IGSs was estimated to be 7-12 kb by genomic Southern hybridization, showing that an rDNA repeating unit of M. croslandi is 14-19 kb-long. The sequences of the coding regions are highly conserved, whereas IGS and ITS (internal transcribed spacer) sequences are not. We obtained clones with insertions of various sizes of R2 elements, the target sequence of which was found in the 28S rRNA coding region. A short segment in the IGS that follows the 3' end of the 28S rRNA gene was predicted to form a secondary structure with long stems.