Locations of 18S and 28S ribosomal genes on the chromosomes of the Indian muntjac

The locations of genes coding for 18S and 28S ribosomal RNA have been mapped on metaphase chromosomes of the Indian muntjac M. muntjak by in situ hybridization with (3H)rRNA from the toad X. laevis. The results show that, in the muntjac, rDNA clusters are associated with the prominent secondary constrictions on the X and the Y1 chromos. In addition a cluster of rDNA is found near the tip of one arm on the longest pair of autosomes. The autosomal cluster of rDNAs usually does not express as a secondary constriction at metaphase.     

Transcriptional organization of the 5.8S ribosomal RNA cistron in Xenopus laevis ribosomal DNA.

Hybridization of purified, 32p-labeled 5.8S ribosomal RNA from Xenopus laevis to fragments generated from X. laevis rDNA by the restriction endonuclease, EcoRI, demonstrates that the 5.8S rRNA cistron lies within the transcribed region that links the 18S and 28S rRNA cistrons.     

Distribution of sequences common to the 25--28S-ribonucleic acid genes of Xenopus laevis and Neurospora crassa.

The extent of homology between the nucleotide sequence of L-rRNA (the major RNA component of the larger ribosomal subparticle) of a lower eukaryote (Neurospora crassa) and an amphibian (Xenopus laevis) was investigated by utilizing rDNA (DNA coding for rRNA) of X. laevis cloned in plasmids pMB9 and pML2, and rDNA of N. crassa cloned in bacteriophage lambda. Hybridization studies revealed that sequences common to both N. crassa and X. laevis L-rRNA comprise a total of approx. 1050 /+- 200 nucleotides. The thermal stability of the X. laevis rDNA.N. crassa L-rRNA hybrid was 5 degrees C lower than that of the X. laevis rDNA.X. laevis L-rRNA duplex, indicating the presence of fewer than 10% mismatches in homologous sequences. X. laevis rDNA was analysed by means of restriction endonucleases and hybridization with 125I-labelled N. crassa L-rRNA. Most (at least 95%) of the conserved sequences were present in a 3000-base-pair fragment produced by restriction with endonucleases HindIII and BamHI. This fragment, which includes the 3'-OH terminus of the L-rRNA-coding region, was used as an adaptor in the construction of a bacteriophage-lambda recombinant. One section of the recombinant phage terminating in a HindIII-specific site was obtained from bacteriophage lambda plac5 (after restriction with endonuclease HindIII). A second section terminating in a BamHi-specific site was obtained from bacteriophage lambda 540 (after restriction with endonuclease BamHI). These two parts were joined by means of the X. laevis rDNA fragment. Further analysis of cloned rDNA by means of restriction endonucleases confirmed that conserved sequences were widely distributed throughout the 3000-base-pair fragment produced by HindIII and BamHi endonucleases. A 3400-base-pair fragment of N. crassa rDNA cloned in a bacteriophage lambda [Cox & Peden (1979) Mol. Gen. Genet. 174, 17--24] was restricted with endonucleases. The products were hybridized with 125I-labelled X. laevis L-rRNA. Conserved sequences were shown to be distributed over a range of approx. 1600--2700 base-pairs. Hence, in neither X. laevis nor N. crassa L-rRNA can be conserved sequences from a single block; instead regions of high and low (or no) homology must be intermingled. Both N. crassa rDNA and X. laevis rDNA were found to hybridize with Drosophila melanogaster L-rDNA sequences. Those rDNA fragments with sequences common to X. laevis and N. crassa L-rRNA also hybridized with D. melanogaster L-rRNA probe. Thus the same set of conserved sequences may be present in all three species.     

Identification of the locations of the methyl groups in 18 S ribosomal RNA from Xenopus laevis and man

The 18 S ribosomal RNA from a variety of vertebrate species contains some 40 to 47 methyl groups. The majority of these are 2'-O-ribose substituents; the remaining few are on bases. Several lines of evidence have permitted the identification of the precise locations of the methyl groups in the primary structure of 18 S ribosomal RNA of Xenopus laevis and man. Digestion of RNA with T1 ribonuclease, followed by analysis of the methylated oligonucleotides yielded data on sequences immediately surrounding the methyl groups. Preparative hybridization of X. laevis 18 S ribosomal RNA restriction fragments of ribosomal DNA, followed by fingerprinting analysis on RNA recovered from the hybrids, allowed each methylated oligonucleotide to be mapped to a specific region within 18 S ribosomal RNA. The data on RNA oligonucleotides were correlated with Xenopus ribosomal DNA sequence data in the regions defined by the mapping experiments to identify the precise locations of most of the methyl groups in the X. laevis 18 S RNA sequence. The remaining uncertainties in Xenopus were solved with the aid of data from ribonuclease A fingerprints and, in a few instances, relevant oligonucleotide or sequence data from other laboratories. The locations of most of the methyl groups in human 18 S ribosomal RNA were deduced from the high degree of correspondence between methylated oligonucleotides from human and X. laevis 18 S RNA, together with knowledge of the human 18 S ribosomal DNA sequence. The remaining methylation sites in human 18 S RNA were located with assistance from relevant published comparative data. In the aligned sequences, human and other mammalian 18 S RNA are methylated at all the same positions as in X. laevis, and there are seven additional 2'-O-methylation sites in mammalian 18 S RNA. Further features of the methyl group distribution are briefly reviewed.     

Cloning and characterization of ribosomal RNA genes from wheat and barley.

Wheat and barley DNA enriched for ribosomal RNA genes was isolated from actinomycin D-CsCl gradients and used to clone the ribosomal repeating units in the plasmid pAC184. All five chimeric plasmids isolated which contained wheat rDNA and eleven of the thirteen which had barley rDNA were stable and included full length ribosomal repeating units. Physical maps of all length variants cloned have been constructed using the restriction endonucleases Eco Rl, Bam Hl, Bgl II, Hind III and Sal I. Length variation in the repeat units was attributed to differences in the spacer regions. Comparison of Hae III and Hpa II digestion of cereal rDNAs and the cloned repeats suggests that most methylated cytosines in natural rDNA are in -CpG-. Incomplete methylation occurs at specific Bam Hl sites in barley DNA. Detectable quantities of ribosomal spacer sequences are not present at any genomic locations other than those of the ribosomal RNA gene repeats.     

DNaseI-hypersensitive sites at promoter-like sequences in the spacer of Xenopus laevis and Xenopus borealis ribosomal DNA.

We have detected a DNAseI hypersensitive site in the ribosomal DNA spacer of Xenopus laevis and Xenopus borealis. The site is present in blood and embryonic nuclei of each species. In interspecies hybrids, however, the site is absent in unexpressed borealis rDNA, but is present normally in expressed laevis rDNA. Hypersensitive sites are located well upstream (over lkb) of the pre-ribosomal RNA promoter. Sequencing of the hypersensitive region in borealis rDNA, however, shows extensive homology with the promoter sequence, and with the hypersensitive region in X. laevis. Of two promoter-like duplications in each spacer, only the most upstream copy is associated with hypersensitivity to DNAaseI. Unlike DNAaseI, Endo R. MspI digests the rDNA of laevis blood nuclei at a domain extending downstream from the hypersensitive site to near the 40S promoter. Since the organisation of conserved sequence elements within this "proximal domain" is similar in three Xenopus species whose spacers have otherwise evolved rapidly, we conclude that this domain plays an important role in rDNA function.