Regular arrangement of nucleosomes on 5S rRNA genes in Xenopus laevis.

The chromatin structure of the oocyte-type 5S RNA genes in Xenopus laevis was investigated. Blot hybridization analysis of DNA from micrococcal nuclease digests of erythrocyte nuclei showed that 5S DNA has the same average nucleosome repeat length, 192 +/- 4 base pairs, as two Xenopus satellite DNAs and bulk erythrocyte chromatin. The positions of nuclease-sensitive regions in the 5S DNA repeats of purified DNA and chromatin from erythrocytes were mapped by using an indirect end-labeling technique. Although most of the sites cleaved in purified DNA were also cleaved in chromatin, the patterns of intensities were strikingly different in the two cases. In 5S chromatin, three nuclease-sensitive regions were spaced approximately a nucleosome length apart, suggesting a single, regular arrangement of nucleosomes on most of the 5S DNA repeats. The observed nucleosome locations are discussed with respect to nucleotide sequences known to be important for expression of 5S RNA. Because the preferred locations appear to be reestablished in each repeating unit, despite spacer length heterogeneity, we suggest that the regular chromatin structure reflects the presence of a sequence-specific DNA-binding component on inactive 5S RNA genes.     

The genomic organization of dispersed tRNA and 5 S RNA genes in Xenopus laevis

The 5 S DNAs and several tDNAs of Xenopus laevis reside primarily in large clusters of tandem repeating units. We have discovered that a substantial number of these genes, along with portions of their adjacent spacer sequences, are also located in dispersed genomic locations apart from the major clusters. This was accomplished by "null-digesting" total genomic DNA with restriction enzymes that do not cut within the X. laevis tDNA or 5 S DNA major repeats. The tDNA and 5 S DNA main clusters therefore remain intact and can be easily separated on gels from the dispersed tDNAs and 5 S DNAs present as low molecular weight restriction fragments. Probing these smaller fragments with different portions of the major repeats has revealed that many of the dispersed genes are organized differently from the corresponding tDNAs and 5 S DNAs of the primary clusters. Some of the fragments containing dispersed genes are actually present in multiple copies. In addition, many tDNA null-digestion fragments contain more than one type of tRNA coding region. One set of "dispersed" tDNAs actually comprises a tandemly arranged minor tDNA family which has retained the same repeat length (3.18 kb) as the major tDNA family, but has a substantially different organization. There is significant population polymorphism in the organization of the dispersed tDNAs and 5 S DNAs. Dispersed genes that appear to be derived from clusters of tandem repeats ("orphons") have been described for several gene families in invertebrates. The occurrence of this phenomenon in vertebrates as well, suggests that such dispersed genes may be a general feature of all eukaryotic genomes.     

Chromosomal footprinting of transcriptionally active and inactive oocyte-type 5S RNA genes of Xenopus laevis

The chromatin structure of the Xenopus oocyte-specific 5S rRNA genes was examined at high resolution in immature oocyte and somatic cell chromosomes by DNase I footprinting. On oocyte chromatin, where the genes are active, the cleavage preferences over the entire gene region showed a periodic pattern of sensitivity and were dramatically different from the patterns obtained with deproteinized DNA or somatic cell chromatin. Further, the normal binding site for TFIIIA over the internal promoter region was preferentially sensitive to cleavage, indicating that TFIIIA was not bound in the manner predicted by in vitro experiments. In somatic cell chromatin, the oocyte-type 5S genes displayed a cleavage pattern largely similar to deproteinized DNA suggesting the absence of positioned nucleosomes on these inactive genes, although the presence of uncharacterized repressor complexes could not be ruled out. These data are discussed in terms of potential forms of the chromatin structure and alternative mechanisms of oocyte-type gene activation.     

Organization of 5S genes in chromatin of Xenopus laevis.

The chromatin organization of the genes coding for 5S RNA in Xenopus laevis has been investigated with restriction endonucleases and micrococcal nuclease. Digestion of nuclei from liver, kidney, blood and kidney cells maintained in culture with micrococcal nuclease reveals that these Xenopus cells and tissues have shorter nucleosome repeat lengths than the corresponding cells and tissues from other higher organisms. 5S genes are organized in nucleosomes with repeat lengths similar to those of the bulk chromatin in liver (178 bp) and cultured cells (165 bp); however, 5S gene chromatin in blood cells has a shorter nucleosome repeat (176 bp) than the bulk of the genome in these cells (184 bp). From an analysis of the 5S DNA fragments produced by extensive restriction endonuclease cleavage of chromatin in situ, no special arrangement of the nucleosomes with respect to the sequence of 5S DNA can be detected. The relative abundance of 5S gene multimers follows a Kuhn distribution, with about 57% of all HindIII sites cleaved. This suggests that HindIII sites can be cleaved both in the nucleosome core and linker regions.     

Computer modeling from solution data of spinach chloroplast and of Xenopus laevis somatic and oocyte 5 S rRNAs

Detailed atomic models of a eubacterial 5 S rRNA (spinach chloroplast 5 S rRNA) and of a eukaryotic 5 S rRNA (somatic and oocyte 5 S rRNA from Xenopus laevis) were built using computer graphic. Both models integrate stereochemical constraints and experimental data on the accessibility of bases and phosphates towards several structure-specific probes. The base sequence was first inserted on to three-dimensional structural fragments picked up in a specially devised databank. The fragments were modified and assembled interactively on an Evans & Sutherland PS330. Modeling was finalized by stereochemical and energy refinement. In spite of some uncertainty in the relative spatial orientation of the substructures, the broad features of the models can be generalized and several conclusions can be reached: (1) both models adopt a distorted Y-shape structure, with helices B and D not far from colinearity; (2) no tertiary interactions exist between loop c and region d or loop e; (3) the internal loops, in particular region d, contain several non-canonical base-pairs of A.A, U.U and A.G types; (4) invariant residues appear to be more important for protein or RNA binding than for maintaining the tertiary structure. The models are corroborated by footprinting experiments with ribosomal proteins and by the analysis of various mutants. Such models help to clarify the structure-function relationship of 5 S rRNA and are useful for designing site-directed mutagenesis experiments.     

The distribution of oocyte 5S,somatic 5S and 18S + 28S rDNA sequences in the lampbrush chromosomes of Xenopus laevis

The nucleolus organizer locus of Xenopus laevis lampbrush chromosomes was identified by in situ hybridization of a ³H-labelled probe complementary to 18S + 28S rDNA. The nucleolus organizer is an axial granule on chromosome III that lies four-fifths the way down this chromosome reading from its larger (left) telomere, just within an exploded region that extends to its right end, where the lateral loops are exceptionally long. By in situ hybridization of ³H-labelled oocyte and somatic 5S spacer cRNA probes to similarly RNase-treated and denatured lampbrush chromosomes, the multiple sites of oocyte and somatic 5S gene families were identified. Oocyte 5S genes lie at the larger telomeres of the 15 chromosomes that possess these structures; that is, all but chromosomes X, XVII and XVIII. There are a further four sites, all peripheral, and in three of these, on chromosomes VII, X and XI, the sequences lie on lateral loops that are resolvable with the light microscope. By contrast all of the somatic 5S gene clusters occupy peripheral sites. There are two sites on chromosome III, one of which may be shared with oocyte 5S sequences; one on chromosome VII, which is very likely shared with oocyte 5S sequences; one terminal site on chromosome X; one site on chromosome XI that lies on a single pair of long loops which are inserted in a conspicuous and recognizable axial granule, loops which certainly carry oocyte 5S sequences too; two nearly terminal sites alongside the larger telomeres on chromosomes XII and XIV; and single interstitial sites on all three of the sphere-bearing chromosomes, VIII, IX and XVI. We suggest that 5S sequences on resolvable loops are transcribed by readthrough from upstream promoters, probably by polymerase II.     

A comparison of the solution structures and conformational properties of the somatic and oocyte 5S rRNAs of Xenopus laevis

The secondary and tertiary structures of Xenopus oocyte and somatic 5S rRNAs were investigated using chemical and enzymatic probes. The accessibility of both RNAs towards single-strand specific nucleases (T1, T2, A and S1) and a helix-specific ribonuclease from cobra venom (RNase V1) was determined. The reactivity of nucleobase N7, N3 and N1 positions towards chemical probes was investigated under native (5 mM MgCl2, 100 mM KCl, 20 degrees C) and semi-denaturing (1 mM EDTA, 20 degrees C) conditions. Ethylnitrosourea was used to identify phosphates not reactive towards alkylation under native conditions. The results obtained confirm the presence of the five helical stems predicted by the consensus secondary structure model of 5S rRNA. The chemical reactivity data indicate that loops C and D are involved in a number of tertiary interactions, and loop E folds into an unusual secondary structure. A comparison of the data obtained for the two types of Xenopus 5S rRNA indicates that the conformations of the oocyte and somatic 5S rRNAs are very similar. However, the data obtained with nucleases under native conditions, and chemical probes under semi-denaturing conditions, reveal that helices III and IV in the somatic 5S rRNA are less stable than the same structures in oocyte 5S rRNA. Using chimeric 5S rRNAs, it was possible to demonstrate that the relative resistance of oocyte 5S rRNA to partial denaturation in 4 M urea is conferred by the five oocyte-specific nucleotide substitutions in loop B/helix III. In contrast, the superior stability of oocyte 5S rRNA in the presence of EDTA is related to a single C substitution at position 79.     

Nucleotide sequence encoding the 5'' end of Xenopus laevis 18S rRNA.

We have sequenced a region of cloned Xenopus laevis ribosomal DNA encompassing the last 24 nucleotides of the external transcribed spacer and the first 275 nucleotides of the 18S gene. The start of the 18S gene was identified by correlating the results obtained from RNA hybridization and fingerprinting with the DNA sequence. This 5' region of 18S rRNA contains five 2'-O-methyl groups and at least six pseudouridine residues. Several of these modified nucleotides are clustered into a relatively short region from nucleotides 99-124. Nucleotides 227-250 constitute a distinctive sequence of 24 consecutive G and C residues. Comparison with the first 160 nucleotides of a yeast 18S gene (25) reveals three blocks of high sequence homology separated by two short tracts where homology is low or absent. The external transcribed spacer sequences diverge widely from within a few nucleotides of the start of the 18S gene.     

Chromosomal mapping of Xenopus 5S genes: somatic-type versus oocyte-type.

Xenopus 5S RNA genes exhibit a pattern of differential expression during development in which some members (oocyte-type) are transcribed only in oocytes, while others (somatic-type) are expressed in both oocytes and somatic cells. Using cloned DNA probes specific for each gene type, we determined the positions of these genes on Xenopus metaphase chromosomes by in situ hybridization. Somatic-type 5S genes in both X. laevis and X. borealis are located at the distal end of the long arm of only one chromosome (number 9). The oocyte-type 5S RNA genes are found at the distal ends of the long arms of most Xenopus chromosomes, including chromosome 9. Thus, large scale differences in chromosomal location cannot explain the selective expression of these genes, as suggested previously.     

Oocyte and somatic 5S ribosomal RNA and 5S RNA encoding genes in Xenopus tropicalis.

We have investigated the structure of oocyte and somatic 5S ribosomal RNA and of 5S RNA encoding genes in Xenopus tropicalis. The sequences of the two 5S RNA families differ in four positions, but only one of these substitutions, a C to U transition in position 79 within the internal control region of the corresponding 5S RNA encoding genes, is a distinguishing characteristic of all Xenopus somatic and oocyte 5S RNAs characterized to date, including those from Xenopus laevis and Xenopus borealis. 5S RNA genes in Xenopus tropicalis are organized in clusters of multiple repeats of a 264 base pair unit; the structural and functional organization of the Xenopus tropicalis oocyte 5S gene is similar to the somatic but distinct from the oocyte 5S DNA in Xenopus laevis and Xenopus borealis. A comparative sequence analysis reveals the presence of a strictly conserved pentamer motif AAAGT in the 5'-flanking region of Xenopus 5S genes which we demonstrate in a separate communication to serve as a binding signal for an upstream stimulatory factor.     

The nucleotide sequence of oocyte 5S DNA in Xenopus laevis. II. The GC-rich region

The primary sequence of the GC-rich half of the repeating unit in X. laevis 5S DNA has been determined in both a single plasmid-cloned repeating unit and in the total population of repeatig units. The GC-rich half of the repeating unit contains a single long duplication of 174 nucleotides. The duplicated segment commences 73 nucleotides preceding the 5' end of the gene and terminates at nucleotide 101 of the gene. The duplicated portion of the gene, termed the pseudogene, differs by 10 nucleotides from the corresponding portion of the gene, and the remaining duplicated sequence of 73 nucleotides differs by 13 nucleotides. The plasmid-cloned repeating unit differs from the dominant sequence in the total population repeating units by 6 nucleotides in the GC-rich region. Evidence is provided that most of the CpG dinucleotides in 5S DNA are at least partially methylated.