Location of the genes for 5S ribosomal RNA in Xenopus laevis

In situ hybridization of 5S RNA and cRNA transcribed in vitro from Xenopus laevis 5S DNA shows that 5S DNA is localized at or near the telomere region of the long arm of many, if not all, of the X. laevis chromosomes. No 5S DNA is detected near the nucleolus organizer in the normal X. laevis chromosome complement, but in a X. laevis kidney cell line, 5S DNA is found at the distal end of the secondary constriction. The arrangement of 5S DNA in several types of interphase nuclei is described. — During the pairing stages of meiosis the telomeres of most or perhaps all of the chromosomes become closely associated so that the regions containing 5S DNA form a single cluster. This close association might be either a cause or a result of the presence of the similar sequences of 5S DNA on many telomeres. It suggests that the uniformity of 5S sequences on non-homologous chromosomes might be maintained by crossing-over between the chromosomes.     

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.     

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.     

Reiterated transfer RNA genes of Xenopus laevis

The proportion of the Xenopus laevis genome complementary to “7 S” RNA, unfractionated transfer RNA and some selected aminoacyl-tRNAs, and the sequence complexity of these RNA species, have been determined by following the kinetics of RNA-DNA hybridization on filters under conditions of RNA excess at optimum rate temperature. For hybridization of aminoacyl-labelled tRNAs, conditions for optimum aminoacylation were first determined and, where necessary, aminoacyl-tRNAs were treated with nitrous acid to prevent discharge during annealing. Neither the extent nor rate of hybridization was affected by this treatment.“7 S” RNA, coded for by 580 genes per haploid complement of chromosomes, reacts like a single family of nucleotide sequences, whereas about 43 basic tRNA sequences are coded for by at least 7800 genes. If hybrids are not treated with RNase A, the apparent tDNA redundancy is some 23% greater but no more nucleotide sequences are detectable. Taken together, the results suggest that each tRNA sequence is, on average, 200-fold reiterated.The reiteration varies, however, for different aminoacyl-tRNAs. Thus, hybridization resolves only one valyl-tRNA which is coded for by 240 genes, but at least four leucyl-tRNA sequences can be distinguished by hybridization, each of which is on average 90-fold reiterated. Reiteration also varies for the two methionyl-tRNAs detectable both by hybridization and by reversed phase chromatography: tRNA₁^Met and tRNA₂^Met are 310- and 170-fold reiterated, respectively, and each is kinetically homogeneous. These saturation values are almost exactly additive and are not influenced by the presence of other tRNA species. Thus the results suggest that Xenopus tRNAs are no more heterogeneous than would be predicted by the genetic code, despite the high but variable multiplicity of tRNA cistrons.     

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.     

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.     

High resolution mapping of Xenopus laevis 5S and ribosomal RNA genes by EM in situ hybridization

We have developed a modification of in situ hybridization at the electron microscope level that permits simultaneous detection of at least two sequences. Probes are labelled with either biotin or AAF and detected with two distinct sizes of colloidal gold. This protocol has been applied to map the positions of Xenopus laevis oocyte-type 5S genes relative to ribosomal precursor genes in several independently derived cell lines. The results for the line TRXO, which expresses some oocyte 5S RNA, indicate that this inappropriate expression is not due to translocation from telomeric sites into the nucleolus organizer, as previously hypothesized. In addition we found that four other Xenopus cell lines, none of which express these genes, also contain distinct 5S oocyte translocations. These results suggest that an alteration in chromosome position is insufficient to result in gene activation and that sequences which are telomeric-proximal are exceptionally prone to translocation.     

Mapping of mitochondrial 4 S RNA genes in Xenopus laevis by electron microscopy

The distribution of sites hybridizing with mitochondrial 4 S RNA molecules on mitochondrial DNA of Xenopus laevis has been mapped in relation to the ribosomal RNA genes and EcoRI restriction endonuclease sites. RNA molecules linked to ferritin were employed for this purpose. We have obtained evidence for 15 4 S RNA sites on the H-strand and six sites on the L-strand of X. laevis mtDNA^∥. An indication of the possible existence of one additional site on the H-strand and four additional sites on the L-strand has been obtained. One 4 S RNA site is located in the gap between the two rRNA genes, and one site flanks each outside end of the rRNA genes. The other 4 S RNA sites are distributed almost evenly throughout both strands of the mtDNA. A comparison with the map of 4 S RNA sites on the mtDNA of HeLa cells (Angerer et al., 1976) suggests considerable evolutionary conservation of site organization.