A pseudogene structure in 5S DNA of Xenopus laevis

The 5S DNA of Xenopus laevis, coding for oocyte-type 5S RNA, consists of many copies of a tandemly repeated unit of about 700 base pairs. Each unit contains a "pseudogene" in addition to the gene. The pseudogene has been partly sequenced and appears to be an almost perfect repeat of 101 residues of the gene. The order of components in the repeat unit is (5') long spacer--gene--linker--pseudogene (3') in the "+" strand (or H strand) of the DNA. The possible function of the pseudogene is discussed.     

The nucleotide sequence of oocyte 5S DNA in xenopus laevis. I. The AT-rich spacer

The primary sequence of the principal spacer region in X. laevis oocyte 5S DNA has been determined. The spacer is AT-rich and comprises half or more of each repeating unit. The sequence is internally repetitious; most of it can be represented by the following set of oligonucleotides:

$\text{CAA}{}^{\mathrm{C}}{}_{\mathrm{A}}\text{GTTTTCAA}{}^{\mathrm{AA}}{}_{\mathrm{GG}}\text{TTTG}{}^{\mathrm{C}}{}_{\mathrm{A}}\text{A}{}^{\mathrm{G}}{}_{\mathrm{T}}\text{TTTT(T)}$

The spacer, which varies in length from about 360 to 570 or more nucleotides, can be subdivided into a region (A₂) which is variable in length in different repeating units, flanked by regions (A₁, A₃, B₁) which are relatively constant in length. The A₂ region consists, on the average, of 5–6 tandem copies of the oligonucleotide CAAAGTTT-GAGTTTT; variation in the redundancy of this oligonucleotide accounts for much of the repeat length variation in the genomic 5S DNA. Most copies of this oligonucleotide are identical, although several differing by 1 or 2 nucleotides have been detected in plasmid-cloned 5S DNA fragments. Regions A₁ and A₃ comprise a linear array of similar, but not identical, oligonucleotides; most repeating units contain very similar A₁ and A₃ sequences. Region B₁ is a sequence of 49 nucleotides immediately adjacent to the 5′ terminus of the 5S rRNA sequence. It is GC-rich, much less repetitive than the remainder of the spacer and contains several palindromes, but no regions of dyad symmetry. This sequence is identical in all six of the single cloned repeating units of 5S DNA analyzed.     

Repeating units of xenopus laevis oocyte-type 5S DNA are heterogeneous in length

The restriction enzymes Hind III and Hae III cleave Xenopus laevis 5S DNA at one and three sites, respectively, in each repeating unit of approximately 700 base pairs. The cleavage sites for both enzymes have been located within the repeating unit by denaturation mapping of the restriction fragments. The Hind III products and one of the Hae III fragments are variable in length, indicating heterogeneity in the length of the repeating unit in 5S DNA. This length heterogeneity is confined to the major A + T-rich spacer region. Repeating units differ from each other by discrete quanta of approximately 15 base pairs. The A + T-rich spacer has been shown to consist largely of tandem subrepeats of just this size (Brownlee, Cartwright, and Brown, 1974). We suggest that the repeat-length heterogeneity is due to variable numbers of these subrepeats in the spacer regions of the major repeating units.     

Adjacent repeating units of xenopus laevis 5S DNA can be heterogeneous in length

The distribution of length heterogeneity in adjacent repeating units of X. laevis 5S DNA has been examined by “cloning” 5S DNA in bacteria. Fragments of 5S DNA produced by partial digestion with Hind III and containing 1, 4, and 5 repeating units have been inserted at the single Hind III site of the tetracycline-resistance plasmid, pSC101, and the hybrid plasmids cloned in E. coli. Adjacent 5S DNA repeats in the cloned multi-repeat fragments can differ in length. This finding rules out some mechanisms which have been proposed to account for the parallel evolution of tandem repeated DNAs. The results are consistent with an unequal crossing-over mechanism and place some constraints on the molecular processes in this recombinatory event.     

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.     

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.     

Characterization of two xenopus somatic 5S DNAs and one minor oocyte-specific 5S DNA

The somatic 5S DNA from X. borealis (Xbs 5S DNA) and X. laevis (Xis 5S DNA) and a minor oocyte-specific 5S DNA from X. laevis (Xit 5S DNA) have been purified, and individual repeating units have been cloned and sequenced. The two somatic 5S DNAs differ from the major oocyte 5S DNAs in having GC-rich spacers, homogeneous repeat lengths and no "pseudogenes." The somatic 5S DNAs from the two species have similar spacer sequences with differences due to single base changes and insertions/deletions. The spacer of the minor oocyte-specific 5S DNA (Xit) has the AT-rich sequence characteristic of the major oocyte 5S DNAs from X. laevis and X. borealis, and contains one duplication that has diverged approximately 40%. Like the somatic 5S DNAs, Xit 5S DNA has a homogeneous length repeat and a unique nucleotide sequence in its spacer. The presence of variable-length spacer regions in a multigene family correlates with variables numbers of a simple sequence in the spacer regions.     

A DNA binding protein from Xenopus laevis oocyte mitochondria

A DNA binding protein has been isolated, by affinity chromatography on DNA cellulose, from mitochondria and from purified mitDNA-protein complexes from oocytes of Xenopus laevis. This 12,500 daltons protein is polymeric in its native form and binds to DNA with a high efficiency. It exhibits an apparently preferential binding to the single-stranded fiber of the D loop structures.     

The cyclization of Xenopus laevis 5 S DNA

DNA from Xenopus laevis containing the sequences complementary to 5 S RNA has been studied by the formation of folded rings. Maximal cyclization for fragments 1 to 2 μm in length is 45 to 55%. Thus the efficiency of folded ring formation from this tandemly-repeating DNA is about 50%, assuming that all fragments are 5 S DNA. From the ring frequency as a function of the number of nucleotides removed from the 3′ terminals of the shear-broken fragments, one may calculate that the repeating sequence is approximately 750 nucleotides long, a number that agrees with earlier partial denaturation mapping. The circumference of the folded rings confirms this repeating length since most rings correspond to modular size classes of 0.25-μm increments. Fragments 12 μm long cyclize almost as readily as 1 to 2-μm fragments do. Therefore, the length of the regions (g-regions) containing the tandemly-repeating 5 S DNA is more than 12 μm. The folded rings are about as stable to linearization by increasing concentrations of formamide as the duplex DNA is to denaturation. This indicates that the local, non-transcribed, spacer portions which represent the majority (83%) of the nucleotides in the tandemly-repeating unit, are probably homogeneous in sequence. The exonuclease-treated 5 S DNA fragments cyclize more rapidly than phage T7 DNA, and the kinetics are in accord with theoretical expectation.     

Genetic recombination of Xenopus laevis 5 S DNA in bacteria

The behavior in genetic recombination of Xenopus laevis 5 S DNA has been examined, with particular emphasis on the role of 15-base-pair tandem repeats in the A + T-rich spacer. Fragments of 5 S DNA were introduced into Escherichia coli cells as inserts in the recombination vectors, lambda rva and lambda rvb. Intermolecular recombinants were selected in which, because of properties of the phage vectors, the crossover event must have occurred within the 5 S DNA inserts. Inserts from individual recombinants have been characterized in detail. The effects of varying the number (n) of 15-base-pair repeats and the recombination capabilities of the phage and host have been investigated. In these crosses, unequal crossovers can occur, yielding inserts different in size from the parental inserts. When the number of 15-mers is large (n = 12 or 20), most of the unequal crossovers have occurred within the 15-mers, resulting in an altered n value, although other homologies within the 5 S DNA sequence can also support unequal events. Increasing n in the parental inserts modestly increases the overall frequency of recombination and the percentage of altered inserts. We conclude that, in a bacterial setting, the 15-base-pair repeats stimulate recombination only slightly by allowing alternative registers for heteroduplex formation. The degree of stimulation observed is less than predicted by one simple model.     

DNA methylation patterns in the 5S DNAs of Xenopus laevis

The frequency of cytosine methylation at specific sites in the somatic 5S DNA (X1s) and trace oocyte 5S DNA (X1t) of X. laevis has been determined using restriction enzymes that are inhibited by the presence of 5-methylcytosine (5mC) within their cleavage sequences. 5S DNA methylation patterns were determined in genomic DNA from mature red blood cells, which express neither type of 5S gene, and from liver, which expresses only X1s. All the sites examined in X1t are greater than 95% methylated in red cells and liver. In the X1s of red cells all the sites examined are methylated in greater than 95% of repeats, while in liver some sites are modified in only 90% of repeats. Repeats containing unmethylated sites are randomly distributed throughout the tandem arrays in both red cells and liver. The high levels of methylation for X1s are in marked contrast to the situation with other Xenopus genes which do have sites of significant undermethylation in tissues where they are active. Thus, undermethylation in active genetic regions may not be a general feature for all classes of eukaryotic genes.