Sequence organization of the spacer DNA in a ribosomal gene unit of Xenopus laevis

5-Methylcytosine in eukaryotic DNA

A small portion of the cytosine residues in the DNA of higher eukaryotes as well as in that of many lowe eukaryotes if methylated. The resulting 5-methylcytosine residues occur in specific in the DNA, usually adjacent to guanine residues on the 3' side. This methylation of eukaryotic DNA has been proposed to function in many ways, including control of transcription, maintenance of chromosome structure, repair of DNA, establishment of preferred sites for mutation, oncogenic transformation, and, in certain systems, protection of DNA against enzymatic degradation.

Histone gene clusters of the newt notophthalmus are separated by long tracts of satellite DNA

The genomic organization of the histone genes of the newt Notophthalmus viridescens is described. Genes for the five proteins are clustered on a 9.0 kb segment of cloned DNA which is part of a homogeneous family of sequences containing 600--800 members per haploid genome. The 9.0 kb histone gene clusters are not adjacent in the genome, but are separated from neighboring clusters by up to 50 kb or more of cluster spacer sequences; some or all of these spacer sequences are members of a predominantly centromeric satellite DNA with a 2235 bp repeating unit.

Nucleotide sequence of Xenopus laevis 18S ribosomal RNA inferred from gene sequence

18S ribosomal RNA in Xenopus laevis is 1,825 nucleotides long, as inferred from sequence analysis of an 18S gene. All the 40 rRNA methyl groups can be located in the sequence. Comparison with the yeast (Saccharomyces cerevisiae) 18S sequence reveals extensive regions of high homology interspersed with tracts having little or no homology. Regions of high homology contain almost all the RNa methyl groups. Major regions of low homology area considerably richer in C + G in Xenopus than in yeast.

The nucleotide sequence of the initiation region of the ribosomal transcription unit from mouse

The 5' end of 45S pre-rRNA has been located on a cloned rDNA fragment from mouse by r-loop mapping and the nuclease S1 protection technique. 45S pre-rRNA could be shown to represent the primary transcript of the ribosomal genes because 5' polyphosphate termini have been detected by an enzymatic assay. The sequence of about 1100 nucleotides surrounding the initiation site for ribosomal RNA transcription has been determined. Features of this region of the ribosomal DNA will be discussed. A comparison of the nucleotide sequence with corresponding areas of ribosomal genes from other eukaryotes does not reveal significant homology in the region of transcription initiation.

Specific transcription of mouse ribosomal DNA in a cell-free system that mimics control in vivo

Cloned ribosomal DNA (rDNA) from mouse, which contains the initiation site of 45S pre-rRNA transcription and 5' flanking sequences, has been used as the template in an in vitro transcription system. In the presence of extracts from rapidly growing Ehrlich ascites cells, RNA polymerase I initiates specifically in that region of purified rDNA where the 5' end of 45S rRNA has been mapped. This is shown by electrophoretic analysis of the length of run-off transcripts synthesized from truncated templates, by S1 nuclease mapping, and by hybridization analysis of the in vitro products. The ability of the crude extracts to promote faithful transcription of mouse rDNA correlates with the proliferation rate of the cells. Only extracts prepared from exponentially growing mouse cells contain the factor(s) required for the faithful transcription of mouse ribosomal genes. Extracts from nongrowing or slowly growing mouse cells show very little activity. Thus, the cell-free system somehow reflects the rRNA synthetic activity of the cell and will prove valuable for the identification and purification of the various factors that are involved in the specific read-out of rDNA and may play a central role in the regulation of transcription of the ribosomal genes.

The nucleotide sequence of the putative transcription initiation site of a cloned ribosomal RNA gene of the mouse

Approximately one kilobase pairs surrounding and upstream the transcription initiation site of a cloned ribosomal DNA (rDNA) of the mouse were sequenced. The putative transcription initiation site was determined by two independent methods: one nuclease S1 protection and the other reverse transcriptase elongation mapping using isolated 45S ribosomal RNA precursor (45S RNA) and appropriate restriction fragments of rDNA. Both methods gave an identical result; 45S RNA had a structure starting from ACTCTTAG---. Characteristically, mouse rDNA had many T clusters (greater than or equal to 5) upstream the initiation site, the longest being 21 consecutive T's. A pentadecanucleotide, TGCCTCCCGAGTGCA, appeared twice within 260 nucleotides upstream the putative initiation site. No such characteristic sequences were found downstream this site. Little similarity was found in the upstream of the transcription initiation site between the mouse, Xenopus laevis and Saccharomyces cerevisiae rDNA.

Methylation map of Xenopus laevis ribosomal RNA

One of the most enigmatic features of eukaryotic ribosomal RNA is the presence of many methylated nucleotides. The numbers of RNA methyl groups range from approximately 70 per ribosome in yeast to over 100 in vertebrates. Here it is shown that the methylated nucleotides in Xenopus laevis rRNA are broadly but non-uniformly distributed. In 18S rRNA 2'-O-methylations are partly concentrated in the 5' region and base methylations near the 3' end. In 28S rRNA methyl groups are infrequent in the 5' region, moderately frequent in the central region and abundant in an 1,100-nucleotide tract near the 3' end.

The structure of the yeast ribosomal RNA genes. 2. The nucleotide sequence of the initiation site for ribosomal RNA transcription

The 5'-terminal coding sequence for the 37 S precursor to rRNA of Saccharomyces cerevisiae is identified by reverse transcriptase extension and protection mapping with nuclease S1. The sequence of a 419 bp rDNA fragment containing the transcription initiation site and its adjacent region is determined.

Fine structure of ribosomal RNA. IV. Extraordinary evolutionary conservation in sequences that flank introns in rDNA

By hybridization and DNA sequencing, we have defined a specific region in Xenopus rDNA that is extremely conserved between Tetrahymena, a protozoan, and Xenopus, a vertebrate. This highly conserved region is found at the site where an intron has been shown to interrupt Tetrahymena rDNA [1,2], although we have not detected introns in genomic or cloned Xenopus rDNA. We have noted that the sequences corresponding to nuclear rDNA interon-flanking regions show an intriguing complementarity to tRNAiMet. This suggests possible models for tRNA-rRNA interactions in protein synthesis and/or rRNA splicing.

Cloning and determination of a putative promoter region of a mouse ribosomal deoxyribonucleic acid fragment

An endonuclease EcoRI digest of mouse DNA was subjected to molecular cloning, after partial purification with respect to the ribosomal RNA sequence, using lambda gtWES x lambda B with an in vitro packaging technique. Twelve positive clones were obtained from approximately 2 X 10(4) plaques. One of the clones transferred to the plasmid pBR322 (PMrEL-1) was about 14.9 kb long, hybridizing only with 18S rRNA but not with 28S rRNA. Hybridization of restriction fragments and electron microscopic studies of the R-loop confirmed that this fragment carried about half of the 18S rRNA sequences at one end, suggesting that it contained the initiation site for the 45S preribosomal RNA (pre-rRNA). S1-nuclease protection mapping with hybrids between restriction fragments of the cloned DNA and the 45S pre-rRNA indicated that at least major transcription of the 45S RNA started at a site approximately 4.0 kb upstream from the 5' end of the 18S rRNA. This was confirmed by electron microscopic observations of these hybrids.

Recombination of a eukaryotic DNA in bacteria

Single, 824 bp repeating units of xenopus laevis oocyte-type 5S DNA were inserted into the recombination vectors, lambda rva and lambda rvb. When the inserts had the same orientation with respect to the lambda chromosomes. Spi- imm434 recombinants were recovered by selection on a P2, lambda double lysogenic host. Because of the structure of the vectors, the crossover point in each recombinant must lie completely within the 5S DNA insert. The physical characteristics of these recombinants were determined by examination of restriction enzyme digests. By use of RecA mutant hosts and the Red- vector, lambda rvc, recombination frequencies were measured separately for the bacterial and phage systems. Some of the recombination events resulted in 5S DNA inserts of altered length due to unequal crossovers within repeated sequences in the 5S DNA spacer. The occurrence of just such events in frog 5S DNA had been predicted, based on the structure of 5S DNA and evolutionary considerations.

Distinctive sequence of human mitochondrial ribosomal RNA genes

The nucleotide sequence spanning the ribosomal RNA (rRNA) genes of cloned human mitochondrial DNA reveals an extremely compact genome organization wherein the putative tRNA genes are probably 'butt-jointed' around the two rRNA genes. The sequences of the rRNA genes are significantly homologous in some regions to eukaryotic and prokaryotic sequences, but distinctive; the tRNA genes also have unusual nucleotide sequences. It seems that human mitochondria did not originate from recognizable relatives of present day organisms.

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.

Ubiquitous and gene-specific regulatory 5' sequences in a sea urchin histone DNA clone coding for histone protein variants

The DNA sequences of the entire structural H4, H3, H2A and H2B genes and of their 5' flanking regions have been determined in the histone DNA clone h19 of the sea urchin Psammechinus miliaris. In clone h19 the polarity of transcription and the relative arrangement of the histone genes is identical to that in clone h22 of the same species. The histone proteins encoded by h19 DNA differ in their primary structure from those encoded by clone h22 and have been compared to histone protein sequences of other sea urchin species as well as other eukaryotes. A comparative analysis of the 5' flanking DNA sequences of the structural histone genes in both clones revealed four ubiquitous sequence motifs; a pentameric element GATCC, followed at short distance by the Hogness box GTATAAATAG, a conserved sequence PyCATTCPu, in or near which the 5' ends of the mRNAs map in h22 DNA and lastly a sequence A, containing the initiation codon. These sequences are also found, sometimes in modified version, in front of other eukaryotic genes transcribed by polymerase II. When prelude sequences of isocoding histone genes in clone h19 and h22 are compared areas of homology are seen to extend beyond the ubiquitous sequence motifs towards the divergent AT-rich spacer and terminate between approximately 140 and 240 nucleotides away from the structural gene. These prelude regions contain quite large conservative sequence blocks which are specific for each type of histone genes.

Organization of ribosomal genes in Paramecium tetraurelia

The macronuclear ribosomal DNA (rDNA) of the ciliated protozoan Paramecium tetraurelia (stock 51) was analyzed by digestion with restriction endonucleases. The fragments which contained ribosomal RNA (rRNA) coding sequences and spacer sequences were identified. The spacer sequences exhibited some heterogeneity in size. The genes coding for 5.8S RNA, but not for 5S RNA, are linked to the 17S and 25S rRNA genes. Complementary RNA, synthesized from rDNA of stock 51, was hybridized with restriction digests of whole cell DNA from six other allopatric stocks of this species. The restriction patterns of the rDNA from these seven stocks were, in general, very similar, and the sizes of the coding sequences were identical in all seven stocks. Only the restriction pattern of rDNA from stock 127 differed significantly from that of stock 51. The rDNA from stock 127 was isolated and characterized, and with the exception of the restriction pattern of its spacer, it resembled the rDNA from stock 51. It is concluded that the rDNA repeat in Paramecium, including the spacer, has, in general, been conserved during the course of evolution. It is suggested that in some species, even in the absence of genetic exchange among geographically separated populations, selection pressure may act to conserve spacers of tandemly repeated rDNA. The conservation may be related to the number of rDNA copies in the germinal nucleus.

More ribosomal spacer sequences from Xenopus laevis

The base sequence analysis of a Xenopus laevis ribosomal DNA repeat (7) has been extended to cover almost the entire non-transcribed and external transcribed spacer. A compilation of these sequences is presented. All the repetitive and non-repetitive sequence elements of the spacer are identified and their evolution discussed. Comparison of the X.laevis and S.cerevisiae (25,26) ribosomal DNAs shows about 80% sequence conservation in the 18S gene but no sequence conservation, from the available data, in the external transcribed spacer. The sequence coding for the 3' terminus of the X.laevis 40S ribosomal precursor RNA is presented and its structural features analyzed.

Nucleotide sequence of genes coding for tRNAPhe and tRNATyr from a repeating unit of X. laevis DNA

A cloned 3.18 kb repeating unit of Xenopus laevis DNA, known to contain two tRNA1Met genes, has been partially sequenced. The sequenced region could potentially code for two more tRNA species. One is a phenylalanine tRNA with the same primary sequence as that found in a variety of mammals. The other is a tyrosine tRNA with a 13 bp intervening sequence located immediately adjacent or very close to the 3' nucleotide of the anticodon. The two putative genes have opposite polarity and the sequences encoding the 5' nucleotides of the mature tRNAs are separated by only 72 bp of DNA. Homologous GC-rich sequences of dyad symmetry precede each gene. Neither gene codes for the 3' terminal CCA expected in the nature tRNAs. A short T cluster is present in the noncoding strand 3 bp away from the 3' end of the tRNATyr gene. A similar short T cluster is located 26 bp downstream of the tRNAPhe sequence. The nucleotides in between are very GC-rich and are capable of forming a stable RNA hairpin. The possible significance of these features for tRNA gene evolution, RNA splicing and transcription is discussed.

Structural organization of mouse rDNA: comparison of transcribed and non-transcribed regions

The DNA of the recombinant phage lambda gtWES Mr974 (GRUMMT et al., 1979) which contains the 18S region and adjacent spacer sequences of the ribosomal genes from mouse has been digested with the restriction endonuclease SalI. Fragments corresponding to the non-transcribed spacer (A and D) and the external transcribed spacer (B) have been prepared and their nucleotide composition and sequence organization has been determined. The data indicate that the part of the non-transcribed spacer contained in Mr974 consists of at least two structural domains of distinct sequence characteristics. Fragment A contains 49% G + C and exhibits a high sequence complexity. Fragment D, the spacer fragment flanking the coding region, is very rich in G + C and is obviously composed of an internally repetitive sequence which is cut by several restriction enzymes into a similar set of repetitive fragments. Most of the fragments have sizes that are multiples of 60 and 80 or 140 base pairs, respectively, suggesting an alternating 60/80bp arrangement. This regular sequence in fragment D accounts both for the observed instability and length heterogeneity of the rDNA insert in several clones and probably for the heterogeneity in the structure of the ribosomal repeats in the genomic DNA.

The nucleotide sequence of the initiation and termination sites for ribosomal RNA transcription in X. laevis

In this study, we have located the sites of transcription initiation and termination on a cloned fragment of ribosomal DNA from X. laevis, and have sequenced the surrounding nucleotides. As reported previously (Reeder, Sollner-Webb and Wahn, 1977), about 25% of the 40S rRNA precursor molecules isolated from oocytes have polyphosphate 5' termini and are therefore presumed to represent primary transcripts. These ends hybridize specifically to the 221 bp DNA fragment and removed the overhanging DNA region with S1 nuclease. In the other, we hybridized 40S RNA to a 221 bp fragment of ribosomal DNA. The nucleotides encoding the 5' end of the 40S RNA were located more precisely by two methods. In one, we hybridized 40S RNA to the 221 bp DNA fragment and removed the overhanging DNA region with S1 nuclease. In the other, we hybridized 40S RNA to a smaller DNA fragment and extended the recessed 3' terminus of the DNA using reverse transcriptase. The resultant DNA fragments were sized on sequencing gels. Both determinations map the 5' end of 40S RNA at the same site in the rDNA, about 2250 bp upstream from the Eco RI site in the 18S rRNA coding sequence. At this site we find a DNA sequence beginning AGGGGAAGAC.... which agrees with partial sequence data from the 5' end of polyphosphorylated and bulk 40S rRNA. Features of this region of the ribosomal DNA will be discussed in this paper. A 227 nucleotide region surrounding the initiation site was also sequenced from an independently derived clone and found to differ in only one nucleotide. In addition, a sequence is found about 1100 nucleotides upstream from the 5' end of the gene that has 90% homology to the sequence from nucleotides minus 125 to +4 in the initiation region. At the termination region, X. laevis ribosomal DNA has a single recognition site for the restriction enzyme Hind III in each repeating unit. Using the S1 nuclease technique, the 3' termini of both the 40S precursor and mature 28S rRNA are seen to map within this recognition sequence. The sequence surrounding the Hind III site has striking homology to termination sites recognized by other RNA polymerase classes. Sequences with similar features are also found upstream from the initiation site.