Mapping of the Xenopus laevis 5.8S rDNA by restriction and DNA sequencing

Mechanism and site of action of a ribosome-inactivating protein type 1 fromDianthus barbatuswhich inactivatesEscherichia coliribosomes

A single chain ribosome-inactivating protein with RNA N-glycosidase activity, here named Dianthin 29, was isolated from leaves of Dianthus barbatus L. Incubation of intact Escherichia coli ribosomes with Dianthin 29 and subsequent aniline treatment of the isolated rRNA releases a rRNA fragment of 243 nucleotides from 23 S rRNA. Nucleotide sequence studies showed that the site of N-glycosidic bond cleavage is at A-2660 within the universally conserved sequence 5'-AGUACGAGAGGA-3' near the 3'-end of 23/28 S rRNAs. To our knowledge, Dianthin 29 is the first ribosome-inactivating protein which is shown to inactivate intact prokaryotic ribosomes in the same manner as eukaryotic ribosomes.

A ribosomal orphon sequence from Xenopus laevis flanked by novel low copy number repetitive elements

We have used a differential cloning approach to isolate ribosomal/non-ribosomal frontier sequences from Xenopus laevis. A ribosomal intergenic spacer sequence (IGS) was cloned and shown not to be physically linked with the ribosomal locus. This ribosomal orphon contained the IGS sequences found immediately downstream of the 28S gene and included an array of enhancer repetitions and a non-functional spacer promoter. The orphon sequence was flanked by a member of the novel 'Frt' low copy repetitive element family. Three individual Frt repeats were sequenced and all members of this family were shown to lie clustered at two chromosomal sites, one of which contained the ribosomal orphon. One of the Frt elements contained an insertion of 297 bp that showed extensive homology to sequences within at least three other Xenopus genes. Each homology region was flanked by members of the T2 family of short interspersed repetitive elements, (SINEs), and by its target insertion sequence, suggesting multiple translocation events. The data are discussed in terms of the evolution of the ribosomal gene locus.

The sequence of the 5' end of the U8 small nucleolar RNA is critical for 5.8S and 28S rRNA maturation

Ribosome biogenesis in eucaryotes involves many small nucleolar ribonucleoprotein particles (snoRNP), a few of which are essential for processing pre-rRNA. Previously, U8 snoRNA was shown to play a critical role in pre-rRNA processing, being essential for accumulation of mature 28S and 5.8S rRNAs. Here, evidence which identifies a functional site of interaction on the U8 RNA is presented. RNAs with mutations, insertions, or deletions within the 5'-most 15 nucleotides of U8 do not function in pre-rRNA processing. In vivo competitions in Xenopus oocytes with 2'O-methyl oligoribonucleotides have confirmed this region as a functional site of a base-pairing interaction. Cross-species hybrid molecules of U8 RNA show that this region of the U8 snoRNP is necessary for processing of pre-rRNA but not sufficient to direct efficient cleavage of the pre-rRNA substrate; the structure or proteins comprising, or recruited by, the U8 snoRNP modulate the efficiency of cleavage. Intriguingly, these 15 nucleotides have the potential to base pair with the 5' end of 28S rRNA in a region where, in the mature ribosome, the 5' end of 28S interacts with the 3' end of 5.8S. The 28S-5.8S interaction is evolutionarily conserved and critical for pre-rRNA processing in Xenopus laevis. Taken together these data strongly suggest that the 5' end of U8 RNA has the potential to bind pre-rRNA and in so doing, may regulate or alter the pre-rRNA folding pathway. The rest of the U8 particle may then facilitate cleavage or recruitment of other factors which are essential for pre-rRNA processing.

Type 1 ribosome-inactivating proteins depurinate plant 25S rRNA without species specificity

Four different type 1 ribosome-inactivating proteins (RIPs) with RNA N-glycosidase activity were tested for their ability to attack the large rRNA of plant ribosomes derived from tobacco plants, as well as from the plant species from which the particular RIP had been isolated. Incubation of tobacco ribosomes with RIPs isolated from either Phytolacca americana L. (pokeweed), Dianthus barbatus L. (carnation), Spinacia oleracea L. (spinach) or Chenopodium amaranthicolor Coste and Reyn. (chenopodium) rendered the 25S rRNA sensitive to aniline-catalyzed hydrolysis, generating a single rRNA-fragment of about 350 nucleotides. The same fragment was generated when rRNAs from pokeweed, carnation, spinach or chenopodium ribosomes were aniline-treated without any deliberate treatment of the ribosomes with the respective RIP. This indicated that ribosomes from all RIP-producing plants were already inactivated by their own RIPs during preparation. These results demonstrate that plant ribosomes are generally susceptible to RIP attack, including modification by their own RIPs. Direct sequencing of the newly generated fragments revealed that a single N-glycosidic bond at an adenosine residue within the highly conserved sequence 5'-AGUACGAGAGGA-3' was cleaved by all of the RIPs investigated, a situation also found in animal, yeast and Escherichia coli ribosomes.

Physical and genetic mapping of cloned ribosomal DNA from Toxoplasma gondii: primary and secondary structure of the 5S gene

The ribosomal DNA (rDNA encoding rRNA) of the obligately intracellular protozoan parasite, Toxoplasma gondii, was identified, cloned, physically mapped, its copy number determined, and the 5S gene sequenced. Using total RNA as a probe, a collection of recombinant lambda phages containing copies of rDNA were isolated from a lambda 2001 tachyzoite genomic library. Northern gel hybridization confirmed specific homology of the 7.5-kb rDNA unit, subcloned into pTZ18R, to T. gondii rRNA. The mapped rDNA found in pTOX1 contained small ribosomal subunit (SS; 18S)- and large ribosomal subunit (LS; 26S)-encoding genes localized using intragenic heterologous probes from the conserved sequences of the SS (18S) and LS (28S) Xenopus laevis genes. the physical mapping data, together with partial digestion experiments and Southern gel hybridization, confirmed a 7.5-kb rDNA unit arranged in a simple head-to-tail fashion that is tandemly repeated. We estimated the rDNA repeat copy number in T. gondii to be 110 copies per haploid tachyzoite genome. Parts of the SS gene and the complete 5S gene were sequenced. The 5S gene was found to be within the rDNA locus, a rare occurrence found only in some fungi and protozoa. Secondary-structure analysis revealed an organization remarkably similar to the 5S RNA of eukaryotes.

Binding of protein synthesis initiation factor 4E to oligoribonucleotides: effects of cap accessibility and secondary structure

The binding of rabbit globin mRNA to the 25-kDa cap binding protein eIF-4E from human erythrocytes was found to be 5.3-fold stronger than the binding of the cap analogue m7GpppG to eIF-4E [Gross et al. (1990) Biochemistry 29, 5008-5012]. In order to investigate whether this effect is due to the longer sequence of nucleotides in globin mRNA or to other features such as cap accessibility or secondary structure, oligoribonucleotide analogues of rabbit alpha-globin mRNA were synthesized by T7 RNA polymerase from a synthetic oligodeoxynucleotide template in the presence of m7GpppG; these oligoribonucleotide analogues possess varying degrees of cap accessibility and secondary structure. Equilibrium association constants for the interaction of these oligoribonucleotides and purified human erythrocyte eIF-4E were obtained from direct fluorescence titration experiments. The data indicate that while the presence of the m7G cap is required for efficient recognition by eIF-4E, the cap need not be completely sterically accessible, since other structural features within the mRNA also influence binding.

The ribosomal genes of the mosquito, Aedes aegypti

The characterisation of the ribosomal genes of the mosquito, Aedes aegypti, is described. Preliminary experiments using a cloned Drosophila ribosomal DNA (rDNA) repeat to probe Southern transfers of Ae. aegypti genomic DNA has indicated that the rDNA repeat of Ae. aegypti is 9.0 kb in length and that individual rDNA repeats exhibit a high degree of homogeneity with respect to length and the position of restriction enzyme recognition sites within the rDNA. The preliminary mapping data together with partial digestion experiments demonstrate that, as in all other higher eukaryotes, the rDNA repeats are arranged in a head-to-tail, tandemly repeating manner. The restriction mapping of cloned rDNA repeats confirmed the largely uniform length of the Ae. aegypti rDNA repeat and provided a more detailed physical map of the DNA. A restriction site polymorphism was detected in one clone (Aar9) which contains an extra HincII site, which is not present in three other clones studied (Aar1, Aar3, or Aar7). Transcription mapping has allowed the allocation of identities to the various restriction fragments and the approximate positioning of the transcription unit. The estimate of rDNA repeat copy number in Ae. aegypti (approximately 500 copies per haploid genome) is similar to the estimate reported for the closely related species, Aedes albopictus, of 430 copies per haploid genome. Ribosomal DNA thus comprises approximately 0.6% of the total Ae. aegypti genome. Analysis of the variation of the rDNA repeat unit both within individual mosquitoes and between strains of Ae. aegypti, has severed to confirm the remarkable homogeneity of the rDNA repeat unit in this insect.

Locations of methyl groups in 28 S rRNA of Xenopus laevis and man. Clustering in the conserved core of molecule

28 S ribosomal RNA from several vertebrate species contains some 68 to 70 methyl groups. Evidence described in this paper enables some 58 methyl groups to be located in the primary structure of 28 S ribosomal RNA from Xenopus laevis. Most of the locations are unambiguous but a few are currently tentative. In human 28 S ribosomal RNA the great majority of the same sites are methylated as in Xenopus, but there are a few differences between the respective methyl group distributions. The main features of the methyl group distribution are as follows. (1) All of the identified methyl groups are in conserved core regions of 28 S ribosomal RNA. (2) Methylation is much more heavily concentrated in the 3' region of the molecule than in the 5' region (in contrast to 18 S ribosomal RNA, in which there is a major cluster of 2'-O-methyl groups in the 5' region). (3) In addition to the heavily methylated 3' region, clusters of methyl groups occur elsewhere in 28 S ribosomal RNA in the vicinity of domain boundaries. For domains 3 to 6, the two ends of each domain are united in a helix and are linked to adjacent domains either directly or by short single-stranded regions. It therefore follows that the methyl groups near the boundaries of these domains come together into the same general region of the three-dimensional structure. Within this large-scale pattern of distribution, methyl groups occur in a variety of local environments, examples of which are discussed. The triply methylated sequence Am-Gm-Cm-A occurs in a short single-stranded region which links domain 3 to domain 4. Near the 3' end of domain 5 there is a cluster of 11 methyl groups including a 2'-O-methyl pseudouridine in a tract of 160 nucleotides whose sequence is totally conserved between Xenopus and man. These methyl groups are variously distributed between single-stranded regions and short or imperfect but conserved helices. A further cluster of methyl groups including the highly conserved Um-Gm-psi sequence occurs in a region of domain 6 which is implicated in peptidyl transfer. Possible relationships between methylation and other events in ribosome maturation are discussed.

An unusually compact ribosomal DNA repeat in the protozoan Giardia lamblia

The ribosomal RNA (rRNA) genes of the protozoan parasite Giardia lamblia have been analyzed with respect to size, composition and copy number. They are found to be remarkable in several respects. First, the rRNAs themselves are the smallest yet reported for any eukaryotic organism. Second, the genes encoding them are found as an exceptionally small tandemly repeated unit of only 5.4 kilobase-pairs. Third, the genes are extraordinarily G:C rich, even in regions which are highly conserved between all other eukaryotic rRNA genes. Finally, by analogy to other organisms, the 5.8S RNA appears to lack about 15 nucleotides from its 3'-end, a region previously thought to be essential for 5.8S RNA function. We also provide the first estimates of the genomic complexity and total G:C content of this important protozoan pathogen.

A simple gene-expression system for the small subunit of ribulose bisphosphate carboxylase in leaves ofNicotiana sylvestris

InNicotiana sylvestris only four transcripts coding for the small subunit of RUBISCO are present in leaves. They are very closely related as they are identical in the nucleotide sequence of the non-coding regions and show only three silent point differences in the region coding for the mature peptide.The main difference among these four transcripts lies in the length of the non-coding regions. Half of the SmRNA population as confirmed by direct RNA sequencing has an additional nucleotide sequence in the leader region. Two cDNAs have an additional nucleotide sequence at the end of the 3' non-coding region. Based on these criteria the transcripts were classified into two groups:.group I has a 73-nucleotide-long leader sequence and the nucleotides T, A and C at position 327, 432 and 519 in the coding region..group II has a 60-nucleotide-long leader sequence and the nucleotides C, G and T at these positions in the coding region.The two cDNAs showing a difference in the length of the 3' non-coding region belong to group II.The study of all these transcripts argues for the possibility that only two families of genes are expressed in leaves ofN. sylvestris.

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.

Restriction endonuclease mapping of ribosomal RNA genes: sequence divergence and the origin of the tetraploid treefrog Hyla versicolor

Hyla chrysoscelis (2n = 24) and H. versicolor (2n = 48) are a diploid-tetraploid species pair of treefrogs. Restriction endonuclease mapping of ribosomal RNA (rRNA) gene repeat units of diploids collected from eastern and western populations reveals no differences within rRNA gene coding regions but distinctive differences within the nontranscribed spacers. A minimum of two physical maps is required to construct an rRNA gene map for the tetraploid, whose repeat units appear to be a composite, with about 50% of the elements resembling the "western" diploid population and about 50% resembling the "eastern" population. These results imply that this population of the tetraploid species may have arisen from a genetically hybrid diploid. Alternatively, the dual level of sequence heterogeneity in H. versicolor may reflect some type of gene flow between the two species. The coding region of the rRNA genes in the tetraploid differs from that in either diploid in about 20% of all repeat units, as exemplified by a BamHI site located near the 5' terminus of the 28 S rRNA gene. If the 20% variant class of 28 S rRNA gene coding sequences is expressed, then there must be two structural classes of ribosomes; if only the 80% sequence class is expressed, then a genetic control mechanism must be capable of distinguishing between the two different sequence variants. It is postulated that the 20% variant sequence class may be correlated with a partial functional diploidization of rRNA genes in the tetraploid species.

Are there insertions in the ribosomal DNA of vertebrates?

We have analysed the Eco RI restriction pattern of rDNA of the newt Triturus vulgaris and of some other amphibian species by Southern blotting and hybridization with nick-translated Xenopus rDNA prepared from the recombinant plasmids pXlr11 and pXlr12 (21). After hybridization with r11, the 28S coding fragments become visible in two bands, a prominent one of 5.3 kb and a weak band of 5.9 kb representing about 8% of the 28S genes. The evidence obtained so far by additional digestions with Bam HI and Bgl II indicates that in this species and in Triturus helveticus the coding regions of the 5.9 kb fragments are interrupted by an insertion 0.6 kb in length located in a 1.6 kb Bgl II fragment at the 3' end of the Eco RI fragment, which we believe to be the first described in a vertebrate.

Cap accessibility correlates with the initiation efficiency of alfalfa mosaic virus RNAs

The rate of cap removal from the alfalfa mosaic virus (A1MV) RNAs with tobacco acid pyrophosphatase (TAP) depends on the RNA species. At 37 degrees C and in the absence of divalent cation, RNA 3 reacts more slowly than the other three, which are decapped at similar rates. In the presence of magnesium, at 25 degrees C, TAP also discriminates against RNA 1. Thus the order of reactivity with TAP largely mimics the hierarchy of initiation efficiencies of the A1MV RNAs (Godefroy-Colburn et al., preceding paper in this journal). Our interpretation of these findings is that cap accessibility is what limits the rate of reaction with initiation factors as well as with TAP. In this hypothesis, translational discrimination between naturally capped messages would be related to the rate of 'breathing' of their 5' ends.

Complete sequence of one of the mRNAs coding for the small subunit of ribulose bisphosphate carboxylase of Nicotiana sylvestris

The combination of cDNA and RNA sequencing techniques has enabled determination of the complete sequence of one of the mRNAs coding for the precursor of the small subunit of ribulose bisphosphate carboxylase of Nicotiana sylvestris. In this 898-nucleotide-long mRNA, 540 nucleotides code for the entire 180-amino-acid-long precursor polypeptide consisting of the 57-amino acid-long transit peptide and the 123-amino-acid-long mature protein, while 60 and 195 nucleotides belong to the 5' and 3' noncoding flanking regions, respectively. The 5' end, which is very rich in AG residues, contains several direct and indirect repeated sequences, and a possible hairpin structure. The 3' end, terminated by a 103-nucleotide-long poly-A tail, is very rich in AU residues but does not contain the classical polyadenylation signal sequence.

Complete nucleotide sequence of RNA 3 from alfalfa mosaic virus, strain S

We report the sequence of RNA 3 from strain S of Alfalfa mosaic virus (2,055 nucleotides). This RNA codes for a 32.4 kd protein (P3) and for the 24 kd coat protein (P4). The largest part of the sequence was established using RNA sequencing methods. The completion of the sequence in the region coding for P3 was achieved with cloned cDNA synthesized after priming at internal sites of RNA 3. Comparison of the RNA sequences coding P3 and P4 proteins in strain S with those reported in the literature for strain 425 revealed a higher amino acid substitution rate (3%) for P3 than for P4 (congruent to 1%) despite a similar average base substitution of 3-4% in these regions. In P3, two out of nine amino acid changes occur in hydrophilic regions. The amino acid changes in P4 do not modify the local hydrophilicity distribution. The intercistronic region displays a low degree of base substitution (2%) when compared with the untranslated 3'-end region (3.6%) or the 5'-end leader region (8%), the average substitution rate being 3.2%.

Structural organization of the two main rDNA size classes of Ascaris lumbricoides

The two main rDNA size classes in the genome of Ascaris lumbricoides consist of 8.8 kb and 8.4 kb long repeating units present in a quantitative ratio of roughly 10:1. They both contain the genes coding for 18 , 5.8S and 26S ribosomal RNAs. The length heterogeneity is due to a 450 bp long spacer region localized in the longer repeating unit which begins 870 bp upstream of the 5'-end 18S gene. A few additional microheterogeneities in base sequence occur at the 5'-end of the 26S gene. The 18S, 5.8S and 26S coding regions have been mapped on both the 8.8 kb and 8.4 kb repeating units and the localization of the 5'- and 3'-ends of the 18S and 26S genes has been performed by S1 protection. No intervening sequences are present in either coding region of the two main rDNA size classes.

The avian malaria Plasmodium lophurae has a small number of heterogeneous ribosomal RNA genes

The structure and number of the ribosomal RNA (rRNA) genes of the avian malaria parasite Plasmodium lophurae has been examined using Southern blot analysis and recombinant DNA techniques. The ribosomal DNA (rDNA) of P. lophurae has been cloned into the plasmid pBR322, beginning with size-selected populations of Cla I- and Hind III-restricted parasite DNA. The structure of two clones (CL-1 and HA-2) is presented in detail. These two clones together probably represent the entire 17s and 25s coding regions of P. lophurae. Analysis of quantitative genomic Southern blots reveals that there are approximately six rRNA genes per haploid genome, and that the rRNA genes may be divided into four distinct classes by restriction analysis. Examination of the flanking regions of these genes indicates that they are not organized into easily recognizable tandem repeats.

The cloned rRNA genes of P. lophurae: a novel rDNA structure

The detailed structure of two ribosomal DNA (rDNA) clones CL-1 and HA-2, from the avian malaria parasite Plasmodium lophurae has been examined using hybridization and electron microscopy. The results demonstrate that the clone CL-1 contains two regions homologous to 25s rRNA of approximately 2200 base pairs (bp) and 450 bp in length, separated by a non homologous region of 240 bp. CL-1 also contains two regions of approximately 1100 bp and 550 bp homologous to 17s rRNA, separated by a non homologous region of 230 bp. The clone HA-2 contains a single region of 670 bp, which is homologous to 25s rRNA. This region is flanked by non homologous stretches of DNA 940 bp and 110 bp in length. As HA-2 is known to be adjacent to CL-1 in the genome (1), these results suggest that the 25s rDNA is interrupted twice, and the 17s rDNA once, by stretches of DNA not found in mature rRNA.

Sequence analysis of 28S ribosomal DNA from the amphibian Xenopus laevis

We have determined the complete nucleotide sequence of Xenopus laevis 28S rDNA (4110 bp). In order to locate evolutionarily conserved regions within rDNA, we compared the Xenopus 28S sequence to homologous rDNA sequences from yeast, Physarum, and E. coli. Numerous regions of sequence homology are dispersed throughout the entire length of rDNA from all four organisms. These conserved regions have a higher A + T base composition than the remainder of the rDNA. The Xenopus 28S rDNA has nine major areas of sequence inserted when compared to E. coli 23S rDNA. The total base composition of these inserts in Xenopus is 83% G + C, and is generally responsible for the high (66%) G + C content of Xenopus 28S rDNA as a whole. Although the length of the inserted sequences varies, the inserts are found in the same relative positions in yeast 26S, Physarum 26S, and Xenopus 28S rDNAs. In one insert there are 25 bases completely conserved between the various eukaryotes, suggesting that this area is important for eukaryotic ribosomes. The other inserts differ in sequence between species and may or may not play a functional role.

Nucleotide sequences of the 5.8S rRNAs of a mollusc and a porifer, and considerations regarding the secondary structure of 5.8S rRNA and its interaction with 28S rRNA

We report the primary structures of the 5.8 S ribosomal RNAs isolated from the sponge Hymeniacidon sanguinea and the snail Arion rufus. We had previously proposed (Ursi et al., Nucl. Acids Res. 10, 3517-3530 (1982)) a secondary structure model on the basis of a comparison of twelve 5.8 S RNA sequences then known, and a matching model for the interaction of 5.8 S RNA with 26 S RNA in yeast. Here we show that the secondary structure model can be extended to the 25 sequences presently available, and that the interaction model can be extended to the binding of 5.8 S RNA to the 5'-terminal domain of 28 S (26 S) RNA in three species.

Location of the initial cleavage sites in mouse pre-rRNA

The locations of three cleavages that can occur in mouse 45S pre-rRNA were determined by Northern blot hybridization and S1 nuclease mapping techniques. These experiments indicate that an initial cleavage of 45S pre-rRNA can directly generate the mature 5' terminus of 18S rRNA. Initial cleavage of 45S pre-rRNA can also generate the mature 5' terminus of 5.8S rRNA, but in this case cleavage can occur at two different locations, one at the known 5' terminus of 5.8S rRNA and another 6 or 7 nucleotides upstream. This pattern of cleavage results in the formation of cytoplasmic 5.8S rRNA with heterogeneous 5' termini. Further, our results indicate that one pathway for the formation of the mature 5' terminus of 28S rRNA involves initial cleavages within spacer sequences followed by cleavages which generate the mature 5' terminus of 28S rRNA. Comparison of these different patterns of cleavage for mouse pre-rRNA with that for Escherichia coli pre-rRNA implies that there are fundamental differences in the two processing mechanisms. Further, several possible cleavage signals have been identified by comparing the cleavage sites with the primary and secondary structure of mouse rRNA (see W. E. Goldman, G. Goldberg, L. H. Bowman, D. Steinmetz, and D. Schlessinger, Mol. Cell. Biol. 3:1488-1500, 1983).

Location of the initial cleavage sites in mouse pre-rRNA

The locations of three cleavages that can occur in mouse 45S pre-rRNA were determined by Northern blot hybridization and S1 nuclease mapping techniques. These experiments indicate that an initial cleavage of 45S pre-rRNA can directly generate the mature 5' terminus of 18S rRNA. Initial cleavage of 45S pre-rRNA can also generate the mature 5' terminus of 5.8S rRNA, but in this case cleavage can occur at two different locations, one at the known 5' terminus of 5.8S rRNA and another 6 or 7 nucleotides upstream. This pattern of cleavage results in the formation of cytoplasmic 5.8S rRNA with heterogeneous 5' termini. Further, our results indicate that one pathway for the formation of the mature 5' terminus of 28S rRNA involves initial cleavages within spacer sequences followed by cleavages which generate the mature 5' terminus of 28S rRNA. Comparison of these different patterns of cleavage for mouse pre-rRNA with that for Escherichia coli pre-rRNA implies that there are fundamental differences in the two processing mechanisms. Further, several possible cleavage signals have been identified by comparing the cleavage sites with the primary and secondary structure of mouse rRNA (see W. E. Goldman, G. Goldberg, L. H. Bowman, D. Steinmetz, and D. Schlessinger, Mol. Cell. Biol. 3:1488-1500, 1983).

A comparison of vertebrate interferon gene families detected by hybridization with human interferon DNA

Cloned human interferon complementary DNAs were used as hybridization probes to detect interferon alpha and beta gene families in restriction endonuclease digests of total genomic DNA isolated from a wide range of vertebrates and invertebrates. A complex interferon-alpha multigene family was detected in all mammals examined, whereas there was little or no cross-hybridization of human interferon-alpha complementary DNA to non-mammalian vertebrates or invertebrates. In contrast, human interferon-beta complementary DNA detected one or two interferon-beta genes in all mammals tested, with the exception of the cow and the blackbuck, both of which possessed a complex interferon-beta multigene family which has presumably arisen by a recent series of gene duplications. Interferon-beta sequences could also be detected in non-mammalian vertebrates ranging from birds to bony fish. Detailed restriction endonuclease mapping of DNA sequences neighbouring the interferon-beta gene in a variety of primates indicated a strong evolutionary conservation of flanking sequences, particularly on the 3' side of the gene.

Structure of mouse rRNA precursors. Complete sequence and potential folding of the spacer regions between 18S and 28S rRNA

We have determined the complete nucleotide sequence of the regions of mouse ribosomal RNA transcription unit which separate mature rRNA genes. These internal transcribed spacers (ITS) are excised from rRNA precursor during ribosome biosynthesis. ITS 1, between 18S and 5.8S rRNA genes, is 999 nucleotides long. ITS 2, between 5.8S and 28S rRNA genes, is 1089 nucleotides long. Both spacers are very rich in G + C, 70 and 74% respectively. Mouse sequences have been compared with the other available eukaryotes: while no homology is apparent with yeast or xenopus, mouse and rat ITS sequences have been largely conserved, with homologous segments interspersed with highly divergent tracts. Homology with rat is much more extensive for ITS 1 than for ITS 2. Tentative secondary structure models are proposed for the folding of these regions within rRNA precursor; they are closely related in mouse and rat.

Structure of the 5'-terminal untranslated region of the genomic RNAs from two strains of alfalfa mosaic virus

We report the sequences of the 5'-terminal regions of the 3 Alfalfa Mosaic Virus genomic RNAs for the Strasbourg strain (AlMV-S) and for a new isolate, AlMV-B; they are compared to similar data obtained by Koper-Zwarthoff et al. (Nucleic Acids Res. 1980, 8, 5635-5647) for strain 425. The structure of these leaders is highly conserved in RNAs 1 and 2. The length of the leader is 102, 100 and 101 nucleotides in RNA1 for strains S, B and 425 respectively; 55 and 56 in RNA2 for strains S and B respectively. In RNA3 however, there are important differences near the 5'-terminus between strain S and the other two: The total leader length is 258 nucleotides for strain S and 242 for strain B. The secondary structure models show a conserved hairpin near the 5'-end of each genomic RNA of AlMV-S. This hairpin is inexistent in RNA3 of the B and 425 strains. The degree of base-pairing increases with leader length. The initiator codon is located in a single stranded region in RNA2 whereas it is found in a hairpin stem in RNA 3.

Multiple heterogeneities in the transcribed spacers of ribosomal DNA from Xenopus laevis

Ribosomal DNA (rDNA) from Xenopus laevis contains several heterogeneities in all three transcribed spacers, as revealed by analysis of cloned and uncloned amplified rDNA from oocytes and cloned chromosomal rDNA from erythrocytes. Heterogeneities include single base changes and length variants of one to several nucleotides. Sites of variation are widely but non-uniformly distributed, some occurring only a short distance outside the boundaries of the rRNA coding regions. No two transcription units that we have yet examined are identical throughout their transcribed spacer regions.

Sequence and secondary structure of mouse 28S rRNA 5'terminal domain. Organisation of the 5.8S-28S rRNA complex

We present the sequence of the 5' terminal 585 nucleotides of mouse 28S rRNA as inferred from the DNA sequence of a cloned gene fragment. The comparison of mouse 28S rRNA sequence with its yeast homolog, the only known complete sequence of eukaryotic nucleus-encoded large rRNA (see ref. 1, 2) reveals the strong conservation of two large stretches which are interspersed with completely divergent sequences. These two blocks of homology span the two segments which have been recently proposed to participate directly in the 5.8S-large rRNA complex in yeast (see ref. 1) through base-pairing with both termini of 5.8S rRNA. The validity of the proposed structural model for 5.8S-28S rRNA complex in eukaryotes is strongly supported by comparative analysis of mouse and yeast sequences: despite a number of mutations in 28S and 5.8S rRNA sequences in interacting regions, the secondary structure that can be proposed for mouse complex is perfectly identical with yeast's, with all the 41 base-pairings between the two molecules maintained through 11 pairs of compensatory base changes. The other regions of the mouse 28S rRNA 5'terminal domain, which have extensively diverged in primary sequence, can nevertheless be folded in a secondary structure pattern highly reminiscent of their yeast' homolog. A minor revision is proposed for mouse 5.8S rRNA sequence.

Nucleotide sequence of the region between the 18S rRNA sequence and the 28S rRNA sequence of rat ribosomal DNA

The DNA sequence of the intragenic region of the rat 45S ribosomal RNA precursor was determined. This sequence contains 2282 nucleotides and extends from the conserved EcoR I site near the 3' terminus of 18S rRNA to 69 nucleotides downstream of the 5' terminus of 28S rRNA. The sequences corresponding to 18S and 5.8S rRNA were identified by comparison with previously published data. The 5' terminus of rat 28S rRNA was identified by S1 nuclease protection and reverse transcriptase elongation assays. The internal transcribed spacers were found to be 1066 and 765 nucleotides long and had little homology with those of Xenopus and yeast. Regions of sequence homology between rat and Xenopus were found at the junctions of the internal transcribed spacers with 18S, 5.8S and 28S rRNA. These homologies suggest that these sequences may function as recognition sites for the processing of the ribosomal precursor RNA.

Molecular cloning and characterization of ribosomal RNA genes from the brine shrimp

A library of genomic DNA from the brine shrimp, Artemia, has been constructed with the Charon 4A phage vector, utilizing EcoRI passenger fragments. Screening this library with purified Xenopus laevis cloned rDNA genes has resulted in the identification and plaque purification of a recombinant containing a complete Artemia (18 S + 26 S) rDNA repeat unit. A physical map derived from the analysis of restriction endonuclease digests of the repeat unit, which measures 13.9 kilobase pairs, is similar to the map derived from genomic DNA. In common with several other species, the 26 S rRNA gene terminates with a HindIII recognition site.

DNAase I sensitivity and methylation of active versus inactive rRNA genes in xenopus species hybrids

We studied the chromatin structure and methylation of ribosomal RNA genes (rDNA) in hybrids between Xenopus laevis and Xenopus borealis. S1-nuclease protection experiments showed that 97%-98% of the rRNA precursor in hybrid tadpoles was of the X. laevis type. Preferential expression of the laevis rDNA was correlated with its hypersensitivity to DNAase I compared to borealis rDNA. Borealis and laevis rDNAs gave equivalent methylation patterns, however. The results show that hypomethylated sites in the nontranscribed spacer are not sufficient to ensure DNAase I hypersensitivity or transcription of the borealis rDNA. Also, heavy methylation of the transcribed region of laevis rDNA is compatible with its hypersensitivity to DNAase I. The absence of coupling between hypomethylation and DNAase I sensitivity argues against the view that the methylation pattern directly triggers the active chromatin structure, though it does not exclude a less intimate relationship between transcription and DNA hypomethylation. Examination of borealis sperm rDNA showed that hypomethylated sites were present at the same spacer locations as in somatic cells. This contrasts with X. laevis, where hypomethylated sites are detectable in the spacer of somatic rDNA, but not in sperm. Thus the loss of spacer methylation that is seen in early development of X. laevis does not occur in X. borealis.

Sequence organization of the spacer in the ribosomal genes of Xenopus clivii and Xenopus borealis

We have studied in X. clivii and X. borealis cloned EcoRI fragments containing the spacer located between the 28S and 18S ribosomal genes. We report for these two species the nucleotide sequences at both ends of the NTS region with special emphasis on the sequences around the transcription initiation site of the 40S rRNA precursor. In X. clivii the location of the 5' end of the precursor was mapped. In both species the sequences around the 40S origin are duplicated in the NTS. Nucleotide sequence comparison has revealed a stretch of 13 identical bases around the transcription initiation site of X. laevis and X. clivii. The same sequence is also present at the presumptive transcription initiation site of X. borealis rDNA.

The nucleotide sequence of the intergenic region between the 5.8S and 26S rRNA genes of the yeast ribosomal RNA operon. Possible implications for the interaction between 5.8S and 26S rRNA and the processing of the primary transcript

We have determined the nucleotide sequence of part of a cloned yeast ribosomal RNA operon extending from the 5.8S RNA gene downstream into the 5' -terminal region of the 26S RNA gene. We mapped the pertinent processing sites, viz. the 5' end of 26S rRNA and the 3'ends of 5.8S rRNA and its immediate precursor, 7S RNA. At the 3' end of 7S RNA we find the sequence UCGUUU which is very similar to the type I consensus sequence UCAUUA/U present at the 3' ends of 17S, 5.8S and 26S rRNA as well as 18S precursor rRNA in yeast. At the 5' end of the 26S RNA gene we find a sequence of thirteen nucleotides which is homologous to the type II sequence present at the 5' termini of both the 17S and the 5.8S RNA gene. These findings further support the suggestion put forward earlier (G.M. Veldman et al. (1980) Nucl. Acids Res. 8, 2907-2920) that both consensus sequences are involved in the recognition of precursor rRNA by the processing nuclease(s). We discuss a model for the processing of yeast rRNA in which a processing enzyme sequentially recognizes several combinations of a type I and a type II consensus sequence. We also describe the existence of a significant base complementarity between sequences in the 5' -terminal region of 26S rRNA and the 3' -terminal region of 5.8S rRNA. We suggest that base pairing between these sequences contributes to the binding between 5.8S and 26S rRNA.

Sequence homologies between eukaryotic 5.8S rRNA and the 5' end of prokaryotic 23S rRNa: evidences for a common evolutionary origin

The question of the evolutionary origin of eukaryotic 5.8S rRNA was re-examined after the recent publication of the E. coli 23S rRNA sequence (26,40). A region of the 23S RNA located at its 5' end was found to be approximately 50% homologous to four different eukaryotic 5.8S rRNAs. A computer comparison analysis indicates that no other region of the E. coli ribosomal transcription unit (greater than 5 000 nucleotides in length) shares a comparable homology with 5.8S rRNA. Homology between the 5' end of e. coli 23S and four different eukaryotic 5.8S rRNAs falls within the same range as that between E. coli 5S RNA from the same four eukaryotic species. All these data strongly suggest that the 5' end of prokaryotic 23S rRNA and eukaryotic 5.8S RNA have a common evolutionary origin. Secondary structure models are proposed for the 5' region of E. coli 23S RNA.

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 construction, identification and partial characterization of plasmids containing guinea-pig milk protein complementary DNA sequences

A complementary DNA (cDNA) plasmid library has been constructed in the plasmid pAT153, using poly(A)-containing RNA isolated from the lactating guinea-pig mammary gland as the starting material. Double stranded cDNA was inserted into the EcoRI site of the plasmid using poly(dA . dT) tails, then transformed into Escherichia coli HB101. From the resulting colonies we have selected and partially characterized plasmids containing cDNA copies of the mRNAs for casein A, casein B, casein C and alpha-lactalbumin. However, the proportion containing casein C cDNA was exceptionally low, and these contained at best 60% of the mRNA sequence.

Binding of ribosomes to the 5' leader sequence (N = 258) of RNA 3 from alfalfa mosaic virus

RNA 3 of alfalfa mosaic virus (AlMV) contains information for two genes: near the 5' end an active gene coding for a 35 Kd protein and, near the 3' end, a silent gene coding for viral coat protein. We have determined a sequence of 318 nucleotides which contains the potential initiation codon for the 35 Kd protein at 258 nucleotides from the 5' end. This long leader sequence can form initiation complexes containing three 80 S ribosomes. A shorter species of RNA, corresponding to a molecule of RNA 3 lacking the cap and the first 154 nucleotides (RNA 3') has been isolated. The remaining leader sequence of 104 nucleotides in RNA 3' forms a single 80 S initiation complex with wheat germ ribosomes. The location of the regions of the leader sequence of RNA 3 involved in initiation complex formation with 80 S ribosomes is reported.

Nucleotide sequence through the 18S-28S intergene region of a vertebrate ribosomal transcription unit

We have determined the nucleotide sequence of part of a cloned ribosomal transcription unit from Xenopus laevis extending from the 3' region of the 18S gene through the 18S-28S intergene region into the start of the 28S gene. The 18S 3' region possess two tracts of high homology with the corresponding segments of other eukaryotic 18S genes (yeast and Bombyx mori) separated by a tract of low homology which in X. laevis is rich in G plus C. The first internal transcribed spacer, between the 18S and 5.8S genes, is 557 nucleotides long, very rich in G plus C (84%) and shows no sequence homology with the corresponding yeast sequence. The 5.8S rRNA sequence is revised slightly in the light of the DNA sequence. The second internal transcribed spacer, between the 5.8S and 28S genes, is 262 nucleotides long and is even richer in G plus C (88%) than the first internal spacer. 28S rRNA starts with the sequence pUCAG. This is encoded at the first of three closely linked TCAG sites in 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.

Chemical modification studies and the secondary structure of HeLa cell 5.8S rRNA

Various secondary structure models have been proposed for 5.8 S rRNA. In this paper HeLa cell 5.8 S rRNA is shown to possess several sites that are reactive to carbodiimide at 25 degrees, and other regions that are unreactive. Previous work has established the distribution of reactive and unreactive cytidine residues along the primary structure (11). The secondary structure model of Nazar et al. (7) is fully compatible with the chemical reactivity data whereas other models are partly incompatible. We conclude that the model of Nazar et al. provides the best approximation so far available to the conformation of isolated 5.8 S rRNA. Findings on the effect temperature on the chemical reactivity of different parts of the structure are summarized. The findings described in this paper should provide a basis for examining the specific interaction of 5.8 S rRNA with 28 s rRNA.

Multiple ribosomal gene sites revealed by in situ hybridization of Xenopus rDNA to Triturus lampbrush chromosomes

A variety of 3H-labelled ribosomal gene probes were hybridized in situ to the nascent transcripts of lampbrush chromosomes from the crested newt, Triturus cristatus carnifex. The probes were from Xenopus laevis and included rDNA isolated by CsCl gradient centrifugation, recombinant plasmids and purified restriction fragments of rDNA. All the probes gave essentially the same result. About 10-15 loop pairs were distinctly labelled in each preparation, almost all of them located on the heteromorphic arms (HTAs) of chromosome 1. Ribosomal gene probes were also hybridized in situ to the DNA of denatured mitotic chromosomes from some of the individuals used to provide lampbrush preparations. Minor, scattered sites of hybridization were found in the HTAs, but the main clusters of ribosomal genes were found on chromosomes 6 and/or 9, in agreement with previous determinations of nucleolus organizer position in this species. However, the nucleolus organizers were not sites of labelled loops in lampbrush transcript hybridizations.--We have incubated isolated lampbrush-stage nuclei in media containing alpha-amanitin and labelled RNA precursors. Although extrachromosomal nucleolar genes incorporated label, supposedly due to transcription by RNA polymerase I, no lampbrush loops were labelled.--It appears that in T. c. carnifex there are ribosomal gene sequences at the main nucleolus organizers and at a number of sites scattered along the HTAs. The ribosomal genes at the nucleolus organizers are not extended in the form of actively transcribing loops unlike the ribosomal sequences on the HTAs, which are heavily labelled in transcript hybridization. The ribosomal sequences on the HTAs appear not to be transcribed by the same RNA polymerase that transcribes the ribosomal genes of extrachromosomal nucleoli.

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.