A reinvestigation of 5' leads to 3' polarity in 40S ribosomal RNA precursor of Xenopus laevis

An alternative molecular mechanism of action of 5-fluorouracil, a potent anticancer drug

It is assumed that the primary mode of action of 5-fluorouracil (5-FUra) is mediated via inhibition of thymidylate synthetase. Persistent inhibition of cellular proliferation after treatment of the 5-FUra-inhibited cells with exogenous thymidine do not support the notion that the anti-proliferitive action of 5-FUra is due exclusively to inhibition of DNA replication. Our studies have revealed an alternative mechanism of action at the level of pre-ribosomal RNA (pre-rRNA) processing. Pre-rRNA processing was inhibited completely in vitro as well as in S-100 extract from the mouse lymphosarcoma P1798 cells that were treated with 5-FUra. Under this condition, the 5-FUra-substituted pre-rRNA substrate was processed efficiently at the primary processing site. This study showed that the activity and/or the synthesis of a factor potentially involved in pre-rRNA processing is blocked in cells treated with the fluoropyrimidine. UV-cross-linking study showed that a 200 kDa polypeptide designated ribosomal RNA binding protein (RRBP) was absent in the S-100 extract from the drug-treated mouse lymphosarcoma cells. Since a polypeptide that cross-links to a processing site on RNA is usually involved in the RNA processing, RRBP may have a direct role in pre-rRNA processing. A key molecular mechanism far the antiproliferative action of 5-FUra may be due to its interference with the activity and/or synthesis of RRBP. Exposure of cells to 5-FUra did not inhibit the interaction between U3 small nucleolar RNA (snoRNA) and pre-rRNA at the primary processing site (a key step in the processing reaction) and the formation of U3 small nucleolar ribonucleoprotein (snoRNP). Treatment of cells with the fluoropyrimidine did not block the 3' end processing of pre-messenger RNA (pre-mRNA). This article also discusses the effects of 5-FUra on pre-mRNA splicing and mRNA translation, and proposes other avenues of research to explore further the mechanism of action of this important pyrimidine analog.

Sequence and structural elements critical for U8 snRNP function in Xenopus oocytes are evolutionarily conserved

We have generated mutants in Xenopus U8 RNA, a nucleolar snRNA required for the maturation of 5.8S and 28S rRNAs, to identify sequences and structural domains essential for RNA stability, particle assembly, and function of the U8 RNP. Activity of the mutants was assayed by microinjection of in vitro-synthesized U8 RNAs into the cytoplasm of Xenopus oocytes. Most of the mutant RNAs were stable, bound fibrillarin, a protein common to several of the nucleolar-specific snRNPs, and became hypermethylated. Although hypermethylation of the 5' cap of U8 RNA and fibrillarin binding can occur in either the cytoplasmic or nuclear compartment of Xenopus oocytes, neither is required for nuclear import. We find that the trimethylguanosine cap, although present on the endogenous U8 RNA, is not essential for stability, particle assembly, or functioning of U8 in the coordinate processing of pre-rRNA at sites 3' of 28S and 5' of 5.8S RNA. Several conserved single- and double-stranded sequences within the 5' domain of U8 RNA are essential for function.

Isolation of a herpes simplex virus type 1 mutant with a deletion in the virion host shutoff gene and identification of multiple forms of the vhs (UL41) polypeptide

The virion host shutoff (vhs) gene (UL41) of herpes simplex virus type 1 (HSV-1) encodes a virion component that induces degradation of host mRNAs and the shutoff of most host protein synthesis. Subsequently, the vhs protein accelerates the turnover of all kinetic classes of viral mRNA. To identify the vhs (UL41) polypeptide within infected cells and virions, antisera raised against a UL41-lacZ fusion protein were used to characterize the polypeptides encoded by wild-type HSV-1 and two mutants: vhs1, a previously characterized mutant that lacks detectable virion host shutoff activity, and vhs-delta Sma, a newly constructed mutant containing a deletion of 196 codons from UL41. Two forms of the vhs (UL41) polypeptide were identified in cells infected with the wild-type virus or vhs1. Wild-type HSV-1 produced a major 58-kDa polypeptide, as well as a less abundant 59.5-kDa form of the protein, while vhs1 produced 57- and 59-kDa polypeptides that were approximately equally abundant. Although for either virus, both forms of the protein were phosphorylated, they differed in the extent of phosphorylation. While both vhs polypeptides were found in infected cells, only the faster migrating, less phosphorylated form was incorporated into virions. vhs-delta Sma encoded a smaller, 31-kDa polypeptide which, although present in infected cells, was not incorporated into virions. The results identify multiple forms of the vhs (UL41) polypeptide and suggest that posttranslational processing affects its packaging into virions, as well as its ability to induce mRNA degradation.

Disruption of U8 nucleolar snRNA inhibits 5.8S and 28S rRNA processing in the Xenopus oocyte

The nucleoli of vertebrate cells contain several snRNPs, of which only one, U3, has been assigned a role in rRNA processing. We present the primary sequence of Xenopus U8, a fibrillarin-associated nucleolar snRNA, and examine its expression through oocyte development. Antisense deoxyoligonucleotides were microinjected into Xenopus oocytes to deplete the endogenous pool of U8 RNA. Analysis of the mature rRNAs and rRNA intermediates that accumulate in the U8-depleted oocytes indicate that the U8 snRNP is essential for correct maturation of the 5.8S and 28S rRNAs at both their 5' and 3' ends. U8 is therefore a nucleolar snRNA implicated in a nucleolytic rRNA processing step other than 18S maturation. Evidence for a long-lived 5.8S rRNA intermediate (12S) in Xenopus is also presented.

Hormonal regulation of adult type keratin gene expression in larval epidermal cells of the frog Xenopus laevis

Triiodothyronin (T3) is known to induce amphibian metamorphosis but other hormones such as glucocorticoids accelerate T3 action. The increase in plasma concentration of both T3 and glucocorticoids during metamorphic climax is correlated with the transformation of the epidermis from larval type (uncornified) to adult type (cornified). Previously we have shown that T3 induced adult-type 63 Kd keratin gene expression and cornification of the larval epidermis. In this study, we have examined the effects of T3 and hydrocortisone (HC) on the conversion of larval to adult epidermal cells in vitro. When larval epidermal cells were treated with both T3 and HC, they had a synergistic effect on adult-type keratin synthesis (both 63 Kd and 49 Kd keratins) and epidermal cornification. The synergistic effect between T3 and HC required a pretreatment with T3 for 3 days. During this time, addition of HC to cultures containing T3 did not change the amount of 63 Kd keratin mRNA. Thus, HC did not reduce the lag time for epidermal cells to respond to T3. After 4 days of hormone treatment, T3 increased the amount of 63 Kd keratin mRNA 9-fold while T3 and HC induced it 18-fold. When cultures were pretreated with T3 for 3 days, a 1 day treatment with HC was sufficient to obtain the synergistic effect. Thus the induction of 63 Kd keratin gene expression by T3 required a much longer lag (3 days) than the lag required for the synergistic action of T3 and HC (less than 1 day).(ABSTRACT TRUNCATED AT 250 WORDS)

In vitro mRNA degradation system to study the virion host shutoff function of herpes simplex virus

The virion host shutoff (vhs) gene of herpes simplex virus encodes a virion polypeptide that induces degradation of host mRNAs at early times and rapid turnover of viral mRNAs throughout infection. To better investigate the vhs function, an in vitro mRNA degradation system was developed, consisting of cytoplasmic extracts from HeLa cells infected with wild-type herpes simplex virus type 1 or a mutant encoding a defective vhs polypeptide. Host and viral mRNAs were degraded rapidly in extracts from cells productively infected with wild-type herpes simplex virus type 1 but not in extracts from mock-infected cells or cells infected with the mutant vhs1. In contrast, 28S rRNA was stable in all three kinds of extract. Accelerated turnover of host mRNAs was also observed in extracts from cells infected with wild-type virus in the presence of dactinomycin, indicating that the activity was induced by a structural component of the infecting virions. The in vitro vhs activity was inactivated by heat or proteinase K digestion but was insensitive to brief treatment of the extracts with micrococcal nuclease. It was not inhibited by placental RNase inhibitor, it exhibited a strong dependence upon added Mg2+, it was active at concentrations of K+ up to 200 mM, and it did not require the components of an energy-generating system. In summary, the in vitro mRNA degradation system appears to accurately reproduce the vhs-mediated decay of host and viral mRNAs and should be useful for studies of the mechanism of vhs action.

Dissection of the 16S rRNA binding site for ribosomal protein S4

The ribosomal protein S4 from Escherichia coli is essential for initiation of assembly of 30S ribosomal subunits. We have undertaken the identification of specific features required in the 16S rRNA for S4 recognition by synthesizing mutants bearing deletions within a 460 nucleotide region which contains the minimum S4 binding site. We made a set of large nested deletions in a subdomain of the molecule, as well as individual deletions of nine hairpins, and used a nitrocellulose filter binding assay to calculate association constants. Some small hairpins can be eliminated with only minor effects on S4 recognition, while three hairpins scattered throughout the domain (76-90, 376-389 and 456-476) are essential for specific interaction. The loop sequence of hairpin 456-476 is important for S4 binding, and may be directly recognized by the protein. Some of the essential features are in phylogenetically variable regions; consistent with this, Mycoplasma capricolum rRNA is only weakly recognized by S4, and no specific binding to Xenopus laevis rRNA can be detected.

Control of mRNA stability by the virion host shutoff function of herpes simplex virus

vhs1 is a mutant of herpes simplex virus type 1 that is defective in the virion host shutoff function responsible for the degradation of cellular mRNAs and the concomitant shutoff of host protein synthesis. In this study, the effect of the vhs1 mutation on the metabolism of viral mRNAs was examined by measuring the half-lives and patterns of accumulation of 10 different viral mRNAs representing all kinetic classes. The vhs1 mutation had the effect of dramatically lengthening the cytoplasmic half-lives of all 10 mRNAs. In wild-type virus infections, the 10 mRNAs had similar half-lives, suggesting that little, if any, target mRNA selectivity was exhibited by the vhs function. The vhs1 mutation caused overaccumulation of a number of mRNAs. The effect was most dramatic for the alpha (immediate-early) mRNA for ICP27 and the beta (early) mRNAs encoding thymidine kinase, ICP8, and DNA polymerase. Whereas in wild-type infections these mRNAs increased to peak levels and subsequently declined in abundance, in vhs1 infections they continued to accumulate until late times. A significant but less dramatic overaccumulation was observed for several beta-gamma (delayed-early) and gamma (late) mRNAs. The results suggest that the vhs protein plays an important role in determining the half-lives of viral mRNAs belonging to all kinetic classes and in so doing is important in the normal downregulation at late times of alpha and beta gene expression.

28 S ribosomal RNA in vertebrates. Locations of large-scale features revealed by electron microscopy in relation to other features of the sequences

The 28 S rRNA from several vertebrate species, when examined by electron microscopy, is seen to contain regions of extensive secondary structure, as first reported for HeLa-cell 28 S rRNA by Wellauer & Dawid [(1973) Proc. Natl. Acad. Sci. U.S.A. 70, 2827-2831]. Here we correlate the locations of these regions, determined from the electron-microscopic data, with the primary structure of 28 S rRNA from human, mouse and Xenopus laevis determined by sequence analysis of rDNA. The secondary-structure features observed by electron microscopy correspond closely to phylogenetically variable G + C-rich regions that largely comprise the eukaryotic expansion segments in these three species. In most if not all cases the features can be identified with long G + C-rich helices deduced from sequence data. Correlations are given between the locations of the secondary-structure features and several 'landmark' restriction sites in 28 S rDNA. By correlating the locations of the rRNA methyl groups reported elsewhere [Maden (1988) J. Mol. Biol. 201, 289-314] with the present findings it is concluded that the rRNA secondary-structure features revealed by electron microscopy are largely or wholly unmethylated.

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.

Heat-sensitive mutant strain of Neurospora crassa, 4M(t), conditionally defective in 25S ribosomal ribonucleic acid production

A heat-sensitive mutant strain of Neurospora crassa, 4M(t), was studied in an attempt to define its molecular lesion. The mutant strain is inhibited in conidial germination and mycelial extension at the nonpermissive temperature (37 degrees C). Macromolecular synthesis studies showed that both ribonucleic acid (RNA) and protein syntheses are inhibited when 4-h cultures are shifted from 20 to 37 degrees C. Density gradient analysis of ribosomal subunits made at 37 degrees C indicated that strain 4M(t) is deficient in the accumulation of 60S ribosomal subunits in that the ratio of 60S/37S subunits was 0.29:1 compared with 1.6:1 for the parental strain. This phenotype was shown to be the result of a slow rate of processing of, and a deficiency in the amount of, the immediate precursor to 25S ribosomal RNA (the large RNA of the 60S subunit) in the sequence of events constituting the production of mature ribosomal RNAs from the primary transcript of the ribosomal deoxyribonucleic acid, the precursor ribosomal RNA molecule. Analysis of polysomes suggested that the heat-sensitive gene product might function in both the assembly and the function of the 60S ribosomal subunit, since there was a smaller proportion of newly made 60S subunits synthesized at 37 degrees C in the polysome region of the gradients than in the monosome-plus-subunit region. The ribosomal RNA processing defect is apparently responsible for the observed defects in germination and macromolecular synthesis at 37 degrees C, but the precise molecular lesion is not known. On the basis of these results, the heat-sensitive mutant allele in the 4M(t) strain is considered to define the rip1 (ribosome production) gene locus.

Thyroid hormone induction of keratin genes: a two-step activation of gene expression during development

To determine the mechanism of action of the thyroid hormone triiodothyronine (T3) during metamorphosis of the amphibian epidermis, we have investigated the developmental activation of the 63-kD keratin genes in the frog Xenopus laevis. These genes code for three closely related keratins that first appear in the larval epidermis and accumulate during metamorphosis to become the most abundant proteins in the adult epidermis. We report here that the 63-kD keratins and their mRNAs first appear at stages 48-52. The level of 63-kD keratin gene expression remains relatively low until stage 56 and then increases dramatically. Quantitative analysis of the concentration of 63-kD keratin mRNA demonstrates low levels until stage 55/56, followed by an increase greater than 300-fold from stage 55/56 to the adult. Each adult cell contains approximately 55,000 molecules of the 63-kD keratin mRNAs. T3 is not required for the initial activation of the 63-kD keratin genes, but high-level expression is absolutely dependent on T3. High-level expression is prevented by propylthiouracil, which inhibits thyroid hormone synthesis and can be induced precociously both in vivo and in vitro with exogenous T3 as early as stage 48, but not prior to that time. Thus, the full activation of the 63-kD keratin genes during development requires two regulatory steps, one independent and one dependent on T3.

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.

Length polymorphism in rDNA indicates somatic alterations in the genome of Triturus vulgaris

We have analyzed the EcoRI restriction pattern of ribosomal genes (rDNA) isolated from several organs of single individuals of the newt Triturus vulgaris by Southern blotting and hybridization with corresponding Xenopus probes (r11 and r12). Using length polymorphism of rDNA spacers as a molecular marker, it became evident that in individual newts the pattern of ribosomal genes is not always constant but varies between different tissues of the same animal suggesting the occurrence of genome alterations during ontogenesis.

Identification and cloning of localized maternal RNAs from Xenopus eggs

A central question in developmental biology is to explain how cells in different regions of an embryo acquire different developmental fates. We have begun to address this question by investigating whether specific RNAs are localized within a frog egg. Differential screening of a cDNA library shows that most maternal RNAs are uniformly distributed along the animal-vegetal axis. However, we find that a rare class of maternal RNAs is localized. cDNA clones of four localized RNAs have been characterized. Three of these cDNAs are derived from maternal RNAs that are concentrated in the animal hemisphere of unfertilized eggs and remain localized through the early blastula stage. One cDNA is derived from a maternal RNA found almost exclusively in the vegetal hemisphere at both stages. These studies show that some informational molecules, specifically RNAs, are localized in eggs and are inherited by particular blastomeres.

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.

Isolation and properties of a single-strand 5'----3' exoribonuclease from Ehrlich ascites tumor cell nucleoli

A single-strand-specific, nucleolar exoribonuclease from Ehrlich ascites tumor cells has been isolated and purified free from other nucleases. The exonuclease degraded single-stranded RNA processively from either a 5'-hydroxyl or a 5'-phosphorylated end and released 5'-mononucleotides. The enzyme digested single-strand poly(C), poly(U), and poly(A) equally well but did not degrade duplex poly(C).poly(I) or poly(A).poly(U). Less than 0.2% of duplex DNA or 1.5% of heat-denatured DNA was degraded under the conditions which resulted in greater than 26% degradation of RNA. The ribonuclease required Mg2+ (0.2 mM) for optimum activity and was inhibited by ethylenediaminetetraacetic acid but not by human placental RNase inhibitor. The native enzyme had a Stokes radius of 42 A and a sedimentation coefficient (S20,w) of 4.3 S. From these values, an apparent molecular weight of 76 000 was derived by using the Svedberg equation. The localization and unique mode of degradation suggest a role for the 5'----3' exoribonuclease in ribosomal RNA processing.

Xenopus laevis 28S ribosomal RNA: a secondary structure model and its evolutionary and functional implications

Based upon the three experimentally derived models of E. coli 23S rRNA (1-3) and the partial model for yeast 26S rRNA (4), which was deduced by homology to E. coli, we derived a secondary structure model for Xenopus laevis 28S rRNA. This is the first complete model presented for eukaryotic 28S rRNA. Compensatory base changes support the general validity of our model and offer help to resolve which of the three E. coli models is correct in regions where they are different from one another. Eukaryotic rDNA is longer than prokaryotic rDNA by virtue of introns, expansion segments and transcribed spacers, all of which are discussed relative to our secondary structure model. Comments are made on the evolutionary origins of these three categories and the processing fates of their transcripts. Functionally important sites on our 28S rRNA secondary structure model are suggested by analogy for ribosomal protein binding, the GTPase center, the peptidyl transferase center, and for rRNA interaction with tRNA and 5S RNA. We discuss how RNA-RNA interactions may play a vital role in translocation.

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.

Chromatin structure of Xenopus rDNA transcription termination sites. Evidence for a two-step process of transcription termination

The ultrastructure of Xenopus laevis (X.l.) 40S pre-rRNA transcription termination sites was investigated by electron microscopy. Amplified nucleolar chromatin was rapidly dispersed and processed for chromatin spread preparations. This type of preparation revealed that many rDNA termination sites appeared as 50 nm long segments of chromatin axis covered by a complex of three closely spaced RNA polymerase particles. Particle (Ptl) was characterized by the association with the terminal full-length pre-rRNP fibril; particles (Pt2) and (Pt3) are located downstream from (Ptl) and appear to be devoid of transcript fibrils. This particular structural arrangement as well as sequence homology analyses of 3' adjacent spacer rDNA segments indicate that transcript release and dissociation of polymerase particles are not necessarily coupled and termination of X.l. rDNA transcription may occur as a two step process. The structural data are correlated with homologies of DNA sequences at Xenopus rDNA transcription termination regions and are discussed with respect to sequence data of 3' termination sites of rRNA genes from other species.

Ribosomal RNA sequence conservation and gene number in the larval brine shrimp

The haploid genome size of Artemia is determined to be about 0.9 X 10(12), as evidenced both by Feulgen microspectrophotometry of individual diploid class nuclei, which are but one of five polyploid classes present within the larvae, and by analysis of the reassociation kinetics of the isolated single copy DNA component. Polysomes isolated from 24-h incubation stage larvae contain an average of 10 ribosomes per messenger RNA molecule. Their rRNAs are found to have sedimentation coefficients of 18 S and 26 S, corresponding to molecular weights of 0.70 X 10(6) and 1.40 X 10(6), respectively, as determined by polyacrylamide electrophoresis and also by sucrose density centrifugation. Denaturation in glyoxal followed by agarose gel electrophoresis shows that unlike deuterostome rRNAs, Artemia 26 S rRNA contains a cryptic nick about midway in the molecule, which is not found in the 18 S molecule. Isolated rRNAs were labelled in vitro with 125I and hybridized with filter-immobilized DNA to saturation, which occurred at 0.051% for Xenopus, and at 0.074% for Artemia. From these results, it is calculated that in the haploid Artemia genome there are about 320 copies of the (18 S + 26 S) ribosomal RNA genes. Reciprocal heterologous hybridizations between these two species show that they share about 30% homology between their rDNA coding sequences.

Origin of replication from Xenopus laevis mitochondrial DNA promotes high-frequency transformation of yeast

A specific fraction of chromosomal DNA from both yeast and a wide variety of other eukaryotes, but not from Escherichia coli, promotes high-frequency transformation in yeast. The plasmids containing these sequences are maintained as extra-chromosomal molecules in transformed cells. These results suggest that similar or identical sequences are used for the initiation of DNA replication in eukaryotes. To test this hypothesis, several foreign eukaryotic DNAs implicated directly or indirectly in the initiation of DNA replication have been examined for their ability to promote autonomous, extrachromosomal replication in yeast. Simian virus 40 DNA, amplified Xenopus laevis ribosomal DNA, X. laevis 5S ribosomal DNA, X. laevis mtDNA, and five different members of the Alu I family of human middle repetitive DNAs were cloned into the vector YIp5 and used to transform yeast. Of these DNAs, only Xenopus mtDNA promoted high-frequency transformation and extrachromosomal maintenance of YIp5 DNA. A 2.2-kilobase EcoRI fragment from the 17.4-kilobase mtDNA molecule was responsible for these activities. This fragment contains the sequence used for the initiation of replication in Xenopus mitochondria.

Heat-sensitive mutant strain of Neurospora crassa, 4M(t), conditionally defective in 25S ribosomal ribonucleic acid production

A heat-sensitive mutant strain of Neurospora crassa, 4M(t), was studied in an attempt to define its molecular lesion. The mutant strain is inhibited in conidial germination and mycelial extension at the nonpermissive temperature (37 degrees C). Macromolecular synthesis studies showed that both ribonucleic acid (RNA) and protein syntheses are inhibited when 4-h cultures are shifted from 20 to 37 degrees C. Density gradient analysis of ribosomal subunits made at 37 degrees C indicated that strain 4M(t) is deficient in the accumulation of 60S ribosomal subunits in that the ratio of 60S/37S subunits was 0.29:1 compared with 1.6:1 for the parental strain. This phenotype was shown to be the result of a slow rate of processing of, and a deficiency in the amount of, the immediate precursor to 25S ribosomal RNA (the large RNA of the 60S subunit) in the sequence of events constituting the production of mature ribosomal RNAs from the primary transcript of the ribosomal deoxyribonucleic acid, the precursor ribosomal RNA molecule. Analysis of polysomes suggested that the heat-sensitive gene product might function in both the assembly and the function of the 60S ribosomal subunit, since there was a smaller proportion of newly made 60S subunits synthesized at 37 degrees C in the polysome region of the gradients than in the monosome-plus-subunit region. The ribosomal RNA processing defect is apparently responsible for the observed defects in germination and macromolecular synthesis at 37 degrees C, but the precise molecular lesion is not known. On the basis of these results, the heat-sensitive mutant allele in the 4M(t) strain is considered to define the rip1 (ribosome production) gene locus.

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.

Precise localization and nucleotide sequence of the two mouse mitochondrial rRNA genes and three immediately adjacent novel tRNA genes

The complete DNA sequence of the ribosomal RNA region of mouse L cell mitochondrial DNA has been determined. Genes for the small (12S) and large (16S) rRNAs have been precisely located by direct sequencing of the termini of the two mature rRNAs. A comparison of the lengths (956 and 1582 nucleotides) and terminal sequences of the mature rRNAs with the DNA coding sequences indicates that mouse mt rRNAs are not spliced. Computer analysis of the complete DNA sequence has identified three potential transfer RNA genes. A gene for phenylalanine tRNA is located immediately adjacent to the 5' end of the 12S rRNA gene, a valine tRNA gene occupies the entire region between the 12S and 16S rRNA genes and a leucine tRNA gene is located immediately adjacent to the 3' end of the 16S gene. Hybridization of 32P-labeled, tRNA-sized mtRNA to selected DNA restriction endonuclease fragments from the rRNA region confirms the existence of small, abundant mtRNAs transcribed from these DNA sequences. All three tRNA genes and both rRNA genes are transcribed from the heavy strand of mtDNA. The mt rRNA sequences exhibit notable homologies to other rRNAs and, in particular, to those of E. coli. Within the 3' terminal 50 nucleotides, the mouse mt 12S rRNA contains a potential 10 bp hairpin structure and a sequence of 15 consecutive nucleotides common to the RNA of the small ribosomal subunit in all systems, but does not contain the mRNA binding site (ACCUCC) found in E. coli and corn chloroplast rRNAs. The mt tRNA genes do not have the 3' terminal CCA sequence encoded in the DNA, nor do they contain any intervening sequences. Two of the three tRNSa would lack many features which are known to be strictly conserved in all other nonorganelle tRNAs which have been sequenced. The fact that all the genes in this region are directly contiguous with at most one intervening nucleotide suggests that the entire region is transcribed into a polycistronic precursor RNA which is processed by endonucleolytic cleavages. The organization of the genes of the rRNA operon of mouse mtDNA, when compared to the organization of rRNA and tRNA genes in bacterial or eucaryotic nuclear genomes, provides evidence for the endosymbiotic hypothesis of the biogenesis of mammalian mitochondria.

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.

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.

Distribution of sequences common to the 25--28S-ribonucleic acid genes of Xenopus laevis and Neurospora crassa

The extent of homology between the nucleotide sequence of L-rRNA (the major RNA component of the larger ribosomal subparticle) of a lower eukaryote (Neurospora crassa) and an amphibian (Xenopus laevis) was investigated by utilizing rDNA (DNA coding for rRNA) of X. laevis cloned in plasmids pMB9 and pML2, and rDNA of N. crassa cloned in bacteriophage lambda. Hybridization studies revealed that sequences common to both N. crassa and X. laevis L-rRNA comprise a total of approx. 1050 /+- 200 nucleotides. The thermal stability of the X. laevis rDNA.N. crassa L-rRNA hybrid was 5 degrees C lower than that of the X. laevis rDNA.X. laevis L-rRNA duplex, indicating the presence of fewer than 10% mismatches in homologous sequences. X. laevis rDNA was analysed by means of restriction endonucleases and hybridization with 125I-labelled N. crassa L-rRNA. Most (at least 95%) of the conserved sequences were present in a 3000-base-pair fragment produced by restriction with endonucleases HindIII and BamHI. This fragment, which includes the 3'-OH terminus of the L-rRNA-coding region, was used as an adaptor in the construction of a bacteriophage-lambda recombinant. One section of the recombinant phage terminating in a HindIII-specific site was obtained from bacteriophage lambda plac5 (after restriction with endonuclease HindIII). A second section terminating in a BamHi-specific site was obtained from bacteriophage lambda 540 (after restriction with endonuclease BamHI). These two parts were joined by means of the X. laevis rDNA fragment. Further analysis of cloned rDNA by means of restriction endonucleases confirmed that conserved sequences were widely distributed throughout the 3000-base-pair fragment produced by HindIII and BamHi endonucleases. A 3400-base-pair fragment of N. crassa rDNA cloned in a bacteriophage lambda [Cox & Peden (1979) Mol. Gen. Genet. 174, 17--24] was restricted with endonucleases. The products were hybridized with 125I-labelled X. laevis L-rRNA. Conserved sequences were shown to be distributed over a range of approx. 1600--2700 base-pairs. Hence, in neither X. laevis nor N. crassa L-rRNA can be conserved sequences from a single block; instead regions of high and low (or no) homology must be intermingled. Both N. crassa rDNA and X. laevis rDNA were found to hybridize with Drosophila melanogaster L-rDNA sequences. Those rDNA fragments with sequences common to X. laevis and N. crassa L-rRNA also hybridized with D. melanogaster L-rRNA probe. Thus the same set of conserved sequences may be present in all three species.

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.

Characterization of mouse ribosomal gene fragments purified by molecular cloning

Four mouse ribosomal gene fragments cloned in lambda gtWES were studied by restriction enzyme mapping and Southern transfer experiments. These fragments were found to contain 18S DNA and transcribed as well as non-transcribed spacer DNA. Variation in the structure of these mouse DNA inserts was limited to one region of spacer DNA. This variation may reflect real structural differences found in mouse ribosomal genes or possibly deletion events which occurred during cloning. The transcribed regions of the inserts appear identical to one antoher and restriction enzyme fragments from this region correspond to fragments observed in digests of total mouse DNA. These clones will be useful in studying the structure of transcribed spacer DNA including the ribosomal gene promoter.

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.

Size and secondary structure of avian myeloblastosis virus associated ribosomal RNA: comparison with cellular and precursor ribosomal RNA

Ribosomal RNA isolated from ribosomes present inside avian myeloblastosis virus (AMV) was characterized by electron microscopy using the formamide-urea spreading technique. The molecular weight and the secondary structures were compared with those of r-RNA and precursor r-NA isolated from host cells, the leukemic myeloblasts. The molecular weight of viral r-RNA (1.62 +/- 0.18 X 10(6) and 0.69 +/- 0.10 X 10(6)) and the molecular weight of cellular r-RNA (1.63 +/- 0.18 X 10(6) and 0.67 +/- 0.09 X 10(6)), the latter obtained from avian myeloblasts, were found to be identical and comparable with the molecular weight of chicken liver r-RNA. Likewise, the secondary structures of viral r-RNA were identical to those of cellular r-RNA. The postulated possible precursor character of viral r-RNA was excluded, since the molecules of viral r-RNA do not show any similarity to those of precursor r-RNA. Previously observed differences in behavior of viral and cellular (myeloblastic) r-RNA in sedimentation and electrophoretic mobility are discussed.

Electron-microscopic demonstration of terminal and internal initiation sites for cDNA synthesis on vitellogenin mRNA

cDNA synthesized on purified vitellogenin mRNA from Xenopus liver was hybridized to the template in formamide/urea at 22 degrees C to avoid degradation of the RNA. The hybrids formed were visualized by spreading for electron microscopy. Contour length measurements proved that most of the RNA molecules in the hybrids were still intact showing the expected molecular weight of 2.3 x 10(6). The hybridized cDNA corresponded on the average to 12% of the RNA length. In about 80% of the molecules the cDNA was located at one end. Since cDNA synthesis was primed by oligo(dT), the terminal duplex region marks the 3' end of the vitellogenin mRNA molecule. Internal duplex regions were mainly located at a specific position starting about 2800 nucleotides from the 3' end. Since the cDNA hybridizing at the internal position could specifically be synthesized on a vitellogenin RNA fragment isolated on poly(U)-Sepharose as an oligo(A)-containing RNA, we conclude that cDNA synthesis is not only initiated by the poly(A) of the 3' end, but also by a specific internal sequence.