Biochemical research on oogenesis. The storage particles of the teleost fish Tinca tinca

Oocytes ofTinca tinca and other Teleosts accumulate small and large molecules of RNA in noncoordinate fashion. Previtellogenic oocytes synthesize far less 28 S and 18 S RNA than tRNA and 5 S RNA, so that the latter molecules make up 50 to 90% of total RNA in these cells. As inXenopus laevis, tRNA and 5 S RNA made in excess by small oocytes ofT. tinca are stored in two kinds of nucleoprotein particles, sedimenting at 7 S and 42 S. In this paper we describe the biochemical and physical properties of the storage particles ofT. tinca. The 7 S particles are made up of one 5 S RNA and one 32,000 M_r protein (c). The molecular weight of this protein is lower by 8,000 than itsX. laevis counterpart. In contrast, the 42 S particles have the same size and composition inT. tinca andX. laevis. The 42 S particles of both species are made up of four subunits, each of which contains three molecules of tRNA, one molecule of 5 S RNA, two molecules of a 50,000-M_r protein (a), and one molecule of a 40,000-M_r protein (b). We present evidence showing that in the 42 S particles protein a is associated with tRNA, whereas protein b is associated with 5 S RNA, and suggesting that protein c is a cleavage product of protein b.     

Biochemical research on oogenesis: Oocytes of Xenopus laevis synthesize but do not accumulate 5S RNA of somatic type

The oocytes of amphibians and teleosts begin to accumulate 5S RNA several months before other components of the ribosomes become available. Two types of genes coding for 5S RNA are active during oogenesis of these animals. One type of genes is expressed only in oocytes. The other type is expressed in both oocytes and somatic cells. In this paper, we show that the oocytes of Xenopus laevis do not accumulate 5S RNA of somatic type. We conclude that the products of the two types of genes behave differently during oogenesis. One product is stored by the oocytes, whereas the other is not. The heterogeneity of 5S genes in Xenopus laevis might have arisen because oocytes and somatic cells needed different kinds of 5S RNA. These needs are met by molecules having different primary structures, different conformations, and different metabolic stabilities in vivo. We do not understand how these properties are related to one another.     

Evolution of the 5 S RNA genes in vertebrates

Summary We have built the phylogenetic tree of Vertebrate 5S RNA using the sequence data of thirteen species belonging to six groups. Evolution of the 5S genes has been very slow in Vertebrates since 90 residues are identical in all 5S RNAs which are presently sequenced.In Amphibians and Teleosts different 5S genes are active in oocytes and in somatic cells. This dual gene system has probably been acquired independently by Amphibians and Teleosts. In Amphibians, the oocyte-type 5S genes have evolved much faster than the somatic-type genes. This is not true in all species since the oocyte-type genes of one Teleost (Tinca tinca) have evolved more slowly than the somatic-type genes.There are in all Vertebrate 5S RNAs five complementary regions which can be base-paired. The sequence data are compatible with the three secondary-structure models that have been proposed for 5S RNA.     

Oocyte and somatic 5S ribosomal RNA and 5S RNA encoding genes in Xenopus tropicalis.

We have investigated the structure of oocyte and somatic 5S ribosomal RNA and of 5S RNA encoding genes in Xenopus tropicalis. The sequences of the two 5S RNA families differ in four positions, but only one of these substitutions, a C to U transition in position 79 within the internal control region of the corresponding 5S RNA encoding genes, is a distinguishing characteristic of all Xenopus somatic and oocyte 5S RNAs characterized to date, including those from Xenopus laevis and Xenopus borealis. 5S RNA genes in Xenopus tropicalis are organized in clusters of multiple repeats of a 264 base pair unit; the structural and functional organization of the Xenopus tropicalis oocyte 5S gene is similar to the somatic but distinct from the oocyte 5S DNA in Xenopus laevis and Xenopus borealis. A comparative sequence analysis reveals the presence of a strictly conserved pentamer motif AAAGT in the 5'-flanking region of Xenopus 5S genes which we demonstrate in a separate communication to serve as a binding signal for an upstream stimulatory factor.     

Inhibitor of ribosomal RNA synthesis in Xenopus laevis embryos: VI. Occurrence in mature oocytes and unfertilized eggs

Occurrence of a factor(s) which can selectively inhibit ribosomal RNA synthesis in isolated neurula cells of Xenopus laevis was examined in oocytes, unfertilized eggs, and embryos of Xenopus laevis. It was found that acid-soluble materials from full-sized oocytes, white-banded mature oocytes, unfertilized eggs, and pregastrular embryos were all active in significantly reducing the relative ratio of the [³H]uridine incorporation into 18S and 28S ribosomal RNA to that into 4S RNA from the control value. These results suggest that the inhibitor appears in the terminal step of oogenesis and, hence, may be assumed as a maternal regulator.     

L-bodies are RNA–protein condensates driving RNA localization in Xenopus oocytes

Ribonucleoprotein (RNP) granules are membraneless compartments within cells, formed by phase separation, that function as regulatory hubs for diverse biological processes. However, the mechanisms by which RNAs and proteins interact to promote RNP granule structure and function in vivo remain unclear. In Xenopus laevis oocytes, maternal mRNAs are localized as large RNPs to the vegetal hemisphere of the developing oocyte, where local translation is critical for proper embryonic patterning. Here we demonstrate that RNPs containing vegetally localized RNAs represent a new class of cytoplasmic RNP granule, termed localization-bodies (L-bodies). We show that L-bodies contain a dynamic protein-containing phase surrounding a nondynamic RNA-containing phase. Our results support a role for RNA as a critical component within these RNP granules and suggest that cis-elements within localized mRNAs may drive subcellular RNA localization through control over phase behavior.     

Very long-lived messenger RNA in ovaries of Xenopus laevis

It is possible to label with radioactivity newly synthesized ovarian RNA after intraperitoneal injection of [³H]guanosine and [³H]uridine into immature Xenopus laevis, if ovaries in which only previtellogenic stage 1 oocytes are present. Following the amount of radioactivity in the ovarian pool of acid-soluble precursors indicates a complete clearance of acid-soluble radioactivity within 15–20 days after injection. Incorporation of radioactivity into total RNA (which is almost exclusively 4 and 5S RNAs at this stage) and poly(A)⁺ RNA ceases between 15 and 20 days after injection, but the total amount of radioactivity in these RNA fractions does not decline appreciably over the next 18 months. During this time, the ovary grows and develops since stage 6 oocytes eventually appear and there is a 10- to 20-fold increase in total RNA content, which changes in composition from almost exclusively (95%) 4 and 5S RNAs to mainly (75%) 18 and 28S RNAs. Thus, despite continued growth and development, radioactive RNA molecules synthesized during previtellogenesis survive for lengths of time commensurate with the length of oogenesis (1–2 years). Although very limited (<7%) reincorporation of radioactivity into RNA is detected, it cannot alone account for the stability of the label in poly(A)⁺ RNA. These results are interpreted as indicative of synthesis during previtellogenesis of tRNA, 5SrRNA, and messenger RNA molecules which are very long-lived.     

Biochemical research on oogenesis. Comparison between the proteins of the ribosomes and the proteins of the 42 S particles from small oocytes of Xenopus laevis

Previtellogenic oocytes of Xenopus laevis synthesize large amounts of 5 S RNA and transfer RNA, but very little, if any, 28 S and 18 S RNA. About half of the RNA of these oocytes is stored in nucleoprotein particles sedimenting at 42 S. These particles contain 5 S RNA, transfer RNA, and several proteins, the function of which remains so far unknown.The proteins of the 42 S particles were analyzed by two-dimensional electrophoresis on polyacrylamide gel. The resulting fingerprints displayed one major and two minor basic spots. None of these coincided with any of the 37 spots produced by the 60 S subunit of the ribosomes and with the 30 spots produced by the 40 S subunit. We conclude that no ribosomal component other than 5 S RNA is present in the 42 S particles.The fingerprints of 40 S and 60 S ribosomal proteins from X. laevis coincided almost completely with the corresponding fingerprints from the rat and the rabbit.     

Biochemical studies of mammalian oogenesis: synthesis and stability of various classes of RNA during growth of the mouse oocyte in vitro

The synthesis of various classes of RNA in mouse oocytes at different stages of growth has been examined after incubating follicles in medium containing radiolabeled uridine. After fractionation on poly(U)-Sepharose of radiolabeled oocyte RNA, of which about 83% is associated with the nucleus after a 5-hr labeling period, revealed that about 40–50% of the radiolabeled RNA behaved as poly(A)-containing RNA. This value remained fairly constant during the period of oocyte growth in which oocyte diameter increased from about 35 to about 55 μm. After a 5-hr labeling, the percentage of radiolabeled poly(A)-containing RNA in either the fully grown dictyate oocyte, metaphase II oocyte, or one-cell embryo was about 20%. After a 5-hr labeling, agarose gel electrophoretic analysis of the radiolabeled species of oocyte RNA obtained after fractionation on poly(U)-Sepharose revealed the presence of a putative ribosomal RNA precursor, ribosomal (28 and 18 S) RNA, transfer plus 5 S RNA and heterodisperse poly(A)-containing RNA. A significant fraction of the radiolabeled RNA species was quite large (>40 S). The ratios of the relative proportions of the radiolabeled ribosomal RNAs and transfer plus 5 S RNA remained essentially constant during oocyte growth. The stability of various classes of RNA was examined by incubating follicles with radiolabeled uridine, washing the follicles free of radioactivity and culturing the follicles under conditions which support oocyte growth in vitro (Eppig, 1977). Under these conditions, total oocyte radiolabeled RNA was quite stable as determined by retention of acid-insoluble radioactive material ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 28}\text{days}$). However, under conditions in which oocytes are viable but do not grow, the half-life of total RNA was about 4.5 days. Poly(A)-containing RNA was also very stable; after 8 days in culture, about 50% of the radiolabeled poly(A)-containing RNA present after 5 hr of labeling was still present. Agarose gel electrophoretic analysis of radiolabeled RNA in oocytes after 4 days of culture and after fractionation on poly(U)-Sepharose revealed the presence of ribosomal (28 and 18 S) RNA, transfer plus 5 S RNA, and heterodisperse poly(A)-containing RNA. At this time, these RNAs are located in the oocyte cytoplasm. In addition, the molecular weight distribution of poly(A)-containing RNA was significantly lower than that after 5 hr of labeling. The ratios of the relative proportions of radiolabeled ribosomal RNAs and transfer plus 5 S RNA were quite similar to those after 5 hr of labeling.     

CONTROL OF 5S RNA SYNTHESIS DURING EARLY DEVELOPMENT OF ANUCLEOLATE AND PARTIAL NUCLEOLATE MUTANTS OF XENOPUS LAEVIS

Ribosomes of all eukaryotes contain a single molecule of 5S, 18S, and 28S RNA. In the frog Xenopus laevis the genes which code for 18S and 28S RNA are located in the nucleolar organizer, but these genes are not linked to the 5S RNA genes. Therefore the synthesis of the three ribosomal RNAs provides a model system for studying interchromosomal aspects of gene regulation. In order to determine if the synthesis of the three ribosomal RNAs are interdependent, the relative rate of 5S RNA synthesis was measured in anucleolate mutants (o/o), which do not synthesize any 18S or 28S RNA, and in partial nucleolate mutants (p^l-1/o), which synthesize 18S and 28S RNA at 25% of the normal rate. Since the o/o and p^l-1/o mutants have a complete and partial deletion of 18S and 28S RNA genes respectively, but the normal number of 5S RNA genes, they provide a unique system in which to study the dependence of 5S RNA synthesis on the synthesis of 18S and 28S RNA. Total RNA was extracted from embryos labeled during different stages of development and analyzed by polyacrylamide gel electrophoresis. Quite unexpectedly it was found that 5S RNA synthesis in o/o and p^l-1/o mutants proceeds at the same rate as it does in normal embryos. Furthermore, 5S RNA synthesis is initiated normally at gastrulation in o/o mutants in the complete absence of 18S and 28S RNA synthesis.     

A comparison of Xenopus laevis oocyte and embryo mRNA

Total RNA, extracted from mature oocytes and tadpoles of Xenopus laevis, was used as a template for in vitro protein synthesis. The oocyte RNA is markedly deficient in abundant mRNA species by comparison to tadpole RNA or other somatic RNAs, in agreement with previous experiments using RNA-cDNA hybridization analysis (S. Perlman and M. Rosbash, 1978, Develop. Biol.63, 197–212). Oocyte pA⁺ RNA is also larger than tadpole pA⁺ RNA or other somatic pA⁺ populations. The larger oocyte pA⁺ RNA and smaller oocyte pA⁺ RNA are equally good templates for in vitro protein synthesis, which implies that much, and perhaps all, of the large oocyte pA⁺ RNA is bona fide mRNA. We suggest that the relatively large size of the oocyte pA⁺ RNA population is due, at least in part, to the relative lack of abundant mRNA species in the population. This suggestion follows from the observation of 0. Meyuhas and R. P. Perry (1979, Cell16, 139–148) that L-cell-abundant mRNAs are preferentially small and rare mRNAs preferentially large. Most of the oocyte pA⁺ sequences are also present in tadpoles and are still adenylated at this stage. Oocyte proteins synthesized in vivo do not appear deficient in abundant proteins, suggesting that a translational control mechanism operates to select certain pA⁺ RNAs at higher frequencies than others.     

Polyadenylic acid-containing RNA in Xenopus laevis oocytes

The quantity of poly(A)-containing RNA is measured in Xenopus laevis oocytes as a function of developmental stage. The amount of poly(A)-containing RNA per oocyte, 0.7 to 1.0% of the total RNA, remains relatively constant from early vitellogenesis until ovulation. It is largely present in the cytoplasm of the oocyte in the form of a ribonucleoprotein complex. The poly(A) sequence is approximately 100 bases in length and is attached to molecules of heterogeneous sedimentation coefficients.