Informational ribonucleoprotein particles of newt oocytes: polyribosome-associated ribonucleoproteins

Various species of rapidly labelled, informational ribonucleoproteins can be isolated from homogenates of newt oocytes. Polyribosome-associated ribonucleoprotein can be separated from heterogeneous nuclear ribonucleoprotein and free cytoplasmic ribonucleoprotein by sucrose gradient centrifugation. The polyribosome-associated ribonucleoprotein can be released from the ribosome complex by treatment with low concentrations of EDTA and has the following properties: 1. It is rapidly labelled with [3H]uridine under condition (incubation of oocytes for 4 h and less at 20 degrees C) where there is no detectable labelling of ribosomal subunits. 2. It is heterogeneous in size, consisting of particles most of which sediment between 40 S and 80 S. 3. Its sedimentation coefficient is related directly to the size of the polyribosomal complex from which it is derived. 4. Its density ranges from 1.35 g/cm3 to 1.55 g/cm3 irrespective of size. This indicates protein to RNA ratios of 4:1 to 2:1. 5. It is active, when complexed with ribosomes, in cell-free protein synthesis. It is concluded that this polyribosome-associated ribonucleoprotein is functional messenger and its role in oocyte maturation is discussed.     

Identification of a 60-kDa phosphoprotein that binds stored messenger RNA of Xenopus oocytes

Rapidly labelled, polyadenylated RNA is contained in three distinct fractions isolated from homogenized amphibian oocytes: (a) in ribonucleoprotein particles that are associated with a fibrillar matrix, the complexes sedimenting at greater than 1500S; (b) in ribonucleoprotein particles that sediment at 20-120S and have the characteristics of stored (maternal) messenger ribonucleoprotein (mRNP) and (c) in polyribosomes that sediment at 120-360S. We have compared the RNA and protein components of the first two of these RNP fractions. The polyadenylated RNA extracted from the two RNP fractions differs in that the RNA from fibril-associated RNP contains a much higher content of repeat sequences than does the RNA from mRNP. In other words, the RNA from fibril-associated RNP is largely unprocessed and may constitute a premessenger state, which for convenience is referred to as premessenger RNP (pre-mRNP). RNA-binding experiments demonstrate that the polypeptide most tightly bound in pre-mRNP is a 54-kDa component (p54), whereas the polypeptide most tightly bound in mRNP is a 60-kDa component (p60). Antibodies raised against p60 are used to show that this polypeptide is a common major component of pre-mRNP and mRNP and that it is also located in oocyte nuclei. However the state of p60 is modified between the premessenger and stored message levels: the polypeptide in mRNP is heavily phosphorylated whereas the equivalent polypeptide in pre-mRNP is completely unphosphorylated. The relative roles of the presence of repeat sequences and phosphorylation of mRNA-associated protein in blocking translation are discussed.     

Persistence of nonribosome bound 5 S RNA in full-grown oocytes of Xenopus laevis

The 4 and 5 S RNA containing 42 S ribonucleoprotein (RNP) particles characteristic of previtellogenic and white oocytes cannot be detected in full-grown oocytes. When full-grown oocyte RNPs are separated on sucrose gradients 4 and 5 S RNA cannot be detected in the 42 S region. However, not all of the 5 S RNA stored during early oogenesis is incorporated into ribosomes at later stages. A substantial pool (20% of the total) of 5 S RNA remains in a non-ribosome-bound fraction sedimenting at about 7 S in full-grown oocytes.     

RNA-binding proteins of Rana temporaria oocytes: incorporation into informosomes of oocytes in vivo]

The participation of RNA-binding protein in the formation of informosomes in vivo was studied using an intracellular microinjection technique. The RNA-binding protein of the frog Rana temporaria oocytes was isolated by affinity chromatography and was labelled in vitro without any loss of its activity. It was shown that during cultivation of the oocytes the specific incorporation of the injected RNA -- binding [3H]-protein into the ribonucleoprotein particles occurred. These particles were further described as informosomes, characteristic ribonucleoprotein particles of animal cells.     

Ribosomal and informational ribonucleoprotein complexes of animal cells. Study on rat liver ribonucleic acids as constituents of ribonucleoprotein complexes by chromatography on nucleoprotein-celite columns.

A novel method of RNA fractionation has been developed. Nuclear and cytoplasmic rat liver RNA species were fractionated as constituents of corresponding ribonucleoprotein particles, which were previously adsorbed on a Celite-column by their protein component. The fractionation is based on a dissociation of the particles (linear concentration gradient of LiCl and urea with subsequent temperature gradient), which results in a gradual release of the RNA molecules from ribonucleoprotein complexes. Thus the fractionation is in accordance with the tightness of the RNA-protein bonds. A gradient elution of RNA from a nucleoprotein-Celite column permitted fractionation of both ribosomal and rapidly labelled non-ribosomal RNA. The latter, both nuclear and cytoplasmic, could be separated by chromatography on nucleoprotein-Celite columns into two main fractions (components I and V). In cytoplasmic RNA components I and V presumably correspond to mlRNA (messenger-like RNA of free cytoplasmic particles) and mRNA (template RNA associated with ribosomes) respectively.     

An RNA-binding protein from Xenopus oocytes is associated with specific message sequences

Monoclonal antibodies directed against an RNA-binding protein from Xenopus oocytes were used to immunoselect messenger ribonucleoprotein (mRNP) particles. RNA was extracted from both the immunoselected and nonselected fractions and was used to direct the synthesis of oligo (dT)-primed 32P-cDNA. These two cDNA preparations were then used to probe Xenopus stage-1 oocyte cDNA libraries to identify sequences that had been specifically coimmunoselected by the antibodies. Three cDNA clones were shown to be derived specifically from the antibody-selected mRNPs. During very early oogenesis (stage 1-2), the RNA-binding protein and the three coselected mRNAs sediment in the nontranslating mRNP region of a sucrose gradient. By oocyte stage 6, the binding protein concentration decreases by as much as 22-fold relative to polyadenylated RNA. At this stage of development, the three mRNAs are found predominantly in the polysome region of a sucrose gradient. These data demonstrate that Xenopus oocytes contain an RNA-binding protein which binds specific message sequences and may regulate their expression.     

Characterization of ribonucleoprotein particles released from isolated nuclei of regenerating rat liver in two different in vitro systems.

The ribonucleoprotein particles released from isolated nuclei of regenerating rat liver in two in vitro systems were studied and the following results were obtained. 1. When the isolated nuclei of regenerating rat liver labeled in vivo with [14C] orotic acid were incubated in medium containing ATP and an energy-regenerating system (medium I) release of labeled 40-S particles was observed. Analysis of these 40-S particles showed that they contained heterogeneous RNA but no 18 S or 28 S ribosomal RNAs and their buoyant density in CsCl was 1.42-1.45 g/cm3, suggesting that they were nuclear informosome-like particles released during incubation. 2. When the same nuclei were incubated in the same medium fortified with dialyzed cytosol, spermidine and yeast RNA (medium II), release of labeled 60-S and 40-S particles was observed. Using CsCl buoyant density gradient centrifugation, two components were found in the labeled ribonucleoprotein particles released from nuclei in this medium. The labeled 60-S particles were found to contain 28-S RNA as the main component and their buoyant density in CsCl was 1.61 g/cm3, suggesting that they were labeled large ribosomal subunits. The labeled 40-S particles contained both 18 S RNA and heterogeneous RNA and they formed two discrete bands in CsCl, at 1.40 and 1.56 g/cm3, suggesting that they contained small ribosomal subunits and nuclear informosome-like particles. 3. These results clearly indicate that addition of dialyzed cytosol, spermidine and low molecular yeast RNA to medium I causes the release of ribosomal subunits or their precursors from isolated nuclei in the in vitro system.     

Properties of the RNA-component informosome from amphibian oocytes

RNA synthesis in in vivo ovulated oocytes of Rana temporaria frog was studied. It was shown that RNA synthesised during oocyte maturation is non-mitochondrial and is localized mostly in the ribonucleoprotein fraction; the bulk of the RNA is present in informosomes. The RNA extracted from informosomes shows a heterogeneous sedimentative distribution with predominant components of 19S and 26-27S. This RNA does not adsorb on oligo(dT)-cellulose columns.     

Small nuclear U-ribonucleoproteins in Xenopus laevis development. Uncoupled accumulation of the protein and RNA components

The accumulation of protein and RNA components of small nuclear U-ribonucleoprotein particles is non-co-ordinate during oogenesis and early embryogenesis in Xenopus laevis. Northern blot hybridization of a cloned Xenopus U2-RNA gene to oocyte and embryo RNAs demonstrates that the amount of small nuclear U2-RNA per oocyte reaches a plateau early in oogenesis (at the start of yolk deposition); further accumulation is not observed in oogenesis, nor in embryogenesis until the late blastula stage. In contrast, we show by immunoblot analysis that the proteins that bind to small nuclear U-RNAs continue to be accumulated after vitellogenesis begins, reaching maximum amounts only at the end of oocyte development. No further accumulation of these proteins is seen during embryogenesis. The consequences of this non-co-ordinate synthesis of small nuclear RNA and small nuclear RNA-binding proteins are as follows: a 10- to 20-fold excess of the protein components of the small ribonucleoprotein particles over small nuclear RNA exists in large oocytes; the bulk of the protein is cytoplasmic, while the RNA is nuclear. Thus the excess protein in the cytoplasm is uncomplexed with RNA. The imbalance between protein and RNA is not corrected until the late blastula or early gastrula stages of embryogenesis, when a tenfold increase in the amount of small nuclear U2-RNA is detected. Thus the protein, but not the RNA, components of small nuclear U-ribonucleoprotein particles are stockpiled in oocytes for later use in embryonic development. During the course of these studies, we also found that there are tissue-specific differences in the Sm-antigenic proteins of X. laevis.     

DNA fiber replication in chromosomes of a higher plant (Pisum sativum).

Ribosomal precursor particles were extracted from the yeast Saccharomyces carlsbergensis and analysed. After a brief labelling of yeast protoplasts with ³H-uridine, three basic ribonucleoprotein components were detected, sedimenting at approx. 90S, 66S and 43S in sucrose gradients containing magnesium. The 90S particles contained the 37S ribosomal precursor RNA as a major component and a small though variable amount of 29S ribosomal precursor RNA. The 66S and 43S particles contained 29S and 18S ribosomal precursor RNA, respectively. Kinetic data indicate a precursor-product relationship between the 90S particles and the two other ribonucleoprotein components, consistent with the conversion: 90S → 66S + 43S. The 90S and 66S preribosomes appeared to be present exclusively in the nucleus, whereas the 43S particles were mainly present in the cytoplasmic fraction. Apparently, the final maturation step in the formation of the 40S ribosomal subunits takes place in the cytoplasm. The 90S and 66S precursor particles have a relatively higher ratio of protein to RNA than the mature large ribosomal subunits, as judged from their buoyant densities in CsCl gradients. This finding suggests that also in a primitive eukaryotic organism, like yeast, ribosome maturation involves, in addition to a decrease in the size of the RNA components, an even stronger decrease in the amount of associated protein. In contrast, the 43S particles appeared to have the same buoyant density as the 40S ribosomal subunits.     

Ribonucleoprotein formation by the ORF1 protein of the non-LTR retrotransposon Tx1L in Xenopus oocytes.

The Tx1L elements constitute a family of site-specific non-LTR retrotransposons found in the genome of the frog Xenopus laevis . The elements have two open reading frames (ORFs) with homology to proteins of retroviruses and other retroelements. This study demonstrates an expected activity of one of the element-encoded proteins. The RNA binding properties of ORF1p, the product of the first ORF of Tx1L, were examined after expression from RNA injected into Xenopus oocytes. Using sucrose gradient sedimentation and non-denaturing gel electrophoresis, we show that ORF1p associates with RNA in cytoplasmic ribonucleoprotein (RNP) particles. Discrete RNPs are formed with well-defined mobilities. The ORF1p RNPs are distinct from endogenous RNPs that contain stored oocyte mRNAs and two specific endogenous mRNAs do not become associated with ORF1p. ORF1p appears to be capable of associating with its own mRNA and with other injected RNAs, independent of specific recognition sequences. Although nuclear localization of ORF1p was anticipated, based both on the supposed mechanism of transposition and on the presence of a potential nuclear localization signal, no significant fraction of the protein was found in the oocyte nucleus. Nonetheless, the RNA binding capability of ORF1p is consistent with the proposed model for transposition of non-LTR retrotransposons.     

An autoradiographic and cytophotometric study of oogenesis in a pulmonate snail,Planorbarius corneus

Summary The spatial and temporal patterns of macromolecular syntheses in oocytes and somatic auxiliary cells of the snail Planorbarius corneus have been investigated by autoradiography and cytophotometry. Oogenesis has been divided into three stages, comprising early meiosis up to diplotene (stage I), previtellogenetic growth phase (stage II), and vitellogenesis (stage III). No DNA synthesis was found in any oocyte stage. In stage-I oocytes, only nucleoli were found labelled with ³H-uridine. Oocyte nuclei of stage II and III actively synthesize RNA in nucleoli and chromosomes. The most intense incorporation of uridine in chromatin probably occurs during the previtellogenesis — vitellogenesis transition period during which cytological findings suggest well developed lampbrush chromosomes. RNA synthesis in amphinucleoli of stage-III oocytes is restricted to basophilic nucleolar parts, whereas acidophilic parts (protein bodies) neither synthesize nor store RNA. During vitellogenesis oocytes incorporate amino acids into yolk platelet proteins. Radioactive proteins are found in yolk platelet precursors 5 h after injection of the tracer and in yolk platelets 3 h thereafter. The labelling pattern suggests that oocytes synthesize certain hitherto unidentified yolk components. No evidence for the participation of follicle cells in synthesis and transport of vitellogenic proteins has been obtained from autoradiography. Cytological findings suggest an important role for these cells in oogenesis. They are highly active in RNA and protein synthesis. Cellular differentiation is accompanied by polyploidization of the nuclei which attain a highest DNA content of 256 c. Polyploidization probably occurs in incremental steps as indicated by complete endomitotic chromosomal cycles. Autoradiographs show that, during vitellogenesis, oocytes do not incorporate significant amounts of glucose, and only certain follicle cells were labelled with glucose, probably indicating the synthesis of glycogen.     

Inhibition of protein kinase C function by injection of intracellular receptors for the enzyme.

We tested the hypothesis that the translocation and function of protein kinase C (PKC) requires the binding of PKC to its intracellular receptors (RACKs), using insulin-induced maturation of Xenopus oocytes. We show that after exposure of oocytes to insulin, PKC translocated from the cytosol to the particulate fraction. PKC is also required for insulin-induced oocyte maturation: microinjection of a PKC inhibitory peptide delayed maturation. To determine whether translocation of PKC was a result of the binding of PKC to the RACKs in the particulate fraction, we microinjected purified rat brain RACKs into oocytes before insulin exposure. Microinjection of RACKs, but not inactive phosphorylated RACKS, inhibited PKC translocation and delayed oocyte maturation. These results suggest an in vivo role for RACKs in a function mediated by PKC.     

The course of the assembly of ribosomal subunits in yeast

The course of the assembly of the various ribosomal proteins of yeast into ribosomal particles has been studied by following the incorporation of radioactive individual protein species in cytoplasmic ribosomal particles after pulse-labelling of yeast protoplasts with tritiated amino acids. The pool of ribosomal proteins is small relative to the rate of ribosomal protein synthesis, and, therefore, does not affect essentially the appearance of labelled ribosomal proteins on the ribosomal particles. From the labelling kinetics of individual protein species it can be concluded that a number of ribosomal proteins of the 60 S subunit (L6, L7, L8, L9, L11, L15, L16, L23, L24, L30, L32, L36, L40, L41, L42, L44 and L45) associate with the ribonucleoprotein particles at a relatively late stage of the ribosomal maturation process. The same was found to be true for a number of proteins of the 40 S ribosomal subunit (S10, S27, S31, S32, S33 and S34). Several members (L7, L9, L24 and L30) of the late associating group of 60-S subunit proteins were found to be absent from a nuclear 66 S precursor ribosomal fraction. These results indicate that incorporation of these proteins into the ribosomal particles takes place in the cytoplasm at a late stage of the ribosomal maturation process.     

Ribosomal Precursors and Ribonucleic Acid Synthesis in Escherichia coli

Ribosomes and immature ribonucleoprotein particles were isolated from extracts of log-phase cells grown under various conditions. Quantitative measurements were made to determine the relative amounts of immature particles present in the extracts. The results indicate that the steady-state level of ribosomal precursors accounted for essentially a constant fraction of the total ribonucleic acid (RNA) of the cells. For cells with RNA-protein ratios between 0.43 and 0.65, about 1.6% of the total RNA occurred as immature ribonucleoprotein particles. Further, increased levels of immature particles were shown to be correlated with a reduced rate of RNA synthesis in cells recovering from chloramphenicol inhibition. The reduction was found to vary directly with the duration of pretreatment in chloramphenicol and, consequently, with the level of immature particles present in the cells.