Regulation of protein synthesis and accumulation during oogenesis in Xenopus laevis

Ribosome RNA Profiling to Quantify Ovarian Development and Identify Sex in Fish

Terminologies of ovary development, by somewhat subjective describing and naming main changes of oocytes, have been criticized for confusing and inconsistency of terms and classifications, and the incurred consequences impede communication among researchers. In the present work, we developed regression between ovary development and three ribosome RNA (rRNA) indexes, namely 5S rRNA percent, 18S rRNA percent, and 5S–18S rRNA ratio, using close relationship between volume percent of primary growth stage oocytes or gonadosomatic index and rRNA content, demonstrating species-specific quantification of ovary development can be established in species with either synchronous and asynchronous oogenesis. This approach may be extended to any species with primary growth oocytes, e.g. anurans and reptiles, to predict maturity stages in females. We further confirmed that 5S rRNA percent and 5S/18S rRNA ratio can serve as markers to distinguish sexes unambiguously. A micro-invasive sampling method may be invented for non-lethal prediction of ovary development and sex because only a small amount of ovary sample (<50 mg) is needed for the approach established in the current work. Researchers who work with ovary RNA-seq in these taxa should realize that insufficient depletion of rRNA will probably lead to incorrect quantification of gene expression and inaccurate conclusions.

Linking maternal and somatic 5S rRNA types with different sequence-specific non-LTR retrotransposons

5S rRNA is a ribosomal core component, transcribed from many gene copies organized in genomic repeats. Some eukaryotic species have two 5S rRNA types defined by their predominant expression in oogenesis or adult tissue. Our next-generation sequencing study on zebrafish egg, embryo, and adult tissue identified maternal-type 5S rRNA that is exclusively accumulated during oogenesis, replaced throughout the embryogenesis by a somatic-type, and thus virtually absent in adult somatic tissue. The maternal-type 5S rDNA contains several thousands of gene copies on chromosome 4 in tandem repeats with small intergenic regions, whereas the somatic-type is present in only 12 gene copies on chromosome 18 with large intergenic regions. The nine-nucleotide variation between the two 5S rRNA types likely affects TFIII binding and riboprotein L5 binding, probably leading to storage of maternal-type rRNA. Remarkably, these sequence differences are located exactly at the sequence-specific target site for genome integration by the 5S rRNA-specific Mutsu retrotransposon family. Thus, we could define maternal- and somatic-type MutsuDr subfamilies. Furthermore, we identified four additional maternal-type and two new somatic-type MutsuDr subfamilies, each with their own target sequence. This target-site specificity, frequently intact maternal-type retrotransposon elements, plus specific presence of Mutsu retrotransposon RNA and piRNA in egg and adult tissue, suggest an involvement of retrotransposons in achieving the differential copy number of the two types of 5S rDNA loci.

The Scd6/Lsm14 protein xRAPB has properties different from RAP55 in selecting mRNA for early translation or intracellular distribution in Xenopus oocytes

Oocytes accumulate mRNAs in the form of maternal ribonucleoprotein (RNP) particles, the protein components of which determine the location and stability of individual mRNAs prior to translation. Scd6/Lsm14 proteins, typified by RAP55, function in a wide range of eukaryotes in repressing translation and relocating mRNPs to processing bodies and stress granules. In Xenopus laevis, the RAP55 orthologue xRAPA fulfils these functions. Here we describe the properties of a variant of xRAPA, xRAPB, which is a member of the Lsm14B group. xRAPB differs from xRAPA in various respects: it is expressed at high concentration earlier in oogenesis; it interacts specifically with the DDX6 helicase Xp54; it is detected in polysomes and stalled translation initiation complexes; its over-expression leads to selective binding to translatable mRNA species without evidence of translation repression or mRNA degradation. Since both Xp54 and xRAPA are repressors of translation, activation appears to be effected through targeting of xRAPB/Xp54.

CDNA cloning and characterization of S6 kinase and its effect on yolk protein gene expression in the oriental fruit fly Bactrocera dorsalis (Hendel)

p70 S6 kinase (S6K), a serine/threonine protein kinase, is a downstream target of target of rapamycin (TOR) gene and an important regulator of protein synthesis responsible for cell growth and reproduction. In this study, a S6K gene, named BdS6K (GenBank Accession No. GQ203802), was isolated from the oriental fruit fly Bactrocera dorsalis (Hendel). Quantitative RT-PCR showed that BdS6K mRNA is expressed at a higher level in egg than in other developmental stages, as well as in ovary than in fat body. Downregulation of BdS6K activity by rapamycin treatment in larval stage resulted in the developmental defects of larvae, pupae, and adults, with a reduced yolk protein (YP) expression in the fat body throughout the first reproductive cycle with a substantial reduction in ovary size, and also repressed the egg development in female fruit fly. Knockdown of BdS6K gene by RNA interference in the adult significantly decreased the YP expression. These observations support the involvement of BdS6K signaling in the regulation of the YP synthesis and egg development in B. dorsalis.

p70(S6K) controls selective mRNA translation during oocyte maturation and early embryogenesis in Xenopus laevis

In mammalian cells, p70(S6K) plays a key role in translational control of cell proliferation in response to growth factors. Because of the reliance on translational control in early vertebrate development, we cloned a Xenopus homolog of p70(S6K) and investigated the activity profile of p70(S6K) during Xenopus oocyte maturation and early embryogenesis. p70(S6K) activity is high in resting oocytes and decreases to background levels upon stimulation of maturation with progesterone. During embryonic development, three peaks of activity were observed: immediately after fertilization, shortly before the midblastula transition, and during gastrulation. Rapamycin, an inhibitor of p70(S6K) activation, caused oocytes to undergo germinal vesicle breakdown earlier than control oocytes, and sensitivity to progesterone was increased. Injection of a rapamycin-insensitive, constitutively active mutant of p70(S6K) reversed the effects of rapamycin. However, increases in S6 phosphorylation were not significantly affected by rapamycin during maturation. mos mRNA, which does not contain a 5'-terminal oligopyrimidine tract (5'-TOP), was translated earlier, and a larger amount of Mos protein was produced in rapamycin-treated oocytes. In fertilized eggs rapamycin treatment increased the translation of the Cdc25A phosphatase, which lacks a 5'-TOP. Translation assays in vivo using both DNA and RNA reporter constructs with the 5'-TOP from elongation factor 2 showed decreased translational activity with rapamycin, whereas constructs without a 5'-TOP or with an internal ribosome entry site were translated more efficiently upon rapamycin treatment. These results suggest that changes in p70(S6K) activity during oocyte maturation and early embryogenesis selectively alter the translational capacity available for mRNAs lacking a 5'-TOP region.

RNA transport

RNA molecules synthesized in the nucleus are transported to their sites of function throughout the eukaryotic cell by specific transport pathways. This review focuses on transport of messenger RNA, small nuclear RNA, ribosomal RNA, and transfer RNA between the nucleus and the cytoplasm. The general molecular mechanisms involved in nucleocytoplasmic transport of RNA are only beginning to be understood. However, during the past few years, substantial progress has been made. A major theme that emerges from recent studies of RNA transport is that specific signals mediate the transport of each class of RNA, and these signals are provided largely by the specific proteins with which each RNA is associated.

RNA-protein interactions of stored 5S RNA with TFIIIA and ribosomal protein L5 during Xenopus oogenesis

We studied the pathway of 5S RNA during oogenesis in Xenopus laevis from its storage in the cytoplasm to accumulation in the nucleus, the sequence requirements for the 5S RNA to follow that pathway, and the 5S RNA-protein interactions that occur during the mobilization of stored 5S RNA for assembly into ribosomes. In situ hybridization to sections of oocytes indicates that 5S RNA first becomes associated with the amplified nucleoli during vitellogenesis when the nucleoli are activity synthesizing ribosomal RNA and assembling ribosomes. When labeled 5S RNA is microinjected into the cytoplasm of stage V oocytes, it migrates into the nucleus, whether microinjected naked or complexed with the protein TFIIIA as a 7S RNP storage particle. During vitellogenesis, a nonribosome bound pool of 5S RNA complexed with ribosomal protein L5 (5S RNPs) is formed, which is present throughout the remainder of oogenesis. Immunoprecipitation assays on homogenates of microinjected oocytes showed that labeled 5S RNA can become complexed either with L5 or with TFIIIA. Nucleotides 11 through 108 of the 5S RNA molecule provide the necessary sequence and conformational information required for the formation of immunologically detectable complexes with TFIIIA or L5 and for nuclear accumulation. Furthermore, labeled 5S RNA from microinjected 7S RNPs can subsequently become associated with L5. Such labeled 5S RNA is found in both 5S RNPs and 7S RNPs in the cytoplasm, but only in 5S RNPs in the nucleus of microinjected oocytes. These data suggest that during oogenesis a major pathway for incorporation of 5S RNA into nascent ribosomes involves the migration of 5S RNA from the nucleus to the cytoplasm for storage in an RNP complex with TFIIIA, exchange of that protein association for binding with ribosomal protein L5, and a return to the nucleus for incorporation into ribosomes as they are being assembled in the amplified nucleoli.

42Sp48 in previtellogenic Xenopus oocytes is structurally homologous to EF-1 alpha and may be a stage-specific elongation factor

We have isolated the cDNA for 42Sp48 and EF-1 alpha from mixed stage oocytes and tailbud (stage 22) Xenopus laevis cDNA libraries by use of the cDNA for human elongation factor-1 alpha (EF-1 alpha) as probe. The nucleotide and deduced amino acid sequences of the entire coding region of 42Sp48 and EF-1 alpha cDNA were established. The proposed functional homology of the proteins is reflected in highly conserved amino acid sequences (91% identity), while the large number of silent mutations at the gene level may serve to prevent recombination at their loci. 42Sp48 is apparently encoded by two genes in Xenopus, while no sequences corresponding to 42Sp48 could be found in murine or human genomic DNA. 42Sp48 has been proposed to act as a stage-specific elongation factor in Xenopus. Comparison of the deduced amino acid sequences of 42Sp48 and EF-1 alpha with that of elongation factor Tu from E. coli, for which the three-dimensional structure including that of the GTP binding sites have been determined, supports this hypothesis.

Elongation factor 1 alpha (EF-1 alpha) is concentrated in the Balbiani body and accumulates coordinately with the ribosomes during oogenesis of Xenopus laevis

In Xenopus laevis oocytes two distinct systems catalyze the mRNA-dependent binding of aminoacyl tRNA to the A site of ribosomes. These systems are elongation factor 1 alpha (EF-1 alpha) and the 42S nucleoprotein particle. This particle is also implicated in the long-term storage of 5S RNA and aminoacyl tRNA during early oogenesis. We report here that the ribosomes and the storage particles are distributed uniformly in the cytoplasm of previtellogenic (stage I) oocytes. In contrast, EF-1 alpha is concentrated in a small region of the cytoplasm, known as the mitochondrial mass or Balbiani body. When the Balbiani body disperses in early vitellogenic oocytes (stage II), EF-1 alpha becomes evenly distributed in the cytoplasm. The main phase of EF-1 alpha accumulation follows the disappearance of the 42S particles (stage II), but coincides with the main phase of ribosome accumulation (stages III and IV).

Protein-mediated nuclear export of RNA: 5S rRNA containing small RNPs in xenopus oocytes

We have analyzed RNP formation and nucleocytoplasmic migration of 5S RNA and 5S RNA variants transcribed from microinjected genes in Xenopus oocytes. Using antisera against three different proteins we find that newly transcribed nuclear 5S rRNA transiently interacts with La antigen. The La protein is then replaced by either ribosomal protein L5 or the 5S gene-specific transcription factor IIIA (TFIIIA), and each of these two RNPs migrates out of the nucleus and accumulates in the cytoplasm. RNA molecules that are impaired in their ability to interact with L5 and TFIIIA are retained in the nucleus. Thus, L5 and TFIIIA define a new functional class of proteins involved in the nuclear export of RNA. In addition, we show that RNP migration depletes the nucleus of TFIIIA, resulting in a loss of transcription competence for newly injected 5S rRNA genes.

Translational inactivation of ribosomal protein mRNAs during Xenopus oocyte maturation

Ribosomal protein synthesis ceases upon maturation of Xenopus oocytes. We find that this cessation results from the dissociation of ribosomal protein mRNAs from polysomes and is accompanied by the deadenylation of these transcripts. A synthetic mRNA encoding ribosomal protein L1, microinjected into stage VI oocytes, is deadenylated and released from polysomes upon maturation. Our results indicate that sequences located within 387 bp of the 3' terminus of L1 mRNA direct both the deadenylation and polysomal release of this ribosomal protein mRNA. The proper translational regulation of an exogenous ribosomal protein mRNA in microinjected oocytes provides a basis for determining the sequence specificity for the differential utilization of maternal mRNAs during oocyte maturation.

Post-translational control of ribosomal protein L1 accumulation in Xenopus oocytes

A functional ribosomal protein mRNA, encoding the 60 S subunit protein L1, has been synthesized in vitro using bacteriophage SP6 RNA polymerase. This mRNA directs the synthesis of a product indistinguishable from L1 protein purified from Xenopus ovarian ribosomes. Our results show that L1 synthesis in stage VI oocytes increases in response to microinjection of exogenous SP6-L1 mRNA, but excess L1 protein is not stably accumulated. These results indicate that dosage compensation does not occur at the translational level for this ribosomal protein mRNA and that the abundance of this protein in fully grown oocytes is subject to post-translational regulation.

Expression of ribosomal protein genes during Xenopus development

The Xenopus ribosomal protein genes provide an excellent system to elucidate the complex regulation encompassing 60 functionally related proteins present in equimolar amounts in ribosomal subunits. Oogenesis and embryogenesis provide unique opportunities to investigate ribosome biosynthesis in situations wherein gene activation of individual components is uncoupled from assembly of the ribosomal subunits. This chapter has focused on the basic parameters that control ribosomal protein gene expression during development. Translational control is clearly a major level for coordinating the regulation of these genes during development, as is posttranslational stability of the ribosomal proteins and RNA splicing of the L1 gene. In addition to these levels of control under active investigation, a number of intriguing problems remain to be addressed in any detail. For example, the mechanisms that balance ribosomal protein production with subunit assembly in oocytes remain to be determined. Resolution of these events must also define the processes by which ribosomal proteins, upon synthesis in the cytoplasm, are first translocated to the nucleus and subsequently to the nucleolus for subunit assembly. Functional approaches in which these genes are assayed for accurate developmental control in microinjected oocytes and fertilized eggs will undoubtedly provide information on the synthesis of this eukaryotic organelle and the signals responsible for altering these processes at different developmental stages.

Biochemical research on oogenesis: protein synthesis in whole cells and in cell-free extracts of Xenopus laevis immature ovaries

Nearly all tRNA molecules in previtellogenic oocytes of Xenopus laevis are included in nucleoprotein particles sedimenting at 42S. The tRNA-binding sites of these particles have several properties in common with those of the ribosomes. This suggests that the 42S particles might behave like unprogrammed ribosomes and be the site of a template-independent polymerization of amino acids. We expected this reaction to be insensitive to protein synthesis inhibitors, such as cycloheximide and puromycin. We found that these antibiotics almost completely inhibit the incorporation of labeled amino acids into protein, when added to the incubation medium of whole ovaries or free oocytes. In cell-free extracts of ovaries, the incorporation of amino acids is partially insensitive to cycloheximide and puromycin. When such extracts are fractionated by sucrose density centrifugation and incubated with ATP, a major peak of amino acid incorporation can be detected, which nearly coincides with the 42S particle peak.

Ribosomal protein, histone and calmodulin mRNAs are differently regulated at the translational level during oogenesis of Xenopus laevis

The localization of r-protein mRNA in subcellular compartments has been analysed. It was observed that the mRNA for a representative r-protein (L1) is diffuse in the cytoplasm, as shown by in situ hybridization experiments and that the distribution of rp-mRNA between polysomes and light mRNPs changes during oogenesis. In early oogenesis this mRNA is found mostly in subpolysomal fractions, whereas at the beginning of vitellogenesis (stage II) it becomes associated with polysomes where it remains in a constant amount at later stages. Histone and calmodulin mRNA, on the contrary, are mostly associated with non-polysomal fast-sedimenting particles throughout oogenesis. This suggests that the partition of different classes of mRNA between polysomes, light mRNP and heavy particles depends on their nature and might be determined by different requirements for these mRNAs during oogenesis.

Stable repression of ribosomal protein L1 synthesis in Xenopus oocytes by microinjection of antisense RNA

The synthesis of an endogenous ribosomal protein, L1, is selectively and efficiently inhibited by microinjection of antisense L1 RNAs into Xenopus oocytes. Repression of L1 synthesis is achieved within 12 hr and is maintained for 48 hr. RNase-protection assays reveal the formation of RNA X RNA duplexes in vivo between the endogenous L1 mRNA and injected antisense transcripts. Partial-length antisense RNAs, complementary to only the 3'-terminal region of L1 mRNA, repress translation as effectively as a full-length antisense RNA, indicating that complementarity to the 5' region of L1 mRNA is not required for efficient inhibition. The use of antisense RNA to repress synthesis of an endogenous ribosomal protein provides a functional basis for determining mechanisms that integrate ribosomal protein synthesis with ribosome assembly during oogenesis.

A cDNA clone for a polyadenylated RNA-binding protein of Xenopus laevis oocytes hybridizes to four developmentally regulated mRNAs

Xenopus laevis oocytes contain a unique group of proteins which decrease during oogenesis, bind poly(A) RNA, and possibly play a role in the regulation of translation. A monoclonal antibody generated against one of these proteins was used to screen an expression vector cDNA library. A cDNA clone was isolated and confirmed to code for the binding protein by in vitro translation of hybrid-selected RNA followed by immunoprecipitation. This cDNA, when used in RNA gel blots, hybridized to four transcripts of 2.0, 1.7 (two transcripts of similar size), and 1.2 kilobases. All of the transcripts decreased in amount during oogenesis and were not evident in somatic cells. In addition, the fraction of the transcripts associated with polysomes decreased during oogenesis. Digestion of the cDNA insert with PstI generated two fragments of 220 and 480 base pairs which, when used as probes in an RNA gel blot, hybridized to unique as well as common transcripts. Genomic Southern blots suggested the presence of a single gene, indicating that these transcripts arose by alternative processing.

Coordinate expression of ribosomal protein genes during Xenopus development

The expression of ribosomal protein and rRNA genes during Xenopus oogenesis results in the synthesis of sufficient ribosomes to support development of the swimming tadpole. cDNA clones for ribosomal proteins L13, L15, L23, and S22 have been isolated and used as probes to examine ribosomal protein gene transcripts during oogenesis and embryogenesis. Our results show that ribosomal protein mRNAs attain maximal steady-state levels in stage II oocytes concomitant with the onset of vitellogenesis. Approximately 50% of ribosomal protein mRNAs are associated with polysomes throughout oogenesis, resulting in a constant rate of ribosomal protein synthesis in stage III through stage VI oocytes. In contrast, the polysomal to nonpolysomal distribution of bulk poly(A)+ RNA increases during oogenesis, resulting in a five- to eightfold stimulation in the rate of overall protein synthesis. Following fertilization, maternal ribosomal protein mRNAs are degraded. Accumulation of de novo ribosomal protein transcripts is first detectable during gastrulation, but ribosomal protein mRNAs do not enter polysomes until stage 30 tailbud embryos. We find no discernible structural or functional differences between ribosomal protein transcripts in the polysomal and the nonpolysomal fractions for the observed stages of oocytes and embryos. These results are consistent with a model in which control of ribosomal protein synthesis is regulated at the translational level during Xenopus development.

A cDNA clone for a polyadenylated RNA-binding protein of Xenopus laevis oocytes hybridizes to four developmentally regulated mRNAs

Xenopus laevis oocytes contain a unique group of proteins which decrease during oogenesis, bind poly(A) RNA, and possibly play a role in the regulation of translation. A monoclonal antibody generated against one of these proteins was used to screen an expression vector cDNA library. A cDNA clone was isolated and confirmed to code for the binding protein by in vitro translation of hybrid-selected RNA followed by immunoprecipitation. This cDNA, when used in RNA gel blots, hybridized to four transcripts of 2.0, 1.7 (two transcripts of similar size), and 1.2 kilobases. All of the transcripts decreased in amount during oogenesis and were not evident in somatic cells. In addition, the fraction of the transcripts associated with polysomes decreased during oogenesis. Digestion of the cDNA insert with PstI generated two fragments of 220 and 480 base pairs which, when used as probes in an RNA gel blot, hybridized to unique as well as common transcripts. Genomic Southern blots suggested the presence of a single gene, indicating that these transcripts arose by alternative processing.

Growing Xenopus oocytes have spare translational capacity

Previous studies have shown that exogenous mRNAs injected into full-grown (stage 6) Xenopus oocytes are translated only at the expense of endogenous messages; translational capacity is limited. In this report, we demonstrate that injection of globin mRNA into small, stage 4 oocytes results in an increase in total protein synthesis without a concomitant decrease in the translation of endogenous mRNAs. The absence of competition with endogenous messages in stage 4 oocytes, injected with globin mRNA, compared with stage 6 oocytes, was not due to differential turnover of the injected mRNA. Hybridization of RNA from mRNA-injected oocytes at both stages revealed that similar amounts of globin mRNA were present. These results are interpreted to mean that protein synthesis in growing oocytes is limited by the availability of mRNA and not components of the translational machinery. This conclusion, however, does not apply to all mRNA classes. The capacity of stage 4 oocytes to translate a mRNA (zein) on membrane-bound polysomes is as restricted as reported previously for stage 6 oocytes. This result suggests that putative membrane binding sites or rough endoplasmic reticulum content are limited in oocytes at both stages. The possible role of association of injected mRNA with endogenous proteins that prevent translation is discussed.

Quantitative changes in protein synthesis during oogenesis in Xenopus laevis

Protein synthesis rates in Xenopus laevis oocytes from stage 1 through stage 6 were measured. In addition, the translational efficiencies, total RNA contents, and percentages of ribosomes in polysomes in growing oocytes at several stages were determined. Stage 1 oocytes synthesize protein at a mean rate of 0.18 ng hr-1 while stage 6 oocytes make protein at a rate of 22.8 ng hr-1. Polysomes from growing and full-grown oocytes sedimented in a sucrose gradient with a peak value of 300 S, corresponding to a weight-average packing density of 10 ribosomes per mRNA. Ribosome transit times of endogenous mRNAs were essentially unchanged at all stages examined. While the oocyte's total ribosomal RNA content was observed to increase about 115-fold during oogenesis, the percentage of ribosomes in polysomes remained constant at approximately 2%. Taken together, the data suggest that the 127-fold increase in protein synthesis which occurs during Xenopus oogenesis involves the progressive recruitment onto polysomes of mRNA from the maternal stockpile.

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.

Increased ribosomal affinity for mRNA causes resistance to edeine in a mutant of Saccharomyces cerevisiae

The effect of edeine on the translation of mRNA or poly(U)-directed polyphenylalanine synthesis has been studied in an edeine-resistant mutant of Saccharomyces cerevisiae under three different experimental conditions: in the whole lysate system, in a micrococcal-nuclease-treated lysate, and in a high-salt-treated lysate. The results indicate that translation of messenger is more resistant to edeine in the whole lysate than in the depleted lysates; these observations suggest that resistance to edeine is associated with the presence of endogenous mRNA. It is shown that 40S mutant subunits have a higher affinity for polysomal RNA than 40S wild-type subunits. Since the mRNA binding is inhibited by 7-methylguanosine 5'-monophosphate, the interaction between polysomal RNA and 40S ribosomes is specific for mRNA. The data demonstrate that in each of the depleted lysates, with edeine initially present, the formation of the 80S initiation complex is inhibited. However, edeine inhibition of [3H]methionine binding to 80S ribosomes is overcome completely in the mutant extract by preincubation of this lysate with polysomal RNA. The results indicate that the mutant may carry a specific change in a messenger-binding factor or in a ribosomal protein thereby permitting an increased stability of the messenger-ribosome complex which consequently results in an increased resistance of the mutant lysate to edeine.

Distribution and utilization of 5 S-RNA-binding proteins during the development of Xenopus oocytes

At early stages of oogenesis in Xenopus laevis most of the ribosomal 5S RNA is complexed with three proteins to form two types of cytoplasmic RNP storage particle. A particle sedimenting at 42S contains 5S RNA and tRNA together with two proteins of Mr 48000 (P48) and Mr 43000 (P43) and a second particle sedimenting at 7S contains 5S RNA plus a protein of Mr 40000 (P40, also known as the transcription factor, TFIIIA). In this report we use antibodies monospecific for each protein to follow the movement of 5S RNA from nucleus to cytoplasm to nucleolus to cytoplasm and to determine the fate of each of the proteins that associate with 5S RNA during these transitions. Both P48 and P43 have roles additional to the formation of the 42S RNP storage particle; P48 is detected in the nucleus during early oogenesis and is cleaved to yield an Mr-33000 fragment that remains associated with 5S RNA that is excess to ribosome requirement during late oogenesis; P43 appears to be cleaved to yield fragments of Mr 28000 and 17000, the latter being present in ribosomal fractions. Apparently, there is no function for P40 in addition to those already described in transcription of 5S RNA genes and in storage of 5S RNA as a 7S RNP particle.

Immunological identity of proteins that bind stored 5S RNA in Xenopus oocytes

In small oocytes of Xenopus laevis, the three most abundant proteins are isolated as basic polypeptides with molecular weights of 48 kD (P48), 43 kD (P43) and 40 kD (P40, also known as transcription factor IIIA). All three proteins share common properties in being able to bind specifically ribosomal 5S RNA molecules and influence, in different ways, their rates of production and utilization. It has been shown by biochemical analysis and immunological characterization that the three proteins are structurally distinct and are most probably the products of different genes. Immunostaining and radio-immunoassays indicate that both P48 and P43 have diverged considerably in structure between the amphibian genera Xenopus and Triturus. Antibodies raised against the transcription factor for Xenopus laevis 5S RNA genes (P40/TFIIIA) do not cross-react with the transcription factor isolated from oocytes of the closely related species Xenopus borealis. A protein equivalent of TFIIIA is not found in 5S RNA-containing RNP storage particles of Triturus oocytes. The functions of the three Xenopus oocyte proteins in transporting 5S RNA between different cellular compartments are considered in the light of these variations.

Reversible inhibition of translation by Xenopus oocyte-specific proteins

A characteristic of growing oocytes of all animal species is the synthesis and accumulation of messenger RNA which is destined to be used primarily by the early embryo. The mechanism(s) which regulates the translation of this maternal mRNA remains unknown. However, the inability of the oocyte to translate all of its putative mRNA has been attributed to at least three limitations: (1) The rate of translation is limited by the availability of components of the translational apparatus other than mRNA, (2) the structural organization of the mRNA prevents translation, and (3) proteins associated with the mRNA prevent translation. Several investigators have suggested that proteins associated with maternal mRNA suppress translation in sea urchin eggs, although others claim that such results may be due to experimental artefacts. Oocyte-specific proteins have been identified in association with non-translating poly(A)+ mRNAs from Xenopus laevis oocytes, and we report here that when these proteins are reconstituted with mRNAs in vitro the translation of the mRNAs in vitro is reversibly repressed. The implication is that these proteins are involved in the regulation of translation of stored maternal mRNAs.

Interspersed poly(A) RNAs of amphibian oocytes are not translatable

The poly(A) RNA of the Xenopus oocytes has been shown to include both single copy and interspersed transcripts. Interspersed maternal poly(A) RNAs contain repetitive sequence elements distributed within regions transcribed from single copy sequences. When renatured these RNAs form partially double-stranded RNA networks, and as shown earlier this can be utilized for preparative separation of interspersed maternal transcripts from maternal transcripts that remain single-stranded after renaturation (Anderson et al., 1982). The translational activity of these RNA fractions was tested in vitro, in wheat germ and reticulocyte systems. While the single-stranded fractions supported protein synthesis, the interspersed oocyte RNAs displayed little translational activity. Translational activity was measured in vivo by injection into the Xenopus oocyte. Oocytes previously injected with globin mRNA were injected with increasing amounts of single-stranded, double-stranded, or denatured double-stranded RNA fractions, and the amount of globin synthesis was determined. It was found that single-stranded RNA competes with globin mRNA for the limited translational apparatus of the oocyte, as manifested by a quantitative reduction of globin synthesis. However, globin synthesis was not affected when double-stranded RNA, either in renatured or denatured form, was injected. We conclude that the interspersed RNAs are not translated within the oocyte. The amount of single and double-stranded RNAs loaded onto polysomes in the injected oocytes was also determined. Sixty seven per cent of radio-iodinated single-stranded RNA pelleted with polysomes in injected oocytes, whereas less than 20% of similarly labeled double-stranded RNA pelleted with polysomes. This value is similar to that obtained when partially hydrolyzed RNA is injected, suggesting again that essentially none of the interspersed RNA is translated in vivo. The significance of these findings in relation to translational regulation during oogenesis and early development is discussed.

Intermediate-size filaments in a germ cell: Expression of cytokeratins in oocytes and eggs of the frog Xenopus

Vitellogenic oocytes and eggs of the frog Xenopus laevis contain intermediate-size filaments that are resistant to extractions in high-salt buffers and Triton X-100 and are specifically stained with antibodies to cytokeratins. Gel electrophoresis of cytoskeletal proteins from Xenopus oocytes shows a specific enrichment of three polypeptides designated components 1 [Mr, 56,000; IEP (pI obtained by two-dimensional gel electrophoresis in the presence of 9.5 M urea), ca. 5.9], 2 (Mr, 46,000; IEP, 5.38), and 3 (Mr, 42,000; IEP, ca. 5.3). The same three cytoskeletal polypeptides are found in eggs and early embryos, in intestinal mucosa of adult frogs, and in cultured kidney epithelial cells. They are different from amphibian vimentin and desmin and from the keratins present in the epidermis of adult frogs. Peptide mapping and immunoblotting experiments indicate that Xenopus cytokeratin component 1 is related to cytokeratin A of higher vertebrates but is different from the two smaller cytoskeletal polypeptides 2 and 3. Incorporation of [35 S]methionine shows that all three polypeptides are synthesized in both oocytes and embryos. Our observations show that maternal storage is not only restricted to proteins serving basic cellular functions but also can extend to proteins related to a specific form of cell differentiation (i.e., epithelial formation) in the early embryo. The data suggest that mechanisms of epithelial differentiation in Xenopus embryogenesis are different from those of early mammalian embryos in which no such intermediate-size-filament storage pool has been detected.

Nuclear exclusion of transcription factor IIIA and the 42s particle transfer RNA-binding protein in Xenopus oocytes: a possible mechanism for gene control?

The intracellular location of 7S and 42S RNP particles in Xenopus oocytes has been determined by immunohistochemistry. Using antibodies directed against the 48-mol-wt protein component of the 42S particle and against transcription factor IIIA, the protein moiety of the 7S particle, we show that these ribonucleoprotein particles are detectable only in the oocyte cytoplasm, being excluded from the nucleus. The mechanism of this nuclear exclusion, and its possible significance in the regulation of 5S RNA gene expression, are discussed.

Specific interaction of proteins with 5 S RNA and tRNA in the 42 S storage particle of Xenopus oocytes

During early oogenesis in amphibia, most of the 5 S RNA and tRNA is stored in a ribonucleoprotein particle that sediments at 42 S. In Xenopus laevis the 42 S particle contains two major proteins: of Mr 48 000 (P48) and 43 000 (P43). It is shown that heterogeneity in composition of the 42 S particle reflects a changing situation whereby initially, both 5 S RNA and tRNA are complexed with P48 (1 molecule 5 S RNA: 1 molecule P48; 2 or 3 molecules tRNA: 1 molecule P48), but later, tRNA becomes increasingly associated with P43 (in a 1:1 ratio) although 5 S RNA remains complexed with a cleavage product of P48. These changes relate to the eventual utilization of the excess 5 S RNA and tRNA in ribosome assembly and protein synthesis.

Isolation and characterization of a 7 S RNP particle from mature Xenopus laevis oocytes

Mature oocytes of Xenopus laevis contain a 7 S RNP particle consisting of two components, ribosomal 5 S RNA and a protein of Mr approximately 45000. The structure of the free 5 S rRNA and the 7 S RNP complex has been studied by diethylpyrocarbonate modification of adenines. A74, A77, A90, A100, A101 and A103 of the 5 S rRNA are protected upon association of the protein.