A test for masked message: the template activity of messenger ribonucleoprotein particles isolated from sea urchine eggs

Emergent dynamics of adult stem cell lineages from single nucleus and single cell RNA-Seq of Drosophila testes

Proper differentiation of sperm from germline stem cells, essential for production of the next generation, requires dramatic changes in gene expression that drive remodeling of almost all cellular components, from chromatin to organelles to cell shape itself. Here, we provide a single nucleus and single cell RNA-seq resource covering all of spermatogenesis in Drosophila starting from in-depth analysis of adult testis single nucleus RNA-seq (snRNA-seq) data from the Fly Cell Atlas (FCA) study. With over 44,000 nuclei and 6000 cells analyzed, the data provide identification of rare cell types, mapping of intermediate steps in differentiation, and the potential to identify new factors impacting fertility or controlling differentiation of germline and supporting somatic cells. We justify assignment of key germline and somatic cell types using combinations of known markers, in situ hybridization, and analysis of extant protein traps. Comparison of single cell and single nucleus datasets proved particularly revealing of dynamic developmental transitions in germline differentiation. To complement the web-based portals for data analysis hosted by the FCA, we provide datasets compatible with commonly used software such as Seurat and Monocle. The foundation provided here will enable communities studying spermatogenesis to interrogate the datasets to identify candidate genes to test for function in vivo.

Smaug assembles an ATP-dependent stable complex repressing nanos mRNA translation at multiple levels

The nanos (nos) mRNA encodes the posterior determinant of the Drosophila embryo. Translation of the RNA is repressed throughout most of the embryo by the protein Smaug binding to Smaug recognition elements (SREs) in the 3' UTR. Translation is locally activated at the posterior pole by Oskar. This paper reports that the SREs govern the time- and ATP-dependent assembly of an exceedingly stable repressed ribonucleoprotein particle (RNP) in embryo extract. Repression can be virtually complete. Smaug and its co-repressor Cup as well as Trailer hitch and the DEAD box protein Me31B are part of the repressed RNP. The initiation factor eIF4G is specifically displaced, and 48S pre-initiation complex formation is inhibited. However, later steps in translation initiation are also sensitive to SRE-dependent inhibition. These data confirm several previously untested predictions of a current model for Cup-dependent repression but also suggest that the Cup model by itself is insufficient to explain translational repression of the nos RNA. In the embryo extract, recombinant Oskar relieves translational repression and deadenylation by preventing Smaug's binding to the SREs.

Ribosomal analysis of rapid rates of protein synthesis in the Antarctic sea urchin Sterechinus neumayeri

Previous research has shown that developing stages of the Antarctic sea urchin Sterechinus neumayeri have high rates of protein synthesis that are comparable to those of similar species living in much warmer waters. Direct measurements of the biosynthetic capacities of isolated ribosomes have not been reported for marine organisms living in the extreme-cold environment of Antarctica. Such measurements are required for a mechanistic understanding of how the critical and highly complex processes involved in protein synthesis are regulated in animals living in the coldest marine environment on Earth (< -1 degrees C). We tested the hypothesis that high rates of protein synthesis in the cold are a direct result of high biosynthetic capacities of ribosomes engaged in protein synthesis. Our results show that the rate at which ribosomes manufacture proteins (i.e., the peptide elongation rate) at -1 degrees C is surprisingly similar to rates measured in other sea urchin species at temperatures that are over 15 degrees C warmer. Average peptide elongation rates for a range of developmental stages of the Antarctic sea urchin were 0.36 codons s(-1) (+/- 0.05, SE). On the basis of subcellular rate determinations of ribosomal activity, we calculated stage-specific rates of protein synthesis for blastulae and gastrulae to be 3.7 and 6.5 ng protein h(-1), respectively. These findings support the conclusion that the high rates of biosynthesis previously reported for the Antarctic sea urchin are an outcome of high ribosomal activities.

eIF4E association with 4E-BP decreases rapidly following fertilization in sea urchin

The eukaryotic translation initiation factor (eIF) 4F facilitates the recruitment of ribosomes to the mRNA 5' end. The 4E-BPs are small proteins with hypophosphorylated forms that interact with the cap binding protein eIF4E, preventing its interaction with eIF4G, thereby preventing ribosome interaction with mRNA. In sea urchin, fertilization triggers a rapid rise in protein synthesis. Here, we demonstrate that a 4E-BP homologue exists and is associated with eIF4E in unfertilized eggs. We also show that 4E-BP/eIF4E association diminishes a few minutes following fertilization. This decrease is correlated with a decrease in the total amount of 4E-BP in combination with an increase in the phosphorylation of the protein. We propose that 4E-BP acts as a repressor of protein synthesis in unfertilized sea urchin eggs and that 4E-BP/eIF4E dissociation plays an important role in the rise in protein synthesis that occurs shortly following fertilization.

Identification of a novel mRNA-associated protein in oocytes of Pleurodeles waltl and Xenopus laevis

Amphibian oocytes accumulate a large pool of mRNA molecules for future embryonic development. Due to their association with specific proteins the stored maternal RNAs are translationally repressed. The identification of these RNA-binding proteins and the characterization of their functional domains may contribute to the understanding of the translational repression mechanisms and the subsequent activation processes during early embryogenesis. Here we present the complete Pleurodeles cDNA sequence of a cytoplasmic protein which is present in oocytes, eggs, and very early cleavage stage embryos but undetectable in postcleavage embryo and adult tissues. The predicted molecular mass of the protein is 55 kDa and the apparent molecular mass as determined by SDS-PAGE, 68 kDa. The deduced amino acid sequence reveals proline- and serine-rich domains in the aminoterminal part as well as two RGG boxes which represent characteristic motifs of several RNA-binding proteins. No distinct homologies to the consensus RNA recognition motif were found. The 55-kDa protein was recovered in cytoplasmic ribonucleoprotein (RNP) particles containing poly(A)+ RNA. It was therefore termed RAP55 for mRNA-associated protein of 55 kDa. However, a direct interaction of RAP55 with mRNA could not be demonstrated by UV-crosslinking experiments, indicating that it is bound to mRNP complexes via protein-protein interactions. RAP55 is evolutionarily conserved since antibodies raised against a recombinant Pleurodeles RAP55 fragment recognize the protein from Pleurodeles and Xenopus. The expression pattern and intracellular distribution of RAP55 suggest that it is part of those mRNP particles which are translationally repressed during oogenesis and become activated upon progesterone-induced oocyte maturation.

Storage of messenger RNA in eukaryotes: envelopment with protein, translational barrier at 5' side, or conformational masking by 3' side?

Messenger RNA can be stored in the cytoplasm of higher Eukaryotes in the form of masked messenger ribonucleoprotein particles (masked mRNPs, or informosomes). The typical example is the storage of mRNPs in germ cells (oocytes and spermatocytes). The masked mRNPs are inactive in translation, stable, i.e., protected against degradation, and unavailable for poly(A) tail processing, such as cytoplasmic polyadenylation and deadenylation. The major nonspecific mRNA-binding protein forming mRNPs and belonging to a special p50 family of basic, glycine-rich, phosphorylatable proteins seems to be necessary, but not sufficient for the masking. In some cases, mRNA-specific repressor proteins bound to the 5'-untranslated regions (5'-UTR) of mRNAs may be involved. Interactions of the 3'-untranslated regions (3'-UTR) with sequence-specific proteins seem to be of decisive importance for the masking of mRNPs. The hypothesis is proposed that the masking is achieved through a 3'-UTR-induced conformational rearrangement of mRNP; closing into a circle and condensation of mRNP are considered plausible.

Translational activity of mouse protamine 1 messenger ribonucleoprotein particles in the reticulocyte and wheat germ cell-free translation systems

Protamine 1 mRNAs are inactivated by a block to the initiation of translation in early spermatids and are translationally active in late spermatids in mice. To determine whether translation of protamine 1 mRNAs is inhibited by a protein repressor, the translational activity of ribonucleoprotein particles and deproteinized RNAs were compared in the reticulocyte and wheat germ cell-free translation lysates. To isolate RNPs, cytoplasmic extracts of total testes were fractionated by large-pore gel filtration chromatography. Ribonucleoprotein particles in the excluded fractions stimulated synthesis of radiolabeled translation products for protamine 1 about twofold less effectively than deproteinized RNAs in the reticulocyte lysate, but were inactive in the wheat germ lysate. The ability of translationally repressed protamine 1 ribonucleoprotein particles to form initiation complexes with 80S ribosomes in the reticulocyte lysate was also measured. Protamine 1 ribonucleoprotein particles isolated by gel filtration and in unfractionated cytoplasmic extracts of early spermatids were nearly as active in forming initiation complexes as deproteinized mRNAs. The isolation of ribonucleoprotein particles in buffers of varying ionic strength, protease inhibitors, and several other variables had no major effect on the ability of protamine 1 ribonucleoprotein particles to form initiation complexes in the reticulocyte lysate. These results can be explained by artifacts in the isolation or assay of ribonucleoprotein particles or by postulating that protamine 1 mRNAs are inactivated by a mechanism that does not involve protein repressors, such as sequestration.

Role of cytoplasmic mRNP proteins in translation

Polyribosomal and free mRNPs from rabbit reticulocytes were isolated and characterized. Translation of mRNPs was studied in the rabbit reticulocyte and wheat germ cell-free systems. Both classes of mRNPs were active in rabbit reticulocyte lysates. However, considerable differences between mRNPs and mRNA have been revealed. High concentrations of mRNA in the form of mRNP did not inhibit protein biosynthesis, whereas the same amounts of deproteinized mRNA caused inhibition of this process. Polyribosomal mRNPs and deproteinized mRNA, but not free mRNPs, are active in the wheat germ cell-free translation system. Translation of free mRNPs in this system can be restored by addition of 0.5 M KCl-wash of rabbit reticulocyte ribosomes. These results suggest the existence of a special repressor/activator regulatory system which controls mRNA distribution between free mRNPs and polyribosomes in rabbit reticulocytes. This regulatory system should include: i) a translation repressor associated with mRNA within free mRNPs, preventing its translation; and ii) a translation activator associated with ribosomes, overcoming the effect of the repressor. Both classes of cytoplasmic mRNPs contain a major 50 kDa protein (p50). The content of this protein per mol of mRNA in free mRNPs is twice as much as in polyribosomal ones. The method of p50 isolation has been developed and some properties of this protein were investigated. It has been shown that small amounts of p50 stimulate, whereas high amounts inhibit mRNA translation. We suggest that p50 has a dual role in protein biosynthesis. In polyribosomal mRNPs (p50:mRNA approximately 2:1, mol/mol), this protein promotes the translation process.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of a protease from Xenopus embryos

A proteolytic enzyme was purified from Xenopus embryos. The purification procedure consisted of fractionation of an extract of embryos with acetone, gel filtration of Sephadex G-75 and chromatography on carboxymethyl-cellulose and hydroxylapatite. The preparation of enzyme appeared to be homogeneous as judged by electrophoresis in polyacrylamide gels. This protease had a molecular mass of 43-44 kDa and was composed of two subunits with molecular masses of 30 kDa and 13 kDa. The optimal pH of the reaction catalysed by the protease was approximately 4.0. This proteolytic activity was inhibited by antipain, leupeptin and iodoacetic acid; it was not affected by phenylmethylsulfonyl fluoride and pepstatin; and it was enhanced by dithiothreitol. In the presence of RNA, the optimal pH was shifted from pH 4.0 to pH 4.5. The protease was activated by addition of total RNA from Xenopus embryos, by poly(rU) or poly(rG). In contrast, after addition of tRNA or poly(rC), no activation of the protease was observed.

A special repressor/activator system controls distribution of mRNA between translationally active and inactive mRNPs in rabbit reticulocytes

Translation of free mRNPs and polyribosomal mRNPs from rabbit reticulocytes was studied in a rabbit reticulocyte and wheat germ cell-free systems. It has been shown that translation efficiency of polyribosomal mRNPs and the mRNA isolated from the particles is nearly the same in both systems. At the same time, mRNP's translatability, which is high in the homologous cell-free system, is very low in the system from wheat germs. Translation efficiency of free mRNPs in the wheat germ system can be restored by addition of 0.5 M K CI-wash of rabbit reticulocyte ribosomes. The results testify to the existence of some special repressor repressor/activator system which controls the distribution of mRNA between free mRNPs and polyribosomes in rabbit reticulocytes.

Translational active mRNPs from rabbit reticulocytes are qualitatively different from free mRNA in their translatability in cell-free system

The translatability of polyribosomal and free mRNPs from rabbit reticulocytes and their mRNA was compared. Both classes of mRNPs turned out to be active in rabbit reticulocyte lysates. Considerable differences between mRNPs and mRNA have been revealed. The most striking feature of mRNPs was that high concentrations of mRNPs do not inhibit protein biosynthesis, whereas high concentrations of mRNA strongly inhibit this process. This inhibition is specific for mRNA and does not occur at the addition of the same amount of rRNA from E. coli. The features of mRNP translation are not the result of addition of the supplementary translation factors within particles. The specific function of mRNP proteins in the process of translation is under discussion.

Poly(A) elongation during Xenopus oocyte maturation is required for translational recruitment and is mediated by a short sequence element

Xenopus oocytes contain several mRNAs that are mobilized into polysomes only at the completion of meiosis (maturation) or at specific times following fertilization. To investigate the mechanisms that control translation during early development, we have focused on an mRNA, termed G10, that is recruited for translation during oocyte maturation. Coincident with its translation, the poly(A) tail of this message is elongated from approximately 90 to 200 adenylate residues. To identify the cis sequence that is required for this cytoplasmic adenylation and recruitment, we have synthesized wild-type and deletion mutant G10 mRNAs with SP6 polymerase. When injected into oocytes that subsequently were induced to mature with progesterone, wild-type G10 mRNA, but not mutant transcripts lacking a 50-base sequence in the 3'-untranslated region, was polyadenylated and recruited for translation. The 50-base sequence was sufficient to confer polyadenylation and translation when fused to globin mRNA, which does not normally undergo these processes during oocyte maturation. Further mutational analysis of this region revealed that a U-rich sequence 5' to the AAUAAA hexanucleotide nuclear polyadenylation signal, as well as the hexanucleotide itself, were both required for polyadenylation and translation. The 50-base cis element directs polyadenylation, but not translation per se, as a transcript that terminates with 3'-deoxyadenosine (cordycepin) is not recruited for translation. The available data suggest that the dynamic process of polyadenylation, and not the length of the poly(A) tail, is required for translational recruitment during oocyte maturation.

Fertilization triggers unmasking of maternal mRNAs in sea urchin eggs

Fertilization of sea urchin eggs results in a large increase in the rate of protein synthesis which is mediated by the translation of stored maternal mRNA. The masked message hypothesis suggests that messenger ribonucleoprotein particles (mRNPs) from unfertilized eggs are translationally inactive and that fertilization results in alterations of the mRNPs such that they become translationally active. Previous workers have isolated egg mRNPs by sucrose gradient centrifugation and have assayed their translational activity in heterologous cell-free systems. The conflicting results they obtained are probably due to the sensitivity of mRNPs to artifactual activation and inactivation. Previously, we demonstrated that unfractionated mRNPs in a sea urchin cell-free translation system were translationally inactive. Now, using large-pore gel filtration chromatography, we partially purified egg mRNPs while retaining their translationally repressed state. Polysomal mRNPs from fertilized eggs isolated under the same conditions were translationally active. The changes in the pattern of proteins synthesized by fractionated unfertilized and fertilized mRNPs in vitro were similar to those changes observed in vivo. Treatment of egg mRNPs with buffers containing high salt and EDTA, followed by rechromatography, resulted in the activation of the mRNPs and the release of an inhibitor of translation from the mRNPs. Analysis of the inhibitory fraction on one-dimensional sodium dodecyl sulfate gels indicated that this fraction contains a complex set of proteins, several of which were released from high-salt-EDTA-activated mRNPs and not from inactive low-salt control mRNPs. One of the released proteins may be responsible for the repression of egg mRNPs in vitro and be involved in the unmasking of mRNPs at fertilization.

Fertilization triggers unmasking of maternal mRNAs in sea urchin eggs

Fertilization of sea urchin eggs results in a large increase in the rate of protein synthesis which is mediated by the translation of stored maternal mRNA. The masked message hypothesis suggests that messenger ribonucleoprotein particles (mRNPs) from unfertilized eggs are translationally inactive and that fertilization results in alterations of the mRNPs such that they become translationally active. Previous workers have isolated egg mRNPs by sucrose gradient centrifugation and have assayed their translational activity in heterologous cell-free systems. The conflicting results they obtained are probably due to the sensitivity of mRNPs to artifactual activation and inactivation. Previously, we demonstrated that unfractionated mRNPs in a sea urchin cell-free translation system were translationally inactive. Now, using large-pore gel filtration chromatography, we partially purified egg mRNPs while retaining their translationally repressed state. Polysomal mRNPs from fertilized eggs isolated under the same conditions were translationally active. The changes in the pattern of proteins synthesized by fractionated unfertilized and fertilized mRNPs in vitro were similar to those changes observed in vivo. Treatment of egg mRNPs with buffers containing high salt and EDTA, followed by rechromatography, resulted in the activation of the mRNPs and the release of an inhibitor of translation from the mRNPs. Analysis of the inhibitory fraction on one-dimensional sodium dodecyl sulfate gels indicated that this fraction contains a complex set of proteins, several of which were released from high-salt-EDTA-activated mRNPs and not from inactive low-salt control mRNPs. One of the released proteins may be responsible for the repression of egg mRNPs in vitro and be involved in the unmasking of mRNPs at fertilization.

Three translationally regulated mRNAs are stored in the cytoplasm of clam oocytes

In situ hybridization was used to examine the spatial distributions of three translationally controlled maternal RNAs in oocytes and two-cell embryos of the clam Spisula. 3H-labeled single-stranded RNA probes were generated from SP6 recombinant clones containing DNA inserts encoding portions of histone H3 (the DNA sequence which is presented here), cyclin A, and the small subunit of ribonucleotide reductase. Hybridization of these probes to oocytes, in which the mRNAs are translationally inactive, shows that these mRNAs are stored in the cytoplasm. There is no evidence for sequestration of any of the RNAs within the nucleus or any other discrete structure. Instead they appear to be evenly distributed throughout the cytoplasm.

Inhibitor of eukaryotic initiation factor 4F activity in unfertilized sea urchin eggs

Extracts from unfertilized sea urchin eggs contain an inhibitor of translation that inhibits protein synthesis in cell-free translation systems from sea urchin embryos or rabbit reticulocytes. The inhibitory effects of egg extracts can be reversed by the addition of mammalian eukaryotic initiation factor 4F (eIF-4F) in both sea urchin embryo and reticulocyte systems, suggesting that the inhibitor inactivates this initiation factor. The accumulated data suggest that the ability of eIF-4F to recycle may be compromised. The addition of eIF-4F to cell-free translation systems from unfertilized sea urchin eggs also stimulates protein synthesis. However, the stimulation does not increase protein synthetic activity in the egg cell-free translation system to the levels observed in those produced from 2-hr embryos. This suggests that, although the unfertilized egg contains an inhibitor of eIF-4F and reduced levels of eIF-4F activity, inactivation of this component is only one of the factors involved in the low rate of maternal mRNA utilization found prior to fertilization.

Widespread changes in the translation and adenylation of maternal messenger RNAs following fertilization of Spisula oocytes

We have reported previously that sequence-specific adenylations and deadenylations accompany changes in the translation of maternal mRNA following fertilization of Spisula oocytes (E.T. Rosenthal, T.R. Tansey, and J.V. Ruderman, 1983, J. Mol. Biol. 166, 309-327). The data presented here confirm and extend those observations. We have identified four classes of maternal mRNA with respect to translation: Class 1-not translated in oocytes and translated at very high efficiency immediately after fertilization, Class 2-not translated in oocytes and partially utilized for translation following fertilization, Class 3-translated in oocytes and not translated in embryos, and Class 4-not translated either before or after fertilization. There is an excellent, although not perfect, correlation between the translation of an mRNA and its polyadenylation status. The poly(A) tails of all the mRNAs which are translated in oocytes and untranslated in embryos are shortened at fertilization, and the poly(A) tails of those mRNAs which are untranslated in oocytes and translated in embryos are lengthened at fertilization. These adenylations and deadenylations occur simultaneously during the first 20 min following fertilization.

An in vitro system derived from Friend erythroleukemia cells to study messenger RNA stability

A system consisting of 40-80S messenger ribonucleoprotein particles (mRNP) from stationary Friend erythroleukemia (FEL) cells was used to investigate the stability of mRNA in vitro. The majority of mRNP mRNAs were found to be stable when incubated for periods of up to ninety minutes at 37 degrees. Nonetheless, many mRNAs are greatly reduced in abundance, including ones for eucaryotic elongation factor Tu (eEF-Tu) and the 73-78 kDa polypeptide commonly found in association with the poly(A) tails of mRNA. A divalent cation dependent ribonuclease (probably an endoribonuclease) could be washed off mRNP by treatment of the particles with 0.5M NaCl. The mRNAs contained in the resultant salt washed mRNPs, including eEF-Tu, were stable when incubated in vitro.

Regulation of the utilization of mRNA for eucaryotic elongation factor Tu in Friend erythroleukemia cells

When Friend erythroleukemia cells were allowed to grow to stationary phase (2 X 10(6) to 3 X 10(6) cells per ml), approximately 60% of the mRNA for eucaryotic elongation factor Tu (eEF-Tu) sedimented at less than or equal to 80S, and most of the remaining factor mRNA was associated with small polysomes. Under the same growth conditions, greater than 90% of the mRNA for eucaryotic initiation factor 4A remained associated with polysomes. The association of eEF-Tu mRNA with polysomes changed dramatically when stationary-phase cells were treated with fresh medium. After 1 h in fresh medium, approximately 90% of eEF-Tu mRNA in Friend cells was found in heavy polysomes. Associated with the shift of eEF-Tu mRNA into heavy polysomes, we found at least a 2.6-fold increase in the synthesis of eEF-Tu in vivo as well as a remarkable 40% decrease in the total amount of eEF-Tu mRNA per cell. Our data raise the possibility that eEF-Tu mRNA that has accumulated in ribonucleoprotein particles in stationary-phase cells is degraded rather than reutilized for eEF-Tu synthesis.

The function of proteins that interact with mRNA

Specific proteins are associated with mRNA in the cytoplasm of eukaryotic cells. The complement of associated proteins depends upon whether the mRNA is an integral component of the polysomal complex being translated, or, alternatively, whether it is part of the non-translated free mRNP fraction. By subjecting cells to ultraviolet irradiation in vivo to cross-link proteins to mRNA, mRNP proteins have been shown to be associated with specific regions of the mRNA molecule. Examination of mRNP complexes containing a unique mRNA has suggested that not all mRNA contain the same family of associated RNA binding proteins. The functions of mRNA associated proteins may include a role in providing stability for mRNA, and/or in modulating translation. With the recent demonstrations that both free and polysomal mRNPs are associated with the cytoskeletal framework, specific mRNP proteins may play a role in determining the subcellular localization of specific mRNPs.

Regulation of the utilization of mRNA for eucaryotic elongation factor Tu in Friend erythroleukemia cells

When Friend erythroleukemia cells were allowed to grow to stationary phase (2 X 10(6) to 3 X 10(6) cells per ml), approximately 60% of the mRNA for eucaryotic elongation factor Tu (eEF-Tu) sedimented at less than or equal to 80S, and most of the remaining factor mRNA was associated with small polysomes. Under the same growth conditions, greater than 90% of the mRNA for eucaryotic initiation factor 4A remained associated with polysomes. The association of eEF-Tu mRNA with polysomes changed dramatically when stationary-phase cells were treated with fresh medium. After 1 h in fresh medium, approximately 90% of eEF-Tu mRNA in Friend cells was found in heavy polysomes. Associated with the shift of eEF-Tu mRNA into heavy polysomes, we found at least a 2.6-fold increase in the synthesis of eEF-Tu in vivo as well as a remarkable 40% decrease in the total amount of eEF-Tu mRNA per cell. Our data raise the possibility that eEF-Tu mRNA that has accumulated in ribonucleoprotein particles in stationary-phase cells is degraded rather than reutilized for eEF-Tu synthesis.

Injected mRNA does not increase protein synthesis in unfertilized, fertilized, or ammonia-activated sea urchin eggs

We have investigated whether the rate of protein synthesis in unfertilized and fertilization-activated sea urchin eggs is limited by the availability of mRNA by injecting eggs, zygotes, and ammonia-activated eggs with globin mRNA. Message-injected and buffer-injected cells were labeled with radioactive amino acids and the proteins separated on a polyacrylamide gel. The relative amounts of newly synthesized globin and endogenous proteins were obtained by scanning the gel fluorograph. Globin mRNA is translated poorly in Strongylocentrotus droebachiensis eggs and does not significantly increase or decrease endogenous protein synthesis. In zygotes and ammonia-activated eggs, however, globin mRNA is translated well and appears to compete with endogenous mRNAs for the limiting component of the translational machinery as it is released. Our results are consistent with the hypothesis that either ribosomes or recruitment factors are gradually activated after fertilization or ammonia treatment, that such components are the rate-limiting factor, and that they impart the typical sigmoidal increase in protein synthesis rate observed in fertilized eggs before the first cleavage.

Small cytoplasmic RNAs from human placental free mRNPs. Structure and their effect on in vitro protein synthesis

A new family of small cytoplasmic RNA species (scRNAs) was found to be associated with human term-placental free messenger ribonucleoprotein particles (mRNPs). Placental scRNAs strongly inhibit translation of both homologous and heterologous mRNAs in a cell-free rabbit reticulocyte system. scRNAs could be resolved into at least four different RNA species. One of the RNA molecules, scRNA species 1, was the most potent protein synthesis inhibitor found among the placental scRNAs. The nucleotide sequence of the scRNA species 1 was determined. In spite of its short length, scRNA species 1 still exhibited a very strong inhibitory effect on the in vitro protein synthesis. scRNAs were found to be complexed with proteins in the form of scRNPs. Proteins of these complexes enhanced the inhibitory effect of scRNAs on in vitro translation. Experiments provided evidence that inhibition of in vitro protein synthesis by the scRNAs is not dependent upon mRNA concentration. However, inhibition can be overcome by increasing the ratio lysate/scRNAs, thus suggesting that scRNAs act on some essential component of the cell-free system. The degree of inhibition is decreased when scRNAs are added after the start of translation, suggesting that scRNAs (or scRNPs) interfere with the initiation stage of translation, probably acting on an initiation factor(s). Placental scRNAs are unique in their size, being smaller than other known scRNAs. Their association with free cytoplasmic repressed mRNPs in human placenta suggests that scRNAs play a role in the regulation of mRNP metabolism and, consequently, in the control of mRNA translation.

The role of cap methylation in the translational activation of stored maternal histone mRNA in sea urchin embryos

Cap methylation was examined in the early sea urchin embryo. Nucleotide analyses of 3H-methyl methionine-labeled RNA in two-cell embryos and in unfertilized eggs show that fertilization activates the cap methylation of about 10(7) RNA molecules. Greater than 37% of methyl-labeled RNAs following fertilization hybridize with so-called early histone genes H1, H4, and H2B, which encode a subpopulation of the maternal mRNA molecules. Activation of RNA cap methylation is inhibited by aphidicolin, but not by actinomycin D, suggesting that this process is temporally coordinated with DNA replication, but independent of RNA transcription. These results indicate that the translational activation of maternal early histone mRNA during fertilization is a consequence of cap methylation of mRNAs incompletely formed during oogenesis.

Multiple levels of regulation of protein synthesis at fertilization in sea urchin eggs

Fertilization of sea urchin eggs results in a large stimulation of protein synthesis. This increase in protein synthesis is mediated by the mobilization of stored maternal mRNA (mRNPs) into polysomes, but the details of the molecular mechanisms which regulate this process are not well understood. Using a sea urchin egg cell-free translation system, evidence has been obtained which indicates that the capacity to initiate protein synthesis on new mRNAs is limited. Addition of exogenous mRNAs failed to stimulate overall protein synthesis, whereas supplementing the system with a nuclease-treated reticulocyte lysate, an S-100 supernatant fraction, or purified eIF-2 stimulated nearly twofold. In addition, the levels of 43 S preinitiation complexes containing a 40 S ribosomal subunit and methionyl-tRNA were increased at pH 7.4 compared to pH 6.9, or when reticulocyte S-100 was added. However, other experiments showed clearly that mRNA availability may also regulate translation in the sea urchin egg. Sea urchin lysates only stimulated poorly the nuclease-treated reticulocyte lysate system, and the mRNPs in the sea urchin lysate did not bind to reticulocyte 43 S preinitiation complexes. Since purified sea urchin egg mRNA was active in both assays, the bulk of sea urchin mRNA must be masked in the egg, and remain masked in the in vitro assays. Thus, protein synthesis appears to be regulated at both the level of mRNA availability and the activity of components of the translational machinery.

Informational content of the echinoderm egg

The sea urchin egg contains a store of mRNA synthesized during oogenesis but translated only after fertilization, which accounts for a large, rapid increase in the rate of synthesis of largely the same set of proteins synthesized by eggs. Starfish oocytes contain a population of stored maternal mRNA that becomes actively translated upon GVBD and codes for a set of proteins distinct from that synthesized by oocytes. The sequence complexity of RNA in echinoderm eggs is about 3.5 x 10(8) nucleotides, enough to code for about 12,000 different mRNAs averaging 3 kb in length. About 2-4% of the egg RNA functions as mRNA during early embryonic development; most of the sequences are rare, represented in a few thousand copies per egg, but some are considerably more abundant. Many of the stored RNA sequences accumulate during the period of vitellogenesis, which lasts a few weeks. The mechanisms of storage and translational activation of maternal mRNA are not well understood. Histone mRNAs are sequested in the egg pronucleus until first cleavage, but other mRNAs are widely distributed in the cytoplasm. The population of maternal RNA includes many very large molecules having interspersed repetitive sequence transcripts colinear with single-copy sequences. The structural features of much of the cytoplasmic maternal RNA is thus reminiscent of incompletely processed nuclear precursors of mRNA. The functional role of these strange molecules is not understood, but many interesting possibilities have been considered. For instance, they may be segregated into different cell lineages during cleavage and/or they may become translationally activated by selective processing during development. Maternal mRNA appears to be underloaded with ribosomes when translated, possibly because the coding sequences are short relative to the size of the mRNA. Most abundant and many rare mRNA sequences persist during embryonic development. The rare sequence molecules are replaced by newly synthesized RNA, but some abundant maternal transcripts appear to persist throughout embryonic development. Most of the proteins present in the egg do not change significantly in mass during development, but a few decline or accumulate substantially. Together, these observations indicate that much of the information for embryogenesis is stored in the egg, although substantial changes in gene expression occur during development.

Translational repression of mRNA for eucaryotic elongation factors in Friend erythroleukemia cells

Poly(A)-containing mRNA was prepared from polyribosomes and postpolyribosomal messenger ribonucleoprotein particles (mRNP) from Friend erythroleukemic cells. Both mRNA types were translated in vitro and the 35S-labeled translation products examined by two-dimensional gel electrophoresis. Among the most abundant untranslated mRNA species was the mRNA coding for eucaryotic elongation factor Tu (eEF-Tu). In addition, the mRNA for eucaryotic elongation factor Ts was also present in Friend cells in untranslated form. Calculations based on translation assays indicate that eEF-Tu represents about 15% of the translation products of RNP mRNA and that approximately 40% of the eEF-Tu synthesized in vitro is encoded by translationally repressed mRNA. This repressed mRNA can be activated by addition of cycloheximide to cell cultures. At the level of 0.1 micrograms/ml, cycloheximide was found to inhibit cellular protein synthesis by about 50% while augmenting the relative rate of eEF-Tu synthesis 1.6-fold. This result suggested that eEF-Tu mRNA might initiate poorly. However, addition of supersaturating levels of mRNA to a reticulocyte lysate augmented eEF-Tu synthesis about twofold, while generally depressing the synthesis of other proteins by about 40%. Thus the storage of large amounts of eEF-Tu mRNA in vivo is unlikely to be due directly to the ineffectiveness of the mRNA in competing for the initiation machinery of the cell. The results presented in this report suggest that the supply of active eEF-Tu in erythroleukemic cells is controlled, at least in part, by a translational mechanism.

Evolutionary conservation of DNA coding for maternal RNA in sea urchins

The extent of evolutionary conservation of DNA complimentary to RNA stored in the mature oocyte of the sea urchin S. purpuratus has been assessed. To do this, such DNA was hybridized with total genomic DNA of S. purpuratus and S. franciscanus and the thermal stability of the resultant duplexes was measured by two methods. In the first method, the duplexes were bound to hydroxylapatite and thermally eluted; the difference in thermal stability between homologous and heterologous duplexes averaged 6.9 degrees C in duplicate determinations. In the second experiment, the same hybrids were thermally melted in 2.4M tetraethylammonium chloride, then assayed with S1 nuclease; the difference in thermal stability of homologous and heterologous duplexes was 4.8 degrees C. Either value is significantly lower than the divergence of total single-copy DNA among these species as measured by the same techniques. This demonstrates that DNA sequences complimentary to maternal RNA are conserved during evolution, and thus that a high fraction of them are likely to be physiologically functional.

Isolation and characterization of a translation inhibitor from human term placenta

An inhibitor of protein synthesis has been isolated from free cytoplasmic ribonucleoprotein particles of human term placenta. The inhibitor is resistant to phenol, DNase, proteinase K, and heating at 100 degrees C, but is sensitive to alkaline hydrolysis. These data suggest that the inhibitor is RNA. Experiments provide evidence that this preparation contains no RNase contaminant and does not induce an RNase in this assay system. Three lines of evidence suggest that the inhibitor acts at the initiation of protein synthesis in the wheat germ translation system. First, a lag occurs before cessation of translation when the inhibitor is added to translating polyribosomes. This lag is identical to that seen upon the addition of aurintricarboxylic acid, a known inhibitor of initiation. Second, sucrose gradient analyses demonstrate that, when the inhibitor is present at the start of translation, 40 S complexes form, but neither 80 S complexes nor polyribosomes are seen. Third, gradient analyses show that, when the inhibitor is added to translating polyribosomes, 40 S complexes accumulate with a progressive loss of polyribosomes. Finally, the extent of inhibition depends upon the amount of wheat germ extract added to the reaction mixture and not the amount of mRNA present. This suggests an interaction between the inhibitor and a component of the wheat germ extract.

Alternative modes of enkephalin biosynthesis regulation by reserpine and cyclic AMP in cultured chromaffin cells

Exposure of bovine chromaffin cells in primary culture to 5 microM reserpine or 25 microM forskolin results in an increase in enkephalin peptide levels within 24-48 hr; 25 microM forskolin (or cholera toxin at 50 micrograms/ml) causes a 1.5- to 2-fold increase in enkephalin peptide levels, which is maximal after 48 hr of exposure and is totally blocked by addition of cycloheximide (0.5 microgram/ml). Reserpine (5 microM) elicits a 1.5- to 2-fold increase in enkephalin peptide levels within 24 hr, which is only partially blocked by cycloheximide. Chromatographic analysis of cellular extracts shows that forskolin increases levels of both [Met]enkephalin pentapeptide and high molecular weight enkephalin-containing peptides, while reserpine causes an increase in [Met]enkephalin pentapeptide and a concomitant decrease in high molecular weight enkephalin-containing peptides, suggesting enhanced conversion of enkephalin precursor(s) to the mature polypeptide hormone. Measurement of preproenkephalin messenger RNA (mRNAenk) by RNA blot hybridization with a cDNA probe for mRNAenk reveals that forskolin and cholera toxin cause a relatively rapid (less than 17 hr) 3- to 5-fold increase in mRNAenk, while exposure to reserpine elicits a gradual decrease in enkephalin mRNA (a 50%-80% decline) beginning within 24 hr and continuing over a 72-hr period. These results suggest that forskolin and reserpine differentially regulate enkephalin biosynthesis in cultured chromaffin cells, the former by increasing, presumably via a cAMP-dependent mechanism, cellular mRNA coding for preproenkephalin and the latter by a post-translational increase in proenkephalin processing.

Cytoplasmic mRNA-protein complexes of chicken muscle cells and their role in protein synthesis

Irradiation of chicken muscle cells with ultraviolet light (254 nm) to cross-link RNA and protein moieties was used to examine the polypeptide complements of cytoplasmic mRNA-protein complexes (mRNP). The polypeptides of translationally active mRNP complexes released from polysomes were compared to the repressed nonpolysomal cytoplasmic (free) mRNP complexes. In general, all of the polypeptides present in free mRNPs were also found in the polysomal mRNPs. In contrast to polysomal mRNPS, polypeptides of Mr 28 000, 32 000, 46 000, 65 000 and 150 000 were either absent or present in relatively smaller quantities in free mRNP complexes. On the other hand, the relative proportion of polypeptides of Mr 130 000 and 43 000 was higher in free mRNPs than in polysomal mRNP complexes. To examine the role of cytoplasmic mRNP complexes in protein synthesis or mRNA metabolism, the changes in these complexes were studied following (a) inhibition of mRNA synthesis and (b) heat-shock treatment to alter the pattern of protein synthesis. Actinomycin D was used to inhibit mRNA synthesis in chick myotubes. The possibility of newly synthesized polypeptides of cytoplasmic mRNP complexes being assembled into these complexes in the absence of mRNA synthesis was examined. These studies showed that the polypeptides of both free and polysomal mRNP complexes can bind to pre-existing mRNAs, therefore suggesting that polypeptides of mRNP complexes can be exchanged with a pool of RNA-binding proteins. In free mRNP complexes, this exchange of polypeptides is significantly slower than in the polysomal mRNP complexes. Heat-shock treatment of chicken myotubes induces the synthesis of three polypeptides of Mr = 81 000, 65 000 and 25 000 (heat-shock polypeptides). Whether this altered pattern of protein synthesis following heat-shock treatment could affect the polypeptide composition of translationally active polysomal mRNPs was examined. The results of these studies show that, compared to normal cells, more newly synthesized polypeptides were assembled into polysomal mRNPs following heat-shock treatment. A [35S]methionine-labeled polypeptide of Mr = 80 000 was detected in mRNPs of heat-shocked cells, but not of normal cells. This polypeptide was, however, detected by AgNO3 staining of the unlabeled polypeptide of mRNP complexes of normal cells. These results, therefore, suggest that the assembly of newly synthesized 80 000-Mr polypeptide to polysomal mRNPs was enhanced following induction of new heat-shock mRNAs. The results of these studies reported here have been discussed in relation to the concept that free mRNP complexes are inefficiently translated in vivo.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Modification of ribosomal proteins in sea urchin eggs following fertilization

Analysis of the ribosomal proteins in sea urchin eggs by two-dimensional polyacrylamide gel electrophoresis revealed postfertilization changes in the proteins of both the small and the large subunits. Five egg-ribosomal proteins (S7, S16, S19, L19, L31) appeared to undergo rapid changes to the corresponding embryo-specific proteins. These changes were completed within 30 min after fertilization, and identical electrophoretic patterns were observed among the different developmental stages of embryos. One of the five proteins, S7, showed an increase in the phosphorylated form. The remainder showed qualitative shifts to the corresponding embryo-specific proteins; however, peptide map analyses revealed the existence of common structural units between the corresponding proteins. These modifications were observed in the three species of sea urchin studied (Pseudocentrotus depressus, Hemicentrotus pulcherrimus and Anthocidaris crassispina), except in the case of one protein (L31). Purification of ribosomes by different procedures based on high-salt treatment gave the same results with respect to the egg-specific and embryo-specific proteins.