Initiation does not limit the rate of globin synthesis in message-injected Xenopus oocytes

Eukaryotic initiation factor 4A stimulates translation in microinjected Xenopus oocytes

The injection of heterologous mRNA into fully grown Xenopus oocytes results not only in the synthesis of the heterologous protein but also in a reciprocal decrease in the synthesis of endogenous proteins. This indicates that injected and endogenous mRNAs compete for some component which is rate-limiting for translation in oocytes. We have attempted to identify this rate-limiting translational component. We find that heterologous and homologous polysomes compete with endogenous mRNAs as effectively as naked mRNA, indicating that polysomes do not contain detectable levels of the rate-limiting factor. In addition, we have used micrococcal nuclease digestion and a mRNA-specific oligonucleotide to destroy the mRNA component of polysomes. The remaining polysome factors, when injected into oocytes, failed to stimulate translation. When several eukaryotic translation initiation factors were injected into oocytes, initiation factor 4A consistently increased general oocyte protein synthesis by about twofold. It is possible that the availability of eIF-4A in oocytes is a key factor in limiting the overall rate of protein 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.

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.

The biosynthesis of biologically active proteins in mRNA-microinjected Xenopus oocytes

The basic properties of mRNA-injected Xenopus oocytes as a heterologous system for the production of biologically active proteins will be reviewed. The advantages and limitations involved in the use of this in ovo system will be discussed, as compared with in vitro cell-free translation systems and with in vivo microinjected mammalian cells in culture. The different assay systems that have been utilized for the identification of the biological properties of oocyte-produced proteins will be described. This section will review the determination of properties such as binding of natural ligands, like heme or alpha-bungarotoxin; immunological recognition by antibodies; subcellular compartmentalization and/or secretion; various enzymatic catalytic activities; and induction in ovo of biological activities that affect other living cells in culture, such as those of interferon and of the T-cell receptor. The limitations involved in interpretation of results obtained using mRNA-injected oocytes will be critically reviewed. Special attention will be given to the effect of oocyte proteases and of changes in the endogenous translation rate on quantitative measurements of oocyte-produced proteins. In addition, the validity of the various measurement techniques will be evaluated. The various uses of bioassays of proteins produced in mRNA-injected Xenopus oocytes throughout the last decade will be reviewed. Nuclear and cytoplasmic injections, mRNA and protein turnover measurements and abundance calculations, and the use of in ovo bioassays for molecular cloning experiments will be discussed in this section. Finally, potential future uses of the oocyte system in various fields of research, such as immunology, neurobiology, and cell biology will be suggested.

The oocyte as a secretory cell

Xenopus laevis oocytes secrete a large variety of foreign secretory proteins after the microinjection of mRNA or DNA. Two classes of such proteins are discussed in detail. These are the chick oviduct proteins ovalbumin and lysozyme, and the mouse MOPC 21 immunoglobulin. The injection of mRNAs for mouse immunoglobulin heavy or light chain leads to the synthesis, segregation, but not secretion of the encoded proteins unless the two mRNAs are simultaneously or sequentially injected into the same oocytes. Chicken ovalbumin and lysozyme are synthesized and secreted from oocyte after the injection of either oviduct mRNA or cloned DNA (ovalbumin). The secreted lysozyme is exported considerably faster than ovalbumin; however, 40% of the lysozyme synthesized cannot be secreted and, after fractionation of oocytes on sucrose gradients, is found in a higher density position than ovalbumin. No competition at the level of secretion or translation was noted when different amounts of immunoglobulin and ovalbumin mRNAs were injected into oocytes. However, the co-injection of ovalbumin mRNA and mRNAs encoding anti-ovalbumin immunoglobins resulted in the formation of a complex of the two types of protein within the oocyte. In these circumstances, secretion of the immunoglobulin was severely reduced.

Mobilization of maternal mRNA in amphibian eggs with special reference to the possible role of membraneous supramolecular structures

Current knowledge of the mechanism of mobilization of maternal mRNA is summarized herein and a working hypothesis has been constructed to explain the mechanism on the assumption that the mRNA enters the cytoplasm in association with the cytoplasmic membraneous structures and is then stored in the structures until liberation and relocation at the step of oocyte maturation. An extensive turnover of poly(A) sequences as well as the occurrence of repetitive sequences in the maternal mRNA may be relevant to mRNA activation.

Translational control of protein synthesis after infection by vesicular stomatitis virus

Four hours after infection of BHK cells by vesicular stomatitis virus (VSV), the rate of total protein synthesis was about 65% that of uninfected cells and synthesis of the 12 to 15 predominant cellular polypeptides was reduced to a level about 25% that of control cells. As determined by in vitro translation of isolated RNA and both one- and two-dimensional gel analyses of the products, all predominant cellular mRNA's remained intact and translatable after infection. The total amount of translatable mRNA per cell increased about threefold after infection; this additional mRNA directed synthesis of the five VSV structural proteins. To determine the subcellular localization of cellular and viral mRNA before and after infection, RNA from various sizes of polysomes and nonpolysomal ribonucleoproteins (RNPs) was isolated from infected and noninfected cells and translated in vitro. Over 80% of most predominant species of cellular mRNA was bound to polysomes in control cells, and over 60% was bound in infected cells. Only 2 of the 12 predominant species of translatable cellular mRNA's were localized to the RNP fraction, both in infected and in uninfected cells. The average size of polysomes translating individual cellular mRNA's was reduced about two- to threefold after infection. For example, in uninfected cells, actin (molecular weight 42,000) mRNA was found predominantly on polysomes with 12 ribosomes; after infection it was found on polysomes with five ribosomes, the same size of polysomes that were translating VSV N (molecular weight 52,000) and M (molecular weight 35,000) mRNA. We conclude that the inhibition of cellular protein synthesis after VSV infection is due, in large measure, to competition for ribosomes by a large excess of viral mRNA. The efficiency of initiation of translation on cellular and viral mRNA's is about the same in infected cells; cellular ribosomes are simply distributed among more mRNA's than are present in growing cells. About 20 to 30% of each of the predominant cellular and viral mRNA's were present in RNP particles in infected cells and were presumably inactive in protein synthesis. There was no preferential sequestration of cellular or viral mRNA's in RNPs after infection.

Messenger RNA competition in living Xenopus oocytes

When calf lens crystallin mRNA and rabbit globin mRNA are competing for factors limiting protein synthesis in living Xenopus oocytes, no mRNA species is preferentially selected for translation. Differences in the intrinsic translational efficiency of the mRNA species exist, but the relative efficiencies are the same at high and low mRNA concentrations. mRNAs already being translated, in particular endogenous oocyte mRNAs, are less sensitive to competitive inhibition by injected mRNAs. As injected mRNAs gradually become incorporated into the protein-synthesizing machinery of the oocyte, they acquire the same status as the oocyte's own active mRNAs. Exogenous mRNAs this become endogenous mRNAs. These results, together with previous estmates of the translational efficiency of injected heterologous mRNA species, are compatible with the assumption that a large proportion of the endogenous mRNAs is not competing for the translational apparatus of the oocyte and, therefore, probably is present in the temporarily inactivated form.

Maintenance of the ratio of alpha and beta globin synthesis in rabbit reticulocytes

The synthesis of rabbit alpha and beta globins under various conditions was studied using intact reticulocytes and reticulocyte cell-free systems. Raising salt concentration of media in which reticulocytes were incubated with radioactive amino acids reduced the total protein synthesis but did not affect the ratio of alpha to beta globins produced. Using a reticulocyte lysate which had been incubated with micrococcal nuclease to remove the endogenous globin messenger RNA activity, it was found that unlike the intact cell or the untreated lysate very little alpha globin was synthesised on adding purified globin mRNA. These results are discussed in terms of their compatibility with some proposed models of coordination of alpha and beta globin production.