Translational control during early development

Early development in many animals is programmed by maternally inherited messenger RNAs. Many of these mRNAs are translationally dormant in immature oocytes, but are recruited onto polysomes during meiotic maturation, fertilization, or early embryogenesis. In contrast, other mRNAs that are translated in oocytes are released from polysomes during these later stages of development. Recent studies have begun to define the cis and trans elements that regulate both translational repression and translational induction of maternal mRNA. The inhibition of translation of some mRNAs during early development is controlled by discrete sequences residing in the 3' and 5' untranslated regions, respectively. The translation of other RNAs is due to polyadenylation which, at least in oocytes of the frog Xenopus laevis, is regulated by a U-rich cytoplasmic polyadenylation element (CPE). Although similar, the CPE sequences of various mRNAs are sufficiently different to be bound by different proteins. Two of these proteins and their interactions are described here.     

Sequence-specific adenylations and deadenylations accompany changes in the translation of maternal messenger RNA after fertilization of Spisula oocytes

A dramatic change in the pattern of protein synthesis occurs within ten minutes after fertilization of Spisula oocytes. This change is regulated entirely at the translational level. We have used DNA clones complementary to five translationally regulated messenger RNAs to follow shifts in mRNA utilization at fertilization and to characterize alterations in mRNA structure that accompany switches in translational activity in vivo. Four of the mRNAs studied are translationally inactive in the oocyte. After fertilization two of these mRNAs are completely recruited onto polysomes, and two are partially recruited. All four of these mRNAs have very short poly(A) tracts in the oocyte; after fertilization the poly(A) tails lengthen considerably. In contrast, a fifth mRNA, that encoding alpha-tubulin mRNA, is translated very efficiently in the oocyte and is rapidly lost from polysomes after fertilization. Essentially all alpha-tubulin mRNA in the oocyte is poly(A)+ and a large portion of this mRNA undergoes complete deadenylation after fertilization. These results reveal a striking relationship between changes in adenylation and translational activity in vivo. This correlation is not perfect, however. Evidence for and against a direct role for polyadenylation in regulating these translational changes is discussed. Changes in poly(A) tails are the only alterations in mRNA sizes that we have been able to detect. This indicates that, at least for the mRNAs studied here, translational activation is not due to extensive processing of larger translationally incompetent precursors. We have also isolated several complementary DNA clones to RNAs encoded by the mitochondrial genome. Surprisingly, the poly(A) tracts of at least two of the mitochondrial RNAs also lengthen in response to fertilization.     

Maturation-specific deadenylation in Xenopus oocytes requires nuclear and cytoplasmic factors.

During the meiotic maturation of Xenopus oocytes, maternal mRNAs that lack a cytoplasmic polyadenylation element are deadenylated and translationally inactivated. In this report, we have characterized the regulation of poly(A) removal during maturation. Deadenylation in vivo is detected only after germinal vesicle breakdown and does not require de novo protein synthesis. Enucleated oocytes do not deadenylate either endogenous or microinjected RNAs upon maturation, indicating that a nuclear component is required for poly(A) removal. Whole cell extracts prepared from both immature and mature oocytes deadenylate exogenous RNA substrates in vitro. Deadenylation activity is not detected in isolated nuclear or cytoplasmic extracts obtained from immature oocytes, but is reconstituted when these fractions are combined in vitro. These results indicate that the factors required for deadenylation activity are present in immature oocytes, but that poly(A) removal is prevented by the sequestration of one or more of these components within the nucleus. Maturation-specific deadenylation of maternal mRNAs occurs upon the release of nuclear factors into the cytoplasm at germinal vesicle breakdown.     

Maternal mRNA expression in early development: regulation at the 3' end

Early development in many animals is programmed by maternal mRNAs inherited by the fertilized egg. Many of these RNAs are translationally dormant in immature oocytes, but are recruited onto polysomes during meiotic maturation or fertilization. Polyadenylation plays a major role in controlling the translation of maternal mRNA during these times of development. Polyadenylation, in turn, is dependent upon two cis elements that reside in the 3'-terminal region of responsive mRNAs. In two cases, the factors that interact with these regions have been examined. The half-life of maternal mRNA also is regulated by polyadenylation, which again is controlled by 3'-terminal cis elements. The recent literature covering these topics is reviewed.     

Translational control in oocyte development

Translational control of specific mRNAs is a widespread mechanism of gene regulation, and it is especially important in pattern formation in the oocytes of organisms in which the embryonic axes are established maternally. Drosophila and Xenopus have been especially valuable in elucidating the relevant molecular mechanisms. Here, we comprehensively review what is known about translational control in these two systems, focusing on examples that illustrate key concepts that have emerged. We focus on protein-mediated translational control, rather than regulation mediated by small RNAs, as the former appears to be predominant in controlling these developmental events. Mechanisms that modulate the ability of the specific mRNAs to be recruited to the ribosome, that regulate polyadenylation of specific mRNAs, or that control the association of particular mRNAs into translationally inert ribonucleoprotein complexes will all be discussed.     

Visualization of the reconstituted FRGY2-mRNA complexes by electron microscopy

Xenopus oocytes store large quantities of translationally dormant mRNA in the cytoplasm as storage messenger ribonucleoprotein particles (mRNPs). The Y-box proteins, mRNP3 and FRGY2/mRNP4, are major RNA binding components of maternal storage mRNPs in oocytes. In this study, we show that the FRGY2 proteins form complexes with mRNA, which leads to mRNA stabilization and translational repression. Visualization of the FRGY2-mRNA complexes by electron microscopy reveals that FRGY2 packages mRNA into a compact RNP. Our results are consistent with a model that the Y-box proteins function in packaging of mRNAs to store them stably for a long time in the oocyte cytoplasm.     

The mouse Y-box protein, MSY2, is associated with a kinase on non-polysomal mouse testicular mRNAs

In male germ cells many mRNAs are sequestered by proteins into translationally silent messenger ribo-nucleoprotein (mRNP) particles. These masked paternal mRNAs are stored and translated at specific times of germ cell development. Little is known about the mammalian testicular mRNA masking proteins bound to non-polysomal mRNAs. In this report, the major proteins binding to non-polysomal testicular mRNAs were isolated and analyzed. The two predominant proteins identified were: a Y-box protein (MSY2), the mammalian homolog to the Xenopus oocyte masking protein FRGY2/mRNP3+4, and a poly(A) binding protein. A kinase activity was also found associated with these non-polysomal RNAs. The kinase co-immunoprecipitates with MSY2 and phosphorylates MSY2 in vitro. The MSY2 associated kinase is not casein kinase 2, the kinase believed to phosphorylate mRNP3+4 in oocytes, but a yet unidentified kinase. MSY2 was found to be phosphorylated in vivo and MSY2 dephosphorylation led to a decrease in its affinity to bind RNA as judged by northwestern blotting. Therefore, testicular masked mRNAs may be regulated by the phosphorylation state of MSY2. Reconstitution experiments in which non-polysomal mRNA-binding proteins are dissociated from their RNAs and allowed to bind to exogenous mRNAs suggest that MSY2 binds RNA in a sequence-independent fashion. Furthermore, association of the non-polysomal derived proteins to exogenous non-specific mRNAs led to their translational repression in vitro.     

Expression of alpha- and beta-tubulin genes during development of sea urchin embryos

Mature unfertilized eggs of the sea urchin Lytechinus pictus contain multiple alpha-tubulin mRNAs, which range in size from 1.75 to 4.8 kb, and two beta-tubulin mRNAs, 1.8 and 2.25 kb. These mRNAs were found at similar levels throughout the early cleavage stages. RNA gel blot hybridizations showed that prominent quantitative and qualitative changes in tubulin mRNAs occurred between the early blastula and hatched blastula stages. The overall amounts of alpha- and beta-tubulin mRNAs increased two- to fivefold between blastula and pluteus. These increases were due mainly to a rise in a 1.75-kb alpha RNA and a new 2.0-kb beta RNA. Other, minor changes also occurred during subsequent development. All size classes of alpha- and beta-tubulin RNAs in early and late embryos contained poly(A)+ translatable sequences. As reported earlier, some of each of the alpha RNAs, but neither of the beta RNAs, are translated in the egg and a small portion of each of the stored alpha and beta RNAs is recruited onto polysomes within 30 min of fertilization. In the work described here, subsequent development up to the morula stage was accompanied by a gradual recruitment of tubulin mRNAs into polysomes. By the early blastula stage, most of the maternal tubulin sequences were associated with polysomes. In contrast to the gradual recruitment of maternal sequences throughout cleavage, the tubulin mRNAs which appeared at the blastula stage showed no delay in entering polysomes. The exact fraction of each mRNA that was translationally active at later stages varied somewhat among the individual mRNAs. From the differential hybridization patterns of egg, embryo, and testis RNAs to various tubulin cDNA and genomic DNA probes, it is concluded that at least one gene producing maternal alpha mRNA is different from a second one which is expressed only in testis. Each of the three embryonic beta RNAs is encoded by a different beta gene; at least two of these different beta genes are also expressed in testis.     

Part of Xenopus translin is localized in the centrosomes during mitosis

During oogenesis, maternal mRNAs are synthesised and stored in a translationally dormant form due to the presence of regulatory elements at the 3' untranslated regions (3'UTR). In Xenopus oocytes, several studies have described the presence of RNA-binding proteins capable to repress maternal-mRNA translation. The testis-brain RNA-binding protein (TB-RBP/Translin) is a single-stranded DNA- and RNA-binding protein which can bind the 3' UTR regions (Y and H elements) of stored mRNAs and can suppress in vitro translation of the mRNAs that contain these sequences. Here we report the cloning of the Xenopus homologue of the TB-RBP/Translin protein (X-translin) as well as its expression, its localisation, and its biochemical association with the protein named Translin associated factor X (Trax) in Xenopus oocytes. The fact that this protein is highly present in the cytoplasm from stage VI oocytes until 48 h embryos and that it has been described as capable to inhibit paternal mRNA translation, indicates that it could play an important role in maternal mRNA translation control during Xenopus oogenesis and embryogenesis. Moreover, we investigated X-translin localisation during cell cycle in XTC cells. In interphase, although a weak and diffuse nuclear staining was observed, X-translin was mostly present in the cytoplasm where it exhibited a prominent granular staining. Interestingly, part of X-translin underwent a remarkable redistribution throughout mitosis and associated with centrosomes, which may suggest a new unknown role for this protein in cell cycle.     

A cis-acting element in the coding region of cyclin B1 mRNA couples subcellular localization to translational timing

Subcellular localization of messenger RNAs (mRNAs) to correct sites and translational activation at appropriate timings are crucial for normal progression of various biological events. However, a molecular link between the spatial regulation and temporal regulation remains unresolved. In immature zebrafish oocytes, translationally repressed cyclin B1 mRNA is localized to the animal polar cytoplasm and its temporally regulated translational activation in response to a maturation-inducing hormone is essential to promote oocyte maturation. We previously reported that the coding region of cyclin B1 mRNA is required for the spatio-temporal regulation. Here, we report that a sequence, CAGGAGACC, that is conserved in the coding region of vertebrate cyclin B1 mRNA is involved in the regulation. Like endogenous cyclin B1 mRNA, reporter mRNAs harboring the sequence CAGGAGACC were localized to the animal polar cytoplasm of oocytes, while those carrying mutations in the sequence (with no change in the coding amino acids) were dispersed in the animal hemisphere of oocytes. Furthermore, translational activation of the mutant mRNAs was initiated at a timing earlier than that of endogenous and wild-type reporter mRNAs during oocyte maturation. Interaction of CAGGAGACC with proteins in vitro suggests that this sequence functions in collaboration with a trans-acting protein factor(s) in oocytes. These findings reveal that the sequence in the coding region of cyclin B1 mRNA plays an important role as a cis-acting element in both subcellular localization and translational timing of mRNA, providing a direct molecular link between the spatial and temporal regulation of mRNA translation.     

The deadenylating nuclease (DAN) is involved in poly(A) tail removal during the meiotic maturation of Xenopus oocytes.

Exonucleolytic degradation of the poly(A) tail is often the first step in the decay of eukaryotic mRNAs and is also used to silence certain maternal mRNAs translationally during oocyte maturation and early embryonic development. We previously described the purification of a poly(A)-specific 3'-exoribonuclease (deadenylating nuclease, DAN) from mammalian tissue. Here, the isolation and functional characterization of cDNA clones encoding human DAN is reported. Recombinant DAN overexpressed in Escherichia coli has properties similar to those of the authentic protein. The amino acid sequence of DAN shows homology to the RNase D family of 3'-exonucleases. DAN appears to be localized in both the nucleus and the cytoplasm. It is not stably associated with polysomes or ribosomal subunits. Xenopus oocytes contain nuclear and cytoplasmic DAN isoforms, both of which are closely related to the human DAN. Anti-DAN antibody microinjected into oocytes inhibits default deadenylation during progesterone-induced maturation. Ectopic expression of human DAN in enucleated oocytes rescues maturation-specific deadenylation, indicating that amphibian and mammalian DANs are functionally equivalent.     

Mechanism of post-segregational killing: translation of Hok, SrnB and Pnd mRNAs of plasmids R1, F and R483 is activated by 3''-end processing.

The gene systems hok/sok of R1, srnB of F and pnd of R483 mediate plasmid maintenance by killing of plasmid-free segregants. Translation of the very stable mRNAs encoding the killer proteins is regulated by small unstable antisense RNAs. The differential decay rates of the inhibitory antisense RNAs and the mRNAs encoding the killer proteins is the basis for the onset of killer mRNA translation in newborn plasmid-free segregants and the killing of these cells. We have suggested previously that this requires that the killer mRNAs occur in two forms. A translationally inactive form was proposed to be converted into a 3'-truncated, translationally active mRNA. In the presence of the antisense RNA, translation from this killer mRNA should be inhibited. In this communication we present in vivo and in vitro evidence that support this model. The requirement for 3'-processing for killer gene expression is demonstrated. By using in vitro techniques it is shown that full-length Hok mRNA is translationally inactive, whereas a 3'-end truncated version of the Hok mRNA is translationally active. In vitro secondary structure probing suggests that the 3'-end of the full-length Hok mRNA folds back onto the translational initiation region of the mok gene and thereby inhibits translation of the mRNA. By inference we conclude that the Pnd and SrnB mRNAs are regulated by a similar mechanism.     

CPEB controls the cytoplasmic polyadenylation of cyclin, Cdk2 and c-mos mRNAs and is necessary for oocyte maturation in Xenopus.

Cytoplasmic polyadenylation is a key mechanism controlling maternal mRNA translation in early development. In most cases, mRNAs that undergo poly(A) elongation are translationally activated; those that undergo poly(A) shortening are deactivated. Poly(A) elongation is regulated by two cis-acting sequences in the 3'-untranslated region (UTR) of responding mRNAs, the polyadenylation hexanucleotide AAUAAA and the U-rich cytoplasmic polyadenylation element (CPE). Previously, we cloned and characterized the Xenopus oocyte CPE binding protein (CPEB), showing that it was essential for the cytoplasmic polyadenylation of B4 RNA. Here, we show that CPEB also binds the CPEs of G10, c-mos, cdk2, cyclins A1, B1 and B2 mRNAs. We find that CPEB is necessary for polyadenylation of these RNAs in egg extracts, suggesting that this protein is required for polyadenylation of most RNAs during oocyte maturation. Our data demonstrate that the complex timing and extent of polyadenylation are partially controlled by CPEB binding to multiple target sites in the 3' UTRs of responsive mRNAs. Finally, injection of CPEB antibody into oocytes not only inhibits polyadenylation in vivo, but also blocks progesterone-induced maturation. This is due to inhibition of polyadenylation and translation of c-mos mRNA, suggesting that CPEB is critical for early development.     

Possible involvement of insulin-like growth factor 2 mRNA-binding protein 3 in zebrafish oocyte maturation as a novel cyclin B1 mRNA-binding protein that represses the translation in immature oocytes

In immature zebrafish oocytes, dormant cyclin B1 mRNAs localize to the animal polar cytoplasm as aggregates. After hormonal stimulation, cyclin B1 mRNAs are dispersed and translationally activated, which are necessary and sufficient for the induction of zebrafish oocyte maturation. Besides cytoplasmic polyadenylation element-binding protein (CPEB) and cis-acting elements in the 3′ untranslated region (UTR), Pumilio1 and a cis-acting element in the coding region of cyclin B1 mRNA are important for the subcellular localization and timing of translational activation of the mRNA. However, mechanisms underlying the spatio-temporal control of cyclin B1 mRNA translation during oocyte maturation are not fully understood. We report that insulin-like growth factor 2 mRNA-binding protein 3 (IMP3), which was initially described as a protein bound to Vg1 mRNA localized to the vegetal pole of Xenopus oocytes, binds to the 3′ UTR of cyclin B1 mRNA that localizes to the animal pole of zebrafish oocytes. IMP3 and cyclin B1 mRNA co-localize to the animal polar cytoplasm of immature oocytes, but in mature oocytes, IMP3 dissociates from the mRNA despite the fact that its protein content and phosphorylation state are unchanged during oocyte maturation. IMP3 interacts with Pumilio1 and CPEB in an mRNA-dependent manner in immature oocytes but not in mature oocytes. Overexpression of IMP3 and injection of anti-IMP3 antibody delayed the progression of oocyte maturation. On the basis of these results, we propose that IMP3 represses the translation of cyclin B1 mRNA in immature zebrafish oocytes and that its release from the mRNA triggers the translational activation.