Full-grown Xenopus oocytes arrest at the G2/M border of meiosis I. Progesterone breaks this arrest, leading to the resumption of the meiotic cell cycles and maturation of the oocyte into a fertilizable egg. In these oocytes, progesterone interacts with an unidentified surface-associated receptor, which induces a non-transcriptional signalling pathway that stimulates the translation of dormant c-mos messenger RNA. Mos, a mitogen-activated protein (MAP) kinase kinase kinase, indirectly activates MAP kinase, which in turn leads to oocyte maturation. The translational recruitment of c-mos and several other mRNAs is regulated by cytoplasmic polyadenylation, a process that requires two 3' untranslated regions, the cytoplasmic polyadenylation element (CPE) and the polyadenylation hexanucleotide AAUAAA. Although the signalling events that trigger c-mos mRNA polyadenylation and translation are unclear, they probably involve the activation of CPEB, the CPE binding factor. Here we show that an early site-specific phosphorylation of CPEB is essential for the polyadenylation of c-mos mRNA and its subsequent translation, and for oocyte maturation. In addition, we show that this selective, early phosphorylation of CPEB is catalysed by Eg2, a member of the Aurora family of serine/threonine protein kinases.
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.
CPEB is an RNA binding protein that interacts with the maturation-type cytoplasmic polyadenylation element (CPE) (consensus UUUUUAU) to promote polyadenylation and translational activation of maternal mRNAs in Xenopus laevis. CPEB, which is conserved from mammals to invertebrates, is composed of three regions: an amino-terminal portion with no obvious functional motif, two RNA recognition motifs (RRMs), and a cysteine-histidine region that is reminiscent of a zinc finger. In this study, we investigated the physical properties of CPEB required for RNA binding. CPEB can interact with RNA as a monomer, and phosphorylation, which modifies the protein during oocyte maturation, has little effect on RNA binding. Deletion mutations of CPEB have been overexpressed in Escherichia coli and used in a series of RNA gel shift experiments. Although a full-length and a truncated CPEB that lacks 139 amino-terminal amino acids bind CPE-containing RNA avidly, proteins that have had either RRM deleted bind RNA much less efficiently. CPEB that has had the cysteine-histidine region deleted has no detectable capacity to bind RNA. Single alanine substitutions of specific cysteine or histidine residues within this region also abolish RNA binding, pointing to the importance of this highly conserved domain of the protein. Chelation of metal ions by 1,10-phenanthroline inhibits the ability of CPEB to bind RNA; however, RNA binding is restored if the reaction is supplemented with zinc. CPEB also binds other metals such as cobalt and cadmium, but these destroy RNA binding. These data indicate that the RRMs and a zinc finger region of CPEB are essential for RNA binding.In many animals, maternal mRNAs that are synthesized and stored in a translationally dormant form during oogenesis become activated either upon reentry into the meiotic divisions (oocyte maturation) or after fertilization. These mRNAs encode a number of important products such as those that drive the early embryonic cell divisions, establish embryonic polarity, and determine certain cell lineages (15,40,42). The translational repression/activation of maternal mRNA appears to be quite complex and involves inhibitory (masking) cis elements (10,16,32,37), some clearly defined inhibitory proteins (4, 31), positively acting cis elements (26,33,38,41), and activator proteins (14). In several cases, translational activation is not direct but instead is mediated by changes in poly(A) tail length. That is, in oocytes, several translationally dormant mRNAs contain relatively short poly(A) tails, usually consisting of fewer than 20 nucleotides. During oocyte maturation or early embryogenesis, several specific mRNAs undergo poly(A) elongation and resulting translational activation (15,30,42).In maturing Xenopus oocytes, two cis elements located in the 3Ј untranslated region (UTR) of target RNAs, the cytoplasmic polyadenylation element (CPE) and the hexanucleotide AAU AAA, regulate poly(A) elongation. The CPE, which has the general structure UUUUUAU, usually resides within 30 nucleotides 5Ј...
Cytoplasmic poly(A) elongation is widely utilized during the early development of many organisms as a mechanism for translational activation. Targeting of mRNAs for this mechanism requires the presence of a U-rich element, the cytoplasmic polyadenylation element (CPE), and its binding protein, CPEB. Blocking cytoplasmic polyadenylation by interfering with the CPE or CPEB prevents the translational activation of mRNAs that are crucial for oocyte maturation. The CPE sequence and CPEB are also important for translational repression of mRNAs stored in the Xenopus oocyte during oogenesis. To understand the contribution of protein metabolism to these two roles for CPEB, we have examined the mechanisms influencing the expression of CPEB during oogenesis and oocyte maturation. Through a comparison of CPEB mRNA levels, protein synthesis, and accumulation, we find that CPEB is synthesized during oogenesis and stockpiled in the oocyte. Minimal synthesis of CPEB, <3.6%, occurs during oocyte maturation. In late oocyte maturation, 75% of CPEB is degraded coincident with germinal vesicle breakdown. Using proteasome and ubiquitination inhibitors, we demonstrate that CPEB degradation occurs via the proteasome pathway, most likely through ubiquitin-conjugated intermediates. In addition, we demonstrate that degradation requires a 14 amino acid PEST domain.
Meiotic progression in Xenopus oocytes, and all other oocytes investigated, is dependent on polyadenylation-induced translation of stockpiled maternal mRNAs. Early during meiotic resumption, phosphorylation of CPE-binding protein (CPEB) is required for polyadenylation-induced translation of mRNAs encoding cell cycle regulators. Xenopus Gef (XGef), a Rho-family guanine-exchange factor, influences the activating phosphorylation of CPEB. An exchange-deficient version of XGef does not, therefore implicating Rho-family GTPase function in early meiosis. We show here that Clostridium difficile Toxin B, a Rho-family GTPase inhibitor, does not impair early CPEB phosphorylation or progression to germinal vesicle breakdown, indicating that XGef does not influence these events through activation of a Toxin-B-sensitive GTPase. Using the inhibitors U0126 for mitogen-activated protein kinase (MAPK), and ZM447439 for Aurora kinase A and Aurora kinase B, we found that MAPK is required for phosphorylation of CPEB, whereas Aurora kinases are not. Furthermore, we do not detect active Aurora kinase A in early meiosis. By contrast, we observe an early, transient activation of MAPK, independent of Mos protein expression. MAPK directly phosphorylates CPEB on four residues (T22, T164, S184, S248), but not on S174, a key residue for activating CPEB function. Notably, XGef immunoprecipitates contain MAPK, and this complex can phosphorylate CPEB. MAPK may prime CPEB for phosphorylation on S174 by an as-yet-unidentified kinase or may activate this kinase.
The candidate testis-determining Y genes of the mouse Zfy-1 and Zfy-2, encode proteins containing an acidic amino terminus and a carboxyl terminus composed of 13 zinc fingers. The zinc finger domain is conserved among human and mouse zinc finger X and Y genes. We report a 6-amino-acid deletion in the Zfy-2 zinc finger domain of laboratory mice possessing musculus Y chromosomes. The effect of this deletion on the function of Zfy-2 is not known. The reverse transcriptase-polymerase chain reaction (RT-PCR) and Northern blot techniques were used to study expression of Zfy in adults and fetuses. In adults, the data suggest that Zfy-1 and Zfy-2 transcription is linked to spermatogenesis, that transcription increases with the initiation of meiosis, and that high levels of these mRNAs are found in postmeiotic round spermatid cells. The data also suggest that differential expression of these two genes is present with expression of Zfy-2 being slightly greater than Zfy-1. In fetuses, Zfy transcripts were detected in several tissues, including the testes. In contrast to the situation in adults, the data suggest that expression of Zfy-1 is greater than that of Zfy-2. The data suggesting that Zfy-1 expression is present in fetal testes support the hypothesis that this gene plays a role in testis differentiation. However, because the Zfy genes are apparently also expressed during spermatogenesis and in fetal organs other than testes, they may serve additional functions besides their postulated role in testis determination.
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