Xenopus laevis zygote arrest 2 (zar2) encodes a zinc finger RNA-binding protein that binds to the translational control sequence in the maternal Wee1 mRNA and regulates translation

Zygote arrest (Zar) proteins are crucial for early embryonic development, but their molecular mechanism of action is unknown. The Translational Control Sequence (TCS) in the 3' untranslated region (UTR) of the maternal mRNA, Wee1, mediates translational repression in immature Xenopus oocytes and translational activation in mature oocytes, but the protein that binds to the TCS and mediates translational control is not known. Here we show that Xenopus laevis Zar2 (encoded by zar2) binds to the TCS in maternal Wee1 mRNA and represses translation in immature oocytes. Using yeast 3 hybrid assays and electrophoretic mobility shift assays, Zar2 was shown to bind specifically to the TCS in the Wee1 3'UTR. RNA binding required the presence of Zn(2+) and conserved cysteines in the C-terminal domain, suggesting that Zar2 contains a zinc finger. Consistent with regulating maternal mRNAs, Zar2 was present throughout oogenesis, and endogenous Zar2 co-immunoprecipitated endogenous Wee1 mRNA from immature oocytes, demonstrating the physiological significance of the protein-RNA interaction. Interestingly, Zar2 levels decreased during oocyte maturation. Dual luciferase reporter tethered assays showed that Zar2 repressed translation in immature oocytes. Translational repression was relieved during oocyte maturation and this coincided with degradation of Zar2 during maturation. This is the first report of a molecular function of zygote arrest proteins. These data show that Zar2 contains a zinc finger and is a trans-acting factor for the TCS in maternal mRNAs in immature Xenopus oocytes.     

Xenopus ElrB, but not ElrA, binds RNA as an oligomer: possible role of the linker

We have shown that ElrA and ElrB, Xenopus ELAV homologues, bind the Vg1 mRNA 3'UTR translation element in Xenopus oocytes and implicated ElrB in mediating translational repression during oogenesis. Here we report that, while ElrA and ElrB are 69% identical and both exhibit RNA binding in the nM range, recombinant ElrB, but not ElrA, is able to oligomerise. This oligomerisation is also seen with the endogenous protein. Both RNA binding and oligomerisation require the linker region flanked with two RNA recognition motifs. Our data demonstrate a novel and unique property of ElrB which may be important for its function as a translational regulator.     

Interaction of proteins with the mRNA for ribosomal protein L1 in Xenopus: structural characterization of in vivo complexes and identification of proteins that bind in vitro to its 5'UTR.

Xenopus r-protein mRNAs are known to be coordinately regulated at the translational level. To find out if RNA/protein interactions are involved in this control mechanism, we have characterized the particles containing the translationally repressed rp-mRNA and we have investigated the proteins that specifically bind to this type of mRNA. By sedimentation analysis and isopycnic centrifugation we have found that the repressed rp-mRNAs are assembled in slow sedimenting complexes where the RNA is prevalent over the protein mass (2.3 to 1). This composition is maintained also after in vitro reconstitution of the particle. We carried out also a detailed analysis of in vitro RNA/protein complex formation by focusing our attention on the 5'UTR, very similar in different rp-mRNAs and important in the translational regulation. We describe specific interactions of L1 mRNA with four proteins. The binding site of two of them, 57 kD and 47 kD, is in the typical pyrimidine sequence at the 5' end and is position dependent. Proteins of the same size interact also with the analogous region of r-protein S1 and L14 mRNA, not with unrelated RNAs. Binding of two other proteins, 31 kD and 24 kD, in the downstream region of the 5'UTR was also observed. The most evident 57 kD protein has been partially purified. Although the binding of these proteins to the r-protein mRNA 5'UTR is specific, their involvement in the translation regulation remains to be proved.     

VgRBP71 stimulates cleavage at a polyadenylation signal in Vg1 mRNA,resulting in the removal of a cis-acting element that represses translation

Translation of Vg1 mRNA is repressed in Xenopus oocytes until it is localized to the vegetal cortex. Localization and translational repression are mediated by separate elements in the 3'UTR of the mRNA. VgRBP71 binds to the 3' end of the localization element and stimulates cleavage at an adjacent polyadenylation signal. The protein has an RNA strand-separation activity that likely underlies this event. Polyadenylation occurs at this site in Vg1 mRNA with the consequence of removing the downstream translational repressor element. Ectopic expression of VgRBP71 in stage II oocytes results in cleavage of the mRNA and premature expression of Vg1 protein. These results support a model in which VgRBP71 activates translation of Vg1 mRNA by promoting the removal of a cis-acting repressor element.     

Identification of a translation inhibitory element (TIE) in the 3' untranslated region of the human interferon-beta mRNA

We have previously reported that the 3' untranslated region (UTR) of the human interferon-beta mRNA has an inhibitory effect on the mRNA translation both in vitro, in a rabbit reticulocyte lysate, and in vivo, in the Xenopus oocyte. In the present study, we identify the sequence in the 3' UTR which is responsible for this translation inhibition. We show that this sequence is located between the 100th and 161st nucleotides downstream from the translation stop codon. It contains several repeats of the A + U-rich consensus octanucleotide UUAUUUAU, which is also present in the 3' UTR of several mRNAs involved in the inflammatory response. We also demonstrate here that the inhibitory effect of the sequence on the mRNA translation does not depend on its position in relation to the termination codon. However, no inhibition of translation is observed when this sequence is inserted in the 5' UTR of the mRNA. The removal of the translation inhibitory sequence not only improves the mRNA translation in Xenopus oocytes but it also strongly decreases the IFN-beta mRNA stability in those cells. This suggests that, in this system at least, the mRNA degradation is linked to its translational efficiency.     

A co-repressor assembly nucleated by Sex-lethal in the 3'UTR mediates translational control of Drosophila msl-2 mRNA

Drosophila Sex-lethal (dSXL)-mediated translational repression of male-specific lethal 2 (msl-2) mRNA is essential for X-chromosome dosage compensation. Binding of dSXL to specific sites in both untranslated regions of msl-2 mRNA is necessary for inhibition of translation initiation. We describe the organization of dSXL as a translational regulator and show that the RNA binding and translational repressor functions are contained within the two RRM domains and a C-terminal heptapeptide extension. The repressor function is dormant unless dSXL binds to msl-2 mRNA with its own RRMs, because dSXL tethering via a heterologous RNA-binding peptide does not elicit translational inhibition. We reveal proteins that crosslink to the msl-2 3' untranslated region (3'UTR) and co-immunoprecipitate with dSXL in a fashion that requires its intact repressor domain and correlates with translational regulation. Translation competition and UV-crosslink experiments show that the 3'UTR msl-2 sequences adjacent to dSXL-binding sites are necessary to recruit titratable co-repressors. Our data support a model where dSXL binding to the 3'UTR of msl-2 mRNA activates the translational repressor domain, thereby enabling it to recruit co-repressors in a specific fashion.     

Xtr, a plural tudor domain-containing protein, is involved in the translational regulation of maternal mRNA during oocyte maturation in Xenopus laevis

Xtr in the fertilized eggs of Xenopus has been demonstrated to be a member of a messenger ribonucleoprotein (mRNP) complex that plays a crucial role in karyokinesis during cleavage. Since the Xtr is also present both in oocytes and spermatocytes and its amount increases immediately after spematogenic cells enter into the meiotic phase, this protein was also predicted to act during meiotic progression. Taking advantage of Xenopus oocytes' large size to microinject anti-Xtr antibody into them for inhibition of Xtr function, we examined the role of Xtr in meiotic progression of oocytes. Microinjection of anti-Xtr antibody into immature oocytes followed by reinitiation of oocyte maturation did not affect germinal vesicle break down and the oscillation of Cdc2/cyclin B activity during meiotic progression but caused abnormal spindle formation and chromosomal alignment at meiotic metaphase I and II. Immunoprecipitation of Xtr showed the association of Xtr with FRGY2 and mRNAs such as RCC1 and XL-INCENP mRNAs, which are involved in the progression of karyokinesis. When anti-Xtr antibody was injected into oocytes, translation of XL-INCENP mRNA, which is known to be repressed in immature oocytes and induced after reinitiation of oocyte maturation, was inhibited even if the oocytes were treated with progesterone. A similar translational regulation was observed in oocytes injected with a reporter mRNA, which was composed of an enhanced green fluorescent protein open reading frame followed by the 3' untranslational region (3'UTR) of XL-INCENP mRNA. These results indicate that Xtr regulates the translation of XL-INCENP mRNA through its 3'UTR during meiotic progression of oocyte.     

Mos 3' UTR regulatory differences underlie species-specific temporal patterns of Mos mRNA cytoplasmic polyadenylation and translational recruitment during oocyte maturation

The Mos proto-oncogene is a critical regulator of vertebrate oocyte maturation. The maturation-dependent translation of Mos protein correlates with the cytoplasmic polyadenylation of the maternal Mos mRNA. However, the precise temporal requirements for Mos protein function differ between oocytes of model mammalian species and oocytes of the frog Xenopus laevis. Despite the advances in model organisms, it is not known if the translation of the human Mos mRNA is also regulated by cytoplasmic polyadenylation or what regulatory elements may be involved. We report that the human Mos 3' untranslated region (3' UTR) contains a functional cytoplasmic polyadenylation element (CPE) and demonstrate that the endogenous Mos mRNA undergoes maturation-dependent cytoplasmic polyadenylation in human oocytes. The human Mos 3' UTR interacts with the human CPE-binding protein and exerts translational control on a reporter mRNA in the heterologous Xenopus oocyte system. Unlike the Xenopus Mos mRNA, which is translationally activated by an early acting Musashi/polyadenylation response element (PRE)-directed control mechanism, the translational activation of the human Mos 3' UTR is dependent on a late acting CPE-dependent process. Taken together, our findings suggest a fundamental difference in the 3' UTR regulatory mechanisms controlling the temporal induction of maternal Mos mRNA polyadenylation and translational activation during Xenopus and mammalian oocyte maturation.     

Rapid deadenylation and Poly(A)-dependent translational repression mediated by the Caenorhabditis elegans tra-2 3' untranslated region in Xenopus embryos

The 3' untranslated region (3'UTR) of many eukaryotic mRNAs is essential for their control during early development. Negative translational control elements in 3'UTRs regulate pattern formation, cell fate, and sex determination in a variety of organisms. tra-2 mRNA in Caenorhabditis elegans is required for female development but must be repressed to permit spermatogenesis in hermaphrodites. Translational repression of tra-2 mRNA in C. elegans is mediated by tandemly repeated elements in its 3'UTR; these elements are called TGEs (for tra-2 and GLI element). To examine the mechanism of TGE-mediated repression, we first demonstrate that TGE-mediated translational repression occurs in Xenopus embryos and that Xenopus egg extracts contain a TGE-specific binding factor. Translational repression by the TGEs requires that the mRNA possess a poly(A) tail. We show that in C. elegans, the poly(A) tail of wild-type tra-2 mRNA is shorter than that of a mutant mRNA lacking the TGEs. To determine whether TGEs regulate poly(A) length directly, synthetic tra-2 3'UTRs with and without the TGEs were injected into Xenopus embryos. We find that TGEs accelerate the rate of deadenylation and permit the last 15 adenosines to be removed from the RNA, resulting in the accumulation of fully deadenylated molecules. We conclude that TGE-mediated translational repression involves either interference with poly(A)'s function in translation and/or regulated deadenylation.     

The Xenopus ELAV protein ElrB represses Vg1 mRNA translation during oogenesis

Xenopus laevis Vg1 mRNA undergoes both localization and translational control during oogenesis. We previously characterized a 250-nucleotide AU-rich element, the Vg1 translation element (VTE), in the 3'-untranslated region (UTR) of this mRNA that is responsible for the translational repression. UV-cross-linking and immunoprecipitation experiments, described here, revealed that the known AU-rich element binding proteins, ElrA and ElrB, and TIA-1 and TIAR interact with the VTE. The levels of these proteins during oogenesis are most consistent with a possible role for ElrB in the translational control of Vg1 mRNA, and ElrB, in contrast to TIA-1 and TIAR, is present in large RNP complexes. Immunodepletion of TIA-1 and TIAR from Xenopus translation extract confirmed that these proteins are not involved in the translational repression. Mutagenesis of a potential ElrB binding site destroyed the ability of the VTE to bind ElrB and also abolished translational repression. Moreover, multiple copies of the consensus motif both bind ElrB and support translational control. Therefore, there is a direct correlation between ElrB binding and translational repression by the Vg1 3'-UTR. In agreement with the reporter data, injection of a monoclonal antibody against ElrB into Xenopus oocytes resulted in the production of Vg1 protein, arguing for a role for the ELAV proteins in the translational repression of Vg1 mRNA during early oogenesis.     

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 250-nucleotide UA-rich element in the 3' untranslated region of Xenopus laevis Vg1 mRNA represses translation both in vivo and in vitro.

Xenopus laevis Vgl mRNA undergoes both localization and translational control during oogenesis. Vg1 protein does not appear until late stage IV, after localization is complete. To determine whether Vg1 translation is regulated by cytoplasmic polyadenylation, the RACE-PAT method was used. Vg1 mRNA has a constant poly(A) tail throughout oogenesis, precluding a role for cytoplasmic polyadenylation. To identify cis-acting elements involved in Vg1 translational control, the Vg1 3' UTR was inserted downstream of the luciferase ORF and in vitro transcribed, adenylated mRNA injected into stage III or stage VI oocytes. The Vg1 3' UTR repressed luciferase translation in both stages. Deletion analysis of the Vg1 3' UTR revealed that a 250-nt UA-rich fragment, the Vg1 translational element or VTE, which lies 118 nt downstream of the Vg1 localization element, could repress translation as well as the full-length Vg1 3' UTR. Poly(A)-dependent translation is not necessary for repression as nonadenylated mRNAs are also repressed, but cap-dependent translation is required as introduction of the classical swine fever virus IRES upstream of the luciferase coding region prevents repression by the VTE. Repression by the Vg1 3' UTR has been reproduced in Xenopus oocyte in vitro translation extracts, which show a 10-25-fold synergy between the cap and poly(A) tail. A number of proteins UV crosslink to the VTE including FRGY2 and proteins of 36, 42, 45, and 60 kDa. The abundance of p42, p45, and p60 is strikingly higher in stages I-III than in later stages, consistent with a possible role for these proteins in Vg1 translational control.     

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.     

Identification of a competitive translation determinant in the 3' untranslated region of alfalfa mosaic virus coat protein mRNA.

We report that the competitive translational activity of alfalfa mosaic virus coat protein mRNA (CP RNA), a nonadenylated mRNA, is determined in part by the 3' untranslated region (UTR). Competitive translation was characterized both in vitro, with cotranslation assays, and in vivo, with microinjected Xenopus laevis oocytes. In wheat germ extracts, coat protein synthesis was constant when a fixed amount of full-length CP RNA was cotranslated with increasing concentrations of competitor globin mRNA. However, translation of CP RNA lacking the 3' UTR decreased significantly under competitive conditions. RNA stabilities were equivalent. In X. laevis oocytes, which are translationally saturated and are an inherently competitive translational environment, full-length CP RNA assembled into large polysomes and coat protein synthesis was readily detectable. Alternatively, CP RNA lacking the 3' UTR sedimented as small polysomes, and little coat protein was detected. Again, RNA stabilities were equivalent. Site-directed mutagenesis was used to localize RNA sequences or structures required for competitive translation. Since the CP RNA 3' UTR has an unusually large number of AUG nucleotide triplets, two AUG-containing sites were altered in full-length RNA prior to oocyte injections. Nucleotide substitutions at the sequence GAUG, 20 nucleotides downstream of the coat protein termination codon, specifically reduced full-length CP RNA translation, while similar substitutions at the next AUG triplet had little effect on translation. The competitive influence of the 3' UTR could be explained by RNA-protein interactions that affect translation initiation or by ribosome reinitiation at downstream AUG codons, which would increase the number of ribosomes committed to coat protein synthesis.     

Mechanism of translational regulation by miR-2 from sites in the 5' untranslated region or the open reading frame

MicroRNAs (miRs) commonly regulate translation from target mRNA 3' untranslated regions (UTRs). While effective miR-binding sites have also been identified in 5' untranslated regions (UTRs) or open reading frames (ORFs), the mechanism(s) of miR-mediated regulation from these sites has not been defined. Here, we systematically investigate how the position of miR-binding sites influences translational regulation and characterize their mechanistic basis. We show that specific translational regulation is elicited in vitro and in vivo not only from the 3'UTR, but equally effectively from six Drosophila miR-2-binding sites in the 5'UTR or the ORF. In all cases, miR-2 triggers mRNA deadenylation and inhibits translation initiation in a cap-dependent fashion. In contrast, single or dual miR-2-binding sites in the 5'UTR or the ORF yield rather inefficient or no regulation. This work represents the first demonstration that 5'UTR and ORF miR-binding sites can function mechanistically similarly to the intensively investigated 3'UTR sites. Using single or dual binding sites, it also reveals a biological rationale for the high prevalence of miR regulatory sites in the 3'UTR.     

Translational control of maskin mRNA by its 3' untranslated region

BACKGROUND INFORMATION: Maskin is a member of the TACC (transforming acidic coiled-coil) domain proteins found in Xenopus laevis oocytes and embryos. It has been implicated in the co-ordination of the spindle and has been reported to mediate translational repression of cyclin B1 mRNA. RESULTS: In the present study, we report that maskin mRNA is translationally repressed at the level of initiation in stage 4 oocytes and becomes activated in stage 6 oocytes. The translational repression of maskin mRNA correlates with the presence of a short poly(A) tail on this mRNA in stage 4 oocytes. The 3'-UTR (untranslated region) of maskin can confer the translational regulation to a reporter mRNA, and so can the 3'-UTR of human TACC3. A conserved GUCU repeat element was found to repress translation in both stage 4 and stage 6 oocytes, but deletion of this element did not abrogate repression in stage 4 oocytes. UV cross-linking experiments indicated that overlapping sets of proteins bind efficiently to both the maskin and the cyclin B1 3'-UTRs. As reported previously, CPEB [CPE (cytoplasmic polyadenylation element)-binding protein] binds to the cyclin B1 3'-UTR, but its binding to the maskin 3'-UTR is minimal. By RNA affinity chromatography and MS, we identified the EDEN-BP [EDEN (embryonic deadenylation element)-binding protein] as one of the proteins binding to both the maskin and the cyclin B1 3'-UTRs. CONCLUSIONS: Maskin mRNA is translationally regulated by at least two repressor elements and an activation element. One of the repessor elements is the evolutionarily conserved GUCU repeat. EDEN-BP binds to both the maskin and cyclin B1 3'-UTRs, indicating it may be involved in the deadenylation of these mRNAs.     

Coupled mRNA stabilization and translational silencing of cyclooxygenase-2 by a novel RNA binding protein,CUGBP2

Cyclooxygenase-2 (COX-2) expression is translationally silenced in epithelial cells undergoing radiation-induced apoptosis. CUGBP2, a predominantly nuclear protein, is also rapidly induced in response to radiation and translocates to the cytoplasm. Antisense-mediated suppression of CUGBP2 renders radioprotection through a COX-2-dependent prostaglandin pathway, providing an in vivo demonstration of translation inhibition activity for CUGBP2. CUGBP2 binds to two sets of AU-rich sequences (AREs) located within the first sixty nucleotides of the COX-2 3' untranslated region (3'UTR). Upon binding, CUGBP2 stabilizes a chimeric luciferase-COX-2 3'UTR mRNA but inhibits its translation. These findings identify a novel paradigm for RNA binding proteins in facilitating opposing functions of mRNA stability and translation inhibition and reveal a mechanism for inhibiting COX-2 expression in cancer cells.     

The stem-loop binding protein is required for efficient translation of histone mRNA in vivo and in vitro

Metazoan replication-dependent histone mRNAs end in a conserved stem-loop rather than in the poly(A) tail found on all other mRNAs. The 3' end of histone mRNA binds a single class of proteins, the stem-loop binding proteins (SLBP). In Xenopus, there are two SLBPs: xSLBP1, the homologue of the mammalian SLBP, which is required for processing of histone pre-mRNA, and xSLBP2, which is expressed only during oogenesis and is bound to the stored histone mRNA in Xenopus oocytes. The stem-loop is required for efficient translation of histone mRNAs and substitutes for the poly(A) tail, which is required for efficient translation of other eucaryotic mRNAs. When a rabbit reticulocyte lysate is programmed with uncapped luciferase mRNA ending in the histone stem-loop, there is a three- to sixfold increase in translation in the presence of xSLBP1 while xSLBP2 has no effect on translation. Neither SLBP affected the translation of a luciferase mRNA ending in a mutant stem-loop that does not bind SLBP. Capped luciferase mRNAs ending in the stem-loop were injected into Xenopus oocytes after overexpression of either xSLBP1 or xSLBP2. Overexpression of xSLBP1 in the oocytes stimulated translation, while overexpression of xSLBP2 reduced translation of the luciferase mRNA ending in the histone stem-loop. A small region in the N-terminal portion of xSLBP1 is required to stimulate translation both in vivo and in vitro. An MS2-human SLBP1 fusion protein can activate translation of a reporter mRNA ending in an MS2 binding site, indicating that xSLBP1 only needs to be recruited to the 3' end of the mRNA but does not need to be directly bound to the histone stem-loop to activate translation.