Regulation of BAG-1 IRES-mediated translation following chemotoxic stress.

There are three major isoforms of BAG-1 in mammalian cells, termed BAG-1L (p50), BAG-1M (p46) and BAG-1S (p36) that function as pro-survival proteins and are associated with tumorigenesis and chemoresistance. Initiation of BAG-1 protein synthesis can occur by both cap-dependent and cap-independent mechanisms and it has been shown that synthesis of BAG-1S is dependent upon the presence of an internal ribosome entry segment (IRES) in the 5'-UTR of BAG-1 mRNA. We have shown previously that BAG-1 IRES-meditated initiation of translation requires two trans-acting factors poly (rC) binding protein 1 (PCBP1) and polypyrimidine tract binding protein (PTB) for function. The former protein allows BAG-1 IRES RNA to attain a structure that permits binding of the ribosome, while the latter protein appears to be involved in ribosome recruitment. Here, we show that the BAG-1 IRES maintains synthesis of BAG-1 protein following exposure of cells to the chemotoxic drug vincristine but not to cisplatin and that this is brought about, in part, by the relocalization of PTB and PCBP1 from the nucleus to the cytoplasm.

Translational control in vertebrate development.

Translational control plays a large role in vertebrate oocyte maturation and contributes to the induction of the germ layers. Translational regulation is also observed in the regulation of cell proliferation and differentiation. The features of an mRNA that mediate translational control are found both in the 5' and in the 3' untranslated regions (UTRs). In the 5' UTR, secondary structure, the binding of proteins, and the presence of upstream open reading frames can interfere with the association of initiation factors with the cap, or with scanning of the initiation complex. The 3' UTR can mediate translational activation by directing cytoplasmic polyadenylation and can confer translational repression by interference with the assembly of initiation complexes. Besides mRNA-specific translational control elements, the nonspecific RNA-binding proteins contribute to the modulation of translation in development. This review discusses examples of translational control and their relevance for developmental regulation.

Cytoplasmic polyadenylation elements mediate masking and unmasking of cyclin B1 mRNA.

During oocyte maturation, cyclin B1 mRNA is translationally activated by cytoplasmic polyadenylation. This process is dependent on cytoplasmic polyadenylation elements (CPEs) in the 3' untranslated region (UTR) of the mRNA. To determine whether a titratable factor might be involved in the initial translational repression (masking) of this mRNA, high levels of cyclin B1 3' UTR were injected into oocytes. While this treatment had no effect on the poly(A) tail length of endogenous cyclin B1 mRNA, it induced cyclin B1 synthesis. A mutational analysis revealed that the most efficient unmasking element in the cyclin 3' UTR was the CPE. However, other U-rich sequences that resemble the CPE in structure, but which do not bind the CPE-binding polyadenylation factor CPEB, failed to induce unmasking. When fused to the chloramphenical acetyl transferase (CAT) coding region, the cyclin B1 3' UTR inhibited CAT translation in injected oocytes. In addition, a synthetic 3' UTR containing multiple copies of the CPE also inhibited translation, and did so in a dose-dependent manner. Furthermore, efficient CPE-mediated masking required cap-dependent translation. During the normal course of progesterone-induced maturation, cytoplasmic polyadenylation was necessary for mRNA unmasking. A model to explain how cyclin B1 mRNA masking and unmasking could be regulated by the CPE is presented.

Maskin is a CPEB-associated factor that transiently interacts with elF-4E.

In Xenopus, the CPE is a bifunctional 3' UTR sequence that maintains maternal mRNA in a dormant state in oocytes and activates polyadenylation-induced translation during oocyte maturation. Here, we report that CPEB, which binds the CPE and stimulates polyadenylation, interacts with a new factor we term maskin. Maskin contains a peptide sequence that is conserved among elF-4E-binding proteins. Affinity chromatography demonstrates that CPEB, maskin, and elF-4E reside in a complex in oocytes, and yeast two-hybrid analyses indicate that CPEB and maskin bind directly, as do maskin and elF-4E. While CPEB and maskin remain together during oocyte maturation, the maskin-elF-4E interaction is substantially reduced. The dissolution of this complex may result in the binding of elF-4E to elF-4G and the translational activation of CPE-containing mRNAs.

The Mos pathway regulates cytoplasmic polyadenylation in Xenopus oocytes.

Cytoplasmic polyadenylation controls the translation of several maternal mRNAs during Xenopus oocyte maturation and requires two sequences in the 3' untranslated region (UTR), the U-rich cytoplasmic polyadenylation element (CPE), and the hexanucleotide AAUAAA. c-mos mRNA is polyadenylated and translated soon after the induction of maturation, and this protein kinase is necessary for a kinase cascade culminating in cdc2 kinase (MPF) activation. Other mRNAs are polyadenylated later, around the time of cdc2 kinase activation. To determine whether there is a hierarchy in the cytoplasmic polyadenylation of maternal mRNAs, we ablated c-mos mRNA with an antisense oligonucleotide. This prevented histone B4 and cyclin A1 and B1 mRNA polyadenylation, indicating that the polyadenylation of these mRNAs is Mos dependent. To investigate a possible role of cdc2 kinase in this process, cyclin B was injected into oocytes lacking c-mos mRNA. cdc2 kinase was activated, but mitogen-activated protein kinase was not. However, polyadenylation of cyclin B1 and histone B4 mRNA was still observed. This demonstrates that cdc2 kinase can induce cytoplasmic polyadenylation in the absence of Mos. Our data further indicate that although phosphorylation of the CPE binding protein may be involved in the induction of Mos-dependent polyadenylation, it is not required for Mos-independent polyadenylation. We characterized the elements conferring Mos dependence (Mos response elements) in the histone B4 and cyclin B1 mRNAs by mutational analysis. For histone B4 mRNA, the Mos response elements were in the coding region or 5' UTR. For cyclin B1 mRNA, the main Mos response element was a CPE that overlaps with the AAUAAA hexanucleotide. This indicates that the position of the CPE can have a profound influence on the timing of cytoplasmic polyadenylation.

Translational control of gene expression.

Translational regulation of mRNA is an important step in the control of gene expression. In a general way, the efficiency of the translational apparatus can be influenced either positively or negatively by changing the level or the activity of rate-limiting protein factors taking part in the process of translation. But translational control can also be very specific, affecting only a single mRNA or class of mRNA molecules. In most of these cases regulation takes place at the level of initiation of translation, which is often attributable to structural peculiarities of the mRNA in question, especially of the 5'-untranslated region or leader. This review summarizes the mechanisms which lie at the root of translational control. A better understanding of these mechanisms will eventually provide us with new drugs and antisense oligonucleotide technology, aimed at influencing the level of expression of single proteins. These developments are of interest to basic researchers and clinicians alike, because they may profoundly change the ways in which we treat, e.g. viral infections and malignancies in the future.

Proteins binding to the leader of the 6.0 kb mRNA of human insulin-like growth factor 2 influence translation.

The leader of the 6.0 kb human insulin-like growth factor 2 (IGF-2) mRNA, leader 3, has been reported to partially repress translation. In the regulation of this phenomenon, RNA-binding proteins may play a role. Using UV-irradiation crosslinking, we found specific binding of four proteins (57, 43, 37 and 36 kDa) to this leader. Binding of these proteins to RNA proved to be highly sensitive to the potassium chloride concentration in the buffer solution, each protein having its own optimum. The 57 kDa protein was indistinguishable by size, binding properties and immunoprecipitation from the polypyrimidine tract binding protein (PTB), first described as a nuclear protein binding to the polypyrimidine tracts (PPTs) in introns. Cross-competition experiments showed that leader 3 has a much higher affinity for this 57 kDa protein than the PPT on which PTB was originally characterized. By competition with different fragments of leader 3, we were able to localize the binding of the 57 kDa protein to a 162 nt RNA fragment (AsnI-PvuII) in the 3'-part of the leader. When placed before a chloramphenicol acetyltransferase (CAT) open reading frame, this RNA fragment stimulated translation in reticulocyte lysate 3-fold, while other fragments of leader 3 repressed translation. The efficient translation directed by the 162 nt AsnI-PvuII fragment fused to CAT could be repressed by adding free AsnI-PvuII RNA fragment, indicating that the high translation efficiency of the AsnI-PvuII-CAT synthetic mRNA was due to the binding of protein and not to the structure of the RNA itself.

Influence of the four leader sequences of the human insulin-like-growth-factor-2 mRNAs on the expression of reporter genes.

The human insulin-like-growth-factor-2 (IGF-2) gene generates mRNAs with four different leader sequences, but with identical coding and trailing regions. Previous research has revealed that the leader-2-containing and leader-4-containing mRNAs are completely polysomal, whereas mRNAs possessing leader-3 are predominantly present in the untranslated free messenger ribonucleoprotein particle (mRNP), both in cell lines and in foetal liver tissue. To investigate the influence of the IGF-2 leader sequences on expression of the gene, IGF-2 leader-luciferase and leader-chloramphenicol acetyltransferase fusion constructs were transfected transiently into different cell lines. In these experiments, the levels of expression obtained by constructs with leader-1, leader-2 and leader-4 were very similar, both at the level of mRNA and protein. Leader-3, however, strongly repressed the expression of the fusion mRNA via an unknown mechanism. This repression appeared to be confined to nucleotides at positions 328-906 of the leader sequence. The remaining 5' part of the leader sequence was efficient both in RNA expression and in translation, but the 3' part of the leader (nucleotides 906-1180) again moderately repressed luciferase expression, possibly due to endonucleolytic cleavage in this region of the RNA. To evaluate the effect of the IGF-2 leaders on in vitro translation, leader-chloramphenicol acetyltransferase fusion mRNAs were synthesized and translated in reticulocyte lysates. Compared to a chloramphenicol acetyltransferase control RNA, leader-1-chloramphenicol acetyltransferase mRNA translated over 20-fold less efficiently, whereas leader-2 repressed translation of its chloramphenicol acetyltransferase mRNA moderately (3-5 fold). Despite a general improvement of the translation efficiency upon translation in HeLa lysate, these discrepancies with the transfection data persisted. Translation of leader-3-containing mRNAs in reticulocyte lysates was barely detectable. The whole 5' region of leader-3, up to nucleotide 614, could be shown to be repressive. Only leader-4 directed translation of the chloramphenicol acetyltransferase open reading frame efficiently. As with leader-1 and leader-2, this L4-chloramphenicol acetyltransferase mRNA translated in a cap-dependent manner under the conditions of our experiments; translation of this mRNA was relatively resistant to addition of cap analogue. We conclude that all four IGF-2 leader sequences differ in their translational properties. This makes it likely that changes in the translational machinery will affect the expression of the various IGF-2 mRNAs differentially.

Translation initiation on the insulin-like growth factor II leader 1 is developmentally regulated.

The majority of cellular mRNAs have relatively short and unstructured 5' untranslated regions (UTRs) that allow efficient translation, such as the beta-globin mRNA. An exception to this rule is the group of growth factor mRNAs which, in general, have long 5' UTRs with a high G + C content. An example is insulin-like growth factor II (IGF-II), which is encoded by four mRNAs, arising from four different promoters. Transcripts having the human IGF-II leader 1 are only expressed in adult liver where IGF-II protein synthesis is solely under direction of this 5' UTR. We investigated the translational efficiency in vitro of this 5' UTR, linked to the chloramphenicol acetyltransferase (CAT) encoding region. As expected from the primary structure of IGF-II leader 1, translational efficiency was very low compared with beta-globin 5' UTR-CAT mRNA. Addition of cell extract from undifferentiated P19 embryonal carcinoma (EC) cells preferentially stimulated translation of an IGF-II 5' UTR RNA construct. No translational stimulation was found when cell extract from differentiated P19 EC cells was added. In contrast with the beta-globin 5' UTR, translation initiation on the IGF-II 5' UTR was not dependent on the presence of a cap structure. The results imply that only in undifferentiated P19 EC cells and not in their differentiated derivatives is a factor present that specifically stimulates IGF-II RNA translation, thereby suggesting translational regulation of IGF-II production during early embryonic development. A mechanism for translation initiation on the 5' UTR of IGF-II is discussed.

Differential polysomal localization of human insulin-like-growth-factor-2 mRNAs in cell lines and foetal liver.

Examination of the association of insulin-like-growth-factor-2 mRNAs with polyribosomes in five cell lines revealed that greater than 50% of the total mRNA population was present in the untranslated free mRNP fraction for each cell line. Of the different subtypes of insulin-like-growth-factor-2 messengers, the least abundant mRNAs, starting with exon 4 (leader 2, 5.0 kb) and exon 6 (leader 4, 4.8 kb), were found in the polysomes only, while the most abundant transcript, starting with exon 5 (leader 3, 6.0 kb and 2.1 kb) was found predominantly in the untranslated fractions. 20-30% of leader 3 mRNAs, however, were in the larger polysomes (four or more ribosomes), indicating that a subpopulation of this mRNA can be translated efficiently. The peak fraction for the leader 4 insulin-like-growth-factor-2 mRNA (4.8 kb) in the polysomes was migrating faster in the sucrose gradients than the peak fractions of leader 2 and 3 mRNAs (5.0 kb and 6.0 kb), implying that more ribosomes were associated with this type of mRNA. In foetal liver, the situation was similar, though in this case the leader 2 mRNA was most heavily loaded with polysomes. Treatment of cells with low concentrations of cycloheximide caused the polysomal RNAs to shift to even larger polysomes while the untranslated fraction of the leader 3 mRNAs stayed in the untranslated fractions. These results indicate that, both in established cell lines and in foetal liver, insulin-like-growth-factor-2 translation is influenced both by mRNP sequestration and differential translation initiation efficiency of the insulin-like-growth-factor-2 mRNAs.