Promoter control of translation in Xenopus oocytes

Translation factor mRNA granules direct protein synthetic capacity to regions of polarized growth

mRNA localization serves key functions in localized protein production, making it critical that the translation machinery itself is present at these locations. Here we show that translation factor mRNAs are localized to distinct granules within yeast cells. In contrast to many messenger RNP granules, such as processing bodies and stress granules, which contain translationally repressed mRNAs, these granules harbor translated mRNAs under active growth conditions. The granules require Pab1p for their integrity and are inherited by developing daughter cells in a She2p/She3p-dependent manner. These results point to a model where roughly half the mRNA for certain translation factors is specifically directed in granules or translation factories toward the tip of the developing daughter cell, where protein synthesis is most heavily required, which has particular implications for filamentous forms of growth. Such a feedforward mechanism would ensure adequate provision of the translation machinery where it is to be needed most over the coming growth cycle.

Expression of FTZ-F1alpha in transgenic Xenopus embryos and oocytes

Fushi tarazu transcription factor-1 (FTZ-F1) was originally found as a regulator of fushi tarazu gene expression in Drosophila. The frog homologue (FTZ-F1alpha) and the 3.5 kb 5'-flanking region of the FTZ-F1alpha gene have been cloned, and it has been shown by reverse transcription-polymerase chain reaction that FTZ-F1alpha expression begins in embryos at stage 11 and becomes stronger after that. By in situ hybridization analysis, the FTZ-F1alpha mRNA was also found in immature frog oocytes. In this study, immunohistology revealed that the product of FTZ-F1alpha was localized in the cytoplasm of the immature oocyte. To analyze the promoter activity of the Rana rugosa FTZ-F1alpha gene, transgenic Xenopus were produced carrying the fusion construct, consisting of truncated 5'-flanking regions (3.0, 1.8 and 0.3 kb) of the FTZ-F1alpha gene and the green fluorescent protein (GFP) open reading frame. The 0.3 kb 5'-flanking region could drive GFP expression in Xenopus embryos at stage 20 and in immature oocytes in the ovary 2 months after metamorphosis. Gel mobility shift assay was used to test whether proteins in extracts from Xenopus embryos and ovaries bound to the 0.3 kb DNA. The extract from embryos at stage 11 formed one retarded band. The extract from ovaries formed a different retarded band. The results, taken together, indicate that production of transgenic Xenopus is very useful for the analysis of the promoter activity of genes in amphibians. The results also suggest that at least two proteins (one in the embryo and the other in the ovary of 2-month-old postmetamorphosing Xenopus) bind the 0.3 kb 5'-flanking region of the FTZ-F1alpha gene. These proteins may be involved in the regulation of FTZ-F1alpha gene expression in amphibians.

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.

Xenopus oocytes as an expression system for plant transporters

The Xenopus oocyte provides a powerful system for the expression and characterisation of plant membrane proteins. Many different types of plant membrane proteins have been expressed and characterised using this system. As there are already several general reviews on the methodology for oocyte expression of channel proteins, we have summarised the particular advantages and disadvantages of using the system for the characterisation of plant cotransporter proteins. As an example of how the system can be used to identify transporters, we describe evidence for a low affinity nitrate transporter in oocytes injected with poly(A) RNA extracted from nitrate-induced barley roots. Furthermore, we describe evidence that the expression of some transporters in oocytes can modify the properties of endogenous membrane proteins. We conclude that although care must be taken in the interpretation of results and in choosing appropriate controls for experiments, oocyte expression is an excellent tool which will have an important role in characterising plant membrane proteins.

Characterization of DP103, a novel DEAD box protein that binds to the Epstein-Barr virus nuclear proteins EBNA2 and EBNA3C

The Epstein-Barr virus-encoded nuclear antigens EBNA2 and EBNA3C both interact with the cellular transcription factor RBP-Jkappa and modulate the expression of several shared target genes, suggesting a tight cooperation in latently infected cells. In a survey for additional cellular factors that bind to EBNA2 as well as EBNA3C, we have isolated and characterized DP103, a novel human member of the DEAD box family of putative ATP-dependent RNA helicases. The interaction with DP103 is mediated by amino acids (aa) 121-213 of EBNA2 and aa 534-778 of EBNA3C, regions that are not involved in binding of the viral proteins to RBP-Jkappa. The DP103-cDNA encodes a protein of 824 aa that harbors all of the common DEAD box motifs. Monoclonal antibodies raised against DP103 detect a protein of 103 kDa in mammalian cells that resides in high molecular weight complexes in vivo. We have detected an ATPase activity intrinsic to or closely associated with DP103. By subcellular fractionation, we find DP103 in both a soluble nuclear fraction as well as in the insoluble skeletal fraction. Whereas the protein and its mRNA are uniformly expressed in all tested cell lines, we observed differential expression of the mRNA in normal human tissues.

Activities of cold-shock domain proteins in translation control

For efficient processing, transport, storage, translation, and degradation, stretches of RNA transcripts are required in a single-stranded conformation (ssRNA). A superfamily of OB-fold proteins is characterized by preference of binding to ssRNA. This superfamily consists of proteins containing either an S1 domain (S1-D) or a cold-shock domain (CSD). In a variety of situations. S1-D or CSD proteins are found in association with DEAD-box RNA helicases and the two types of protein appear to function together to maintain regions of ssRNA. CSD proteins are commonly found bound to stored (nontranslating) mRNA, particularly during early development. Although complete removal of the CSD proteins from mRNA permits its translation in vitro, low concentrations of CSD protein on the mRNA may be required for maximal translation efficiency in vivo. Another component of stored mRNP particles in Xenopus oocytes is the protein kinase CK2, which phosphorylates the associated CSD proteins. It is argued here that the loading of CSD proteins on mRNA and the stability of the protein/mRNA complex are regulated by RNA helicase activity and protein phosphorylation.

Activities of cold-shock domain proteins in translation control

For efficient processing, transport, storage, translation, and degradation, stretches of RNA transcripts are required in a single-stranded conformation (ssRNA). A superfamily of OB-fold proteins is characterized by preference of binding to ssRNA. This superfamily consists of proteins containing either an S1 domain (S1-D) or a cold-shock domain (CSD). In a variety of situations. S1-D or CSD proteins are found in association with DEAD-box RNA helicases and the two types of protein appear to function together to maintain regions of ssRNA. CSD proteins are commonly found bound to stored (nontranslating) mRNA, particularly during early development. Although complete removal of the CSD proteins from mRNA permits its translation in vitro, low concentrations of CSD protein on the mRNA may be required for maximal translation efficiency in vivo. Another component of stored mRNP particles in Xenopus oocytes is the protein kinase CK2, which phosphorylates the associated CSD proteins. It is argued here that the loading of CSD proteins on mRNA and the stability of the protein/mRNA complex are regulated by RNA helicase activity and protein phosphorylation.

Dual roles of p82, the clam CPEB homolog, in cytoplasmic polyadenylation and translational masking

In the transcriptionally inert maturing oocyte and early embryo, control of gene expression is largely mediated by regulated changes in translational activity of maternal mRNAs. Some mRNAs are activated in response to poly(A) tail lengthening; in other cases activation results from de-repression of the inactive or masked mRNA. The 3' UTR cis-acting elements that direct these changes are defined, principally in Xenopus and mouse, and the study of their trans-acting binding factors is just beginning to shed light on the mechanism and regulation of cytoplasmic polyadenylation and translational masking. In the marine invertebrate, Spisula solidissima, the timing of activation of three abundant mRNAs (encoding cyclin A and B and the small subunit of ribonucleotide reductase, RR) in fertilized oocytes correlates with their cytoplasmic polyadenylation. However, in vitro, mRNA-specific unmasking occurs in the absence of polyadenylation. In Walker et al. (in this issue) we showed that p82, a protein defined as selectively binding the 3' UTR masking elements, is a homolog of Xenopus CPEB (cytoplasmic polyadenylation element binding protein). In functional studies reported here, the elements that support polyadenylation in clam egg lysates include multiple U-rich CPE-like motifs as well as the nuclear polyadenylation signal AAUAAA. This represents the first detailed analysis of invertebrate cis-acting cytoplasmic polyadenylation signals. Polyadenylation activity correlates with p82 binding in wild-type and CPE-mutant RR 3' UTR RNAs. Moreover, since anti-p82 antibodies specifically neutralize polyadenylation in egg lysates, we conclude that clam p82 is a functional homolog of Xenopus CPEB, and plays a positive role in polyadenylation. Anti-p82 antibodies also result in specific translational activation of masked mRNAs in oocyte lysates, lending support to our original model of clam p82 as a translational repressor. We propose therefore that clam p82/CPEB has dual functions in masking and cytoplasmic polyadenylation.

Expression of DjY1, a protein containing a cold shock domain and RG repeat motifs, is targeted to sites of regeneration in planarians

Planarians are well-known for their exceptional regenerative abilities. This investigation focuses on the involvement of a Y-box protein, defined by the presence of a cold-shock domain, in regeneration-specific processes. Previous studies have shown that developmentally expressed Y-box proteins bind to mRNA molecules and regulate the timing of their translation. We have isolated and characterized a planarian Y-box gene, DjY1, which is specifically expressed at the site of regeneration, the blastema. DjY1 transcripts appear rapidly at the site of cutting and increase in number as the blastema grows. The timing and level of expression is similar irrespective of the orientation of the cut: in anterior, posterior, and lateral regenerative tissue. As regeneration nears completion, there is a general decrease in transcript level except in structures which are still differentiating, specifically in the auricles where new DjY1 transcripts are produced. A similarly modulated temporal pattern of expression throughout regeneration is seen in assaying the DjY1 protein. Within the population of blastemal cells, a subset of differentiating cells is specifically immunostained using antibodies to DjY1. The DjY1 protein contains a cold-shock domain and RG-repeat motifs, both of which are associated with RNA-binding properties: in vitro binding studies using recombinant DjY1 show that the preferred template is single-stranded RNA of heterogeneous sequence. These data provide the first direct evidence that a Y-box protein is involved in the regeneration process in planarians and implicate DjY1 in the translational regulation of differentiation-specific mRNAs.

Nuclear history of a pre-mRNA determines the translational activity of cytoplasmic mRNA

The pathways of synthesis and maturation of pre-messenger RNA in the nucleus have a direct effect on the translational efficiency of mRNA in the cytoplasm. The transcription of intron-less mRNA in vivo directs this mRNA towards translational silencing. The presence of an intron at the 5' end of the transcript relieves this silencing, whereas an intron at the 3' end further represses translation. These regulatory events are strongly dependent on the transcription of pre-mRNA in the nucleus. The impact of nuclear history on regulatory events in the cytoplasm provides a novel mechanism for the control of gene expression.

Isolation and characterization of goldfish Y box protein, a germ-cell-specific RNA-binding protein

Cyclin B is a regulatory subunit of maturation-promoting factor. In goldfish (Carassius auratus) oocytes, cyclin B is synthesized de novo after stimulation by 17alpha,20beta-dihydroxy-4-pregnen-3-one (maturation-inducing hormone). In this study, we examined goldfish oocyte proteins bound to cyclin B mRNA. Using oligo(dT)-cellulose affinity chromatography and northwestern blotting analysis, we identified a 54-kDa cyclin B mRNA-binding protein (p54). Southwestern blotting analysis showed the binding of p54 to the Y box DNA element (CTGATTGGCCAA), suggesting that p54 is a Y box protein in goldfish. We isolated two cDNA clones, GFYP1 and GFYP2, the latter of which encodes a germ-cell-specific Y box protein. An antibody against a GFYP2 protein recognized p54, suggesting that p54 is identical or highly similar to GFYP2 protein. This is also supported by the finding that a recombinant GFYP2 expressed in bacteria bound to both the Y box DNA element and the goldfish cyclin B mRNA synthesized in vitro. These results suggest that p54 is a germ-cell-specific Y box protein and is a potential masking protein of cyclin B mRNA in goldfish oocytes.

Multifunctional proteins suggest connections between transcriptional and post-transcriptional processes

Recent findings indicate that substantial cross-talk may exist between transcriptional and post-transcriptional processes. Firstly, there are suggestions that specific promoters influence the post-transcriptional fate of transcripts, pointing to communication between protein complexes assembled on DNA and nascent pre-mRNA. Secondly, an increasing number of proteins appear to be multifunctional, participating in transcriptional and post-transcriptional events. The classic example is TFIIIA, required for both the transcription of 5S rRNA genes and the packaging of 5S rRNA. TFIIIA is now joined by the Y-box proteins, which bind DNA (transcription activation and repression) and RNA (mRNA packaging). Furthermore, the tumour suppressor WT1, at first thought to be a typical transcription factor, may also be involved in splicing; conversely, hnRNP K, a bona fide pre-mRNA-binding protein, appears to be a transcription factor. Other examples of multifunctional proteins are mentioned: notably PTB, Sxl, La and PU.1. It is now reasonable to assert that some proteins, which were first identified as transcription factors, could just as easily have been identified as splicing factors, hnRNP, mRNP proteins and vice versa. It is no longer appropriate to view gene expression as a series of compartmentalised processes; instead, multifunctional proteins are likely to co-ordinate different steps of gene expression.

Chromatin domains and nuclear compartments: establishing sites of gene expression in eukaryotic nuclei

Establishing sites of transcription in the nuclei of higher eukaryotic cells is a very complex process. Before transcription can begin, a series of transcription factors must associate with their recognition motifs, within promoters and more remote activating sequences. Once bound, these factors and associated proteins are believed to form a complex that positions the RNA polymerase holoenzyme so that transcription can commence. As a consequence, active genes assume a specialized chromatin state across regions that define functional domains. Global nuclear architecture appears to stabilize these active domains by providing local environments dedicated to gene expression. As the spatial organization of these sites is unaffected by the removal of most chromatin they must be associated with a structural network. This nucleoskeleton, the associated transcription 'factories' and chromatin loops that arise as DNA binds proteins within factories now appear to be fundamental features of nuclear structure in higher eukaryotes. I argue that concentrating proteins needed to perform different steps of RNA synthesis within specialized nuclear compartments will be important in orchestrating events required for efficient gene expression.

Life and death in the cytoplasm: messages from the 3' end

The cytoplasmic life of an mRNA revolves around the regulation of its localization, translation and stability. Interactions between the two ends of the mRNA may integrate translation and mRNA turnover. Regulatory elements in the region between the termination codon and poly(A) tail - the 3' untranslated region - have been identified in a wide variety of systems, as have been some of the key players with which these elements interact.

Masking and unmasking maternal mRNA. The role of polyadenylation, transcription, splicing, and nuclear history

We establish that masked mRNAs synthesized from exogenous plasmid templates microinjected into the nuclei of Xenopus oocytes are translationally activated (unmasked) on oocyte maturation concomitant with polyadenylation. Synthetic mRNA injected into the cytoplasm of the oocyte is translated over an order of magnitude more efficiently than is the cognate mRNA synthesized in vivo. Both mRNA synthesized in vivo and mRNA microinjected into the oocyte cytoplasm require a cytoplasmic polyadenylation element in the 3'-untranslated region to activate translation on maturation. Although polyadenylation upon oocyte maturation can relieve the translational repression of mRNA synthesized in vivo, the excision of an intron within the nucleus does not relieve repression. We suggest that the translational repression coupled to the transcription process will more effectively repress inappropriate gene expression in the oocyte and offer the potential to achieve a wider range of gene regulation.

The regulation of human immunodeficiency virus type-1 gene expression

Despite 15 years of intensive research we still do not have an effective treatment for AIDS, the disease caused by human immunodeficiency virus (HIV). Recent research is, however, revealing some of the secrets of the replication cycle of this complex retrovirus, and this may lead to the development of novel antiviral compounds. In particular the virus uses strategies for gene expression that seem to be unique in the eukaryotic world. These involve the use of virally encoded regulatory proteins that mediate their effects through interactions with specific viral target sequences present in the messenger RNA rather than in the proviral DNA. If there are no cellular counterparts of these RNA-dependent gene-regulation pathways then they offer excellent targets for the development of antiviral compounds. The viral promoter is also subject to complex regulation by combinations of cellular factors that may be functional in different cell types and at different cell states. Selective interference of specific cellular factors may also provide a route to inhibiting viral replication without disrupting normal cellular functions. The aim of this review is to discuss the regulation of HIV-1 gene expression and, as far as it is possible, to relate the observations to viral pathogenesis. Some areas of research into the regulation of HIV-1 replication have generated controversy and rather than rehearsing this controversy we have imposed our own bias on the field. To redress the balance and to give a broader view of HIV-1 replication and pathogenesis we refer you to a number of excellent reviews [Cullen, B. R. (1992) Microbiol. Rev. 56, 375-394; Levy, J. A. (1993) Microbiol. Rev. 57, 183-394; Antoni, B. A., Stein, S. & Rabson, A. B. (1994) Adv. Virus Res. 43, 53-145; Rosen, C. A. & Fenyoe, E. M. (1995) AIDS (Phila.) 9, S1-S3].

Translational repression dependent on the interaction of the Xenopus Y-box protein FRGY2 with mRNA. Role of the cold shock domain, tail domain, and selective RNA sequence recognition

We have examined the determinants of the translational repression of mRNA by the Xenopus oocyte-specific Y-box protein FRGY2 using in vitro and in vivo assays. In vitro reconstitution of messenger ribonucleoprotein (mRNP) complexes demonstrates that the sequence-specific RNA-binding cold shock domain is not required for translational repression, whereas the RNA-binding C-terminal tail domain is essential. However, microinjection of reconstituted mRNPs into Xenopus oocytes demonstrates that although translational repression occurs in the absence of consensus RNA binding sequences for FRGY2, the presence of FRGY2 recognition elements within mRNA potentiates translational repression. Analysis of the in vivo assembly of mRNP shows that the cold shock domain alone is not stably incorporated into mRNP, whereas the C-terminal tail domain is sufficient for stable incorporation. We suggest that translational repression of mRNA by FRGY2 is favored by sequence-selective recognition of RNA sequences by the cold shock domain. However, translational repression in vitro and the assembly of mRNP in vivo requires the relatively nonspecific interaction of the C-terminal tail domain with mRNA. Thus two distinct domains of FRGY2 are likely to contribute to translational control.

Coupling transcription to translation: a novel site for the regulation of eukaryotic gene expression

Recent experiments using Xenopus oocytes demonstrate that the history of a particular mRNA in the nucleus can influence the efficiency with which that mRNA will be utilized by the translational machinery. Individual promoter elements, specific protein-RNA interactions and the splicing process within the nucleus can all influence translational fate within the cytoplasm. Central to the regulatory mechanisms influencing the translation process is the packaging of mRNA by a highly conserved family of Y-box proteins. These Y-box proteins are found in cytoplasmic messenger ribonucleoprotein particles where they have a causal role in restricting the recruitment of mRNA to the translational machinery. Nuclear processes influence the packaging of mRNA by the Y-box proteins in the cytoplasm and in consequence mRNA translation. This functional coupling provides a novel site for the regulation of eukaryotic gene expression.