Regulation of adenovirus transcription by an E1a gene in microinjected Xenopus laevis oocytes

A transcription assay for EWS oncoproteins in Xenopus oocytes

Aberrant chromosomal fusion of the Ewing's sarcoma oncogene (EWS) to several different cellular partners produces the Ewing's family of oncoproteins (EWS-fusion-proteins, EFPs) and associated tumors (EFTs). EFPs are potent transcriptional activators, dependent on the N-terminal region of EWS (the EWS-activation-domain, EAD) and this function is thought to be central to EFT oncogenesis and maintenance. Thus EFPs are promising therapeutic targets, but detailed molecular studies will be pivotal for exploring this potential. Such studies have so far largely been restricted to intact mammalian cells while recent evidence has indicated that a mammalian cell-free transcription system may not support bona fide EAD function. Therefore, the lack of manipulatable assays for the EAD presents a significant barrier to progress. Using Xenopus laevis oocytes we describe a plasmid-based micro-injection assay that supports efficient, bona fide EAD transcriptional activity and hence provides a new vehicle for molecular dissection of the EAD.

The control of cyclin B1 mRNA translation during mouse oocyte maturation

In maturing mouse oocytes, protein synthesis is required for meiotic maturation subsequent to germinal vesicle breakdown (GVBD). While the number of different proteins that must be synthesized for this progression to occur is unknown, at least one of them appears to be cyclin B1, the regulatory subunit of M-phase-promoting factor. Here, we investigate the mechanism of cyclin B1 mRNA translational control during mouse oocyte maturation. We show that the U-rich cytoplasmic polyadenylation element (CPE), a cis element in the 3' UTR of cyclin B1 mRNA, mediates translational repression in GV-stage oocytes. The CPE is also necessary for cytoplasmic polyadenylation, which stimulates translation during oocyte maturation. The injection of oocytes with a cyclin B1 antisense RNA, which probably precludes the binding of a factor to the CPE, delays cytoplasmic polyadenylation as well as the transition from GVBD to metaphase II. CPEB, which interacts with the cyclin B1 CPE and is present throughout meiotic maturation, becomes phosphorylated at metaphase I. These data indicate that CPEB is involved in both the repression and the stimulation of cyclin B1 mRNA and suggest that the phosphorylation of this protein could be involved in regulating its activity.

Complementation of transforming domains in E1a/myc chimaeras

The myc oncogene is functionally similar to adenovirus E1a in its ability to collaborate with activated ras oncogenes to transform primary fibroblasts. The transforming functions of E1a and myc have been mapped to two distinct regions in each protein. I investigated the functional similarities between E1a and myc by constructing E1a/myc chimaeras to discover whether the individual transforming domains of E1a could complement individual myc-transforming domains. Transformation assays in rat embryo fibroblasts demonstrated that the N-terminal transforming domain of E1a (CR1) could complement the C-terminal transforming domain of myc in cis, and that the reciprocal chimaera (N-terminal myc/C-terminal E1a) was also active. Chimaeras constructed using domains from transformation-defective mutants of either E1a or myc were inactive, indicating that both E1a and myc domains contribute to function. These experiments suggest that transformation by myc and E1a may involve interactions with common substrates.

The E2 protein of human papillomavirus type 16. Over-expression and purification of an active transcriptional regulator

The E2 open reading frame of human papillomavirus type 16 was inserted into the Escherichia coli vector pKK223-3, and expressed to greater than 15% of total cellular protein when induced with isopropyl beta-D-thiogalactopyranoside. The highest expressing clone was grown in bulk and the E2 protein purified to homogeneity by the following procedure: (a) isolation of the insoluble protein fraction; (b) extraction with urea; (c) quaternary amino-ethyl-Sepharose ion-exchange chromatography and (d) renaturation and chromatography on dextran sulphate. That the purified protein was fully functionally active was confirmed by its specific DNA-binding properties and its ability to activate gene transcription by over two orders of magnitude in an in vivo assay.

Novel phenotype of C3H 10T1/2 fibroblasts cotransfected with the c-Ha-ras and adenovirus 5 E1A oncogenes

C3H 10T1/2 fibroblasts are converted to fully transformed phenotype following coexpression of an activated c-Ha-ras gene and either a constitutively expressed viral or cellular myc gene. In this report, we examined whether the early region 1A (E1A) of adenovirus 5, which synergizes with ras to convert primary embryonic cells to a transformed phenotype, can synergize with ras to transform the established mouse embryonic cell line, C3H 10T1/2. We demonstrate that coexpression of ras and E1A generated a transformed phenotype that could be scored by colony assays and by soft agarose assays but not by standard focus assays. The ras-E1A-transformed phenotype relies on sequences present in conserved regions 1 and 2 of the E1A proteins and, in part, on information encoded by the extreme carboxy terminus of E1A. The contrast between the transformed phenotypes generated following the transfection of C3H 10T1/2 cells with either ras and myc or ras and E1A suggests that myc and E1A cooperate with ras to transform C3H 10T1/2 cells by mechanisms that can be distinguished using this established cell line as a model system.

Use of Xenopus oocytes to study the expression of cloned genes and translation of mRNA

One of the most active areas of research in the field of molecular biology is the examination of the mechanisms associated with the regulation of gene expression. Our understanding of the events in eukaryotic transcription has been aided by the ability to test the expression of various genomic DNA constructs after their microinjection into the germinal vesicle of Xenopus oocytes. This in vivo transcription system has permitted the analysis of the involvement of cis-acting DNA sequences and the examination of the effect of co-injected trans-acting factors on gene expression. Furthermore, the Xenopus oocyte has been employed widely as an in vivo translation system. Not only is the Xenopus oocyte system a sensitive assay for the translation of rare mRNAs but it also has the ability to post-translationally modify and compartmentalize numerous types of proteins. Finally, the Xenopus oocyte has proven useful in the procedures associated with the cloning and screening of cDNAs.

Rapid turnover of adenovirus E1A is determined through a co-translational mechanism that requires an aminoterminal domain

The product of the adenovirus E1A 13S mRNA can both stimulate and repress the expression of certain viral and cellular genes. As with several other regulatory proteins, E1A has a short half-life, approximately 40 min. Although this short half-life is observed in cells expressing the E1A gene, it is not the case with cells injected with E1A protein, where its half-life is very long, generally greater than 15 h. We have sought to reconcile these apparent differences in E1A stability. Using Xenopus oocytes, we find that E1A exhibits its characteristic short half-life when it is synthesized from injected mRNA while it has a very long half-life when it is injected as a protein synthesized originally in Escherichia coli or reticulocyte lysates. In order to delineate the amino acids responsible for rapid E1A turnover, several deletion mRNAs were constructed, injected into oocytes, and E1A half-life determined. Carboxyl-terminal deletions and an internal deletion of residues 38-86 failed to increase the half-life of E1A. In contrast, amino-terminal deletions of 70 and 14 residues resulted in very stable E1A proteins (t1/2 greater than 20 h). Furthermore, deletion of the second amino acid, an arginine, resulted in a stable E1A protein. The amino-terminal region of E1A was able to induce the rapid turnover of a normally stable protein, beta-globin, in oocytes injected with an E1A-globin chimeric mRNA. This E1A-induced instability of globin was abolished, however, when the protein was first synthesized in reticulocyte lysates and then injected into oocytes. The amino-terminal region of E1A is also important in governing halflife in adenovirus-infected HeLa cells. These results demonstrate that the half-life of E1A is established cotranslationally through a mechanism involving sequences within the amino-terminal 37 residues.

Novel control elements in the alpha-1 tubulin gene promoter from Chlamydomonas reinhardii

Alpha-1 tubulin is the principal alpha-tubulin isotype found in the flagella of the unicellular green alga, Chlamydomonas reinhardii. Although the pattern of tubulin mRNA accumulation and utilization has been examined in some detail in Chlamydomonas (Lefebvre and Rosenbaum 1986), the transcriptional mechanisms establishing tubulin mRNA levels are not understood. To begin an analysis of the alpha-1 tubulin gene transcriptional control elements, we studied a number of promoter mutants of this gene from Chlamydomonas. These mutants, assayed by injection into Xenopus oocyte nuclei, delimit the promoter to 36 bp of DNA upstream of the cap site and 73 bp of the untranslated mRNA leader. A major rate-controlling element lies in a short GC-rich sequence positioned between the TATA homology and the mRNA cap site (position + 1). A similar sequence motif has been found in the same position upstream of all four tubulin genes of Chlamydomonas (Brunke et al. 1984). A 10 bp linker insertion within this sequence abolishes transcription. A far upstream sequence, located in a fragment between -400 and -800, is an efficiency element, whose deletion inhibits transcription in vivo by about 30%. The upstream element (ue) also has the unique ability to drive RNA polymerase II (RNAPII) transcription in vivo when isolated from all downstream promoter elements, unlike any control element described to date. These results suggest that a sequence within the upstream element is an entry site for RNAPII into the tubulin transcription unit.

The inducible lac operator-repressor system is functional for control of expression of injected DNA in Xenopus oocytes

We have investigated the use of the Escherichia coli lac operator-repressor system to regulate the expression of genes introduced by microinjection into Xenopus laevis oocytes. We observe that expression of an MSV-cat fusion gene, in which the lac operator was inserted between the TATA box and the transcription start point (tsp), or between the tsp and the start codon (ATG), is completely repressed when the lac repressor protein is added to the plasmid suspension prior to injection. The lac repressor had no detectable effect on the expression of a coinjected HSV-1 tk gene that had no operator insertion (or on an MSV-cat gene without an operator), indicating that the nonspecific DNA-binding properties of the repressor do not inhibit transcription. CAT activity expressed from the operator-containing MSV-cat genes transcribed in the oocyte nucleus was also inhibited by repressor injected into the oocyte cytoplasm, showing that biologically active repressor proteins can enter the nucleus from the cytoplasm. Injection of the inducer IPTG into the oocyte cytoplasm markedly derepressed the repressed cat genes but not the HSV-1 tk gene coinjected as an internal control. Overall, our results show that the lac operator-repressor system can be useful as a genetic switch in the regulation of gene expression of injected DNA in frog oocytes. Finally, our observations on the vectors used in this work show that the MSV enhancer significantly activates transcription from the SV40 early promoter in frog oocytes, although previous studies have indicated that the MSV enhancer is not necessary for the activity of the MSV promoter in oocytes [Graves et al., Mol. Cell. Biol. 5 (1985) 1945-1958].

Transformed Xenopus embryos as a transient expression system to analyze gene expression at the midblastula transition

The onset of transcriptional activity during embryogenesis in Xenopus laevis is at the 4000- to 8000-cell stage (stage 8-8.5) and is referred to as the midblastula transition (MBT). Most exogenous circular DNA that is microinjected into the fertilized egg also is expressed at the MBT. The transformed Xenopus embryo at these early stages was used as a transient expression system in order to determine the effects of (1) promoter strength, (2) physical conformation, (3) degree of replication, and (4) a regulatory molecule on the expression of an injected gene coding for chloramphenicol acetyl transferase. This gene linked to a relatively strong promoter (SV40 early promoter -pSV2CAT), a weak promoter (adenovirus early promoter -pE3CAT), or in circular or linear form is expressed at stage 8-8.5 following injection into fertilized eggs. pE3CAT coinjected with the E1a protein (enhances the transcription of the E3 promoter) is also expressed at stage 8.5, but expression is enhanced 2-7.6 fold. These data suggest that the inhibition of transcription prior to the MBT could not be perturbed by either the presence of different promoters or a positive regulatory molecule such as the E1a protein.

Adenovirus E1a proteins repress transcription from the SV40 early promoter

Using a transient expression assay in HeLa cells, we show that products from the adenovirus-5 E1a transcription unit repress transcription from the SV40 early promoter. The repression is unrelated to T antigen autoregulation, occurs maximally with low concentrations of E1a expression plasmid, is exerted at the transcriptional level, and requires functional E1a protein. The 289 and 243 amino acid E1a proteins are equally effective at repressing transcription. Since only the 289 amino acid protein is efficient at activating transcription, we conclude that activation and repression are separate E1a functions. We discuss possible mechanisms for E1a repression and the relationship of repression to the function of E1a in cell immortalization and transformation.

Efficient expression of cloned complementary DNAs for secretory proteins after injection into Xenopus oocytes

Cloned complementary DNAs encoding chicken ovalbumin, chicken prelysozyme and calf preprochymosin, prochymosin and chymosin were inserted downstream from various viral promoters in modified recombinant "shuttle" vectors. Microinjection of the ovalbumin, prelysozyme and preprochymosin constructs into the nuclei of Xenopus laevis oocytes resulted in the synthesis, segregation in membranes and secretion into the extracellular medium of ovalbumin, lysozyme and prochymosin, respectively. Judging from molecular weight estimations, lysozyme and prochymosin were correctly proteolytically processed while ovalbumin, which lacks a cleavable signal sequence, was glycosylated. Injection of the DNA construct encoding prochymosin without its signal sequence resulted in synthesis of prochymosin protein that was localized exclusively in the oocyte cytoplasm. No immunospecific protein was detected after injection of the DNA encoding mature chymosin. In terms of protein expression in oocytes, the Herpes simplex thymidine kinase (TK) promoter was up to sevenfold more effective than the simian virus 40 (SV40) early promoter, and equally as effective as the Moloney murine sarcoma virus long terminal repeat element. Where tested, protein expression in oocytes was much reduced if DNA sequences encoding the SV40 small t intron and its flanking sequences were present in the constructs. S1 nuclease mapping of transcripts produced after injection of DNAs containing the TK promoter indicated that the majority of transcripts initiated at, or within, two bases of the known "cap" site. However, minor transcripts initiating upstream from this site were observed and one (or more) of these transcripts was responsible for the synthesis of an ovalbumin polypeptide containing a 51 amino acid N-terminal extension. This extended protein remained in the oocyte cytosol. When ovalbumin cDNA was inserted into the vectors with opposite polarity to the viral promoter, expression in oocytes resulted in the predominant synthesis and secretion of a variant ovalbumin with a 21 amino acid N-terminal extension, although some full-length ovalbumin was also synthesized and secreted. S1 mapping revealed the presence, in these oocytes, of transcripts of predicted polarity initiating 118 bases upstream from the wild type ovalbumin initiator ATG, at a previously unreported SV40 "promoter". No protein synthesis was detected after the injection of these reverse-orientation constructs into baby hamster kidney (BHK-21) cells.

Replication, integration and expression of exogenous DNA injected into fertilized eggs of Xenopus laevis

We have analyzed the fate of circular and linear DNA molecules following microinjection into the cytoplasm of fertilized eggs of Xenopus laevis. Recombinant plasmids containing sea urchin histone genes (pSp 102), Drosophila ADH genes (sAC-1), and SV40 (SV2 CAT) replicate during the development of the injected frog embryo. In contrast, pBR322 either as monomers or multimers does not appear to replicate as efficiently. Generally, injected circular DNAs were not detectable by the gastrula stage of development, although there were several examples in which these molecules persisted until larval stages. In 90% of the cases, injected linear DNAs persisted as discrete molecules into early embryonic stages. A portion of the DNA sequences complementary to injected linear and circular molecules was detected comigrating with the high-molecular-weight cellular frog DNA (48 kb or larger) from mid-cleavage stages onward. Restriction enzyme analysis of DNA from injected embryos suggested some copies of the injected DNAs were integrated into the frog genome. This occurred in about 10%-30% of the cases of injected circular DNA and approximately 60%-70% of the cases of injected linear DNA. We were able to rescue circular plasmids from the injected blastulae by retransforming Escherichia coli. Restriction enzyme analysis of this DNA suggested that the majority of injected circular DNAs were not modified following replication in the frog embryo. The DNA of Xenopus embryos was highly methylated. On the other hand, injected DNA sequences were not methylated de novo even after many replication cycles in the frog embryo. Ribonucleic acid (RNA) transcripts from the injected DNAs were detectable by the late blastula stage of development.