The cytoskeletal network controls c-Jun translation in a UTR-dependent manner.

The cytoskeleton is a dynamic network that undergoes restructuring during various cellular events, influencing cell proliferation, differentiation, and apoptosis. Here, we report that accumulation of c-Jun, a member of the AP1 family of transcription factors that play a key role in normal and aberrant cell growth, dramatically increases upon depolymerization of the cytoskeleton, and that, unexpectedly, this increase is controlled translationally. Depolymerization of the actin or microtubule network induces an increase in c-Jun accumulation with no corresponding increase in c-Jun mRNA or in the half-life of the c-Jun protein, but rather in the translatability of its transcript. This increase is mediated by the untranslated regions (UTRs) of c-Jun mRNA, and is not dependent on activated mitogen-activated protein kinase pathways. This novel mechanism of c-Jun regulation might be relevant to physiological conditions in which c-Jun plays a pivotal role.

In vitro methylation of the BsuRI (5'-GGCC-3') sites in the E2a region of adenovirus type 2 DNA does not affect expression in Xenopus laevis oocytes.

The early region 2a (E2a) of adenovirus type 2 (Ad2) DNA codes for a 72,000-dalton DNA-binding protein and is expressed in the Ad2-transformed hamster cell line HE1 but not in cell lines HE2 and HE3 (H. Esche, J. Virol. 41:1076-1082, 1982; K. Johansson et al., J. Virol. 27:628-639, 1978). An inverse correlation between DNA methylation at the 5'-CCGG-3' sites of the E2a region and of gene expression in these cell lines has been observed (L. Vardimon et al., Nucleic Acids Res. 8:2461-2473, 1980). When the cloned E2a region of Ad2 DNA is methylated in vitro at the 5'-CCGG-3' sites, the gene is not transcribed after being injected into the nuclei of Xenopus laevis oocytes, whereas unmethylated DNA is expressed (L. Vardimon et al., Eur. J. Cell Biol. 25:13-15, 1981; L. Vardimon et al., Proc. Natl. Acad. Sci. U.S.A. 79:1073-1077, 1982). These data demonstrate that DNA methylation is directly involved in the shut-off of transcription. In the present communication we investigated in detail the control region of the gene for the DNA-binding protein in Ad2-transformed cell lines and showed that the first late control region (map coordinate 72 on the viral DNA) of the E2a region is present in its entirety in cell lines HE1, HE2, and HE3. The HaeIII sites (5'-GGCC-3') in the E2a region in all three cell lines were not methylated. When the DNA methyltransferase BsuRI was used, all 5'-GGCC-3' sites in the cloned E2a region of Ad2 DNA were methylated in vitro. It was shown that methylation of these sites did not inhibit the expression of this viral gene in X. laevis oocytes. Thus, for methylation to affect gene expression in the E2a region it has to occur at specific sites (e.g., 5'-CCGG-3') which may be different for other genes.

Accumulation of c-src mRNA is developmentally regulated in embryonic neural retina.

Accumulation of c-src mRNA gradually increased during early development of the neural retina in chicken embryos and reached a peak by days 11 to 13 of embryonic life. Thereafter, its amount declined to a low level which persisted also in adult retina. The early increase in c-src mRNA correlated inversely with the decrease in the amount of H3.2 replication histone mRNA and with the decline in the rate of cell growth. The accumulation profile of c-src mRNA corresponded to that of pp60c-src protein, suggesting that the latter is regulated at the level of transcription.

Expression of v-src in embryonic neural retina alters cell adhesion, inhibits histogenesis, and prevents induction of glutamine synthetase.

Using Rous sarcoma virus as the vector, v-src or c-src genes were introduced into 6-day chicken embryo retina tissue in organ culture and their effects on retina development were investigated. Overexpression of c-src in many of the cells had no noticeable effect on retina development. In contrast, infection with v-src resulted in abnormal histogenesis and inhibition of differentiation. Although only a portion of the cells in infected tissue expressed the oncogene and displayed the transformation phenotype, the other cells were also hindered from becoming normally positioned and organized. Therefore, presence of oncogene-transformed cells within the tissue hindered organization and development of adjacent nontransformed cells. Failure of normal cell relationships impeded induction by cortisol of glutamine synthetase in Muller glia, which requires contact associations of the glia cells with neurons. The transformed cells tended to assemble into chaotic clusters, suggesting that their adhesiveness and contact affinities had become altered. This was confirmed by aggregation experiments with dissociated cells which showed that adhesiveness of transformed cells was greatly reduced and that they had lost the ability to cohere with nontransformed cells. In binary mixtures of transformed and nontransformed cells, the two sorted out into separate aggregates. Transformed cells formed loose clusters devoid of tissue architecture; aggregates of nontransformed cells became organized into retinotypic structures, and glutamine synthetase was inducible. Our findings suggest that the mechanisms of cell adhesion and cell affinities are a key target of v-src activity in infected cells and that modification of the cell surface may be a leading factor in other cellular changes characteristic of the v-src transformation phenotype.

The cytoskeletal network controls c-Jun expression and glucocorticoid receptor transcriptional activity in an antagonistic and cell-type-specific manner.

The physical and functional link between adhesion molecules and the cytoskeletal network suggests that the cytoskeleton might mediate the transduction of cell-to-cell contact signals, which often regulate growth and differentiation in an antagonistic manner. Depolymerization of the cytoskeleton in confluent cell cultures is reportedly sufficient to initiate DNA synthesis. Here we show that depolymerization of the cytoskeleton is also sufficient to repress differentiation-specific gene expression. Glutamine synthetase is a glia-specific differentiation marker gene whose expression in the retinal tissue is regulated by glucocorticoids and is ultimately dependent on glia-neuron cell contacts. Depolymerization of the actin or microtubule network in cells of the intact retina mimics the effects of cell separation, repressing glutamine synthetase induction by a mechanism that involves induction of c-Jun and inhibition of glucocorticoid receptor transcriptional activity. Depolymerization of the cytoskeleton activates JNK and p38 mitogen-activated protein kinase and induces c-Jun expression by a signaling pathway that depends on tyrosine kinase activity. Induction of c-Jun expression is restricted to Müller glial cells, the only cells in the tissue that express glutamine synthetase and maintain the ability to proliferate upon cell separation. Our results suggest that the cytoskeletal network might play a part in the transduction of cell contact signals to the nucleus.

Cell to cell contacts control the transcription activity of the glucocorticoid receptor.

Contact interactions between glia and neurons are required for hormonal induction of glutamine synthetase in Müller glial cells. Glucocorticoids induce a pronounced increase in glutamine synthetase gene transcription in the intact retinal tissue but not in separated retinal cells. However, if the separated cells are reaggregated and glial cells reestablish contacts with neurons, glutamine synthetase inducibility is restored. This study examines the possible involvement of the glucocorticoid receptor (GR) in cell contact control of glutamine synthetase induction. Using the glucocorticoid-inducible reporter construct, p delta G46TCO, and control constructs that are not inducible by glucocorticoids, we demonstrated that the trans-activating capability of GR markedly declines upon cell separation. Analysis of GR protein revealed that cell separation results in a pronounced decrease in GR expression. This decrease temporally correlated with the decline in glutamine synthetase gene transcription. Cell separation also results in a marked increase in c-Jun expression. This increase might be related to the decline in GR activity since elevation of c-Jun expression in the intact tissue inhibits the transcription activity of GR. Over-expression of GR by transfection of a GR expression vector or activation of endogenous GR molecules by 8-bromo-cAMP enhanced the responsiveness of separated retinal cells to glucocorticoids. These results demonstrate that transcription activity of the receptor protein depends on contact interactions between retinal cells and suggest that GR is involved in cell contact control of glutamine synthetase induction.

Methylation of adenovirus genes in transformed cells and in vitro: influence on the regulation of gene expression?

An inverse correlation has been described between the levels of DNA methylation in specific segments of adenovirus DNA integrated into the genomes of transformed and tumor cells and the extent to which these segments are expressed as messenger RNA. In the adenovirus type 2 (Ad2)-transformed hamster cell lines HE2 and HE3, the virus-specific DNA binding protein (DBP) is not expressed, and the DNA in the DBP gene is completely methylated in all 5'-CCGG-3' sites. At least part of the late promoter/leader sequence of the DBP gene is present in cell lines HE2 and HE3. In line HE1, on the other hand, the DBP is expressed, and the DNA in the DBP gene is unmethylated at the 5'-CCGG-3' (HpaII) sites. The late promotor/leader sequence of the DBP gene is expressed in cytoplasmic RNA isolated from line HE1. The effect of DNA methylation has also been tested in vitro in a microinjection system using Xenopus laevis oocytes. Unmethylated DNA fragments of Ad2 (E2a region) have been found to serve as active templates. When the same fragments are methylated at the 5'-CCGG-3' sites by the HpaII DNA-methyltransferase, viral RNA synthesis is inhibited upon microinjection into oocyte nuclei. These results provide direct evidence for the notion that DNA methylated at highly specific sites is somehow involved in the regulation of gene expression.

Leptin modulates the glucocorticoid-induced ovarian steroidogenesis.

Leptin regulates food intake and other activities through its hypothalamic receptor. Leptin receptors are also found in other organs, including the ovary. Direct effects of leptin in ovarian steroid production were studied in primary rat granulosa cells and in rat and human granulosa cell lines. Leptin (0.6-18 nM) suppressed ovarian steroid synthesis costimulated by FSH and dexamethasone. Production of pregnenolone, progesterone, and 20alpha-hydroxy-4-pregnen-3-one was inhibited by leptin. This inhibition was due at least in part to reduced expression of adrenodoxin, a component of the P450scc system enzyme. Costimulation of progesterone production by forskolin and dexamethasone was also inhibited by leptin, whereas the forskolin-induced cAMP production was not affected. We find that leptin induces c-Jun expression and attenuates the transcriptional activity of the glucocorticoid receptor (GR) in granulosa cells. Elevation of c-Jun expression by other means, e.g. 12-O tetradecanoyl-phorbol-13-acetate or transfecting with a c-Jun expression vector, abolished the transcriptional activity of the GR. A leptin-induced elevation of c-Jun modulates the transcriptional activity of the GR, possibly leading to the observed attenuation of steroidogenesis. It was recently shown that glucocorticoids stimulate leptin expression in vivo, which in turn, inhibits cortisol synthesis. A direct action of leptin on the ovary is an additional element of a regulatory network that maintains the homeostasis of steroid production.

Hormonal and non-hormonal regulation of glutamine synthetase in the developing neural retina.

Two isoforms of the glucocorticoid receptor, with apparent molecular mass of 90 and 95 kDa, are expressed in embryonic chicken neural retina. The 95-kDa receptor represents a hyperphosphorylated form of the 90-kDa receptor. Activation of the glucocorticoid receptor by cortisol results in a dose-dependent increase in receptor phosphorylation, translocation of receptor molecules into the nucleus and a decline in the total amount of the receptor. Activation of the glucocorticoid receptor can also be observed in the developing retinal tissue in ovo. At late embryonic ages, when the systemic level of glucocorticoids increases, a substantial quantity of receptor molecules becomes translocated into the nucleus, the relative level of the 95-kDa isoform increases, and the total amount of receptor declines. Activation of the receptor molecules in ovo correlates directly with an increase in transcription of the glucocorticoid-inducible gene, glutamine synthetase. The close correlation between the increase in systemic glucocorticoids, activation of glucocorticoid receptor molecules and induction of glutamine synthetase gene transcription suggests that glucocorticoids are directly involved in the developmental control of glutamine synthetase expression. Long-term organ culturing of embryonic retinal tissue in the absence of hormone results in an increase in glutamine synthetase expression. This increase, which is only 5 to 10% of that observed in ovo, is not mediated by activated receptor molecules and represents a mechanism for non-hormonal regulation of glutamine synthetase.

Molecular basis for differential expression of glutamine synthetase in retina glia and neurons.

Glutamine synthetase (GS) is a differentiation marker of retina glial cell. It is expressed in the chicken neural retina at a particularly high level, is inducible by glucocorticoids and is always confined to Müller glia. This study investigated the molecular basis for tissue and cell-type specific expression of the GS gene. A high level of GS expression in the retina was found to coincide with the accumulation of a relatively high level of GS mRNA in this tissue. The gliatoxic agent alpha-aminoadipic acid, which can selectively destroy glia cells, was used to demonstrate that restriction of GS induction to Müller glia is controlled at a transcriptional level. Cortisol could induce accumulation of GS mRNA and transcription of the GS gene in Müller glia but not in retina neurons. Glia and neurons were also found to differ in their ability to express the glucocorticoid inducible CAT construct, p delta G46TCO, which is controlled by a 'simple GRE' promoter. When introduced into cells of retina tissue, this construct was cortisol-inducible in glia whereas in neurons it was only slightly inducible or not at all. Introduction of a glucocorticoid receptor expression vector into the cells facilitated induction of the CAT construct in neurons. Analysis by immunoblotting revealed that expression of the glucocorticoid receptor protein is predominantly restricted to Müller glia. These results suggest that differential levels of glucocorticoid receptor expression in glia and neurons might be the basis for cell-type specific induction of GS.

Can DNA methylation regulate gene expression?

The E2a region of the Ad2 genome encodes the Ad2-specific DBP. An inverse correlation between the level of DNA methylation at the 5'-CC*GG-3' sites of the E2a region and the extent of expression of DBP has been demonstrated in Ad2-transformed hamster cell lines (Vardimon et al. 1980). Four different leaders are used in the transcription of the E2a region in cells productively infected with Ad2. The leader located at coordinate 75 on the viral genome is used early after infection and the other three leaders are used late after infection (Chow et al. 1979). The analysis of the integration patterns of the viral DNA in the Ad2-transformed cell lines has revealed that the early leader is deleted in the cell lines which do not express the DBP (Vardimon and Doerfler 1981). The late leader located at coordinate 72 on the viral genome is present. The region encoding that late leader has been subcloned, and the cytoplasmic RNA from the cell line which expresses the DBP has been analyzed. It has been shown that the late leader is used in transformed cells. Hence the absence of the early leader cannot be the immediate reason for the lack of expression of the DBP. Correlations between DNA methylation and the absence of gene expression may indicate that methylation regulates gene expression or that methylation is the consequence of lacking gene expression. In order to decide between these alternatives an in vitro system has been employed. The HindIII A fragment of the Ad2 DNA which encodes the DBP has been methylated in vitro by the HpaII DNA methyltransferase. Methylated or unmethylated HindIII A fragment has been microinjected into the nuclei of Xenopus laevis oocytes. Unmethylated HindIII A fragment has been found to be expressed as specific viral RNA, whereas no viral RNA can be found in oocytes microinjected with methylated HindIII A fragment. The possibility of a nonspecific inhibitory factor in the methylated DNA preparation has been ruled out by the simultaneous microinjection of sea urchin histone gene DNA together with the methylated HindIII A fragment. Histone genes are expressed, while the expression of the methylated viral gene is blocked. By using the single-strand-specific endonuclease S1 we have shown that in Xenopus laevis oocytes initiation of transcription of the E2a region starts exactly at the same site as in Ad2 productively infected cells. These results provide direct evidence for the notion that DNA methylation at specific sites is involved in the regulation of gene expression.

MicroRNA miR-125b controls melanoma progression by direct regulation of c-Jun protein expression.

A fundamental event in the development and progression of malignant melanoma is the deregulation of cancer-relevant transcription factors. We recently showed that c-Jun is a main regulator of tumor progression in melanoma and thus the most important member of the AP-1 transcription factor family for this disease. Interestingly, we revealed that c-Jun expression was regulated on the post-transcriptional level and therefore speculated that miRNAs could be involved in c-Jun regulation. We determined seed sequences for miR-125b and miR-527 in the coding region of c-Jun mRNA that hints at the direct involvement of miRNA-dependent regulation on the protein level. We found that the expression of miR-125b was significantly reduced in malignant melanoma cell lines and tissue samples compared with melanocytes, whereas miR-527 remained unchanged. In further functional experiments, treatment of melanoma cells with pre-miR-125b resulted in strong suppression of cellular proliferation and migration, supporting the role of miR-125b in melanoma. In addition, transfection of pre-miR-125b led to strong downregulation of c-Jun protein but not mRNA expression in melanoma cells. Luciferase assays using reporter plasmids containing the miR-125b seed sequence in the luciferase coding region confirmed the direct interaction with miR-125b. Furthermore, immunoprecipitation of Ago-2 revealed that c-Jun mRNA accumulated in the RNA-induced silencing complex after pre-miR-125b transfection in melanoma cells. In summary, we identified an important role for miR-125b in malignant melanoma. Moreover, we demonstrated post-transcriptional regulation of c-Jun by this miRNA and showed that c-Jun is a main mediator of the effects of miR-125b on melanoma cells.

Post-transcriptional regulation controlled by E-cadherin is important for c-Jun activity in melanoma.

A central event in the development of malignant melanoma is the loss of the tumor-suppressor protein E-cadherin. Here, we report that this loss is linked to the activation of the proto-oncogene c-Jun, a key player in tumorigenesis. In vivo, malignant melanomas show strong expression of the c-Jun protein in contrast to melanocytes. Interestingly, c-Jun mRNA levels did not differ in the melanoma cell lines when compared to melanocytes, suggesting that c-Jun could be regulated at the post-transcriptional level. To uncover the link between E-cadherin and c-Jun, we re-expressed E-cadherin in melanoma cells and detected decreased protein expression and activity of c-Jun. Furthermore, c-Jun accumulation is dependent on active E-cadherin-mediated cell-cell adhesion and regulated via the cytoskeleton. Additionally, we determined that, with respect to c-Jun regulation, there are two melanoma subgroups. One subgroup regulates c-Jun expression via the newly discovered E-cadherin-dependent signaling pathway, whereas the other subgroup uses the MAPKinases to regulate its expression. In summary, our data provide novel insights into the tumor-suppressor function of E-cadherin, which contributes to the suppression of c-Jun protein translation and transcriptional activity independent of MAPKinases.

In Z-DNA the sequence G-C-G-C is neither methylated by Hha I methyltransferase nor cleaved by Hha I restriction endonuclease.

Plasmids carrying 24- or 32-base-pair inserts of alternating (dG-dC) residues were used to analyze the level of methylation of the G-C-G-C sites by Hha I DNA methyltransferase and their cleavage by Hha I endonuclease in the B-DNA or Z-DNA conformation. In supercoiled plasmids in which the inserts formed Z-DNA, the extent of methylation at the insert G-C-G-C sites was dramatically lower than the level of methylation at the G-C-G-C sites located outside the insert in the same plasmid. Similarly, cleavage by Hha I endonuclease was sharply lowered when the insert was in the Z-DNA form. In the relaxed plasmid, all its G-C-G-C sites were methylated to the same extent and the unmethylated sites were readily cleaved. After treatment with the methylase, the supercoiled plasmid was linearized and then digested with Hha I restriction endonuclease. This exposed unmethylated G-C-G-C sites from the insert that had been protected against cleavage in the Z conformation. A chemical reaction was used to study the distribution of the unmethylated cytosine residues. No accumulation of unmethylated cytosine residues was found anywhere along the entire 32-base-pair insert, which is consistent with a cooperative B-Z transition.

Involvement of c-Jun in the control of glucocorticoid receptor transcriptional activity during development of chicken retinal tissue.

The ability of the glucocorticoid receptor (GR) to induce gene expression in embryonic chicken retinal tissue increases dramatically during development, although the quantity of the receptor molecules does not change greatly with age. This study examines the possible involvement of c-Jun in the developmental control of GR activity. Expression of c-Jun in retinal tissue was high at early embryonic ages and declined during development. Elevation of c-Jun expression in retina of mid-developmental ages by treatment with 12-O-tetradecanoyl-phorbol-13-acetate (TPA), or by introduction of a c-Jun expression vector, caused a pronounced decline in the inducibility of the endogenous glutamine synthetase gene and the transiently transfected CAT constructs p delta G46TCO and pGS2.1CAT, that are controlled by a minimal consensus glucocorticoid response element (GRE) promoter and the glutamine synthetase promoter, respectively. The effect of c-Jun was dose dependent and could be reversed by overexpression of GR. C-Jun-evoked repression of GR activity could be relieved by overexpression of Jun D. Overexpression of Jun D could also elevate the responsiveness of early embryonic retina to glucocorticoids and cause a 5-fold increase in p delta G46TCO induction. The effect of Jun D could be reversed by overexpression of c-Jun. Expression of c-Jun might therefore be important for repression of GR activity at early embryonic ages.

Developmental regulation of glutamine synthetase and carbonic anhydrase II in neural retina.

Glutamine synthetase (GS) is expressed in the neural retina only in Muller glia cells and is inducible with cortisol. A chicken genomic clone that contains at least part of the coding region for the GS enzyme was used to investigate developmental changes in the level of GS mRNA in embryonic chicken retina. A major GS transcript (approximately equal to 3 kilobases) detected by the probe begins to accumulate sharply on day 15 of embryonic development. When cortisol is prematurely supplied to early embryonic retina, it induces precocious accumulation of GS mRNA and of the GS enzyme. At later ages, these effects of cortisol are significantly greater, which suggests that competence to transcribe or stabilize GS mRNA in response to stimulation with cortisol increases with development. Carbonic anhydrase II (CA-II) is expressed in early retina in all the cells, but it becomes later restricted to Muller glia. Using cloned CA-II cDNA, we detected a high level of CA-II mRNA in early retina, followed by a decline due to arrest of CA-II mRNA accumulation in differentiated neurons. As glia cells mature, CA-II mRNA and the enzyme increase to a new high level. Therefore, changes in CA-II gene expression during retina development reflect differentiation-dependent cell-type-specific control of CA-II mRNA accumulation.

Patch homologies and the integration of adenovirus DNA in mammalian cells.

The hamster cell line HE5 has been derived from primary hamster embryo cells by transformation with human adenovirus type 2 (Ad2). Each cell contains 2-3 copies of Ad2 DNA inserted into host DNA at apparently identical sites. The site of the junction between the right terminus of Ad2 DNA and hamster cell DNA was cloned and sequenced. The eight [corrected] right terminal nucleotides of Ad2 DNA were deleted. The unoccupied cellular DNA sequence in cell line HE5 , corresponding to the site of the junction between Ad2 and hamster cell DNA, was also cloned; 120-130 nucleotides in the cellular DNA were found to be identical to the cellular DNA sequence in the cloned junction DNA fragment, up to the site of the junction. The unoccupied and the occupied cellular DNAs and the adjacent viral DNA exhibited a few short nucleotide homologies. Patch homologies ranging in length from dodeca - to octanucleotides were detected by computer analyses at locations more remote from the junction site. When the right terminal nucleotide sequence of Ad2 DNA was matched to randomly selected sequences of 401 nucleotides from vertebrate or prokaryotic DNA, similar homologies were observed. It is likely that foreign (viral) DNA can be inserted via short sequence homologies at many different sites of cellular DNA.

Developmental control of glucocorticoid receptor transcriptional activity in embryonic retina.

In chicken embryo retina, competence for induction of the glutamine synthetase [L-glutamate:ammonia ligase (ADP-forming); EC 6.3.1.2] gene by glucocorticoid hormones increases progressively with development; this competence is minimal in 6-day retina (E6) and high by day 10 (E10). Because the level of glucocorticoid receptors (GRs) in the retina does not increase during that time, we investigated whether the transcriptional activity of GR increased between days 6 and 10 of development. The glucocorticoid-inducible chloramphenicol acetyltransferase (CAT) constructs 2GRE-37TK and p delta G46TCO, which contain glucocorticoid-responsive elements attached to a TATA box and to the thymidine kinase promoter, respectively, were transfected into E6 and E10 retinas, and their inducibility was examined. CAT expression could be induced in the transfected E10 retina but was not induced in the transfected E6 retina. However, induction was obtained also in E6 retina after cotransfection with a GR expression vector. Noninducible CAT constructs (pRSV-CAT, pSV2CAT, and pBLCAT2) were expressed at both ages at similar levels. The CAT construct pGS2.1CAT, which is controlled by the upstream sequence of the chicken glutamine synthetase gene, could be induced in E10 retina but was not induced in E6 retina; however, cotransfection with the GR expression vector resulted in induction of pGS2.1CAT also in E6 retina. We interpret these results as showing that the transcriptional activity of GR in embryonic retina is developmentally controlled and suggest that its increase is causally implicated in the development of competence for glutamine synthetase induction.