Smad proteins suppress CCAAT/enhancer-binding protein (C/EBP) beta- and STAT3-mediated transcriptional activation of the haptoglobin promoter.

Activin A, a member of the transforming growth factor beta (TGFbeta) superfamily, blocks interleukin (IL)-6 biological functions. The molecular basis of the influence of this TGFbeta signaling on the IL-6 receptor triggered cascade is unknown. We studied IL-6-induced secretion of the acute phase protein haptoglobin by hepatoma cells. Overexpression of the C/EBPbeta gene, a downstream effector in the IL-6 pathway, activated transcription from the haptoglobin promoter. This was abolished by either a constitutively active form of activin A type IB receptor (CAactRIB) or by a combination of Smad3 and Smad4. Similarly, Smads abolished transcriptional activation by co-stimulation with IL-6 and STAT3. The transcription co-activator p300 partially overcame the suppressive effect of Smads. Electrophoretic mobility shift assays indicated that C/EBPbeta binding to haptoglobin promoter DNA was reduced by over-expression of CAactRIB and Smad4. We thus show that Smad proteins operate as transcription inhibitors on target genes of the IL-6 induced pathway. The effect of Smads is exerted on components of the transcription activation complex and may also involve interference with DNA binding. This study thus depicts molecular sites of interaction between the TGFbeta superfamily and the IL-6 signaling cascades.

Preclinical evaluation of two human anti-hepatitis B virus (HBV) monoclonal antibodies in the HBV-trimera mouse model and in HBV chronic carrier chimpanzees.

Two human monoclonal antibodies (mAbs) against hepatitis B surface antigen (HBsAg) generated in the Trimera mouse system are described. Both mAbs 17.1.41 and 19.79.5 are of the IgG1 isotype and have high affinity constants for HBsAg binding in the range of 10(-10) mol/L. Monoclonal antibody 17.1.41 recognizes a conformational epitope on the a determinant of HBsAg whereas mAb 19.79.5 recognizes a linear one. The 2 mAbs bind to a panel of hepatitis B virus (HBV) subtypes with distinct patterns. The neutralizing activity of these antibodies was tested in 2 different animal model systems. Administration of each mAb to HBV-Trimera mice, a system that provides a mouse model for human hepatitis B infection, reduced the viral load and the percentage of HBV-DNA-positive mice in a dose-dependent manner. These 2 mAbs were more effective than a polyclonal antibody preparation (Hepatect; Biotest Pharma, Dreieich, Germany) in both inhibition of HBV liver infection and reduction of viral load. A single administration of a mixture of these mAbs into HBV chronic carrier chimpanzees resulted in immediate reduction in HBsAg levels followed by recurrence to initial levels within few days. Thus, these mAbs may be potential candidates for preventive therapy or in combination with other antiviral agents against HBV. Further studies in humans are needed to assess these mAbs in various clinical indications.

Stress activated protein kinase p38 is involved in IL-6 induced transcriptional activation of STAT3.

The pleiotropic cytokine interleukin-6 (IL-6) induces acute phase protein expression in HepG2 human hepatoma cells and promotes the growth of mouse B9 hybridoma. The signaling cascades leading to these biological functions are only partially known. We analysed the involvement of MAPK homologues in IL-6 transduction pathways and found that interleukin-6 triggered activation of p38 stress-activated protein kinase (p38) but not of jun kinase. p38 activity was required for biological functions including acute phase protein secretion from HepG2 hepatoma and proliferation of B9 hybridoma cells. Using a reporter gene construct containing a 190 bp promoter fragment of the acute phase protein haptoglobin we found that p38 is involved in transcriptional activation of the haptoglobin promoter by STAT3 but not by NF-IL6. Thus, we present evidence for a role of p38 in IL-6 induced functions and a possible cross-talk between this MAPK homologue and the STAT pathway.

Individual promoter and intron p53-binding motifs from the rat Cyclin G1 promoter region support transcriptional activation by p53 but do not show co-operative activation.

The rat Cyclin G1 gene promoter contains one p53-binding motif upstream of the transcription start site, and a second motif downstream in the first intron. We have investigated the possibility that these motifs co-operate to permit high level promoter activation by p53. Although individual motifs supported p53-dependent, orientation-independent transcriptional activation, using reporter plasmids containing both motifs, we found no evidence for co-operative promoter activation either after co-transfection with human p53 expression plasmids, or after exposure of transfected cells to cisplatin and UV-radiation.

Human monoclonal antibodies specific to hepatitis B virus generated in a human/mouse radiation chimera: the Trimera system.

An approach to develop fully human monoclonal antibodies in a human/mouse radiation chimera, the Trimera system, is described. In this system, functional human lymphocytes are engrafted in normal strains of mice which are rendered immuno-incompetent by lethal total body irradiation followed by radioprotection with severe combined immunodeficient (SCID) mouse bone marrow. Following transplantation, human lymphocytes colonize murine lymphatic organs and secrete human immunoglobulins. We have established this system as a tool to develop fully human monoclonal antibodies, and applied it for the generation of monoclonal antibodies specific for hepatitis B virus surface antigen. A strong memory response to hepatitis B surface antigen was elicited in Trimera engrafted with lymphocytes from human donors positive for antibodies to hepatitis B surface antigen. The human specific antibody fraction in the Trimera was 10(2)-10(3)-fold higher as compared with that found in the donors. Spleens were harvested from Trimera mice showing high specific-antibody titres and cells were fused to a human-mouse heteromyeloma fusion partner. Several stable hybridoma clones were isolated and characterized. These hybridomas produce high-affinity, IgG, anti-hepatitis B surface antigen antibodies demonstrating the potential of the Trimera system for generating fully human monoclonal antibodies. The biological function and the neutralizing activity of these antibodies are currently being tested.

p53 binds and represses the HBV enhancer: an adjacent enhancer element can reverse the transcription effect of p53.

The transcription program of the hepatitis B virus (HBV) genome is regulated by an enhancer element that binds multiple ubiquitous and liver-enriched transcription activators. HBV transcription and replication are repressed in the presence of p53. Here we describe a novel molecular mechanism that is responsible for this repression. The p53 protein binds to a defined region within the HBV enhancer in a sequence-specific manner, and this, surprisingly, results in p53-dependent transcriptional repression in the context of the whole HBV enhancer. This unusual behavior of the HBV enhancer can be reconstituted by replacing its p53-binding region with the p53-binding domain of the mdm2 promoter. Remarkably, mutation of the EP element of the enhancer reversed the effect of p53 from repression to transcriptional stimulation. Furthermore, EP-dependent modulation of p53 activity can be demonstrated in the context of the mdm2 promoter, suggesting that EP is not only required but is also sufficient to convert p53 activity from positive to negative. Our results imply that the transcriptional effect of DNA-bound p53 can be dramatically modulated by the DNA context and by adjacent DNA-protein interactions.

Involvement of p21(WAF1/Cip1), CDK4 and Rb in activin A mediated signaling leading to hepatoma cell growth inhibition.

Cytokines are growth inhibitory in a target cell specific manner. The signaling pathways that characterize each cell type play a crucial role in determining the responsiveness to cytokine triggering. Activin A has been shown to suppress the growth of primary hepatocytes. Similarly, the human HepG2 hepatoma cell line was growth arrested by activin A as judged by lack of cell proliferation and suppression of DNA synthesis. In HepG2 cells activin A further induced accumulation of retinoblastoma protein in the hypophosphorylated form known to prevent entrance into S phase. This finding implies the involvement of cyclin dependent kinases and CDK inhibitors. Examination of HepG2 cells following addition of activin A revealed reduced expression of CDK4 and conversely, an increase in the CKI p21(WAF1/Cip1). This accumulation of p21(WAF1/Cip1) protein was partly due to increased transcriptional activity. Functional inactivation of p53, using a miniprotein that oligomerizes with p53 and abrogates DNA binding, abolished the ability of activin A to induce transcriptional activation from the p21(WAF1/Cip1) promoter. Thus, activin A, like transforming growth factor beta, seems to suppress cell growth through the downstream target Rb. However, each of these cytokines seem to operate through a distinct pathway.

A functional p53-responsive intronic promoter is contained within the human mdm2 gene.

The mdm2 gene is a target for transcriptional activation by the p53 tumor suppressor gene product. Previous work has revealed that the mouse mdm2 gene contains two promoters: one is located upstream to the gene and is active in the absence of p53, the other resides within the first intron and requires p53 for transcriptional activity. To determine whether this unique promoter activation pattern is biologically important, we investigated the structure and function of the corresponding region of the human mdm2 (hmdm2) gene. We report here that the hmdm2 gene also contains an intronic, p53-dependent promoter. The structural features of this promoter are highly conserved between mouse and man, as opposed to the lack of conservation of the first exon. This promoter is triggered in vivo in the presence of activated wild type p53, leading to the production of novel mRNA species. The intronic hmdm2 promoter contains two tandem p53 binding elements. Deletion analysis suggests that optimal promoter activity requires the simultaneous binding of p53 to both elements; this may serve to prevent premature triggering of the promoter by p53.

Identification of p53 target genes through immune selection of genomic DNA: the cyclin G gene contains two distinct p53 binding sites.

An immune-selection procedure was employed in order to isolate p53-binding sites from rat genomic DNA. One such site was found to reside within the first intron of the cyclin G gene. Cyclin G mRNA levels are strongly elevated upon induction of wild type p53 activity in cells carrying a temperature sensitive p53 mutant. The cyclin G gene also carries a second p53-binding motif upstream to its transcriptional start site. The presence of two high affinity p53-binding sites may confer upon the cyclin G gene the potential to be activated very efficiently by p53. These data raise the possibility that cyclin G may be a downstream mediator of at least some of the biological effects of p53.

Wild type p53 can mediate sequence-specific transactivation of an internal promoter within the mdm2 gene.

The p53 tumor suppressor gene product can complex with polypeptides encoded by the mdm2 putative protoncogene. In addition, mdm2 mRNA levels have been shown to increase following the activation of wild type (wt) p53. To determine the basis for the effect of wt p53 on mdm2 mRNA, we studied the interaction of the mdm2 gene with p53. We report that wt p53 can bind sequence-specifically to a DNA region residing downstream to exon 1 of the mdm2 gene. This is correlated with a pronounced p53-dependent transcriptional activation. Efficient p53-dependent transactivation can be obtained with an mdm2 genomic DNA fragment lacking the putative mdm2 promoter. These findings suggest that p53 can induce transcription from an internal promoter located within the mdm2 gene. These findings raise the possibility that, in addition to increasing the overall levels of mdm2 mRNA, wt p53 may also modulate the repertoire of mdm2 transcripts present within the cell.

Sequence-specific DNA binding by p53: identification of target sites and lack of binding to p53 - MDM2 complexes.

An immune selection procedure was employed in order to isolate p53 binding sites from mouse genomic DNA. Two DNA clones capable of tight specific interaction with wild type p53 were subjected to further characterization. In both cases, the p53 binding regions displayed a high degree of sequence homology with the consensus binding site defined for human genomic DNA. One of the clones was found to be derived from the LTR of a retrovirus-like element (a member of the GLN family). The region encompassing the GLN LTR p53 binding site could confer p53 responsiveness upon a heterologous promoter. Furthermore, the expression of the endogenous, chromosomally integrated GLN elements was significantly induced upon activation of wild type p53 in cells harboring a temperature sensitive p53 mutant. Finally, it was demonstrated that p53 - MDM2 complexes fail to bind tightly to such a p53 binding site. This may contribute to the inhibition by MDM2 of p53-mediated transcriptional activation.

Tight DNA binding and oligomerization are dispensable for the ability of p53 to transactivate target genes and suppress transformation.

The p53 tumor suppressor protein can bind tightly to specific sequence elements in the DNA and induce the transactivation of genes harboring such p53 binding sites. Various lines of evidence suggest that p53 binds to its target site as an oligomer. To test whether oligomerization is essential for the biological and biochemical activities of p53, we deleted a major part of the dimerization domain of mouse wild-type p53. The resultant protein, termed p53wt delta SS, was shown to be incapable of forming detectable homo-oligomers in vitro and is, therefore, likely to be predominantly if not exclusively monomeric. In agreement with the accepted model, p53wt delta SS indeed failed to exhibit measurable DNA binding in vitro. Surprisingly, though, it was still capable of suppressing oncogene-mediated transformation and of transactivating in vivo a target gene containing p53 binding sites. These findings indicate that dimerization-defective p53 is biologically active and may engage in productive sequence-specific DNA interactions in vivo. Furthermore, p53 dimerization probably leads to cooperative binding to specific DNA sequences.

Identification of a minimal transforming domain of p53: negative dominance through abrogation of sequence-specific DNA binding.

Mutations in the p53 gene are most frequent in cancer. Many p53 mutants possess transforming activity in vitro. In cells transformed by such mutants, the mutant protein is oligomerized with endogenous cell p53. To determine the relevance of oligomerization for transformation, miniproteins containing C-terminal portions of p53 were generated. These miniproteins, although carrying no point mutation, transformed at least as efficiently as full-length mutant p53. Transforming activity was coupled with the ability to oligomerize with wild-type p53, as well as with the ability to abrogate sequence-specific DNA binding by coexpressed wild-type p53. These findings suggest that p53-mediated transformation may operate through a dominant negative mechanism, involving the generation of DNA binding-incompetent oligomers.

Cotransfection of granulosa cells with simian virus 40 and Ha-RAS oncogene generates stable lines capable of induced steroidogenesis.

Cellular and viral oncogenes are usually defined on the basis of their ability to elicit neoplastic transformation. However, oncogene activity has also been implicated in the control of differentiation. We have tested whether transfection of primary cultured granulosa cells with various oncogenes can yield cell lines that maintain their differentiated properties. Primary granulosa cells were prepared from diethylstilbestrol-treated immature female rats and transfected with simian virus 40 (SV40) DNA or with SV40 plus activated human Ha-RAS oncogene. Transfection with SV40 plus Ha-RAS yielded cell lines that lost response to gonadotropins but, after 48 hr of stimulation with isoproterenol, cholera toxin, forskolin, or 8-bromoadenosine 3',5'-cyclic monophosphate (8-Br-cAMP), produced progesterone at levels comparable to those of differentiated primary cells. In contrast, cells transformed only by SV40 lost their ability to produce progesterone. Whereas in primary cell cultures progesterone production was already evident after a 3-hr incubation with 1 mM 8-Br-cAMP, in cotransfected cells progesterone production became evident only after 12 hr. All cotransformed cell lines produced SV40 large tumor antigen as well as human RAS p21 protein. The expression of the expected oncogenes in the various cell lines was confirmed by mRNA analysis. These results suggest that the expression of an activated RAS oncogene in granulosa cells can play a role in preserving inducible steroidogenesis.