Identification of a p53 binding site in the human retinoblastoma susceptibility gene promoter.

p53 is a tumor suppressor gene found to be mutated in a wide variety of tumors. The encoded p53 protein has properties of a classical transcription factor, but the promoter targets for its regulation are largely unknown. We have investigated the ability of p53 to regulate activity of the human retinoblastoma susceptibility gene (Rb) promoter using a cotransfection assay in CCL-64 and Saos-2 cells. p53 was able to stimulate transcription from the Rb promoter at low input doses of p53 expression plasmid, whereas transcription was repressed at high input doses. The stimulatory effect of p53 on Rb promoter activity mapped to a region between 4 and 92 base pairs upstream from the start site of translation, whereas the region controlling repression by p53 mapped to the basal transcriptional control region of the promoter between -207 and -185. Moreover, an oligonucleotide containing Rb promoter sequences between -63 and -88 was sufficient to confer stimulation by p53 when inserted upstream from a minimal heterologous promoter. Gel mobility shift analysis was used to demonstrate that p53 can bind to a sequence within the -63 to -88 oligonucleotide with homology to a p53 binding site. The presence of a functional p53 binding site in the human retinoblastoma tumor suppressor gene promoter suggests that p53 can regulate Rb promoter activity.

The human retinoblastoma susceptibility gene promoter is positively autoregulated by its own product.

The product of the retinoblastoma susceptibility gene is a 105-kDa protein that has properties of a cell cycle regulatory factor. Previous reports indicated that two distinct DNA-binding factors, RBF-1 and ATF, play an important part in the transcription of the human retinoblastoma gene (Rb). Recently, we demonstrated that pRb activates expression of the human transforming growth factor-beta 2 gene through ATF-2. Since the human Rb gene promoter also contains an ATF-2-like binding site, we examined whether pRb can regulate its own expression through ATF-2. Here we report that overexpression of Rb stimulates Rb promoter activity through the ATF binding site in a variety of different cell types. Mutation of the ATF binding site of the Rb promoter abolishes the Rb autoinduction. We have also determined that the carboxyl-terminal domain of pRb is responsible for the Rb autoinduction through ATF-2. Rb autoinduction may be important for maintaining the action of pRb during cell growth, and loss of autoinductibility may contribute to retinoblastoma.

CpG methylation inactivates the promoter activity of the human retinoblastoma tumor-suppressor gene.

Cytosine methylation of CpG sites in the promoter region of eucaryotic genes is involved in the inactivation of expression of certain genes. Given that methylation can lead to reduced transcription, it is possible that expression of tumor-suppressor genes is also inactivated by hypermethylation, thereby contributing to the etiology of cancer. Recently we found five sporadic retinoblastoma tumors (16% of all unilateral cases) with hypermethylation of the 5' end of the retinoblastoma gene without detecting any structural abnormalities. However, it is unclear whether the promoter of the retinoblastoma gene is actually inactivated by its hypermethylation. Here we show that specific hypermethylation in the promoter region of the retinoblastoma gene reduces its expression to only 8% of the unmethylated control. Furthermore, we have found that two transcription factors important for the promoter activity, an activating transcription factor (ATF)-like factor and the retinoblastoma binding factor 1, do not bind when their recognition sequences are CpG methylated. These results in vitro strongly support the hypothesis that CpG methylation of the human tumor-suppressor gene can result in the inactivation of the gene and thus lead to oncogenesis.

Release of arachidonic acid and formation of oxygenated derivatives after complement attack on macrophages: role of channel formation.

Treatment of [3H]arachidonic acid ([3H]C20:4)-labeled, antibody-sensitized mouse resident peritoneal macrophages with rabbit serum complement, or C6-deficient rabbit serum + C6, caused hydrolytic release of incorporated [3H]C20:4 from phospholipids, followed by conversion to oxygenated derivatives. The C6 dose-response curve for release of C20:4 plus its metabolites was monotonic, which indicates dependence on channel formation, whereas the dose-response curve for lysis displayed multi-hit behavior. High-performance liquid chromatography demonstrated that the major radiolabeled products in the aqueous phase co-eluted with C20:4, 6-keto-prostaglandin F1 alpha (6-keto-PGF1 alpha), and prostaglandin E2. Kinetic studies of the release of 6-keto-PGF1 alpha, the major metabolite, displayed biphasic characteristics; a moderate amount of this prostaglandin was released before the onset of cell lysis. Experimental evidence obtained by freeze-thaw or by incubation of these cells with melittin or A23187 indicated that cell lysis does not necessarily result in the production of inflammatory mediators. Furthermore, when macrophages were treated with serum complement, it was apparent that the major part of the release was due to C5b-9 and not to the action of C5a. We conclude that release of C20:4 and its derivatives from complement-treated macrophages does not depend on cytolysis, but is a consequence of insertion and channel formation.

Consequences of cell membrane attack by complement: release of arachidonate and formation of inflammatory derivatives.

Treatment of [3H]arachidonic acid [( 3H]C20:4)-labeled and antibody-sensitized Ehrlich ascites tumor cells with guinea pig or rabbit serum complement (C) released up to about 20 or 25% of the incorporated [3H]C20:4 into the aqueous phase as a consequence of C-induced hydrolysis of cellular phospholipid. The dose-response curve of release of [3H]C20:4 from Ehrlich ascites tumor cells, with respect to C, was approximately in the same range as the cytolytic response. In the case of [3H]C20:4-labeled and antibody-sensitized peritoneal mouse macrophages, treatment with C induced release of about 11% of the incorporated 3H as C20:4 and about 6% as prostaglandins, thromboxane B2, and hydroxyicosatetraenoic acids. C6- and C8-deficient rabbit and human sera, respectively, induced release of small amounts of [3H]C20:4 from Ehrlich ascites tumor cells and macrophages; these deficient sera also released traces of oxygenated derivatives from macrophages. Addition of purified C6 or C8 effectively restored release from both cell types, indicating that the terminal C proteins, up to and including C8, are required for the major part of the release. Our results do not rule out a possible requirement for C9.