Erhard Wintersberger

Histone Deacetylase 1 Can Repress Transcription by Binding to Sp1

ABSTRACT The members of the Sp1 transcription factor family can act as both negative and positive regulators of gene expression. Here we show that Sp1 can be a target for histone deacetylase 1 (HDAC1)-mediated transcriptional repression. The histone deacetylase inhibitor trichostatin A activates the chromosomally integrated murine thymidine kinase promoter in an Sp1-dependent manner. Coimmunoprecipitation experiments with Swiss 3T3 fibroblasts and 293 cells demonstrate that Sp1 and HDAC1 can be part of the same complex. The interaction between Sp1 and HDAC1 is direct and requires the carboxy-terminal domain of Sp1. Previously we have shown that the C terminus of Sp1 is necessary for the interaction with the transcription factor E2F1 (J. Karlseder, H. Rotheneder, and E. Wintersberger, Mol. Cell. Biol. 16:1659–1667, 1996). Coexpression of E2F1 interferes with HDAC1 binding to Sp1 and abolishes Sp1-mediated transcriptional repression. Our results indicate that one component of Sp1-dependent gene regulation involves competition between the transcriptional repressor HDAC1 and the transactivating factor E2F1.

Interaction of Sp1 with the growth- and cell cycle-regulated transcription factor E2F.

Within the region around 150 bp upstream of the initiation codon, which was previously shown to suffice for growth-regulated expression, the murine thymidine kinase gene carries a single binding site for transcription factor Sp1; about 10 bp downstream of this site, there is a binding motif for transcription factor E2F. The latter protein appears to be responsible for growth regulation of the promoter. Mutational inactivation of either the Sp1 or the E2F site almost completely abolishes promoter activity, suggesting that the two transcription factors interact directly in delivering an activation signal to the basic transcription machinery. This was verified by demonstrating with the use of glutathione S-transferase fusion proteins that E2F and Sp1 bind to each other in vitro. For this interaction, the C-terminal part of Sp1 and the N terminus of E2F1, a domain also present in E2F2 and E2F3 but absent in E2F4 and E2F5, were essential. Accordingly, E2F1 to E2F3 but not E2F4 and E2F5 were found to bind sp1 in vitro. Coimmunoprecipitation experiments showed that complexes exist in vivo, and it was estabilished that the distance between the binding sites for the two transcription factors was critical for optimal promoter activity. Finally, in vivo footprinting experiments indicated that both the sp1 and E2F binding sites are occupied throughout the cell cycle. Mutation of either binding motif abolished binding of both transcription factors in vivo, which may indicate cooperative binding of the two proteins to chromatin-organized DNA. Our data are in line with the hypothesis that E2F functions as a growth- and cell cycle regulated tethering factor between Sp1 and the basic transcription machinery.

The Tumor Suppressor p53 and Histone Deacetylase 1 Are Antagonistic Regulators of the Cyclin-Dependent Kinase Inhibitor p21/WAF1/CIP1 Gene

ABSTRACT The cyclin-dependent kinase inhibitor p21/WAF1/CIP1 is an important regulator of cell cycle progression, senescence, and differentiation. Genotoxic stress leads to activation of the tumor suppressor p53 and subsequently to induction of p21 expression. Here we show that the tumor suppressor p53 cooperates with the transcription factor Sp1 in the activation of the p21 promoter, whereas histone deacetylase 1 (HDAC1) counteracts p53-induced transcription from the p21 gene. The p53 protein binds directly to the C terminus of Sp1, a domain which was previously shown to be required for the interaction with HDAC1. Induction of p53 in response to DNA-damaging agents resulted in the formation of p53-Sp1 complexes and simultaneous dissociation of HDAC1 from the C terminus of Sp1. Chromatin immunoprecipitation experiments demonstrated the association of HDAC1 with the p21 gene in proliferating cells. Genotoxic stress led to recruitment of p53, reduced binding of HDAC1, and hyperacetylation of core histones at the p21 promoter. Our findings show that the deacetylase HDAC1 acts as an antagonist of the tumor suppressor p53 in the regulation of the cyclin-dependent kinase inhibitor p21 and provide a basis for understanding the function of histone deacetylase inhibitors as antitumor drugs.

Coordinated trans activation of DNA synthesis- and precursor-producing enzymes by polyomavirus large T antigen through interaction with the retinoblastoma protein.

Previously constructed Swiss mouse 3T3 fibroblasts producing polyomavirus large T antigen after addition of dexamethasone were used to study the transcriptional activation by the viral protein of five genes coding for enzymes involved in DNA synthesis and precursor production, namely, dihydrofolate reductase, thymidine kinase, thymidylate synthase, DNA polymerase alpha, and proliferating-cell nuclear antigen. It was found that all these genes, whose expression is stimulated at the G1/S boundary of the cell cycle after growth stimulation by serum addition, are coordinately trans activated when T antigen is induced in cells previously growth arrested by serum withdrawal. Cell lines carrying the information for a mutant form of large T antigen, in which a glutamic acid residue in the binding site for the retinoblastoma protein was changed into aspartic acid, were constructed to test the involvement of an interaction of T antigen with the retinoblastoma protein in this reaction. It was found that the mutated T protein is incapable of stimulating transcription of any one of the genes. The promoter of three of the genes (dihydrofolate reductase, thymidine kinase, and DNA polymerase alpha) unequivocally carries binding sites for transcription factor E2F, suggesting that complexes forming with this growth- and cell cycle-regulating transcription factor are the targets for T antigen. Although there is so far no evidence that thymidylate synthase and proliferating cell nuclear antigen are regulated via E2F, our data indicate that the retinoblastoma protein still is involved in the control of these genes. mRNA for E2F itself increases in amount at the G1/S border in serum-stimulated cells but not during polyomavirus T antigen-induced transcriptional activation of DNA synthesis enzymes in arrested cells.

Sp1 and NF-Y Are Necessary and Sufficient for Growth-dependent Regulation of the Hamster Thymidine Kinase Promoter

Thymidine kinase (TK) genes from different species are growth- and cell cycle-regulated in a very similar manner; still, the promoter regions of these genes show little homology to each other. It was previously shown that the murine TK gene is growth-regulated by Sp1 and E2F. Here we have characterizedcis-regulatory elements in the hamster promoter that are essential and sufficient to confer efficient and serum-responsive expression. The TK promoter was isolated from baby hamster kidney cells. DNase I protection experiments revealed a protected region from positions −24 to −99 relative to the transcription start site. Within this region, binding sites for the transcription factor Sp1 and a CCAAT box, which interacts with the transcription factor NF-Y, were identified. An E2F-like sequence was found not to bind protein, and its removal did not affect promoter activity. This was supported by the observation that cotransfection of a hamster TK reporter gene construct with E2F-1 does not lead to transactivation of the promoter. A 122-base pair region that contains a single Sp1 site, a CCAAT box, and a TATA element was found to be sufficient for serum-responsive expression of a reporter gene. Mutations that inactivate any one of these three elements caused a strong reduction or a loss of promoter activity.

Rifamycin insensitivity of RNA synthesis in yeast

Rifamycin and its derivatives are strong inhibitors of RNA synthesis in bacteria but not in the nuclei of animal cells [l-3] . It has been shown that the antibiotic binds to the bacterial DNA-dependent RNA polymerase, thereby interfering with the process of chain intiation [4-61 . The sensitivity or insensitivity of RNA synthesis towards rifamycin istherefore a property of the respective enzymes. This distinguishes rifamycin from other antibiotic inhibitors of RNA synthesis, such as actinomycin, which are known to react with the DNA template rather than with the polymerase. In this communication we report studies on the effect of rifampicin, a highly potent rifamycin deriva.tive, on the synthesis of RNA catalyzed by cellular extracts as well as by a partially purified preparation of DNA-dependent RNA polymerase from the yeast, Saccharomyces cerevisiae. In addition, we have examined the influence of the antibiotic on the RNA synthesis in isolated and highly purified yeast mitochondria. Rifamycin was found to be without effect on these reactions, even at concentrations as high as 50 pg/ml.

DNA-dependent RNA polymerases from yeast. Partial characterization of three nuclear enzyme activities.

Studies on DNA-dependent RNA polymerases from nuclei of animal cells had shown that these enzyme activities can be separated into two or three fractions on DEAE-Sephadex columns [l-3] . One of these fractions (enzyme B according to the nomenclature of Kedinger, Nuret and Chambon [4] ), is inhibited by cu-amanitin and thus contrasts to fraction A, which is of nucleolar origin and insensitive to the drug [3, 51. More detailed characterization of the enzyme fractions A and B has provided evidence that both contain more than one enzyme protein differing in their subunit composition [4, 6-81 . We are interested in the DNA-dependent RNA polymerases from yeast for the following reasons: (1) yeast cells can be obtained in large quantities and thus provide a very suitable starting material for the purification and molecular characterization of RNA polymerases, (2) yeast is one of the simplest, non-differentiated eukaryotes and it is therefore of interest to compare its RNA polymerases with those of the more complicated, differentiated animal cells and (3) by variation of the growth conditions, yeast cells can be obtained in different physiological states and it would be interesting to investigate whether such changes have an effect on the distribution and activity of the RNA polymerases. Multiple forms of DNA-dependent RNA polymerase from yeast have been reported recently [9, lo] ; however a more detailed comparison of these enzymes with each other and with the respective polymerases from animal cells is still lacking. We have obtained evidence for the occurrence in sonified yeast extracts of three DNA-dependent RNA polymerases of nuclear origin. The three enzymes differ in their template specificity and in their sensitivity towards cu-amanitin.

Overexpression of Thymidine Kinase mRNA Eliminates Cell Cycle Regulation of Thymidine Kinase Enzyme Activity

Expression of thymidine kinase (TK) enzyme activity and mRNA is strictly S phase-specific in primary cells. In contrast, DNA tumor virus-transformed cells have enhanced and constitutive levels of TK mRNA during the whole cell cycle. Their TK protein abundance, however, still increases at the G-S transition and stays high throughout G until mitosis. Therefore, post-transcriptional control must account for the decoupling of TK mRNA from protein synthesis in G. To characterize the underlying mechanism, we studied the consequences of TK mRNA abundance on the cell cycle-dependent regulation of TK activity in nontransformed cells. Constitutive as well as conditional human and mouse TK cDNA vectors were stably transfected into mouse fibroblasts, which were subsequently synchronized by centrifugal elutriation. Low constitutive TK mRNA expression still resulted in a fluctuation of TK activity with a pronounced maximum in S phase. This pattern of cell cycle-dependent TK activity variation reflected the one in primary cells but is caused by post-transcriptional control. Increasing overexpression of TK transcripts after hormonal induction compromised this regulation. At the highest constant mRNA levels, regulation of enzyme activity was totally abolished in each phase of the cell cycle. These data indicate that post-transcriptional regulation of TK is tightly coupled to the amount of mRNA; high concentrations apparently titrate a factor(s) required for repressing TK production during G and presumably also G.

Alternate Activation of Two Divergently Transcribed Mouse Genes from a Bidirectional Promoter Is Linked to Changes in Histone Modification

Thymidine kinase (TK) is a growth factor-inducible enzyme that is highly expressed in proliferating mammalian cells. Expression of mouse TK mRNA is controlled by transcriptional and posttranscriptional mechanisms including antisense transcription. Here we report the identification of a novel gene that is divergently transcribed from the bidirectional TK promoter. This gene encodes kynurenine formamidase (KF), an enzyme of the tryptophan metabolism. Whereas the TK gene is induced upon interleukin-2-mediated activation of resting T cells, the KF gene becomes simultaneously repressed. The TK promoter is regulated by E2F, SP1, histone acetyltransferases, and deacetylases. The binding site for the growth-regulated transcription factor E2F is beneficial for TK promoter activity but not required for KF expression. In contrast, the SP1 binding site is crucial for transcription in both directions. Inhibition of histone deacetylases by trichostatin A leads to increased histone acetylation at the TK/KF promoter and thereby to selective activation of the TK promoter and simultaneous shut-off of KF expression. Similarly, TK gene activation by interleukin-2 is linked to histone hyperacetylation, whereas KF expression correlates with reduced histone acetylation. The KF gene is the rare example of a mammalian gene whose expression is linked to histone hypoacetylation at its promoter.

DNA amplification: New insights into its mechanism

DNA amplification is a process whereby a limited part of the genome is increased in copy number with various consequences for the cell. It is frequently observed in cancer cells and it can be induced in mammalian cells grown in culture as well as in tumor cells when these are subjected to growth inhibiting drugs. In recent years new insights into the mechanisms involved in DNA amplification have been obtained; discussion of these will form the major subject of this short review.