SUMMARY Inhibitors of histone deacetylases (HDACi) hold a considerable therapeutic promise as clinical anticancer therapies. However, currently known HDACi exhibit limited isoform specificity, off-target activity, and undesirable pharmaceutical properties. Thus, HDACi with new chemotypes are needed to overcome these limitations. Here, we identify a class of HDACi with a previously undescribed benzoylhydrazide scaffold that is selective for the class I HDACs. These compounds are competitive inhibitors with a fast-on/slow-off HDAC-binding mechanism. We show that the lead compound, UF010, inhibits cancer cell proliferation via class I HDAC inhibition. This causes global changes in protein acetylation and gene expression resulting in activation of tumor suppressor pathways and concurrent inhibition of several oncogenic pathways. The isotype selectivity coupled with interesting biological activities in suppressing tumor cell proliferation support further preclinical development of the UF010 class of compounds for potential therapeutic applications.
Acetyltransferase p300 (KAT3B) plays key roles in signaling cascades that support cancer cell survival and sustained proliferation. Thus, p300 represents a potential anticancer therapeutic target. To discover novel anticancer agents that target p300, we conducted a high-throughput screening campaign. A library of 622,079 compounds was assayed for cytotoxicity to the triple-negative breast cancer (TNBC) cell line MDA-MB-231 but not to the human mammary epithelial cells. The resulting compounds were tested in a biochemical assay for inhibiting the enzymatic activity of p300. One compound (L002, NSC764414) displayed an IC50 of 1.98 μM against p300 in vitro, inhibited acetylation of histones and p53, and suppressed STAT3 activation in cell-based assays. L002 could be docked to the active site of the p300 catalytic domain. Biochemical tests of a series of related compounds revealed functional groups that may impact inhibitory potency of L002 against p300. Interestingly, these analogs showed inhibitory activities against CBP (the cellular paralog of p300), PCAF and GCN5, but not to other acetyltransferases (KAT5, KAT6B and KAT7), histone deacetylases (HDACs) and histone methyltransferases. Among the NCI-60 panel of cancer cell lines, leukemia and lymphoma cell lines were extremely sensitive to L002, whereas it is toxic to only a limited number of cell lines derived from solid tumors. Notably, breast cancer cell lines, especially those derived from TNBC, were highly susceptible to L002. In vivo, it potently suppressed tumor growth and histone acetylation of MDA-MB-468 xenografts. Thus, these new acetyltransferase inhibitors are potential anticancer therapeutics.
Potent and histone deacetylase 3 (HDAC3)-specific PROTAC XZ9002 is reported here.
In normal cells p53 activity is tightly controlled and MDM2 is a known negative regulator. Here we show that via its acidic domain, Daxx binds to the COOH-terminal domain of p53, whose positive charges are critical for this interaction, as Lys to Arg mutations preserved, but Lys to Ala or Ser to Glu mutations abolished Daxx-p53 interaction. These results thus implicate acetylation and phosphorylation of p53 in regulating its binding to Daxx. Interestingly, whereas Daxx did not bind to p53 in cells as assessed by immunoprecipitation, MDM2 expression restored p53-Daxx interaction, and this correlated with deacetylation of p53. In p53/MDM2-null mouse embryonic fibroblasts (DKO MEF), Daxx repressed p53 target promoters whose p53-binding elements were required for the repression. Coexpression of Daxx and MDM2 led to further repression. p53 expression in DKO MEF induced apoptosis and Daxx expression relieved this effect. Similarly, in HCT116 cells, Daxx conferred striking resistance to 5-fluorouracil-induced apoptosis. As p53 is required for 5-fluorouracil-induced cell death, our data show that Daxx can suppress cell death induced by p53 overexpression and p53-dependent stress response. Collectively, our data reveal Daxx as a novel negative regulator of p53. Importantly, posttranslational modifications of p53 inhibit Daxx-p53 interaction, thereby relieving negative regulation of p53 by Daxx.The critical role of p53 in tumor suppression is manifested in frequent mutations of the p53 gene in cancers (ϳ50% of all human cancers) and in its inactivation in many other cancers by cellular or viral oncogenes and other epigenetic alterations (1). p53-deficient mice develop normally, although such mice exhibit higher incidence of tumors than their wild-type counterparts, demonstrating a critical role for p53 in suppressing tumors (2). p53 exerts its tumor suppression function by activating expression of genes involved in growth arrest and apoptosis (3, 4), and it can also induce apoptosis directly by binding to Bcl-2 family proteins and triggering cytochrome c release (5). Inducing growth arrest and cell death by p53 can impact negatively on normal cell growth and organismal development. Indeed, deletion of the mdm2 gene, whose product is a negative regulator of p53, results in embryonic lethality, but deletion of both p53 and mdm2 simultaneously completely rescues such lethal phenotype (6, 7). Thus, p53 activity must be tightly controlled under physiological conditions. In addition to MDM2, numerous cellular and viral proteins interact with p53 and these proteins can positively or negatively modulate p53-mediated biological effects. Recently, we and others demonstrated that the transcriptional corepressor Daxx interacts with p53 (8 -10), but the biological significance of this interaction remains to be explored.Daxx was initially identified as a binding protein of Fas death domain and was shown to potentiate Fas-mediated apoptosis (11). Subsequent studies implicate Daxx in promoting apoptosis in diverse stress conditions (12-1...
In a genome-wide screen for putative tumor suppressor genes, the EBF3 locus on the human chromosome 10q26.3 was found to be deleted or methylated in 73% of the examined cases of brain tumors. EBF3 is expressed in normal brain but is silenced in brain tumors. Therefore, it is suggested that EBF3 is a tumor suppressor. However, it remains unknown whether inactivation of EBF3 locus also occurs in other types of tumors and what functions of EBF3 underlie EBF3-mediated tumor suppression. We show here that expression of EBF3 resulted in cell cycle arrest and apoptosis. The expression of cyclindependent kinase inhibitors was profoundly affected with early activation and then repression of p21 cip1/waf1 and persistent activation of both p27 kip1 and p57 kip2 , whereas genes involved in cell survival and proliferation were suppressed. EBF3 bound directly to p21 cip1/waf1 promoter and regulated transcription from both p21 cip1/waf1 and p27 kip1 promoters in reporter assays. Apoptosis occurred 48 hours after EBF3 expression with caspase-3 activation. Silencing of the EBF3 locus was observed in brain, colorectal, breast, liver, and bone tumor cell lines and its reactivation was achieved on treatment with 5-aza-2 ¶-deoxycytidine and trichostatin A in a significant portion of these tumor cells. Therefore, EBF3 regulates a transcriptional program underlying a putative tumor suppression pathway.
Hyperacute rejection (HAR) is the first critical immunological hurdle that must be addressed in order to develop xenogeneic organs for human transplantation. In the area of cell-based xenotransplant therapies, natural antibodies (XNA) and complement have also been considered barriers to successful engraftment. Transgenic expression of human complement inhibitors in donor cells and organs has significantly prolonged the survival of xenografts. However, expression of complement inhibitors without eliminating xenogeneic natural antibody (XNA) reactivity may provide insufficient protection for clinical application. An approach designed to prevent XNA reactivity during HAR is the expression of human alpha1, 2-fucosyltransferase (H-transferase, HT). H-transferase expression modifies the cell surface carbohydrate phenotype of the xenogeneic cell, resulting in the expression of the universal donor O antigen and a concomitant reduction in the expression of the antigenic Galalpha1,3-Gal epitope. We have engineered various transgenic pig lines that express HT in different cells and tissues, including the vascular endothelium. We demonstrate that in two different HT transgenic lines containing two different HT promoter constructs, expression can be differentially regulated in a constitutive and cytokine-inducible manner. The transgenic expression of HT results in a significant reduction in the expression of the Galalpha1,3-Gal epitope, reduced XNA reactivity, and an increased resistance to human serum-mediated cytolysis. Transgenic pigs that express H-transferase promise to become key components for the development of xenogeneic cells and organs for human transplantation.
The adenovirus E1B 55-kDa protein impairs the p53 pathway and enhances transformation, although the underlying mechanisms remain to be defined. We found that Daxx binds to the E1B 55-kDa protein in a yeast two-hybrid screen. The two proteins interact through their C termini. Mutation of three potential phosphorylation sites (S489/490 and T494 to alanine) within the E1B 55-kDa protein did not affect its interaction with Daxx, although such mutations were previously shown to inhibit E1B's ability to repress p53-dependent transcription and to enhance transformation. In addition to their coimmunoprecipitation in 293 extracts, purified Daxx interacted with the E1B 55-kDa protein in vitro, indicating their direct interaction. In 293 cells, Daxx colocalized with the E1B 55-kDa protein within discrete nuclear dots, where p53 was also found. Such structures were distinct from PML (promyelocytic leukemia protein) bodies, and it appeared that Daxx was displaced from PML bodies. Thus, the Daxx concentration was diminished in dots with a prominent presence of PML and vice versa. Indeed, PML overexpression led to dramatic redistribution of Daxx from p53-E1B 55-kDa protein complexes to PML bodies. Additionally, expression of the E1B 55-kDa protein in Saos2 osteosarcoma cells reduced the number of PML bodies. Our data suggest that E1B and PML compete for available Daxx in the cell. Surprisingly, Daxx significantly augmented p53-mediated transcription and the E1B 55-kDa protein eliminated this effect. Thus, it is likely that the E1B 55-kDa protein sequesters Daxx and p53 in specific nuclear locations, where p53 cannot activate transcription. One consequence of the Daxx-E1B interaction might be an alteration of normal interactions of Daxx, PML, and p53, which may contribute to cell transformation.Cancer arises from a cell that undergoes a number of specific changes. Transformation of primary human cells requires at least four genetic events: inactivation of both the p53 and pRb pathways, activation of mitogenic oncogenes such as ras, and telomere maintenance (11). These genetic changes may also underlie cell transformation induced by DNA tumor viruses. In fact, it is well known that several viral oncogenes involved in virus-induced cell transformation inactivate both the p53 and pRb pathways. These viral oncogenes include the simian virus 40 (SV40) large T antigen, the human papillomavirus (HPV) 16 E6 and E7 proteins, and the adenovirus (Ad) E1A and E1B proteins (1). Recent in vitro cell transformation experiments used the SV40 large T antigen and the HPV E6 and E7 oncogenes to inactivate the p53 and pRb pathways (11,25). Interestingly, in combination with ras and the gene for the catalytic subunit of telomerase, the SV40 large T antigen effectively transformed human primary cells (11), but HPV E6 and E7 failed to do so (25), suggesting that inactivation of cellular pathways in addition to pRb and p53 may be required in malignant transformation.
p53 SUMOylation promotes its nuclear export. The SIM-binding groove of a SUMO moiety linked to p53 and a SIM in CRM1 regulates their interaction. CRM1 binds to tetrameric p53 with a properly folded core domain, and CRM1 with a mutated SIM in the HEAT9 loop accumulates with SUMOylated p53 at NPCs and cytoplasmic aggregates.
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