Effective eradication of cancer requires treatment directed against multiple targets. The p53 and nuclear factor κB (NF-κB) pathways are dysregulated in nearly all tumors, making them attractive targets for therapeutic activation and inhibition, respectively. We have isolated and structurally optimized small molecules, curaxins, that simultaneously activate p53 and inhibit NF-κB without causing detectable genotoxicity. Curaxins demonstrated anticancer activity against all tested human tumor xenografts grown in mice. We report here that the effects of curaxins on p53 and NF-κB, as well as their toxicity to cancer cells, result from “chromatin trapping” of the FACT (facilitates chromatin transcription) complex. This FACT inaccessibility leads to phosphorylation of the p53 Ser392 by casein kinase 2 and inhibition of NF-κB–dependent transcription, which requires FACT activity at the elongation stage. These results identify FACT as a prospective anticancer target enabling simultaneous modulation of several pathways frequently dysregulated in cancer without induction of DNA damage. Curaxins have the potential to be developed into effective and safe anticancer drugs.
The circadian clock controls many physiological parameters including immune response to infectious agents, which is mediated by activation of the transcription factor NF-κB. It is widely accepted that circadian regulation is based on periodic changes in gene expression that are triggered by transcriptional activity of the CLOCK/BMAL1 complex. Through the use of a mouse model system we show that daily variations in the intensity of the NF-κB response to a variety of immunomodulators are mediated by core circadian protein CLOCK, which can up-regulate NF-κB-mediated transcription in the absence of BMAL1; moreover, BMAL1 counteracts the CLOCK-dependent increase in the activation of NF-κB-responsive genes. Consistent with its regulatory function, CLOCK is found in protein complexes with the p65 subunit of NF-κB, and its overexpression correlates with an increase in specific phosphorylated and acetylated transcriptionally active forms of p65. In addition, activation of NF-κB in response to immunostimuli in mouse embryonic fibroblasts and primary hepatocytes isolated from Clock-deficient mice is significantly reduced compared with WT cells, whereas Clock-Δ19 mutation, which reduces the transactivation capacity of CLOCK on E-box-containing circadian promoters, has no effect on the ability of CLOCK to up-regulate NF-κB-responsive promoters. These findings establish a molecular link between two essential determinants of the circadian and immune mechanisms, the transcription factors CLOCK and NF-κB, respectively.
Acquisition of a transformed phenotype involves deregulation of several signal transduction pathways contributing to unconstrained cell growth. Understanding the interplay of different cancer-related signaling pathways is important for development of efficacious multitargeted anticancer drugs. The small molecule 9-aminoacridine (9AA) and its derivative, the antimalaria drug quinacrine, have selective toxicity for tumor cells and can simultaneously suppress nuclear factor-jB (NF-jB) and activate p53 signaling. To investigate the mechanism underlying these drug activities, we used a combination of twodimensional protein separation by gel electrophoresis and mass spectrometry to identify proteins whose expression is altered in tumor cells by 9AA treatment. We found that 9AA treatment results in selective downregulation of a specific catalytic subunit of the phosphoinositide 3-kinase (PI3K) family, p110c. Further exploration of this observation demonstrated that the mechanism of action of 9AA involves inhibition of the prosurvival AKT/ mammalian target of rapamycin (mTOR) pathway that lies downstream of PI3K. p110c translation appears to be regulated by mTOR and feeds back to further modulate mTOR and AKT, thereby impacting the p53 and NF-jB pathways as well. These results reveal functional interplay among the PI3K/AKT/mTOR, p53 and NF-jB pathways that are frequently deregulated in cancer and suggest that their simultaneous targeting by a single small molecule such as 9AA could result in efficacious and selective killing of transformed cells.
Nuclear factorκB (NFκB) plays a critical role in cancer development and progression. Thus, the NFκB signaling pathway provides important targets for cancer chemoprevention and anticancer chemotherapy. The central steps in NFκB activation are phosphorylation and proteasome-dependent degradation of its inhibitory proteins termed IκBs. Consequently, the major pharmacological approaches to target NFκB include (1) repression of IκB kinases (IKKs) and (2) blocking the degradation of IκBs by proteasome inhibitors. We quantitatively compared the efficacy of various proteasome inhibitors (MG132, lactacystin and epoxomicin) and IKK inhibitors (BAY 11-7082 and PS1145) to block NFκB activity induced by TNFα or TPA and to sensitize LNCaP prostate carcinoma cells to apoptosis. Our studies revealed significant differences between these two classes of NFκB inhibitors. We found that proteasome inhibitors epoxomicin and MG132 attenuated NFκB induction much more effectively than the IKK inhibitors. Furthermore, in contrast to IKK inhibitors, all studied proteasome inhibitors specifically blocked TPA-induced generation de novo of NFκB p50 homodimers-(p50/p50). These results suggest that the proteasome plays a dominant role in TPA-induced formation of functional p50 homodimers, while IKK activity is less important for this process. Interestingly, profound attenuation of p50/p50 DNA-binding does not reduce the high potency of proteasome inhibitors to suppress NFκB-dependent transcription. Finally, proteasome inhibitors were much more effective in sensitizing LNCaP cells to TNFα-induced apoptosis compared to IKK inhibitors at the concentrations when both types of agents similarly attenuated NFκB activity. We conclude that this remarkable pro-apoptotic potential of proteasome inhibitors is partially mediated through NFκB-independent mechanism.
The 9-aminoacridine (9AA) derivative quinacrine (QC) has a long history of safe human use as an antiprotozoal and antirheumatic agent. QC intercalates into DNA and RNA and can inhibit DNA replication, RNA transcription, and protein synthesis. The extent of QC intercalation into RNA depends on the complexity of its secondary and tertiary structure. Internal ribosome entry sites (IRESs) that are required for initiation of translation of some viral and cellular mRNAs typically have complex structures. Recent work has shown that some intercalating drugs, including QC, are capable of inhibiting hepatitis C virus IRES-mediated translation in a cell-free system. Here, we show that QC suppresses translation directed by the encephalomyocarditis virus (EMCV) and poliovirus IRESs in a cell-free system and in virus-infected HeLa cells. In contrast, IRESs present in the mammalian p53 transcript that are predicted to have less-complex structures were not sensitive to QC. Inhibition of IRES-mediated translation by QC correlated with the affinity of binding between QC and the particular IRES. Expression of viral capsid proteins, replication of viral RNAs, and production of virus were all strongly inhibited by QC (and 9AA). These results suggest that QC and similar intercalating drugs could potentially be used for treatment of viral infections.
Quinacrine (QC) is an anti-inflammatory drug that has been used for the treatment of malaria and rheumatoid diseases. The mechanism(s) underlying the anti-inflammatory activity of QC remains poorly understood. We recently reported the QC-mediated inhibition of the NF-jB pathway using an in vitro model. To test this potential mechanism in vivo, we used the contact hypersensitivity response (CHS) to chemical allergen sensitization and challenge in mice as a model of skin inflammation. The results indicated that QC treatment inhibited NF-jB activation in the skin during allergen sensitization. This inhibition was reflected by decreased mRNA expression and protein production of the NF-jB-dependent cytokines TNF-a and IL-1b and the chemokine CCL21 in the skin. The decreases in these cytokines resulted in reduced migration of allergen-presenting dendritic cells from the skin into skin-draining lymph nodes and markedly decreased activation of effector CD8 + T cells for the CHS response to allergen challenge (inhibitory concentration 50% or IC 50 was 55 mg/kg). These findings reveal a previously unrecognized mechanism of QC-mediated inhibition of inflammation.
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