Browsing by Author "Stark, George R."

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    CDK8/19 Mediator kinases potentiate induction of transcription by NFκB
    (National Academy of Sciences, 2017-09-19) Chen, Mengqian; Liang, Jiaxin; Ji, Hao; Yang, Zhengguan; Altilia, Serena; Hu, Bing; Schronce, Adam; McDermott, Martina S. J.; Schools, Gary P.; Lim, Chang-uk; Oliver, David; Shtutman, Michael S.; Lu, Tao; Stark, George R.; Porter, Donald C.; Broude, Eugenia V.; Roninson, Igor B.; Pharmacology and Toxicology, School of Medicine
    Nuclear factor-κB (NFκB) transcription factors have been implicated in several major diseases, including inflammatory disorders, viral infections, and cancer. NFκB-inhibiting drugs typically have side effects, possibly due to sustained NFκB suppression. The ability to affect induced, but not basal, NFκB activity could provide therapeutic benefit without associated toxicity. We report that the transcription-regulating kinases CDK8/19 potentiate NFκB activity, including the expression of tumor-promoting proinflammatory cytokines, by enabling the completion of NFκB-initiated transcription. CDK8/19 inhibitors suppress the induction of gene expression by NFκB or other transcription factors, but generally do not affect basal expression of the same genes. The role of CDK8/19 in newly induced transcription identifies these kinases as mediators of transcriptional reprogramming, a key aspect of development, differentiation, and pathological processes., The nuclear factor-κB (NFκB) family of transcription factors has been implicated in inflammatory disorders, viral infections, and cancer. Most of the drugs that inhibit NFκB show significant side effects, possibly due to sustained NFκB suppression. Drugs affecting induced, but not basal, NFκB activity may have the potential to provide therapeutic benefit without associated toxicity. NFκB activation by stress-inducible cell cycle inhibitor p21 was shown to be mediated by a p21-stimulated transcription-regulating kinase CDK8. CDK8 and its paralog CDK19, associated with the transcriptional Mediator complex, act as coregulators of several transcription factors implicated in cancer; CDK8/19 inhibitors are entering clinical development. Here we show that CDK8/19 inhibition by different small-molecule kinase inhibitors or shRNAs suppresses the elongation of NFκB-induced transcription when such transcription is activated by p21-independent canonical inducers, such as TNFα. On NFκB activation, CDK8/19 are corecruited with NFκB to the promoters of the responsive genes. Inhibition of CDK8/19 kinase activity suppresses the RNA polymerase II C-terminal domain phosphorylation required for transcriptional elongation, in a gene-specific manner. Genes coregulated by CDK8/19 and NFκB include IL8, CXCL1, and CXCL2, which encode tumor-promoting proinflammatory cytokines. Although it suppressed newly induced NFκB-driven transcription, CDK8/19 inhibition in most cases had no effect on the basal expression of NFκB-regulated genes or promoters; the same selective regulation of newly induced transcription was observed with other transcription signals potentiated by CDK8/19. This selective role of CDK8/19 identifies these kinases as mediators of transcriptional reprogramming, a key aspect of development and differentiation as well as pathological processes.
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    NF-κB: Regulation by Methylation
    (American Association for Cancer Research, 2015-09-15) Lu, Tao; Stark, George R.; Department of Pharmacology and Toxicology, IU School of Medicine
    In normal cells exposed to stress, the central transcription factor NF-κB is activated only transiently, to modulate the activation of downstream immune responses. However, in most cancers, NF-κB is abnormally activated constitutively, contributing thus to oncogenesis and tumor progression. Therefore, downregulating NF-κB activity is an important goal of cancer treatment. In order to control NF-κB activity therapeutically, it is helpful to understand the molecular mechanisms that normally govern its activation and how dysregulated NF-κB activity may aid the development of disease. Recent evidence from our laboratories and others indicates that, in addition to various posttranslational modifications of NF-κB that have been observed previously, including phosphorylation, ubiquitination, and acetylation, NF-κB can be methylated reversibly on lysine or arginine residues by histone-modifying enzymes, including lysine and arginine methyl transferases and demethylases. Furthermore, these methylations are required to activate many downstream genes. Interestingly, amplifications and mutations of several such enzymes have been linked to cancer. We propose that some of these mutations may alter the methylation not only of histones but also of NF-κB, making them attractive therapeutic targets.