Abstract
CDK9 is the catalytic subunit of positive elongation factor b (P-TEFb) that controls the transition of RNA polymerase II (RNAPII) into elongation. CDK9 inhibitors block mRNA synthesis and trigger activation of the stress-sensitive p53 protein. This in turn induces transcription of CDKN1A (p21) and other cell cycle control genes. It is presently unclear if and how p53 circumvents a general P-TEFb-requirement when it activates its target genes. Our investigations using a panel of specific inhibitors reason for a critical role of CDK9 also in the case of direct inhibition of the kinase. At the prototypic p21 gene, the activator p53 initially accumulates at the pre-bound upstream enhancer followed—with significant delay—by de novo binding to a secondary enhancer site within the first intron of p21. This is accompanied by recruitment of the RNAPII initiation machinery to both elements. ChIP and functional analyses reason for a prominent role of CDK9 itself and elongation factor complexes PAF1c and SEC involved in pause and elongation control. It appears that the strong activation potential of p53 facilitates gene activation in the situation of global repression of RNAPII transcription. The data further underline the fundamental importance of CDK9 for class II gene transcription.
Highlights
The tumor suppressor protein p53 becomes activated and stabilized upon cellular stress and various types of genotoxic insult
We further assumed that activation of p53 by ATM/ATR kinase family members follows CDK9 inhibition with a certain delay because the former sense the impaired pause release of RNA polymerase II (RNAPII) induced by inhibition of the latter [22]
To clarify this issue mRNA synthesis was kinetically dissected at p53 target genes following the addition of CDK9 inhibitors
Summary
The tumor suppressor protein p53 becomes activated and stabilized upon cellular stress and various types of genotoxic insult. The p53 response is tightly controlled and fine-tuned at multiple levels, for example by stimulus-specific posttranslational modifications of p53 that affect its stability and/or its interactions with other proteins and DNA. P53 acts primarily as transcriptional activator that binds as tetramer to cis-regulatory regions of genes involved in cell cycle arrest, senescence, DNA repair or apoptosis [1]. The initial characterization of a p53-specific response element (RE) dates back to the early 1990s [2,3]. PLOS ONE | DOI:10.1371/journal.pone.0146648 January 8, 2016
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