The positive transcription elongation factor b (P-TEFb) plays a pivotal role in productive elongation of nascent RNA molecules by RNA polymerase II. Core active P-TEFb is composed of CDK9 and cyclin T. In addition, mammalian cell extracts contain an inactive P-TEFb complex composed of four components, CDK9, cyclin T, the 7SK snRNA and the MAQ1/HEXIM1 protein. We now report an in vitro reconstitution of 7SK-dependent HEXIM1 association to purified P-TEFb and subsequent CDK9 inhibition. Yeast three-hybrid tests and gel-shift assays indicated that HEXIM1 binds 7SK snRNA directly and a 7SK snRNArecognition motif was identified in the central part of HEXIM1 (amino acids (aa) 152-155). Data from yeast two-hybrid and pull-down assay on GST fusion proteins converge to a direct binding of P-TEFb to the HEXIM1 C-terminal domain (aa 181-359). Consistently, point mutations in an evolutionarily conserved motif (aa 202-205) were found to suppress P-TEFb binding and inhibition without affecting 7SK recognition. We propose that the RNA-binding domain of HEXIM1 mediates its association with 7SK and that P-TEFb then enters the complex through association with HEXIM1.
Analysis of the Large Inactive P-TEFb Complex Indicates That It Contains One 7SK Molecule, a Dimer of HEXIM1 or HEXIM2, and Two P-TEFb Molecules Containing Cdk9 Phosphorylated at Threonine 186
Cyclin-dependent kinases (Cdks) 1 are key regulators of a variety of cellular processes, such as cell cycle progression, transcription, and neuronal differentiation. The kinase activity of Cdks in turn is tightly regulated. Association with a cyclin partner and phosphorylation of the T-loop is needed for activation of Cdks. They are also subject to negative regulation via phosphorylation or through interaction with a family of Cdk inhibitory proteins (1-4).P-TEFb plays a key role in RNA polymerase II elongation control (5-7). It is comprised of one of two isoforms of Cdk9 (8, 9) and one of three cyclins, T1, T2 (10), or K (11) in human. One of the major targets of the kinase activity of P-TEFb is the carboxyl-terminal domain of the largest subunit of RNA polymerase II (12), and this phosphorylation of the carboxyl-terminal domain by P-TEFb occurs during transcription elongation (13). P-TEFb controls gene expression by regulating the fraction of RNA polymerase II molecules that generate full-length mRNAs (6). In addition to its normal cellular role, P-TEFb has been shown to be recruited by the viral transactivator Tat to the promoter to enhance viral transcription, which is required for efficient HIV-1 replication (8, 14 -18). P-TEFb is uniquely regulated by the reversible association of a small nuclear RNA, 7SK (19,20),. Glycerol gradient analyses of cell lysates indicate that two forms of P-TEFb exist in the cell: a large inactive form containing 7SK and HEXIM proteins, and a smaller active form comprised of just P-TEFb subunits (9,19,21,23,24). When cells are treated with P-TEFb inhibitors, such as 5,6-dichloro-1--Dribofuranosylbenzimidazole, or other agents that block transcription elongation, the large form is converted into the small active form (21). This form of P-TEFb regulation is physiologically significant, because it has been shown that all signals that trigger cardiac hypertrophy converge at the critical step of activating P-TEFb through dissociation of 7SK and HEXIM. This activation causes increased cellular transcription, and an increase in the size of cardiomyocytes (25)(26)(27). Several studies have uncovered some of the important interactions in the 7SK⅐HEXIM1⅐P-TEFb complex. Two regions of HEXIM1 have been characterized. The region centered upon KHRR (amino acids 152-155) is involved in binding of 7SK, and contains nuclear localization signals (21,28,29). A second region centered upon PYNT (amino acids 202-205) is involved in interaction with P-TEFb (23, 29). In addition, regions involved in interactions have been narrowed down to amino acids 1-254 of 726 of cyclin T1, all of Cdk9, and nucleotide 1-175 of 7SK (19,21,22). Furthermore, phosphorylation of the T-loop of Cdk9 has been implicated in activation of P-TEFb, and is required for the formation of the 7SK⅐HEXIM1⅐P-TEFb complex (30).In this report, we analyzed the stoichiometry of the 7SK⅐HEXIM1⅐P-TEFb complex. We identified residues critical for inhibition of the kinase activity of P-TEFb, and formation of the 7SK⅐HEXIM1⅐P-TEFb complex....
Basal transcription of the HIV LTR is highly repressed and requires Tat to recruit the positive transcription elongation factor, P-TEFb, which functions to promote the transition of RNA polymerase II from abortive to productive elongation. P-TEFb is found in two forms in cells, a free, active form and a large, inactive complex that also contains 7SK RNA and HEXIM1 or HEXIM2. Here we show that HIV infection of cells led to the release of P-TEFb from the large form. Consistent with Tat being the cause of this effect, transfection of a FLAG-tagged Tat in 293T cells caused a dramatic shift of P-TEFb out of the large form to a smaller form containing Tat. In vitro, Tat competed with HEXIM1 for binding to 7SK, blocked the formation of the P-TEFb–HEXIM1–7SK complex, and caused the release P-TEFb from a pre-formed P-TEFb–HEXIM1–7SK complex. These findings indicate that Tat can acquire P-TEFb from the large form. In addition, we found that HEXIM1 binds tightly to the HIV 5′ UTR containing TAR and recruits and inhibits P-TEFb activity. This suggests that in the absence of Tat, HEXIM1 may bind to TAR and repress transcription elongation of the HIV LTR.
The kinase activity of positive transcription elongation factor b (P-TEFb), composed of cyclin-dependent kinase 9 and cyclin T1 or T2, is required for the transition of RNA polymerase II into productive elongation. P-TEFb activity has been shown to be negatively regulated by association with the small nuclear RNA 7SK and the HEXIM1 protein. Here, we characterize HEXIM2, a previously predicted protein with sequence similarity to HEXIM1. HEXIM2 is expressed in HeLa and Jurkat cells, and glycerol gradient analysis and immunoprecipitations indicate that HEXIM2, like HEXIM1, has a regulated association with P-TEFb. As HEXIM1 is knocked down, HEXIM2 functionally compensates for its association with P-TEFb. Electrophoretic mobility shift assays and in vitro kinase assays demonstrate that HEXIM2 forms complexes containing 7SK and P-TEFb and, in conjunction with 7SK, inhibits P-TEFb kinase activity. Our results provide strong evidence that HEXIM2 is a regulator of P-TEFb function. Furthermore, our results support the idea that the utilization of HEXIM1 or HEXIM2 to bind and inhibit P-TEFb can be differentially regulated in vivo.Transcription by RNA polymerase II is a highly regulated process, influenced by many factors and a cycle of RNA polymerase II phosphorylation (1, 2). The default state of RNA polymerase II transcription is abortive, with RNA polymerase II falling under the influence of negative factors such as DRB 1 sensitivity-inducing factor (DSIF), and negative elongation factor (NELF), resulting in the production of short transcripts (3-5). The transition to the productive elongation of full-length transcripts requires positive transcription elongation factor b (P-TEFb) (6, 7), which phosphorylates serine 2 residues in the heptad repeats of the carboxyl-terminal domain of the largest subunit of RNA polymerase II (7,8). P-TEFb is required for the proper expression of RNA polymerase II genes. The knockdown of cyclin-dependent kinase 9 or both of the cyclin Ts in Caenorhabditis elegans reduces the expression of early embryonic genes and the level of serine 2 phosphorylation of the carboxylterminal domain and leads to the death of the embryo at an early stage (9). Inhibition of P-TEFb kinase activity through treatment with flavopiridol blocks the transcription of RNA polymerase II genes in HeLa cells (10, 11), with complete inhibition causing apoptosis. P-TEFb activity can be targeted to specific genes through association with activators, such as human immunodeficiency virus-1 Tat (12, 13), CIITA (14), nuclear factor-B (15), and Myc (16, 17).There are two distinct P-TEFb complexes, which differ in size, composition, and activity (18, 19). The originally identified, smaller P-TEFb complex has kinase activity (7) and is composed of Cdk9 42 or Cdk9 55 (20) and a cyclin partner T1, T2, or K (21, 22). A large P-TEFb complex with reduced kinase activity was found to contain the small nuclear RNA 7SK (18, 19) and HEXIM1 (23,24), in addition to P-TEFb subunits. Independently, HEXIM1 and 7SK have limited inhibitory effect...
Interplay between 7SK snRNA and oppositely charged regions in HEXIM1 direct the inhibition of P-TEFb
Transcription elongation of eukaryotic genes by RNA polymerase II depends on the positive transcription elongation factor b (P-TEFb). When sequestered into the large complex, P-TEFb kinase activity is inhibited by the coordinate actions of 7SK small nuclear RNA (7SK snRNA) and hexamethylene bisacetamide (HMBA)-induced protein 1 (HEXIM1). We found that the basic region in HEXIM1 directs its nuclear import via two monopartite and two bipartite nuclear localization sequences. Moreover, the arginine-rich motif within it is essential for its binding to 7SK snRNA, P-TEFb, and inhibition of transcription. Notably, the basic region interacts with the adjacent acidic regions in the absence of RNA. The removal of the positive or negative charges from these regions in HEXIM1 leads to its sequestration into the large complex and inhibition of transcription independently of the arginine-rich motif. Finally, the removal of the negative charges from HEXIM1 results in its subnuclear localization into nuclear speckles. We propose a model where the interplay between 7SK snRNA and oppositely charged regions in HEXIM1 direct its binding to P-TEFb and subcellular localization that culminates in the inhibition of transcription.
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