Clustering phenotype populations by genome-wide RNAi and multiparametric imaging

How to predict gene function from phenotypic cues is a longstanding question in biology.Using quantitative multiparametric imaging, RNAi-mediated cell phenotypes were measured on a genome-wide scale.On the basis of phenotypic ‘neighbourhoods', we identified previously uncharacterized human genes as mediators of the DNA damage response pathway and the maintenance of genomic integrity.The phenotypic map is provided as an online resource at http://www.cellmorph.org for discovering further functional relationships for a broad spectrum of biological modul

SIRT1 Regulates HIV Transcription via Tat Deacetylation

The human immunodeficiency virus (HIV) Tat protein is acetylated by the transcriptional coactivator p300, a necessary step in Tat-mediated transactivation. We report here that Tat is deacetylated by human sirtuin 1 (SIRT1), a nicotinamide adenine dinucleotide-dependent class III protein deacetylase in vitro and in vivo. Tat and SIRT1 coimmunoprecipitate and synergistically activate the HIV promoter. Conversely, knockdown of SIRT1 via small interfering RNAs or treatment with a novel small molecule inhibitor of the SIRT1 deacetylase activity inhibit Tat-mediated transactivation of the HIV long terminal repeat. Tat transactivation is defective in SIRT1-null mouse embryonic fibroblasts and can be rescued by expression of SIRT1. These results support a model in which cycles of Tat acetylation and deacetylation regulate HIV transcription. SIRT1 recycles Tat to its unacetylated form and acts as a transcriptional coactivator during Tat transactivation

Recruitment and Activation of RSK2 by HIV-1 Tat

The transcriptional activity of the integrated HIV provirus is dependent on the chromatin organization of the viral promoter and the transactivator Tat. Tat recruits the cellular pTEFb complex and interacts with several chromatin-modifying enzymes, including the histone acetyltransferases p300 and PCAF. Here, we examined the interaction of Tat with activation-dependent histone kinases, including the p90 ribosomal S6 kinase 2 (RSK2). Dominant-negative RSK2 and treatment with a small-molecule inhibitor of RSK2 kinase activity inhibited the transcriptional activity of Tat, indicating that RSK2 is important for Tat function. Reconstitution of RSK2 in cells from subjects with a genetic defect in RSK2 expression (Coffin-Lowry syndrome) enhanced Tat transactivation. Tat interacted with RSK2 and activated RSK2 kinase activity in cells. Both properties were lost in a mutant Tat protein (F38A) that is deficient in HIV transactivation. Our data identify a novel reciprocal regulation of Tat and RSK2 function, which might serve to induce early changes in the chromatin organization of the HIV LTR

Transcriptional synergy between Tat and PCAF is dependent on the binding of acetylated Tat to the PCAF bromodomain

The human immunodeficiency virus (HIV) Tat protein plays an essential role in promoting efficient transcriptional elongation of viral transcripts. We report that the transcriptional co-activator PCAF and Tat interact and synergize to activate the HIV promoter. The binding of Tat and PCAF in vitro and in vivo is dependent on the acetylated state of Lys50 of Tat and on the PCAF bromodomain. Structural analysis of the acetylated Tat peptide bound to the PCAF bromodomain defined amino acids Y47 and R53 in Tat and V763, Y802, and Y809 in PCAF as critical interaction points between the two proteins. Mutation of each of these residues in either Tat or PCAF inhibited in a cumulative manner the Tat–PCAF interaction in vitro and in vivo, and abrogated the synergistic activation of the HIV promoter by both proteins. These observations demonstrate that acetylation of Tat establishes a novel protein–protein interaction domain at the surface of Tat that is necessary for the transcriptional activation of the HIV promoter

Acetylation of cyclin T1 regulates the equilibrium between active and inactive P-TEFb in cells

The elongation competence of the RNA polymerase II complex is critically dependent on the positive transcription elongation factor b (P-TEFb). P-TEFb exists in two forms in cells, an active form composed of cyclin T1 and CDK9 and an inactive form, in which cyclin T1/CDK9 is sequestered by Hexim1 and 7SK snRNA. Here, we report that partitioning of active and inactive P-TEFb is regulated by acetylation of cyclin T1. Cyclin T1 acetylation triggers dissociation of Hexim1 and 7SK snRNA from cyclin T1/CDK9 and activates the transcriptional activity of P-TEFb. This activation is lost in P-TEFb complexes containing cyclin T1 that can no longer be acetylated. An acetylation-deficient cyclin T1 mutant dominantly suppresses NF-κB-mediated activation of the interleukin-8 promoter but continues to synergize normally with the HIV Tat protein to transactivate the HIV long terminal repeat. These findings support the model that acetylation of cyclin T1 serves as a physiological switch that liberates P-TEFb from its endogenous inhibitors Hexim1 and 7SK snRNA, but is not required for the cooperative action with HIV Tat

Superinduction of Tat activity in CLS fibroblasts.

<p>(A) Western blot analysis of cellular extracts of fibroblasts from a patient with CLS and control human fibroblasts. (B) Nuclear microinjection of CLS fibroblasts with synthetic Tat (amino acids 1–72), the HIV LTR luciferase reporter, a CMV-GFP expression plasmid, and either the empty vector, an RSK2 expression construct, or a plasmid expressing kinase-deficient RSK2. Values are means±SEM of five experiments. (C) Coinjection of the 5xUAS luciferase reporter, a plasmid expressing the Gal4-VP16 transactivator and CMV-GFP with either the RSK2-expressing plasmid or the vector alone. Values are means±SEM of three experiments.</p

Role of histone kinases in Tat transactivation.

<p>(A) Chromatin immunoprecipitation analysis of Jurkat T cells containing an integrated HIV promoter in the absence or presence of Tat. Immunoprecipitations were performed with α-phospho-histone H3 antibodies (serine 10) followed by radioactive PCR with primers specific for the HIV LTR, the c-fos, or the β-globin genes. (B) Jurkat 1G5 cells containing an integrated HIV LTR luciferase construct were transiently transfected with Tat/FLAG (25 ng) and kinase-deficient (KD) kinase expression vectors (200 ng). (C) Western blot analysis of cellular lysates from 293 cells cotransfected with the indicated expression plasmids. (D) Transfection of CMV luciferase (25 ng) with the KD RSK2 expression plasmid (200 ng) in Jurkat cells. (E) Transfection of 5xUAS luciferase and Gal4-CDK9 (20 ng) with the KD RSK2 expression plasmid (200 ng) in Jurkat cells. Values are means±SEM of three experiments.</p

Activation of RSK2 by Tat.

<p>(A) Autoradiography of radioactive <i>in vitro</i> synthesized RSK2 proteins before (Input) and after binding to biotinylated synthetic Tat (amino acids 1–72) or to beads alone. Increasing amounts of <i>in vitro</i> translated RSK2 were included in the binding reaction. (B) Kinase assay of endogenous RSK2 immunoprecipitated from Cos7 cells transfected with wild type Tat/FLAG, TatF38A/FLAG, or empty vector. Values are means±SEM of four experiments. (C) Western blotting of nuclear extracts isolated from Cos7 cells cotransfected with RSK2/HA and Tat/FLAG or with RSK2/HA and Tat F38A/FLAG constructs. Densitometric quantification of the phospho-S227-specific bands was performed using the NIH Image software. (D) Chromatin immunoprecipitation analysis of the Jurkat T cell line A2, latently infected with an HIV-based lentiviral vector expressing Tat/FLAG from the HIV LTR after treatment with TNF-α. At indicated time points, cells were harvested and immunoprecipitations were performed in duplicate with α-phospho-S227 antibodies followed by PCR with primers specific for the HIV LTR or the c-fos gene.</p