Interaction of the human androgen receptor transactivation function with the general transcription factor TFIIF

The human androgen receptor (AR) is a ligand-activated transcription factor that regulates genes important for male sexual differentiation and development. To better understand the role of the receptor as a transcription factor we have studied the mechanism of action of the N-terminal transactivation function. In a protein–protein interaction assay the AR N terminus (amino acids 142–485) selectively bound to the basal transcription factors TFIIF and the TATA-box-binding protein (TBP). Reconstitution of the transactivation activity in vitro revealed that AR142–485 fused to the LexA protein DNA-binding domain was competent to activate a reporter gene in the presence of a competing DNA template lacking LexA binding sites. Furthermore, consistent with direct interaction with basal transcription factors, addition of recombinant TFIIF relieved squelching of basal transcription by AR142–485. Taken together these results suggest that one mechanism of transcriptional activation by the AR involves binding to TFIIF and recruitment of the transcriptional machinery.

Positive regulation of general transcription factor SIII by a tailed ubiquitin homolog.

General transcription factor SIII, a heterotrimer composed of 110-kDa (p110), 18-kDa (p18), and 15-kDa (p15) subunits, increases the catalytic rate of transcribing RNA polymerase II by suppressing transient pausing by polymerase at multiple sites on DNA templates. Here we report molecular cloning and biochemical characterization of the SIII p18 subunit, which is found to be a member of the ubiquitin homology (UbH) gene family and functions as a positive regulatory subunit of SIII. p18 is a 118-amino acid protein composed of an 84-residue N-terminal UbH domain fused to a 34-residue C-terminal tail. Mechanistic studies indicate that p18 activates SIII transcriptional activity above a basal level inherent in the SIII p110 and p15 subunits. Taken together, these findings establish a role for p18 in regulating the activity of the RNA polymerase II elongation complex, and they bring to light a function for a UbH domain protein in transcriptional regulation.

Human general transcription factor TFIIA: characterization of a cDNA encoding the small subunit and requirement for basal and activated transcription.

The human general transcription factor TFIIA is one of several factors involved in specific transcription by RNA polymerase II, possibly by regulating the activity of the TATA-binding subunit (TBP) of TFIID. TFIIA purified from HeLa extracts consists of 35-, 19-, and 12-kDa subunits. Here we describe the isolation of a cDNA clone (hTFIIA gamma) encoding the 12-kDa subunit. Using expression constructs derived from hTFIIA gamma and TFIIA alpha/beta (which encodes a 55-kDa precursor to the alpha and beta subunits of natural TFIIA), we have constructed a synthetic TFIIA with a polypeptide composition similar to that of natural TFIIA. The recombinant complex supports the formation of a DNA-TBP-TFIIA complex and mediates both basal and Gal4-VP16-activated transcription by RNA polymerase II in TFIIA-depleted nuclear extracts. In contrast, TFIIA has no effect on tRNA and 5S RNA transcription by RNA polymerase III in this system. We also present evidence that both the p55 and p12 recombinant subunits interact with TBP and that the basic region of TBP is critical for the TFIIA-dependent function of TBP in nuclear extracts.

An essential component of a C-terminal domain phosphatase that interacts with transcription factor IIF in Saccharomyces cerevisiae

One of the essential components of a phosphatase that specifically dephosphorylates the Saccharomyces cerevisiae RNA polymerase II (RPII) large subunit C-terminal domain (CTD) is a novel polypeptide encoded by an essential gene termed FCP1. The Fcp1 protein is localized to the nucleus, and it binds the largest subunit of the yeast general transcription factor IIF (Tfg1). In vitro, transcription factor IIF stimulates phosphatase activity in the presence of Fcp1 and a second complementing fraction. Two distinct regions of Fcp1 are capable of binding to Tfg1, but the C-terminal Tfg1 binding domain is dispensable for activity in vivo and in vitro. Sequence comparison reveals that residues 173–357 of Fcp1 correspond to an amino acid motif present in proteins of unknown function predicted in many organisms.

A kinase-deficient transcription factor TFIIH is functional in basal and activated transcription.

Phosphorylation of the carboxyl-terminal domain (CTD) of the large subunit of RNA polymerase II has been suggested to be critical for transcription initiation, activation, or elongation. A kinase activity specific for CTD is a component of the general transcription factor TFIIH. Recently, a cyclin-dependent kinase-activator kinase (MO15 and cyclin H) was found to be associated with TFIIH preparations and was suggested to be the CTD kinase. TFIIH preparations containing mutant, kinase-deficient MO15 lack CTD kinase activity, indicating that MO15 is critical for polymerase phosphorylation. Nonetheless, these mutant TFIIH preparations were fully functional (in vitro) in both basal and activated transcription. These results indicate that CTD phosphorylation is not required for transcription with a highly purified system.

Identification of the gene (SSU71/TFG1) encoding the largest subunit of transcription factor TFIIF as a suppressor of a TFIIB mutation in Saccharomyces cerevisiae.

Mutations in the Saccharomyces cerevisiae SSU71 gene were isolated as suppressors of a transcription factor TFIIB defect that confers both a cold-sensitive growth defect and a downstream shift in transcription start-site selection at the cyc1 locus. The ssu71-1 suppressor not only suppresses the conditional phenotype but also restores the normal pattern of transcription initiation at cyc1. In addition, the ssu71-1 suppressor confers a heat-sensitive phenotype that is dependent upon the presence of the defective form of TFIIB. Molecular and genetic analysis of the cloned SSU71 gene demonstrated that SSU71 is a single-copy essential gene encoding a highly charged protein with a molecular mass of 82,194 daltons. Comparison of the deduced Ssu71 amino acid sequence with the protein data banks revealed significant similarity to RAP74, the larger subunit of the human general transcription factor TFIIF. Moreover, Ssu71 is identical to p105, a component of yeast TFIIF. Taken together, these data demonstrate a functional interaction between TFIIB and the large subunit of TFIIF and that this interaction can affect start-site selection in vivo.

The 62- and 80-kDa subunits of transcription factor IIH mediate the interaction with Epstein-Barr virus nuclear protein 2.

EBNA 2 (Epstein-Barr virus nuclear antigen 2) is an acidic transactivator essential for EBV transformation of B lymphocytes. We show that EBNA 2 directly interacts with general transcription factor IIH. Glutathione S-transferase (GST)-EBNA 2 acidic domain fusion protein depleted transcription factor IIH activity from a TFIIH nuclear fraction. The p89 (ERCC3), p80 (ERCC2), and p62 subunits of TFIIH were among the proteins retained by GST-EBNA 2. Eluates from the GST-EBNA 2 beads reconstituted activity in a TFIIH-dependent in vitro transcription assay. The p62 and p80 subunits of TFIIH independently bound to GST-EBNA 2, whereas the p34 subunit of TFIIH only bound in the presence of p62. A Trp-->Thr mutation in the EBNA 2 acidic domain abolishes EBNA 2 transactivation in vivo and greatly compromised EBNA 2 association with TFIIH activity and with the p62 and p80 subunits, providing a link between EBNA 2 transactivation and these interactions. Antibodies directed against the p62 subunit of TFIIH coimmunoprecipitated EBNA 2 from EBV-transformed B lymphocytes, indicating that EBNA 2 associates with TFIIH in vivo.

Mammalian Mat1 subunit of Transcription Factor IIH in gene-specific and general transcription

All protein-encoding genes in eukaryotes are transcribed into messenger RNA (mRNA) by RNA Polymerase II (RNAP II), whose activity therefore needs to be tightly controlled. An important and only partially understood level of regulation is the multiple phosphorylations of RNAP II large subunit C-terminal domain (CTD). Sequential phosphorylations regulate transcription initiation and elongation, and recruit factors involved in co-transcriptional processing of mRNA. Based largely on studies in yeast models and in vitro, the kinase activity responsible for the phosphorylation of the serine-5 (Ser5) residues of RNAP II CTD has been attributed to the Mat1/Cdk7/CycH trimer as part of Transcription Factor IIH. However, due to the lack of good mammalian genetic models, the roles of both RNAP II Ser5 phosphorylation as well as TFIIH kinase in transcription have provided ambiguous results and the in vivo kinase of Ser5 has remained elusive. The primary objective of this study was to elucidate the role of mammalian TFIIH, and specifically the Mat1 subunit in CTD phosphorylation and general RNAP II-mediated transcription. The approach utilized the Cre-LoxP system to conditionally delete murine Mat1 in cardiomyocytes and hepatocytes in vivo and and in cell culture models. The results identify the TFIIH kinase as the major mammalian Ser5 kinase and demonstrate its requirement for general transcription, noted by the use of nascent mRNA labeling. Also a role for Mat1 in regulating general mRNA turnover was identified, providing a possible rationale for earlier negative findings. A secondary objective was to identify potential gene- and tissue-specific roles of Mat1 and the TFIIH kinase through the use of tissue-specific Mat1 deletion. Mat1 was found to be required for the transcriptional function of PGC-1 in cardiomyocytes. Transriptional activation of lipogenic SREBP1 target genes following Mat1 deletion in hepatocytes revealed a repressive role for Mat1apparently mediated via co-repressor DMAP1 and the DNA methyltransferase Dnmt1. Finally, Mat1 and Cdk7 were also identified as a negative regulators of adipocyte differentiation through the inhibitory phosphorylation of Peroxisome proliferator-activated receptor (PPAR) γ. Together, these results demonstrate gene- and tissue-specific roles for the Mat1 subunit of TFIIH and open up new therapeutic possibilities in the treatment of diseases such as type II diabetes, hepatosteatosis and obesity.

Transcription factor occupancy in differentiating skeletal muscle

With recent advances in high-throughput sequencing, mapping of genome-wide transcription factor occupancy has become feasible. To advance the understanding of skeletal muscle differentiation specifically and transcriptional regulation in general, I determined the genome-wide occupancy map for myogenin in differentiating C2C12 myocyte cells. I then analyzed the myogenin map for underlying sequence content and the association between occupied elements and expression trajectories of adjacent genes. Having determined that myogenin primarily associates with expressed genes, I performed a similar analysis on occupancy maps of other transcription factors active during skeletal muscle differentiation, including an extensive analysis of co-occupancy. This analysis provided strong motif evidence for protein-protein interactions as the primary driving force in the formation of Myogenin / Mef2 and MyoD / AP-1 complexes at jointly-occupied sites. Finally, factor occupancy analysis was extended to include bHLH transcription factors in tissues other than skeletal muscle. The cross-tissue analysis led to the emergence of a motif structure used by bHLH TFs to encode either tissue-specific or "general" (public) access in a variety of lineages.

Lineage-specific transcription factor aberrations in AML

Transcription factors play a key role in the commitment of hematopoietic stem cells to differentiate into specific lineages [78]. This is particularly important in that a block in terminal differentiation is the key contributing factor in acute leukemias. This general theme of the role of transcription factors in differentiation may also extend to other tissues, both in terms of normal development and cancer. Consistent with the role of transcription factors in hematopoietic lineage commitment is the frequent finding of aberrations in transcription factors in AML patients. Here, we intend to review recent findings on aberrations in lineage-restricted transcription factors as observed in patients with acute myeloid leukemia (AML).

Angiotensin Ii As A General Growth Factor

Angiotensin II (Ang II), a key protein in the renin-angiotensin system, can induce cardiac hypertrophy through an intracrine system as well as affect gene transcription. The receptor to Ang II responsible for this effect, AT1, has been localized to the nucleus of cell types in addition to cardiomyocytes. In this study, we induced expression of Ang II in MC3T3 osteoblasts and K7M2 osteosarcomas and measured changes in protein expression of Annexin V and matrix metalloproteinase 2 (MMP2), proteins identified previously through mass spectrometry analysis as being regulated by Ang II. Annexin V is downregulated in both immortalized murine bone (MC3T3) cells and in cancerous immortalized murine (K7M2) cells induced to express Ang II. MC3T3 cells which express Ang II show a downregulation of MMP2 expression, but Ang II-expressing K7M2 cells show an upregulation of MMP2. The differential regulation of MMP2 between the cancerous cells and noncancerous cells implicates a role for Ang in in tumor metastasis, as MMP2 is a metastatic protein. Annexin V is used as a marker for apoptosis, but nothing is known of the function of the endogenous protein. That Annexin V is potentially regulated by Ang II provides more information with which to characterize the protein and could suggest a function for Annexin V as part of a signal transduction pathway inside of the cell.

Functional characterization of transcription factor USF

USF, Upstream Stimulatory Factor, is a family of ubiquitous transcription factors that contain highly conserved basic helix-loop-helix leucine zipper DNA binding domains and recognize the core DNA sequence CACGTG. In human and mouse, two members of the USF family, USF1 and USF2, encoded by two different genes, contribute to the USF activity. In order to gain insights into the mechanisms by which USFs function as transcriptional activators, different approaches were used to map the domains of USF2 responsible for nuclear localization and transcriptional activation. Two stretches of amino acids, one in the basic region of the DNA binding domain, the other in a highly conserved N-terminal region, were found to direct nuclear localization independently of one another. Two distinct activation domains were also identified. The first one, located in the conserved N-terminal region that overlaps the C-terminal nuclear localization signal, functioned only in the presence of an initiator element in the promoter of the reporter. The second, in a nonconserved region, activated transcription in the absence of an initiator element or when fused to a heterologous DNA binding domain. These results suggest that USF2 functions in different promoter contexts by selectively utilizing different activation domains.^ The deletion analysis of USF2 also identified two dominant negative mutants of USF, one lacking the activation domain, the other lacking the basic domain. The latter proved useful for testing the direct involvement of USFs in the transcriptional activation mediated by the viral protein IE62.^ To investigate the biological function of USFs, foci and colony formation assays were used to study the growth regulation by USFs. It was found that USFs had a strong antagonistic effect on cellular transformation mediated by the bHLH/LZ protein Myc. This effect required the DNA binding activity of either USF 1 or USF2. Moreover, USF2, but not USF1 or other mutants of USFs, was also found to have strong inhibitory effect on the cellular transformation by E1a and on the growth of HeLa cells. These results demonstrate that USFs could potentially regulate growth through two mechanisms, one by antagonizing the function of Myc in cellular transformation, the other by mediating a more general growth inhibitory effect. ^

HLH106, a Drosophila transcription factor with similarity to the vertebrate sterol responsive element binding protein.

We cloned a Drosophila homolog to the sterol responsive element binding proteins (SREBPs). In vertebrates, the SREBPs are regulated by a mechanism that involves cleavage of the protein that normally residues in the cellular membranes and translocation of the released transcription factor into the nucleus. Regulation of the Drosophila factor HLH106 apparently follows the same mechanism, and we find the full-length gene product in the membrane fraction and a shorter cross-reacting form in the nuclear fraction. This nuclear form, which may correspond to proteolytically activated HLH106, is abundant in the blood cell line mbn-2. The general domain structure of HLH106 is very similar to that in SREBP. HLH106 is expressed throughout development, and it is present at high levels in Drosophila cell lines. In contrast to the rat homolog, HLH106 transcripts are not more abundant in adipose tissue than in other tissues.

Core promoter-specific function of a mutant transcription factor TFIID defective in TATA-box binding.

In conjunction with other general initiation factors, the TATA box-binding protein (TBP) can direct basal transcription by RNA polymerase II from TATA-containing promoters, but its stable interaction with TBP-associated factors (TAFs) in the TFIID complex is required both for activator-dependent transcription and for basal transcription directed by an initiator element. We have generated a TATA-binding-defective TFIID complex containing an amino acid substitution in the DNA-binding surface of its TBP subunit. This mutated TFIID is defective in both basal and activated transcription from core promoters containing only a TATA box but supports transcription from initiator-containing promoters independently of the presence or absence of a TATA sequence. Our results show that a functional initiator element is needed to bypass the requirement for an active TATA DNA-binding surface in TFIID and imply that gene-specific transcription can be achieved by modulating distinct core promoter-specific TFIID functions--e.g., TBP-TATA versus TAF-initiator interactions.

Evolutionary conservation of human TATA-binding-polypeptide-associated factors TAFII31 and TAFII80 and interactions of TAFII80 with other TAFs and with general transcription factors.

Human transcription initiation factor TFIID is composed of the TATA-binding polypeptide (TBP) and at least 13 TBP-associated factors (TAFs) that collectively or individually are involved in activator-dependent transcription. To investigate protein-protein interactions involved in TFIID assembly and in TAF-mediated activator functions, we have cloned and expressed cDNAs encoding human TAFII80 and TAFII31. Coimmunoprecipitation assays showed that TAFII80 interacted with TAFII250, TAFII31, TAFII20, and TBP, but not with TAFII55. Similar assays showed that TAFII80 interacted with TFIIE alpha and with TFIIF alpha (RAP74) but not with TFIIB, TFIIE beta, or TFIIF beta (RAP30). Further studies with TAFII80 mutations revealed three distinct interaction domains which fall within regions conserved in human TAFII80, Drosophila TAFII60, and yeast TAFII60. The N terminus of TAFII80 (residues 1-100) interacts with both TAFII31 and TAFII20, while two C-terminal regions are involved, respectively, in interactions with TAFII250 and TFIIF alpha (RAP74) (residues 203-276) and with TBP and TFIIE alpha (residues 377-505). The interactions between TAFII80 and general factors TFIIE alpha and TFIIF alpha (RAP74) could be important for recruitment of GTFs during activator-dependent transcription. Because TAFs 80, 31, and 20 show sequence similarities to histones H4, H3, and H2B, as well as some parallel interactions, this subset of TAFs may form a related core structure within TFIID.