Marjorie Brand

Function of TAF II -containing complex without TBP in transcription by RNA polymerase II

Initiation of transcription of a gene from a core promoter region by RNA polymerase II requires the assembly of several initiation factors to form a preinitiation complex. Assembly of this complex, is thought to be nucleated exclusively by the sequence-specific binding of the TFIID transcription factor complex, which is composed of the TATA-binding protein (TBP) and TBP-associated factors (TAFIIs) (refs 3, 4), to the different promoters. Here we isolate and characterize a new multiprotein complex that does not contain either TBP or a TBP-like factor but is composed of several TAFIIs and other proteins. This complex can replace TFIID on both TATA-containing and TATA-lacking promoters in in vitro transcription assays. Moreover, an anti-TBP antibody that inhibits TBP- and TFIID-dependent transcription does not inhibit activity of this new complex. These results indicate that TBP-free RNA polymerase II mediated transcription may be able to occur in mammalian cells and that multiple preinitiation complexes may play an important role in regulating gene expression.

Identification of TATA-binding Protein-free TAFII-containing Complex Subunits Suggests a Role in Nucleosome Acetylation and Signal Transduction

Recently we identified a novel human (h) multiprotein complex, called TATA-binding protein (TBP)-free TAFII-containing complex (TFTC), which is able to nucleate RNA polymerase II transcription and can mediate transcriptional activation. Here we demonstrate that TFTC, similar to other TBP-free TAFII complexes (yeast SAGA, hSTAGA, and hPCAF) contains the acetyltransferase hGCN5 and is able to acetylate histones in both a free and a nucleosomal context. The recently described TRRAP cofactor for oncogenic transcription factor pathways was also characterized as a TFTC subunit. Furthermore, we identified four other previously uncharacterized subunits of TFTC: hADA3, hTAFII150, hSPT3, and hPAF65β. Thus, the polypeptide composition of TFTC suggests that TFTC is recruited to chromatin templates by activators to acetylate histones and thus may potentiate initiation and activation of transcription.

UV‐damaged DNA‐binding protein in the TFTC complex links DNA damage recognition to nucleosome acetylation

Initiation of transcription of protein‐encoding genes by RNA polymerase II (Pol II) was thought to require transcription factor TFIID, a complex comprised of the TATA box‐binding protein (TBP) and TBP‐associated factors (TAFIIs). In the presence of TBP‐free TAFII complex (TFTC), initiation of Pol II transcription can occur in the absence of TFIID. TFTC containing the GCN5 acetyltransferase acetylates histone H3 in a nucleosomal context. We have identified a 130 kDa subunit of TFTC (SAP130) that shares homology with the large subunit of UV‐damaged DNA‐binding factor. TFTC preferentially binds UV‐irradiated DNA, UV‐damaged DNA inhibits TFTC‐mediated Pol II transcription and TFTC is recruited in parallel with the nucleotide excision repair protein XP‐A to UV‐damaged DNA. TFTC preferentially acetylates histone H3 in nucleosomes assembled on UV‐damaged DNA. In agreement with this, strong histone H3 acetylation occurs in intact cells after UV irradiation. These results suggest that the access of DNA repair machinery to lesions within chromatin may be facilitated by TFTC via covalent modification of chromatin. Thus, our experiments reveal a molecular link between DNA damage recognition and chromatin modification.

The TFIID components human TAF(II)140 and Drosophila BIP2 (TAF(II)155) are novel metazoan homologues of yeast TAF(II)47 containing a histone fold and a PHD finger.

ABSTRACT The RNA polymerase II transcription factor TFIID comprises the TATA binding protein (TBP) and a set of TBP-associated factors (TAFIIs). TFIID has been extensively characterized for yeast, Drosophila, and humans, demonstrating a high degree of conservation of both the amino acid sequences of the constituent TAFIIs and overall molecular organization. In recent years, it has been assumed that all the metazoan TAFIIs have been identified, yet no metazoan homologues of yeast TAFII47 (yTAFII47) and yTAFII65 are known. Both of these yTAFIIs contain a histone fold domain (HFD) which selectively heterodimerizes with that of yTAFII25. We have cloned a novel mouse protein, TAFII140, containing an HFD and a plant homeodomain (PHD) finger, which we demonstrated by immunoprecipitation to be a mammalian TFIID component. TAFII140 shows extensive sequence similarity toDrosophila BIP2 (dBIP2) (dTAFII155), which we also show to be a component of DrosophilaTFIID. These proteins are metazoan homologues of yTAFII47 as their HFDs selectively heterodimerize with dTAFII24 and human TAFII30, metazoan homologues of yTAFII25. We further show that yTAFII65 shares two domains with theDrosophila Prodos protein, a recently described potential dTAFII. These conserved domains are critical for yTAFII65 function in vivo. Our results therefore identify metazoan homologues of yTAFII47 and yTAFII65.

TATA-binding Protein-free TAF-containing Complex (TFTC) and p300 Are Both Required for Efficient Transcriptional Activation*

Initiation of transcription of protein-encoding genes by RNA polymerase II was thought to require transcription factor TFIID, a complex comprising the TATA-binding protein (TBP) and TBP-associated factors (TAFs). In the presence of TBP-free TAF complex (TFTC), initiation of polymerase II transcription can occur in the absence of TFIID. TFTC contains several subunits that have been shown to play the role of transcriptional coactivators, including the GCN5 histone acetyltransferase (HAT), which acetylates histone H3 in a nucleosomal context. Here we analyze the coactivator function of TFTC. We show direct physical interactions between TFTC and the two distinct activation regions (H1 and H2) of the VP16 activation domain, whereas the HAT-containing coactivators, p300/CBP (CREB-binding protein), interact only with the H2 subdomain of VP16. Accordingly, cell transfection experiments demonstrate the requirement of both p300 and TFTC for maximal transcriptional activation by GAL-VP16. In agreement with this finding, we show that in vitro on a chromatinized template human TFTC mediates the transcriptional activity of the VP16 activation domain in concert with p300 and in an acetyl-CoA-dependent manner. Thus, our results suggest that these two HAT-containing co-activators, p300 and TFTC, have complementary rather than redundant roles during the transcriptional activation process.

UTX demethylase activity is required for satellite cell–mediated muscle regeneration

The X chromosome-encoded histone demethylase UTX (also known as KDM6A) mediates removal of repressive trimethylation of histone H3 lysine 27 (H3K27me3) to establish transcriptionally permissive chromatin. Loss of UTX in female mice is embryonic lethal. Unexpectedly, male UTX-null mice escape embryonic lethality due to expression of UTY, a paralog that lacks H3K27 demethylase activity, suggesting an enzyme-independent role for UTX in development and thereby challenging the need for active H3K27 demethylation in vivo. However, the requirement for active H3K27 demethylation in stem cell-mediated tissue regeneration remains untested. Here, we employed an inducible mouse KO that specifically ablates Utx in satellite cells (SCs) and demonstrated that active H3K27 demethylation is necessary for muscle regeneration. Loss of UTX in SCs blocked myofiber regeneration in both male and female mice. Furthermore, we demonstrated that UTX mediates muscle regeneration through its H3K27 demethylase activity, as loss of demethylase activity either by chemical inhibition or knock-in of demethylase-dead UTX resulted in defective muscle repair. Mechanistically, dissection of the muscle regenerative process revealed that the demethylase activity of UTX is required for expression of the transcription factor myogenin, which in turn drives differentiation of muscle progenitors. Thus, we have identified a critical role for the enzymatic activity of UTX in activating muscle-specific gene expression during myofiber regeneration and have revealed a physiological role for active H3K27 demethylation in vivo.

Splicing of Ezh1 gets muscle out of stressful situations

As cells undergo terminal differentiation, the composition of Polycomb-repressive complex 2 (PRC2) changes and the histone H3K27 methyltransferase Ezh2 is progressively replaced by its homolog Ezh1. By identifying an enzymatically inactive splice variant of Ezh1 that is sensitive to cellular stress, Bodega et al. now demonstrate that PRC2–Ezh1 has an essential role in establishing an altered gene expression program required for postmitotic muscle cells to adapt to environmental changes.