Gene-Specific H1 Eviction through a Transcriptional Activator→p300→NAP1→H1 Pathway.

Linker histone H1 has been correlated with transcriptional inhibition, but the mechanistic basis of the inhibition and its reversal during gene activation has remained enigmatic. We report that H1-compacted chromatin, reconstituted in vitro, blocks transcription by abrogating core histone modifications by p300 but not activator and p300 binding. Transcription from H1-bound chromatin is elicited by the H1 chaperone NAP1, which is recruited in a gene-specific manner through direct interactions with activator-bound p300 that facilitate core histone acetylation (by p300) and concomitant eviction of H1 and H2A-H2B. An analysis in B cells confirms the strong dependency on NAP1-mediated H1 eviction for induction of the silent CD40 gene and further demonstrates that H1 eviction, seeded by activator-p300-NAP1-H1 interactions, is propagated over a CCCTC-binding factor (CTCF)-demarcated region through a distinct mechanism that also involves NAP1. Our results confirm direct transcriptional inhibition by H1 and establish a gene-specific H1 eviction mechanism through an activator→p300→NAP1→H1 pathway.

The human PAF1 complex acts in chromatin transcription elongation both independently and cooperatively with SII/TFIIS.

Genetic and cell-based studies have implicated the PAF1 complex (PAF1C) in transcription-associated events, but there has been no evidence showing a direct role in facilitating transcription of a natural chromatin template. Here, we demonstrate an intrinsic ability of human PAF1C (hPAF1C) to facilitate activator (p53)- and histone acetyltransferase (p300)-dependent transcription elongation from a recombinant chromatin template in a biochemically defined RNA polymerase II transcription system. This represents a PAF1C function distinct from its established role in histone ubiquitylation and methylation. Importantly, we further demonstrate a strong synergy between hPAF1C and elongation factor SII/TFIIS and an underlying mechanism involving direct hPAF1C-SII interactions and cooperative binding to RNA polymerase II. Apart from a distinct PAF1C function, the present observations provide a molecular mechanism for the cooperative function of distinct transcription elongation factors in chromatin transcription.

RAD6-Mediated transcription-coupled H2B ubiquitylation directly stimulates H3K4 methylation in human cells.

H2B ubiquitylation has been implicated in active transcription but is not well understood in mammalian cells. Beyond earlier identification of hBRE1 as the E3 ligase for H2B ubiquitylation in human cells, we now show (1) that hRAD6 serves as the cognate E2-conjugating enzyme; (2) that hRAD6, through direct interaction with hPAF-bound hBRE1, is recruited to transcribed genes and ubiquitylates chromatinized H2B at lysine 120; (3) that hPAF-mediated transcription is required for efficient H2B ubiquitylation as a result of hPAF-dependent recruitment of hBRE1-hRAD6 to the Pol II transcription machinery; (4) that H2B ubiquitylation per se does not affect the level of hPAF-, SII-, and p300-dependent transcription and likely functions downstream; and (5) that H2B ubiquitylation directly stimulates hSET1-dependent H3K4 di- and trimethylation. These studies establish the natural H2B ubiquitylation factors in human cells and also detail the mechanistic basis for H2B ubiquitylation and function during transcription.

Transcription of in vitro assembled chromatin templates in a highly purified RNA polymerase II system.

In mammalian cells RNA polymerase II efficiently transcribes nucleosome-packaged DNA. In this regard, a fundamental question concerns the nature and mechanism of action of the accessory factors that are necessary and sufficient for, or enhance, transcription through nucleosomal arrays by RNA polymerase II. Here we describe a highly purified system that allows for efficient activator-dependent transcription by RNA polymerase II from the promoter through several contiguous nucleosomes on defined chromatin templates. The system contains natural or recombinant histones, chromatin assembly factors, the histone-acetyltransferase p300, all components of the general transcription machinery, general coactivators and the elongation factor SII (TFIIS). As examples of the applicability of this system for mechanistic analyses of these and other factors, representative experiments show (i) that activated transcription from chromatin templates is concomitantly dependent on the activator, p300-mediated histone acetylation and elongation factor SII/TFIIS. (ii) that SII/TFIIS acts in a highly synergistic manner with p300 (and histone acetylation) at a step subsequent to preinitiation complex (PIC) formation and (iii) that SII/TFIIS works directly at the elongation step of chromatin transcription. Here we describe purification methods for the different factors employed and the specific transcriptional assays that led to the above-mentioned conclusions. This purified system will be very useful as an assay system for the discovery of new factors or the mechanistic analysis of known or candidate factors involved in transcription initiation or elongation on chromatin templates, including factors that effect specific histone modifications or nucleosomal remodeling.

Structural and functional organization of TRAP220, the TRAP/mediator subunit that is targeted by nuclear receptors.

The TRAP/Mediator complex serves as a coactivator for many transcriptional activators, including nuclear receptors such as the thyroid hormone receptor (TR) that targets the TRAP220 subunit. The critical but selective function of TRAP220 is evidenced by the embryonic lethal phenotype of Trap220(-)(/)(-) mice and by the observation that Trap220(-)(/)(-) fibroblasts (isolated before embryonic death) are impaired in specific nuclear receptor-dependent pathways. Here we have used a biochemical and genetic approach to understand the basis of specificity in TRAP220 function. We show that Trap220(-)(/)(-) cells possess a TRAP/Mediator complex that is relatively intact and compromised in its ability to support TR-dependent, but not VP16-dependent, transcription in vitro. Transfection studies using TRAP220 mutants revealed that the N terminus of TRAP220 is necessary and sufficient for stable association with the TRAP/Mediator complex and, further, that TRAP220-dependent TR function in transfected cells requires both of the NR boxes that contain the LXXLL motif implicated in nuclear receptor binding. Similarly, an analysis of isolated TRAP/Mediator complexes with mutations in either or both of the two NR boxes confirmed a critical role for them in in vitro coactivator function. The implications of these observations are discussed in terms of our present understanding of coactivator function.

Alternative mechanisms by which mediator subunit MED1/TRAP220 regulates peroxisome proliferator-activated receptor gamma-stimulated adipogenesis and target gene expression.

Mediator is a general coactivator complex connecting transcription activators and RNA polymerase II. Recent work has shown that the nuclear receptor-interacting MED1/TRAP220 subunit of Mediator is required for peroxisome proliferator-activated receptor gamma (PPARgamma)-stimulated adipogenesis of mouse embryonic fibroblasts (MEFs). However, the molecular mechanisms remain undefined. Here, we show an intracellular PPARgamma-Mediator interaction that requires the two LXXLL nuclear receptor recognition motifs on MED1/TRAP220 and, furthermore, we show that the intact LXXLL motifs are essential for optimal PPARgamma function in a reconstituted cell-free transcription system. Surprisingly, a conserved N-terminal region of MED1/TRAP220 that lacks the LXXLL motifs but gets incorporated into Mediator fully supports PPARgamma-stimulated adipogenesis. Moreover, in undifferentiated MEFs, MED1/TRAP220 is dispensable both for PPARgamma-mediated target gene activation and for recruitment of Mediator to a PPAR response element on the aP2 target gene promoter. However, PPARgamma shows significantly reduced transcriptional activity in cells deficient for a subunit (MED24/TRAP100) important for the integrity of the Mediator complex, indicating a general Mediator requirement for PPARgamma function. These results indicate that there is a conditional requirement for MED1/TRAP220 and that a direct interaction between PPARgamma and Mediator through MED1/TRAP220 is not essential either for PPARgamma-stimulated adipogenesis or for PPARgamma target gene expression in cultured fibroblasts. As Mediator is apparently essential for PPARgamma transcriptional activity, our data indicate the presence of alternative mechanisms for Mediator recruitment, possibly through intermediate cofactors or other cofactors that are functionally redundant with MED1/TRAP220.

Synergistic functions of SII and p300 in productive activator-dependent transcription of chromatin templates.

We have reconstituted a highly purified RNA polymerase II transcription system containing chromatin templates assembled with purified histones and assembly factors, the histone acetyltransferase p300, and components of the general transcription machinery that, by themselves, suffice for activated transcription (initiation and elongation) on DNA templates. We show that this system mediates activator-dependent initiation, but not productive elongation, on chromatin templates. We further report the purification of a chromatin transcription-enabling activity (CTEA) that, in a manner dependent upon p300 and acetyl-CoA, strongly potentiates transcription elongation through several contiguous nucleosomes as must occur in vivo. The transcription elongation factor SII is a major component of CTEA and strongly synergizes with p300 (histone acetylation) at a step subsequent to preinitiation complex formation. The purification of CTEA also identified HMGB2 as a coactivator that, while inactive on its own, enhances SII and p300 functions.

The TBN protein, which is essential for early embryonic mouse development, is an inducible TAFII implicated in adipogenesis.

Human TFIID contains the TATA-binding protein (TBP) and several TBP-associated factors (hTAFs) that have been shown to play important roles, within TFIID, both in core promoter recognition and as coactivators. Here we show that the human TAF(II)43 (TAF8) is an integral component of a functional TFIID and an apparent ortholog to the recently reported mouse TBN, which is essential for early embryonic mouse developmental events. Significantly, we also show that TAF8 is dramatically induced and sequestered within TFIID upon differentiation of 3T3-L1 preadipocytes to adipocytes, whereas the expression of all other TAFs tested is slightly reduced. Moreover, when ectopically expressed, the histone fold domain of TAF8 acts as a dominant-negative mutant and selectively inhibits 3T3-L1 adipogenic differentiation. Furthermore TAF8 acts as a positive regulator of adipogenesis and reverses the inhibitory effect of its histone fold. These data suggest a selective role for TAF8 in a specific cell differentiation process(es).

The TRAP/Mediator coactivator complex interacts directly with estrogen receptors alpha and beta through the TRAP220 subunit and directly enhances estrogen receptor function in vitro.

Target gene activation by nuclear hormone receptors, including estrogen receptors (ERs), is thought to be mediated by a variety of interacting cofactors. Here we identify a number of nuclear extract-derived proteins that interact with immobilized ER ligand binding domains in a 17beta-estradiol-dependent manner. The most prominent of these are components of the thyroid hormone receptor-associated protein (TRAP)/Mediator coactivator complex, which interacts with ERalpha and ERbeta in both unfractionated nuclear extracts and purified form. Studies with extracts from TRAP220(-/-) fibroblasts reveal that these interactions depend on TRAP220, a TRAP/Mediator subunit previously shown to interact with ER and other nuclear receptors in a ligand-dependent manner. The physiological relevance of the in vitro interaction is documented further by the isolation of an ERalpha-TRAP/Mediator complex from cultured cells expressing an epitope-tagged ERalpha. Finally, the complete TRAP/Mediator complex is shown to enhance ER function directly in a highly purified cell-free transcription system. These studies firmly establish a direct role for TRAP/Mediator, through TRAP220, in ER function.

Transcription coactivator TRAP220 is required for PPAR gamma 2-stimulated adipogenesis.

The TRAP (thyroid hormone receptor-associated proteins) transcription coactivator complex (also known as Mediator) was first isolated as a group of proteins that facilitate the function of the thyroid hormone receptor. This complex interacts physically with several nuclear receptors through the TRAP220 subunit, and with diverse activators through other subunits. TRAP220 has been reported to show ligand-enhanced interaction with peroxisome proliferator-activated receptor gamma(2) (PPAR gamma(2)), a nuclear receptor essential for adipogenesis. Here we show that Trap220(-/-) fibroblasts are refractory to PPAR gamma(2)-stimulated adipogenesis, but not to MyoD-stimulated myogenesis, and do not express adipogenesis markers or PPAR gamma(2) target genes. These defects can be restored by expression of exogenous TRAP220. Further indicative of a direct role for TRAP220 in PPAR gamma(2) function via the TRAP complex, TRAP functions directly as a transcriptional coactivator for PPAR gamma(2) in a purified in vitro system and interacts with PPAR gamma(2) in a ligand- and TRAP220-dependent manner. These data indicate that TRAP220 acts, via the TRAP complex, as a PPAR gamma(2)-selective coactivator and, accordingly, that it is specific for one fibroblast differentiation pathway (adipogenesis) relative to another (myogenesis).