Transcription basal

The DNA part of each control module can be divided into three main regions, the core or basal promoter elements, the promoter proximal elements and the distal enhancer elements (Figure 9.1). The best characterized core promoter element is the TATA box, a DNA sequence that is rich in A-T base pairs and located 25 base pairs upstream of the transcription start site. The TATA box is recognized by one of the basal transcription factors, the TATA box-binding protein, TBP, which is part of a multisubunit complex called TFIID. This complex in combination with RNA polymerase 11 and other basal transcription factors such as TFIIA and TFIIB form a preinitiation complex for transcription. 

TBP mutants lacking the N-terminal region are fully functional in promoter binding and stimulation of basal transcription and therefore these two functions must be provided by the C-terminal domain. Furthermore, the C-terminal domain of yeast TBP contains all the functions essential for normal yeast cell growth and for responses to specific transcriptional activators with a net negative charge. This C-terminal domain contains two homologous... 

TFIIA and TFIIB are two basal transcription factors that are involved in the nucleation stages of the preinitiation complex by binding to the TBP-TATA box complex. Crystal structures of the ternary complex TFIIA-TBP-TATA box have been determined by the groups of Paul Sigler, Yale University, and Timothy Richmond, ETH, Zurich, and that of the TFIIB-TBP-TATA box by Stephen Burley and collaborators. The TBP-DNA interactions and the distortions of the DNA structure are essentially the same in these ternary complexes as in the binary TBP-TATA complex. 

Buratowski, S. The basics of basal transcription by RNA Polymerase II. Cell 77 1-3, 1994. 

Nuclear Receptor Regulation of Hepatic Cytochrome P450 Enzymes. Figure 1 General mechanism for transcriptional activation of CYP genes by xenochemicals that activate their cognate xeno-receptor proteins. In the case of Ah receptor, the receptor s heterodimerization partner is Arnt, whereas in the case of the nuclear receptors CAR, PXR, and PPARa, the heterodimerization partner is RXR. The coactivator and basal transcription factor complexes shown are each comprised of a large number of protein components. 

This early biological result spurred a variety of biochemical studies of the interactions of various polyamides with the basal transcription machinery and TE-DNA complexes. Two studies have used promoter scanning to identify sites where polyamide binding inhibits transcription [64, 65]. The method uses a series of DNA constructs with designed polyamide binding sites at varying distances from... 

A small number of genes lack a TATA box. In such instances, two additional cis elements, an initiator sequence (Inr) and the so-called downstream promoter element (DPE), direct RNA polymerase II to the promoter and in so doing provide basal transcription starting from the correct site. The Inr element spans the start... 

Figure 37-9. The eukaryotic basal transcription complex. Formation of the basal transcription complex begins when TFIID binds to the TATA box. It directs the assembly of several other components by protein-DNA and protein-protein interactions. The entire complex spans DNA from position -30 to +30 relative to the initiation site (+1, marked by bent arrow). The atomic level, x-ray-derived structures of RNA polymerase II alone and ofTBP bound to TATA promoter DNA in the presence of either TFIIB or TFIIA have all been solved at 3 A resolution. The structure of TFIID complexes have been determined by electron microscopy at 30 A resolution. Thus, the molecular structures of the transcription machinery are beginning to be elucidated. Much of this structural information is consistent with the models presented here.

Figure 37-10. Two models for assembly of the active transcription complex and for how activators and coactivators might enhance transcription. Shown here as a small oval is TBP, which contains TFIID, a large oval that contains all the components of the basal transcription complex illustrated in Figure 37-9 (ie, RNAPII andTFIIA,TFIIB, TFIIE,TFIIF, and TFIIFI). Panel A The basal transcription complex is assembled on the promoter after the TBP subunit of TFIID is bound to the TATA box. Several TAFs (coactivators) are associated with TBP. In this example, a transcription activator, CTF, is shown bound to the CAAT box, forming a loop complex by interacting with a TAF bound to TBP. Panel B The recruitment model. The transcription activator CTF binds to the CAAT box and interacts with a coactivator (TAF in this case). This allows for an interaction with the preformed TBP-basal transcription complex. TBP can now bind to the TATA box, and the assembled complex is fully active.

Work by facilitating binding of the basal transcription complex to the promoter... 

Figure 39-17. Proteins that regulate transcription have several domains. This hypothetical transcription factor has a DNA-binding domain (DBD) that is distinct from a ligand-binding domain (LBD) and several activation domains (ADs) (1-4). Other proteins may lack the DBD or LBD and all may have variable numbers of domains that contact other proteins, including co-regulators and those of the basal transcription complex (see also Chapters 42 and 43).

Figure 43-11. The hormone response transcription unit. The hormone response transcription unit is an assembly of DNA elements and bound proteins that interact, through protein-protein interactions, with a number of coactivator or corepressor molecules. An essential component is the hormone response element which binds the ligand (A)-bound receptor (R). Also Important are the accessory factor elements (AFEs) with bound transcription factors. More than two dozen of these accessory factors (AFs), which are often members of the nuclear receptor superfamily, have been linked to hormone effects on transcription. The AFs can interact with each other, with the liganded nuclear receptors, or with coregulators. These components communicate with the basal transcription complex through a coregulator complex that can consist of one or more members of the pi 60, corepressor, mediator-related, or CBP/p300 families (see Table 43-6).

Chromatin remodeling, transcription factor modification by various enzyme activities, and the communication between the nuclear receptors and the basal transcription apparatus are accomplished by protein-protein interactions with one or more of a class of coregulator molecules. The number of these coregulator molecules now exceeds 100, not counting species variations and splice variants. The first of these to be described was the CREB-binding protein, CBP. CBP, through an amino terminal domain, binds to phosphorylated serine 137 of CREB and mediates transactivation in response to cAMP. It thus is described as a coactivator. CBP and... 

A small number of proteins, including NCoR and SMRT, comprise the corepressor family. They function, at least in part, as described in Figure 43-2. Another family includes the TRAPs, DRIPs, and ARC (Table 43-6). These so-called mediator-related proteins range in size from 80 kDa to 240 kDa and are thought to be involved in linking the nuclear receptor-coactivator complex to RNA polymerase II and the other components of the basal transcription apparatus. 

In eukaryotes, general transcription factors must bind to the promoter to allow RNA polymerase II to bind and form the initiation complex at the start site for transcription. General manscription factors are common to most genes. The general transcription factor TFIID (the TATA fector) must bind to the TATA box before RNA polymerase II can bind. Other examples delude SP-1 and NF-.l that modulate basal transcription of many genes. 

In vitro interactions between HMG proteins and the basal transcription machinery have also been reported. Human HMGBl binds to the TATA-box binding protein (TBP) and interferes with the normal binding of TFIIB in the preinitiation complex [154,155], thereby inhibiting TBP function both HMGBl and TFIIB independently enhance binding of TBP to TATA-box DNA [154]. Similarly, Nhp6ap promotes the formation of a complex with TBP and TFIIA at the TATA... 

The correlation between histone acetylation and eukaryotic transcription were recognized many years ago [128,129]. However, it has not been until very recently, with the discovery that both HATs [130-133] and HDACs [134-138] are an integral part of the basal transcriptional machinery, that the molecular link for this correlation was established. This discovery has rekindled interest in this post-translational histone modification with implications ranging from basic chromatin research to applied medical investigations. Indeed, histone acetylation has been linked to cancer [139-144] and certain types of HDAC inhibitors are already being used to treat certain forms of cancer [145]. 

Basal transcription on chromatin assembled on methylated DNA repression r 50-fold repression... 

In the resting state, the lysine residues in the N-terminal tail of the histones (see p. 238) are not acetylated. In this state, which can be produced by histone deacetylases [1], the nucleosomes are stable. It is only the interaction of activator and regulator proteins with their control elements that allows the binding of coactivator complexes that have histone acetylase activity [2]. They acetylate the histone tails and thereby loosen the nu-cleosome structure suf ciently for the basal transcription complex to form. 

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