TATA boxes

Fig. 2. Two views of the stmcture of the TATA-box binding protein (TBP)—DNA complex, where TATA is the nucleotide sequence...

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. 

Figure 9.1 The transcriptional elements of a eucaryotic structural gene extend over a large region of DNA. The regulatory sequences can be divided into three main regions (1) the basal promoter elements such as the TATA box, (2) the promoter proximal elements close to the initiation site, and (3) distal enhancer elements far from the initiation site.

Figure 9.2 Schematic model for transcriptional activation. The TATA box-binding protein, which bends the DNA upon binding to the TATA box, binds to RNA polymerase and a number of associated proteins to form the preinitiation complex. This complex interacts with different specific transcription factors that bind to promoter proximal elements and enhancer elements.

The general transcription factor TFllD is believed to be the key link between specific transcription factors and the general preinitiation complex. However, the purification and molecular characterization of TFllD from higher eucaryotes have been hampered by its instability and heterogeneity. All preparations of TFllD contain the TATA box-binding protein in combination with a variety of different proteins called TBP-associated factors, TAFs. When the preinitiation complex has been assembled, strand separation of the DNA duplex occurs at the transcription start site, and RNA polymerase II is released from the promoter to initiate transcription. However, TFIID can remain bound to the core promoter and support rapid reinitiation of transcription by recruiting another molecule of RNA polymerase. 

The three-dimensional structures of TBP-TATA box complexes are known... 

Figure 9.3 Comparison of the consensus nucleotide sequence of the TATA box (a) and the sequences of the DNA fragments used in the crystal structure determinations of the TATA box-binding proteins from yeast (b) and the plant Arabidopsis thaliana (c).

Figure 9.S Schematic diagram illustrating the structure of the complex between TBP and a DNA fragment containing the TATA box. Both the stirmps and the underside of the saddle are in contact with the DNA. (Adapted from V. Kim et al., Nature 365 514-520, 1993.)...

Most sequence-specific regulatory proteins bind to their DNA targets by presenting an a helix or a pair of antiparallel p strands to the major groove of DNA. Recognition of the TATA box by TBP is therefore exceptional it utilizes a concave pleated sheet protein surface that interacts with the minor groove of DNA. Since the minor groove has very few sequence-specific... 

Figure 9.6 The DNA fragment is sharply bent in the TATA box region (orange) so that the DNA helices on both sides form an angle of about 110° to each other instead of 180° for undistorted B-DNA. The view of the DNA is rotated about 90° compared with that of Figure 9.5.

The interaction area between TBP and the TATA box is mainly hydrophobic... 

The only sequence-specific hydrogen bonds between TBP side chains and the bases in the minor groove occur at the very center of the TATA box (Figure 9.7). The amide groups of two asparagine side chains donate four hydrogen bonds, two each to adjacent bases on the same DNA strand (Asn 69... 

Figure 9.7 Sequence specific interactions between TBP and the TATA box. Asn 69 and Thr 124 from one domain and the equivalent residues Asn 159 and Thr 215 from the second domain interact with the palindromic TATA sequence of the central region of the TATA box.

Like Thr 124 and Thr 215, the Asn 69 and Asn 159 residues occupy equivalent positions in the two homologous motifs of TBP. By analogy with the symmetric binding of a dimeric repressor molecule to a palindromic sequence described in Chapter 8, the two motifs of TBP form symmetric sequence-specific hydrogen bonds to the quasi-palindromic DNA sequence at the center of the TATA box. The consensus TATA-box sequence has an A-T base pair at position 4, but either a T-A or an A-T base pair at the symmetry-related position 5, and the sequence is, therefore, not strictly palindromic. However, the hydrogen bonds in the minor groove can be formed equally well to an A-T base pair or to a T-A base pair, because 02 of thymine and N3 of adenine occupy nearly stereochemically equivalent positions, and it is sufficient, therefore, for the consensus sequence of the TATA box to be quasi-palindromic. 

In conclusion, one important factor that contributes to the strong affinity of TBP proteins to TATA boxes is the large hydrophobic interaction area between them. Major distortions of the B-DNA structure cause the DNA to present a wide and shallow minor groove surface that is sterically complementary to the underside of the saddle structure of the TBP protein. The complementarity of these surfaces, and in addition the six specific hydrogen bonds between four side chains from TBP and four hydrogen bond acceptors from bases in the minor groove, are the main factors responsible for causing TBP to bind to TATA boxes 100,000-fold more readily than to a random DNA sequence. 

The sharp bend of DNA at the TATA box induced by TBP binding is favorable for the formation of the complete DNA control module in particular, for the interaction of specific transcription factors with TFIID. Since these factors may bind to DNA several hundred base pairs away from the TATA box, and at the same time may interact with TBP through one or several TAFs, there must be several protein-DNA interactions within this module that distort the regular B-DNA structure (see Figure 9.2). The DNA bend caused by the binding of TBP to the TATA box is one important step to bring activators near to the site of action of RNA polymerase. 

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. 

TFIIB is arranged in two domains, both of which have the cyclin fold described in Chapter 6. Both domains bind to the TBP-TATA box complex at the C-terminal stirrup and helix of TBP. The phosphate and sugar moities of DNA form extensive non-sequence-specific contacts with TFIIB both upstream and downstream of the middle of the TATA box. 

TFIIA also has two domains, one of which is a four-helix bundle and the other an antiparallel p sandwich. The p sandwich interacts with the N-termi-nal half of TBP and thus positions TFIIA on the other side of the complex compared with TFIIB. This domain also interacts with phosphates and sugars of DNA upstream of the TATA box. Tbe four-helix bundle domain makes no contact with DNA or TBP and is far removed from the position of TFIIB. 

DNA binding by TBP is strongly dependent on the presence of T-A base pairs in the TATA box. Bending allows remote sites on the DNA, with their bound cognate specific transcription factors, to come close together such that the proteins can interact to form the transcriptional preinitiation complex. 

Nikilov, D.B., et al. Crystal structure of TFllD TATA-box binding protein. Nature 360 40-46, 1992. 

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