Signals for TBP/TATA box recognition

The TATA box-binding protein (TBP) recognizes its target sites (TATA boxes) by indirectly reading the DNA sequence through its conformation effects (indirect readout). Here, we explore the molecular mechanisms underlying indirect readout of TATA boxes by TBP by studying the binding of TBP to adenovirus major late promoter (AdMLP) sequence variants, including alterations inside as well as in the sequences flanking the TATA box. We measure here the dissociation kinetics of complexes of TBP with AdMLP targets and, by phase-sensitive assay, the intrinsic bending in the TATA box sequences as well as the bending of the same sequence induced by TBP binding. In these experiments we observe a correlation of the kinetic stability to sequence changes within the TATA recognition elements. Comparison of the kinetic data with structural properties of TATA boxes in known crystalline TBP/TATA box complexes reveals several "signals" for TATA box recognition, which are both on the single base-pair level, as well as larger DNA tracts within the TATA recognition element. The DNA bending induced by TBP on its binding sites is not correlated to the stability of TBP/TATA box complexes. Moreover, we observe a significant influence on the kinetic stability of alteration in the region flanking the TATA box. This effect is limited however to target sites with alternating TA sequences, whereas the AdMLP target, containing an A tract, is not influenced by these changes.     

A-Tract bending: insights into experimental structures by computational models

While solution structures of adenine tract (A-tract) oligomers have indicated a unique bend direction equivalent to negative global roll (commonly termed "minor-groove bending"), crystallographic data have not unambiguously characterized the bend direction; nevertheless, many features are shared by all A-tract crystal and solution structures (e.g. propeller twisting, narrow minor grooves, and localized water spines). To examine the origin of bending and to relate findings to the crystallographic and solution data, we analyze molecular dynamics trajectories of two solvated A-tract dodecamers: 1D89, d(CGCGA(6)CG), and 1D98, d(CGCA(6)GCG), using a new general global bending framework for analyzing bent DNA and DNA/protein complexes. It is significant that the crystallographically-based initial structures are converted from dissimilar to similar bend directions equivalent to negative global roll, with the average helical-axis bend ranging from 10.5 degrees to 14.1 degrees. The largest bend occurs as positive roll of 12 degrees on the 5' side of the A-tracts (supporting a junction model) and is reinforced by gradual curvature at each A-tract base-pair (bp) step (supporting a wedge model). The precise magnitude of the bend is subtly sequence dependent (consistent with a curved general sequence model). The conversion to negative global roll only requires small local changes at each bp, accumulated over flexible moieties both outside and inside the A-tract. In contrast, the control sequence 1BNA, d(CGCGA(2)TTCGCG), bends marginally (only 6.9 degrees ) with no preferred direction. The molecular features that stabilize the bend direction in the A-tract dodecamers include propeller twisting of AT base-pairs, puckering differences between A and T deoxyriboses, a narrow minor groove, and a stable water spine (that extends slightly beyond the A-tract, with lifetimes approaching 0.2 ns). The sugar conformations, in particular, are proposed as important factors that support bent DNA. It is significant that all these curvature-stabilizing features are also observed in the crystallographic structures, but yield overall different bending paths, largely due to the effects of sequences outside the A-tract. These results merge structural details reported for A-tract structures by experiment and theory and lead to structural and dynamic insights into sequence-dependent DNA flexibility, as highlighted by the effect of an A-tract variant of a TATA-box element on bending and flexibility required for TBP binding.     

CH/pi interactions in the crystal structure of TATA-box binding protein/DNA complexes

Crystal structures of TATA box-binding proteins (TBP) of various sources bound to their promoter DNA (TATA box) were analyzed with use of our program CHPI. A number of short CH/Csp2 contacts have been unveiled in these complexes at the boundary of TBP and the TATA box minor groove. The result was discussed in the context of the CH/pi interaction. Thus, the nature of nonpolar forces, reported in the past at the interface of the two components, has been attributed to the CH/pi interaction. Furthermore, many CH/pi contacts have been disclosed within the same strand of the promoter DNA. The structure of the TATA element, partially unwound and severely bent on complexation, seems to be stabilized by CH/pi interactions; H2' of the deoxyribose moiety and the methyl group in the thymine nucleotide play the primary role.     

Dimer dissociation and thermosensitivity kinetics of the Saccharomyces cerevisiae and human TATA binding proteins.

A kinetic analysis of dimer dissociation, TATA DNA binding, and thermal inactivation of the yeast Saccharomyces cerevisiae and human TATA binding proteins (TBP) was conducted. We find that yeast TBP dimers, like human TBP dimers, are slow to dissociate in vitro (t(1/2) approximately 20 min). Mild mutations in the crystallographic dimer interface accelerate the rate of dimer dissociation, whereas severe mutations prevent dimerization. In the presence of excess TATA DNA, which measures the entire active TBP population, dimer dissociation represents the rate-limiting step in DNA binding. These findings provide a biochemical extension to genetic studies demonstrating that TBP dimerization prevents unregulated gene expression in yeast [Jackson-Fisher, A. J., Chitikila, C., Mitra, M., and Pugh, B. F. (1999) Mol. Cell 3, 717-727]. In the presence of vast excesses of TBP over TATA DNA, which measures only a very small fraction of the total TBP, the monomer population in a monomer/dimer equilibrium binds DNA rapidly, which is consistent with a simultaneous binding and bending of the DNA. Under conditions where other studies failed to detect dimers, yeast TBP's DNA binding activity was extremely labile in the absence of TATA DNA, even at temperatures as low as 0 degrees C. Kinetic analyses of TBP instability in the absence of DNA at 30 degrees C revealed that even under fairly stabilizing solution conditions, TBP's DNA binding activity rapidly dissipated with t(1/2) values ranging from 6 to 26 min. TBP's stability appeared to vary with the square root of the TBP concentration, suggesting that TBP dimerization helps prevent TBP inactivation.