Selective binding of the TATA box-binding protein to the TATA box-containing promoter: analysis of structural and energetic factors

Structural comparisons have led to the suggestion that the conformational rearrangement that would be required to change A-DNA into the TA-DNA form of DNA observed in the complex with the TATA box binding protein (TBP) could be completed by modifying only the value of the glycosyl bond chi by approximately 45 degrees. The lack of a high number of crystal structures of this type makes it difficult to conclude whether a smooth transition from A-DNA to TA-DNA can occur without disrupting at any point either the Watson-Crick base pairing or the A-DNA conformation of the backbone. To explore the possibility of such a smooth transition, constrained molecular dynamics simulations were carried out for the double-stranded dodecamer d(GGTATATAAAAC), in which a transition from A-DNA to TA-DNA was induced by modifying only the chi angle values. The results demonstrate the feasibility of a continuous path in the A-DNA to TA-DNA transition. Varying extents of DNA curvature are also attainable, by maintaining the A-DNA backbone structure and Watson-Crick hydrogen bonding while changing the chi angle value smoothly from that in A-DNA to one corresponding to B-DNA.     

DNA sequence-specific recognition by the Saccharomyces cerevisiae "TATA" binding protein: promoter-dependent differences in the thermodynamics and kinetics of binding

The equilibrium binding and association kinetics of the Saccharomyces cerevisiae TATA Binding Protein (TBP) to the E4 and Major Late promoters of adenovirus (TATATATA and TATAAAAG, respectively), have been directly compared by quantitative DNase I titration and quench-flow "footprinting". The equilibrium binding of TBP to both promoters is described by the equilibrium TBP + DNA"TATA" left and right arrow TBP-DNA"TATA". The salt dependence of TBP binding to both promoters is identical within experimental error while the temperature dependence differs significantly. The observed rate of association follows simple second-order kinetics over the TBP concentration ranges investigated. The salt and temperature dependencies of the second-order association rate constants for TBP binding the two promoters reflect the dependencies determined by equilibrium binding. The TBP-E4 promoter interaction is entropically driven at low temperature and enthalpically driven at high temperature while the TBP-Major Late promoter reaction is entropically driven over virtually the entire temperature range investigated. These data suggest that the reaction mechanisms of TBP-promoter interactions are TATA sequence-specific and provide for differential regulation of promoters as a function of environmental variables.