A disorder-to-order transition coupled to DNA binding in the essential zinc-finger DNA-binding domain of yeast ADR1.

The motional dynamics and solvent-exchange behavior of free and DNA-bound forms of the minimal zinc-finger DNA-binding domain of the yeast transcription factor ADR1 (ADR1-DBD) are investigated using NMR. The parameters measured include the 1H-15N heteronuclear NOE, 15N and 1H T1 relaxation rates, 15N T2 relaxation rates, and solvent-exchange rates. The spin relaxation parameters, spectral density maps, and solvent-exchange behavior show that, exclusive of the N and C termini, three distinct regions of free ADR1-DBD exhibit different motions on multiple timescales. The N-terminal proximal, or accessory, region appears to be unstructured and highly flexible: it exhibits large amplitude motions on a picosecond timescale, little or no protection from solvent exchange, and random-coil proton chemical shifts. The two zinc fingers tumble anisotropically as folded domains, with the tumbling of the individual fingers being only partly correlated to each other, and are modestly protected from solvent exchange except near the tips of the fingers and in the linker joining them. Free ADR1-DBD exhibits exchange broadening around P97 in the proximal region, at the tip of finger 1, and throughout finger 2. Upon binding, most of the proximal region and both zinc fingers tumble as a single domain and exhibit significantly reduced picosecond timescale motions. This region becomes more protected from solvent exchange. The bound portion of the proximal region is proposed to lie exposed on the surface of the DNA. Exchange broadening remains around P97 but also becomes evident for residues in direct contact with the DNA and in the linker. We conclude that the region of ADR1-DBD essential for high-affinity binding undergoes a disorder-to-order transition upon binding to its cognate DNA and, together with the zinc fingers, forms a cohesive molecular complex with the nucleic acid.

Ser45 plays an important role in managing both the equilibrium and transition state energetics of the streptavidin-biotin system.

The contribution of the Ser45 hydrogen bond to biotin binding activation and equilibrium thermodynamics was investigated by biophysical and X-ray crystallographic studies. The S45A mutant exhibits a 1,700-fold greater dissociation rate and 907-fold lower equilibrium affinity for biotin relative to wild-type streptavidin at 37 degrees C, indicating a crucial role in binding energetics. The crystal structure of the biotin-bound mutant reveals only small changes from the wild-type bound structure, and the remaining hydrogen bonds to biotin retain approximately the same lengths. No additional water molecules are observed to replace the missing hydroxyl, in contrast to the previously studied D128A mutant. The equilibrium deltaG degrees, deltaH degrees, deltaS degrees, deltaC degrees(p), and activation deltaG++ of S45A at 37 degrees C are 13.7+/-0.1 kcal/mol, -21.1+/-0.5 kcal/mol, -23.7+/-1.8 cal/mol K, -223+/-12 cal/mol K, and 20.0+/-2.5 kcal/mol, respectively. Eyring analysis of the large temperature dependence of the S45A off-rate resolves the deltaH++ and deltaS++ of dissociation, 25.8+/-1.2 kcal/mol and 18.7+/-4.3 cal/mol K. The large increases of deltaH++ and deltaS++ in the mutant, relative to wild-type, indicate that Ser45 could form a hydrogen bond with biotin in the wild-type dissociation transition state, enthalpically stabilizing it, and constraining the transition state entropically. The postulated existence of a Ser45-mediated hydrogen bond in the wild-type streptavidin transition state is consistent with potential of mean force simulations of the dissociation pathway and with molecular dynamics simulations of biotin pullout, where Ser45 is seen to form a hydrogen bond with the ureido oxygen as biotin slips past this residue after breaking the native hydrogen bonds.

Streptavidin-biotin binding energetics.

The high affinity energetics in the streptavidin-biotin system provide an excellent model system for studying how proteins balance enthalpic and entropic components to generate an impressive overall free energy for ligand binding. We review here concerted site-directed mutagenesis, biophysical, and computational studies of aromatic and hydrogen bonding interaction energetics between streptavidin and biotin. These results also have provided insight into how streptavidin builds a large activation barrier to dissociation by managing the enthalpic and entropic activation components. Finally, we review recent studies of the biotin dissociation pathway that address the fundamental question of how ligands exit protein binding pockets.

Thermodynamic evaluation of binding interactions in the methionine repressor system of Escherichia coli using isothermal titration calorimetry.

The binding interactions of the methionine repressor protein, MetJ, from Escherichia coli with its cognate, metbox DNA sequence and corepressor S-adenosylmethionine were examined using calorimetric methods. A detailed thermodynamic characterization of this system which exhibits the recently reported (beta alpha alpha)2 binding motif provides values for delta G, delta H, and delta S for each step in the repressor binding cycle. These studies show that, in the presence of corepressor, MetJ binds to a single metbox operator site with delta G = -7.7 kcal.mol-1, whereas in the absence of corepressor, the free energy of interaction with a single site is -5.8 kcal.mol-1. Cooperative interactions between two repressor molecules bound to two adjacent sites contribute an additional free energy of -1.3 kcal.mol-1 to binding at the second site. Binding is enthalpically unfavorable in the absence of the corepressor with delta H = +2.6 kcal.mol-1 but becomes exothermic with delta H = -4.6 kcal.mol-1 when corepressor is present. The heat capacity for the system decreases significantly by delta Cp = -290 cal.mol-1.K-1 on a per site basis when the protein binds to DNA, and interactions between repressor molecules bound to adjacent sites contribute a delta Cp = -800 cal.mol-1.K-1, indicating that solvent exclusion plays a significant role in binding in this system. The corepressor binds to the unbound repressor protein with a free energy of delta G = -6.0 kcal.mol-1 and to the MetJ-operator complex with delta G = -6.95 kcal.mol-1. Repressor binding to random-sequence DNA was estimated to occur with a free energy of -5.7 kcal.mol-1 in the presence of corepressor. These data clearly indicate that MetJ repressor dimer binds specifically to the central region of its 8 bp cognate metbox operator but recognizes partial operator sequences as short as 6 bp. Cooperativity in binding of adjacent MetJ dimers to a double metbox sequence is demonstrated to be important in determining the energetics of the interaction. Finally, the corepressor S-adenosylmethionine enhances the affinity of MetJ for its recognition site DNA by a factor of 25 and contributes significantly to the net exothermicity of repressor binding.

Improved excitation pulse bandwidths using shaped pulses, with application to heteronuclear half filters in macromolecular NMR.

The advantageous use of sinc-shaped pulses in heteronuclear half filters is explored for studying biological macromolecules. The typical square, or hard, pulse used in half-filter pulse sequences for heteronuclear excitation results in suboptimal suppression of unwanted resonances due to incomplete inversion of spins. The novel use of short-duration shaped pulses applied at high power achieves more uniform excitation profiles over the extended frequency ranges often needed for heteronuclear filtering. This approach is used in the development of a double-tuned omega 1, omega 2-double-half-filtered, double-quantum-filtered COSY experiment. The efficiency of this experiment incorporating sinc pulses compares favorably with that obtained with square pulses in a mixture of 13C-labeled and unlabeled amino acids. Sinc-pulse-filtered spectra of the 24 kDa methionine repressor protein dimer MetJ, uniformly 13C-labeled expect at two unlabeled methionine residues, were also obtained to demonstrate the utility of this approach in biomacromolecular studies.

A structural snapshot of an intermediate on the streptavidin-biotin dissociation pathway.

It is currently unclear whether small molecules dissociate from a protein binding site along a defined pathway or through a collection of dissociation pathways. We report herein a joint crystallographic, computational, and biophysical study that suggests the Asp-128 --> Ala (D128A) streptavidin mutant closely mimics an intermediate on a well-defined dissociation pathway. Asp-128 is hydrogen bonded to a ureido nitrogen of biotin and also networks with the important aromatic binding contacts Trp-92 and Trp-108. The Asn-23 hydrogen bond to the ureido oxygen of biotin is lengthened to 3.8 A in the D128A structure, and a water molecule has moved into the pocket to replace the missing carboxylate interaction. These alterations are accompanied by the coupled movement of biotin, the flexible binding loop containing Ser-45, and the loop containing the Ser-27 hydrogen bonding contact. This structure closely parallels a key intermediate observed in a potential of mean force-simulated dissociation pathway of native streptavidin, where the Asn-23 hydrogen bond breaks first, accompanied by the replacement of the Asp-128 hydrogen bond by an entering water molecule. Furthermore, both biotin and the flexible loop move in a concerted conformational change that closely approximates the D128A structural changes. The activation and thermodynamic parameters for the D128A mutant were measured and are consistent with an intermediate that has traversed the early portion of the dissociation reaction coordinate through endothermic bond breaking and concomitant gain in configurational entropy. These composite results suggest that the D128A mutant provides a structural "snapshot" of an early intermediate on a relatively well-defined dissociation pathway for biotin.