Kinetic and thermodynamic studies of purine repressor binding to corepressor and operator DNA.

The kinetic and thermodynamic parameters for purine repressor (PurR)-operator and PurR-guanine binding were determined using fluorescence spectroscopy and nitrocellulose filter binding. Operator binding affinity was increased by the presence of guanine as demonstrated previously (Choi, K. Y., Lu, F., and Zalkin, H. (1994) J. Biol. Chem. 269, 24066-24072; Rolfes, R. J., and Zalkin, H. (1990) J. Bacteriol. 172, 5637-5642), and conversely guanine binding affinity was increased by the presence of operator. Guanine enhanced operator affinity by increasing the association rate constant and decreasing the dissociation rate constant for binding. Operator had minimal effect on the association rate constant for guanine binding; however, this DNA decreased the dissociation rate constant for corepressor by approximately 10-fold. Despite significant sequence and structural similarity between PurR and LacI proteins, PurR binds to its corepressor ligand with a lower association rate constant than LacI binds to its inducer ligand. However, the rate constant for PurR-guanine binding to operator is approximately 3-fold higher than for LacI binding to its cognate operator under the same solution conditions. The distinct metabolic roles of the enzymes under regulation by these two repressor proteins provide a rationale for the observed functional differences.

Affinity and specificity of trp repressor-DNA interactions studied with fluorescent oligonucleotides.

Fluorescence-based solution methods have been used to study the binding of the trp repressor of Escherichia coli to a series of oligonucleotides bearing all or partial determinants for high affinity specific binding. The tryptophan, salt concentration and competitor DNA dependence of the binding affinities was examined for these targets. Binding to a fluorescein-labeled 20 base-pair hairpin structure oligonucleotide, which contains a palindromic repressor binding site (GAACTAGTTAACTAGTAC) and is known to bind repressor in a 1 : 1 dimer-DNA complex, resulted in a protein concentration-dependent, competable static quenching of fluorescence in presence of co-repressor, l-tryptophan. The affinity recovered from the fits of these intensity profiles at 100 mM KCl was on the order of 4x10(8) M-1. In absence of co-repressor an increase in intensity at high repressor concentration (>10(-7) M) was observed. The salt concentration dependence of the specific binding of the holo-repressor to this oligonucleotide was approximately half as large as what would be predicted by the number of phosphate contacts in the crystal structures of the complex. Repressor binding to the fluorescein-labeled hairpin 20mer was compared with binding to a rhodamine-labeled 36 base-pair oligonucleotide bearing two inverted structural half-sites GNACT separated by an eight base-pair spacer containing none of the natural intervening sequence. The rather low affinity observed for the 36mer revealed that the intervening sequence in the natural operators contains energetic specificity determinants. Binding to a rhodamine-labeled oligonucleotide bearing a completely non-specific sequence was shown to occur over the same concentration range (>100 nM), regardless of tryptophan concentration, whereas binding to sequences bearing partial specificity ratio between 100 and 1000, depending upon the salt concentration. Even in absence of added KCl, the specificity ratio of trp repressor was greater than 100, implicating a significant free energy contribution from non-electrostatic interaction forces.

Characterization of charge change super-repressor mutants of trp repressor: effects on oligomerization conformation, ligation and stability.

We have carried out a physical characterization of mutant repressor proteins of the trp repressor system of Escherichia coli by circular dichroism, chemical denaturation, and 8-anilino-1-naphthalenesulfonate binding. We have also probed the protein-protein interactions via fluorescence anisotropy and lifetime measurements and measured the thermodynamics of ligand (L-tryptophan) binding by isothermal titration calorimetry. Here, we present investigations of four charge change super-repressor mutants: EK13, EK18, DN46 and EK49, and compare these results with those previously obtained for wild-type trp repressor and the AV77 super-repressor mutant. These studies demonstrate that super-repressor phenotypes may result from changes in operator affinity (DN46, EK49), protein-protein interactions (EK18), as well as the coupling of folding to ligand binding (AV77, EK13, EK18). Correlations between the oligomerization behavior and cooperativity of DNA binding for some of these mutants indicate that coupling of oligomerization to DNA binding modulates operator site occupation giving rise to the super-repressor phenotype. The present results underscore the complex interplay between the multiple equilibria in this system. Moreover, they provide insights into the structural basis for the mutational perturbation of the energetics of this classical allosterically controlled transcriptional regulator.

Evidence for coupling of folding and function in trp repressor: physical characterization of the superrepressor mutant AV77.

The fine-control of gene expression in the trp repressor system is achieved through the thermodynamic linkage of multiple equilibria involving the trp repressor protein (TR), tryptophan (L-Trp) and DNA. We have undertaken studies of superrepressor mutants of TR as a means of dissecting the coupled equilibria that contribute to repressor function. Unlike all the other tested super-repressors that exhibit differences from wild-type TR DNA binding affinity or stoichiometry, the AV77 superrepressor (an alanine to valine substitution at position 77: AV77TR) has been indistinguishable from TR in vitro. The present studies using a variety of biophysical measurements comparing TR and AV77TR provide strong evidence that the helix-turn-helix (HTH) region of apoTR exists in a partially folded conformation. Far UV CD spectra of the two proteins reveal a 10% increase in helical content for the apoAV77TR compared to apoTR. Moreover, urea denaturation studies demonstrate that apoAV77TR is more stable to denaturation than apoTR. ApoTR binds large amounts of 1,8-ANS, a hydrophobic fluorescence probe used to detect protein folding intermediates, with high affinity, where apoAV77TR exhibits only marginal binding of this ligand. While the tryptophan affinities of the two proteins as measured by titration calorimetry are quite similar, the thermodynamic signatures are distinct, with a much reduced unfavorable entropic contribution for AV77TR. Finally, the allosteric effect of L-Trp on oligomerization is abolished by the AV77 mutation. Taken together these data support previous calorimetric studies implicating coupling of folding and L-Trp binding for TR. Moreover, they are consistent with NMR observations indicating partial disorder in the HTH region of apoTR. Based upon the distinct biophysical properties of TR and AV77TR, we propose a model in which folding of the HTH region accompanies ligand binding in TR. In this model distinct protein-protein interactions of the apo- and holoTR link this conformational change to apparent operator affinities, thereby modulating TR function in vivo.

Structure of the trigonal form of recombinant oxidized flavodoxin from Anabaena 7120 at 1.40 A resolution.

The oxidized recombinant flavodoxin from the cyanobacterium Anabaena 7120 has been crystallized in a trigonal form. The recombinant protein has an identical primary structure to that purified directly from Anabaena, which functions as a substitute for ferredoxin in an iron-deficient environment for electron transfer from photosystem I to ferredoxin-NADP(+) reductase. X-ray data to 1.40 A were collected on a Siemens area detector. Of the 311 379 reflections collected, 36069 reflections were unique in space group P3(1)21 (a = 55.36, c = 102.59 A) with an R(merge) of 3.8%. The structure was solved by molecular replacement using coordinates from the wild-type monoclinic structure previously solved in this laboratory [Rao, Shaffie, Yu, Satyshur, Stockman & Markley (1992). Protein Sci. 1, 1413-1427]. The structure was refined with X-PLOR and SHELXL93 to a crystallographic R-factor of 13.9% for 32963 reflections with I> 2sigma(I). The final structure contains 2767 atoms including 31 flavin mononucleotide (FMN) atoms, 299 water molecules, and one sulfate ion. The protein is comprised of a central five-stranded beta-sheet surrounded by five helices and binds a single molecule of FMN at the C-terminus of the sheet. The trigonal protein structure and the crystal packing are compared with the monoclinic wild-type protein. Helix alpha3 in this structure is less distorted than in the monoclinic structure and shows additional hydrogen bonds in the N-terminal portion of the helix. The trigonal structure is extensively hydrogen bonded in three major areas with neighboring molecules compared with five regions in the monoclinic structure, but using significantly fewer hydrogen bonds to stabilize the lattice. There are several hydrogen bonds to the amide groups from water molecules several of which stabilize and extend the ends of the beta-sheet.