Solution structure and dynamics of GCN4 cognate DNA: NMR investigations.

A 12 bp long GCN4-binding, self-complementary duplex DNA d(CATGACGTCATG)(2) has been investigated by NMR spectroscopy to study the structure and dynamics of the molecule in aqueous solution. The NMR structure of the DNA obtained using simulated annealing and iterative relaxation matrix calculations compares quite closely with the X-ray structure of ATF/CREB DNA in complex with GCN4 protein (DNA-binding domain). The DNA is also seen to be curved in the free state and this has a significant bearing on recognition by the protein. The dynamic characteristics of the molecule have been studied by (13)C relaxation measurements at natural abundance. A correlation has been observed between sequence-dependent dynamics and recognition by GCN4 protein.

The solution structure of Lac repressor headpiece 62 complexed to a symmetrical lac operator.

BACKGROUND: Lactose repressor protein (Lac) controls the expression of the lactose metabolic genes in Escherichia coli by binding to an operator sequence in the promoter of the lac operon. Binding of inducer molecules to the Lac core domain induces changes in tertiary structure that are propagated to the DNA-binding domain through the connecting hinge region, thereby reducing the affinity for the operator. Protein-protein and protein-DNA interactions involving the hinge region play a crucial role in the allosteric changes occurring upon induction, but have not, as yet, been analyzed in atomic detail. RESULTS: We have used nuclear magnetic resonance (NMR) spectroscopy and restrained molecular dynamics (rMD) to determine the structure of the Lac repressor DNA-binding domain (headpeice 62; HP62) in complex with a symmetrized lac operator. Analysis of the structures reveals specific interactions between Lac repressor and DNA that were not found in previously investigated Lac repressor-DNA complexes. Important differences with the previously reported structures of the HP56-DNA complex were found in the loop following the helix-turn-helix (HTH) motif. The protein-protein and protein-DNA interactions involving the hinge region and the deformations in the DNA structure could be delineated in atomic detail. The structures were also used for comparison with the available crystallographic data on the Lac and Pur repressor-DNA complexes. CONCLUSIONS: The structures of the HP62-DNA complex provide the basis for a better understanding of the specific recognition in the Lac repressor-operator complex. In addition, the structural features of the hinge region provide detailed insight into the protein-protein and protein-DNA interactions responsible for the high affinity of the repressor for operator DNA.

Biophysical investigations on the myb-DNA system.

The oncogene product c-myb is a transcriptional modulator and is known to play important roles in cell growth and differentiation. It binds to DNA in a sequence specific manner and its cognate sequence motifs have been detected in the genes of proteins implying its role in a variety of regulatory functions. The protein has a DNA binding domain consisting of three imperfect repeats with highly conserved tryptophans at regular spacings in each of the repeats. We have carried out a variety of investigations on the structure and interactions of the DNA binding domain of Drosophila c-myb and its cognate DNA target sequences. The domain has been bacterially over-expressed by subcloning a segment of the gene coding for the domain in a pET 11d vector and transforming it into E. coli BL21 (DE3). Circular dichroism of the protein has revealed that the domain is largely helical in nature. Fluorescence investigations indicated that three out of the nine tryptophans are solvent exposed and the others are buried in the interior. The recombinant protein is able to distinguish between specific and non-specific DNA targets in its binding and the interaction is largely electrostatic in nature in both cases. Dynamic fluorescence quenching experiments suggested that the DNA binding sites on the protein for specific and non-specific DNA targets are physically different. Most of the conserved tryptophans are associated with the specific DNA binding site. Simulated annealing and molecular dynamic simulations in a water matrix have been used to predict an energetically favoured conformation for the protein. Calculation of surface accessibilities of the individual residues shows that nearly 60% of the residues are less than 50% accessible to the solvent. Two and three dimensional NMR experiments with isotopically labelled protein have enabled spin system identification for many residue type and the types of residues involved in hydrophobic core formation in the protein. In an attempt to see the DNA surface possibly involved in specific interaction with the protein, a three-dimensional structure of a 12 mer cognate DNA has been determined by NMR in conjunction with restrained energy minimization. The recognition sequence shows interesting structural characteristics that may have important roles in specific interaction.

NMR structure of the extended Myb cognate sequence and modeling studies on specific DNA-Myb complexes.

The recognition sequence of the Myb protein has been recently described to be pyAACKGHH (where py = T/C, K = G/T, and H = A/C/T), modifying the earlier identification as pyAACKG [Ording, E., et al. (1994) Eur. J. Biochem. 222, 113-120]. We had earlier determined the solution structure of the minimal cognate sequence TAACGG, choosing py = T and K = G, embeded in a 12-mer DNA duplex by NMR and related computational techniques [Radha, P. K., et al. (1995) Biochemistry 34, 5913-5912]. To understand the structural significance of the above modification and the role of the variability in the recognition sequence, we have investigated here the solution structure of a different DNA segment, d-ACAACTGCAGTTGT, which contains the extended Myb cognate site, CAACTGCA. The three-dimensional structure of the 14-mer duplex has been determined from NMR data by relaxation matrix and restrained molecular dynamics calculations. The structure of the above cognate sequence in the 14-mer duplex has been compared with that of the cognate sequence, TAACGG, in the 12-mer duplex and also with that in the NMR structure of the Myb DNA binding domain (R2R3)-DNA complex determined by Ogata et al. recently [Ogata, K., et al. (1994) Cell 79, 639-648]. The comparison highlighted differences in several structural parameters for the cognate sites in the DNA segments. Modeling studies by taking out the protein from the complex and presenting it with 12-mer and 14-mer DNA structures indicated that the protein induces structural alterations to drive the cognate site to a reasonably conserved structure. The extent of similarity of the derived structures was, however, dependent on the base sequences. Base changes in the minimal cognate sequence in the 12-mer-protein complex and in the 14-mer-protein complex so as to match the sequence of Ogata et al. produced a more conserved structure of the complex. A reverse exercise, in which the Ogata DNA in the complex was mutated to match the 12-mer and 14-mer minimal cognate sequences, complemented the above observations of the subtle sequence dependence of the structure in the complex. On the other hand, base changes in the extension did not influence the DNA-protein complex structure significantly. We also observed that the structural changes in the protein were very minor when different DNA sequences or different DNA structures were presented to it. These observations would be of interest from the point of view of DNA-Myb recognition.

Bacterial expression, characterization and DNA binding studies on Drosophila melanogaster c-Myb DNA-binding protein.

The Drosophila Myb homologue retains an evolutionarily conserved typical sequence of three imperfect tandem tryptophan repeat units (R1-R2-R3) of 51-53 amino acids towards its N-terminus as its presumptive DNA binding domain. Using PCR amplification and the T7 expression vector pET 11d, we have overproduced this tryptophan repeat domain of Drosophila Myb in Escherichia coli and the protein has been purified. Circular dichroic measurements indicate that the protein has a high helical component (58.6%) in its overall structure. The protein is found to recognize the same cognate target sequence TAACGG, as recognized by the vertebrate proteins. The DNA binding properties of the protein have been investigated in detail by fluorescence spectroscopy taking advantage of the large number of tryptophan residues present in the protein. The fluorescence of the native Drosophila R123 was quenched when synthetic duplex DNA oligomers were added to the protein. The oligomers containing specific Myb target sites quenched the protein fluorescence to a greater extent than the non-specific DNA. Binding constants of the protein to the targets were also length dependent for smaller oligomers. Experiments with the collisional quencher acrylamide and cysteine modification reagent indicated that the specific and non-specific target sequences interact with the protein differently. In the former case both the buried and the exposed tryptophan residues were affected by DNA binding whereas in the latter only the solvent-exposed residues were involved.

The DNA-binding domain of Drosophila melanogaster c-Myb undergoes a multistate denaturation.

The DNA-binding domain of Drosophila c-Myb protein has been studied using different spectroscopic probes, namely CD, fluorescence, acrylamide quenching and NMR, to determine the structure of some of its sub-domains and their relative stabilities in aqueous solutions. While CD and fluorescence spectroscopy showed that the protein had completely lost its tertiary and secondary structures in approximately 3 M urea, solvent accessibility of the tryptophan residues was still partial, as determined by acrylamide quenching. This suggested the presence of significant amounts of residual structure which persisted until the urea concentration was raised to approximately 6.0 M. Thermal-denaturation experiments also indicated the presence of an intermediate in the unfolding pathway. The experimental data could be fitted assuming a minimum of three states in both modes of denaturation. The thermodynamic parameters for the apparent three-state transition have been determined. From the protein stability curve, we have determined that Drosophila melanogaster Myb R123 has maximal stability at 16 degrees C and pH 7.0.

Solution structure of the conserved segment of the Myb cognate DNA sequence by 2D NMR, spectral simulation, restrained energy minimization, and distance geometry calculations.

Solution structure of a self-complementary DNA duplex d-ACCGTTAACGGT containing the TAACGG recognition segment of Myb protein has been obtained by NMR spectroscopy. Complete resonance assignments of all the protons (except H5', H5" protons) have been obtained following standard procedures based on two-dimensional NMR techniques. Using a total of 72 coupling constants, and 95 NOE intensities, restrained energy minimization has been carried out, with the X-PLOR force field. The distance constraint set has been iteratively refined, for better fits with experimental NOE intensities. Using the final constraint set thus obtained, and explicit H-bond constraints for A.T, G.C base pairs in the duplex, distance geometry calculations have been carried in the torsion angle space with the program TANDY-2S to identify the family of structures consistent with the NMR data. We observe that the constraint set does indeed define a unique structure for the DNA segment. The structural details have been analyzed, and the sequence-dependent variations in torsion angles, base pair geometries, and helicoidal parameters have been documented. We observed that the helix axis displays a nonregular path, and three centered H-bonds have been seen at AA, AC, and CC steps in the major groove of the helix. Substantial variations have been observed for the helix axis and the groove widths at the recognition site. The base pairs exhibit high negative propeller twists. The structure is characterized by O4'-endo geometry for all the sugar rings (expect G10), and the other torsion angles belong to the B-DNA families.