Cloning, expression and purification of the DNA binding domain of RFX protein

The RFX DNA binding domain (DBD) is a novel highly conserved motif belonging to a large number of dimer DNA binding proteins which have diverse regulatory functions in eukaryotic organisms. To characterize this novel motif, a 78mer polypeptide corresponding to the DBD of human hRFX (hrfX1/DBD), a prototypical member of the RFX family has been cloned and overproduced in Escherichia coli. A purification procedure using cation exchange chromatography has also been developed.     

The salt dependence of the interferon regulatory factor 1 DNA binding domain binding to DNA reveals ions are localized around protein and DNA

The equilibrium dissociation constant of the DNA binding domain of interferon regulatory factor 1 (IRF1 DBD) for its DNA binding site depends strongly on salt concentration and salt type. These dependencies are consistent with IRF1 DBD binding to DNA, resulting in the release of cations from the DNA and both release of anions from the protein and uptake of a cation by the protein. We demonstrated this by utilizing the fact that the release of fluoride from protein upon complex formation does not contribute to the salt concentration dependence of binding and by studying mutants in which charged residues in IRF1 DBD that form salt bridges with DNA phosphates are changed to alanine. The salt concentration dependencies of the dissociation constants of wild-type IRF1 DBD and the mutants R64A, D73A, K75A, and D73A/K75A were measured in buffer containing NaF, NaCl, or NaBr. The salt concentration and type dependencies of the mutants relative to wild-type IRF1 DBD provide evidence of charge neutralization by solution ions for R64 and by a salt bridge between D73 and K75 in buffer containing chloride or bromide salts. These data also allowed us to determine the number, type, and localization of condensed ions around both IRF1 DBD and its DNA binding site.     

RFX proteins, a novel family of DNA binding proteins conserved in the eukaryotic kingdom.

Until recently, the RFX family of DNA binding proteins consisted exclusively of four mammalian members (RFX1-RFX4) characterized by a novel highly conserved DNA binding domain. Strong conservation of this DNA binding domain precluded a precise definition of the motif required for DNA binding. In addition, the biological systems in which these RFX proteins are implicated remained obscure. The recent identification of four new RFX genes has now shed light on the evolutionary conservation of the RFX family, contributed greatly to a detailed characterization of the RFX DNA binding motif, and provided clear evidence for the function of some of the RFX proteins. RFX proteins have been conserved throughout evolution in a wide variety of species, including Saccharomyces cerevisiae, Schizosaccharomyces pombe, Caenorhabditis elegans, mouse and man. The characteristic RFX DNA binding motif has been recruited into otherwise very divergent regulatory factors functioning in a diverse spectrum of unrelated systems, including regulation of the mitotic cell cycle in fission yeast, the control of the immune response in mammals, and infection by human hepatitis B virus.     

A consensus motif in the RFX DNA binding domain and binding domain mutants with altered specificity.

The RFX DNA binding domain is a novel motif that has been conserved in a growing number of dimeric DNA-binding proteins, having diverse regulatory functions, in eukaryotic organisms ranging from yeasts to humans. To characterize this novel motif, we have performed a detailed dissection of the site-specific DNA binding activity of RFX1, a prototypical member of the RFX family. First, we have performed a site selection procedure to define the consensus binding site of RFX1. Second, we have developed a new mutagenesis-selection procedure to derive a precise consensus motif, and to test the accuracy of a secondary structure prediction, for the RFX domain. Third, a modification of this procedure has allowed us to isolate altered-specificity RFX1 mutants. These results should facilitate the identification both of additional candidate genes controlled by RFX1 and of new members of the RFX family. Moreover, the altered-specificity RFX1 mutants represent valuable tools that will permit the function of RFX1 to be analyzed in vivo without interference from the ubiquitously expressed endogenous protein. Finally, the simplicity, efficiency, and versatility of the selection procedure we have developed make it of general value for the determination of consensus motifs, and for the isolation of mutants exhibiting altered functional properties, for large protein domains involved in protein-DNA as well as protein-protein interactions.     

The binding of zinc (II) to a double-stranded oligodeoxyribonucleotide. A voltammetric study

Binding of zinc to a 19 mer double-stranded oligodeoxyribonucleotide was investigated by anodic stripping voltammetry and cyclic voltammetry in order to understand the roles of zinc in DNA cleavage catalyzed by mung bean nuclease. These methods rely on the direct monitoring of zinc oxidation current in the absence and in the presence of the oligo. Zinc titration curves with the ds-oligodeoxyribonucleotide were obtained in concentrations ranging from 3.62 x 10(-9) to 3.62 x 10(-8) M and 4.06 x 10(-10) to 5.25 x 10(-9) M. The acquired data were used to determine the dissociation constant, stoichiometry and zinc binding sites of the complex and to understand the specific changes of ds-oligodeoxyribonucleotide secondary structure by zinc binding. The oxidation-reduction process of zinc was also investigated by cyclic voltammetry through I (oxidation current) versus v(1/2) (square root of scan rate) curves in the absence and in the presence of the double-stranded oligodeoxyribonucleotide.     

The two modes of binding of Ru(phen)(2)dppz(2+) to DNA: thermodynamic evidence and kinetic studies

The binding of Ru(phen)(2)dppz(2+) (dppz=dipyrido[3,2-a:2',3'-c]phenazine) to DNA was investigated at pH 7.0 and 25 degrees C using stopped-flow and spectrophotometric methods. Equilibrium measurements show that two modes of binding, whose characteristics depend on the polymer to dye ratio (C(P)/C(D)), are operative. The binding mode occurring for values of C(P)/C(D) higher than 3 exhibits positive cooperativity, which is confirmed by kinetic experiments. The reaction parameters are K=2 x 10(3)M(-1), omega=550, n=1, k(r)=(1.9+/-0.5) x 10(7)M(-1)s(-1) and k(d)=(9.5+/-2.5)x10(3)s(-1) at I=0.012 M. The results are discussed in terms of prevailing surface interaction with DNA grooves accompanied by partial intercalation of the dppz residue. The other binding mode becomes operative for C(P)/C(D)<3 and the equilibria analysis shows this is an ordinary intercalation mode (K=1.3 x 10(6) M(-1), n=1.5 at I=0.012 M and K=2 x 10(5) M(-1), n=1.2 at I=0.21 M). Similar behaviour is displayed by double-stranded poly(A).     

Identification of a peptide binding motif for secreted frizzled-related protein-1

Secreted Frizzled-related proteins (sFRPs) bind Wnts and modulate their activity. To identify putative sFRP-1 binding motifs, we screened an M13 phage displayed combinatorial peptide library. A predominant motif, L/V-VDGRW-L/V, was present in approximately 70% of the phage that bound sFRP-1. Use of peptide/alkaline phosphatase chimeras and alanine scanning confirmed that the conserved motif was important for sFRP-1 recognition. The dissociation constant for a peptide/sFRP-1 complex was 3.9 microM. Additional analysis revealed that DGR was the core of the binding motif. Although Wnt proteins lack this sequence, other proteins possessing the DGR motif may function as novel binding partners for sFRP-1.     

Probing the binding of the coumarin drugs using peptide fragments of DNA gyrase B protein.

Bacterial DNA gyrase, has been identified as the target of several antibacterial agents, including the coumarin drugs. The coumarins inhibit the gyrase action by competitive binding to the ATP-binding site of DNA gyrase B (GyrB) protein. The high in vitro inhibitory potency of coumarins against DNA gyrase reactions has raised interest in studies on coumarin-gyrase interactions. In this context, a series of low-molecular weight peptides, including the coumarin resistance-determining region of subunit B of Escherichia coli gyrase, has been designed and synthesized. The first peptide model was built using the natural fragment 131-146 of GyrB and was able to bind to novobiocin (K(a) = 1.8 +/- 0.2 x 10(5)/m) and ATP (K(a) = 1.9 +/- 0.4 x 10(3)/m). To build the other sequences, changes in the Arg(136) residue were introduced so that the binding to the drug was progressively reduced with the hydrophobicity of this residue (K(a) = 1.3 +/- 0.1 x 10(5)/m and 1.0 +/- 0.2 x 10(5)/m for Ser and His, respectively). No binding was observed for the change Arg(136) to Leu. In contrast, the binding to ATP was not altered, independently of the changes promoted. On the contrary, for peptide-coumarin and peptide-ATP complexes, Mg(2+) appears to modulate the binding process. Our results demonstrate the crucial role of Arg(136) residue for the stability of coumarin-gyrase complex as well as suggest a different binding site for ATP and in both cases the interactions are mediated by magnesium ions.     

DNA binding properties of the marine sponge pigment fascaplysin

Association of fascaplysin with double-stranded calf thymus DNA was investigated by means of isothermal titration calorimetry, absorption spectroscopy, and circular dichroism. The UV spectroscopic data could be well interpreted in terms of a two-site model for the binding of fascaplysin to DNA revealing affinity constants of K1 = 2.5 x 10(6) M(-1) and K2 = 7.5 x 10(4) M(-1) (base pairs of DNA). Based on the typical change observed in the absorption and circular dichroism spectra, intercalation of fascaplysin is regarded as the major binding mode. The calorimetric titration curves showed an exothermic reaction which was exhausted at a 2:1 base pair/drug; ratio. This finding is in agreement with an intercalation model comprising nearest neighbor exclusion. In addition, significantly weaker non-intercalative DNA interactions can be observed at high drug concentration. By comparison of all these data with the binding behavior of known intercalating agents, it is concluded that fascaplysin intercalates into DNA.     

Equilibrium binding of single-stranded DNA to the secondary DNA binding site of the bacterial recombinase RecA

The bacterial recombinase RecA forms a nucleoprotein filament in vitro with single-stranded DNA (ssDNA) at its primary DNA binding site, site I. This filament has a second site, site II, which binds ssDNA and double-stranded DNA. We have investigated the binding of ssDNA to the RecA protein in the presence of adenosine 5'-O-(thiotriphosphate) cofactor using fluorescence anisotropy. The RecA protein carried out DNA strand exchange with a 5'-fluorescein-labeled 32-mer oligonucleotide. The anisotropy signal was shown to measure oligonucleotide binding to RecA, and the relationship between signal and binding density was determined. Binding of ssDNA to site I of RecA was stable at high NaCl concentrations. Binding to site II could be described by a simple two-state equilibrium, K = 4.5 +/- 1.5 x 10(5) m(-1) (37 degrees C, 150 mm NaCl, pH 7.4). The reaction was enthalpy-driven and entropy-opposed. It depended on salt concentration and was sensitive to the type of monovalent anion, suggesting that anion-dependent protein conformations contribute to ssDNA binding at site II.     

Stability and DNA binding ability of the DNA binding domains of interferon regulatory factors 1 and 3

The thermodynamic properties and DNA binding ability of the N-terminal DNA binding domains of interferon regulatory factors IRF-1 (DBD1) and IRF-3 (DBD3) were studied using microcalorimetric and optical methods. DBD3 is significantly more stable than DBD1: at 20 degrees C the Gibbs energy of unfolding of DBD3 is -28.6 kJ/mol, which is 2 times larger than that of DBD1, -14.9 kJ/mol. Fluorescence anisotropy titration experiments showed that at this temperature the association constants with the PRDI binding site are 1.1 x 10(6) M(-)(1) for DBD1 and 3.6 x 10(6) M(-)(1) for DBD3, corresponding to Gibbs energies of association of -34 and -37 kJ/mol, respectively. However, the larger binding energy of DBD3 is due to its larger electrostatic component, while its nonelectrostatic component is smaller than that of DBD1. Therefore, DBD1 appears to have more sequence specificity than DBD3. Binding of DBD1 to target DNA is characterized by a substantially larger negative enthalpy than binding of DBD3, implying that the more flexible structure of DBD1 forms tighter contacts with DNA than the more rigid structure of DBD3. Thus, the strength of the DBDs' specific association with DNA is inversely related to the stability of the free DBDs.     

Thymol and carvacrol binding to DNA: model for drug-DNA interaction

Thymol and carvacrol can bind to major and minor grooves of B-DNA. The aim of this study was to examine the interaction of calf thymus DNA with thymol and carvacrol in aqueous solution and physiological pH with thymol/DNA and carvacrol/DNA (phosphate) molar ratios of 1/20, 1/10, 1/5, and 1/1. Fourier transform infrared and UV-visible difference spectroscopy were used to determine the thymol and carvacrol binding mode, binding constant, sequence selectivity, DNA secondary structure, and structural variations of thymol/DNA and carvacrol/DNA complexes in aqueous solution. Spectroscopic evidence showed that the thymol and carvacrol interaction occurred mainly through H-bonding of the thymol and carvacrol OH group to the guanine N7, cytosine N3, and backbone phosphate group with overall binding constant of K(thymol-DNA) = 2.43 x 10(3) M(-1), K(carvacrol-DNA) = 1.55 x 10(3) M(-1). In thymol and carvacrol-DNA complexes, DNA remains in the B-family structure.     

Catalytic and DNA binding properties of the ogg1 protein of Saccharomyces cerevisiae: comparison between the wild type and the K241R and K241Q active-site mutant proteins

The Ogg1 protein of Saccharomyces cerevisiae belongs to a family of DNA glycosylases and apurinic/apyrimidinic site (AP) lyases, the signature of which is the alpha-helix-hairpin-alpha-helix-Gly/Pro-Asp (HhH-GPD) active site motif together with a conserved catalytic lysine residue, to which we refer as the HhH-GPD/K family. In the yeast Ogg1 protein, yOgg1, the HhH-GPD/K motif spans residues 225-260 and the conserved lysine is K241. In this study, we have purified the K241R and K241Q mutant proteins and compared their catalytic and DNA binding properties to that of the wild-type yOgg1. The results show that the K241R mutation greatly impairs both the DNA glycosylase and the AP lyase activities of yOgg1. Specificity constants for cleavage of a 34mer oligodeoxyribonucleotide containing a 7,8-dihydro-8-oxoguanine (8-OxoG) paired with a cytosine, [8-OxoG.C], are 56 x 10(-)(3) and 5 x 10(-)(3) min(-)(1) nM(-)(1) for the wild-type and the K241R protein, respectively. On the other hand, the K241Q mutation abolishes the DNA glycosylase and AP lyase activities of yOgg1. In contrast, the K241R and K241Q proteins have conserved wild-type DNA binding properties. K(dapp) values for binding of [8-OxoG.C] are 6.9, 7.4, and 4.8 nM for the wild-type, K241R, and K241Q proteins, respectively. The results also show that AP site analogues such as 1, 3-propanediol (Pr), tetrahydrofuran (F), or cyclopentanol (Cy) are not substrates but constitute good inhibitors of the wild-type yOgg1. Therefore, we have used a 59mer [Pr.C] duplex to further analyze the DNA binding properties of the wild-type, K241R, and K241Q proteins. Hydroxyl radical footprints of the wild-type yOgg1 show strong protection of six nucleotides centered around the Pr lesion in the damaged strand. On the complementary strand, only the cytosine placed opposite Pr was strongly protected. The same footprints were observed with the K241R and K241Q proteins, confirming their wild-type DNA binding properties. These results indicate that the K241Q mutant protein can be used to study interactions between yOgg1 and DNA containing metabolizable substrates such as 8-OxoG or an AP site.     

The DNA binding properties of the Escherichia coli RecQ helicase

The RecQ helicase family is highly conserved from bacteria to men and plays a conserved role in the preservation of genome integrity. Its deficiency in human cells leads to a marked genomic instability that is associated with premature aging and cancer. To determine the thermodynamic parameters for the interaction of Escherichia coli RecQ helicase with DNA, equilibrium binding studies have been performed using the thermodynamic rigorous fluorescence titration technique. Steady-state fluorescence anisotropy measurements of fluorescein-labeled oligonucleotides revealed that RecQ helicase bound to DNA with an apparent binding stoichiometry of 1 protein monomer/10 nucleotides. This stoichiometry was not altered in the presence of AMPPNP (adenosine 5'-(beta,gamma-imido) triphosphate) or ADP. Analyses of RecQ helicase interactions with oligonucleotides of different lengths over a wide range of pH, NaCl, and nucleic acid concentrations indicate that the RecQ helicase has a single strong DNA binding site with an association constant at 25 degrees C of K=6.7 +/- 0.95 x 10(6) M(-1) and a cooperativity parameter of omega=25.5 +/- 1.2. Both single-stranded DNA and double-stranded DNA bind competitively to the same site. The intrinsic affinities are salt-dependent, and the formation of DNA-helicase complex is accompanied by a net release of 3-4 ions. Allosteric effects of nucleotide cofactors on RecQ binding to DNA were observed only for single-stranded DNA in the presence of 1.5 mM AMPPNP, whereas both AMPPNP and ADP had no detectable effect on double-stranded DNA binding over a large range of nucleotide cofactor concentrations.     

The effect of C-terminal helix stabilization on specific DNA binding by monomeric GCN4 peptides.

DNA binding by a 29-residue, monomeric, GCN4 basic region peptide, GCN4br, as well as by peptide br-C, a monomeric basic-region analogue that is helix stabilized at its C-terminal end by a Lys25. Asp29 side-chain lactam-bridged alanine-rich sequence, was studied at 25 C in an aqueous buffer containing 100 mm NaCl. Mixing of both peptides with duplex DNA containing the cAMP-responsive element (CRE) was accompanied by significant helix stabilization in the peptides, whereas mixing of the peptides with duplex DNA containing a scrambled CRE site was not. Peptide NBD-br-C was synthesized as a fluorescent probe to evaluate these peptide-DNA interactions further. Quantitative analysis of the fluorescence quenching of peptide NBD-br-C by CRE half-site DNA indicated the formation of a 1:1 complex with a dissociation constant of 1.41 +/- 0.22 microm. Competitive displacement fluorescence assays of CRE half-site binding gave dissociation constants of 0.65 +/- 0.09 microm for peptide br-C and 3.9 +/- 0.5 microM for GCN4br, which corresponds to a free energy difference of 1.1 kcal/mol that is attributed to the helix stabilization achieved in peptide br-C. This result indicates that helix initiation by the alpha-helical leucine zipper dimerization motif in native bzip proteins, such as GCN4, contributes significantly to the affinity of basic region peptides for their recognition sites on DNA. Our fluorescence assay should also prove useful for determining dissociation constants for CRE binding by other GCN4 basic region analogues under equilibrium conditions and physiological salt concentrations.