Project description:The intrinsic curvature of seven 98 bp DNA molecules containing up to four centrally located A6-tracts has been measured by gel and capillary electrophoresis as a function of the number and arrangement of the A-tracts. At low cation concentrations, the electrophoretic mobility observed in polyacrylamide gels and in free solution decreases progressively with the increasing number of phased A-tracts, as expected for DNA molecules with increasingly curved backbone structures. Anomalously slow electrophoretic mobilities are also observed for DNA molecules containing two pairs of phased A-tracts that are out of phase with each other, suggesting that out-of-phase distortions of the helix backbone do not cancel each other out. The mobility decreases observed for the A-tract samples are due to curvature, not cation binding in the A-tract minor groove, because identical free solution mobilities are observed for a molecule with four out-of-phase A-tracts and one with no A-tracts. Surprisingly, the curvature of DNA A-tracts is gradually lost when the monovalent cation concentration is increased to ?200 mM, regardless of whether the cation is a hydrophilic ion like Na+, NH4+, or Tris+ or a hydrophobic ion like tetrabutylammonium. The decrease in A-tract curvature with increasing ionic strength, along with the known decrease in A-tract curvature with increasing temperature, suggests that DNA A-tracts are not significantly curved under physiological conditions.

Project description:GroEL is a bacterial chaperone protein that assembles into a homotetradecameric complex exhibiting D(7) symmetry and utilizes the co-chaperone protein GroES and ATP hydrolysis to assist in the proper folding of a variety of cytosolic proteins. GroEL utilizes two metal cofactors, Mg(2+) and K(+), to bind and hydrolyze ATP. A K(+)-binding site has been proposed to be located next to the nucleotide-binding site, but the available structural data do not firmly support this conclusion. Moreover, more than one functionally significant K(+)-binding site may exist within GroEL. Because K(+) has important and complex effects on GroEL activity and is involved in both positive (intra-ring) and negative (inter-ring) cooperativity for ATP hydrolysis, it is important to determine the exact location of these cation-binding site(s) within GroEL. In this study, the K(+) mimetic Tl(+) was incorporated into GroEL crystals, a moderately redundant 3.94 A resolution X-ray diffraction data set was collected from a single crystal and the strong anomalous scattering signal from the thallium ion was used to identify monovalent cation-binding sites. The results confirmed the previously proposed placement of K(+) next to the nucleotide-binding site and also identified additional binding sites that may be important for GroEL function and cooperativity. These findings also demonstrate the general usefulness of Tl(+) for the identification of monovalent cation-binding sites in protein crystal structures, even when the quality and resolution of the diffraction data are relatively low.

Project description:We report the first experimental probing of electrostatic interactions on the pyrimidine side of a bent A tract. Although the curvature of short A tracts (A4-A6) has long been studied, its physical origins remain under debate. Current hypotheses include the influence of major-groove hydrogen bonds between propeller-twisted base pairs, electrostatic effects of closely associated minor-groove cations, effects of minor-groove solvation, and stacking effects at the junctions adjacent to the A tract. We investigated this problem through the substitution of thymidines in A5 tracts by difluorotoluene deoxynucleoside (F), a non-polar molecule of the same size and shape which lacks hydrogen bonding and metal-ion complexing capabilities. Ligation experiments with phased A tracts demonstrated that F substitution has asymmetric effects on the bend angle. The strongest effects occurred at the second and third thymines where curvature was reduced from 19.8 degrees to 5.3 degrees and 9.6 degrees, respectively. Moderate effects were observed with substitutions at positions 1 and 4, while substitution at position 5 had no effect on bend angle. The results support the hypothesis that highly localized electrostatic interactions are a principal cause of A-tract curvature. Furthermore, they are most consistent with the notion that local metal-ion complexation at O2 of thymine is a strong component of these interactions.

Project description:Monovalent-cation-activated enzymes are abundantly represented in plants and in the animal world. Most of these enzymes are specifically activated by K+, whereas a few of them show preferential activation by Na+. The monovalent cation specificity of these enzymes remains elusive in molecular terms and has not been reengineered by site-directed mutagenesis. Here we demonstrate that thrombin, a Na+-activated allosteric enzyme involved in vertebrate blood clotting, can be converted into a K+-specific enzyme by redesigning a loop that shapes the entrance to the cation-binding site. The conversion, however, does not result into a K+-activated enzyme.

Project description:Using selected theoretical methods the affinity of a large range of Lewis bases towards model cations has been quantified. The range of model cations includes the methyl cation as the smallest carbon-centered electrophile, the benzhydryl and trityl cations as models for electrophilic substrates encountered in Lewis base-catalyzed synthetic procedures, and the acetyl cation as a substrate model for acyl-transfer reactions. Affinities towards these cationic electrophiles are complemented by data for Lewis-base addition to Michael acceptors as prototypical neutral electrophiles.

Project description:The presence of a regulatory site for monovalent cations that affects the conformation of the MgATP-binding pocket leading to enzyme activation has been demonstrated for ribokinases. This site is selective toward the ionic radius of the monovalent cation, accepting those larger than Na(+). Phosphofructokinase-2 (Pfk-2) from Escherichia coli is homologous to ribokinase, but unlike other ribokinase family members, presents an additional site for the nucleotide that negatively regulates its enzymatic activity. In this work, we show the effect of monovalent cations on the kinetic parameters of Pfk-2 together with its three-dimensional structure determined by x-ray diffraction in the presence of K(+) or Cs(+). Kinetic characterization of the enzyme shows that K(+) and Na(+) alter neither the kcat nor the KM values for fructose-6-P or MgATP. However, the presence of K(+) (but not Na(+)) enhances the allosteric inhibition induced by MgATP. Moreover, binding experiments show that K(+) (but not Na(+)) increases the affinity of MgATP in a saturable fashion. In agreement with the biochemical data, the crystal structure of Pfk-2 obtained in the presence of MgATP shows a cation-binding site at the conserved position predicted for the ribokinase family of proteins. This site is adjacent to the MgATP allosteric binding site and is only observed in the presence of Cs(+) or K(+). These results indicate that binding of the monovalent metal ions indirectly influences the allosteric site of Pfk-2 by increasing its affinity for MgATP with no alteration in the conformation of residues present at the catalytic site.

Project description:We report comparative structural changes of potassium-contained zeolite-W (K-MER, structural analogue of natural zeolite merlinoite) and monovalent extra-framework cation (EFC)-exchanged M-MERs (M = Li+, Na+, Ag+, and Rb+). High-resolution synchrotron X-ray powder diffraction study precisely determines that crystal symmetry of MERs is tetragonal (I4/mmm). Rietveld refinement results reveal that frameworks of all MERs are geometrically composed of disordered Al/Si tetrahedra, bridged by linkage oxygen atoms. We observe a structural relationship between a group of Li-, Na-, and Ag-MER and the group of K- and Rb-MER by EFC radius and position of M(1) site inside double 8-membered ring unit (d8r). In the former group, a-axes decrease reciprocally, c-axes gradually extend by EFC size, and M(1) cations are located at the middle of the d8r. In the latter group, a- and c-axes lengths become longer and shorter, respectively, than axes of the former group, and these axial changes come from middle-to-edge migration of M(1) cations inside the d8r channel. Unit cell volumes of the Na-, Ag-, and K-MER are ca. 2005 Å3, and the volume expansion in the MER series is limited by EFC size, the number of water molecules, and the distribution of extra-framework species inside the MER channel. EFC sites of M(1) and M(2) show disordered and ordered distribution in the former group, and all EFC sites change to disordered distribution after migration of the M(1) site in the latter group. The amount of water molecules and porosities are inversely proportional to EFC size due to the limitation of volume expansion of MERs. The channel opening area of a pau composite building unit and the amount of water molecules are universally related as a function of cation size because water molecules are mainly distributed inside a pau channel.

Project description:The monovalent cation (MVC) site of the tryptophan synthase from Salmonella typhimurium plays essential roles in catalysis and in the regulation of substrate channeling. In vitro, MVCs affect the equilibrium distribution of intermediates formed in the reaction of l-Ser with the alpha(2)beta(2) complex; the MVC-free, Cs(+)-bound, and NH(4)(+)-bound enzymes stabilize the alpha-aminoacrylate species, E(A-A), while Na(+) binding stabilizes the l-Ser external aldimine species, E(Aex(1)). Two probes of beta-site reactivity and conformation were used herein, the reactive indole analogue, indoline, and the l-Trp analogue, l-His. MVC-bound E(A-A) reacts rapidly with indoline to give the indoline quinonoid species, E(Q)(indoline), which slowly converts to dihydroiso-l-tryptophan. MVC-free E(A-A) gives very little E(Q)(indoline), and turnover is strongly impaired; the fraction of E(Q)(indoline) formed is <3.5% of that given by the Na(+)-bound form. The reaction of l-Ser with the MVC-free internal aldimine species, E(Ain), initially gives small amounts of an active E(A-A) which converts to an inactive species on a slower, conformational, time scale. This inactivation is abolished by the binding of MVCs. The inactive E(A-A) appears to have a closed beta-subunit conformation with an altered substrate binding site that is different from the known conformations of tryptophan synthase. Reaction of l-His with E(Ain) gives an equilibrating mixture of external aldimine and quinonoid species, E(Aex)(his) and E(Q)(his). The MVC-free and Na(+) forms of the enzyme gave trace amounts of E(Q)(his) ( approximately 1% of the beta-sites). The Cs(+) and NH(4)(+) forms gave approximately 17 and approximately 14%, respectively. The reactivity of MVC-free E(Ain) was restored by the binding of an alpha-site ligand. These studies show MVCs and alpha-site ligands act synergistically to modulate the switching of the beta-subunit from the open to the closed conformation, and this switching is crucial to the regulation of beta-site catalytic activity. Comparison of the structures of Na(+) and Cs(+) forms of the enzyme shows Cs(+) favors complexes with open indole binding sites poised for the conformational transition to the closed state, whereas the Na(+) form does not. The beta-subunits of Cs(+) complexes exhibit preformed indole subsites; the indole subsites of the open Na(+) complexes are collapsed, distorted, and too small to accommodate indole.

Project description:A combination of explicit solvent molecular dynamics simulation (30 simulations reaching 4 µs in total), hybrid quantum mechanics/molecular mechanics approach and isothermal titration calorimetry was used to investigate the atomistic picture of ion binding to 15-mer thrombin-binding quadruplex DNA (G-DNA) aptamer. Binding of ions to G-DNA is complex multiple pathway process, which is strongly affected by the type of the cation. The individual ion-binding events are substantially modulated by the connecting loops of the aptamer, which play several roles. They stabilize the molecule during time periods when the bound ions are not present, they modulate the route of the ion into the stem and they also stabilize the internal ions by closing the gates through which the ions enter the quadruplex. Using our extensive simulations, we for the first time observed full spontaneous exchange of internal cation between quadruplex molecule and bulk solvent at atomistic resolution. The simulation suggests that expulsion of the internally bound ion is correlated with initial binding of the incoming ion. The incoming ion then readily replaces the bound ion while minimizing any destabilization of the solute molecule during the exchange.

Project description:The binding mode of telomestatin to G-quadruplex DNA has been investigated using electrospray mass spectrometry, by detecting the intact complexes formed in ammonium acetate. The mass measurements show the incorporation of one extra ammonium ion in the telomestatin complexes. Experiments on telomestatin alone also show that the telomestatin alone is able to coordinate cations in a similar way as a crown ether. Finally, density functional theory calculations suggest that in the G-quadruplex-telomestatin complex, potassium or ammonium cations are located between the telomestatin and a G-quartet. This study underlines that monovalent cation coordination capabilities should be integrated in the rational design of G-quadruplex binding ligands.