Showing papers on "Salt bridge (protein and supramolecular) published in 2002"

Synthesis Beyond the Molecule

Abstract: Weak, noncovalent interactions between molecules control many biological functions. In chemistry, noncovalent interactions are now exploited for the synthesis in solution of large supramolecular aggregates. The aim of these syntheses is not only the creation of a particular structure, but also the introduction of specific chemical functions in these supramolecules.

Crystal Structures of Two Potent Nonamidine Inhibitors Bound to Factor Xa

Abstract: There has been intense interest in the development of factor Xa inhibitors for the treatment of thrombotic diseases. Our laboratory has developed a series of novel non-amidine inhibitors of factor Xa. This paper presents two crystal structures of compounds from this series bound to factor Xa. The first structure is derived from the complex formed between factor Xa and compound 1. Compound 1 was the first non-amidine factor Xa inhibitor from our lab that had measurable potency in an in vitro assay of anticoagulant activity. The second compound, 2, has a molar affinity for factor Xa (K(iapp)) of 7 pM and good bioavailability. The two inhibitors bind in an L-shaped conformation with a chloroaromatic ring buried deeply in the S1 pocket. The opposite end of these compounds contains a basic substituent that extends into the S4 binding site. A chlorinated phenyl ring bridges the substituents in the S1 and S4 pockets via amide linkers. The overall conformation is similar to the previously published structures for amidine-based inhibitors complexed with factor Xa. However, there are significant differences in the interactions between the inhibitor and the protein at the atomic level. Most notably, there is no group that forms a salt bridge with the carboxylic acid at the base of the S1 pocket (Asp189). Each inhibitor forms only one well-defined hydrogen bond to the protein. There are no direct charge-charge interactions. The results indicate that electrostatic interactions play a secondary role in the binding of these potent inhibitors.

Simple Cation−π Interaction between a Phenyl Ring and a Protonated Amine Stabilizes an α-Helix in Water

Abstract: Cation−π interactions have been proposed to be important contributors to protein structure and function. In particular, these interactions have been suggested to provide significant stability at the solvent-exposed surface of a protein. We have investigated the magnitude of cation−π interactions between phenylalanine (Phe) and lysine (Lys), ornithine (Orn), and diaminobutanoic acid (Dab) in the context of an α-helix and have found that only the Phe···Orn interaction provides significant stability to the helix, stabilizing it by −0.4 kcal/mol. This interaction energy is in the same range as a salt bridge in an α-helix, and equivalent to the recently reported Trp···Arg interaction in an α-helix, despite the fact that Trp···guanidinium interactions have been proposed to be stronger than Phe···ammonium interactions. These results indicate that even the simplest cation−π interaction can provide significant stability to protein structure and demonstrate the subtle factors that can influence the observed interac...

Probing alkali metal-pi interactions with the side chain residue of tryptophan.

Abstract: Feeble forces play a significant role in the organization of proteins. These include hydrogen bonding, hydrophobic interactions, salt bridge formation, and steric interactions. The alkali metal cation-π interaction is a force of potentially profound importance but its consideration in biology has been limited by the lack of experimental evidence. Our previous studies of cation–π interactions with Na+ and K+ involved the side arms of tryptophan (indole), tyrosine (phenol), and phenylalanine (benzene) as the arene donors. The receptor system possesses limiting steric constraints. In this report, we show that direct interactions between alkali metals and arenes occur at or within the van der Waals contact distance.

Supramolecular organic photochemistry: Control of covalent bond formation through noncovalent supramolecular interactions and magnetic effects

Abstract: Supramolecular organic photochemistry, a field concerned with the interaction of light with supramolecular assemblies of organic molecules, has been inspired by the remarkable structural and dynamic features of guest@host chemistry, particularly as exemplified by enzymes. Exemplars of supramolecular organic photochemistry from soft-matter hosts (micelles) and hard-matter hosts (porous solids) are discussed with an emphasis on how noncovalent interactions, which are at the heart of supramolecular chemistry, can be systematically exploited to control the catalytic and magnetic effects on the formation of covalent bonds from photochemically produced pairs of radicals.

Structural and thermodynamic studies on a salt-bridge triad in the NADP-binding domain of glutamate dehydrogenase from Thermotoga maritima: cooperativity and electrostatic contribution to stability.

Abstract: Cooperative interactions within ion-pair networks of hyperthermostable proteins are thought to be a major determinant for extreme protein stability. While the favorable thermodynamic contributions of optimized electrostatics in general as well as those of pairwise interactions have been documented, cooperativity between pairwise interactions has not yet been studied thermodynamically in proteins from hyperthermophiles. In this study we use the isolated cofactor binding domain of glutamate dehydrogenase from the hyperthermophilic bacterium Thermotoga maritima to analyze pairwise and cooperative interactions within the salt-bridge triad Arg190-Glu231-Lys193. The X-ray structure of the domain was solved at 1.43 A and reveals the salt-bridge network with surrounding solvent molecules in detail. All three participating charges in the network were mutated to alanine in all combinations. The X-ray structure of the variant lacking all three charges reveals that the removal of the side chains has no effect on the overall conformation of the protein. Using solvent denaturation and thermodynamic cycles, the interaction energies between each pair of residues in the network were determined in the presence and in the absence of the third residue. Both the Arg190-Glu231 ion pair and the Lys193-Glu231 salt bridge in the absence of the third residue, contribute favorably to the free energy for unfolding of the domain in urea. Using guanidinium chloride as denaturant reveals a strong cooperativity between the two ion-pair interactions, the presence of the second ion pair converts the first interaction from destabilizing into stabilizing by as much as 1.09 kcal/mol. The different energetics of the salt-bridge triad in urea and GdmCl are discussed with reference to the observed anion binding in the crystal structure at high ionic strength and their possible role in a highly charged, high-temperature environment such as the cytoplasm of hyperthermophiles.

Hydrogen exchange rates in proteins from water H-1 transverse magnetic relaxation

Abstract: Access to the fast exchange kinetics of labile protein hydrogens in solution is provided by exchange broadening of the water 1H NMR line. We analyzed the chemical shift modulation contribution of labile hydrogens in bovine pancreatic trypsin inhibitor (BPTI) to the transverse 1H spin relaxation rate, R2, of the bulk solvent. Both the experimental pH dependence and the CPMG dispersion of R2 could be quantitatively accounted for on the basis of known chemical shifts, exchange rates, and ionization constants for BPTI. This analysis provided, for the first time, the hydrogen exchange rate constants for Lys and Arg side chains in a protein and pointed to an internal catalysis of the N-terminal amino protons in BPTI by a salt bridge. The method can be used for mapping the hydrogen exchange rates in protein solutions and biomaterials, which may be important for the control of relaxation-weighted contrast in biological MRI.

The [Lys-2-Arg-1-des(17−21)]-Endothelin-1 Peptide Retains the Specific Arg-1−Asp8 Salt Bridge but Reveals Discrepancies between NMR Data and Molecular Dynamics Simulations†

Abstract: The [des(17−21)]-endothelin-1 (CSH-ET) and [Lys-2-Arg-1-des(17−21)]-endothelin-1 (KR-CSH-ET) peptides, designed by removing the five-residue hydrophobic tail from the endothelin-1 (ET-1) and [Lys-2-Arg-1]-endothelin-1 (KR-ET-1) peptides, respectively, were synthesized. Previous studies on KR-ET-1 showed that, in contrast to ET-1, this engineered compound displays a pH-dependent conformational change related to the formation of a stabilizing salt bridge between the Arg-1 and Asp8 side chains. CD and NMR spectra indicate that CSH-ET and KR-CSH-ET display conformational behavior similar to those of ET-1 and KR-ET-1, respectively. The short salt bridge-stabilized KR-CSH-ET peptide therefore appears to be an attractive elementary scaffold for drug design. The solution structure of the salt-bridged form of KR-CSH-ET was determined by NMR at pH 4.5 and is very similar to the corresponding form of the parent KR-ET-1 peptide. Molecular dynamics simulations of the salt-bridged form of KR-CSH-ET were performed using both the GB/SA implicit solvation scheme or an explicit solvation and the particle-mesh Ewald method for long-range electrostatic calculation. Unexpectedly, the Arg-1−Asp8 salt bridge does not display in the simulation the stability that could be expected from the experimental data. The cooperative involvement of a cation−π interaction in formation of the salt bridge has been hypothesized. Difficulties in accurately simulating cation−π interactions might be responsible for the lack of stability in the simulation. At this time, however, no definitive explanation for the observed discrepancy between experiments and simulations is available, and further experimental studies appear to be necessary to fully understand in atomic detail the pH-dependent conformational change observed in the KR-ET-1 series