A quantum-chemical study of the binding ability of βXaaHisGlyHis towards copper(II) ion

The present study analyzed binding of Cu²⁺ to tetrapeptides in water solution at several levels of theoretical approximation. The methods used to study the energetic and structural properties of the complexes in question include semiempirical hamiltonians, density functional theory as well as ab initio approaches including electron correlation effects. In order to shed light on the character of interactions between Cu²⁺ and peptides, which are expected to be mainly electrostatic in nature, decomposition of interaction energy into physically meaningful components was applied.     

Computational study of binding of epothilone A to β-tubulin

Understanding the interactions of epothilones with β-tubulin is crucial for computer aided rational design of macrocyclic drugs based on epothilones and epothilone derivatives. Despite numerous structure-activity relationship investigations we still lack substantial knowledge about the binding mode of epothilones and their derivatives to β-tubulin. In this work, we reevaluated the electron crystallography structure of epothilone A/β-tubulin complex (PDB entry 1TVK) and proposed an alternative binding mode of epothilone A to β-tubulin that explains more experimental facts.     

Two modes of fatty acid binding to bovine β-lactoglobulin--crystallographic and spectroscopic studies

Lactoglobulin is a natural protein present in bovine milk and common component of human diet, known for binding with high affinity wide range of hydrophobic compounds, among them fatty acids 12–20 carbon atoms long. Shorter fatty acids were reported as not binding to β‐lactoglobulin. We used X‐ray crystallography and fluorescence spectroscopy to show that lactoglobulin binds also 8‐ and 10‐carbon caprylic and capric acids, however with lower affinity. The determined apparent association constant for lactoglobulin complex with caprylic acid is 10.8 ± 1.7 × 10³ M^?1, while for capric acid is 6.0 ± 0.5 × 10³ M^?1. In crystal structures determined with resolution 1.9 Å the caprylic acid is bound in upper part of central calyx near polar residues located at CD loop, while the capric acid is buried deeper in the calyx bottom and does not interact with polar residues at CD loop. In both structures, water molecule hydrogen‐bonded to carboxyl group of fatty acid is observed. Different location of ligands in the binding site indicates that competition between polar and hydrophobic interactions is an important factor determining position of the ligand in β‐barrel. Copyright © 2010 John Wiley & Sons, Ltd.     

Infrared spectroscopic studies of calcium binding to inhibited β-trypsins

Fourier transform infrared spectroscopy was used to examine the effect of calcium binding on the secondary structure of two inhibited bovine β-trypsins. Neither the diisopropyl fluorophosphate- nor benzamidine-inhibited forms showed detectable secondary structure perturbation upon calcium binding at pD 6.9 and 5.0, respectively. Considered in light of the recent assignment of an amide I′ band to the autolysis loop of bovine β-trypsin, these results contradict the generally held hypothesis that calcium slows trypsin autolysis by induction of a conformational change at this site and support the recent contention that the mechanism of action has a specific electrostatic origin. In addition, the appearance of a band at 1699 cm⁻¹ in the benzamidine-inhibited form can be interpreted as resulting from the NCN stretching vibrations of the amidinium moiety, which the observed crystal structure indicates is hydrogen-bonded to the carboxyl group of active-sie Asp-189.     

Protein and carbohydrate moieties of a preparation of β-lactamase II

1. A crystalline preparation of beta-lactamase II has been separated into two moieties by gel filtration on a column of Sephadex G-100. 2. The first moiety consisted mainly of carbohydrate and showed virtually no beta-lactamase activity. 3. The second moiety was a protein of molecular weight 22500, which was enzymically active. 4. The protein moiety, like the original protein-carbohydrate complex, required Zn(2+) for beta-lactamase activity. It did not differ significantly from the complex in its behaviour to a number of cephalosporin substrates, but was less stable to heat than the complex. 5. About 30% of the total beta-lactamase activity was lost when the protein-carbohydrate complex was separated into the two moieties. This activity was regained when the protein and carbohydrate moieties were mixed, but the mixture did not show the heat stability of the original complex.     

Regulation of integrin αIIbβ3 ligand binding and signaling by the metal ion binding sites in the β I domain

The ability of αIIbβ3 to bind ligands and undergo outside-in signaling is regulated by three divalent cation binding sites in the β I domain. Specifically, the metal ion-dependent adhesion site (MIDAS) and the synergistic metal binding site (SyMBS) are thought to be required for ligand binding due to their synergy between Ca(2+) and Mg(2+). The adjacent to MIDAS (ADMIDAS) is an important ligand binding regulatory site that also acts as a critical link between the β I and hybrid domains for signaling. Mutations in this site have provided conflicting results for ligand binding and adhesion in different integrins. We have mutated the β3 SyMBS and ADMIDAS. The SyMBS mutant abolished ligand binding and outside-in signaling, but when an activating glycosylation mutation in the αIIb Calf 2 domain was introduced, the ligand binding affinity and signaling were restored. Thus, the SyMBS is important but not absolutely required for integrin bidirectional signaling. The ADMIDAS mutants showed reduced ligand binding affinity and abolished outside-in signaling, and the activating glycosylation mutation could fully restore integrin signaling of the ADMIDAS mutant. We propose that the ADMIDAS ion stabilizes the low-affinity state when the integrin headpiece is in the closed conformation, whereas it stabilizes the high-affinity state when the headpiece is in the open conformation with the swung-out hybrid domain.     

The composition of β-lactamase I and β-lactamase II from Bacillus cereus 569/H

1. Crystalline beta-lactamase I from Bacillus cereus 569/H yielded only amino acids on acid hydrolysis, but crystalline beta-lactamase II from the same organism yielded also substantial quantities of neutral sugars and amino sugars. 2. Analysis with an amino acid analyser indicated that the two enzymes were similar though not identical in overall amino acid composition. Analysis of neutral and amino sugars as their silyl derivatives by gas-liquid chromatography showed that the carbohydrate moiety of beta-lactamase II contained residues of glucose, galactose, mannose, fucose, glucosamine and galactosamine. 3. After oxidation and hydrolysis both beta-lactamases gave small amounts of cysteic acid. After treatment of inactive Zn(2+)-free beta-lactamase II with N-ethylmaleimide or iodoacetate enzymic activity was not restored by the addition of Zn(2+).     

Metal cofactor requirement of β-lactamase II

1. The apoenzyme obtained on removal of Zn(2+) from beta-lactamase II from Bacillus cereus 569/H/9 showed less than 0.001% of the activity of the Zn(2+)-containing enzyme. 2. Removal of Zn(2+) led to a conformational change in the enzyme and partial unmasking of a thiol group. 3. Replacement of Zn(2+) by Co(2+), Cd(2+), Mn(2+) or Hg(2+) gave enzymes with significant, but lower, beta-lactamase activity. No activity was detected in the presence of Cu(2+), Ni(2+), Mg(2+) or Ca(2+). 4. Equilibrium dialysis indicated that the enzyme had at least two Zn(2+) binding sites. With benzylpenicillin as substrate the variation in activity with concentration of Zn(2+) indicated that activity paralleled binding of Zn(2+) to the site of highest affinity. 5. Replacement of Zn(2+) by Co(2+) and Cd(2+) gave enzymes with absorption bands at 340 and 245nm respectively, and raised the question of whether the thiol group in the enzyme is a metal-ion ligand. 6. Reduction of the product obtained by reaction of denatured beta-lactamase II with Ellman's reagent [5,5'-dithiobis-(2-nitrobenzoic acid)] gave a protein which could refold to produce beta-lactamase II activity in high yield.     

A comparison of myocardial β-adrenoreceptor density and ligand binding affinity among selected teleost fishes

This study quantified the cell surface β-adrenoreceptor density and ligand binding affinity in the ventricular tissue of seven teleost species; skipjack tuna (Katsowonus pelamis), yellowfin tuna (Thunnus albacares), Pacific mackerel (Scomber japonicus), mahimahi (dolphin fish; Coryphaena hippurus), sockeye salmon (Oncorhynchus nerka), rainbow trout (Oncorhynchus mykiss) and an Antarctic nototheniid (Trematomus bernacchii). β-Adrenoreceptor density varied by almost fourfold among these species, being highest for the athletic fish: sockeye salmon among the salmonids and skipjack tuna among the scombrids. β-Adrenoreceptor density was lowest for the Antarctic icefish. β-Adrenoreceptor binding affinity varied by almost threefold. We conclude that there is a significant species-specific variability in myocardial β-adrenoreceptor density and binding affinity and these interspecific differences cannot be attributed to temperature even though intraspecifically cold temperature can stimulate an increase in myocardial β-adrenoreceptor density. Instead, we suggest that interspecifically myocardial β-adrenoreceptor density is highest in fish that inhabit tropical water. Accepted: 12 July 2000     

Mutagenesis studies of the β I domain metal ion binding sites on integrin αVβ3 ligand binding affinity

Three divalent cation binding sites in the integrin β I domain have been shown to regulate ligand binding and adhesion. However, the degree of ligand binding and adhesion varies among integrins. The αLβ2 and α4β7 integrins show an increase in ligand binding affinity and adhesion when one of their ADMIDAS (adjacent to MIDAS, or the metal ion-dependent adhesion site) residues is mutated. By contrast, the α2β1, α5β1, and αIIbβ3 integrins show a decrease in binding affinity and adhesion when their ADMIDAS is mutated. Our study here indicated that integrin αVβ3 had lower affinity when the ADMIDAS was mutated. By comparing the primary sequences of these integrin subunits, we propose that one residue associated with the MIDAS (β3 Ala(252)) may account for these differences. In the β1 integrin subunit, the corresponding residue is also Ala, whereas in both β2 and β7 integrin subunits, it is Asp. We mutated the β3 residue Ala(252) to Asp and combined this mutant with mutations of one or two ADMIDAS residues. The mutant A252D showed reduced ligand binding affinity and adhesion. The ligand binding affinity and adhesion were increased when this A252D mutant was paired with mutations of one ADMIDAS residue. But when paired with mutations of two ADMIDAS residues the mutant nearly abolished ligand-binding ability, which was restored by the activating glycosylation mutation. Our study suggests that the variation of this residue contributes to the different ligand binding affinities and adhesion abilities among different integrin families.     

Separation, purification and properties of β-lactamase I and β-lactamase II from Bacillus cereus 569/H/9

1. A procedure was devised which is suitable for the isolation of beta-lactamase I and beta-lactamase II from Bacillus cereus 569/H/9 on a large scale. After adsorption on to Celite both enzymes were eluted in good yield and separated by chromatography on Sephadex CM-50. 2. beta-Lactamase I was separated into three main components by isoelectric focusing and into two components by chromatography. 3. The Zn(2+)-requiring beta-lactamase II obtained by this procedure had a lower molecular weight (22000) than beta-lactamase I (28000) and also differed from the latter in containing one cysteine residue. 4. The beta-lactamase II contained no carbohydrate, but showed the thermostability of the enzyme isolated earlier as a protein-carbohydrate complex. 5. Amino acid analyses and tryptic-digest ;maps' indicate that some degree of homology between beta-lactamase I and beta-lactamase II is possible, but that beta-lactamase I is not composed of the entire sequence of beta-lactamase II together with an additional peptide fragment. 6. A 6-methylpenicillin and a 7-methylcephalosporin showed much lower affinities for both enzymes than did penicillins and cephalosporins themselves.     

Chelator-facilitated chemical modification of IMP-1 metallo-β-lactamase and its consequences on metal binding

A method involving the reversible chemical modification of an active site, zinc-binding cysteine residue (Cys221) for the specific removal of one of the two zinc ions in the metallo-β-lactamase IMP-1 was explored. Covalent modification of Cys221 by 5,5′-dithio-bis(2-nitrobenzoic acid) was greatly enhanced by the presence of dipicolinic acid, and subsequent removal of the modifying group was easily achieved by reduction of the disulfide bond. However, mass spectrometric analyses and an assessment of IMP-1’s catalytic competence are consistent with the maintenance of the enzyme’s binuclear status. The consequences arising from chemical modification of Cys221 are thus distinct from those reported for Cys → Ala/Ser mutants of IMP-1 and other metallo-β-lactamases, which are mononuclear.     

Retrospective molecular docking study of WY-25105 ligand to β-secretase and bias of the three-dimensional structure flexibility

β-Secretase (BACE) is a very promising target in the search for a treatment for Alzheimer’s disease using a protein–ligand inhibition approach. Given the many published X-ray structures of BACE protein, structure-based drug design has been used extensively to support new inhibitor discovery programs. Due to the high flexibility and large catalytic site of this protein, sampling of the huge conformational space of the binding site is the big challenge to overcome and is the main limitation of the most widely used docking programs. Incorrect treatment of these pitfalls can introduce bias into ligand docking and could affect the results. This is especially the case with the WY-25105 compound reported by the Wyeth Corporation as a BACE ligand that did not fit into any of the known crystal structures. In the present retrospective study, a set of available X-ray enzyme structures was selected and molecular dynamics simulations were conducted to generate more diverse representative BACE protein conformations. These conformations were then used for a docking study of the WY-25105 compound. The results confirmed the need to use an ensemble of structures in protein–ligand docking for identification of new binding modes in structure-based drug design of BACE inhibitors.

Site-selective binding of Zn(II) to metallo-β-lactamase L1 from Stenotrophomonas maltophilia

Extended X-ray absorption fine structure studies of the metallo-β-lactamase L1 from Stenotrophomonas maltophilia containing 1 and 2 equiv of Zn(II) and containing 2 equiv of Zn(II) plus hydrolyzed nitrocefin are presented. The data indicate that the first, catalytically dominant metal ion is bound by L1 at the consensus Zn₁ site. The data further suggest that binding of the first metal helps preorganize the ligands for binding of the second metal ion. The di-Zn enzyme displays a well-defined metal–metal interaction at 3.42 Å. Reaction with the β-lactam antibiotic nitrocefin results in a product-bound species, in which the ring-opened lactam rotates in the active site to present the S1 sulfur atom of nitrocefin to one of the metal ions for coordination. The product bridges the two metal ions, with a concomitant lengthening of the Zn–Zn interaction to 3.62 Å.     

Loss of enzyme activity during turnover of the Bacillus cereus β-lactamase catalysed hydrolysis of β-lactams due to loss of zinc ion

Metallo-beta-lactamases are zinc-ion-dependent and are known to exist either as mononuclear or as dinuclear enzymes. The kinetics and mechanism of hydrolysis of the native zinc Bacillus cereus metallo-beta-lactamase (BcII) have been investigated under pre-steady-state conditions at different pHs and zinc-ion concentrations. Biphasic kinetics are observed for the hydrolysis of cefuroxime and benzylpenicillin with submicromolar concentrations of enzyme and zinc. The initial burst of product formation far exceeds the concentration of enzyme and the subsequent slower rate of hydrolysis is attributed to a branched kinetic pathway. The pH and metal-ion dependence of the microscopic rate constants of this branching were determined, from which it is concluded that two enzyme species with different metal-to-enzyme stoichiometries are formed during catalytic turnover. The dizinc enzyme is responsible for the fast route but during the catalytic cycle it slowly loses the less tightly bound zinc ion via the branching route to give an inactive monozinc enzyme; the latter is only catalytic following the uptake of a second zinc ion. The rate constant for product formation from the dinuclear enzyme and the branching rate constant show a sigmoidal dependence on pH indicative of important ionizing groups with pK (a)s of 9.0 +/- 0.1 and 8.2 +/- 0.1, respectively. The rate constant for the regeneration of enzyme activity depends on zinc-ion concentration. This unusual behaviour is attributed to an intrinsic property of metallo hydrolytic enzymes that depend on a metal bound water both as a ligand for the second metal ion and as the nucleophile which is consumed during hydrolysis of the substrate and so has to be replaced to maintain the catalytic cycle.     

Mechanistic and spectroscopic studies of metallo-β-lactamase NDM-1

In an effort to biochemically characterize metallo-β-lactamase NDM-1, we cloned, overexpressed, purified, and characterized several maltose binding protein (MBP)-NDM-1 fusion proteins with different N-termini (full-length, Δ6, Δ21, and Δ36). All MBP-NDM-1 fusion proteins were soluble; however, only one, MBP-NDM-1Δ36, exhibited high activity and bound 2 equiv of Zn(II). Thrombin cleavage of this fusion protein resulted in the truncated NDM-1Δ36 variant, which exhibited a k(cat) of 16 s(-1) and a K(m) of 1.1 μM when using nitrocefin as a substrate, bound 2 equiv of Zn(II), and was monomeric in solution. Extended X-ray absorption fine structure studies of the NDM-1Δ36 variant indicate the average metal binding site for Zn(II) in this variant consists of four N/O donors (two of which are histidines) and 0.5 sulfur donor per zinc, with a Zn-Zn distance of 3.38 ?. This metal binding site is very similar to those of other metallo-β-lactamases that belong to the B1 subclass. Pre-steady-state kinetic studies using nitrocefin and chromacef and the NDM-1Δ36 variant indicate that the enzyme utilizes a kinetic mechanism similar to that used by metallo-β-lactamases L1 and CcrA, in which a reactive nitrogen anion is stabilized and its protonation is rate-limiting. While they are very different in terms of amino acid sequence, these studies demonstrate that NDM-1 is structurally and mechanistically very similar to metallo-β-lactamase CcrA.     

A critical histidine residue within LIMP-2 mediates pH sensitive binding to its ligand β-glucocerebrosidase

The lysosomal membrane protein type 2 is a novel identified lysosomal sorting receptor for β-glucocerebrosidase (GC). Mutations in both genes underlie human pathologies causing action myoclonus-renal failure syndrome (AMRF) and Gaucher disease (GD), respectively. We now demonstrate that the lumenal acidification mediated by the vacuolar (H(+) )-ATPase triggers the dissociation of LIMP-2 and GC in late endosomal/lysosomal compartments. Moreover, we identified a single histidine residue in LIMP-2 that is necessary for LIMP-2 and GC binding. This residue is in close proximity to a proposed coiled-coil domain, which determines the binding to GC and may function as a critical pH sensor.     

GPCRs through the keyhole: the role of protein flexibility in ligand binding to β-adrenoceptors

G protein-coupled receptors (GPCRs) are proteins of pharmaceutical importance, with over 30% of all drugs in clinical use targeting them. Increasing numbers of X-ray crystal (XRC) structures of GPCRs offer a wealth of data relating to ligand binding. For the β-adrenoceptors (β-ARs), XRC structures are available for human β₂- and turkey β₁-subtypes, in complexes with a range of ligands. While these structures provide insight into the origins of ligand structure-activity relationships (SARs), questions remain. The ligands in all published complexed XRC structures lack extensive substitution, with no obvious way the ligand-binding site can accommodate β₁-AR-selective antagonists with extended side-chains para- to the common aryloxypropanolamine pharmacophore. Using standard computational docking tools with such ligands generally returns poses that fail to explain known SARs. Application of our Active Site Pressurisation modelling method to β-AR XRC structures and homology models, however, reveals a dynamic area in the ligand-binding pocket that, through minor changes in amino acid side chain orientations, opens a fissure between transmembrane helices H4 and H5, exposing intra-membrane space. This fissure, which we term the “keyhole”, is ideally located to accommodate extended moieties present in many high-affinity β₁-AR-selective ligands, allowing the rest of the ligand structure to adopt a canonical pose in the orthosteric binding site. We propose the keyhole may be a feature of both β₁- and β₂-ARs, but that subtle structural differences exist between the two, contributing to subtype-selectivity. This has consequences for the rational design of future generations of subtype-selective ligands for these therapeutically important targets.     

D-glucose interaction with uranium ion. Synthesis,spectroscopic and structural characterization of uranylglucose adducts and the effect of metal cation binding on the sugar anomeric structures

The interaction of D-glucose with hydrated uranyl salts has been investigated in solution and solid adducts of the type UO₂(D-glucose)X₂·2H₂O, where X = Cl⁻, Br⁻, NO_3⁻ and 0.5 SO_4²⁻ have been isolated. These adducts are characterized by means of FT-IR, ¹H NMR and molar conductivity measurements.Spectroscopic evidence suggested that UO_2²⁺ cation could be bonded to one D-glucose molecule (possibly through O(1)H and O(2)H hydroxyl groups) and to two H₂O, resulting in six-coordination around the uranium ion.The strong sugar H-bonding network is perturbed, on metal ion interaction and the D-glucose α-anomeric structure is favoured, upon uranyl cation coordination.     

The binding of iron and zinc to glyoxalase II occurs exclusively as di-metal centers and is unique within the metallo-β-lactamase family

Cytosolic glyoxalase 2 (GLX2-2) from Arabidopsis thaliana is a metalloenzyme that has been shown to bind a mixture of Zn, Fe, or Mn when produced in cells grown in rich media. In an effort to prepare metal-enriched samples, GLX2-2 was over-expressed in minimal media containing either Zn, Fe, or Mn. The resulting enzymes bound an average of 1 equivalent of metal ion and were partially enriched with a specific metal ion. The enzymes produced in minimal media were active towards the substrate S-d-lactoylglutathione, yielding k_cat/K_m values similar to those of rich media GLX2-2. EPR studies on minimal media GLX2-2 samples revealed spectra which were identical to those over-expressed in rich media that contained nearly 2 equivalents of metal. The EPR spectra showed the presence of antiferromagnetically and ferromagnetically coupled, dinuclear metal centers. EXAFS spectra on the minimal media GLX2-2 samples over-expressed in the presence of Fe or Zn were also very similar to those of the rich media GLX2-2 samples, indicating the presence of dinuclear metal centers. The EXAFS studies also demonstrate that Zn(II) and Fe (in the Fe-enriched sample) are distributed in the dinuclear site. These data indicate that the minimal media GLX2-2 samples are a mixture of fully loaded, dinuclear metal-containing enzyme and metal-free enzyme. This characteristic of A. thaliana GLX2-2 makes it unique among the other members of the metallo--lactamase family in that it does not ever appear to exist as a mononuclear metal ion containing enzyme and that it exhibits positive cooperativity in metal binding.Abbreviations GLX2-2 cytoplasmic glyoxalase II isozyme - EXAFS extended X-ray absorption fine structure - MALDI-TOF matrix-assisted, laser desorption ionization time-of-flight - MG methylglyoxal - SLG S-d-lactoylglutathione - XAS X-ray absorption spectroscopy