Engineering aluminum binding affinity in an isolated EF-hand from troponin C: a computational site-directed mutagenesis study

Peptides with the ability to specifically bind aluminum would potentially be of great use in the fields of biochemistry and environmental chemistry. Unfortunately no such peptides are known. An aluminum-specific peptide may be used as an in vivo chelator, for metalloprotein design, for understanding metal-ion induced folding and metal-ion trafficking, and as an environmental sensor to monitor metal pollution in the environment. Plants genetically engineered to produce an aluminum binding peptide might be useful in environmental remediation in areas of high free aluminum ion concentration. In this paper, which is the theoretical complement to the experimental work, we analyzed crystallographic structures of EF-hands bound to various metals in order to determine the ligand distances and identities to compare to metal-ion size, charge, electronegativity, and coordination number and performed energy minimization calculations to identify possible mutations. We then constructed various mutant sequences in silico in an isolated EF-hand from troponin C and analyzed their binding behavior using molecular mechanics for binding to Tb(3+) as compared to Al(3+). As a result of these analyses we were able to isolate some characteristics that could lead to mutant peptides with enhanced aluminum activity that we plan to test experimentally in the future. We also performed metal-ion binding studies with the isolated EF-hand used in the computational work to examine the ability of Al(3+) and comparative metals to bind the peptide. In competition studies, the peptide demonstrated preference for Tb(3+) over Al(3+).     

Structure-function studies of apoA-I variants: site-directed mutagenesis and natural mutations

Five mutants of apolipoprotein A-I (apoA-I), apoA-I(Delta63-73), apoA-I(Delta140-150), apoA-I(63-73@140-150), apoA-I(R149V), and apoA-I(P143A) were compared with human plasma apoA-I for their ability to promote cholesterol and phospholipid efflux from HepG2 cells. A significantly lower capacity to promote cholesterol and phospholipid efflux was observed with lipid-free apoA-I(Delta63-73), while mutations apoA-I(Delta140-150) and apoA-I(P143A) affected phospholipid efflux only. When added as apoA-I/palmitoyloleoyl phosphatidylcholine (POPC) complex, mutations apoA-I(63-73@140-150) and apoA-I(Delta140-150) affected cholesterol efflux. None of the mutations affected alpha-helicity of the lipid-free mutants or their self-association. Five natural mutations of apoA-I, apoA-I(A95D), apoA-I (Y100H), apoA-I(E110K), apoA-I(V156E), and apoA-I (H162Q) were studied for their ability to bind lipids and promote cholesterol efflux. None of the mutations affected lipid-binding properties, cholesterol efflux, or alpha-helicity of lipid-free mutants. Two mutations affected self-association of apoA-I: apoA-I(A95D) was more prone to self-association, while apoA-I(E100H) did not self-associate. The following conclusions could be made from the combined data: i) regions 210-243 and 63-100 are the lipid-binding sites of apoA-I and are also required for the efflux of lipids to lipid-free apoA-I, suggesting that initial lipidation of apoA-I is rate limiting in efflux; ii) in addition to the lipid-binding regions, the central region is important for cholesterol efflux to lipidated apoA-I, suggesting its possible involvement in interaction with cells.     

Interaction of glucosamine with uracil and thymine: a computational study

Noncovalent interactions are ubiquitous and have been well recognized in chemistry, biology and material science. Yet, there are still recurring controversies over their natures, due to the wide range of noncovalent interaction terms. In this Essay, we employed the Valence Bond (VB) methods to address two types of interactions which recently have drawn intensive attention, i.e., the halogen bonding and the CH???HC dihydrogen bonding. The VB methods have the advantage of interpreting molecular structures and properties in the term of electron-localized Lewis (resonance) states (structures), which thereby shed specific light on the alteration of the bonding patterns. Due to the electron localization nature of Lewis states, it is possible to define individually and measure both polarization and charge transfer effects which have different physical origins. We demonstrated that both the ab initio VB method and the block-localized wavefunction (BLW) method can provide consistent pictures for halogen bonding systems, where strong Lewis bases NH₃, H₂O and NMe₃ partake as the halogen bond acceptors, and the halogen bond donors include dihalogen molecules and XNO₂ (X?=?Cl, Br, I). Based on the structural, spectral, and energetic changes, we confirm the remarkable roles of charge transfer in these halogen bonding complexes. Although the weak C-H???H-C interactions in alkane dimers and graphane sheets are thought to involve dispersion only, we show that this term embeds delicate yet important charge transfer, bond reorganization and polarization interactions.

     

Lysosomal sulfoglycolipid storage in the kidneys of mice deficient for arylsulfatase A (ASA) and of double-knockout mice deficient for ASA and galactosylceramide synthase

The inherited deficiency of arylsulfatase A (ASA) causes lysosomal accumulation of sulfoglycolipids (mainly sulfo-galactosylceramide, S-GalCer ) and leads to metachromatic leukodystrophy in humans. Among visceral organs, kidneys are particularly affected. In the present study, the regional distribution and temporal development of sulfoglycolipid storage in kidneys of ASA-/- mice was investigated histochemically (alcian blue) and ultrastructurally. Furthermore, the sulfoglycolipid storage was examined in kidneys of double-knockout mice, which are incapable of: (a) degrading any sulfolipids (ASA-/-) and (b) synthesizing the major sulfolipid S-GalCer because of deficiency for galactosylceramide synthase (CGT), with the aim to search for additional ASA substrates. In ASA-/- mice, the nephron segments could be ranged in the order of decreasing sulfolipid storage: thin limbs of long-looped nephrons approximately thick ascending limbs > distal convoluted tubules > collecting ducts approximately short thin limbs. Macula densa and proximal tubules were unaffected. In ASA-/-/CGT-/- mice, the long thin limbs and distal convoluted tubules resembled those of ASA-/-/CGT+/+ mice, while the other segments showed less storage. The results suggest that the turnover of sulfolipids in general is highest in the distal nephron except macula densa, and that long thin limbs and distal convoluted tubules are the main sites for turnover of a minor sulfolipid species, which is known to be synthesized in the kidney of CGT-/- mice.     

Exploration of the S(')(1) subsite of neprilysin: a joined molecular modeling and site-directed mutagenesis study

Based on the recently described three-dimensional model of the 507-749 region of neprilysin, which contains the catalytic site of the enzyme, experiments were performed to improve the proposed topology of its large and hydrophobic S(')(1) subsite. Docking studies, site-directed mutagenesis, and biochemical studies were combined. The mutations of various residues proposed to be part of the S(')(1) subsite (F563A, F564A, M579A, F716A, and I718A) did not induce major structural reorganization of the active site as demonstrated by the slight modification of the enzyme activity. The mutations were also analyzed by measuring the inhibitory potencies of thiol inhibitors containing P(')(1) moieties of increasing sizes. These results combined with molecular modeling studies support the proposed topology of the S(')(1) subsite. This, and the critical role of F563 and M579 in inhibitor binding, could facilitate the synthesis of new potent and selective inhibitors.     

The conserved methionine residue of the metzincins: a site-directed mutagenesis study.

The metalloprotease clan of the metzincins derive their name from the presence of a conserved methionine residue that is located on the C-terminal side of the zinc-binding consensus sequence HEXXHXXGXXH. This methionine residue is located in a rather divergent part of the primary sequence but is structurally very well conserved. It is located under the pyramidal base of the three histidine residues that coordinate the catalytic zinc ion and is not involved in any direct contact with the metal nor the substrate. In order to clarify its role, this methionine residue (M226) of the protease C from Erwinia chrysanthemi has been mutated to various other amino acids. The mutants M226L, M226A, M226I were sufficiently stable to be isolated, while the mutants M226H, M226S and M226N could not be purified. The kinetic properties of these mutants were analysed. All mutants showed decreased activity, whereby increases in K(M) as well as decreases in k(cat) were observed. The M226L mutant and M226C-E189 K double mutant, which has the catalytic glutamic acid substituted as well, could be crystallised. The structure of the M226L mutant was determined to a resolution of 2.0 A and refined to R(free) of 0.20. The structure is isomorphous to the wild-type and does not show large differences, with the exception of a very small movement of the zinc-liganding histidine residues. The M226C-E189 K double mutant crystal structure has been refined to an R(free) of 0.20 at 2.1 A resolution. A small rearrangement of the zinc-liganding histidine residues can be detected, which leads to a slightly different zinc coordination and could explain the decrease in activity.     

Interaction of ultrasound waves with bone remodelling: a multiscale computational study

Biomechanics and Modeling in Mechanobiology - Ultrasound stimulation is thought to influence bone remodelling process. But recently, the efficiency of ultrasound therapy for bone healing has been...     

The origin of enantioselectivity in aldolase antibodies: crystal structure, site-directed mutagenesis, and computational analysis

Catalytic aldolase antibodies, generated by reactive immunization, catalyze the aldol reaction with the efficiency of natural enzymes, but accept a much broader range of substrates. Two separate groups of aldolase antibodies that catalyze the same aldol reactions with antipodal selectivity were analyzed by comparing their amino acid sequences with their crystal structures, site-directed mutagenesis data, and computational docking of the transition states of the aldol reaction. The crystal structure of aldolase antibody 93F3 Fab' at 2.5A resolution revealed a combining site with two lysine residues, including LysL89 that reacts to form the covalent enamine intermediate. In contrast, antibody 33F12 has one active site lysine, LysH93. The reactive lysine residues in each group of antibodies are differentially located on the heavy and light chain variable regions in pseudo-symmetric opposite orientations, but both within highly hydrophobic environments. Thus, the defining feature for the observed enantioselectivities of these aldolase antibody catalysts is the respective location and relative disposition of the reactive lysine residues within the active sites of these catalysts.     

Spectral contribution of the individual tryptophan of alphaB-crystallin: a study by site-directed mutagenesis

There are two tryptophan residues in the lens alphaB-crystallin, Trp9 and Trp60. We prepared two Trp --> Phe substituted mutants, W9F and W60F, for use in a spectroscopic study. The two tryptophan residues contribute to Trp fluorescence and near-ultraviolet circular dichroism (UV CD) differently. The major difference in the near-UV CD is the contribution of 1La of Trp: it is positive in W60F but becomes negative in W9F. Further analysis of the near-UV CD shows an increased intensity in the region of 270-280 nm for W60F, suggesting that the Tyr48 is affected by the W60F mutation. It appears that Trp60 is located in a more rigid environment than Trp9, which agrees with a recent structural model in which Trp60 is in a beta-strand.     

Gene cloning and seamless site-directed mutagenesis using single-strand annealing (SSA)

Applied Microbiology and Biotechnology - The full length of interested genes can be usually cloned by assembling exons or RACE products through overlap PCR. However, the procedure requires multiple...     

A structure-based site-directed mutagenesis study on the neurolysin (EC 3.4.24.16) and thimet oligopeptidase (EC 3.4.24.15) catalysis

Neurolysin (EP24.16) and thimet oligopeptidase (EP24.15) are closely related metalloendopeptidases. Site-directed mutagenesis of Tyr(613) (EP24.16) or Tyr(612) (EP24.15) to either Phe or Ala promoted a strong reduction of k(cat)/K(M) for both enzymes. These data suggest the importance of both hydroxyl group and aromatic ring at this specific position during substrate hydrolysis by these peptidases. Furthermore, the EP24.15 A607G mutant showed a k(cat)/K(M) of 2x10(5) M(-1) s(-1) for the Abz-GFSIFRQ-EDDnp substrate, similar to that of EP24.16 (k(cat)/K(M)=3x10(5) M(-1) s(-1)) which contains Gly at the corresponding position; the wild type EP24.15 has a k(cat)/K(M) of 2.5x10(4) M(-1) s(-1) for this substrate.     

Interaction of human alpha-Synuclein and Parkinson's disease variants with phospholipids. Structural analysis using site-directed mutagenesis

alpha-Synuclein has been centrally implicated in neurodegenerative disease, and a normal function in developmental synaptic plasticity has been suggested by studies in songbirds. A variety of observations suggest the protein partitions between membrane and cytosol, a behavior apparently conferred by a conserved structural similarity to the exchangeable apolipoproteins. Here we show that the capacity to bind lipids is broadly distributed across exons 3, 4, and 5 (encoding residues 1-102). Binding to phosphatidylserine-containing vesicles requires the presence of all three exons, while binding to phosphatidic acid can be mediated by any one of the three. Consistent with a "class A2" helical binding mechanism, lipid association is disrupted by introduction of charged residues along the hydrophobic face of the predicted alpha-helix and also by biotinylation of conserved lysines (which line the interfacial region). Circular dichroism spectroscopy reveals a general correlation between the amount of lipid-induced alpha-helix content and the degree of binding to PS-containing vesicles. Two point mutations associated with Parkinson's disease have little (A30P) or no (A53T) effect on lipid binding or alpha-helicity. These results are consistent with the hypothesis that alpha-synuclein's normal functions depend on an ability to undergo a large conformational change in the presence of specific phospholipids.     

Mapping of a hapten-binding site: molecular modeling and site-directed mutagenesis study of an anti-atrazine antibody

A three-dimensional model of the variable domain of the atrazine-specific Fab fragment K411B was constructed by molecular modeling using known structures of highly homologous immunoglobulins as templates. Molecular dynamic simulations and cross-reactivity data were used to predict residues responsible for the binding of the hapten 4-chloro-6-(isopropylamino)-1,3,5-triazine-2-(6-aminohexanecarboxylic acid) (iPr/Cl/C6) instead of atrazine. Specific binding pockets could be defined for the chlorine, the isopropylamino group and the C6-spacer of the hapten. The influence of various amino acids on hapten binding was investigated by site-directed mutagenesis, and the effect of these mutations was analyzed by capture ELISA using the hapten iPr/Cl/C6 and 4-amino-6-chloro-1,3,5-triazine-2-(6-aminohexanecarboxylic acid) (H/Cl/C6). GlyH100a seems to be important in determining the conformation of the heavy-chain complementarity determining region H3; replacing it with any other residue prevented the binding of the hapten. Altering residues responsible for the binding of the chlorine atom (TrpH33, GluH50 and TyrL96) decreased the affinity significantly. Hapten-spacer recognition can be attributed to the interaction with PheL32; replacing PheL32 by leucine reduced the affinity towards iPr/Cl/C6. A triple mutant Fab fragment (GlnL89Glu, ValH37Ile and GluL3Val) showed an affinity 5-fold greater towards iPr/Cl/C6 compared to the wild-type K411B, as a result of better recognition of the isopropylamino group of iPr/Cl/C6.     

Constitutive activation of A(3) adenosine receptors by site-directed mutagenesis

The objective of this study was to create constitutively active mutant human A(3) adenosine receptors (ARs) using single amino acid replacements, based on findings from other G protein-coupled receptors. A(3) ARs mutated in transmembrane helical domains (TMs) 1, 3, 6, and 7 were expressed in COS-7 cells and subjected to agonist radioligand binding and phospholipase C (PLC) and adenylyl cyclase (AC) assays. Three mutant receptors, A229E in TM6 and R108A and R108K in the DRY motif of TM3, were found to be constitutively active in both functional assays. The potency of the A(3) agonist Cl-IB-MECA (1-chloro-N(6)-(3-iodobenzyl)adenosine-5'-N-methyluronamide) in PLC activation was enhanced by at least an order of magnitude over wild type (EC(50) 951 nM) in R108A and A229E mutant receptors. Cl-IB-MECA was much less potent (>10-fold) in C88F, Y109F, and Y282F and mutants or inactive following double mutation of the DRY motif. The degree of constitutive activation was more pronounced for the AC signaling pathway than for the PLC signaling pathway. The results indicated that specific locations within the TMs proximal to the cytosolic region were responsible for constraining the receptor in a G protein-uncoupled conformation.     

Vanadyl(IV) binding to mammalian ferritins. An EPR study aided by site-directed mutagenesis

During its metabolism, vanadium is known to become associated with the iron storage protein, ferritin. To elucidate probable vanadium binding sites on the protein, VO2+ binding to mammalian ferritins was studied using site-directed mutagenesis and EPR spectroscopy. VO2+-apoferritin EPR spectra of human H-chain (100% H), L-chain (100% L), horse spleen (84% L, 16% H) and sheep spleen (45% L, 55% H) ferritins revealed the presence of alpha and beta VO2+ species in all the proteins, implying that the ligands for these species are conserved between the H- and L-chains. The alpha species is less stable than the beta species and decreases with increasing pH, demonstrating that the two species are not pH-related, a result contrary to earlier proposals. EPR spectra of site-directed HuHF variants of several residues conserved in H- and L-chain ferritins (Asp-131, Glu-134, His-118 and His-128) suggest that His-118 near the outer opening of the three-fold channel is probably a ligand for VO2+ and is responsible for the beta signals in the EPR spectrum. The data indicate that VO2+ does not bind to the Asp-131 and Glu-134 residues within the three-fold channels nor does it bind at the ferroxidase site residues Glu-62 or His-65 or at the putative nucleation site residues Glu-61,64,67. While the ferroxidase site is not a site for VO2+ binding, mutation of residues Glu-62 and His-65 of this site to Ala affects VO2+ binding at His-118, located some 17 A away. Thus, VO2+ spin probe studies provide a window on structural changes in ferritin not seen in most previous work and indicate that long-range effects caused by point mutations must be carefully considered when drawing conclusions from mutagenesis studies of the protein.     

Mapping and modification of an antibody hapten binding site: a site-directed mutagenesis study of McPC603

The quantitative contributions of various amino acid residues to hapten binding in the Fv fragment of the antibody McPC603 were investigated by site-directed mutagenesis. The three-dimensional structure of the Fab' fragment of McPC603 is known to atomic resolution. The haptens phosphocholine, choline sulfate, 3-(trimethylammonium)propane-1-sulfonate, 4-(trimethylammonium)butyric acid, and 4-(trimethyl-ammonium)butyric acid methyl ester were tested for binding. It was found that the phosphate group but not the sulfate and sulfonate groups, interacts with the hydroxyl group of Tyr33(h). The required positive charge for the binding of the phosphate must be contributed by Arg52(h); a lysine at this position or an additional positive charge at position 33(h) abolishes the binding to a phosphocholine affinity column. The interaction between Tyr100(l) and Glu35(h) was found to be essential and could not be functionally replaced by any other pair of residues tested. Binding of the quaternary ammonium ion needs a negative charge; it can reside in either Asp97(l) or Asp101(h), but both together prevent binding to the affinity column. These data may serve as the basis for the development of quantitative treatments of antigen-antibody interactions.     

Structural and functional characterization of human microsomal prostaglandin E synthase-1 by computational modeling and site-directed mutagenesis

Microsomal prostaglandin (PG) E synthase-1 (mPGES-1) has recently been recognized as a novel, promising drug target for inflammation-related diseases. Functional and pathological studies on this enzyme further stimulate to understand its structure and the structure-function relationships. Using an approach of the combined structure prediction, molecular docking, site-directed mutagenesis, and enzymatic activity assay, we have developed the first three-dimensional (3D) model of the substrate-binding domain (SBD) of mPGES-1 and its binding with substrates prostaglandin H2 (PGH2) and glutathione (GSH). In light of the 3D model, key amino acid residues have been identified for the substrate binding and the obtained experimental activity data have confirmed the computationally determined substrate-enzyme binding mode. Both the computational and experimental results show that Y130 plays a vital role in the binding with PGH2 and, probably, in the catalytic reaction process. R110 and T114 interact intensively with the carboxyl tail of PGH2, whereas Q36 and Q134 only enhance the PGH2-binding affinity. The modeled binding structure indicates that substrate PGH2 interacts with GSH through hydrogen binding between the peroxy group of PGH2 and the -SH group of GSH. The -SH group of GSH is expected to attack the peroxy group of PGH2, initializing the catalytic reaction transforming PGH2 to prostaglandin E2 (PGE2). The overall agreement between the calculated and experimental results demonstrates that the predicted 3D model could be valuable in future rational design of potent inhibitors of mPGES-1 as the next-generation inflammation-related therapeutic.