Design, synthesis and biological evaluation of mannosyl triazoles as FimH antagonists

Urinary tract infection (UTI) caused by uropathogenic Escherichia coli (UPEC) is one of the most prevalent infectious diseases. Particularly affected are women, who have a 40-50% risk to experience at least one symptomatic UTI episode at some time during their life. In the initial step of the infection, the lectin FimH, located at the tip of bacterial pili, interacts with the high-mannosylated uroplakin Ia glycoprotein on the urinary bladder mucosa. This interaction is critical for the ability of UPEC to colonize and invade the bladder epithelium. X-ray structures of FimH co-crystallized with two different ligands, the physiological binding epitope oligomannose-3 and the antagonist biphenyl α-D-mannoside 4a revealed different binding modes, an in-docking-mode and an out-docking-mode, respectively. To accomplish the in-docking-mode, that is the docking mode where the ligand is hosted by the so-called tyrosine gate, FimH antagonists with increased flexibility were designed and synthesized. All derivatives 5-8 showed nanomolar affinities, but only one representative, the 4-pyridiyl derivative 5j, was as potent as the reference compound n-heptyl α-D-mannoside (1b). Furthermore, a loss of affinity was observed for C-glycosides and derivatives where the triazole aglycone is directly N-linked to the anomeric center. A conformational analysis by NMR revealed that the triazolyl-methyl-C-mannosides 8 adopt an unusual (1)C(4) chair conformation, explaining the comparably lower affinity of these compounds. Furthermore, to address the druglikeness of this new class of FimH antagonists, selected pharmacokinetic parameters, which are critical for oral bioavailability (lipophilicity, solubility, and membrane permeation), were determined.     

Synthesis of trisaccharide fragment of O-specific polysaccharides of Salmonella of serologic groups C2 and C3 and its conversion into synthetic antigen of a copolymer type

Abequosyl-(alpha 1----3)-L-rhamnopyranosyl-(1----2)-D-mannopyranosides anomeric in the rhamnose residue have been synthesised. 2-Benzyloxycarbonylaminoethyl group used as the aglycon can be transformed into 2-acrylamidoethyl aglycon in the final stages of the syntheses. These isomeric alpha-glycosides were converted into copolymer artificial antigens, which are of interest for studying immunochemistry of factor O:8 of Salmonella O-antigens (serological groups C2 and C3).     

Type 1 pilus-mediated bacterial invasion of bladder epithelial cells

Most strains of uropathogenic Escherichia coli (UPEC) encode filamentous adhesive organelles called type 1 pili. We have determined that the type 1 pilus adhesin, FimH, mediates not only bacterial adherence, but also invasion of human bladder epithelial cells. In contrast, adherence mediated by another pilus adhesin, PapG, did not initiate bacterial internalization. FimH-mediated invasion required localized host actin reorganization, phosphoinositide 3-kinase (PI 3-kinase) activation and host protein tyrosine phosphorylation, but not activation of Src-family tyrosine kinases. Phosphorylation of focal adhesin kinase (FAK) at Tyr397 and the formation of complexes between FAK and PI 3-kinase and between alpha-actinin and vinculin were found to correlate with type 1 pilus-mediated bacterial invasion. Inhibitors that prevented bacterial invasion also blocked the formation of these complexes. Our results demonstrate that UPEC strains are not strictly extracellular pathogens and that the type 1 pilus adhesin FimH can directly trigger host cell signaling cascades that lead to bacterial internalization.     

Expression of the carbohydrate recognition domain of FimH and development of a competitive binding assay

Uropathogenic Escherichia coli (UPEC) is the primary cause of urinary tract infections (UTIs). In the first step of this infective process, the virulence factor FimH located on type 1 pili allows UPEC to specifically adhere to oligosaccharides, which are part of glycoproteins on the urinary bladder mucosa. This initial step prevents the clearance of E. coli from the urinary tract and enables the invasion of the host cells. Because FimH antagonists can block this interaction, they exhibit a promising therapeutic potential as anti-infectives. For the evaluation of their binding properties, a reliable, target-based affinity assay is required. Here, we describe the expression and purification of the carbohydrate recognition domain of FimH (FimH-CRD) as well as the development of a competitive binding assay. FimH-CRD linked with a thrombin cleavage site to a 6His-tag is recombinantly expressed and purified by affinity chromatography. For the evaluation of FimH antagonists, a cell-free binding assay based on the interaction of a biotinylated polyacrylamide glycopolymer with the FimH-CRD was developed. Complexation of the biotinylated glycopolymer with streptavidin coupled to horseradish peroxidase allows the quantification of the binding properties of FimH antagonists. The assay format was optimized and validated by a comparison with affinity data from reported assays.     

Uropathogenic E. coli Adhesin-Induced Host Cell Receptor Conformational Changes: Implications in Transmembrane Signaling Transduction

Urinary tract infection is the second most common infectious disease and is caused predominantly by type 1-fimbriated uropathogenic Escherichia coli (UPEC). UPEC initiates infection by attaching to uroplakin (UP) Ia, its urothelial surface receptor, via the FimH adhesins capping the distal end of its fimbriae. UP Ia, together with UP Ib, UP II, and UP IIIa, forms a  16-nm receptor complex that is assembled into hexagonally packed, two-dimensional crystals (urothelial plaques) covering > 90% of the urothelial apical surface. Recent studies indicate that FimH is the invasin of UPEC as its attachment to the urothelial surface can induce cellular signaling events including calcium elevation and the phosphorylation of the UP IIIa cytoplasmic tail, leading to cytoskeletal rearrangements and bacterial invasion. However, it remains unknown how the binding of FimH to the UP receptor triggers a signal that can be transmitted through the highly impermeable urothelial apical membrane. We show here by cryo-electron microscopy that FimH binding to the extracellular domain of UP Ia induces global conformational changes in the entire UP receptor complex, including a coordinated movement of the tightly bundled transmembrane helices. This movement of the transmembrane helix bundles can cause a corresponding lateral translocation of the UP cytoplasmic tails, which can be sufficient to trigger downstream signaling events. Our results suggest a novel pathogen-induced transmembrane signal transduction mechanism that plays a key role in the initial stages of UPEC invasion and receptor-mediated bacterial invasion in general.     

Surfactant Protein D Inhibits Adherence of Uropathogenic Escherichia coli to the Bladder Epithelial Cells and the Bacterium-induced Cytotoxicity: A POSSIBLE FUNCTION IN URINARY TRACT*

The adherence of uropathogenic Escherichia coli (UPEC) to the host urothelial surface is the first step for establishing UPEC infection. Uroplakin Ia (UPIa), a glycoprotein expressed on bladder urothelium, serves as a receptor for FimH, a lectin located at bacterial pili, and their interaction initiates UPEC infection. Surfactant protein D (SP-D) is known to be expressed on mucosal surfaces in various tissues besides the lung. However, the functions of SP-D in the non-pulmonary tissues are poorly understood. The purposes of this study were to investigate the possible function of SP-D expressed in the bladder urothelium and the mechanisms by which SP-D functions. SP-D was expressed in human bladder mucosa, and its mRNA was increased in the bladder of the UPEC infection model in mice. SP-D directly bound to UPEC and strongly agglutinated them in a Ca²⁺-dependent manner. Co-incubation of SP-D with UPEC decreased the bacterial adherence to 5637 cells, the human bladder cell line, and the UPEC-induced cytotoxicity. In addition, preincubation of SP-D with 5637 cells resulted in the decreased adherence of UPEC to the cells and in a reduced number of cells injured by UPEC. SP-D directly bound to UPIa and competed with FimH for UPIa binding. Consistent with the in vitro data, the exogenous administration of SP-D inhibited UPEC adherence to the bladder and dampened UPEC-induced inflammation in mice. These results support the conclusion that SP-D can protect the bladder urothelium against UPEC infection and suggest a possible function of SP-D in urinary tract.     

Characteristic of aromatic amino acid substitution at alpha 96 of hemoglobin

Replacement of valine by tryptophan or tyrosine at position alpha96 of the alpha chain (alpha96Val), located in the alpha(1)beta(2) subunit interface of hemoglobin leads to low oxygen affinity hemoglobin, and has been suggested to be due to the extra stability introduced by an aromatic amino acid at the alpha96 position. The characteristic of aromatic amino acid substitution at the alpha96 of hemoglobin has been further investigated by producing double mutant r Hb (alpha42Tyr --> Phe, alpha96Val --> Trp). r Hb (alpha42Tyr --> Phe) is known to exhibit almost no cooperativity in binding oxygen, and possesses high oxygen affinity due to the disruption of the hydrogen bond between alpha42Tyr and beta99Asp in thealpha(1)beta(2) subunit interface of deoxy Hb A. The second mutation, alpha96Val -->Trp, may compensate the functional defects of r Hb (alpha42Tyr --> Phe), if the stability due to the introduction of trypophan at the alpha 96 position is strong enough to overcome the defect of r Hb (alpha42Tyr --> Phe). Double mutant r Hb (alpha42Tyr --> Phe, alpha96Val --> Trp) exhibited almost no cooperativity in binding oxygen and possessed high oxygen affinity, similarly to that of r Hb (alpha42Tyr --> Phe). (1)H NMR spectroscopic data of r Hb (alpha42Tyr --> Phe, alpha96Val --> Trp) also showed a very unstable deoxy-quaternary structure. The present investigation has demonstrated that the presence of the crucible hydrogen bond between alpha 42Tyr and beta 99Asp is essential for the novel oxygen binding properties of deoxy Hb (alpha96Val --> Trp) .     

Binding of hydrophobic D-galactopyranosides to the lactose permease of Escherichia coli

Binding of alpha- and beta-D-galactopyranosides with different hydrophobic aglycons was compared using substrate protection against N-ethylmaleimide alkylation of single-Cys148 lactose permease. As demonstrated previously, methyl- or allyl-substituted alpha-D-galactopyranosides exhibit a 60-fold increase in binding affinity (K(D) = 0.5 mM), relative to galactose (K(D) = 30 mM), while methyl beta-D-galactopyranoside binds only 3-fold better. In the present study, galactopyranosides with cyclohexyl or phenyl substitutions, both in alpha and beta anomeric configurations, were synthesized. Surprisingly, relative to methyl alpha-D-galactopyranoside, binding of cyclohexyl alpha-D-galactopyranoside to lactose permease is essentially unchanged (K(D) = 0.4 mM), and phenyl alpha-D-galactopyranoside exhibits only a modest increase in binding affinity (K(D) = 0.15 mM). Nitro- or methyl-substituted phenyl alpha-D-galactopyranosides bind with significantly higher affinities (K(D) = 0.014-0.067 mM), and the strongest binding is observed with analogues containing para substituents. In contrast, D-galactopyranosides with a variety of large hydrophobic substituents (isopropyl, cyclohexyl, phenyl, o- or p-nitrophenyl) in beta anomeric configuration exhibit uniformly weak binding (K(D) = 1.0-2.3 mM). The results confirm and extend previous observations that hydrophobic aglycons of D-galactopyranosides increase binding affinity, with a clear predilection toward alpha-substituted sugars. In addition, the data suggest that the primary interaction between the permease and hydrophobic aglycons is directed toward the carbon atom bonded to the anomeric oxygen. The different positioning of this carbon atom in alpha- or beta-D-galactopyranosides thus may provide a rationale for the characteristic binding preference of the permease for alpha anomers.     

Clathrin, AP-2, and the NPXY-binding subset of alternate endocytic adaptors facilitate FimH-mediated bacterial invasion of host cells

The FimH adhesin, localized at the distal tips of type 1 pili, binds mannose-containing glycoprotein receptors like alpha3beta1 integrins and stimulates bacterial entry into target host cells. Strains of uropathogenic Escherichia coli (UPEC), the major cause of urinary tract infections, utilize FimH to invade bladder epithelial cells. Here we set out to define the mechanism by which UPEC enters host cells by investigating four of the major entry routes known to be exploited by invasive pathogens: caveolae, clathrin, macropinocytosis and secretory lysosomes. Using pharmacological inhibitors in combination with RNA interference against specific endocytic pathway components, mutant host cell lines and a mouse infection model system, we found that type 1 pili-dependent bacterial invasion of host cells occurs via a cholesterol- and dynamin-dependent phagocytosis-like mechanism. This process did not require caveolae or secretory lysosomes, but was modulated by calcium levels, clathrin, and cooperative input from the primary clathrin adaptor AP-2 and a subset of alternate adaptors comprised of Numb, ARH and Dab2. These alternate clathrin adaptors recognize NPXY motifs, as found within the cytosolic tail of beta1 integrin, suggesting a functional link between the engagement of integrin receptors by FimH and the clathrin-dependent uptake of type 1-piliated bacteria.     

Binding of para-substituted phenyl glycosides to concanavalin A

The binding of para-substituted phenyl glycopyranosides of α-D-glucose, β-D-glucose, and α-D-mannose by concanavalin A has been related to the electronic and hydrophobic nature of the substituents by multiparameter regression analysis. Hydrophobicity is an important factor for the binding of the β-D-glucosides, especially in the p-alkyl series; a smaller but mutually comparable dependence on hydrophobicity is noted for each of the p-halogeno, p-alkoxy, and p-acyl substituent series. In the last two series, an additional substituent interaction with the protein might occur. The more tightly bound α-D-mannosides and α-D-glucosides show a constant binding ratio for all p-phenyl substituents. Here, hydrophobic contributions are negligible when compares with electronic effects. Hammett relations (p?= 0.5) are valid for α-D-glucosides and α-D-mannosides, and can be improved by considering inductive and mesomeric contributions of the substituents. These observations are compatible with crystallographic data at a resolution of 2 Å. Their relevance for the α-D-anomeric specificity, governed by a protein electrophile, is discussed.     

Integrin-mediated host cell invasion by type 1-piliated uropathogenic Escherichia coli

Uropathogenic Escherichia coli (UPEC), the primary causative agent of urinary tract infections, typically express filamentous adhesive organelles called type 1 pili that mediate both bacterial attachment to and invasion of bladder urothelial cells. Several host proteins have previously been identified as receptors for type 1 pili, but none have been conclusively shown to promote UPEC entry into host bladder cells. Using overlay assays with FimH, the purified type 1 pilus adhesin, and mass spectroscopy, we have identified beta1 and alpha3 integrins as key host receptors for UPEC. FimH recognizes N-linked oligosaccharides on these receptors, which are expressed throughout the urothelium. In a bladder cell culture system, beta1 and alpha3 integrin receptors co-localize with invading type 1-piliated bacteria and F-actin. FimH-mediated bacterial invasion of host bladder cells is inhibited by beta1 and alpha3 integrin-specific antibodies and by disruption of the beta1 integrin gene in the GD25 fibroblast cell line. Phosphorylation site mutations within the cytoplasmic tail of beta1 integrin that alter integrin signaling also variably affect UPEC entry into host cells, by either attenuating or boosting invasion frequencies. Furthermore, focal adhesion and Src family kinases, which propagate integrin-linked signaling and downstream cytoskeletal rearrangements, are shown to be required for FimH-dependent bacterial invasion of target host cells. Cumulatively, these results indicate that beta1 and alpha3 integrins are functionally important receptors for type 1 pili-expressing bacteria within the urinary tract and possibly at other sites within the host.     

Tyrosine phosphorylation of the well packed ephrinB cytoplasmic beta-hairpin for reverse signaling. Structural consequences and binding properties

Tyrosine phosphorylation of the 22-residue cytoplasmic region of ephrinB induces its binding to the SH2 domain of Grb4, thus initiating reverse signaling pathways controlling cytoskeleton assembly and remodeling. Recently, the region corresponding to this 22-residue motif was demonstrated to adopt a well packed beta-hairpin structure with a high conformational stability in the unphosphorylated cytoplasmic subdomain. However, because the binding to Grb4 is phosphorylation-dependent and the hairpin contains three conserved tyrosine residues that may be phosphorylated, the key events remain unknown as to how tyrosine phosphorylation affects the structure of this well packed beta-hairpin and which phosphorylation site is relevant to SH2 domain binding. By characterizing the structural and binding properties of six 22-residue SH2 domain-binding motifs with different phosphorylated sites, the present study reveals that, as shown by circular dichroism and NMR, the unphosphorylated 22-residue motif adopts a well formed beta-hairpin structure in isolation from the ephrinB cytoplasmic subdomain. However, this beta-hairpin is radically abolished by tyrosine phosphorylation, regardless of the relative location and number of Tyr residues. Unexpectedly, the peptides with either Tyr304 or Tyr316 phosphorylated show high affinity binding to SH2 domain, whereas the peptide with Tyr311 phosphorylated has no detectable binding. This implies that ephrinB with Tyr311 phosphorylated might have a currently unidentified binding partner distinct from the Grb4 protein, because Tyr311 is known to be phosphorylated in vivo. Based on the results above, it is thus proposed that the disruption of the tight side-chain packing by tyrosine phosphorylation in the well structured region of a signaling protein may represent a general activation mechanism by which a cryptic binding site is disclosed for new protein-protein interactions.     

Substrate distortion in the Michaelis complex of Bacillus 1,3-1,4-beta-glucanase. Insight from first principles molecular dynamics simulations

The structure and dynamics of the enzyme-substrate complex of Bacillus 1,3-1,4-beta-glucanase, one of the most active glycoside hydrolases, is investigated by means of Car-Parrinello molecular dynamics simulations (CPMD) combined with force field molecular dynamics (QM/MM CPMD). It is found that the substrate sugar ring located at the -1 subsite adopts a distorted 1S3 skew-boat conformation upon binding to the enzyme. With respect to the undistorted 4C1 chair conformation, the 1S3 skew-boat conformation is characterized by: (a) an increase of charge at the anomeric carbon (C1), (b) an increase of the distance between C1 and the leaving group, and (c) a decrease of the intraring O5-C1 distance. Therefore, our results clearly show that the distorted conformation resembles both structurally and electronically the transition state of the reaction in which the substrate acquires oxocarbenium ion character, and the glycosidic bond is partially broken. Together with analysis of the substrate conformational dynamics, it is concluded that the main determinants of substrate distortion have a structural origin. To fit into the binding pocket, it is necessary that the aglycon leaving group is oriented toward the beta region, and the skew-boat conformation naturally fulfills this premise. Only when the aglycon is removed from the calculation the substrate recovers the all-chair conformation, in agreement with the recent determination of the enzyme product structure. The QM/MM protocol developed here is able to predict the conformational distortion of substrate binding in glycoside hydrolases because it accounts for polarization and charge reorganization at the -1 sugar ring. It thus provides a powerful tool to model E.S complexes for which experimental information is not yet available.     

A Method for the Purification of Phospho(Tyr)calmodulin Free of Nonphosphorylated Calmodulin

Phosphocalmodulin has been shown to have a differential biological activity compared to nonphosphorylated calmodulin when assayed on a variety of calmodulin-dependent systems. However, the phosphocalmodulin preparations used so far in those experiments were not necessarily free of nonphosphorylated calmodulin. Therefore, the results obtained may not unquestionably show the real effect of pure phosphocalmodulin on the systems under study. To solve this problem, we describe here a method for the purification of phospho(Tyr)calmodulin free of nonphosphorylated calmodulin. The procedure consists of the following steps: (i) phosphorylation of calmodulin by a fraction enriched in epidermal growth factor receptor tyrosine kinase from rat liver isolated by calmodulin affinity chromatography, (ii) isolation of a calmodulin/phosphocalmodulin mixture by Ca(2+)-dependent chromatography in phenyl-Sepharose, (iii) purification of phospho(Tyr)calmodulin using an anti-phosphotyrosine antibody immobilized in agarose upon elution with phenyl phosphate, and (iv) removal of phenyl phosphate from the phospho(Tyr)calmodulin preparation by filtration chromatography in a Bio-Gel P-2 column. The obtained phospho(Tyr)calmodulin preparation was highly pure and essentially free of nonphosphorylated calmodulin because of the use of anti-phosphotyrosine affinity chromatography. We demonstrate that this ultrapure phospho(Tyr)calmodulin preparation is totally incapable of activating the calmodulin-dependent cyclic nucleotide phosphodiesterase. In contrast, when a nonpurified phospho(Tyr)calmodulin preparation was used a partial activation of this enzyme was observed.     

Sugar binding in lactose permease: anomeric state of a disaccharide influences binding structure

Lactose permease in Escherichia coli (LacY) transports both anomeric states of disaccharides but has greater affinity for α-sugars. Molecular dynamics (MD) simulations are used to probe the protein-sugar interactions, binding structures, and global protein motions in response to sugar binding by investigating LacY (the experimental mutant and wild-type) embedded in a fully hydrated lipid bilayer. A total of 12 MD simulations of 20-25 ns each with β(α)-d-galactopyranosyl-(1,1)-β-d-galactopyranoside (ββ-(Galp)₂) and αβ-(Galp)₂ result in binding conformational families that depend on the anomeric state of the sugar. Both sugars strongly interact with Glu126 and αβ-(Galp)₂ has a greater affinity to this residue. Binding conformations are also seen that involve protein residues not observed in the crystal structure, as well as those involved in the proton translocation (Phe118, Asn119, Asn240, His322, Glu325, and Tyr350). Common to nearly all protein-sugar structures, water acts as a hydrogen bond bridge between the disaccharide and protein. The average binding energy is more attractive for αβ-(Galp)₂ than ββ-(Galp)₂, i.e. −10.7(±0.7) and −3.1(±1.0) kcal/mol, respectively. Of the 12 helices in LacY, helix-IV is the least stable with ββ-(Galp)₂ binding resulting in larger distortion than αβ-(Galp)₂.     

Synthesis and evaluation of thiomannosides,potent and orally active FimH inhibitors

FimH is a type I fimbrial lectin located at the tip of type-1 pili of Gram-negative uropathogenic Escherichia coli (UPEC) guiding its ability to adhere and infect urothelial cells. Accordingly, blocking FimH with small molecule inhibitor is considered as a promising new therapeutic alternative to treat urinary tract infections caused by UPEC. Herein, we report that compounds having the S-glycosidic bond (thiomannosides) had improved metabolic stability and plasma exposures when dosed orally. Especially compound 5h showed the potential to inhibit biofilm formation and also to disrupt the preformed biofilm. And compound 5h showed prophylactic effect in UTI model in mice.     

Quantitative Study of Anomeric Forms of Glucose Produced by α-Glucosidases and Glucoamylases

A gas-liquid chromatographic method was applied to the determination of anomeric forms of sugar produced by carbohydrases. Anomeric forms of glucose released from maltotriose, phenyl α-maltoside and phenyl α-glucoside were determined quantitatively. Thirteen α-glucosidases tested, including α-glucosidase from honey bee and acid α-glucosidase from pig′s liver, were found to produce α-glucose exclusively, and two kinds of glucoamylases, only β-glucose. This method proved very useful for the determination of the anomeric forms of sugar produced. It was confirmed that mammalian acid α-glucosidase does not belong to the category of exo-1,4-α-glucosidase (EC 3.2.1.3).     

Role of tyrosine hot‐spot residues at the interface of colicin E9 and immunity protein 9: A comparative free energy simulation study

The endonuclease activity of the bacterial colicin 9 enzyme is controlled by the specific and high‐affinity binding of immunity protein 9 (Im9). Molecular dynamics simulation studies in explicit solvent were used to investigate the free energy change associated with the mutation of two hot‐spot interface residues [tyrosine (Tyr): Tyr54 and Tyr55] of Im9 to Ala. In addition, the effect of several other mutations (Leu33Ala, Leu52Ala, Val34Ala, Val37Ala, Ser48Ala, and Ile53Ala) with smaller influence on binding affinity was also studied. Good qualitative agreement of calculated free energy changes and experimental data on binding affinity of the mutations was observed. The simulation studies can help to elucidate the molecular details on how the mutations influence protein–protein binding affinity. The role of solvent and conformational flexibility of the partner proteins was studied by comparing the results in the presence or absence of solvent and with or without positional restraints. Restriction of the conformational mobility of protein partners resulted in significant changes of the calculated free energies but of similar magnitude for isolated Im9 and for the complex and therefore in only modest changes of binding free energy differences. Although the overall binding free energy change was similar for the two Tyr–Ala mutations, the physical origin appeared to be different with solvation changes contributing significantly to the Tyr55Ala mutation and to a loss of direct protein–protein interactions dominating the free energy change due to the Tyr54Ala mutation. Proteins 2013. © 2012 Wiley Periodicals, Inc.     

Functional implications of the proximal site hydrogen bonding network in Vitreoscilla hemoglobin (VHb): role of Tyr95 (G5) and Tyr126 (H12)

Although Vitreoscilla hemoglobin (VHb) carries a conventional globin fold, its proximal site geometry is unique in having a hydrogen-bonding network between proximal site residues, HisF8-TyrG5-GluH23 and TyrG5-TyrH12. TyrG5 and TyrH12 were mutated to study their relevance in VHb function. VHb G5 mutants (Tyr95Phe and Tyr95Leu showed no stable oxyform and nitric oxide dioxygenase activity, whereas, VHb H12 mutants (Tyr126Phe and Tyr126Leu) displayed little change in their oxygen affinity indicating a crucial role of Tyr95 in protein function. The VHb H12 mutant, Tyr126Leu, enhanced the intracellular pool of oxygen and cell growth better than VHb. Molecular modeling suggests that the replacement of tyrosine with leucine in Tyr126Leu creates an opening on the protein surface that may facilitate oxygen diffusion and accumulation.     

Modulating catalytic activity by unnatural amino acid residues in a GSH-binding loop of GST P1-1

The loop following helix α2 in glutathione transferase P1-1 has two conserved residues, Cys48 and Tyr50, important for glutathione (GSH) binding and catalytic activity. Chemical modification of Cys48 thwarts the catalytic activity of the enzyme, and mutation of Tyr50 generally decreases the k_cat value and the affinity for GSH in a differential manner. Cys48 and Tyr50 were targeted by site-specific mutations and chemical modifications in order to investigate how the α2 loop modulates GSH binding and catalysis. Mutation of Cys48 into Ala increased K_M^GSH 24-fold and decreased the binding energy of GSH by 1.5 kcal/mol. Furthermore, the protein stability against thermal inactivation and chemical denaturation decreased. The crystal structure of the Cys-free variant was determined, and its similarity to the wild-type structure suggests that the mutation of Cys48 increases the flexibility of the α2 loop rather than dislocating the GSH-interacting residues. On the other hand, replacement of Tyr50 with Cys, producing mutant Y50C, increased the Gibbs free energy of the catalyzed reaction by 4.8 kcal/mol, lowered the affinity for S-hexyl glutathione by 2.2 kcal/mol, and decreased the thermal stability. The targeted alkylation of Cys50 in Y50C increased the affinity for GSH and protein stability. Characterization of the most active alkylated variants, S-n-butyl-, S-n-pentyl-, and S-cyclobutylmethyl-Y50C, indicated that the affinity for GSH is restored by stabilizing the α2 loop through positioning of the key residue into the lock structure of the neighboring subunit. In addition, k_cat can be further modulated by varying the structure of the key residue side chain, which impinges on the rate-limiting step of catalysis.