C-terminus loop 13 of Na+ glucose cotransporter SGLT1 contains a binding site for alkyl glucosides

Recently, we identified the extramembranous C-terminus loop 13 of SGLT1 as a binding site for the aromatic glucoside phlorizin, which competitively inhibits sodium D-glucose cotransport. Alkyl glucosides are also competitive inhibitors of the transport. Therefore, in this study, we searched for potential binding sites for alkyl glucosides in loop 13. To this end, we synthesized a photoaffinity label (2'-Azi-n-octyl)-beta-D-glucoside and analyzed the region of attachment using MALDI mass spectrometry, producing wild-type recombinant truncated loop 13. Furthermore, we prepared four single-Trp mutants of the loop and determined their fluorescence, its change in the presence of alkyl glucosides, and their accessibility to acrylamide. Photolabeling of truncated loop 13 with (2'-Azi-n-octyl)-beta-D-glucoside revealed an attachment of the C2 group of the alkyl chain to Gly-Phe-Phe-Arg (amino acid residues 598-601). In the presence of n-hexyl-beta-D-glucoside, all mutants (R601W, D611W, E621W, and L630W) exhibited a significant decrease in Trp fluorescence with an apparent binding affinity of 8-14 microM. Only L630W exhibited a significant blue shift, and only in R601W was a change in acrylamide quenching (protection) observed. No quenching or protection was found for D-glucose; however, 1-hexanol produced the same results as n-hexyl-beta-D-glucoside. The interaction shows stereoselectivity for n-hexyl-beta-D-glucoside binding; the beta-configuration of the sugar moiety at C1, the cis conformation of the unsaturated alkenyl side chain in the C3-C4 bond, and the alkyl chain length of six to eight carbon atoms lead to an optimum interaction. A schematic two-dimensional model was derived in which C2 interacts with the region around residue 601, C3 and C4 interact with the region between residues 614 and 619, and C6-C8 interact with the region between residues 621 and 630. The data demonstrate that loop 13 provides binding sites for alkyl glucosides as well as for phlorizin; thus, loop 13 of SGLT1 seems to be a major binding domain for the aglucone residues of competitive D-glucose transport inhibitors.     

Binding of phlorizin to the isolated C-terminal extramembranous loop of the Na+/glucose cotransporter assessed by intrinsic tryptophan fluorescence

Phlorizin, a phloretin 2'-glucoside, is a potent inhibitor of the Na(+)/glucose cotransporter (SGLT1). On the basis of transport studies in intact cells, a binding site for phlorizin was suggested in the region between amino acids 604-610 of the C-terminal loop 13. To further investigate phlorizin binding titration experiments of the intrinsic Trp fluorescence of isolated wild-type loop 13 and two mutated loops (Y604K and G609K) were carried out. Phlorizin (135 microM) produced approximately 40% quenching of the fluorescence of wild-type loop 13; quenching could also be observed with the two mutated loops. The apparent K(d) was lowest for the wild-type loop 13 (K(d) approximately 23 microM), followed by mutant G609K (57 microM) and mutant Y604K (70 microM). Binding of phlorizin was further confirmed by a decrease of the accessibility of loop 13 to the collisional quencher acrylamide. The interaction involves the aromatic moiety of the aglucone since phloretin (the aglucone of phlorizin) showed almost the same effects as phlorizin, while d-glucose did not. MALDI-TOF experiments revealed that loop 13 contained a disulfide bond between Cys 560 and Cys 608 that is very important for phlorizin-dependent fluorescence quenching. These studies provide direct evidence that loop 13 is a site (important amino acids including 604-609) for the molecular interaction between SGLT1 and phlorizin. They confirm that the aglucone part of the glucoside is responsible for this interaction.     

D-Glucose-recognition and phlorizin-binding sites in human sodium/D-glucose cotransporter 1 (hSGLT1): a tryptophan scanning study

In order to gain a better understanding of the structure-function relation in hSGLT1, single Trp residues were introduced into a functional hSGLT1 mutant devoid of Trps at positions that previously had been postulated to be involved in sugar recognition/translocation and/or phlorizin binding. The mutant proteins were expressed in Pichia pastoris, purified, and reconstituted into liposomes. In transport experiments the putative sugar binding site mutants W457hSGLT1 and W460hSGLT1 showed a drastic decrease in affinity toward alpha-methyl-d-glucopyranoside with Km values of 13.3 and 5.26 mM compared to 0.4 mM of the Trp-less hSGLT1. In addition, a strong decrease in the inhibitory effect of phlorizin was observed. In Trp fluorescence studies the position of the emission maxima of the mutants, their sensitivity to N-bromosuccinimide oxidation, and their interaction with water soluble quenchers demonstrate that Trp457 and Trp460 are in contact with the hydrophilic extravesicular environment. In both mutants Trp fluorescence was quenched significantly, but differently, by various glucose analogues. They also show significant protection by d-glucose and phlorizin against acrylamide, KI, or TCE quenching. W602hSGLT1 and W609hSGLT1, the putative aglucone binding site mutants, exhibit normal sugar and phlorizin affinity, and show fluorescence properties which indicate that these residues are located in a very hydrophilic environment. Phlorizin and phloretin, but not d-glucose, protect both mutants against collisional quenchers. Depth-calculations using the parallax method suggest a location of Trp457 and Trp460 at an average distance of 10.8 A and 7.4 A from the center of the bilayer, while Trp602 and Trp609 are located outside the membrane. These results suggest that in the native carrier residues Gln at position 457 and Thr at position 460 reside in a hydrophilic access pathway extending 5-7 A into the membrane to which sugars as well as the sugar moiety of inhibitory glucosides bind. Residues Phe602 and Phe609 contribute by their hydrophobic aromatic residues toward binding of the aglucone part of phlorizin. Thereby in the phlorizin-carrier complex a close vicinity between these two subdomains of the transporter is established creating a phlorizin binding pocket with the previously estimated dimensions of 10 x 17 x 7 A.     

Interaction of C-terminal loop 13 of sodium-glucose cotransporter SGLT1 with lipid bilayers

We have previously shown that C-terminal loop 13 of SGLT1 acts as a major binding domain for the aglucon residues of d-glucose transport inhibitors, phlorizin (Raja, M. M., Tyagi, N. K., and Kinne, R. K. H. (2003) Phlorizin Recognition in a C-terminal Fragment of SGLT1 Studied by Tryptophan Scanning and Affinity Labeling, J. Biol. Chem. 278, 49154-49163) and alkyl glucosides (Raja, M. M., Kipp, H., and Kinne, R. K. H. (2004) C-Terminus Loop 13 of Na(+) Glucose Cotransporter SGLT1 Contains a Binding Site for Alkyl Glucosides, Biochemistry 43, 10944-10951). Topology of this loop with regard to the membrane lipids is hitherto a point of debate. Here we report on in vitro incorporation studies using fluorescence of Trp mutants of loop 13 to determine the position of various parts of the loop with the lipid bilayer. Six single Trp mutants were prepared as described in previous studies (Raja et al., 2003) and subsequently incorporated into DOPC:DOPG (60:40% molar ratio) lipid vesicles. Upon addition of the phospholipids only one mutant, R601W, exhibited no change in the fluorescence intensities, position of maxima, or acrylamide accessibility. Mutants Q581W, E621W, and L630W exhibited the most pronounced blue shifts (3-6 nm) and protection against acrylamide, suggesting a position of these segments within the lipid bilayer. This assumption was confirmed by the result that the fluorescence of only these mutants was quenched by doxyl spin membrane embedded labels in the 5- or 12-positions of the acyl side chain of phospholipids. The other parts of the peptide appear to remain outside of the lipid vesicles. Trp-591 and Trp-611 showed, although to a different extent, increase in fluorescence, blue shift of maxima, and decrease in acrylamide accessibility but no interaction with the spin-labeled phospholipids. This suggests changes in the conformation of the peptide itself. These conformation changes are probably induced by the interaction of an adjacent lysine rich region of the peptide with the negatively charged DOPG, since in the absence of this lipid no incorporation of loop 13 into the bilayer is observed. Trypsin cleavage experiments of loop 13 in proteoliposomes yield a peptide containing amino acid residues 603 to 614, confirming that this part of the loop is accessible at the extravesicular face of the membranes. The studies show that at least in the in vitro system the part of loop 13 essential for the interaction with the transport inhibitors is located extracellularly, making a similar arrangement in the intact SGLT1 probable.     

Role of hydration in the conformational transitions between unliganded and liganded forms of loop 13 of the Na+/glucose cotransporter 1

SGLT1 as a Na+/glucose cotransporter is inhibited by phlorizin, a phloretin 2'-glucoside that has strong interactions with the C-terminal loop 13 (residues 541-638). Here we investigated the effect of a partial substitution of glycerol for water in the medium on the stability and phlorizin-binding function of loop 13 using fluorescence spectroscopy. Increasing the glycerol concentration promoted an increase in the stability of the protein to urea. The ability of loop 13 to expose hydrophobic surface promoted by phlorizin binding was partially lost in the presence of glycerol (20%). Glycerol also led to a decrease in the phlorizin affinity of loop 13 in solution. Approximately 15 molecules of water were taken up to cover additional surface area (137.7+/-27.9A(2)) upon formation of the loop 13-phlorizin complex. Together these results demonstrate quantitatively that the stability and phlorizin affinity of loop 13 are critically dependent on protein hydration.     

Structural and Functional Properties of the Membranotropic HIV-1 Glycoprotein gp41 Loop Region Are Modulated by Its Intrinsic Hydrophobic Core

The gp41 disulfide loop region switches from a soluble state to a membrane-bound state during the human immunodeficiency virus type 1 (HIV-1) envelope-mediated membrane fusion process. The loop possesses a hydrophobic core at the center of the region with an unusual basic residue (Lys-601). Furthermore, two loop core mutations, K601A and L602A, are found to inhibit HIV-1 infectivity while keeping wild type-like levels of the envelope, implying that they exert an inhibitory effect on gp41 during the membrane fusion event. Here, we investigated the mode of action of these mutations on the loop region. We show that the K601A mutation, but not the L602A mutation, abolished the binding of a loop-specific monoclonal antibody to a loop domain peptide. Additionally, the K601A, but not the L602A, impaired disulfide bond formation in the peptides. This was correlated with changes in the circular dichroism spectrum imposed by the K601A mutation. In the membrane, however, the L602A, but not the K601A, reduced the lipid mixing ability of the loop peptides, which was correlated with decreased α-helical content of the L602A mutant. The results suggest that the Lys-601 residue provides a moderate hydrophobicity level within the gp41 loop core that contributes to the proper structure and function of the loop inside and outside the membrane. Because basic residues are found between the loop Cys residues of several lentiviral fusion proteins, the findings may contribute to understanding the fusion mechanism of other viruses as well.     

Tryptophan at position 181 of the D2 protein of photosystem II confers quenching of variable fluorescence of chlorophyll: implications for the mechanism of energy-dependent quenching.

The lumenal CD loop region of the D2 protein of photosystem II contains residues that interact with a reaction center chlorophyll and the redox-active Tyr(D). Using combinatorial mutagenesis, photoautotrophic mutants of Synechocystis sp. PCC 6803 have been generated with multiple amino acid changes in this region. The CD loop mutations were transferred into a photosystem I-less Synechocystis strain to facilitate characterization of photosystem II properties in the mutants. Most of the combinatorial photosystem I-less mutants obtained had a high yield of variable fluorescence, F(V). However, in three mutants, which shared a replacement of Phe181 by Trp, the F(V) yield was dramatically reduced although a high rate of oxygen evolution was maintained. A site-directed F181W D2 mutant shared similar properties. Picosecond time-resolved fluorescence measurements revealed that in the combinatorial F181W mutants the fluorescence lifetimes in closed and open photosystem II centers were essentially identical and were similar to the fluorescence lifetime in open centers of the control strain. These results are explained by quenching of variable fluorescence in the mutants by charge separation between Trp181 and excited reaction center chlorophyll. This reaction competes efficiently with fluorescence and nonradiative decay in closed photosystem II centers, where the lifetime of the excitation in the chlorophyll antenna is long. Thermodynamic considerations favor the formation of oxidized tryptophan and reduced chlorophyll in the quenching reaction, presumably followed by charge recombination. A possible role of tryptophan-chlorophyll charge separation in the mechanism of energy-dependent quenching of excitations in photosynthesis is discussed.     

Alanine scanning mutants of the HIV gp41 loop

Based on mutagenesis and structural studies of human immunodeficiency virus (HIV) envelope proteins, the loop region of gp41 is thought to directly interact with gp120. The importance of the HIV gp41 loop region to envelope function has been systematically examined by alanine scanning of all gp41 loop residues and the subsequent characterization of the mutagenic effects on viral entry, envelope expression, envelope processing, and gp120 association with gp41. With respect to the wild-type gp41, mutational effects on viral entry fall into four classes as follows: 1) little or no effect (G594A, S599A, G600A, K601A, N611A, S615A, N616A, and L619A); 2) significantly reduced entry (I595A, L602A, I603A, V608A, and K617A); 3) abolished entry (L593A, W596A, G597A, T606A, W610A, W614A, S618A, and I622A); and 4) enhanced entry (T605A, P609A, S613A, E620A, and Q621A). The reduced functionality of many mutants was apparently due to either disruption of envelope processing (L593A and T606A), viral incorporation of the envelope (W610A, W614A, and I662A), or increased dissociation of gp120 (W596A, G597A, and S618A). The extreme sensitivity of the gp120-gp41 interaction to alanine substitutions (e.g. the G597A and S618A mutants are relatively conservative substitutions) suggests that this association is an attractive and novel target for future drug discovery efforts.     

Analysis of antibody A6 binding to the extracellular interferon gamma receptor alpha-chain by alanine-scanning mutagenesis and random mutagenesis with phage display

The monoclonal antibody A6 binds a conformational epitope comprising mainly the CC' surface loop on the N-terminal fibronectin type-III domain of the extracellular interferon gamma receptor (IFNgammaR). The crystal structure of an A6 Fab-IFNgammaR complex revealed an interface rich in the aromatic side chains of Trp, Tyr, and His residues. These aromatic side chains appear to interact with both polar and hydrophobic groups at the interface, a property which, in general, may be advantageous for ligand binding. To analyze these interactions in more detail, the affinities of 19 A6 alanine-scanning mutants for the IFNgammaR have been measured, using engineered A6 single chain variable region fragments, and a surface plasmon resonance biosensor. Energetically important side chains (DeltaG(mutant) - DeltaG(wt) > 2.4 kcal/mol), that form distinct hot spots in the binding interface, have been identified on both proteins. These include V(L)W92 in A6, whose benzenoid ring appears well situated for a pi-cation (or pi-amine) interaction with the side chain of receptor residue K47 and simultaneously for T-stacking onto the indole ring of W82 in the receptor. At another site, energetically important residues V(H)W52 and V(H)W53, as well as V(H)D54 and V(H)D56, surround the aliphatic side chain of the hot receptor residue K52. Taken together, the results show that side chains distributed across the interface, including many aromatic ones, make key energetic contributions to binding. In addition, the receptor CC' loop has been subjected to random mutagenesis, and receptor mutants with high affinity for A6 have been selected by phage display. Residues previously identified as important for receptor binding to A6 were conserved in the clones isolated. Some mutants, however, showed a much improved affinity for A6, due to changes at Glu55, a residue that appeared to be energetically unimportant for binding the antibody by alanine-scanning mutagenesis. An E55P receptor mutant bound A6 with a 600-fold increase in affinity (K(D) approximately 20 pM), which is one of the largest improvements in affinity from a single point mutation reported so far at any protein-protein interface.     

Lipid binding of the exchangeable apolipoprotein apolipophorin III induces major changes in fluorescence properties of tryptophans 115 and 130

The effect of lipid association on the local environment of the two tryptophan residues of Locusta migratoria apolipophorin III (apoLp-III) has been studied. In the lipid-free state, Trp115 in helix 4 is buried in the hydrophobic interior of the helix bundle, while Trp130 is located in a loop connecting helices 4 and 5. Fluorescence spectroscopy of single Trp mutants revealed an emission maximum (lambda(max)) of 321 nm for apoLp-III-W@115 (excitation 280 nm) which red-shifted to 327 nm upon binding to dimyristoylphosphatidylcholine (DMPC). ApoLp-III-W@130 displayed a lambda(max) of 338 nm while interaction with DMPC resulted in a blue shift to 331 nm. Quenching studies with KI and acrylamide revealed decreased accessibility to Trp115 compared to Trp130, while lipid binding induced a decrease in quenching of Trp130. Aromatic circular dichroism (CD) spectra showed that Trp vibronic transitions at 278, 286, and 294 nm for lipid-free apoLp-III were caused by Trp115. Upon lipid association, aromatic extrema are reversed in sign, becoming entirely negative with both Trp residues contributing to the vibronic transitions, implying restriction in side-chain mobility of these residues. Thus, lambda(max), quencher accessibility, and aromatic CD analysis indicate that Trp115 is much less solvent-exposed than Trp130. Differences in fluorescence properties of these residues are minimized in the lipid-bound state, a result of relocation of Trp115 and Trp130 into the lipid milieu. Thus, in addition to the hydrophobic faces of apoLp-III amphipathic alpha-helices, the loop region containing Trp130 comes in close contact with DMPC.     

Influence of conformation on the fluorescence of tryptophan-containing peptides

Conformational-energy calculations of the zwitterionic forms of Trp, Gly-Trp, Pro-Trp, Phe-Trp, Trp-Gly, Trp-Phe, Trp-Trp, and Trp-Gly-Gly were done using an empirical energy program for peptides (ECEPP). The resulting low-energy conformations were analyzed for the presence of hydrogen bonds, the distances between carbonyl groups and the indole ring, the distances between the N-terminal amino group and the indole ring, the dihedral angle between the planes containing carbonyl groups and the indole ring, and for dipeptides with two aromatic side chains, the dihedral angle and distance between the planes of the aromatic rings. This information was correlated with literature data from x-ray crystallographic studies, fluorescence lifetime studies, and quantum-yield experiments; proposed models of intramolecular quenching are discussed in light of the peptide conformations.     

Probing folding and fluorescence quenching in human gammaD crystallin Greek key domains using triple tryptophan mutant proteins

Human gammaD crystallin (HgammaD-Crys), a major component of the human eye lens, is a 173-residue, primarily beta-sheet protein, associated with juvenile and mature-onset cataracts. HgammaD-Crys has four tryptophans, with two in each of the homologous Greek key domains, which are conserved throughout the gamma-crystallin family. HgammaD-Crys exhibits native-state fluorescence quenching, despite the absence of ligands or cofactors. The tryptophan absorption and fluorescence quenching may influence the lens response to ultraviolet light or the protection of the retina from ambient ultraviolet damage. To provide fluorescence reporters for each quadrant of the protein, triple mutants, each containing three tryptophan-to-phenylalanine substitutions and one native tryptophan, have been constructed and expressed. Trp 42-only and Trp 130-only exhibited fluorescence quenching between the native and denatured states typical of globular proteins, whereas Trp 68-only and Trp 156-only retained the anomalous quenching pattern of wild-type HgammaD-Crys. The three-dimensional structure of HgammaD-Crys shows Tyr/Tyr/His aromatic cages surrounding Trp 68 and Trp 156 that may be the source of the native-state quenching. During equilibrium refolding/unfolding at 37 degrees C, the tryptophan fluorescence signals indicated that domain I (W42-only and W68-only) unfolded at lower concentrations of GdnHCl than domain II (W130-only and W156-only). Kinetic analysis of both the unfolding and refolding of the triple-mutant tryptophan proteins identified an intermediate along the HgammaD-Crys folding pathway with domain I unfolded and domain II intact. This species is a candidate for the partially folded intermediate in the in vitro aggregation pathway of HgammaD-Crys.     

Ligand-binding effects on the kringle 4 domain from human plasminogen: a study by laser photo-CIDNP 1H-NMR spectroscopy

Photo-chemically induced dynamic nuclear polarization (photo-CIDNP) one-dimensional and two-dimensional (2D) 1H-NMR techniques have been applied to the study of the kringle 4 domain of human plasminogen both ligand-free and complexed to the antifibrinolytic drugs epsilon-aminocaproic acid and p-benzylaminesulfonic acid (BASA). A number of aromatic side-chains (His3, Trp72, Tyr41, Tyr50 and Tyr74) appear to be exposed and accessible to 3-N-carboxymethyl-lumiflavin, the photopolarizing flavin dye, both in the presence and in the absence of ligands. A lesser exposure is observed for the Trp25 and Trp62 indole groups in the presence of BASA. The spin-spin (J-coupling) and dipolar (Overhauser) connectivities in the 2D experiments afford absolute assignment of aromatic resonances for the above residues, as well as of those stemming from the Trp72 ring in the presence of BASA. Moreover, a number of H beta resonances can be identified and sorted according to specific types of amino acid residues.     

Mutation of the aromatic amino acid interacting with adenine moiety of ATP to a polar residue alters the properties of multidrug resistance protein 1

Structural analyses of several bacterial ATP-binding cassette (ABC) transporters indicate that an aromatic amino acid residue in a nucleotide-binding domain (NBD) interacts with the adenine ring of the bound ATP and contributes to the ATP binding. Substitution of this aromatic residue with a polar serine residue in bacterial histidine transporter completely abolished both ATP binding and ATP-dependent histidine transport. However, substitution of the aromatic amino acid residue in the human cystic fibrosis transmembrane conductance regulator with a polar cysteine residue did not have any effect on the ATP-dependent chloride channel function of the protein. To determine whether the other eucaryotic ABC transporters use the strategy analogous to that in some bacterial ABC transporters, the aromatic Trp653 residue in NBD1 and the Tyr1302 residue in NBD2 of human multidrug resistance-associated protein 1 (MRP1) was mutated to either a different aromatic residue or a polar cysteine residue. Substitution of the aromatic residue with a different aromatic amino acid, such as W653Y or Y1302W, did not affect ATP-dependent leukotriene C4 (LTC4) transport. In contrast, substitution of the aromatic residue with a polar cysteine residue, such as W653C or Y1302C, decreased the affinity for ATP, resulting in greatly increased Kd values for ATP binding or Km values for ATP in ATP-dependent LTC4 transport. Interestingly, although substitution of the aromatic Trp653 in NBD1 of MRP1 with a polar cysteine residue greatly decreases the affinity for ATP, the ATP-dependent LTC4 transport activities are much higher than that of wild-type MRP1, supporting our hypothesis that the increased release rate of the bound ATP from the mutated NBD1 facilitates the protein to start a new cycle of ATP-dependent solute transport.     

Optimization of a β‐sheet‐cap for long loop closure

Protein loops make up a large portion of the secondary structure in nature. But very little is known concerning loop closure dynamics and the effects of loop composition on fold stability. We have designed a small system with stable β‐sheet structures, including features that allow us to probe these questions. Using paired Trp residues that form aromatic clusters on folding, we are able to stabilize two β‐strands connected by varying loop lengths and composition (an example sequence: R W ITVTI – loop – KKIRV W E). Using NMR and CD, both fold stability and folding dynamics can be investigated for these systems. With the 16 residue loop peptide (sequence: R W ITVTI‐(GGGGKK)₂GGGG‐KKIRV W E) remaining folded (ΔG_U = 1.6 kJ/mol at 295K). To increase stability and extend the series to longer loops, we added an additional Trp/Trp pair in the loop flanking position. With this addition to the strands, the 16 residue loop (sequence: R W ITVRI W ‐(GGGGKK)₂GGGG‐ W KTIRV W E) supports a remarkably stable β‐sheet (ΔG_U = 6.3 kJ/mol at 295 K, T_m = ～55°C). Given the abundance of loops in binding motifs and between secondary structures, these constructs can be powerful tools for peptide chemists to study loop effects; with the Trp/Trp pair providing spectroscopic probes for assessing both stability and dynamics by NMR.     

Fluorescence quenching method for the determination of carbazochrome sodium sulfonate with aromatic amino acids

In Britton‐Robinson (BR) buffer medium (pH 3.3), carbazochrome sodium sulfonate (CSS) can react with some aromatic amino acids such as tryptophan (Trp), tyrosine (Tyr) and phenylalanine (Phe) to form a 1:1 complex by electrostatic attraction, aromatic stacking interaction and Van der Waals' force, resulting in fluorescence quenching of these amino acids. Maximum quenching wavelengths were located at 352 nm (CSS‐Trp system), 303 nm (CSS‐Tyr system) and 284 nm (CSS‐Phe system), respectively. The fluorescence quenching value (ΔF) was proportional to the concentration of CSS in a certain range. The fluorescence quenching method for the determination of CSS showed high sensitivity, with detection limits of 31.3 ng/mL (CSS‐Trp system), 44.6 ng/mL (CSS‐Tyr system) and 315.0 ng/mL (CSS‐Phe system), respectively. The optimum conditions of the reaction conditions and the effect of coexisting substances were investigated and results showed that the method had good selectivity. The method was successfully applied for the rapid determination of CSS in blood and urine samples. Based on the bimolecular quenching constant K_q, the effect of temperature and Stern‐Volmer plots, this study showed that quenching of fluorescence of amino acids by CSS was a static quenching process. Copyright © 2012 John Wiley & Sons, Ltd.     

A comparison of phlorizin and phloretin adsorption by the tapeworm Hymenolepis diminuta

Phloretin and phlorizin adsorb to the tegument surface of Hymenolepis diminuta, with KDs of 2.39 mM and 14.7 microM, respectively, and Vmaxs of 1446 and 12.54 nmoles/g tissue per 2 min, respectively. Phloretin adsorption is not inhibited by phlorizin or glucose. Glucose partially inhibits phlorizin adsorption. Phlorizin, but not phloretin, adsorption to isolated tegument brush border membrane preparations is partially inhibited by N-ethylmaleimide. No indications of phlorizin hydrolysis to phloretin during incubation with H. diminuta were obtained. The data are supportive of spacially separate and distinct binding sites for phloretin and phlorizin in the tegument brush border.     

Probing the dynamics of a mobile loop above the active site of L1, a metallo-beta-lactamase from Stenotrophomonas maltophilia, via site-directed mutagenesis and stopped-flow fluorescence spectroscopy

A structural feature shared by the metallo-beta-lactamases is a flexible loop of amino acids that extends over their active sites and that has been proposed to move during the catalytic cycle of the enzymes, clamping down on substrate. To probe the movement of this loop (residues 152-164), a site-directed mutant of metallo-beta-lactamase L1 was engineered that contained a Trp residue on the loop to serve as a fluorescent probe. It was necessary first, however, to evaluate the contribution of each native Trp residue to the fluorescence changes observed during the catalytic cycle of wild-type L1. Five site-directed mutants of L1 (W39F, W53F, W204F, W206F, and W269F) were prepared and characterized using metal analyses, CD spectroscopy, steady-state kinetics, stopped-flow fluorescence, and fluorescence titrations. All mutants retained the wild-type tertiary structure and bound Zn(II) at levels comparable with wild type and exhibited only slight (<10-fold) decreases in k(cat) values as compared with wild-type L1 for all substrates tested. Fluorescence studies revealed a single mutant, W39F, to be void of the fluorescence changes observed with wild-type L1 during substrate binding and catalysis. Using W39F as a template, a Trp residue was added to the flexile loop over the active site of L1, to generate the double mutant, W39F/D160W. This double mutant retained all the structural and kinetic characteristics of wild-type L1. Stopped-flow fluorescence and rapid-scanning UV-visible studies revealed the motion of the loop (k(obs) = 27 +/- 2 s(-1)) to be similar to the formation rate of a reaction intermediate (k(obs) = 25 +/- 2 s(-1)).     

γδ T cell receptors recognize the non-classical major histocompatibility complex (MHC) molecule T22 via conserved anchor residues in a MHC peptide-like fashion

The molecular mechanisms by which γδ T cells recognize ligand remain a mystery. The non-classical MHC molecule T22 represents the best characterized ligand for murine γδ T cells, with a motif (W … EGYEL) present in the γδ T cell receptor complementary-determining region 3δ (CDR3δ) loop mediating γδ T cell recognition of this molecule. Produced through V(D)J recombination, this loop is quite diverse, with different numbers and chemical types of amino acids between Trp and EGYEL, which have unknown functional consequences for T22 recognition. We have investigated the biophysical and structural effects of CDR3δ loop diversity, revealing a range of affinities for T22 but a common thermodynamic pattern. Mutagenesis of these CDR3δ loops defines the key anchor residues involved in T22 recognition as W … EGYEL, similar to those found for the G8 CDR3δ loop, and demonstrates that spacer residues modulate but are not required for T22 recognition. Comparison of the location of these residues in the T22 interface reveals a striking similarity to peptide anchor residues in classically presented MHC peptides, with the key Trp residue of the CDR3δ motif completing the deficient peptide-binding groove of T22. This suggests that γδ T cell recognition of T22 utilizes the conserved ligand-presenting nature of the MHC fold.