Genetic basis for plasma amino acid concentrations based on absolute quantification: a genome-wide association study in the Japanese population.

To assess the use of plasma free amino acids (PFAAs) as biomarkers for metabolic disorders, it is essential to identify genetic factors that influence PFAA concentrations. PFAA concentrations were absolutely quantified by liquid chromatography-mass spectrometry using plasma samples from 1338 Japanese individuals, and genome-wide quantitative trait locus (QTL) analysis was performed for the concentrations of 21 PFAAs. We next conducted a conditional QTL analysis using the concentration of each PFAA adjusted by the other 20 PFAAs as covariates to elucidate genetic determinants that influence PFAA concentrations. We identified eight genes that showed a significant association with PFAA concentrations, of which two, SLC7A2 and PKD1L2, were identified. SLC7A2 was associated with the plasma levels of arginine and ornithine, and PKD1L2 with the level of glycine. The significant associations of these two genes were revealed in the conditional QTL analysis, but a significant association between serine and the CPS1 gene disappeared when glycine was used as a covariate. We demonstrated that conditional QTL analysis is useful for determining the metabolic pathways predominantly used for PFAA metabolism. Our findings will help elucidate the physiological roles of genetic components that control the metabolism of amino acids.

Rapid identification of ligand-binding sites by using an assignment-free NMR approach.

In this study, we developed an assignment-free approach for rapid identification of ligand-binding sites in target proteins by using NMR. With a sophisticated cell-free stable isotope-labeling procedure that introduces (15)N- or (13)C-labels to specific atoms of target proteins, this approach requires only a single series of ligand titrations with labeled targets. Using titration data, ligand-binding sites in the target protein can be identified without time-consuming assignment procedures. We demonstrated the feasibility of this approach by using structurally well-characterized interactions between mitogen-activated protein (MAP) kinase p38α and its inhibitor 2-amino-3-benzyloxypyridine. Furthermore, we confirmed the recently proposed fatty acid binding to p38α and confirmed the fatty acid-binding site in the MAP kinase insert region.

Incorporation of 15N-labeled ammonia into glutamine amide groups by protein-glutaminase and analysis of the reactivity for α-lactalbumin.

Protein-glutaminase (PG) is an enzyme that catalyzes the deamidation of protein-bound glutamine residues. We found that an enzyme labeling technique (ELT), which is a stable isotope labeling method based on transglutaminase (TGase) reaction, is applicable for PG. PG catalyzed incorporation of (15)N-labeled ammonium ions into reactive glutamine amide groups in α-lactalbumin similarly to TGase and deamidated the most reactive glutamine amide group once labeled with (15)N. Furthermore, we investigated the effect of ammonium ions on the PG activity by peptide mapping, and more reactive glutamine residues were detected than were detected by the ELT in the presence of ammonium ions. This is probably because ammonium ions are competitive inhibitors, causing decreased reactivity for glutamine residues. We propose the reaction scheme of PG in the presence of the (15)N-labeled ammonium ions and show that the ELT method with PG is useful for evaluating the activity of PG.

Rapid identification of protein-protein interfaces for the construction of a complex model based on multiple unassigned signals by using time-sharing NMR measurements.

Protein-protein interactions are necessary for various cellular processes, and therefore, information related to protein-protein interactions and structural information of complexes is invaluable. To identify protein-protein interfaces using NMR, resonance assignments are generally necessary to analyze the data; however, they are time consuming to collect, especially for large proteins. In this paper, we present a rapid, effective, and unbiased approach for the identification of a protein-protein interface without resonance assignments. This approach requires only a single set of 2D titration experiments of a single protein sample, labeled with a unique combination of an (15)N-labeled amino acid and several amino acids (13)C-labeled on specific atoms. To rapidly obtain high resolution data, we applied a new pulse sequence for time-shared NMR measurements that allowed simultaneous detection of a ω(1)-TROSY-type backbone (1)H-(15)N and aromatic (1)H-(13)C shift correlations together with single quantum methyl (1)H-(13)C shift correlations. We developed a structure-based computational approach, that uses our experimental data to search the protein surfaces in an unbiased manner to identify the residues involved in the protein-protein interface. Finally, we demonstrated that the obtained information of the molecular interface could be directly leveraged to support protein-protein docking studies. Such rapid construction of a complex model provides valuable information and enables more efficient biochemical characterization of a protein-protein complex, for instance, as the first step in structure-guided drug development.

Crystal structure of Bifidobacterium Longum phosphoketolase; key enzyme for glucose metabolism in Bifidobacterium.

The crystal structure of Bifidobacterium longum phosphoketolase, a thiamine diphosphate (TPP) dependent enzyme, has been determined at 2.2A resolution. The enzyme is a dimer with the active sites located at the interface between the two identical subunits with molecular mass of 92.5 kDa. The bound TPP is almost completely shielded from solvent except for the catalytically important C2-carbon of the thiazolium ring, which can be accessed by a substrate sugar through a narrow funnel-shaped channel. In silico docking studies of B. longum phosphoketolase with its substrate enable us to propose a model for substrate binding.

Screening for improved activity of a transglutaminase from Streptomyces mobaraensis created by a novel rational mutagenesis and random mutagenesis.

Microbial transglutaminase (MTG) has been used extensively in academic research and the food industries through its cross-linking or posttranslational modification of proteins. Two enzyme engineering approaches were applied to improve MTG activity. One is a novel method of rational mutagenesis, called water-accessible surface hot-space region-oriented mutagenesis (WASH-ROM). One hundred and fifty-one point mutations were selected at 40 residues, bearing high solvent-accessibility surface area, within a 15 A space from the active site Cys64. Among them, 32 mutants showed higher specific activity than the wild type. The other is a random mutagenesis of the whole region of the MTG gene, coupled with a new plate assay screening system, using Corynebacterium Expression System CORYNEX. This in vivo system allowed us to readily distinguish the change in enzymatic activity by monitoring the intensity of enzymatic reaction-derived color zones surrounding recombinant cells. From the library of 24,000 mutants, ten were finally selected as beneficial mutants exhibiting higher specific activity than the wild type. Furthermore, we found that Ser199Ala mutant with additional N-terminal tetrapeptide showed the highest specific activity (1.7 times higher than the wild type). These various beneficial positions leading to increased specific activity of MTG were identified to achieve further enzyme improvements.

Direct determination of the insulin-insulin receptor interface using transferred cross-saturation experiments.

Insulin initiates metabolic control by binding to the insulin receptor (IR) on target cells. Kinetic and mutational analyses have revealed two binding sites on the insulin molecule and the residues that compose them. However, direct determination of the insulin-IR interface is required to distinguish those residues that contribute to receptor binding from those required for structural stability. Here, we successfully characterized one binding site using the nuclear magnetic resonance (NMR) transferred cross-saturation method, which can directly determine the binding interface of a large protein-protein complex. The results showed that this binding site contained three residues that have not been identified previously by mutational analyses. On the basis of the structure of the contact site, we also identified a molecule that can displace insulin from the IR. In addition, we discuss the mode of interaction between insulin and its receptor relative to the NMR analyses.

Substrate specificity of microbial transglutaminase as revealed by three-dimensional docking simulation and mutagenesis.

Transglutaminases (TGases) are used in fields such as food and pharmaceuticals. Unlike other TGases, microbial transglutaminase (MTG) activity is Ca(2+)-independent, broadening its application. Here, a three-dimensional docking model of MTG binding to a peptide substrate, CBZ-Gln-Gly, was simulated. The data reveal CBZ-Gln-Gly to be stretched along the MTG active site cleft with hydrophobic and/or aromatic residues interacting directly with the substrate. Moreover, an oxyanion binding site for TGase activity may be constructed from the amide groups of Cys64 and/or Val65. Alanine mutagenesis verified the simulated binding region and indicated that large molecules can be widely recognized on the MTG cleft.

Monitoring the hydrolysis and transglycosylation activity of alpha-glucosidase from Aspergillus niger by nuclear magnetic resonance spectroscopy and mass spectrometry.

Alpha-glucosidase from Aspergillus niger is an enzyme that catalyzes hydrolysis of alpha-1,4 linkages and transglucosylation to form alpha-1,6 linkages. In this study, an analytical method of oligosaccharides by nuclear magnetic resonance (NMR) was used to provide quantitative estimation of the fractions of each sugar unit and was applied to characterize the alpha-glucosidase reaction. Our data indicated that alpha-glucosidase reacts with the nonreducing end of oligosaccharides to form an alpha-1,6 linkage, and then a sugar unit with two alpha-1,6 linkages is gradually produced. Data from mass spectrometry suggested that the sugar unit with two alpha-1,6 linkages originates mainly from a 3mer and/or 4mer when oligosaccharides are used as substrates.

Crystal structure and enhanced activity of a cutinase-like enzyme from Cryptococcus sp. strain S-2.

The structural and enzymatic characteristics of a cutinase-like enzyme (CLE) from Cryptococcus sp. strain S-2, which exhibits remote homology to a lipolytic enzyme and a cutinase from the fungus Fusarium solani (FS cutinase), were compared to investigate the unique substrate specificity of CLE. The crystal structure of CLE was solved to a 1.05 A resolution. Moreover, hydrolysis assays demonstrated the broad specificity of CLE for short and long-chain substrates, as well as the preferred specificity of FS cutinase for short-chain substrates. In addition, site-directed mutagenesis was performed to increase the hydrolysis activity on long-chain substrates, indicating that the hydrophobic aromatic residues are important for the specificity to the long-chain substrate. These results indicate that hydrophobic residues, especially the aromatic ones exposed to solvent, are important for retaining lipase activity.

[NMR analysis of a contaminant in heparin].

Recently, it has been reported that certain lots of heparin are associated with an acute, rapid onset of serious side effects indicative of allergic reaction, and (1)H NMR is one of the convenience but strong analytical methods to identify a contaminant in heparin. However, an NMR signal from the contaminant in some cases is overlapped with a satellite peak from heparin, leading a misunderstanding of the presence of the contaminant. Here, we show the satellite peak observed close to the NMR signal of the contaminant, and recommend the (13)C decoupling NMR to discriminate the satellite peak from the contaminant.

Curculin exhibits sweet-tasting and taste-modifying activities through its distinct molecular surfaces.

Curculin isolated from Curculigo latifolia, a plant grown in Malaysia, has an intriguing property of modifying sour taste into sweet taste. In addition to this taste-modifying activity, curculin itself elicits a sweet taste. Although these activities have been attributed to the heterodimeric isoform and not homodimers of curculin, the underlying mechanisms for the dual action of this protein have been largely unknown. To identify critical sites for these activities, we performed a mutational and structural study of recombinant curculin. Based on the comparison of crystal structures of curculin homo- and heterodimers, a series of mutants was designed and subjected to tasting assays. Mapping of amino acid residues on the three-dimensional structure according to their mutational effects revealed that the curculin heterodimer exhibits sweet-tasting and taste-modifying activities through its partially overlapping but distinct molecular surfaces. These findings suggest that the two activities of the curculin heterodimer are expressed through its two different modes of interactions with the T1R2-T1R3 heterodimeric sweet taste receptor.

Structural basis of the transition-state stabilization in antibody-catalyzed hydrolysis.

The catalytic antibody 6D9, which was raised against a transition-state analogue (TSA), catalyzes the hydrolysis of a non-bioactive chloramphenicol monoester to generate chloramphenicol. It has been shown that 6D9 utilizes the binding affinity in the catalysis; the differential affinity of the TSA relative to the substrate is equal to the rate enhancement. To reveal the recognition mechanism of 6D9 for the TSA and the substrate, we performed NMR analysis of the Fv fragment of 6D9 (6D9-Fv), together with site-directed mutagenesis and stopped-flow kinetic analyses. Among six 6D9-Fv mutants, Y58(H)A and W100i(H)A displayed significant reductions in their affinities to the TSA, while their substrate-binding affinities were identical with that of the wild-type 6D9-Fv. The stopped-flow kinetic studies revealed that the TSA binding to 6D9-Fv occurred by an induced-fit mechanism. In contrast, no induced-fit type of TSA-binding mechanism was observed for Y58(H)A and W100i(H)A. From NMR experiments, we identified the residues with chemical shifts that were perturbed by the ligand-binding. The residues affected by the TSA binding were located on the TSA-binding site determined by the X-ray study, and on the regions far from the binding site. On the other hand, the residues affected by the substrate binding were localized on the TSA-binding site. As for W100i(H)A, no residue other than those in the binding site was affected by the ligand binding. On the basis of these results and the crystal structure, we concluded that the TSA binding induced a conformational change involving the formation of aromatic-aromatic interactions and a hydrogen bond. These interactions can account for the differential affinity for the TSA relative to the substrate. W100i(H) probably plays an important role in inducing the conformational changes. The present NMR studies have enabled us to visualize the concept of transition-state stabilization in enzymatic catalysis, in which the transition-state contacts are better than those of the substrate.

One functional switch mediates reversible and irreversible inactivation of a herpesvirus protease.

Distinct mechanisms have evolved to regulate the function of proteolytic enzymes. Viral proteases in particular have developed novel regulatory mechanisms, presumably due to their comparatively rapid life cycles and responses to constant evolutionary pressure. Herpesviruses are a family of human pathogens that require a viral protease with a concentration-dependent zymogen activation involving folding of two alpha-helices and activation of the catalytic machinery, which results in formation of infectious virions. Kaposi's sarcoma-associated herpesvirus protease (KSHV Pr) is unique among the herpesvirus proteases in possessing an autolysis site in the dimer interface, which removes the carboxyl-terminal 27 amino acids comprising an alpha-helix adjacent to the active site. Truncation results in the irreversible loss of dimerization and concomitant inactivation. We characterized the conformational and functional differences between the active dimer, inactive monomer, and inactive truncated protease to determine the different protease regulatory mechanisms that control the KSHV lytic cycle. Circular dichroism revealed a loss of 31% alpha-helicity upon dimer dissociation. Comparison of the full-length and truncated monomers by NMR showed differences in 21% of the protein structure, mainly located adjacent to the dimer interface, with little perturbation of the overall protein upon truncation. Fluorescence polarization and active site labeling, with a transition state mimetic, characterized the functional effects of these conformational changes. Substrate turnover is abolished in both the full-length and truncated monomers; however, substrate binding remained intact. Disruption of the helix 6 interaction with the active site oxyanion loop is therefore used in two independent regulatory mechanisms of proteolytic activity.

Induced structure of a helical switch as a mechanism to regulate enzymatic activity.

Herpesviruses encode a protease that is activated by homodimerization at high enzyme concentrations during lytic replication. The homodimer contains two active sites, which are distal from the dimer interface. Assignment of backbone NMR resonances and engineering of a redox switch show that two helices position a loop containing catalytic residues within each active site.

The energetic conversion competence of Escherichia coli during aerobic respiration studied by 31P NMR using a circulating fermentation system.

To determine the actual potential of the energetic conversion efficiency of Escherichia coli during aerobic respiration, apparent P/O ratios (P/O(app)) under either limited or standard glucose-feeding conditions were estimated. The previously reported circulating fermentation system (CFS) was used, and (31)P NMR saturation-transfer (ST) techniques were employed. By coupling with on-line NMR observations, CFS allowed us to evaluate cellular energetics directly, with both the dissolved oxygen tension and glucose feeding precisely controlled to prevent the effect of substrate-level phosphorylation based on aerobic or anaerobic acidogenesis in E. coli cells. Phosphate consumption rates under standard and limited glucose-conditions were estimated as 4.62 +/- 0.46 and 1.99 +/- 0.11 micromol/s g of dry cell weight (DCW), respectively. Using simultaneously assessed O(2) consumption rates, the P/O(app) values under these two conditions were estimated as 1.4 +/- 0.3 and 1.5 +/- 0.1, respectively. To correlate the obtained P/O(app) values with the potential efficiency of respiratory enzymes, we determined the activities of two NADH dehydrogenases (NDH 1 and 2) and two ubiquinol oxidases (bo- and bd-type) during the periods when ST was performed. NDH-1 activities in standard or limited glucose cultures were maintained at 57% or 58% of the total NADH oxidizing activity. The percentages of bo-type oxidase activity in relation to the total ubiqinol oxidizing activity under the standard and limited glucose conditions were 32% and 36%, respectively. These percentages of enzymatic activities represent the respiratory competence of E. coli cells, suggesting that, during the NMR observatory period, the enzymatic activity was not at a maximum, which could also explain the estimated P/O(app) values. If this is the case, enhancing the expression of the bo-type oxidase or disrupting of the bd-type oxidase gene could be effective approach to increasing both the P/O ratio and cellular yields.

Optimization of 13C direct detection NMR methods.

(13)C-detected experiments are still limited by their inherently lower sensitivity, as compared to the equivalent (1)H-detected experiments. Improving the sensitivity of (13)C detection methods remains a significant area of NMR research that may provide better means for studying large macromolecular systems by NMR. In this communication, we show that (13)C-detected experiments are less sensitive to the salt concentration of the sample solution than (1)H-detected experiments. In addition, acquisition can be started with anti-phase coherence, resulting in higher sensitivity due to the elimination of the final INEPT transfer step.

Recombinant curculin heterodimer exhibits taste-modifying and sweet-tasting activities.

Curculin from Curculigo latifolia is a unique sweet protein that exhibits both sweet-tasting and taste-modifying activities. We isolated a gene that encodes a novel protein highly homologous to curculin. Using cDNAs of the previously known curculin (designated as curculin1) and the novel curculin isoform (curculin2), we produced a panel of homodimeric and heterodimeric recombinant curculins by Escherichia coli expression systems. It was revealed that sweet-tasting and taste-modifying activities were exhibited solely by the heterodimer of curculin1 and curculin2.