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.

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.

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.

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.

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.

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).

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.

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.

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.

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.

[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.

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.

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.

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.

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.

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.

Methyl groups as probes for proteins and complexes in in-cell NMR experiments.

Studying protein components of large intracellular complexes by in-cell NMR has so far been impossible because the backbone resonances are unobservable due to their slow tumbling rates. We describe a methodology that overcomes this difficulty through selective labeling of methyl groups, which possess more favorable relaxation behavior. Comparison of different in-cell labeling schemes with three different proteins, calmodulin, NmerA, and FKBP, shows that selective labeling with [(13)C]methyl groups on methionine and alanine provides excellent sensitivity with low background levels at very low costs.

Herpesvirus protease inhibition by dimer disruption.

Kaposi's sarcoma-associated herpesvirus (KSHV), like all herpesviruses, encodes a protease (KSHV Pr), which is necessary for the viral lytic cycle. Herpesvirus proteases function as obligate dimers; however, each monomer has an intact, complete active site which does not interact directly with the other monomer across the dimer interface. Protein grafting of an interfacial KSHV Pr alpha-helix onto a small stable protein, avian pancreatic polypeptide, generated a helical 30-amino-acid peptide designed to disrupt the dimerization of KSHV Pr.

Communication between the active sites and dimer interface of a herpesvirus protease revealed by a transition-state inhibitor.

Structurally diverse organophosphonate inhibitors targeting the active site of the enzyme were used to investigate the relationship of the active site and the dimer interface of wild-type protease in solution. Positional scanning synthetic combinatorial libraries revealed Kaposi's sarcoma-associated herpesvirus protease to be highly specific, even at sites distal to the peptide bond undergoing hydrolysis. Specificity results were used to synthesize a hexapeptide diphenylphosphonate inhibitor of Kaposi's sarcoma-associated herpesvirus protease.

New sequential-assignment routes of nucleic acid NMR signals using a [5'-(13)C]-labeled DNA dodecamer.

NMR signal assignments for DNA oligomers have been performed by the well-established sequential assignment procedures based on NOESY and COSY. The H4'/H5'/H5'' resonance region is congested and difficult to analyze without the use of isotope-labeled DNA oligomers. Here a DNA dodecamer constructed with 2'-deoxy[5'-(13)C]ribonucleotides, 5'-d(*C*G*C*G*A*A*T*T*C*G*CG)-3' (*N = [5'-(13)C]Nucleotide), was prepared in an effort to analyze the H4'/H5'/H5'' resonance region by 2D 1H-13C HMQC-NOESY.

Quantitative identification of the protonation state of histidines in vitro and in vivo.

The C[bond]N coupling constants centered at the C(epsilon 1) and C(delta 2) carbons in histidine residues depend on the protonation state and tautomeric form of the imidazole ring, making them excellent indicators of pH or pK(a), and the ratio of the tautomeric states. In this paper, we demonstrate that the intensity ratios for the C(epsilon 1)-H and C(delta 2)-H cross-peaks measured with a constant time HSQC experiment without and with J(C[bond]N) amplitude modulation are determined by the ratios of the protonated and deprotonated forms and tautomeric states. This allows one to investigate the tautomeric state of histidines as well as their pK(a) in situations where changing the pH value by titration is difficult, for example, for in-cell NMR experiments.