Understanding the Role of Histidine in the GHSxG Acyltransferase Active Site Motif: Evidence for Histidine Stabilization of the Malonyl-Enzyme Intermediate

Acyltransferases determine which extender units are incorporated into polyketide and fatty acid products. The ping-pong acyltransferase mechanism utilizes a serine in a conserved GHSxG motif. However, the role of the conserved histidine in this motif is poorly understood. We observed that a histidine to alanine mutation (H640A) in the GHSxG motif of the malonyl-CoA specific yersiniabactin acyltransferase results in an approximately seven-fold higher hydrolysis rate over the wildtype enzyme, while retaining transacylation activity. We propose two possibilities for the reduction in hydrolysis rate: either H640 structurally stabilizes the protein by hydrogen bonding with a conserved asparagine in the ferredoxin-like subdomain of the protein, or a water-mediated hydrogen bond between H640 and the malonyl moiety stabilizes the malonyl-O-AT ester intermediate.     

Protochlorophyll forms with different molecular arrangements

Spectral properties of protochlorophyll (PChl) forms were investigated in solid-film model systems by absorption. fluorescence and circular dichroism (CD) spectroscopy. The solid films were prepared from diethyl ether solution of PChl on a cover glass surface by evaporation of the solvent. After preparation the films usually showed an absorption maximum at 635 nm or in some cases at 640 nm. The PChl form with 635 nm absorption maximum had no CD signal, whilst the films with absorption maximum at 640 nm gave an intense negative CD band at about 640 nm and a positive one at 668 nm. The treatment of the films with ammonia or acetone vapour resulted in a red shift of the absorption maximum from 635 nm or 640 nm to 650 nm. The study of the CD spectra of the films with different PChl forms showed that, depending on the treatment, forms of PChl with similar absorption and fluorescence spectra, but with opposite CD signals, can exist. It is suggested that the differences of the CD spectra are mainly due to different arrangements of the aggregates.     

Different Effects of Tris and Histidine on a Membrane Bound NaK ATPase from Sugar Beet Roots

A membrane fraction of sugar beet roots prepared in the presence of dithiothreitol contains (Na⁺+ K⁺+ Mg²⁺) ATPase activity. This activity was studied in the presence of different concentrations of Tris and histidine. Tris was found to interact with the ATPase in the following way: (1) Tris at 50 mM increases, in the absence of Na and/or K, the activity in an uncompetitive way with respect to MgATP. (2) Concentrations of Tris > 50 mM cause inhibition in the absence of Na and K when the ratio between MgATP and Tris is relatively low. (3) Though Tris at 50 mM stimulates similarly to Na, it can not substitute for Na in the Na + K activation. (4) In the presence of Na and K, Tris acts as a competitive inhibitor. Histidine has little influence on the rate both in the presence and absence of Na and/or K.     

The accuracy of Q beta RNA translation. 2. Errors during the synthesis of Q beta proteins by cell-free Escherichia coli extracts

The accuracy of Q beta translation by Escherichia coli extracts in polymix and a conventional Tris/Mg2+ system has been followed. Misinsertions of histidine and of tryptophan into the phage coat protein were less frequent in polymix than in Tris/Mg2+, as were errors leading to a change in the coat protein pI. Even the lowest Q beta error rates, however, were still an order of magnitude greater than those for poly(U) or poly(U-G) translation. Comparing Q beta translational errors made in vitro to those found in whole cells, histidine misinsertions were almost twice as frequent, errors leading to a coat protein charge change six times more frequent and tryptophan misinsertions at least 15 times more frequent in vitro. The relation of these findings to measurements of translational accuracy and to factors affecting fidelity is discussed.     

无损光学法测量人胃粘膜/粘膜下层组织的光衰减特性

研究了人正常胃粘膜及粘膜下层组织对640 nm,690 nm,740 nm,790 nm,840 nm和890 nm波长的钛宝石激光的光衰减特性以及光学穿透深度,实验采用激光斜入射式空间分辨反射光和CCD探测器以及非线性拟合确定组织光学特性。结果表明:人正常胃粘膜及粘膜下层组织对六个波长的激光的有效衰减系数和光学穿透深度都是随着激光波长的变化而变化的。其有效衰减系数的最大值在640 nm,其值为1.12 mm-1,最小值在790 nm,其值为0.901 mm-1,最大差异在790 nm和890 nm之间,其值为19.9%,最小差异在690 nm和740nm之间,其值为2.83%。其光学穿透深度的最大值在790 nm,其值为1.11 mm,最小值在640 nm,其值为0.890 mm,最大差异在640 nm和790 nm之间,其值为24.7%,最小差异在690 nm和740 nm之间,其值为2.97%。     

Wavelength Dependence in the Red and Far-Red for Induction of Phytochrome Increase in Mung Bean Hooks

The wavelength dependence for a radiation induced increase of phytochrome in mung bean hooks (Vigna radiata L.), preirradiated with red light, was determined between 640 to 800 nm. Radiation between 640 to 700 nm and 780 to 800 nm had little effect on phytochrome concentration in hooks pretreated with red. Two bands of far-red light, one at 710 nm and the other at 750 to 760 nm, were found to increase phytochrome content about four times. Besides the requirement for a photochemical process, one or more dark processes appear to be necessary for the induction of phytochrome increase.     

Enhancement of oxidative DNA degradation by histidine: the role of stereochemical parameters.

The nicking of supercoiled DNA by H2O2 and ferrous iron has been studied in a variety of environmental conditions. The replicative form of phage fd DNA (fd RF DNA) was used for investigating the phenomenon. The rate of nicking was measured in 10 mM NaCl. The addition of 1 mM Tris-HCl buffer (pH 7.5) slowed down the rate of nicking, the addition of 0.1 mM histidine enhanced it. The simultaneous presence of 1 mM Tris-HCl buffer and of 0.1 mM histidine further enhanced the rate of nicking of fd RF DNA. Increasing the concentration of NaCl dramatically reduced the rate of the reaction. The degradation of fd RF DNA was determined as a function of the concentration of histidine (0-5 mM): the rate increases with concentration, reaches a maximum and then decreases. In the presence of histidine, increasing the concentration of Tris leads to a similar phenomenon. In the absence of histidine, Tris always quenches the degradation of DNA. Electron spin resonance measurements failed to detect an enhancement of the signal characteristic for the hydroxyl radical when histidine was added to the solution containing hydrogen peroxide and ferrous iron. When the nicking of DNA is achieved via the process of auto-oxidation of ferrous iron (i.e., in the absence of added H2O2), histidine only reduces the rate of reaction in a dose-dependent manner, in the explored range of concentrations. In the presence of H2O2 and ferrous iron, histidine enhances the rate of nicking of double-stranded DNA in its supercoiled as well as in its relaxed state, but fails to modify the rate of nicking of fd DNA when it is in its vegetative, single-stranded form.     

Ligand-induced structural changes in amylose partially complexed with iodine

The influence of complexing agents such as methanol, ethanol, 1-propanol, 1-butanol, 1-pentanol, 1-hexanol, cyclohexanol and 2-octanol on the formation of a blue coloured amylose · iodine complex (pH 4.8), under suboptomum concentrations of iodine and in the absence of potassium iodide, is studied by recording the absorbance at 640 nm. A drop in absorbance at 640 nm accompanied by a blue shift in the spectrum (580–640 nm) was observed at higher concentration of the complexing agents. This behaviour of amylose partially complexed with iodine appears to be due to ligand-induced structural changes in the amylose chain. The fall in absorbance at 640 nm observed when the temeprature of amylose · oidine complex in the presence of complexing agents is raised, and the subsequent regeneration of the absorbance on cooling, indicates the possible helix to random coil transition of the amylose chain in an aqueous system.     

Interference by Tris buffer in the estimation of protein by the Lowry procedure

Tris buffers were found to distort the measurement of protein by the Lowry method both by decreasing chromophore development with protein and by contributing blank color. Tris at an assay concentration of 0.37 mm markedly affects measured results. Similar Tris effects were observed at all wavelengths between 450 and 800 nm and with diverse protein samples. The distortion due to Tris is not correctable by simple blank correction, but it can be overcome by incorporating the same amount of Tris in the standards used. The distortion at Tris concentrations <0.15 mm appears to be within tolerable limits. No interference or distortion was observed with sodium phosphate buffer to an assay concentration of 40 mm. An automated Lowry procedure is also presented which gives excellent correlation with the manual method and an average coefficient of variation of <4%.     

The role of histidines in the acetate kinase from Methanosarcina thermophila

The role of histidine in the catalytic mechanism of acetate kinase from Methanosarcina thermophila was investigated by diethylpyrocarbonate inactivation and site-directed mutagenesis. Inactivation was accompanied by an increase in absorbance at 240 nm with no change in absorbance at 280 nm, and treatment of the inactivated enzyme with hydroxylamine restored 95% activity, results that indicated diethylpyrocarbonate inactivates the enzyme by the specific modification of histidine. The substrates ATP, ADP, acetate, and acetyl phosphate protected against inactivation suggesting at least one active site where histidine is modified. Correlation of residual activity with the number of histidines modified, as determined by absorbance at 240 nm, indicated that a maximum of three histidines are modified per subunit, two of which are essential for full inactivation. Comparison of the M. thermophila acetate kinase sequence with 56 putative acetate kinase sequences revealed eight highly conserved histidines, three of which (His-123, His-180, and His-208) are perfectly conserved. Diethylpyrocarbonate inactivation of the eight histidine --> alanine variants indicated that His-180 and His-123 are in the active site and that the modification of both is necessary for full inactivation. Kinetic analyses of the eight variants showed that no other histidines are important for activity. Analysis of additional His-180 variants indicated that phosphorylation of His-180 is not essential for catalysis. Possible functions of His-180 are discussed.     

Absorption and circular dichroism spectra of chloroplast membrane fragments from spinach,barley and a barley mutant at room temperature and liquid nitrogen temperature

The absorption and CD spectra of chloroplast fragments from spinach, barley and a barley mutant (chlorophyll b-minus) were studied at temperatures of 23°C and ?196°C. The CD spectrum of wild type barley and spinach at ?196°C showed troughs at 640, 653, 676 and 695 nm and a maximum at 667 nm. The CD spectrum of the barley mutant at ?196°C consisted of a large trough at 684 nm, a small trough at 695 nm and a positive peak at 670 nm. A new feature observed at ?196°C but not at 23°C is the trough at 640 nm. This 640 nm CD signal is missing in the CD spectrum of the barley mutant. It is attributable to the light-harvesting chlorophyll $\text{a}\text{b}$ protein which appears to be missing in the mutant. Another new feature, the trough at 695 nm, was observed in the CD spectra of spinach, barley and the barley mutant at ?196°C. The 695 nm trough appears to be sensitive to detergents and it may be due to a labile chlorophyll a·protein complex. Possible interpretations of these data are discussed.     

Effects of organic solvent vapors on the protochlorophyllic complex from etiolated leaves. Conditions for reversible and irreversible destruction]

The spectral properties and the ability of etyolated leaves pigments treated with organic solvent vapours (OS) for phototransformations were studied by measuring low temperature fluorescence spectra (-196 degrees C). Under the effects of OS the fluorescence at 655 nm was gradually decreased and that at 630--640 nm was increased. The effects of OS depended on the partial pressure of OS. The ability of the pigments for phototransformations was decreased with an increase in fluorescence at 630 nm. The emission maximum of fluorescence of the pigment formed in the light was shifted by 10--18 nm towards the shortwave region. Partial reversibility of the destroying effects of diethyl ester was found. A removal of the ester vapours resulted in a relative increase of fluorescence in the etyolated leaves at 640--645 nm and a decrease of the amount of "photo-inactive" pigment. The maximum of fluorescence of the pigment formed in the light was shifted towards the long-wave region (approximately 5 nm) as compared to the leaves irradiated in the presence of the ester. Partial functional reconstitution indicates that at least part of the pigment molecules are able to form a protochlorophyllide (protochlorophyll) -- protein complex, similar to the native one.     

A water-mediated salt link in the catalytic site of Escherichia coli alkaline phosphatase may influence activity

Escherichia coli alkaline phosphatase catalyzes the hydrolysis of a wide variety of phosphomonoesters at similar rates, and the reaction proceeds through a phosphoenzyme intermediate. The active site region is highly conserved between the E. coli and mammalian alkaline phosphatases. The three-dimensional structure of the E. coli enzyme indicates that Lys-328, which is replaced by histidine in all mammalian alkaline phosphatases, is bridged to the phosphate through a water molecule. This water molecule is also hydrogen bonded to Asp-327, a bidendate ligand of the one of the two zinc atoms. Here we report the use of site-specific mutagenesis to convert Lys-328 to both histidine and alanine. Steady-state kinetic studies above pH 7.0 indicate that both mutant enzymes have altered pH versus activity profiles compared to the profile for the wild-type enzyme. At pH 10.3, in the presence of Tris, the Lys-328----Ala enzyme is approximately 14-fold more active than the wild-type enzyme. At the same pH in the absence of Tris the Lys-328----Ala enzyme is still 6-fold more active than the wild-type enzyme. Both mutant enzymes have lower phosphate affinities than the wild-type enzyme at all pH values investigated. Pre-steady-state kinetics at pH 5.5 reveal that the Lys-328----Ala enzyme behaves very similar to the phosphate-free wild-type enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Physiological and enzymatic aspects of histidine-mediated control of the tryptophan pathway

Summary It would thus appear that in Saccharomyces cerevisiae there are two forms of histidine-mediated control on the tryptophan pathway. In some strains histidine increases anthranilate synthetase and indole glycerol phosphate synthetase activities, while tryptophan synthetase decreases. In other strains histidine affects coordinately all enzymatic activities involved in tryptophan biosynthesis. The two groups of strains also differ in the formation, during the growth of the enzymatic activities involved in tryptophan biosynthesis. This difference in the relative rates at which the two enzymes are formed may explain the accumulation of intermediates in the cultural media of some strains. The derepression of anthranilate synthetase and indole glycerol phosphate synthetase activities by histidine is particularly manifest in the auxotrophic his₃ strains that show these activities very depressed in histidine starvation; large amounts of this amino acid stimulate them to a considerably greater extent than in prototrophic strains.Abbreviations IGP imidazole glycerol phosphate - InGP indole glycerol phosphate - ASase anthranilate synthetase - InGPase indole-3-glycerol phosphate synthetase - TSase tryptophan synthetase - Tris tris (hydroxymethyl)-aminomethane This investigation was supported by a research grant of C.N.R. (Consiglio Nazionale delle Ricerche, Roma).     

Essential histidine residues in dextransucrase: chemical modification by diethyl pyrocarbonate and dye photo-oxidation

Treatment of Leuconostoc mesenteroides B-512F dextransucrase with diethyl pyrocarbonate (DEP) at pH 6.0 and 25 degrees or photo-oxidation in the presence of Rose Bengal or Methylene Blue at pH 6.0 and 25 degrees, caused a rapid decrease of enzyme activity. Both types of inactivation followed pseudo-first-order kinetics. Enzyme partially inactivated by DEP could be completely reactivated by treatment with 100 mM hydroxylamine at pH 7 and 4 degrees. The presence of dextran partially protected the enzyme from inactivation. At pH 7 or below, DEP is relatively specific for the modification of histidine. DEP-modified enzyme showed an increased absorbance at 240 nm, indicating the presence of (ethoxyformyl)ated histidine residues. DEP modification of the sulfhydryl group of cysteine and of the phenolic group of tyrosine was ruled out by showing that native and DEP-modified enzyme had the same number of sulfhydryl and phenolic groups. DEP modification of the epsilon-amino group of lysine was ruled out by reaction at pH 6 and reactivation with hydroxylamine, which has no effect on DEP-modified epsilon-amino groups. The photo-oxidized enzyme showed a characteristic increase in absorbance at 250 nm, also indicating that histidine had been oxidized, and no decrease in the absorbance at 280 nm, indicating that tyrosine and tryptophan were not oxidized. A statistical, kinetic analysis of the data on inactivation by DEP showed that two histidine residues are essential for the enzyme activity. Previously, it was proposed that two nucleophiles at the active site attack bound sucrose, to give two covalent D-glucosyl-enzyme intermediates. We now propose that in addition, two imidazolium groups of histidine at the active site donate protons to the leaving, D-fructosyl moieties. The resulting imidazole groups then facilitate the formation of the alpha-(1----6)-glycosidic linkage by abstracting protons from the C-6-OH groups, and become reprotonated for the next series of reactions.     

The red light of the helium-neon laser reactivates superoxide dismutase

The effect of low-energy helium-neon laser (HNL) on enzymatic activity, absorbtion spectra and electron paramagnetic resonance (EPR) signals of superoxide dismutase (SOD) from bovine erythrocytes in acid medium were investigated. It was found that incubation during 2 hours at pH 5.9 led to eventually complete inactivation of the enzyme. The subsequent illumination of inactivated SOD by HNL brought about the enzyme reactivation. Both absorption and EPR-spectra were changed after incubation at pH 5.9. These changes may be attributed to protonation of histidine residue in the enzyme active site. After laser irradiation both absorption and EPR spectra were restored to those typical of native enzyme at pH 8.2. In a model system, copper-histidine complex, absorption maximum was shifted from 632-633 nm at pH 5.8 to 639-640 nm at pH 8.5-9.0. The similar long-wave length shift of the maximum was observed after illumination by HNL at pH 5.8. It may be postulated that the photoreactivation of SOD consists essentially in deprotonation of His-61 residue in the enzyme active site and subsequent recovery of imidazole bridge between copper and zinc which had been destroyed at low pH. Since many other enzymes possess similar copper-histidine structures in their active sites, one may expect diverse effects of red (laser) light on the enzyme activity.     

Ethoxyformylation of ribonuclease U2 form Ustilago sphaerogena.

RNase U2 was inactivated by incubation with ethoxyformic anhydride at pH 6.0 and pH 4.5. The absorbance of the RNase U2 increased at around 250 nm and decreased at around 280 nm. The inactivation occurred in parallel with the amount of modified histidine and plots of the relationship between the remaining activity and the modified histidine suggested that the modification of one of the two histidine residues totally inactivated the enzyme. The inactivated enzyme RNase U2 was reactivated by a low concentration of hydroxyamine, with removal of the ethoxyformyl group from the modified histidine residue. At pH 4.5, 2'-adenylate and 2'-guanylate protected RNase U2 from inactivation by ethoxyformic anhydride. The difference CD spectra showed that the ability of RNase U2 to form a complex with 2'-adenylate was lost on ethoxyformylation.     

Essential histidine residues in lysolecithin:lysolecithin acetyltransferase from rabbit lung

Both activities of rabbit lung lysolecithin:lysolecithin acyltransferase (EC 3.1.1.5), hydrolysis and transacylation, are inactivated by diethylpyrocarbonate. The reaction follows pseudo-first-order kinetics, and second-order rate constants of 1.17 mM-1min-1 for hydrolysis and 0.56 mM-1 min-1 for transacylation were obtained at pH 6.5 and 37 degrees C. The rate of inactivation is dependent on pH, showing the involvement of a group with a pK of 6.5. The difference spectra showed an increase in absorbance at 242 nm, indicating the modification of histidine residues. The activity lost by diethylpyrocarbonate modification can be partially recovered by hydroxylamine treatment. The statistical analysis of residual fractional activity versus the number of modified histidine residues leads to the conclusion that two histidine residues are essential for the hydrolytic activity, whereas transacylation activity depends on only one essential histidine. The substrate and substrate analogs protected the enzyme against inactivation by diethylpyrocarbonate, suggesting that the essential residues are located at or near the active site of the enzyme.     

Purification and properties of a pyridoxal 5'-phosphate-dependent histidine decarboxylase from Morganella morganii AM-15

A pyridoxal 5'-phosphate-dependent histidine decarboxylase from Morganella morganii AM-15 was purified to homogeneity. The enzyme is a tetramer (Mr 170,000) of identical subunits and binds 4 pyridoxal-P/tetramer; it is resolved by dialysis against cysteine at pH 6.8. Between pH 6.2 and 8.8, the holoenzyme shows pH-independent absorbance maxima at 333 and 416 nm. Vmax/Km is highest at pH 6.5; this optimum reflects chiefly increased Km values for histidine at lower or higher pH values, whereas Vmax is highest at pH 5.0 and decreases only moderately between pH 5.0 and 8.0. The enzyme also decarboxylates beta-(2-pyridyl)alanine and N tau-methylhistidine (but not N pi-methylhistidine); arginine, lysine, and ornithine are neither substrates nor inhibitors. The hydrazine analogue of histidine, 2-hydrazino-3-(4-imidazolyl)propionic acid, is a very potent competitive inhibitor; other carbonyl reagents and a variety of carboxyl- or amino-substituted histidines also inhibit competitively. alpha-Fluoromethylhistidine is a potent irreversible inhibitor of the enzyme; alpha-methylhistidine is a competitive inhibitor/substrate that is decarboxylated slowly and undergoes a slow decarboxylation-dependent transamination that converts the holoenzyme to pyridoxamine-P and apoenzyme. Dithiothreitol and other simple thiols are mixed-type inhibitors that interact with pyridoxal-P at the active site to form complexes (lambda max congruent to 340 nm), presumably the corresponding thioalkylamines, without resolving the holoenzyme. This histidine decarboxylase (Vmax = 72 mumol X min-1 X mg-1) is much more active than "homogeneous" preparations of mammalian pyridoxal-P-dependent histidine decarboxylase (Vmax congruent to 1.0) and is about equal in activity to the pyruvoyl-dependent histidine decarboxylases from Gram-positive bacteria.