P-hydroxymercurybenzoate Research Articles

Detoxification of hexavalent chromium by Leucobacter sp. uses a reductase with specificity for dihydrolipoamide.

Leucobacter sp. belongs to the metal stressed community and possesses higher tolerance to metals including chromium and can detoxify toxic hexavalent chromium by reduction to less toxic trivalent chromium. But, the mechanism of reduction of hexavalent chromium by Leucobacter sp. has not been studied. Understanding the enzyme catalyzing reduction of chromium is important to improve the species for application in bioremediation. Hence, a soluble reductase catalyzing the reduction of hexavalent chromium was purified from a Leucobacter sp. and characterized. The pure chromate reductase was obtained from the cell-free extract through hydrophobic interaction and gel filtration column chromatographic methods. It was a monomeric enzyme and showed similar molecular weights in both gel filtration (∼68 KDa) and SDS-PAGE (64 KDa). It reduced Cr(VI) using both NADH and NADPH as the electron donor, but exhibited higher activity with NADH. The optimal activity was found at pH 5.5 and 30 °C. The K(m) and V(max) for Cr(VI) reduction with NADH were 46.57 μM and 0.37 μmol min(-1) (mg protein) (-1), respectively. The activity was inhibited by p-hydroxy mercury benzoate, Ag(2+) and Hg(2+) indicating the role of thiol groups in the catalysis. The spectrophotometric analysis of the purified enzyme showed the absence of bound flavin in the enzyme. The N-terminal amino acid sequence and LC/MS analysis of trypsin digested purified enzyme showed similarity to dihydrolipoyl dehydrogenase. The purified enzyme had dihydrolipoyl dehydrogenase activity with dihydrolipoamide as the substrate, which suggested that Leucobacter sp. uses reductase with multiple substrate specificity for reduction of Cr(VI) detoxification.

Microwave-Assisted Photochemical Reactor for the Online Oxidative Decomposition and Determination of p-Hydroxymercurybenzoate and Its Thiolic Complexes by Cold Vapor Generation Atomic Fluorescence Detection

We developed a photochemical method for the online oxidation of p-hydroxymercurybenzoate (PHMB), an organic mercury species widely used for mercaptan and thiolic compound labeling. The method is based on a fully integrated online UV/microwave (MW) photochemical reactor for the digestion of PHMB, followed by cold vapor generation atomic fluorescence spectrometry (CVG-AFS) detection. The MW/UV process led to the quantitative conversion of PHMB and thiol-PHMB complexes to Hg(II), with a yield between 91% and 98%, without using chemical oxidizing reagents and avoiding the use of toxic carcinogenic compounds. This reaction was followed by the reduction of Hg(II) to Hg(0), performed in a knitted reaction coil with NaBH(4) solution, and AFS detection in an Ar/H(2) miniaturized flame. The low MW power applied (18 W) allowed us to keep constant the temperature of the photochemical reactor (21 ± 1 °C), using a flowing water bath. This avoided peak widening due to diffusion processes generally occurring at high temperatures and in the additional cooling coil. This method has been applied to the determination of thiols in human plasma, blood, and wine.

Mapping of Selenium Metabolic Pathway in Yeast by Liquid Chromatography−Orbitrap Mass Spectrometry

A high-resolution mass spectrometric detection method is described for the identification of key metabolites in the selenium pathway in selenium enriched yeast. Iodoacetic acid (IAA) was used as the derivatizing reagent to stabilize the selenols. Oxidized forms of selenocysteine (Se-Cys), selenohomocystine (Se-HCys), selenoglutathione (Se-GSH), seleno-γ-glutamyl-cysteine (Se-Glu-Cys), N-(2,3-dihydroxy-1-oxopropyl)-selenocysteine (Se-DOP-Cys), N-(2,3-dihydroxy-1-oxopropyl)-selenohomocysteine (Se-DOP-HCys), selenomethionine (SeMet), seleno-S-adenosyl-homocysteine (Se-AdoHcy), the conjugate of glutathione and N-(2,3-dihydroxy-1-oxopropyl)-selenocysteine (GSH-Se-DOP-Cys), and the conjugate of glutathione and N-(2,3-dihydroxy-1-oxopropyl)-selenohomocysteine (GSH-Se-DOP-HCys) were found in the selenium enriched yeast certified reference material (SELM-1). Selenols were also derivatized with a mercury tag, p-hydroxymercurybenzoate (PHMB). The selenol-PHMB complexes showed the overlapped isotopic patterns of selenium and mercury, which provided supporting information for the identification of selenols. Both methods showed good agreement (<4 ppm difference) between the theoretical masses of the target compounds and the measured masses in the yeast matrix. The method using IAA as the derivatizing reagent was used to study the response of Saccharomyces cerevisiae to three forms of selenium, Se-Met, Na(2)SeO(3) (Se(IV)), and Na(2)SeO(4)·10H(2)O (Se(VI)) (concentration of Se: 100 mg/L). The production of selenocompounds observed over a 6 h period was high in the Se-Met treated group compared to the groups treated with Se(IV) and Se(VI).

Determination of S-nitrosoglutathione in plasma: Comparison of two methods

In this work we compared the results of the GSNO determination in human plasma by two independent methods. The first method is based on the pre-column derivatization of GSNO thiolic part by p-hydroxymercury benzoate (PHMB) and followed by the determination of GS-PHMB product by reversed phase chromatography coupled to chemical vapour generation atomic fluorescence spectrometry (RPC-CVGAFS). The second method is based on RPC separation of GSNO from interfering compounds and the post-column, on-line enzymatic hydrolysis of GSNO by commercial gamma-glutamyl transferase (GGT) and fluorescence detection. Endogenous GSNO was determined only in plasma from blood sampled by syringe (not by Vacutainers) and ranged between 157 and 257nM on the basis of RPC-CVGAFS method, and between 90 and 225nM by RPC-FD method. There was a good correlation between the two methods (slope=1.06+/-0.09, R(2)=0.9543). RPC-CVGAFS method based on PHMB derivatization determined a GSNO concentration 60+/-20nM in excess with respect to RPC-FD method. Sampling issues connected with common blood sampling procedures like venipuncture and sampling in syringe or Vacutainers still introduce in GSNO analysis unknown factors, which require further investigations.

Determination of S-nitrosoglutathione and other nitrosothiols by p-hydroxymercurybenzoate derivatization and reverse phase chromatography coupled with chemical vapor generation atomic fluorescence detection

S-Nitrosoglutathione (GSNO) reacts with the organic mercurial probe, p-hydroxymercury benzoate (PHMB, HO–Hg–(C 6H 4)–COO −Na +) giving the complex GS–Hg(C 6H 4)COOH (GS–PHMB). This reaction has been studied by UV measurements at 334 nm also in the presence of ascorbic acid and the product of reaction, the GS–PHMB complex, characterized by Electrospray Ionization Mass Spectrometry (ESI-MS) and by Reversed Phase Chromatography (RPLC) coupled on-line and sequentially with a UV–visible diode array detector (DAD) followed by a cold vapor generation atomic fluorescence spectrometer (CVGAFS). The simultaneous presence of PHMB and ascorbate produced a synergistic effect on GSNO decomposition rate that can be observed only above a given concentration threshold of ascorbate (ascorbate/GSNO molar ratio ≥ 180). The results indicated that the formation of GS–PHMB, both in the presence and the absence of ascorbic acid, does not involve the formation of free thiolic species but it takes place through a more complex mechanism. The PHMB derivatives of GSH and GSNO obtained by the present method were found to be identical by ESI-MS. GSSG did not interfere because it was not reduced and derivatized to GS–PHMB. Once complexed by the alkylating agent N-ethylmaleimide (NEM), GSH did not interfere with the derivatization reaction. This ensured a good selectivity of the developed PHMB derivatization system for RSNO determination. Thus, we have optimized the operating conditions for the selective reaction of PHMB with GSNO and other nitrosothiols (RSNOs) in order to determinate RSNOs in human plasma. LODc for RSNOs in plasma ultrafiltrate was 30 nM (injected concentration, 50 μL loop), the DLR ranged between 0.08 and 50 μM and the CV% was 6.5% at 300 nM concentration level. Reduced and oxidized thiols spiked to plasma did not interfere with the measurement of RSNOs. We found that the sampling procedure was critical for the recovery of endogenous and spiked RSNOs. The ultrafiltrate samples of plasma of 8 healthy humans contained 1460 ± 310 CysNO, 1000 ± 330 nM HCysNO and 320 ± 60 nM GSNO if blood was sampled in a mixture NEM/ethylendiaminotetracetic acid (EDTA)/serine–borate complex (SBC), where serine–borate complex is a potent inhibitor of γ-glutamyltransferase, an enzyme involved in the conversion of GSNO into CysGlyNO. In the absence of SBC during the sampling of blood GSNO concentration found in the ultrafiltrate was lower (at level of the determination limit in plasma ultrafiltrate, i.e. 75 nM) and the peak of CysGlyNO appeared, which corresponded to a concentration of 200 ± 60 nM ( N = 4 blood samples).

Optimization of a procedure for the selective isolation of some powerful aroma thiols: Development and validation of a quantitative method for their determination in wine

This paper deals with the isolation properties of four relevant wine mercaptans in two different separation systems and with the subsequent development, optimization and validation of an analytical procedure for their quantitative determination. 4-Methyl-4-mercaptopentanone (4M4MP), 2-furanmethanethiol (FFT), 3-mercaptohexanol (3MH) and 3-mercaptohexyl acetate (AMH) can be quantitatively extracted from 200ml of wine in a bed packed with 1g of LiChrolut EN resins. Fatty acids and diverse interfering compounds are removed by rinsing with an aqueous solution with a 40% of methanol and buffered at pH 7.2 with α,α,α-tris-(hydroxymethyl)-aminomethane (TRIS) 0.2M. Mercaptans can be further isolated by extraction with an aqueous solution of 1mM p-hydroxymercury benzoate. Best results were achieved with an extraction with a solution at pH 10.7 with 0.2M 4-(2-hydroxyethyl)piperazine-1-ethanesulfonic acid (HEPES), further acidification to pH 7.5, release of thiols by the addition of dithioerythritol and extraction with 2×0.75ml dichloromethane. The extract is concentrated to 200 and 20μl are finally injected in a gas chromatograph–ion trap mass spectrometric system. Method detection limits are 0.8, 6, 15 and 5ngl−1 for 4M4MP, FFT, MH and AMH, respectively. The recovery in the sample pre-treatment was 76, 45, 75 and 95%, respectively. Repeatability and linearity are also satisfactory. Different critical aspects, such as the effect of air or the evaporation of the extract were also studied.

Determination and characterization of phytochelatins by liquid chromatography coupled with on line chemical vapour generation and atomic fluorescence spectrometric detection

Liquid chromatography (LC) coupled on line with UV/visible diode array detector (DAD) and cold vapour generation atomic fluorescence spectrometry (CVGAFS) has been developed for the speciation, determination and characterization of phytochelatins (PCs). The method is based on a bidimensional approach, e.g. on the analysis of synthetic PC solutions (apo-PCs and Cd 2+-complexed PCs) (i) by size exclusion chromatography coupled to UV diode array detector (SEC–DAD); (ii) by the derivatization of PC –SH groups in SEC fractions by p-hydroxymercurybenzoate (PHMB) and the indirect detection of PC-PHMB complexes by reversed phase liquid chromatography coupled to atomic fluorescence detector (RPLC–CVGAFS). MALDI-TOF/MS (matrix assisted laser desorption ionization time of flight mass spectrometry) analysis of underivatized synthetic PC samples was performed in order have a qualitative information of their composition. Quantitative analysis of synthetic PC solutions has been performed on the basis of peak area of PC-PHMB complexes of the mercury specific chromatogram and calibration curve of standard solution of glutathione (GSH) complexed to PHMB (GS-PHMB). The limit of quantitation (LOQ) in terms of GS-PHMB complex was 90 nM (CV 5%) with an injection volume of 35 μL, corresponding to 3.2 pmol (0.97 ng) of GSH. The method has been applied to analysis of extracts of cell cultures from Phaeodactylum tricornutum grown in Cd-containing nutrient solutions, analysed by SEC–DAD–CVGAFS and RPLC–DAD–CVGAFS.

Characterization of denatured metallothioneins by reversed phase coupled with on-line chemical vapour generation and atomic fluorescence spectrometric detection

A new analytical hyphenated technique is proposed for determination and characterization of thiolic proteins, based on reverse phase chromatography (RPC) coupled on-line with cold vapour generation atomic fluorescence spectrometry (CVGAFS). Proteins are pre-column simultaneously denatured and derivatized in phosphate buffer solution containing 8.0 mol l −1 urea and p-hydroxymercurybenzoate (PHMB). The derivatized proteins are separated on a C4 Vydac Reverse Phase column. Post-column on-line reaction of derivatized denatured proteins with bromine, generated in situ by KBr/KBrO 3 in HCl medium, allowed the fast conversion of both the uncomplexed PHMB and of the PHMB bound to proteins to inorganic mercury, also in the presence of methanol in the RPC eluent phase. Hg(II) is selectively detected by AFS in a Ar/H 2 miniaturized flame after sodium borohydride reduction to Hg°. Under optimized conditions, on-line bromine treatment gives a 98 ± 2% recovery of both free and protein-complexed PHMB. The effect of methanol on the sensitivity of Hg(II) detection was studied and controlled. RPC-CVGAFS system has been applied to the analysis of metallothioneins from rabbit liver (MT RL) standard solutions, and their commercial isoforms MT-1 and MT-2. The analysis of denatured, PHMB-complexed MTs allowed the determination of the number of thiolic groups complexed by PHMB. It was found that MTs from rabbit liver have 10.0 ± 0.3 (MT-1) and 6.7 ± 0.3 (MT-2 and MT RL) –SH groups complexed by PHMB. The detection limit (LODc) for PHMB in 95% methanol in the optimized conditions was about 9.3 × 10 −9 mol l −1 and for the denatured MTs LODc was about 8.6 × 10 −10 mol l −1, taking into account an approximate complexating ratio PHMB:MTs of 7:1.

Study of the disulfide reduction of denatured proteins by liquid chromatography coupled with on-line cold-vapor-generation atomic-fluorescence spectrometry (LC-CVGAFS).

Hydrophobic-interaction chromatography coupled on-line with chemical-vapor-generation atomic-fluorescence spectrometry (HIC-CVGAFS), optimized recently for the analysis of thiol-containing proteins under denaturing conditions, has been used to study the chemical reduction of denatured proteins. Four proteins chosen as models (human serum albumin (HSA), bovine serum albumin (BSA), alpha-lactalbumin (alpha-Lac) from bovine milk, and lysozyme from chicken egg (Lys)) were denatured with urea and reduced with dithiothreitol (DTT), with selenol as catalyst. The method is based on derivatization of the -SH groups of proteins with p-hydroxymercurybenzoate (PHMB), followed by HIC separation and post-column on-line reaction of the derivatized reduced, denatured proteins with bromine generated in situ. HgII, derived from rapid conversion of uncomplexed and protein-complexed PHMB, is selectively detected by AFS in an Ar/H2 miniaturized flame after sodium borohydride (NaBH4) reduction to Hg degrees . The yield of the reduction was studied as a function of reductant concentration, reduction time (tred), and urea concentration. Results showed that the optimum values for DTT and selenol concentrations and for tred were between 1 and 100 mmol L(-1) and between 1 and 20 min, respectively, depending on the protein studied. The percentage disulfide bond reduction increases as the urea concentration used for protein denaturation increases, giving a single-step sigmoid increment for single-domain, low-MW proteins (alpha-Lac and Lys), and a two-step sigmoid increment for multi-domain, high MW proteins (HSA and BSA). The shapes of plots of percentage reduced disulfide against urea concentration are characteristic of each protein and are correlated with the location of S-S in the protein. Under the adopted conditions complete protein denaturation is the conditio sine qua non for obtaining 100% S-S reduction. The detection limit for denatured, reduced proteins examined under the optimized conditions was found to be in the range 1-5 x 10(-12) mol L(-1) (10-30 pg), depending on the protein considered.

Hydrophobic interaction chromatography coupled with atomic fluorescence spectrometric detection: Effect of the denaturation on the determination of thiolic proteins

Hydrophobic interaction chromatography coupled online with chemical vapour atomic fluorescence spectrometry (HIC–CVGAFS) has been optimized for the analysis of thiolic proteins in denaturing conditions. Proteins are pre-column simultaneously denatured and derivatized in phosphate buffer solution containing 8.0moldm−3 urea and p-hydroxymercurybenzoate (PHMB) and the derivatized denatured proteins are separated on a silica HIC Eichrom Propyl column in the presence of 8.0M urea in the mobile phase. Post-column online reaction of derivatized denatured proteins with bromine, generated in situ by KBr/KBrO3 in HCl medium, allowed the fast conversion of the uncomplexed PHMB and of the PHMB bound to proteins to inorganic mercury also in presence of urea. Hg2+, present in solution as Hg2+–urea complex, is selectively detected by AFS in a Ar/H2 miniaturized flame after sodium borohydride reduction to Hg. Under optimized conditions, online bromine treatment gives a 100±2% recovery of both free and protein-complexed PHMB. Denatured glyceraldehyde-3-phosphate dehydrogenase, aldolase, lactate dehydrogenase, trioso phosphate isomerase and β-lactoglobulin have been examined. As the sensitivity and limit of detection of proteins in the HIC–CVGAFS apparatus depends on number of SH groups reacting with PHMB, the denaturation process, which increases the number of PHMB-reactive thiolic groups in proteins, improves the analytical performances of the described system in protein analysis. The detection limit for the denatured proteins examined was found in the range of 10−10–10−12moldm−3, depending on the considered protein, with linear calibration curves spanning over four decades of concentration.

Selective determination of thiolic proteins by hydrophobic interaction chromatography coupled with on-line cold vapour atomic fluorescence spectrometry

A new analytical method is proposed for the determination and characterization of thiolic proteins, based on hydrophobic interaction chromatography (HIC) coupled on-line with cold vapour atomic fluorescence spectrometry (CVAFS). Thiolic groups are derivatized pre-column by p-hydroxymercurybenzoate (PHMB) and the derivatized proteins are separated on a TSKgel Ether-5PW column. Post-column on-line reaction of derivatized proteins with bromine, generated in situ by KBr/KBrO3 in HCl medium, allowed the fast conversion of protein-bound PHMB to inorganic mercury, Hg(II), which is selectively detected by AFS after sodium borohydride reduction to Hg0. Under optimized conditions, on-line bromine treatment gives a 85 ± 2% recovery of both free and protein-complexed PHMB in less than 2.5 s and at room temperature. Glyceraldehyde-3-phosphate dehydrogenase, aldolase, pyruvate kinase, trioso phosphate isomerase and phospho-glucose isomerase have been examined. Sensitivity and limit of detection of proteins depends on the number of –SH groups reacting with PHMB and are in the range of 10−8–10−9 mol dm−3 with calibration curves spanning over four decades of concentration.

Human serum paraoxonase (PON 1) is inactivated by oxidized low density lipoprotein and preserved by antioxidants

Human serum paraoxonase (PON1) can protect low density lipoprotein (LDL) from oxidation induced by either copper ion or by the free radical generator azo bis amidinopropane hydrochloride (AAPH). During LDL oxidation in both of these systems, a time-dependent inactivation of PON arylesterase activity was observed. Oxidized LDL (Ox-LDL) produced by lipoprotein incubation with either copper ion or with AAPH, indeed inactivated PON arylesterase activity by up to 47% or 58%, respectively. Three possible mechanisms for PON inactivation during LDL oxidation were considered and investigated: copper ion binding to PON, free radical attack on PON, and/or the effect of lipoprotein-associated peroxides on the enzyme. As both residual copper ion and AAPH are present in the Ox-LDL preparations and could independently inactivate the enzyme, the effect of minimally oxidized (Ox-LDL produced by LDL storage in the air) on PON activity was also examined. Oxidized LDL, as well as oxidized palmitoyl arachidonoyl phosphatidylcholine (PAPC), lysophosphatidylcholine (LPC, which is produced during LDL oxidation by phospholipase A2-like activity), and oxidized cholesteryl arachidonate (Ox-CA), were all potent inactivators of PON arylesterase activity (PON activity was inhibited by 35%–61%). PON treatment with Ox-LDL (but not with native LDL), or with oxidized lipids, inhibited its arylesterase activity and also reduced the ability of the enzyme to protect LDL against oxidation. PON Arylesterase activity however was not inhibited when PON was pretreated with the sulfhydryl blocking agent, p-hydroxymercurybenzoate (PHMB). Similarly, on using recombinant PON in which the enzyme’s only free sulfhydryl group at the position of cysteine-284 was mutated, no inactivation of the enzyme arylesterase activity by Ox-LDL could be shown. These results suggest that Ox-LDL inactivation of PON involves the interaction of oxidized lipids in Ox-LDL with the PON’s free sulfhydryl group. Antioxidants such as the flavonoids glabridin or quercetin, when present during LDL oxidation in the presence of PON, reduced the amount of lipoprotein-associated lipid peroxides and preserved PON activities, including its ability to hydrolyze Ox-LDL cholesteryl linoleate hydroperoxides. We conclude that PON’s ability to protect LDL against oxidation is accompanied by inactivation of the enzyme. PON inactivation results from an interaction between the enzyme free sulfhydryl group and oxidized lipids such as oxidized phospholipids, oxidized cholesteryl ester or lysophosphatidylcholine, which are formed during LDL oxidation. The action of antioxidants and PON on LDL during its oxidation can be of special benefit against atherosclerosis since these agents reduce the accumulation of Ox-LDL by a dual effect: i.e. prevention of its formation, and removal of Ox-LDL associated oxidized lipids which are generated during LDL oxidation.

Mechanism of Biochemical Action of Substituted 4-Methylbenzopyran-2-ones. Part 4: Hyperbolic Activation of Rat Liver Microsomal NADPH-Cytochrome C Reductase by the Novel Acetylator 7,8-Diacetoxy-4-methylcoumarin

The effect of 7,8-diacetoxy-4-methylcoumarin (DAMC) has been studied on hepatic NADPH cytochrome C reductase—an enzyme participating in the microsomal electron transport. The preincubation of liver microsomes with DAMC resulted in a time-dependent activation of NADPH cytochrome C reductase. The catalytic activity of the enzyme enhanced nearly 600% by 25μM concentration of DAMC after 10min of preincubation. The action of DAMC on the reductase resulted in enhanced νmax while Km remained constant. A plot of 1/νmax as a function of DAMC concentration resulted in a non-linear, but rectangular hyperbola indicative of hyperbolic activation. DAMC was also proved to be effective in significantly enhancing the activity of NADPH cytochrome C reductase in vivo. 7,8-Dihydroxy-4-methylcoumarin (DHMC), the deacetylated product of DAMC failed to irreversibly activate the enzyme. The activation effect of DAMC upon the enzyme was abolished by p-hydroxymercury benzoate. The role of a transacetylase in transferring the acetyl group of DAMC to the amino acid(s) of the active site of NADPH cytochrome C reductase causing irreversible enzyme activation is enunciated. ©

Site and Significance of Cysteine Residues in Xylose Reductase fromNeurospora crassaas Deduced by Fluorescence Studies

Inactivation of xylose reductase (XR) by p-hydroxymercury benzoate (PHMB) was found to be biphasic with second-order rate constants of 80 and 6 M−1s−1for the fast (kf) and slow (ks) phase respectively. Spectroscopic studies indicated that the inactivation was due to modification of one Cys residue per molecule of XR and not due to subsequent disruption of the quaternary structure. The binding of NADPH to XR (Kd0.9 μM) was depressed on modification of the enzyme by PHMB (Kd2.3 μM). The dependence of PHMB induced inactivation of XR in the presence of alcohols and varying temperature revealed that the Cys residue is situated in a hydrophobic microenvironment and is not involved in hydrogen bonding. Our present investigation usingo-phthalaldehyde (OPTA) as the chemical initiator for fluorescent chemo-affinity labeling and double inhibition studies indicates that Cys residues involved in the reaction with PHMB (SHI) and OPTA (SHII) are distinctly different. Experimental evidence presented here serves to implicate that SHIlocated in a hydrophobic microenvironment at the high affinity NADPH binding site of XR plays a role in the binding of the coenzyme to XR, whereas SHIIserves to maintain the conformation of the active site essential for catalysis by interacting with the NH2group of an essential lysine residue.

Chemical modification of xylanases: evidence for essential tryptophan and cysteine residues at the active site

N-Bromosuccinimide (NBS) completely inactivated xylanases from Chainia and alkalophilic and thermophilic (AT) Bacillus with a concomittant decrease in absorption at 280 nm and with second-order rate constants of 10500 and 5000 M −1ṡ min −1, respectively at pH 6.0 and 25°C. The kinetic analysis of inactivation indicated that one and three tryptophan residues were essential for the xylanase activity from Chainia and Bacillus, respectively. The xylanases were also inhibited by 2-hydroxy-5-nitrobenzyl bromide (HNBB). The modification of cysteine residues by p-hydroxymercurybenzoate (PHMB) and N-ethylmaleimide did not cause a loss in activity of the xylanase from Bacillus, whereas that from Chainia was completely inactivated. The kinetics of inactivation revealed the involvement of one cysteine residue for xylanase from Chainia with a second-order rate constant of 50000 M −1ṡmin −1. The PHMB-modified enzyme failed to show the presence of titrable -SH groups. Xylan afforded complete protection against inactivation by NBS, HNBB and PHMB, indicating the involvement of tryptophan and cysteine residues at the substrate-binding region of the enzyme.

Essential residues in lysolecithin:lysolecithin acyltransferase from rabbit lung: Assessment by chemical modification

The inhibition of lysolecithin:lysolecithin acyltransferase by several specific reagents was studied. Diisopropyl fluorophosphate (DFP) completely inhibited both activities at a concentration of 4 m m. Activity was not protected by substrate and the enzyme showed a change in circular dichroism spectrum upon treatment with inhibitor. Phenylmethanesulfonyl fluoride, another serine-specific reagent, did not inhibit either hydrolysis or transacylation. Therefore, we suggest that DFP does not modify an active serine in the catalytic site. p-Hydroxymercury benzoate and N-ethylmaleimide (NEM) abolished both activities of the enzyme. The presence of substrate partially protected against inactivation. Far-uv CD spectrum of NEM-modified enzyme revealed no changes in protein structure. The existence of two classes of essential cysteine residues was deduced from kinetics of NEM inactivation. Both classes differ in NEM reactivity and also in their participation in the catalytic mechanism. A tyrosine-specific reagent, tetranitromethane, also inhibited hydrolysis and transacylation, following first-order kinetics. The partial protection by substrate suggested the possible existence of essential tyrosines near the active site. At pH 5.0 N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline inactivated hydrolysis but not transacylation. However, both of them remained unchanged at pH 6.5. The substrate prevented the loss of hydrolytic ability. Therefore, a carboxyl residue participating just in the catalytic mechanism of hydrolysis is proposed.

Disc electrophoretic studies of hemoglobin dissociation by p-hydroxymercury benzoate

The reaction of excess p-mercurybenzoate with human hemoglobin produces five electrophoretic species on polyacrylamide gel. Only two of these bands have been previously observed when starch gel was employed. The chemical and electrophoretic studies presented in this paper illustrate that the appearance of an “extra” band in the β zone is due to the ability of PAGE to separate the βb 2 PMB ⇋ β PMB equilibrium to its discrete components. The remaining bands are accounted for by the superior resolution of PAGE over starch gel electrophoresis which allowed the detection of two ( αβ) PMB dimer species.