Purification and properties of hydrogenase from phototrophic bacterium Thiocapsa roseopersicina]

The isolation method and some peoperties of purple sulphur bacteria (Thiocapsa roseopersicina strain BBS) hydrogenase are described Hydrogenase molecular weight is found to be 66000; it contains 3.7 moles of S2- and 3.9 moles of Fe2+ per one mole of the enzyme;pI=4.2. The enzyme absorption spectrum has the maximum at 400-412 nm which is characteristic of proteins containing non-haem iron. Hydrogenase is suggested to consist pf 4 subunits of two types: with molar weight 27000 and 6000. Unlike other hydrogenases, this enzyme is rather resistant to O2 and is more thermostable: the inactivation of the enzyme was observed at the temperature above 80 degrees C; Hydrogenase preparation catalyses D2-H2O exchange reaction, H2 evolution from the reduced methyl viologene (MV) and H2 absorption in the presense of MV or benzylviologene but not in the presense of NAD(P), FAD, FMN, azocarmine, methylene blue and ferricyanide.     

Purification and characterization of an iron-nickel hydrogenase from Thermococcus celer.

Thermococcus celer cells contain a single hydrogenase located in the cytoplasm, which has been purified to apparent homogeneity using three chromatographic steps: Q-Sepharose, DEAE-Fast Flow, and Sephacryl S-200. In vitro assays demonstrated that this enzyme was able to catalyze the oxidation as well as the evolution of H2. T. celer hydrogenase had an apparent MW of 155,000+/-30,000 by gel filtration. When analyzed by SDS polyacrylamide gel electrophoresis a single band of 41,000+/-2,000 was detected. Hydrogenase activity was also detected in situ in a SDS polyacrylamide gel followed by an activity staining procedure revealing a single band corresponding to a protein of apparent Mr 84,000+/-3,000. Measurements of iron and acid-labile sulfide in different preparations of T. celer hydrogenase gave values ranging from 24 to 30 g-atoms Fe/mole of protein and 24 to 36 g-atoms of acid-labile sulfide per mole of protein. Nickel is present in 1.9-2.3 atoms per mole of protein. Copper, tungsten, and molybdenum were detected in amounts lower than 0.5 g-atoms per mole of protein. T. celer hydrogenase was inactive at ambient temperature, exhibited a dramatic increase in activity above 70 degrees C, and had an optimal activity above 90 degrees C. This enzyme showed no loss of activity after incubation at 80 degrees C for 28 h, but lost 50% of its initial activity after incubation at 96 degrees C for 20 h. Hydrogenase exhibited a half-life of approximately 25 min in air. However, after treating the air-exposed sample with sodium dithionite, more than 95% of the original activity was recovered. Copper sulfate, magnesium chloride and nitrite were also inactivators of this enzyme.     

Properties of Stable Hydrogenase from the Purple Sulfur Bacterium Lamprobacter modestohalophilus

Some properties of a hydrogenase from the recently isolated phototrophic sulfur bacterium Lamprobacter modestohalophilus strain Syvash and its resistance to a number of inactivating factors have been investigated. The enzyme consists of two subunits, 64 and 30 kD; pI = 4.5. The optimal pH was 8.5-9.5 for hydrogen uptake and 4.0 for H2 evolution. Hydrogenase preparations were resistant to the effects of O2, CO, and temperature, revealing high stability under storage. A considerable inactivation of the enzyme was observed at temperatures above 80 degrees C; the temperature optimum of methyl viologen reduction by H2 was 85 degrees C. Inhibitory effects of Ni2+, Cd2+, and Mg2+ on the hydrogenase activity were shown to be reversible and competitive with respect to methyl viologen in the hydrogen oxidation reaction.     

Characterization of hydrogenase from the hyperthermophilic archaebacterium, Pyrococcus furiosus

The archaebacterium, Pyrococcus furiosus, grows optimally at 100 degrees C by a fermentative type metabolism in which H2 and CO2 are the only detectable products. The organism also reduces elemental sulfur (S0) to H2S. Cells grown in the absence of S0 contain a single hydrogenase, located in the cytoplasm, which has been purified 350-fold to apparent homogeneity. The yield of H2 evolution activity from reduced methyl viologen at 80 degrees C was 40%. The hydrogenase has a Mr value of 185,000 +/- 15,000 and is composed of three subunits of Mr 46,000 (alpha), 27,000 (beta), and 24,000 (gamma). The enzyme contains 31 +/- 3 g atoms of iron, 24 +/- 4 g atoms of acid-labile sulfide, and 0.98 +/- 0.05 g atoms of nickel/185,000 g of protein. The H2-reduced hydrogenase exhibits an electron paramagnetic resonance (EPR) signal at 70 K typical of a single [2Fe-2S] cluster, while below 15 K, EPR absorption is observed from extremely fast relaxing iron-sulfur clusters. The oxidized enzyme is EPR silent. The hydrogenase is reversibly inhibited by O2 and is remarkably thermostable. Most of its H2 evolution activity is retained after a 1-h incubation at 100 degrees C. Reduced ferredoxin from P. furiosus also acts as an electron donor to the enzyme, and a 350-fold increase in the rate of H2 evolution is observed between 45 and 90 degrees C. The hydrogenase also catalyzes H2 oxidation with methyl viologen or methylene blue as the electron acceptor. The temperature optimum for both H2 oxidation and H2 evolution is greater than 95 degrees C. Arrhenius plots show two transition points at approximately 60 and approximately 80 degrees C independent of the mode of assay. That occurring at 80 degrees C is associated with a dramatic increase in H2 production activity. The enzyme preferentially catalyzes H2 production at all temperatures examined and appears to represent a new type of "evolution" hydrogenase.     

Regulation of hydrogenase formation is temperature sensitive and plasmid coded in Alcaligenes eutrophus

Alcaligenes eutrophus grew well autotrophically with molecular hydrogen at 30 degrees C, but failed to grow at 37 degrees C (Hox Ts). At this temperature the strain grew well heterotrophically with a variety of organic compounds and with formate as an autotrophic substrate, restricting the thermolabile character to hydrogen metabolism. The soluble hydrogenase activity was stable at 37 degrees C. The catalytic properties of the wild-type enzyme were identical to those of a mutant able to grow lithoautotrophically at 37 degrees C (Hox Tr). Soluble hydrogenase was not rapidly degraded at elevated temperatures since the preformed enzyme remained stable for at least 5 h in resting cells or was diluted by growth, as shown in temperature shift experiments. Immunochemical studies revealed that the formation of the hydrogenase proteins was temperature sensitive. No cross-reactivity was detected above temperatures of 34 degrees C. The genetic information of Hox resides on a self-transmissible plasmid in A. eutrophus. Using Hox Tr mutants as donors of hydrogen-oxidizing ability resulted in Hox+ transconjugants which not only had recovered plasmid pHG1 and both hydrogenase activities but also were temperature resistant. This is evidence that the Hox Tr phenotype is coded by plasmid pHG1.     

Purification and characterization of the hydrogen uptake hydrogenase from the hyperthermophilic archaebacterium Pyrodictium brockii.

Pyrodictium brockii is a hyperthermophilic archaebacterium with an optimal growth temperature of 105 degrees C. P. brockii is also a chemolithotroph, requiring H2 and CO2 for growth. We have purified the hydrogen uptake hydrogenase from membranes of P. brockii by reactive red affinity chromatography and sucrose gradient centrifugation. The molecular mass of the holoenzyme was 118,000 +/- 19,000 Da in sucrose gradients. The holoenzyme consisted of two subunits by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The large subunit had a molecular mass of 66,000 Da, and the small subunit had a molecular mass of 45,000 Da. Colorometric analysis of Fe and S content in reactive red-purified hydrogenase revealed 8.7 +/- 0.6 mol of Fe and 6.2 +/- 1.2 mol of S per mol of hydrogenase. Growth of cells in 63NiCl2 resulted in label incorporation into reactive red-purified hydrogenase. Growth of cells in 63NiCl2 resulted in label incorporation into reactive red-purified hydrogenase. Temperature stability studies indicated that the membrane-bound form of the enzyme was more stable than the solubilized purified form over a period of minutes with respect to temperature. However, the membranes were not able to protect the enzyme from thermal inactivation over a period of hours. The artificial electron acceptor specificity of the pure enzyme was similar to that of the membrane-bound form, but the purified enzyme was able to evolve H2 in the presence of reduced methyl viologen. The Km of membrane-bound hydrogenase for H2 was approximately 19 microM with methylene blue as the electron acceptor, whereas the purified enzyme had a higher Km value.     

Purification and properties of membrane-bound hydrogenase from Azotobacter vinelandii

Uptake hydrogenase (EC 1.12) from Azotobacter vinelandii has been purified 250-fold from membrane preparations. Purification involved selective solubilization of the enzyme from the membranes, followed by successive chromatography on DEAE-cellulose, Sephadex G-100, and hydroxylapatite. Freshly isolated hydrogenase showed a specific activity of 110 mumol of H2 uptake (min X mg of protein)-1. The purified hydrogenase still contained two minor contaminants that ran near the front on sodium dodecyl sulfate-polyacrylamide gels. The enzyme appears to be a monomer of molecular weight near 60,000 +/- 3,000. The pI of the protein is 5.8 +/- 0.2. With methylene blue or ferricyanide as the electron acceptor (dyes such as methyl or benzyl viologen with negative midpoint potentials did not function), the enzyme had pH optima at pH 9.0 or 6.0, respectively, It has a temperature optimum at 65 to 70 degrees C, and the measured half-life for irreversible inactivation at 22 degrees C by 20% O2 was 20 min. The enzyme oxidizes H2 in the presence of an electron acceptor and also catalyzes the evolution of H2 from reduced methyl viologen; at the optimal pH of 3.5, 3.4 mumol of H2 was evolved (min X mg of protein)-1. The uptake hydrogenase catalyzes a slow deuterium-water exchange in the absence of an electron acceptor, and the highest rate was observed at pH 6.0. The Km values varied widely for different electron acceptors, whereas the Km for H2 remained virtually constant near 1 to 2 microM, independent of the electron acceptors.     

Partial purification and characterization of the first hydrogenase isolated from a thermophilic sulfate-reducing bacterium.

A soluble [NiFe] hydrogenase has been partially purified from the obligate thermophilic sulfate-reducing bacterium Thermodesulfobacterium mobile. A 17% purification yield was obtained after four chromatographic steps and the hydrogenase presents a purity index (A398 nm/A277 nm) equal to 0.21. This protein appears to be 75% pure on SDS-gel electrophoresis showing two major bands of molecular mass around 55 and 15 kDa. This hydrogenase contains 0.6-0.7 nickel atom and 7-8 iron atoms per mole of enzyme and has a specific activity of 783 in the hydrogen uptake reaction, of 231 in the hydrogen production assay and of 84 in the deuterium-proton exchange reaction. The H2/HD ratio is lower than one in the D2-H+ exchange reaction. The enzyme is very sensitive to NO, relatively little inhibited by CO but unaffected by NO2-. The EPR spectrum of the native hydrogenase shows the presence of a [3Fe-4S] oxidized cluster and of a Ni(III) species.     

The extremely thermophilic eubacterium, Thermotoga maritima, contains a novel iron-hydrogenase whose cellular activity is dependent upon tungsten.

Thermotoga maritima is the most thermophilic eubacterium currently known and grows up to 90 degrees C by a fermentative metabolism in which H2, CO2, and organic acids are end products. It was shown that the production of H2 is catalyzed by a single hydrogenase located in the cytoplasm. The addition of tungsten to the growth medium was found to increase both the cellular concentration of the hydrogenase and its in vitro catalytic activity by up to 10-fold, but the purified enzyme did not contain tungsten. It is a homotetramer of Mr 280,000 and contains approximately 20 atoms of Fe and 18 atoms of acid-labile sulfide/monomer. Other transition metals, including nickel (and also selenium), were present in only trace amounts (less than 0.1 atoms/monomer). The hydrogenase was unstable at both 4 and 23 degrees C, even under anaerobic conditions, but no activity was lost in anaerobic buffer containing glycerol and dithiothreitol. Under these conditions the enzyme was also quite thermostable (t50% approximately 1 h at 90 degrees C) but extremely sensitive to irreversible inactivation by O2 (t50% approximately 10 s in air). The optimum pH ranges for H2 evolution and H2 oxidation were 8.6-9.5 and greater than or equal to 10.4, respectively, and the optimum temperature for catalytic activity was above 95 degrees C. In contrast to mesophilic Fe hydrogenases, the T. maritima enzyme had very low H2 evolution activity, did not use T. maritima ferredoxin as an electron donor for H2 evolution, was inhibited by acetylene but not by nitrite, and exhibited EPR signals typical of [2Fe-2S]1+ clusters. Moreover, the oxidized enzyme did not exhibit the rhombic EPR signal that is characteristic of the catalytic iron-sulfur cluster of mesophilic Fe hydrogenases. These data suggest that T. maritima hydrogenase has a different FeS site and/or mechanism for catalyzing H2 production. The potential role of tungsten in regulating the activity of this enzyme is discussed.     

Catalytic and thermodynamic properties of the urocanate hydratase reaction.

Urocanate hydratase (4-imidazolone-5-propionate hydro-lyase, EC 4.2.1.49) isolated from Pseudomonas putida contains covalently bound alpha-ketobutyrate as its cofactor. In the process of examining the mechanism by which alpha-ketobutyrate serves in this capacity, various thermodynamic parameters and temperature effects on urocanate hydratase activity were determined. As the equilibrium constant at 15 degrees C for imidazooone propionate formation from urocanate is approximately 69, regardless of whether urocanic acid or chemically synthesized imidazolone propionate is used as the initial substrate, it is concluded that the reaction is freely reversible. DeltaG degrees ', deltaH degrees ' and deltaS degrees ' were --2.5 kcal/mole, +5.2 kcal/mole and +26 cal/deg mole, respectively. Measurement of first-order reaction rates at various temperatures, in order to calculate the Arrhenius activation energy, showed a sharp break in the Arrhenius plot at 29 degrees C. Further examination of this phenomenon by determining s20,w values of urocanate hydratase as a function of temperature revealed a dramatic change at 31 degrees C. Since the enzyme in both experiments reverts to its original state when the temperature is lowered back below the transition point, it is proposed that urocanate hydratase undergoes a reversible conformational change or partial dissociation which affects its catalytic properties in the range of 29--31 degrees C.     

Comparative characterization of two distinct hydrogenases from Anabaena sp. strain 7120

Two distinct hydrogenases, hereafter referred to as "uptake" and "reversible" hydrogenase, were extracted from Anabaena sp. strain 7120 and partially purified. The properties of the two enzymes were compared in cell-free extracts. Uptake hydrogenase was largely particulate, and although membrane bound, it could catalyze an oxyhydrogen reaction. Particulate and solubilized uptake hydrogenase could catalyze H2 uptake with a variety of artificial electron acceptors which had midpoint potentials above 0 mV. Reversible hydrogenase was soluble, could donate electrons rapidly to electron acceptors of both positive and negative midpoint potential, and could evolve H2 rapidly when provided with reduced methyl viologen. Uptake hydrogenase was irreversibly inactivated by O2, whereas reversible hydrogenase was reversibly inactivated and could be reactivated by exposure to dithionite or H2. Reversible hydrogenase was stable to heating at 70 degrees C, but uptake hydrogenase was inactivated with a half-life of 12 min at this temperature. Uptake hydrogenase was eluted from Sephadex G-200 in a single peak of molecular weight 56,000, whereas reversible hydrogenase was eluted in two peaks with molecular weights of 165,000 and 113,000. CO was competitive with H2 for each enzyme; the Ki's for CO were 0.0095 atm for reversible hydrogenase and 0.039 atm for uptake hydrogenase. The pH optima for H2 evolution and H2 uptake by reversible hydrogenase were 6 and 9, respectively. Uptake hydrogenase existed in two forms with pH optima of 6 and 8.5. Both enzymes had very low Km's for H2, and neither was inhibited by C2H2.     

Fluorescent labelling of 6-phosphogluconate dehydrogenase from Bacillus stearothermophilus.

The thermophilic 6-phosphogluconate dehydrogenase from Bacillus stearothermophilus was inhibited upon specific modification of the -SH group of cysteine residues by 7-chloro-4-nitrobenzo-2-oxa-1, 3-diazole (NBD-Cl) at pH 7.0. By using 20-100-fold molar excess of NBD-CL the reaction occurs slowly at pH 7.0 as a first order process. Partial protection from inactivation was observed when the substrate 6-phosphogluconate or the coenzyme NADP was added to the reaction mixture. Complete inactivation was achieved upon modification of 1.9 of the six cysteine residues per mole of enzyme, which corresponds to nearly one residue per enzyme subunit. Circular dichroism measurements suggest that the gross structure of the protein molecule is practically unchanged upon reaction of the enzyme with NBD-Cl. Melting profile experiments revealed a single transition occurring at about 65 degrees C. Analogously, the profile of intensity of the fluorescence emission at 520 nm of the enzyme-bound S-NBD groups versus temperature indicated a midpoint of transition near 65 degrees C. Since this melting temperature corresponds closely to that observed with the native enzyme, these results would indicate that the molecular organizations of the native and modified enzyme are similar and stabilized by similar interactions within the polypeptide chain.     

Stability and sulfur-reduction activity in non-aqueous phase liquids of the hydrogenase from the hyperthermophile Pyrococcus furiosus.

Hydrogenase from the hyperthermophilic archaeon, Pyrococcus furiosus, catalyzes the reversible activation of H(2) gas and the reduction of elemental sulfur (S degrees ) at 90 degrees C and above. The pure enzyme, modified with polyethylene glycol (PEG), was soluble (> 5 mg/mL) in toluene and benzene with t(1/2) values of more than 6 h at 25 degrees C. At 100 degrees C the PEG-modified enzyme was less stable in aqueous solution (t(1/2) approximately 10 min) than the native (unmodified) enzyme (t(1/2) approximately 1 h), but they exhibited comparable H(2) evolution, H(2) oxidation, and S degrees reduction activities at 80 degrees C. The H(2) evolution activity of the modified enzyme was twice that of the unmodified enzyme at 25 degrees C. The PEG-modified enzyme did not catalyze S degrees reduction (at 80 degrees C) in pure toluene unless H(2)O was added. The mechanism by which hydrogenase produces H(2)S appears to involve H(2)O as the proton source and H(2) as the electron source. The inability of the modified hydrogenase to catalyze S degrees reduction in a homogeneous non-aqueous phase complicates potential applications of this enzyme.     

Enzymatic breakdown of threonine by threonine aldolase

1. The enzyme which splits threonine to acetaldehyde and glycine has been partially purified from rat liver (five- to sixfold purification) and the name threonine aldolase proposed for it. 2. The general properties of threonine aldolase have been studied. The enzyme is unstable to a pH below 5. The pH optimum of the enzyme reaction is at 7.5-7.7. The initial rate of production of acetaldehyde is proportional to the enzyme concentration, and when the enzyme concentration is constant, the production of acetaldehyde is proportional to the time, provided that the substrate is in excess. The enzyme is inhibited by the carbonyl group reagent, hydroxylamine. Attempts to demonstrate that pyridoxal phosphate is a cofactor were unsuccessful. 3. The enzyme splits only L-allothreonine and L-threonine and is inactive against the D-forms of these amino acids. 4. The enzyme reaction on DL-allothreonine follows first order kinetics. From the first order velocity constants and the initial rates of the rates of the reaction at various substrate concentrations the Michaelis constant, Ks, for this substrate has been evaluated. Michaelis constants have also been determined for threonine. 5. The optimum temperature for the enzymatic breakdown of DL-allothreonine at pH 7.65 was found to be 50 degrees C. in phosphate buffer and 48 degrees C. in tris-maleate buffer. The rate of thermal inactivation of the enzyme threonine aldolase obeys a first order reaction. The heat of thermal inactivation was calculated by the aid of the van't Hoff-Arrhenius equation to be 43,000 cal. per mole for the temperature range 41.2-46.6 degrees C. 6. Equivalent amounts of acetaldehyde and glycine were formed from DL-allothreonine and the enzymatic breakdown of DL-allothreonine was found to be irreversible.     

Distinct redox behaviour of prosthetic groups in ready and unready hydrogenase from Chromatium vinosum.

The redox behaviour of the Ni(III)/Ni(II) transition in hydrogenase from Chromatium vinosum is described and compared with the redox behaviour of the nickel ion in the F420-nonreducing hydrogenase from Methanobacterium thermoautotrophicum. Analogous to the situation in the oxidised hydrogenase of Desulfovibrio gigas (Fernandez, V.M., Hatchikian, E.C., Patil, D.S. and Cammack, R. (1986) Biochim. Biophys. Acta 883, 145-154), the C. vinosum enzyme can also exist in two forms: the 'unready' form (EPR characteristics of Ni(III): gx,y,z = 2.32, 2.24, 2.01) and the 'ready' form (EPR characteristics Ni(III): gx,y,z = 2.34, 2.16, 2.01). Like in the oxidised enzyme of M. thermoautotrophicum the Ni(III)/Ni(II) transition for the unready form titrated completely reversible (both at pH 6.0 and pH 8.0). In contrast, the reversibility of the Ni(III)/Ni(II) transition in the ready enzyme was strongly dependent on pH and temperature. At pH 6.0 and 2 degrees C reduction of Ni(III) in ready enzyme was completely irreversible, whereas at pH 8.0 and 30 degrees C Ni(III) in both ready and unready enzyme titrated with E0' = -115 mV (n = 1). Hampered redox equilibration between the ready enzyme and the mediating dyes is interpreted in terms of an obstruction of the electron transfer from nickel at the active site to the artificial electron acceptors in solution. The origin of this obstruction might be related to possible changes in the protein structure induced by the activation process. The E0'-value of the Ni(III)/Ni(II) equilibrium was pH sensitive (-60 mV/delta pH) indicating that reduction of nickel is coupled to a protonation. A similar pH-dependence was observed for the titration of the spin-spin interaction of Ni(III) and a special form of the [3Fe-4S]+ cluster (E0' = +150 mV, pH 8.0, 30 degrees C). Redox equilibration of this coupling was extremely sensitive to pH and temperature. The uncoupled [3Fe-4S]+ cluster titrated pH-independently with E0' = -10 mV (pH 8.0, 30 degrees C).     

Purification and characterization of putative alkaline [Ni-Fe] hydrogenase from unicellular marine green alga, Tetraselmis kochinensis NCIM 1605

Hydrogenase enzyme from the unicellular marine green alga Tetraselmis kochinensis NCIM 1605 was purified 467 fold to homogeneity. The molecular weight was estimated to be approximately 89kDa by SDS-PAGE. This enzyme consists of two subunits with molecular masses of approximately 70 and approximately 19kDa. The hydrogenase was found to contain 10g atoms of Fe and 1g of atom of Ni per mole of protein. The specific activity of hydrogen evolution was 50micromol H(2)/mg/h of enzyme using reduced methyl viologen as an electron donor. This hydrogenase enzyme has pI value approximately 9.6 representing its alkaline nature. The absorption spectrum of the hydrogenase enzyme showed an absorption peak at 425nm indicating that the enzyme had iron-sulfur clusters. The total of 16 cysteine residues were found per mole of enzyme under the denaturing condition and 20 cysteine residues in reduced denatured enzyme indicating that it has two disulfide bridges.     

Tissue metabolism and enzyme activities in the rodent Heterocephalus glaber, a poor temperature regulator.

1. Tissue oxygen uptake and enzyme activities were investigated in the naked mole rat, Heterocephalus glaber, a mammal notable for its low body temperature and metabolism and poor temperature regulating ability. 2. Q10 for O2 uptake of Heterocephalus crude liver homogenates ranged from 1.91 for the temperature interval 25-30 degrees C to 1.76 within the range 30-38 degrees C, values similar to those reported for typical homoiotherms. 3. Km pyruvate of lactate dehydrogenase in heart muscle had the same temperature dependence in the mole rat and mouse. 4. O2 uptake and cytochrome oxidase activity of skeletal muscle were higher for mole rat than mouse. The reverse was true for heart muscle. Brain and liver O2 uptake showed similar values for both species, while kidney O2 uptake was highest in the mouse. 5. Pyruvate kinase activity in heart and skeletal muscle was higher in mouse than mole rat, suggesting a greater reliance on glycolysis in the former. 6. Na+, K+ -ATPase activity of liver and kidney was 60% higher in mouse than mole rat, while brain was 30% higher in mouse. 7. The results indicate that the effects of temperature on tissue metabolism in the mole rat conform to those in typical homoiotherms. The low body temperature and O2 uptake in the mole rat find no expression in the tissue respiratory capacity.     

无溶剂体系中脂肪酶改造猪油制备功能性脂的研究

我国有丰富廉价的动植物油资源,但这一资源并未得到有效的利用,为了充分利用这些资源,开展了无溶剂系统脂肪酶催化猪油与辛酸酸解制备功能性脂的研究工作。脂肪酶筛选实验表明,在所选用的五种脂肪酶中,来自T .languginosa的固定化脂肪酶LiopzymeTLIM的催化效果最好。以LipozymeTLIM为催化剂,进一步研究了酶量、底物比率、反应时间、反应温度和水分添加量对猪油中辛酸插入率的影响。反应产物通过高效液相色谱法(HPLC)进行分析。研究结果表明,当脂肪酶量为20% (底物重量百分比)时,猪油中辛酸插入率最高。反应时间研究表明,当反应时间达到24h时,辛酸的插入率最高,达到38.77mol%。当猪油与辛酸的比率为1∶2 (摩尔比)时,辛酸的插入率最高,达到30 95mol%。在4 5～6 0℃范围之内,反应温度对辛酸插入率没有明显的影响,温度高于6 0℃时,辛酸插入率降低。水分添加量为2 5 %时,辛酸插入率最高,高达35 76mol%。     

Transport of Ca2+ and Na+ across the chromaffin-granule membrane.

The soluble hydrogenase (hydrogen-NAD+ oxidoreductase, EC 1.12.1.2) of Alcaligenes eutrophus H16 was shown to be stabilized by oxidation with oxygen and ferricyanide as long as electron donors and reducing compounds were absent. The simultaneous presence of H2, NADH and O2 in the enzyme solution, however, caused an irreversible inactivation of hydrogenase that was dependent on the O2 concentration. The half-life periods of 4 degrees C under partial pressures of 0.1, 5, 20 and 50% O2 were 11, 5, 2.5 and 1.5 h respectively. Evidence has been obtained that hydrogenase produces superoxide free radical anions (O2-.), which were detected by their ability to oxidize hydroxylamine to nitrite. The correlation between O2 concentration, nitrite formation and inactivation rates and the stabilization of hydrogenase by addition of superoxide dismutase indicated that superoxide radicals are responsible for enzyme inactivation. During short-term activity measurements (NAD+ reduction, H2 evolution from NADH), hydrogenase activity was inhibited by O2 only very slightly. In the presence of 0.7 mM-O2 an inhibition of about 20% was observed.