Inhibition of phenylalanine hydroxylase activity by alpha-methyl tyrosine, a potent inhibitor of tyrosine hydroxylase.

Inhibitors of phenylalanine hydroxylase and tyrosine hydroxylase were used in the assay of phenylalanine hydroxylase in liver and kidney of rats and mice. Parachlorophenylalanine (PCPA), methyl tyrosine methyl ester and dimethyl tyrosine methyl ester showed 5–15% inhibition while α-methyl tyrosine seemed to inhibit phenylalanine hydroxylase to the extent of 95–98% at concentrations of 5 × 10 ⁻⁵M –1 × 10 ⁻⁴M. After a phenylketonuric diet (0.12% PCPA + 3% excess phenylalanine), the liver showed 60% phenylalanine hydroxylase activity and kidney 82% that present in pair-fed normals. Hepatic activity was normal after 8 days refeeding normal diet whereas kidney showed 63% of normal activity. The PCPA-fed animals showed 34% in liver and 38% in kidney as compared to normals; in both cases normal activity was noticed after refeeding. The phenylalanine-fed animals showed activity similar to that seen in phenylketonuric animals. The temporary inducement of phenylketonuria in these animals may be due to a slight change in conformation of the phenylalanine hydroxylase molecule; once the normal diet is resumed, the enzyme reverts back to its active form. This paper also suggests that α-methyl tyrosine when fed in conjunction with the phenylketonuric diet may suppress phenylalanine hydroxylase activity completely in the experimental animals thus yielding normal tyrosine levels as seen in human phenylketonurics.     

The quantitative determination of phenylalanine hydroxylase in rat tissues. Its developmental formation in liver

A sensitive method was developed for determining the phenylalanine hydroxylase activity of crude tissue preparations in the presence of optimum concentrations of the 6,7-dimethyl-5,6,7,8-tetrahydropterin cofactor (with ascorbate or dithiothreitol to maintain its reduced state) and substrate. Tissue distribution studies showed that, in addition to the liver, the kidney also contains significant phenylalanine hydroxylase activity, one-sixth (in rats) or half (in mice) as much per g as does the liver. The liver and the kidney enzyme have similar kinetic properties; both were located in the soluble phase and were inhibited by the nucleo-mitochondrial fraction. Phenylalanine hydroxylase, like most rat liver enzymes concerned with amino acid catabolism, develops late. On the 20th day of gestation, the liver (and the kidney) is devoid of phenylalanine hydroxylase and at birth contains 20% of the adult activity. During the second postnatal week of development, when the phenylalanine hydroxylase activity was about 40% of the adult value, an injection of cortisol doubled this value. Cortisol had no significant effect on phenylalanine hydroxylase in adult liver or on phenylalanine hydroxylase in kidney at any age.     

Influence of acclimation temperature on GDP-mannose: Dolicholphosphate mannosyltransferase of trout liver (Salmo Gairdneri)

Mannosyltransferase activity has been studied in trout liver microsomes prepared from fish adapted during 1 month at three different temperatures: 7, 15 and 21°C; the purpose of the study was to try and answer this question: is the enzyme sensitive to temperature variations and if so, do optimum pH variations reflect an adaptation to temperature changes? The following effects were observed: 1. Optimum pH values do not vary significantly with incubation temperature; only a discrete shift towards more acidic pH has been observed for trouts raised at 21°C. 2. For trouts raised at 7 and 15°C, the enzymic activity increases slightly with incubation temperature while it remains constant for the trouts acclimated at 21°C. This observation could be explained by a lower level of endogenous dolicholphosphate. 3. At any incubation temperature, the higher the acclimation temperature, the lower the enzymic activity.     

Purification and state of activation of rat kidney phenylalanine hydroxylase

Phenylalanine hydroxylase, the enzyme that catalyzes the irreversible hydroxylation of phenylalanine to tyrosine, was purified from rat kidney with the use of phenyl-Sepharose, DEAE-Sephacel, and gel permeation high pressure liquid chromatography. Our most highly purified fractions had a specific activity in the presence of 6-methyltetrahydropterin, of 1.5 mumol of tyrosine formed/min/mg of protein, which is higher than has been reported hitherto. For the rat kidney enzyme, the ratio of specific activity in the presence of 6-methyltetrahydropterin to the specific activity in the presence of tetrahydrobiopterin (BH4) is 5. By contrast, this ratio for the unactivated rat liver hydroxylase is 80. These results indicate that the kidney enzyme is in a highly activated state. The rat kidney hydroxylase could not be further activated by any of the methods that stimulate the BH4-dependent activity of the rat liver enzyme. In addition, the kidney enzyme binds to phenyl-Sepharose without prior activation with phenylalanine. The phenylalanine saturation pattern with BH4 as a cofactor is hyperbolic with substrate inhibition at greater than 0.5 mM phenylalanine, a pattern that is characteristic of the activated liver hydroxylase. The molecular weight of the rat kidney enzyme as determined by gel permeation chromatography is 110,000, suggesting that the enzyme might be an activated dimer. We conclude, therefore, that phenylalanine hydroxylases from rat kidney and liver are in different states of activation and may be regulated in different ways.     

Distribution of phenylalanine hydroxylase (EC 1.14.3.1) in liver and kidney of vertebrates.

The range of phenylalanine hydroxylase activity was determined by measuring the conversion of radioactive phenylalanine to tyrosine in liver and kidney of various vertebrates. Rodents (rats, mouse, gerbil, hamster and guinea pig) were found to have the highest liver phenylalanine hydroxylase activity among all animals studied. They are also the only species that possessed a significant kidney phenylalanine hydroxylase activity which was about 25% of that found in the liver of the same animal. The synthetic dimethyl-tetrahydro-pteridine, used as a cofactor for the enzyme assay in most studies, catalyzed non-enzymatic hydroxylation of phenylalanine to tyrosine. Inclusion of boiled-blank and strict control of timing between incubation and product measurement were essential precautions to minimize erroneous results from substrate contamination and non-enzymatic hydroxylation.     

A thermophilic extracellular -amylase from Bacillus licheniformis

A strain of Bacillus licheniformis isolated from soil produced an extracellular α-amylase(s) with unusual characteristics. The enzyme was purified 126-fold by starch adsorption, DEAE-cellulose treatment, and CM-cellulose column chromatography. Four active protein bands were detected by disc electrophoresis in poly-acrylamide gel although the enzyme behaved as a single peak during both ultracen-trifugation and chromatography using CM-cellulose and Sephadex G-100. The enzyme showed a very broad pH-activity curve and had substantial activity in the alkaline range. The optimal temperature was 76 °C at pH 9.O. The enzyme was stable between pH 6 and 11 at 25 °C, and below 60 °C at pH 8.0. Using Sephadex G-100 gel filtration, a molecular weight of 22,500 was estimated for the enzyme. The action pattern on amylose and amylopectin is unique in that the predominant product during all stages of hydrolysis is maltopentaose.     

Studies on Tannin Acyl Hydrolase of Microorganisms

Tannin acyl hydrolase (Tannase) from Asp. oryzae No. 7 was purified. The purified enzyme was homogenous on column chromatography (DEAE-Sephadex A50, Sephadex G100), ultra centrifugation and electrophoresis.

The molecular weight of the enzyme estimated by gel filtration method was about 200,000.

The enzyme was stable in the range of pH 3 to 7.5 for 12 hr at 5°C, and for 25 hr at the same temperature in the range of pH 4.5 to 6. The optimum pH for the reaction was 5.5. It was stable under 30°C (over one day, in 0.05 M-citrate buffer of pH 5.5), and the optimum temperature was 30~40°C (reaction for 20min). The activity was lost completely at 55°C in 20 min at pH 5.5, or at 85°C in 10 min at the same pH.

Any metal salt tested did not activate the enzyme, Zink chloride and cupric chloride inhibited the activity or denatured the enzyme. The activity was lost completely by dialysis against EDTA-solution at pH 7.25, although it was not affected by dialysis against deionized water.     

Characterization of the Cellulase Complex of Penicillium echinulatum

New cellulases from a strain of Penicillium echinulatum were characterized for their filter paper activity and β-glucosidase activity. Both activities showed maximum values between pH 4 and 5. With citrate buffer, activities were slightly higher than in acetate buffer of the same pH. Thermal stability of both activities was good up to 55°C. Filter paper activity was significantly reduced at higher temperatures.     

Digestive α-amylase activity in Aelia acuminata L. (Hemiptera: Pentatomidae)

Activity of α-amylase was revealed in the midgut and salivary glands of the wheat and barley pentatomid pest, A. acuminata. The activity was determined in salivary gland more than those in midgut. Optimal activity of the enzyme occurred at 40°C. Optimal pH activity in salivary gland (pH = 6) was more than those in the midgut (pH = 4.5). pH stability analysis of the enzyme showed that the enzyme is more stable at slightly acidic pHs than those at acidic and alkaline pHs. However, α-amylase is more stable at acidic pH in long period of time. Temperature stability analysis determined the enzyme was remarkably active over a broad range of temperature (5–40°C). α-Amylase activity was decreased after addition of MgCl₂, Tris, Triton X-100, CuSO₄, SDS, urea and CaCl₂. The salts NaCl and KCl increased the enzyme activity from midgut and salivary glands. Zymogram analysis of midgut and salivary gland extract showed at least two bands of amylase activity in the midgut and salivary glands.     

Characterization of a NaCl-tolerant β-N-acetylglucosaminidase from <Emphasis Type="Italic">Sphingobacterium</Emphasis> sp. HWLB1

β-N-Acetylglucosaminidases serve important biological functions and various industrial applications. A glycoside hydrolase family 3 β-N-acetylglucosaminidase gene was cloned from Sphingobacterium sp. HWLB1 and expressed in Escherichia coli BL21 (DE3). The purified recombinant enzyme (rNag3HWLB1) showed apparent optimal activity at pH 7.0 and 40 °C. In the presence of 0.5–20.0 % (w/v) NaCl, the activity and stability of rNag3HWLB1 were slightly affected or not affected. The enzyme could even retain 73.6 % activity when 30.0 % (w/v) NaCl was added to the reaction mixture. The half-life of the enzyme was approximately 10 min at 37 °C without the addition of NaCl. However, the enzyme was stable at 37 °C in the presence of 3.0 % (w/v) NaCl. A large negatively charged surface in the catalytic pocket of the enzyme was observed and might contribute to NaCl tolerance and thermostability improvement. The degree of synergy between a commercial endochitinase and rNag3HWLB1 on chitin enzymatic degradation ranged from 3.11 to 3.74. This study is the first to report the molecular and biochemical properties of a NaCl-tolerant β-N-acetylglucosaminidase.     

Production and Properties of a Soymilk-clotting Enzyme System from a Microorganism

Some microorganisms, including some bacteria isolated from soil, were found to secrete an extracellular soymilk-clotting enzyme. Among them, strain No. K-295G-7 showed the highest soymilk-clotting activity and stability of the production of the soymilk-clotting enzyme. The enzyme system (culture filtrate) coagulated protein in soymilk, a curd being formed at pH 5.8~6.7 and at 55~75°C. The optimum temperature for the soymilk-clotting activity was 75°C and the enzyme system was stable at temperatures below 50°C down to 35°C. About 80~100% of the original activity remained after 1 hr at pH 5~7 and 35°C.     

Immobilization of β-amylase on polystyrene cation exchange resin equilibrated with Al3+ions (IR-120 Al3+)

A simple procedure for the immobilization of β-amylase (EC3.2.1.2) on IR-120 Al³⁺ is described. Immobilization brought about a slight shift in the optimum pH towards the alkaline side relative to that of the soluble enzyme. Immobilized β-amylase showed a broader temperature optima (45–55°C) compared with the soluble enzyme (45°C). A six-fold increase in the K_m was also noticed. On storage and repeated use the immobilized enzyme retained approximately 60% of its initial activity up to 120 days at room temperature.     

Immobilization of catalase on cotton fabric oxidized by sodium periodate

Cotton fabric was first oxidized with sodium periodate, and then employed to immobilize catalase. Optimization studies for oxidation of the fabric and immobilization of the enzyme were performed. The properties of the immobilized catalase were examined and compared with those of the free enzyme. A high activity of the immobilized enzyme was obtained when the fabric was oxidized at 40°C and pH 6.0 for 8h in a bath containing 0.20 mol L^?1 sodium periodate and the enzyme was immobilized at 4°C for 24h with a catalase dosage of 120.0 U mL^?1. The immobilized enzyme exhibited optimum activity at 40°C, while the free enzyme had optimal temperature of 30°C, suggesting that the immobilized catalase could be used in a broader temperature range. Both the immobilized and free enzyme had pH optima of 7.0. The staining test and reusability showed that the catalase was fixed covalently on the oxidized cotton fabric.     

来源于葡萄球菌的N-乙酰神经氨酸裂合酶的基因克隆及性质

葡萄球菌Staphylococcus hominis来源的N-乙酰神经氨酸裂合酶基因shnal(GenBank Accession No.EFS20452.1)构建至pET-28a质粒并在大肠杆菌中得到表达.通过目的蛋白的纯化和酶学性质研究发现,ShNAL是一个四聚体,裂解方向的最适反应pH为8.0;合成方向的最适反应pH为7.5,最适反应温度为45℃.在45℃下孵育2h对ShNAL的活力基本无影响,高于45℃时,活力迅速下降.该酶在pH 5.0～10.0的环境中比较稳定,4℃下放置24 h酶的残余活力在70％以上.ShNAL对N-乙酰神经氨酸(Neu5Ac)、N-乙酰甘露糖胺(Man)和丙酮酸(Pyr)的Km值分别是(4.0±0.2) mmol/L、(131.7±12.1)mmol/L和(35.14±3.2) mmol/L,kcat/Km值分别为1.9 L/(mmol·s)、0.08 L/(mmol·s)和0.08 L/(mmol·s).     

Effect of Physicochemical Modifications on Antioxidant Activity of Water-soluble Chitosan

Water-soluble chitosan was processed using ultrasonication, microfluidisation and homogenisation to modify its physicochemical properties. The effect of using sonicated chitosan on formation of chitosan-glucose conjugates was investigated. Untreated and sonicated chitosan conjugates were prepared under varying reaction conditions (such as ratios of reactants, pH and temperature). The conjugates formed were evaluated for colour development and antioxidant activity. For both untreated and sonicated chitosans, the reactivity was found to be higher at pH 6.0/121 °C than at pH 4.9/121 °C. The reactivity was found to be lower at 105 °C at both pH conditions than at 121 °C. This clearly demonstrated the greater reactivity at higher temperature irrespective of the reaction pH. Antioxidant activity studies indicated that the conjugates formed at 121 °C had higher activity. Although sonication of water-soluble chitosan led to slightly enhanced viscosity indicating higher reactivity, it did not improve the antioxidant activity.     

Digestive amylase and pectinase activity in the larvae of alfalfa weevil Hypera postica (Coleoptera: Curculionidae)

The alfalfa weevil Hypera postica is a serious economic pest in most alfalfa grown in many countries worldwide. Digestive α-amylase and pectinase activities of larvae were investigated using general substrates. Midgut extracts from larvae showed an optimum activity for α-amylase against starch at acidic pH (pH 5.0). α-Amylase from larval midgut was more stable at mildly acidic pH (pH 5–6) than highly acidic and alkaline pH. The enzyme showed its maximum activity at 35°C. α-Amylase activity was significantly decreased in the presence of Ca²⁺, Mg²⁺ and sodium dodecylsulfate. On the contrary, K⁺ and Na⁺ did not significantly affect the enzyme activity. Zymogram analysis revealed the presence of one band of α-amylase activity in in-gel assays. Pectinase activity was assayed using agarose plate and colorimetric assays. Optimal pH for pectinase activity in the larval midgut was determined to be pH 5.0. Pectinase enzyme is more stable at pH 4.0–7.0 than highly acidic and alkaline pH. However, the enzyme was more stable at slightly acidic pH (pH 6.0) when incubation time increased. Maximum activity for the enzyme incubated at different temperatures was observed to be 40°C. Optimum pH activity for α-amylase and pectinase is not completely consistent with the pH prevailing in the larval midgut. This is the first report of the presence of pectinase activity in H. postica.     

The effects of starvation and temperature acclimation on pentose phosphate pathway dehydrogenases in brook trout liver

Temperature and starvation were found to be factors which affected the PPP dehydrogenase activities in brook trout liver. Fish acclimated at 5 °C possessed greater levels of G6PD, H6PD, and 6PGD activity than those fish maintained at 10 or 15 °C. This phenomenon was probably associated with increased lipogenesis during cold acclimation.During starvation hepatic G6PD and 6PGD activities decreased, whereas H6PD activity increased slightly. Upon refeeding, the G6PD level gradually increased, but the “overshoot” in enzyme activity reported in mammalian studies was not observed.When both cold acclimation and starvation were studied simultaneously, regulation by temperature was initially the dominant control factor. After 6 wk at 5 °C, there was no difference in specific activities between starved and fed fish. However, fish maintained at 5 °C for longer than 2 mo did show the normal response to starvation and refeeding. Therefore, regulation of the PPP by temperature appears to be a transitory phenomenon and may be associated with temporary metabolic reorganization in the fish.     

Heterologous expression and biochemical characterization of glucose isomerase from Thermobifida fusca

Glucose isomerase (GIase) catalyzes the isomerization of d-glucose to d-fructose. The GIase from Thermobifida fusca WSH03-11 was expressed in Escherichia coli BL21(DE3), and the purified enzyme took the form of a tetramer in solution and displayed a pI value of 5.05. The temperature optimum of GIase was 80 °C and its half life was about 2 h at 80 °C or 15 h at 70 °C. The pH optimum of GIase was 10 and the enzyme retained 95 % activity over the pH range of 5–10 after incubating at 4 °C for 24 h. Kinetic studies showed that the K _m and K _cat values of the enzyme are 197 mM and 1,688 min^?1, respectively. The maximum conversion yield of glucose (45 %, w/v) to fructose of the enzyme was 53 % at pH 7.5 and 70 °C. The present study provides the basis for the industrial application of recombinant T. fusca GIase in the production of high fructose syrup.     

Mathematical modeling of maize starch liquefaction catalyzed by α-amylases from Bacillus licheniformis: effect of calcium, pH and temperature

The first step of starch hydrolysis, i.e. liquefaction has been studied in this work. Two commercial α-amylases from Bacilllus licheniformis, known as Termamyl and Liquozyme have been used for this purpose. Using starch as the substrate, kinetics of both enzymes has been determined at optimal pH and temperature (pH 7, T = 80 °C) and at 65 °C and pH 5.5. Michaelis–Menten model with uncompetitive product inhibition was used to describe enzyme kinetics. Mathematical models were developed and validated in the repetitive batch and fed-batch reactor. Enzyme inactivation was described by the two-step inactivation model. All experiments were performed with and without calcium ions. The activities of both tested amylases are approximately one hundred times higher at 80 °C than at 65 °C. Lower inactivation rates of enzymes were noticed in the experiments performed at 65 °C without the addition of calcium than in the experiments at 80 °C. Calcium ions in the reaction medium significantly enhance amylase stability at 80 °C and pH 7. At other process conditions (65 °C and pH 5.5) a weaker calcium stabilizing effect was detected.     

The demonstration of a specific 5'-nucleotidase activity in rat tissues.

5′-Nucleotidase has been partially purified from rat liver, spleen, kidney, heart, lung, brain and skeletal muscle. The majority of the enzyme activity in each of these tissues was insoluble in 1% of Triton X-100, solubilized in 2% Triton X-100,1% sodium deoxycholate, and stable to incubation at 50 °C for 5 min. The partially purified enzyme from each tissue exhibited the same pH optimum, was inhibited by concanavalin A, and was inhibited in an identical manner by antibody to highly purified 5′-nucleotidase from liver. Since the enzyme is usually concentrated in the plasma membrane (De Pierre, J. W. and Karnovsky, M. L. (1973) J. Cell Biol., 56, 275–303), the results indicate that the enzyme may represent a convenient and general marker for this organelle in rat tissues.