A unique proteolytic action of HCE, a constituent protease of a fish hatching enzyme: tight binding to its natural substrate, egg envelope

High choriolytic enzyme (HCE), a constituent protease of the hatching enzyme of the teleost, Oryzias latipes, swells its natural substrate, egg envelope (chorion) by hydrolyzing it partially. This enzyme was found to be bound tightly to the chorion when it exerted catalytic action. This was evidenced by the experimental results showing (i) that the turnover of this enzyme seemed to be hindered by the chorion, (ii) that the enzyme bound to the chorion could be recovered by washing with an alkaline medium, and (iii) that the bound enzyme could be quantified by radioimmunological estimation. The bound enzyme sustained its original activity and the binding between the enzyme and the chorion seems to be stoichiometric.     

Melibiose is hydrolyzed exocellularly by an inducible exo-alpha-galactosidase in Azotobacter vinelandii

Azotobacter vinelandii hydrolyzed melibiose exocellularly, leading to an accumulation of free glucose and galactose in the medium. This enzyme could also be induced by galactose, raffinose, and stachyose. The alpha-galactosidase activity could be detected quantitatively by using p-nitrophenyl-alpha-galactopyranoside as a substrate for intact cells. Chloramphenicol totally inhibited the induction of this enzyme. However, benzyl alcohol inhibited the secretion of this enzyme but did not inhibit the biosynthesis of the enzyme.     

Melibiose is hydrolyzed exocellularly by an inducible exo-alpha-galactosidase in Azotobacter vinelandii.

Azotobacter vinelandii hydrolyzed melibiose exocellularly, leading to an accumulation of free glucose and galactose in the medium. This enzyme could also be induced by galactose, raffinose, and stachyose. The alpha-galactosidase activity could be detected quantitatively by using p-nitrophenyl-alpha-galactopyranoside as a substrate for intact cells. Chloramphenicol totally inhibited the induction of this enzyme. However, benzyl alcohol inhibited the secretion of this enzyme but did not inhibit the biosynthesis of the enzyme.     

Solubilization and partial purification of heme oxygenase from rat liver.

Hepatic microsomal heme oxygenase was solubilized, partially purified, and characterized from Co2+-treated rats. The enzyme on sodium dodecyl sulfate-polyacrylamide gel electrophoresis exhibited a minimum molecular weight of greater than or equal to 68,000. The solubilized enzyme was totally devoid of contamination with cytochrome P-450 or b5. The requirement for reduced pyridine nucleotides was absolute, and ascorbate could not support heme oxidative activity. However, both TPNH and DPNH could serve as electron donors, with TPNH being more effective. The presence of an appropriate flavoprotein reductase was essential for heme oxidation. The enzyme had an apparent Km of 40 micrometer, a pH optimum of 7.5, and lost substantial activity upon freezing and thawing. Methemoglobin was 30% as effective a substrate for the enzyme as was heme. Free porphyrins could not serve as substrates for the enzyme. The activity of the enzyme was inhibited by HgCl2, p-chloromercuribenzoate, iodoacetamide, mercaptoethanol, and dithiothrietol indicating that free -SH group(s) is necessary for enzyme activity.     

Theoretical and experimental analysis of a soluble enzyme membrane reactor.

Recently enzyme immobilization techniques have been proposed that are mainly founded on the formation of an enzyme-gel layer onto the active surface of an ultrafiltration membrane within an unstirred ultrafiltration cell. If the membrane molecular-weight cutoff is less than the enzyme molecular weight and hence such as to completely prevent enzyme permeation (once the enzyme solution has been charged into the test cell and pressure applied to the system), a time progressive increase in enzyme concentration takes place at the upstream membrane surface that can eventually lead to gelation and hence to enzyme immobilization. However, depending on the total enzyme amount fed, the maximum enzyme concentration achieved in the unsteady state could be less than the gelation level. In this situation, no immobilization occurs and the enzyme still remains in the soluble form although it is practically confined within a limited region immediately upstream the membrane and at fairly high concentrations. In this paper, the experimental conditions that allow gelling to occur are discussed together with a theoretical analysis of the soluble enzyme membrane reactor which is obtained when no gelling takes place. Such a system could be usefully employed in performing kinetic analyses at high enzyme concentration levels that are still in the soluble form.     

Identification of subsidiary catalytic groups at the active site of beta-ketoacyl-CoA thiolase by covalent modification of the protein

beta-Ketoacyl-CoA thiolase (acyl-CoA:acetyl-CoA C-acyltransferase, EC 2.3.1.16) is known to possess sulfhydryl groups of cysteines at the active site that are essential for its catalytic activity. Other groups at the active site that participate in the catalytic process were identified by using anhydride reagents which covalently modify the protein by specifically reacting with any amino groups potentially present at the active site. Since these reagents may also react with thiol groups, the enzyme's amino groups were modified after masking the cysteine thiols present by an alkylalkane thiosulfonate-type reagent, methyl methanethiol-sulfonate (MMTS), that selectively formed a disulfide bridge, thus generating an inactive thiolmethylated enzyme. When this procedure was followed, the enzyme could be undoubtedly modified at its amino by the anhydride reagent, leading to a doubly modified protein. The thiomethyl group could then be removed by reduction with dithiothreitol, yielding an enzyme modified solely on the amino residues. The amino group could be unblocked in turn by exposure to acidic pH. The different anhydrides inactivated thiolase, but only acetoacetyl coenzyme A (AcAcCoA) provided any protection against inactivation. When thiolmethylcitraconyl thiolase was reduced with dithiothreitol the enzyme remained inactive, but when the doubly modified enzyme was exposed to pH 5 then the reduction led to formation of an active enzyme. These results are interpreted as demonstrating a role for an amino group at the enzyme active site. A catalytic mechanism is proposed for the enzyme which involves the amino group.     

Partial reconstitution of human RNase P in HeLa cells between its RNA subunit with an affinity tag and the intact protein components

An RNA affinity tag was incorporated into the RNA subunit of human nuclear RNase P. The tagged RNA assembled with the protein components of RNase P inside HeLa cells to generate an active enzyme. Because of the specificity of the RNA tag to streptavidin, the reconstituted complex could be separated from the native enzyme and other ribonucleoproteins (particularly RNase MRP) by streptavidin agarose chromatography and could be recovered by the eluting agent, biotin. A mutant, tagged RNase P RNA, whose P3 domain was partially replaced, could not reconstitute with the proteins to yield an active enzyme. The P3 domain, therefore, is critical for the structure and function of RNase P.     

Inhibition or initiation of a radical polymerization reaction by an ultraviolet-induced enzymatic process

alpha-Chymotrypsin was modified to a light-controllable enzyme derivative by acylating active serine 195 residue with a cinnamoyl group or analogue. Upon UV irradiation the acylgroup could be isomerized, leading to release of the inhibiting group. Enzymatic activity could thus be regulated by means of UV light. A full 100% inhibition of the enzymatic activity could not be reached by the cinnamoyl derivative. Only posttreatment with diisopropylfluorophosphate yields a fully inactive enzyme derivative. The shelf-life of the inhibited enzyme was rather poor. Only freeze-dried samples could be used for several months without significant recovery of activity. Adapting the sensitivity of the system to visible light seems limited to the size of an enzyme's active site. Combination of the enzymatic system producing an inhibitor or an initiator with a polymerization reaction can result in a photographic process with a higher amplification factor.     

Rat liver uridine diphosphate glucose dehydrogenase: dual mechanism of regulation in vivo

Rat liver UDPglucose (UDPG) dehydrogenase activity was observed to be decreased after fasting and could be restored to normal levels after refeeding glucose. This could be prevented by prior injection of puromycin, suggesting de novo protein synthesis. Administration of insulin to normal rats on stock diet did not influence the enzyme activity. However, the enzyme activity was decreased in the diabetic condition. Intraperitoneal injection of insulin caused an enhancement of the enzyme activity in diabetic animals. Hepatic UDPG dehydrogenase activity was observed to be decreased on ascorbic acid feeding or intraperitoneal injection of the same. The intraperitoneal injection of either insulin or cAMP to ascorbic acid-treated rats resulted in an increase in enzyme activity reaching normal levels. The insulin-mediated increase could not be prevented by prior injection of puromycin, suggesting a post-translational effect. These results indicate two distinct mechanisms for in vivo regulation of hepatic UDPG dehydrogenase.     

The presence of desulfo xanthine dehydrogenase in purified and crude enzyme preparations from rat liver

Crude and purified xanthine dehydrogenase preparations from rat liver were examined for the existence of a naturally occurring inactive form. Reduction of the purified enzyme by xanthine under anaerobic conditions proceeded in two phases. The enzyme was inactivated by cyanide, which caused the release of a sulfur atom from the molybdenum center as thiocyanate. The amount of thiocyanate released was almost in parallel with the initial specific activity. The active and inactive enzymes could be resolved by affinity chromatography on Sepharose 4B/folate gel. These results provided evidence that the purified enzyme preparation from rat liver contained an inactive form. A method for the determination of the active and inactive enzymes in crude enzyme preparations from rat liver was devised based on the fact that only active enzyme could react with [14C]allopurinol and both active and inactive enzymes could be immunoprecipitated quantitatively by excess specific antibody to xanthine dehydrogenase. The amount of [14C]alloxanthine (derived from [14C]allopurinol) bound to the active sulfo enzyme in crude rat liver extracts was about 0.5 mol/mol of FAD. As this content is closely similar to that in the purified enzyme, these results suggest the existence of an inactive desulfo form in vivo.     

Enzyme loading in a solid support with nonuniform pore size distribution

The concept of pore size distribution is incorporated into the Clark model of enzyme immobilization in the present study. This refined model predicted that in the case of small harmonic pore radius with the same surface area and porosity of the support, more enzyme could be loaded in a support with nonuniform pores than that with uniform pores. In comparing the enzyme loading efficiency of the support with two different pore size distributions, the one with Gaussian distribution had the greater amount of enzyme immobilized than the other one with Rajagopalan's distribution. Furthermore, more enzyme could be loaded in a support with wider Gaussian pore size distribution than that with narrower distribution. The immobilized enzyme profile in the solid support with pore size distribution displayed a stepwise pattern which differed appreciably from the sigmoidal profile predicted for the support with uniform pore size. This stepwise enzyme distribution profile became sigmoidal with decreasing h(T) or increasing k. The new model could be used for designing protocols for an enzyme immobilization process.     

Physical properties of L-asparaginase from Serratia marcescens.

Purified L-asparaginase from Serratia marcescens had an apparent-weight average molecular weight of 171,000 to 180,000 as determined by electrophoresis on polyacrylamide gels and by sedimentation equilibrium at low speed in an analytical ultracentrifuge. A subunit molecular weight of 31,500 +/- 1,500 was estimated for the enzyme after treatment with sodium dodecyl sulfate and urea and electrophoresis on polyacrylamide gels; a similar value was obtained by high-speed sedimentation equilibrium in the presence of guanidine hydrochloride. Our data indicate that the Serratia enzyme could have five or six subunits of 32,000 daltons, compared to four subunits of 32,000 daltons in the Escherichia coli enzyme. The Serratia L-asparaginase also appears to be a larger molecule than the enzyme from Erwinia carotovora, Proteus vulgaris, Acinetobacter glutaminasificans, and Alcaligenes eutrophus. The Serratia enzyme, like that from E. caratovora, was more resistant than the E. coli enzyme to dissociation by sodium dodecyl sulfate. This resistance could be due to the finding that the Serratia enzyme had a relatively high hydrophobicity, similar to the enzyme from E. caratovora, when compared with the hydrophobicity of the E. coli enzyme. The isoelectric point of the Serratia enzyme was approximately 5.2. The influence of certain physical characteristics of the enzyme on the biological properties is discussed.     

Production and processing of a recombinant Fasciola hepatica cathepsin B-like enzyme (FhcatB1) reveals potential processing mechanisms in the parasite

The liver fluke, Fasciola hepatica, apparently uses a number of cysteine proteases during its life cycle, most likely for feeding, immune evasion and invasion of tissues. A cathepsin B-like enzyme (herein referred to as FhcatB1) appears to be a major enzyme secreted by the invasive, newly excysted juvenile flukes of this parasite. To examine the processing mechanisms for this enzyme, a recombinant form was expressed in Pichia pastoris and purified to yield a homogenous pool of the enzyme. The purified enzyme could be autoactivated at low pH via a bi-molecular mechanism, a process that was greatly accelerated by the presence of large, negatively charged molecules such as dextran sulfate. The enzyme could also apparently be processed to the correct size by an asparaginyl endopeptidase via cleavage in an unusual insertion N-terminal to the normal cleavage site used to yield the active form of the enzyme. Thus, there appear to be a number of ways in which this enzyme can be processed to its optimally active form prior to secretion by F. hepatica.     

2,4-Dichlorophenoxyacetic acid and the de novo synthesis of invertase in chicory root tissue

Using a dual radioactive labelling technique, the large 2,4-D induced increase in invertase activity in root tissue of chicory (Cichorium intybus) could not be attributed to de novo protein synthesis. The highly active enzyme could have arisen by modification of an inactive enzyme precursor.     

Catechol oxidase from green olives: Properties and partial purification

Catechol oxidase was extracted from an acetone powder prepared from green olive. The enzyme was purified 240-fold by ammonium sulphate fractionation followed by ion exchange chromatography and gel filtration. The enzyme was characterized by substrate specificity and response to inhibitors. Between 7 and 9 bands having catechol oxidase activity could be detected by gel electrophoresis and electrofocusing. The purified enzyme had an estimated MW of 42 000. The enzyme was strongly inhibited by diethyldithiocarbamate. Inhibition by chloride was strongly dependent on pH. The enzyme did not oxidise monophenols.     

肌苷酶电极生物传感器

为了构建肌苷酶电极生物传感器,以固定化核苷磷酸化酶(EC 2.4.2.1)、黄嘌呤氧化酶(EC 1.2.3.2)与过氧化氢电极组成电流型酶电极生物传感器,用于检测肌苷片中的肌苷,其输出电流可达500nA.结果发现,肌苷测定的线性范围为1-268 mg/L,精度:RSD小于0.14%,响应时间:60 s,使用寿命大于25 d,实际测定肌苷片中肌苷含量回收率:100.8%.由此表明:采用双酶电极法测定肌苷片中的肌苷含量,由于酶促反应专一性高、样品不需分离直接进样分析、处理条件温和、反应时间短暂因而结果较为可靠.     

Purification of Epstein-Barr virus DNA polymerase from P3HR-1 cells.

The Epstein-Barr virus DNA polymerase was purified from extracts of P3HR-1 cells treated with n-butyrate for induction of the viral cycle. Sequential chromatography on DNA cellulose, phosphocellulose, and blue Sepharose yielded an enzyme preparation purified more than 1,300-fold. The purified enzyme was distinct from cellular enzymes but resembled the viral DNA polymerase in cells infected with herpes simplex virus type 1 or 2. The active enzyme had an apparent molecular weight of 185,000 as estimated by gel filtration on Sephacryl S-300. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a major polypeptide corresponding to a molecular weight of ca. 110,000. This polypeptide correlated with the catalytic function of the purified enzyme, whereas the other, less abundant polypeptides did not. By immunoblotting, the 110,000-molecular-weight polypeptide could be identified as a viral polypeptide. It could not be determined whether the native enzyme was composed of more than one polypeptide.     

An extracellular--pepstatin insensitive acid protease produced by Thermoplasma volcanium

In this study, some parameters for the production and caseinolytic activity of an extracellular thermostable acid protease from a thermoacidophilic archaeon Thermoplasma volcanium were determined. The highest level of growth and enzyme production were detected at pH 3.0 over an incubation period of 192 h at 60 degrees C. The pH optimum for the acid protease activity was 3.0 and the enzyme was fairly stable over a broad pH range (pH 3.0-8.0). The temperature for maximum activity of the enzyme was 55 degrees C and activity remained stable between 50 degrees C and 70 degrees C. These features could be of relevance for various biotechnological applications of this enzyme. Serine-(PMSF), cysteine-(DTT), metallo-(EDTA) and aspartate-(pepstatin) protease inhibitors did not inhibit the caseinolytic activity of the enzyme. Therefore, Tp. volcanium acid protease could be a member of the pepstatin-insensitive carboxyl proteinases.