The effect of haptoglobin on prostaglandin H synthase from ram vesicular glands

It was shown that the ability of sheep and horse haptoglobins differing in their immunological properties to inhibit PGH synthetase is about the same. It was found that haptoglobin inhibits the PGH synthetase-catalyzed enzymatic reaction, the inhibiting effect being non-competitive with respect to the electron donor, adrenaline. The degree of PGH synthetase inhibition by haptoglobin depends on the glycoprotein concentration, incubation time and enzyme activity.     

Purification of prostaglandin H synthetase and a fluorometric assay for its activity

Prostaglandin H synthetase (PGH synthetase) has been purified to homogeneity from sheep vesicular glands. The pure enzyme has a specific activity of about 40 microM of arachidonic acid consumed per minute per milligram of protein, which corresponds to a turnover number of 2800 min-1 per subunit. The purified enzyme was obtained by one-stage chromatography on DEAE-Toyopearl 650 from Tween 20-solubilized microsomes. A sensitive fluorometric assay for PGH synthetase activity using homovanillic acid (HVA) as electron donor has been proposed. It has been shown that homovanillic acid may be used as the electron donor and that in the presence of HVA the enzyme has an activity of approximately 40 microM/min/mg.     

Enzymatic conversion of prostaglandin H2 to prostaglandin F2 alpha by aldehyde reductase from human liver: comparison to the prostaglandin F synthetase from bovine lung

The primary structure of prostaglandin (PG) F synthetase from bovine lung shows 62% similarity with that of human liver aldehyde reductase (EC 1.1.1.2) (Watanabe, K., Fujii, Y., Nakayama, K., Ohkubo, H., Kuramitsu, S., Kagamiyama, H., Nakanishi, S., and Hayaishi, O. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 11-15). We therefore purified human liver aldehyde reductase to homogeneity and compared the immunological and catalytic properties of aldehyde reductase and PGF synthetase. Although both enzymes belong to a group of aldoketoreductases and their molecular weights are essentially identical, aldehyde reductase had no cross-reactivity to anti-PGF synthetase antiserum. Furthermore, there was a difference in the substrate specificity for reduction of PGs between the two enzymes. Aldehyde reductase catalyzed the reduction of PGJ2, delta 12-PGJ2, PGH2, or PGA2, but not that of PGB2, PGD2, or PGE2, whereas PGF synthetase reduced PGD2. The optimum pH, Km value for PGH2, and the turnover number were 6.5, 100 microM, and 3.1 min-1, respectively. The PGH2 9,11-endoperoxide reductase activity of aldehyde reductase was not affected in the presence of a substrate such as p-nitrobenzaldehyde, DL-glyceraldehyde, or 9,10-phenanthrenequinone, suggesting that PGH2 9,11-endoperoxide and other substrates are reduced at different active site(s). The reaction product formed from PGH2 by this enzyme was identified as PGF2 alpha by gas chromatography/mass spectrometry. These results suggest that aldehyde reductase is not exactly identical to PGF synthetase in terms of its immunological property and substrate specificity for PGs, but that this enzyme is also involved in the direct conversion of PGH2 to PGF2 alpha similar to PGF synthetase.     

Effect of organic solvents on penicillin acylase-catalyzed reactions: interaction of organic solvents with enzymes

The effects of various organic solvents on penicillin acylase-catalyzed synthesis of β-lactam antibiotics (pivampicillin and ampicillin) have been investigated in water-solvent mixtures. The rates of penicillin acylase-catalyzed reactions were found to be significantly reduced by the presence of a small amount of organic solvent. In particular, the rate of enzyme catalysis was extremely low in the presence of ring-structured solvents and acids while enzyme activities were fully restored after removing the solvents. This indicates that interactions between the solvents and the enzyme are specific and reversible. To correlate the inhibitory effects of organic solvents with solvent properties the influence of solvent hydrophobicities and solvent activity on the rate of pivampicillin synthesis was examined. The reaction rate was found to decrease with increasing solvent hydrophobicities, and a better correlation was observed between the reaction rate and solvent activity. The effects of ionic strength on the synthesis of pivampicillin and ampicillin were also examined. The ionic strength dependence indicates that electrostatic interactions are involved in the binding of ionic compounds to the enzyme. On the basis of the active site structure of penicillin acylase, a possible mechanism for molecular interactions between the enzyme and organic solvents is suggested.     

Subunits of fatty acid synthetase complexes. Comparative study of enzyme activities and properties of the half-molecular weight nonidentical subunits of fatty acid synthetase complexes obtained from rat, human, and chicken liver and yeast.

Rat, human, and chicken liver and yeast fatty acid synthetase complexes were dissociated into half-molecular weight nonidentical subunits of molecular weight 225,000–250,000 under the same conditions as used previously for the pigeon liver fatty acid synthetase complex [Lornitzo, F. A., Qureshi, A. A., and Porter, J. W. (1975) J. Biol. Chem.250, 4520–4529]. The separation of the half-molecular weight nonidentical subunits I and II of each fatty acid synthetase was then achieved by affinity chromatography on Sepharose ?-aminocaproyl pantetheine. The separations required, as with the pigeon liver fatty acid synthetase, a careful control of temperature, ionic strength, pH, and column flow rate for success, along with the freezing of the enzyme at ?20 °C prior to the dissociation of the complex and the loading of the subunits onto the column. The separated subunit I (reductase) from each fatty acid synthetase contained β-ketoacyl and crotonyl thioester reductases. Subunit II (transacylase) contained acetyl- and malonyl-coenzyme A: pantetheine transacylases. Each subunit of each complex also contained activities for the partial reactions, β-hydroxyacyl thioester dehydrase (crotonase), and palmitoyl-CoA deacylase. The specific activities of a given partial reaction did not vary in most cases more than twofold from one fatty acid synthetase species to another. The rat and human liver fatty acid synthetases required a much higher ionic strength for stability of their complexes and for the reconstitution of their overall synthetase activity from subunits I and II than did the pigeon liver enzyme. On reconstitution by dialysis in high ionic strength potassium phosphate buffer of subunits I and II of each complex, 65–85% of the control fatty acid synthetase activity was recovered. The rat and human liver fatty acid synthetases cross-reacted on immunoprecipitation with antisera. Similarly, chicken and pigeon liver fatty acid synthetases crossreacted with their antisera. There was, however, no cross-reaction between the mammalian and avian liver fatty acid synthetases and the yeast fatty acid synthetase did not cross-react with any of the liver fatty acid synthetase antisera.     

Influence of various factors on the recognition specificity of tRNAs by yeast valyl-tRNA synthetase.

Using filtration through nitrocellulose membranes we found that complexes between yeast valyl-tRNA synthetase can easily be detected at low pH and ionic strength with the cognate tRNAVal, but also with several non-cognate tRNAs (tRNAPhe, tRNATyr, tRNAMet and tRNAAsp). We show here that the amino acid linked to the tRNA has no detectable effect on these interactions. The influence of various factors on the discrimination by the enzyme between the cognate and the non-cognate tRNAs has been studied. An increase in pH or ionic strength leads to a decrease in the same ratio of the affinity constants between the enzyme and the cognate as well as the noncognate tRNA. The addition of organic solvents has little effect on these constant either in the cognate or in the non-cognate systems; the addition of substrates of the aminoacylation reaction has not effect on the ratio between the constants. This similar behaviour suggests that at least part of the specific of non-specific interactions must be identical. On the contrary, magnesium between 1 mM and 50 mM increases the specificity of recognition, showing the importance of slight conformational changes in the tRNA molecule to the specificity of interaction.     

Spectral properties of the higher oxidation states of prostaglandin H synthase

Prostaglandin H (PGH) synthase reacts with organic hydroperoxides and fatty acid hydroperoxides on a millisecond time scale to generate an intermediate that is spectrally similar to compound I of horseradish peroxidase. Compound I of PGH synthase is converted to compound II within 170 ms. Compound II decays to resting enzyme in a few seconds. Thus, the peroxidase reaction of PGH synthase appears to involve a cycle of native enzyme, compound I, and compound II, typical of heme-containing peroxidases. The Soret absorption maximum of compound I appears to occur at 412 nm but a small amount of compound II may be present. Soret maxima occur at 420, 433, and 419 for compound II, the ferrous enzyme, and the oxyferrous enzyme (compound III), respectively. Rapid scan analysis of the reaction of PGH synthase with arachidonic acid reveals the absorbance of compound II but no evidence for ferrous or oxyferrous enzyme.     

Purification and characterization of GMP synthetase from Yoshida sarcoma ascites cells

GMP synthetase was found in the cytosolic fraction of Yoshida sarcoma ascites cells. However, prolonged centrifugation resulted in precipitation of the enzyme. On sucrose density gradient centrifugation of a crude extract of Yoshida sarcoma ascites cells, a part of this enzyme showed high sedimentability at low ionic strength. On the basis of these observations, GMP synthetase was purified from Yoshida sarcoma ascites cells by means of procedures including centrifugal fractionation. The purified enzyme was shown to be homogeneous on SDS-polyacrylamide gel electrophoresis and isoelectric focusing in polyacrylamide gel. The molecular weight of the GMP synthetase was estimated to be 78,000 by SDS-polyacrylamide gel electrophoresis and gel filtration on Sephadex G-150. Its isoelectric point was estimated to be 5.6. The Km values of this enzyme for XMP, ATP, and glutamine were calculated to be 4.6, 120, and 300 microM, respectively. Although ammonia could substitute for glutamine as a donor of the amino group, the Km value was as high as 120 mM, indicating that it cannot be considered to be a physiological substrate. This enzyme showed high activity only in the presence of Mg2+, and very low activity in the presence of other divalent cations. Inhibition by nucleoside monophosphates was not significant. The enzyme required reduced sulfhydryl compounds for its activity.     

Ionic control of acid phosphatase activity in plant cell walls

Abstract. Purified acid phosphatase from sycamore cell walls is not activated by increasing the ionic strength of the reaction mixture. However activation occurs when the enzyme is bound to small cell wall fragments. The apparent activation of the bound enzyme by ions is paralleled by a decline of the substrate concentration C _1/2, that results in half of the maximum rate. Above ionic strengths of about 0.05 the bound and solubilized enzyme forms behave in the same manner. Titration of cell wall fragments at different ionic strengths show that the local pH, inside the cell wall fragments, is lower than the pH in bulk solution. These results are explained in the light of poly-electrolyte theory. The negative charges of the cell walls generate an electrostatic potential that results in the attraction or repulsion of ions. The local concentration of organic phosphate (the substrate of the enzyme) is then lower than its concentration in bulk solution. This concentration difference explains that the value of C _1/2, or of the apparent K_m of the bound enzyme, is greater than the true K_m of the solubilized enzyme. Increasing the ionic strength tends to equalize bulk and local ion concentrations, and therefore apparently activates the bound enzyme.     

EFFECT OF SALTS ON THE PHYSICAL AND KINETIC PROPERTIES OF HUMAN PLACENTAL CHOLINE ACETYLTRANSFERASE

Abstract— The effects of salt on the properties of human placental choline acetyltransferase have been examined. Increases in enzyme activity, thermal denaturation and susceptibility to proteolysis can be related to increases in ionic strength, rather than to specific salt effects. Increased ionic strength increases the maximal velocity (K_m) of the reaction, with no change in the kinetic parameter V_max/K_m (choline). The pH-K_m profile, measured over the range of 6.5–8.0, indicates the requirement of a dissociated acidic residue whose pKa is below 7.5 at high ionic strength, and a protonated residue whose pKa is above 7.5 at low ionic strength. It is proposed that the conformation of the enzyme is different at high ionic strength and at low ionic strength, and that these different conformational states of the enzyme result in different rate-determining steps of the reaction.     

In vitro reactivation of in vivo ammonium-inactivated glutamine synthetase from Synechocystis sp. PCC 6803.

Glutamine synthetase from Synechocystis sp. strain PCC 6803 is inactivated by ammonium addition to cells growing with nitrate as the nitrogen source. The enzyme can be reactivated in vitro by different methods such as alkaline phosphatase treatment, but not phosphodiesterase, by raising the pH of the crude extract to values higher than 8, by increasing the ionic strength of the cell-free extract, or by preincubation with organic solvents, such as 2-propanol and ethanol. These results suggest that the loss of glutamine synthetase activity promoted by ammonium involves the non-covalent binding of a phosphorylated compound to the enzyme and support previous results that rule out the existence of an adenylylation/deadenylylation system functioning in the regulation of cyanobacterial glutamine synthetase.     

Thromboxane synthetase inhibitors as pharmacological tools: differential biochemical and biological effects on platelet suspensions

The comparative effects of three so called "thromboxane-synthetase-inhibitors" (imidazole, N-0164, and U-51605) on arachidonate metabolism and on platelet aggregation were studied. All three compounds blocked platelet microsomal thromboxane synthesis from prostaglandin endoperoxides without affecting platelet adenyl cyclase. Imidazole, blocked thromboxane synthesis in intact platelets either from arachidonic acid or PGH2, without affecting aggregation. U-51605 simultaneously inhibited thromboxane synthesis and platelet suspension aggregation. N-0164 inhibited aggregation probably at extracellular sites, at concentrations that did not alter arachidonate or PGH2 metabolism. High concentrations of N-0164 simultaneously inhibited PG cyclo-oxygenase and thromboxane synthetase. The lack of specificity of these compounds requires that other actions of these compound must be considered when they are used as pharmacological tools to inhibit thromboxane synthetase.     

Optimization of reaction conditions during enzyme immobilization on soluble carboxyl-containing carriers

The kinetics of 1-ethyl-3-(3′-dimethylaminopropyl)-carbodiimide interaction with carboxylic groups in low and high molecular weight compounds have been investigated for choosing the optimum conditions for enzyme immobilization on carboxylic carriers. Optimum pH values depended on the pK_a of an acid. The ionic strength of the reaction mixture influenced the process of activation with carbodiimide and a decrease in reaction rate accompanied an increase in ionic strength. Optimum conditions for the coupling process with the use of carbodiimide activation are suggested. The process of fibrinolysin immobilization on the soluble copolymer of acrylic acid and acrylamide with carbodiimide as a coupling agent was also studied.     

Effect of ionic strength on chain elongation in ADP-ribosylation of various nucleases

With the use of a reconstituted poly(ADP-ribosyl)ating enzyme system and three purified nucleases, micrococcal nuclease (MN), bull seminal RNase (BS RNase) and Ca2+, Mg2+-dependent endonuclease (BS DNase), as model acceptor proteins for ADP-ribose, the effect of ionic strength on the modification reaction was examined in detail. When these three nucleases were extensively poly(ADP-ribosyl)ated in this system at a low ionic strength (5 mM Tris), they were all inhibited by about 80% and the chain length of the polymer covalently bound to the nucleases was 13 to 23 ADP-ribose units. The observed inhibition was markedly prevented by increasing the ionic strength in the reaction mixture with a concomitant decrease in the polymer size bound to the nucleases. The NaCl concentrations required for decreasing the extent of the inhibition to half of the maximum were calculated to be 20, 50, and 100 mM for MN, BS RNase, and BS DNase, respectively. These values are similar to the NaCl concentrations required for decreasing the average chain lengths of the polymer to half, suggesting that the length of polymer is closely correlated to the extent of inhibition of these nucleases. DNA-binding affinities of these nucleases, expressed in terms of the NaCl concentrations required for eluting the enzymes from DNA-cellulose, were 140, 280, and 340 mM for MN, BS RNase, and BS DNase, respectively. Considering that maintainance of a ternary complex of poly(ADP-ribose) synthetase, acceptor and DNA may be essential for the modification reaction, the relatively strong salt effect observed in the modification of MN may be explained by its low DNA-binding affinity.     

微环境对脂肪酶催化拆分外消旋2－辛醇的影响

微环境对脂肪酶催化拆分外消旋２－辛醇的影响　　　　　　　杨红,曹淑桂,韩四平,黄仲丽,杨同书（吉林大学酶工程国家重点实验室,长春１３００２３）手性２－辛醇不仅是制备液晶材料不可缺少的重要手性原料,也是合成具有光学活性的医药和农药的重要手性中间体．本文...     

Purification and characterization of fatty acid cyclooxygenase from human platelets

The fatty acid cyclooxygenase (EC 1.14.99.1) that produces the prostaglandin, thromboxane, and prostacyclin precursor (PGH2), was solubilized from human platelet microsomes in 20 sucrose and 1.0% Triton X-100. The enzyme was purified 300-fold by electrofocusing, Sephadex G-200 gel filtration, and hydrophobic chromatography on ethyl agarose. The cyclooxygenase catalyzed the conversion of arachidonic acid to prostaglandin endoperioxide, PGH2, that was trapped at -25 degrees C and separated on TLC at -20 degrees C. PGH2 was hydrolyzed to HHT in acidic pH, or was chemically converted to PGE2 in slightly alkaline pH in the absence of cofactors. The enzyme showed a broad pH optimum in the range of 7-9. Hemin containing substances such as methemoglobin were absolutely required as cofactors, while tryptophan, epinephrine, phenol, and hydroquinone stimulated the PGH2 formation. Metal ions, such as ZN2+ and Cd2+ inhibited the enzyme reaction at 0.1 to 1 mM. The molecular weight of the purified enzyme was estimated at 79,432 by sodium dodecyl sulfate disc gel electrophoresis at pH 8.0. The properties of the human platelet enzyme was generally similar to the sheep vesicular enzyme in the method of solubilization, pH optimum, and molecular weight.     

Soluble and particulate forms of muscle alkaline proteinase show differential sensitivity to endogenous inhibitor(s)

Membrane-free washed myofibrils derived from rat skeletal muscle homogenates contained a chymostatin-sensitive protease(s) which acted on associated myofibrillar proteins, at an optimum pH of 8.5, much less rapidly at low ionic strength (insoluble myofilaments) than at high salt concentrations (solubilized proteins). When the myofibrillar fraction was added to the particle-free cytosol prepared from the muscle extracts, proteins of the cytosol were also degraded, but the activity in this case was much more pronounced at low ionic strength. This was because inhibitor(s) of the proteinase present in the cytosol fraction were only effective at high ionic strength when all the myofibrillar (and associated) proteins were in solution. The protease was separated from the bulk of the myofibrillar proteins by gel chromatography at high ionic strength. On dialysis against a low-salt buffer, part of the enzyme was precipitated. The putative cytosolic inhibitor(s) were again only effective on the soluble enzyme at high ionic strength.     

Characteristics of glycogen synthetase I from rabbit skeletal muscles]

Electrophoretic heterogeneity of glycosynthetase I from rabbit skeletal muscles is observed. Multiple glycosynthetase forms are separated in sucrose density gradient, their molecular weights are estimated. The existence of the enzyme as an equilibrium system of oligomeric forms, capable of reversible association-dissociation, is demonstrated. Dissociating effect of ATP, high pH values (11--12) and high ionic strength (2 M KCl) on oligomers of glycogen synthetase I is found to take place. Different activity of oligomers of different association degree is observed.     

Alteration of the specificity of restriction endonucleases in the presence of organic solvents

The specificity of XbaI, SalI, HhaI, PstI, BamHI and SstI is relaxed in the presence of an organic solvent, such as 20% glycerol or 8% dimethylsulfoxide (DMSO). This alteration, very pronounced in some cases, requires an excess of enzyme, varies from one kind of enzyme to another and is highly dependent on the pH, the ionic strength, the nature of the metallic cofactor and/or the presence of a second organic solvent. Preliminary data concerning XbaI and BamHI used under conditions where the relaxation of specificity is moderate, suggest that some of the new ("pseudo") sites correspond to shortened sequences derived from the normal recognition sequence cleaved under the standard conditions of the reaction.