1.1. The role of histidine on the decarboxylation of porphyrinogens of 7-, 6-, and 5-COOH III brought about by porphyrinogen carboxy-lyase (PCL) was studied.
2.2. For this purpose hepatic PCL from normal and hexachlorobenzene (HCB) treated rats were modified with diethylpyrocarbonate.
3.3. The results indicated that the enzyme from both normal and porphyric animals had histidine at the binding sites of all the porphyrinogens assayed.
4.4. Comparative studies between the enzyme from normal and porphyric rats suggested that in vivo HCB treatment affected the active site for the decarboxylation of 7-, 6- and 5-COOH porphyrinogens III at histidine residues.
5.5. On the other hand arginine modification by 2,3-butanedione treatment altered 5-COOH porphyrinogen III decarboxylation for both enzymes. However this amino acid was not involved at the binding site of this substrate.
1.1. Uroporphyrinogen decarboxylase (EC 4.1.1.37) has been purified 16-fold from Rp. palustris to a specific activity of 210 nmol of total decarboxylated porphyrinogens III formed/hr per mg of protein and about 50% yield. The Rp. palustris enzyme exhibits some unusual properties as compared with URO-D from other sources.
2.2. The purified enzyme is a monomer with a molecular weight of ∼46,000, an isoelectric point of 4.6 and an optimum pH of 6.9 and 6.8 with urogen III and I substrate. Neither GSH nor EDTA seem to be necessary for activity, and the decarboxylation rate and the distribution of the reaction products was not affected either by the presence or absence of oxygen.
3.3. The Rp. palustris enzyme is a thermo-stable protein, heating at 60°C for 15 min enhanced several times activity. This is the first time that the heat treatment is included as one of the steps to purify URO-D.
4.4. Thermal activation followed an identical profile using either substrate. The ratios of specific activity for the type III and I isomer of urogen remained constant throughout the purification. These findings are indicating that a single enzyme catalyzes the four decarboxylations occurring from urogen to coprogen.
5.5. Kinetic data employing urogen III and I as substrate showed that the pattern of accumulated intermediates was rather different depending on whether type III or I isomer was used.
6.6. While decarboxylation of urogen III responds to the usual scheme: where v1⪢v2 and decarboxylation of heptagen III is the rate-controlling step.
7.7. Decarboxylation of urogen I revealed a completely different and characteristic picture fitting the scheme: where again v′1⪢v′2 and the removal of the final carboxyl group from pentagen I becomes the rate-limiting step.
1.1. Malic enzyme purified from the fruit tissue of Mangifera indica was irradiated in aqueous solution and the effect of γ-irradiation on the catalytic and regulatory properties of the enzyme was investigated.
2.2. Significant differences in some of the allosteric properties of the enzyme were found as reflected in the various Hill-coefficients.
3.3. Changes in both the kinetic parameters Vmax and Km were observed; suggesting that irradiation leads not only to destruction of the active sites but also to a general denaturation of the enzyme.
4.4. The physiological significance of the radiation induced alterations are discussed against the background of ripening and sensescence.
1.1. Subcellular fractions of rat liver were assayed for PLA2 activity.
2.2. The PLA2 assay measures the release of [3 H]oleic acid from phospholipids, using labeled E. coli as substrate.
3.3. Nuclear fractions contained PLA2 activity, which was Ca2+ dependent and could not be explained from mitochondrial, microsomal or plasma membrane contamination.
4.4. The Vmax value of nuclear PLA2 is 0.30 ± 0.04 pmol oleic acid/min/mg protein; its Km value is 0.86±0.12μM, similar to that of mitochondrial PLA2.
5.5. We conclude that rat liver nuclei contain PLA2 activity.
1.1. A lipoxygenase activity was purified from Thermoactinomyces vulgaris and some of its properties were characterized.
2.2. The enzyme showed a temperature activity range of 40–55°C with still significant activity over 60°C.
3.3. The pH of activity on linoleic acid had a broad range with an optimum at pH 6.0 and a weaker one at pH 11.0.
4.4. On arachidonic acid the pattern was narrow bell-shaped with an optimum at pH 6.5.
5.5. The purified lipoxygenase from Th. vulgaris showed an apparent Km of 1 mM and Vmax of 0.84 μmol diene/min/mg protein.
6.6. It was inhibited by the oxidation products, 9-HPOD and 13-HPOD.
7.7. A 160,000 Da molecular weight of the enzyme was determined by molecular filtration. Methionine, tyrosine, tryptophan and cysteine are apparently involved in its activity.
1.1. Three forms of cholinesterase were sequentially extracted from head and tentacles of Sepia officinalis and noted as low-salt (LSS), detergent (DS) and high-salt (HSS) soluble. They represent about 24, 30 and 46% of total activity.
2.2. All enzyme forms seem to be amphiphilic proteins with hydrophobic domains interacting with non-ionic detergent (Triton X-100) and giving self-aggregation (LSS form).
3.3. The DS form is membrane-anchored by a phosphatidylinositol, while the HSS form is likely linked to some proteoglycan molecule of the extracellular matrix by ionic interactions.
4.4. According to Vmax/Km values, all the enzymes are acetylcholinesterases, even if hydrolyze propionylthiocoline at the highest rate.
5.5. Some kinetic and molecular properties of the studied enzymes are compared with those of other cholinesterases from vertebrates and invertebrates. Possible phylogenic and adaptive features are discussed.
1.1. The mean Km and Vmax values for G3PDH isolated from the lateral muscle of cold-adapted (5°C) rainbow trout, Salmo gairdneri, were twice those of enzyme from warm-adapted (15°C) trout when assayed at 7°C but not at any other temperature.
2.2. The entropy of activation of warm enzyme was about 3 times that of cold enzyme. However, enthalpy or free energy of activation among acclimation groups differed less or not at all.
3.3. Individual G3PDH isolates within either adaptation group differed in kinetic characteristics.
1.1. Low Km 5' nucleotidase purified from human seminal plasma has been used in this study to investigate the response of the enzyme to adenine nucleoside di- and triphosphates in the presence of AMP and IMP as substrates.
2.2. In the presence of AMP, the addition of 0.5 mM ATP to the enzyme Mg-free results into the highest Vmax/Km ratio value and other experimental combinations of effectors tested cause variation of the kinetic parameters of the enzyme, indicating a control of AMP dephosphorylation by adenine nucleotides.
3.3. In the presence of IMP, ATP and ADP activate the enzyme but the response to various experimental combinations of effectors shows no significant difference in the kinetic properties of the enzyme, indicating a different control of the dephosphorylation of IMP.
1.1. Malate dehydrogenase has been purified from the foot muscle of Patella caerulea by ion-exchange chromatography on DEAE-cellulose, affinity chromatography on Blue Agarose and gel filtration on Sephadex G-150.
2.2. The yield was 23.5% of the initial activity with a final specific activity of 257 U/mg of protein.
3.3. The apparent mol. wt of the native enzyme is approx. 75,000 and it consists of two subunits of mol. wts in the range of 36,000–39,000.
4.4. The enzyme exhibits hyperbolic kinetics with respect to oxaloacetate, NADH and l-malate. The Km values were determined to be 0.055 mM for oxaloacetate, 0.010 mM for NADH and 0.37 mM for l-malate. The pH optima are around 8.4 for the reduction of oxaloacetate and 9.2–9.6 for the reduction of oxaloacetate and 9.2–9.6 for the l-malate oxidation. Vmax and Km values for oxaloacetate change in an opposite manner with respect to pH values.
5.5. Of the various compounds tested, only α-ketoglutarate, citrate and adenylate phosphates were found to inhibit the enzyme activity.
6.6. From the above properties it appears that the reaction of cytoplasmic malate dehydrogenase of P. caerulea foot muscle is a key reaction in the anaerobic pathway and it occurs with the production of malate.
1.1. The addition of sulfide to sea-water in respirometer flasks stimulated oxygen uptake by intact Solemya velum; at concentrations of 0.5 and 0.8 mM, the experimental rates were 1.8 and 2.5 times control rates.
2.2. Extracts of gill tissue catalyzed the conversion of thiosulfate to sulfite, the production of adenosine phosphosulfate (APS) from AMP and sulfite and the formation of ATP from APS. The enzymes, thiosulfate sulfurtransferase (EC 2.8.1.1), adenylsulfate reductase (EC 1.8.99.2) and sulfate adenylyl transferase (EC 2.7.7.4) have Km and Vmax in the same range as similar enzymes in other species.
3.3. Calculations based on these experiments suggest that adenylylsulfate reduction is ordinarily catalyzed at no more than 8% of maximum velocity.
1.1. 3,3',4,4'-tetrachlorobiphenyl (PCB 77), but not hexachlorobenzene, induced liver micro-somal cytochrome P-450 (Cyt P-450), ethoxycoumarin-O-deethylase (ECOD) and ethoxyresorufin-O-deethylase (EROD) in rainbow trout. Maximum induction was observed in a PCB 77 injected group of fish (1.0mg/kg, i.p. injection) 13 days after the injections being 2, 10 and 50 times the values of non-induced fish, respectively.
2.2. The apparent Km value of ethoxyresorufin of this induced group of fish differed only slightly from that of non-induced fish. The apparent Vmax value (EROD) was 50 times higher.
3.3. Freezing small pieces of liver in liquid nitrogen did not produce cytochrome P-420.
4.4. Fluorimetric and spectrophotometric measurements of EROD correlated.
1.1. The properties of Na+/K+-transporting ATPase in microsomal fractions from the nervous tissue of the grasshopper, Poekilocerus bufonius were investigated.
2.2. Two components of ATPase activity are present.
3.3. Inclusion of 1 mM ouabain in the incubation media reduced the activity of total and Na+/K+-ATPase by 57 and 79%, respectively.
4.4. The maximum velocity (Vmax) was decreased by the addition of 1 mM ouabain, whereas the apparent Km value was not affected indicating a non-competitive type of inhibition.
5.5. The calculated value of the pI50 was 6.4 (I50 = 3.98 × 10−7M) for ouabain inhibition of the enzyme showing great sensitivity to the cardiac glycoside ouabain.
6.6. The present results show that the physicochemical properties of Na+/K+-transporting ATPase from the brain of P. bufonius are essentially the same as for the enzyme prepared from the excretory system of the insect which has been previously investigated.
7.7. Dissimilarities were also observed between these tissues in the way that the enzyme from the brain was sensitive to ouabain inhibition with a non-competitive type rather than a ouabain-resistance and a competitive type of inhibition for the enzyme from the excretory system.
8.8. These dissimilarities are probably due to different isoenzyme patterns available in the same insect.
1.1. To characterize an enzyme which metabolizes retinal in liver microsomes, several properties of the enzymatic reaction from retinal to retinoic acid were investigated using rabbit liver microsomes.
2.2. The maximum pH of the reaction in the liver microsomes was 7.6.
3.3. The Km and Vmax values for all-trans, 9-cis and 13-cis-retinals were determined.
4.4. The reaction proceeded in the presence of NADPH and molecular oxygen.
5.5. The incorporation of one atom of molecular oxygen into retinal was confirmed by using oxygen-18, showing that the reaction comprised monooxygenation, not dehydrogenation.
6.6. The monooxygenase activity was inhibited by carbon monoxide, phenylisocyanide and antiNADPH-cytochrome P-450 reductase IgG, but not by anti-cytochrome b5 IgG.
7.7. The enzymatic activity inhibited by carbon monoxide was photoreversibly restored by light of a wavelength of around 450 nm.
8.8. The retinal-induced spectra of liver microsomes with three isomeric retinals were type I spectra.
9.9. The microsomal monooxygenase activity induced by phenobarbital or ethanol were more effective than that by 3-methylcholanthrene, clotrimazole or β-naphthoflavone.
10.10. These results showed that the monooxygenase reaction from retinal to retinoic acid in liver microsomes is catalyzed by a cytochrome P-450-linked monooxygenase system.
1.1. The specific activity of DNA-polymerase α isolated from pSV3.neo-transformed cells was more than 9-fold higher than that of polymerase a from untransformed cells.
2.2. Western blot analysis, using anti-SV40 large T antigen, of both a crude cellular extract and of partially purified polymerase a from pSV3.neo-transformed cells revealed a single 76 kDa immunoreactive band not found in either crude extracts or partially purified enzyme from untransformed cells.
3.3. The α polymerases from untransformed and transformed cells differed in molecular size, sensitivity to various inhibitors, specificity of template-primer utilization, and binding affinity for DNA cellulose, but showed essentially no differences in Km or Vmax.
4.4. These data suggest that polymerase α isolated from pSV3.neo-transformed cells exhibits altered physical and catalytic characteristics compared with its untransformed cell counterpart, and that those alterations may be associated with increased replication of the genome in plasmid-transformed cells.
1.1. Fundamental chitin digestion characteristics of Crassostrea virginica crystalline style were investigated.
2.2. Optimum temperature and pH were 34°C and 4.8. respectively.
3.3. The colloidal regenerated chitin (0.56mol/0.5 ml: GlcNAc equivalents) was saturating under all enzyme levels encountered.
4.4. There was no evidence of end product inhibition, even after 100 hr incubation.
5.5. Calculated Km for the chitinase complex was 1.19mM when determined using a 30 min assay, but was only 0.70 mM when determined using a 4.6 hr assay.
6.6. Both Km values are lower than reported for similar assays in other molluscs and for most bacteria.
7.7. Effect of substrate preparation on the kinetics are discussed.
8.8. Eight peaks of chitinase activity were resolved by DEAE-Fractogel ion exchange chromatography.
1.1. The copepod Acartia clausi exhibited two laminarinases (exo- and endo-acting forms) purified by gel chromatography followed by affinity chromatography. Specific antibodies have been raised against the purified exolaminarinase antigen.
2.2. A single band of protein appeared on a polyacrylamide disc gel electrophoresis; its mol. wt is 21,000.
3.3. Biochemical properties of the purified enzyme showed a maximum activity at pH 5.2 and a temperature of 40°C with laminarin as substrate. The thermal stability of the enzyme and the effect of various cations on its activity were examined. The enzyme hydrolyses specifically the β(1–3) linked polysaccharides and had no activity against the α(1–4) or β(1–4) disaccharides or polysaccharides.
4.4. The kinetic parameters Vm and Km vary with the temperature; the affinity constant (Ka) was maximum between 25–30°C. The Arrhenius plot defined two values of energy of activation: 7980 cal/mole and 17,506 cal/mole.
5.5. From the purification scheme the exoacting form appears to be largely dominant over the endoacting form.
1.1. Biliverdin reductase from the liver of eel, Anguilla japonica was characterized and purified with a novel enzymatic staining method on polyacrylamide electrophoretic gel.
2.2. This enzyme could use both NADPH and NADH as coenzyme. The Km of NADPH was 5.2 μM, while that of NADH was 5.50 μM.
3.3. The optimum reaction pH for using HADPH as coenzyme was 5.3. That for NADH was 6.1. The optimum reaction temperature is 37°C.
4.4. When NADPH was used as coenzyme, the Km of biliverdin was 0.6 μM. When NADH was used as coenzyme, the Km of biliverdin was 7.0 μM.
5.5. The activity of the enzyme was inhibited by the concentration of biliverdin. Also, the potency of the enzyme was much less than that of the analogous enzyme isolated from mammals.
6.6. This is a fairly stable enzyme with a mol. wt around 67,000. Its estimated pI was pH 3.5–4.0.
7.7. This is the first time biliverdin reductase has been isolated and characterized from a vertebrate other than mammals. The property of it is quite different from that of mammals.
1.1. The enzyme fructose-1,6-bisphosphatase was purified from the mantle of the sea mussel Mytilus galloprovincialis Lmk. The purified enzyme showed a single band in SDS-polyacrylamide gel electrophoresis. The mol. wt and subunit mol. wt of the enzyme were 105,000 and 27,000, respectively.
2.2. Divalent cations are essential for the enzyme activity. In the absence of chelating agents, FBPase 1 exhibits hyperbolic kinetics with respect to Mn2+, Zn2+ and Mg2+. The Km for Mg2+ is lower than the physiological concentration of cation in the tissue, whereas its Km for Mn2+ and Zn2+ is greater than the respective in vivo concentrations.
3.3. The joint action of Mg2+ and Zn2+ increases the affinity of the enzyme for the substrate Fru-1,6-P2, though Vmax is reduced.
4.4. Na+ strongly inhibits the enzyme even at very low concentrations. K+ has no effect whatsoever.
1.1. The malate dehydrogenase (MHD) activity from the ribbed mussel gill is polymorphic with two distinct mitochondrial forms (M1 and M2) and five forms that could be resolved from cytosolic extracts (C1 to C5) by DEAE-cellulose chromatography and starch gel electrophoresis.
2.2. Two of the cytosolic forms (C3 and C4) may represent interchangeable conformational states.
3.3. With kinetic analysis there appear to be three distinct cytosolic forms (C1, C2 and C3–C4), with C2 possibly behaving as a heterodimer.
4.4. The identity of C5 is uncertain.
5.5. The forms isolated from the mitochondria (M1 and M2) exhibited lower apparent Kms for oxaloacetate (OAA) than the cytosolic forms.
6.6. For all isozymic forms, the apparent Kms for OAA increased as the pH increased between pH 6 and 9
7.7. Increasing the salt concentration raised the Km for OAA for all forms.
8.8. The mMDHs were more sensitive to inhibition by NaCl than the cMDHs.
9.9. Representative cMDH (C1) and mMDH (M2) isozymes exhibited substrate inhibition by high concentrations of OAA with the mMDH possessing lower Kis for substrate inhibition than the cMDH at each pH tested.
10.10. Differences and similarities in Km app. for OAA at the different pHs and salt concentrations indicated that C1, C2 and C3–C4 and C5 were distinct forms, that M1 and M2 were distinct but very similar to each other, and that C1, C2, C3–C4 and C5 were distinct from M1 and M2.
