Stabilization of soluble and immobilized horse liver alcohol dehydrogenase by adenosine 5'-monophosphate

Horse liver alcohol dehydrogenase, which catalyzes oxidoreductions for a broad spectrum of substrates of organic chemical interest, was immobilized on CNBr-activated Sepharose and on decylamine-substituted agarose. The specific activities of the immobilized enzyme preparations were compared with the free enzyme, and the apparent K(m) values of the preparations were determined for a selection of substrates. At pH 9 and 60 degrees C, soluble liver alcohol dehydrogenase was rapidly inactivated, while the enzyme immobilized on CNBr-activated Sepharose was more stable. Adenosine monophosphate (AMP), adenosine diphosphate, and adenosine diphosphoribose protected the free and immobilized alcohol dehydrogenase against heat inactivation. On storage under a variety of conditions, AMP effectively stabilized free horse liver alcohol dehydrogenase and the immobilized preparations.     

The effect of lead on the calcium-handling capacity of rat heart mitochondria.

1. Glucose 6-phosphate dehydrogenase (D-glucose 6-phosphate-NADP+ oxidoreductase, EC 1.1.1.49) from baker's yeast (Saccharomyces cerevisiae) was immobilized on CNBr-activated Sepharose 4B with retention of about 3% of enzyme activity. This uncharged preparation was stable for up to 4 months when stored in borate buffer, pH7.6, at 4 degrees C. 2. Stable enzyme preparations with negative or positive overall charge were made by adding valine or ethylenediamine to the CNBr-activated Sepharose 4B 30min after addition of the enzyme. 3. These three immobilized enzyme preparations retained 40-60% of their activity after 15 min at 50 degrees C. The soluble enzyme is inactivated by these conditions. 4. The soluble enzyme lost 45 and 100% of its activity on incubation for 3h at pH6 and 10 respectively. The three immobilized-enzyme preparations were completely stable over this entire pH range. 5. The pH optimum of the positively and negatively charged immobilized-enzyme preparations were about 8 and 9 respectively. The soluble enzyme and the uncharged immobilized enzyme had an optimum pH at about 8.5 6. Glucose 6-phosphate dehydrogenase immobilized on CNBr-activated Sephadex G-25 was unstable, as was enzyme attached to CNBr-activated Sepharose 4B to which glycine, asparitic acid, valine or ethylenediamine was added at the same time as the enzyme.     

The pH dependence of breakdown of various purified brain proteins by cathepsin D preparations

In a continuing study of control processes of cerebral protein catabolism we compared the activity of cathepsin D from three sources (rat brain, bovine brain, and bovine spleen) on purified CNS proteins (tubulin, actin, calmodulin, S-100 and glial fibrillary acidic protein). The pH optimum was 5 for hydrolysis with tubulin as substrate for all three enzyme preparations, and it was pH 4 with the other substrates. The pH dependence curve was somewhat variable, with S-100 breakdown relatively more active at an acidic pH range. The formation of initial breakdown products and the further catabolism of the breakdown products was dependent on pH; hence the pattern of peptides formed from glial fibrillary acidic protein was different in incubations at different pH's. The relative activity of the enzyme preparations differed, depending on the substrate: with tubulin and S-100 as substrates, rat brain cathepsin D was the most active and the bovine spleen enzyme was the least active. With calmodulin and glial fibrillary acidic protein as substrates, rat brain and spleen cathepsin D activities were similar, and bovine brain cathepsin D showed the lowest activity. Actin breakdown fell between these two patterns.The rates of breakdown of the substrates were different; expressed as μg of substrate split per unit enzyme per h, with rat brain cathepsin D activity was 8–9 with calmodulin and S-100, 4 with glial fibrillary acidic protein, 1.8 with actin, and 0.9 with tubulin. The results show that there are differences in the properties of a protease like cathepsin D, depending on its source; furthermore, the rate of breakdown and the characteristics of breakdown are also dependent on the substrate.We recently measured the breakdown of brain tubulin by cerebral cathepsin D in a continuing study of the mechanisms and controls of cerebral protein catabolism (Bracco et al., 1982a). We found that tubulin breakdown is heterogeneous, that membrane-bound tubulin is resistant to cathepsin D but susceptible to thrombin (Bracco et al., 1982b), and that cytoplasmic tubulin was in at least two pools, one with a higher, another with a lower, rate of breakdown. The pH optimum of tubulin breakdown by cerebral cathepsin D differed significantly from the pH optimum of hemoglobin breakdown by the same enzyme.These findings showed that the properties of breakdown by a cerebral protease depend on the substrate. To further examine this dependence of properties of breakdown on the substrate, we now report measurements of pH dependence of breakdown of several purified proteins (tubulin, actin, calmodulin, S-100, glial fibrillary acidic protein [GFA]) from brain by cathepsin D preparations from three sources, rat brain, bovine brain, and bovine spleen. We also compare the rate of breakdown of the various proteins with the rate of hemoglobin breakdown.     

Cathepsin L. A new proteinase from rat-liver lysosomes.

1. Cathepsin L was purified from rat liver lysosomes by cell fractionation, osmotic disruption of the lysosomes in the lysosomal mitochondrial pellet, gel filtration of the lysosomal extract and chromatography on CM-Sephadex. 2. Cathepsin L is a thiol proteinase and exists in several multiple forms visible on the disc electropherogram. By polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate its molecular weight was found to be 23000-24000. The isoelectric points of the multiple forms of cathepsin L extended from pH 5.8-6.1 ascertained by analytical isoelectric focusing. 3. Using various protein substrates, cathepsin L was found to be the most active endopeptidase from rat liver lysosomes acting at pH 6-7. In contrast to cathepsin B1, its capability of hydrolyzing N-substituted derivatives of arginine is low and it does not split esters. 4. Greatest activity is obtained close to pH 5.0 with 70-90% of maximal activity at pH 4.0 and pH 6.0 and 30-40% at pH 7.0. 5. The enzyme is strongly inhibited by leupeptin and the chloromethyl ketone of tosyl-lysine. Leupeptin acts as a pseudo-irreversible inhibitor. 6. The enzyme is stable for several months at slightly acid pH values in the presence of thiol compounds in a deep-frozen state.     

Isolation, and catalytic and immunochemical properties of cathepsin D-like acid proteinase from rat erythrocytes

An erythrocyte membrane-associated cathepsin D-like acid proteinase, termed "EMAP," was purified to homogeneity from freshly collected rat blood in a yield of 60-65%. The molecular weight of the enzyme was determined to be 80,000-82,000 by Sephadex G-100 gel filtration. The enzyme was inhibited strongly by pepstatin and partially by HgCl2, Pb(NO3)2, and iodoacetic acid. The preferred substrate for the enzyme was hemoglobin. The enzyme also hydrolyzed serum albumin and casein, but to lesser extents, with an optimum pH of 3.5-4.0. However, it could not hydrolyze leucyl-2-naphthylamide, benzyloxycarbonyl-Phe-Arg-4-methyl-7-coumarylamide or other synthetic substrates at pH values ranging from 3.5 to 9.5. The enzyme was very similar to human EMAP in a number of enzymatic properties, whereas it differed from rat cathepsin D in several respects, such as pH stability, molecular weight, isoelectric point, and chromatographic properties. Immunologically, the enzyme cross-reacted with the rabbit antibody prepared against human EMAP. The patterns of immunoelectrophoresis, immunoblotting, and immunoprecipitation of the enzyme were remarkably similar, if not identical, to those of human EMAP. In contrast, rat EMAP showed no reaction with the rabbit antibody raised to rat spleen cathepsin D. These results indicate that EMAP is a unique cathepsin D-like acid proteinase different from ordinary cathepsin D.     

Purification and characterization of rat dopamine beta-monooxygenase and monoclonal antibodies to the enzyme

Dopamine beta-monooxygenase was extensively purified from rat adrenal. The specific activity of the final preparation was approx. 1500 nmol/min per mg protein, which was much higher than the highest yet reported. As judged by gel filtration on Ultrogel AcA22, SDS-polyacrylamide gel electrophoresis, and cross-linking studies, the enzyme appeared to be composed of four identical subunits, each possessing a molecular weight of 88 000. The isoelectric point of the enzyme was estimated to be pH 6.6 in the presence of 8 M urea. Spleen cells from BALB/c mice immunized with rat dopamine beta-monooxygenase were fused to P3-X63-Ag8-653 mouse myeloma cells. From 55 hybrid cells, 10 stable clones secreting anti-dopamine beta-monooxygenase antibody were obtained. Antibody from one clone was coupled to CNBr-activated Sepharose 4B and the monoclonal antibody-Sepharose was shown to be very useful to isolate rat dopamine beta-monooxygenase from crude preparations.     

Purification and characterization of rat dopamine β-monooxygenase and monoclonal antibodies to the enzyme

Dopamine β-monooxygenase was extensively purified from rat adrenal. The specific activity of the final preparation was approx. 1500 nmol/min per mg protein, which was much higher than the highest yet reported. As judged by gel filtration on Ultrogel AcA22, SDS-polyacrylamide gel electrophoresis, and cross-linking studies, the enzyme appeared to be composed of four identical subunits, each possessing a molecular weight of 88 000. The isoelectric point of the enzyme was estimated to be pH 6.6 in the presence of 8 M urea. Spleen cells from BALB/c mice immunized with rat dopamine β-monooxygenase were fused to P3-X63-Ag8-653 mouse myeloma cells. From 55 hybrid cells, 10 stable clones secreting anti-dopamine β-monooxygenase antibody were obtained. Antibody from one clone was coupled to CNBr-activated Sepharose 4B and the monoclonal antibody-Sepharose was shown to be very useful to isolate rat dopamine β-monooxygenase from crude preparations.     

Degradation of myofibrillar proteins by cathepsins B and D

1. The procedure of Barrett [(1973) Biochem. J.131, 809-822] for isolating cathepsins B and D from human liver was modified for use with rat liver and skeletal muscle. The purified enzymes appeared to be similar to those reported in other species. 2. Sephadex G-75 chromatography of concentrated muscle extract resolved two peaks of cathepsin B inhibitory activity, corresponding to molecular weights of 12500 and 62000. 3. The degradation of purified myofibrillar proteins by cathepsins B and D was clearly demonstrated by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. After incubation with enzyme, the polypeptide bands representing the substrates decreased in intensity and lower molecular weight products appeared. 4. Cathepsins B and D, purified from either rat liver or skeletal muscle, were shown to degrade myosin, purified from either rabbit or rat muscle. Soluble denatured myosin was degraded more extensively than insoluble native myosin. Degradation by cathepsin B was inhibited by lack of reducing agent, or by myoglobin, iodoacetic acid and leupeptin, but not by pepstatin. The same potential modifiers were applied to cathepsin D, and only pepstatin produced inhibition. 5. Rat liver cathepsin B had a pH optimum of 5.2 on native rabbit myosin. The pH optimum of cathepsin D was 4.0, with a shoulder of activity about 1pH unit above the optimum. 6. Rat liver cathepsins B and D were demonstrated to degrade rabbit F-actin at pH5.0, and were inhibited by leupeptin and pepstain, respectively. 7. The degradation of myosin and actin by cathepsin D was more extensive than that by cathepsin B.     

Kinetics and stability of immobilized chicken liver xanthine dehydrogenase.

Xanthine dehydrogenase (EC 1.2.1.37) was isolated from chicken livers and immobilized by adsorption to a Sepharose derivative, prepared by reaction of n-octylamine with CNBr-activated Sepharose 4B. Using a crude preparation of enzyme for immobilization it was observed that relatively more activity was adsorbed than protein, but the yield of immobilized activity increased as a purer enzyme preparation was used. As more activity and protein were bound, relatively less immobilized activity was recovered. This effect was probably due to blocking of active xanthine dehydrogenase by protein impurities. The kinetics of free and immobilized xanthine dehydrogenase were studied in the pH range 7.5-9.1. The Km and V values estimated for free xanthine dehydrogenase increase as the pH increase; the K'm and V values for the immobilized enzyme go through a minimum at pH 8.1. By varying the amount of enzyme activity bound per unit volume of gel, it was shown that K'm is larger than Km are result of substrate diffusion limitation in the pores of the support material. Both free and immobilized xanthine dehydrogenase showed substrate activation at low concentrations (up to 2 microM xanthine). Immobilized xanthine dehydrogenase was more stable than the free enzyme during storage in the temperature range of 4-50 degrees C. The operational stability of immobilized xanthine dehydrogenase at 30 degrees C was two orders of magnitude smaller than the storage stability, t 1/2 was 9 and 800 hr, respectively. The operational stability was, however, better than than of immobilized milk xanthine oxidase (t 1/2 = 1 hr). In addition, the amount of product formed per unit initial activity in one half-life, was higher for immobilized xanthine dehydrogenase than for immobilized xanthine oxidase. Unless immobilized milk xanthine oxidase can be considerable stabilized, immobilized chicken liver xanthine dehydrogenase is more promising for application in organic synthesis.     

Cathepsin E from rat neutrophils: its properties and possible relations to cathepsin D-like and cathepsin E-like acid proteinases

An extract of rat neutrophils was found to contain a high hemoglobin-hydrolyzing activity at pH 3.2, about 70% of which does not cross-react with anti-rat liver cathepsin D antibody. A neutrophil non-cathepsin D acid proteinase was successfully isolated from cathepsin D and characterized in comparison with the properties of rat liver cathepsin D. The neutrophil enzyme differed from cathepsin D in chromatographic and electrophoretic behaviors as well as immunological cross-reactivity, and its molecular weight was estimated to be 98,000 by gel filtration on Toyopearl HW 55. These findings strongly suggest that the neutrophil enzyme could be classified as cathepsin E. The enzyme, now designated rat cathepsin E, had an optimal pH at 3.0-3.2, preferred hemoglobin to albumin as substrate, and was markedly resistant to urea denaturation. Rat cathepsins D and E cleaved the insulin B-chain at six and eight sites, respectively; five sites were common for both enzymes. Possible relations among cathepsin E and cathepsin D-like or E-like acid proteinases reported so far were discussed.     

The use of phospholipid vesicles for in vitro studies on cholesteryl ester hydrolysis.

Radiolabeled cholesteryl oleate was incorporated into vesicles prepared from egg yolk lecithin and utilized as a substrate for studies of sterol ester hydrolases present in rat liver homogenates. The cholesteryl oleate was shown to be associated with vesicles (unilamellar liposomes) using Sepharose 4B chromatography. With this substrate, two different cholesteryl ester hydrolytic enzymes were demonstrated in subcellular fractions from the liver homogenates. In the lysosome-rich fraction an acid hydrolase was present, while in the cytosol fraction (150,000 g supernatant), hydrolytic activity was shown to occur with an optimum pH between 8 and 8.5. The substrate was characterized by Sepharose chromatography both before and after incubation with the liver fraction and was not dramatically altered even by rigorous incubation conditions. The lysosomal enzyme preparation was capable of hydrolyzing almost all the cholesteryl oleate in the vesicles. Hydrolysis of the phospholipid was proportionately much less than that of the cholesteryl oleate. Comparisons were performed between the vesicle preparation and an alternate substrate preparation involving the direct addition of cholesteryl oleate in acetone solution. The vesicles appeared to be a better substrate for the lysosomal enzyme whereas the activity in the cytosol fraction did not distinguish between the two substrate preparations. Unsonicated suspensions of cholesteryl oleate and lecithin did not serve as suitable substrates for the enzymes. These studies demonstrate the applicability of cholesteryl ester-containing vesicles as a useful substrate for studying cholesteryl ester hydrolysis in vitro.     

Purification and properties of two enzymes catalyzing galactose transfer to GM2 ganglioside from rat liver Golgi

An enzyme activity which catalyzed the transfer of galactose from UDP-galactose to GM2 ganglioside was demonstrated in rat liver homogenate and enriched 38-fold in specific activity by preparation of Golgi membranes. This activity could be solubilized from Golgi membranes by sonication and extraction with 1% Triton X-100. The solubilized activity catalyzed the formation of GM1 ganglioside and was completely dependent upon the addition of acceptor. The rate of galactose incorporation was constant for up to 5 h at 30 degrees C. This enzyme activity was further purified by gel filtration on Sepharose CL-6B and ion exchange chromatography on DEAE-Sepharose. The elution position on gel filtration corresponded to a molecular weight for the enzyme of 38,000 which was in good agreement with that obtained by sedimentation velocity studies. Ion exchange chromatography resolved GM2 ganglioside galactosyltransferase into two species. The more basic enzyme (I) comprising 28% of the recovered activity was not retarded by the column, whereas enzyme II was eluted from the resin following the application of a salt gradient. Net purification was 120- to 140-fold for each enzyme with a total recovery of 42%. Unlike the activity in the Golgi extract, the purified enzymes I and II were labile to freezing and could be stored at -20 degrees C only in the presence of 50% glycerol. Both enzymes I and II had similar molecular weights and Michaelis constants and both had a strict requirement for Mn2+. Properties which distinguish the two enzymes included pH optima (enzyme I 7.0, enzyme II 6.0) and surfactant requirements. Neither enzyme was active following removal of Triton X-100 from the preparation. Among a series of glycolipids tested for ability to serve as substrates for galactose transfer only GM2 and asialo-GM2 ganglioside served as acceptors.     

Vitellogenesis-related ovary cathepsin D from Xenopus laevis: Purification and properties in comparison with liver cathepsin D

Cathepsin D was purified from ovaries of Xenopus laevis by both QAE-cellulose and pepstatin-Sepharose chromatography and then characterized and compared with Xenopus liver cathepsin D. Ovary cathepsin D appeared predominantly as a 43-kilodalton (kDa) molecular mass, as revealed by SDS-polyacrylamide gel electrophoresis, whereas the liver enzyme was obtained exclusively as a 36-kDa protein. The purified 43-kDa ovary enzyme cleaved vitellogenin limitedly to produce yolk proteins at pH 5.6. The specific activity of ovary cathepsin D was five to six times lower than that of the liver enzyme, as measured by hemoglobin-hydrolysis at pH 3, but the ovary enzyme was shown to be superior to the liver enzyme in terms of vitellogenin-cleaving activity, as examined at pH 5.6. Ovarian enzyme preparations contained variable amounts of 36-kDa species; this form was considered to be an autolytic product of the 43-kDa form arising during purification, because it was not detected in oocyte extracts but was generated by incubation of the purified 43-kDa enzyme alone in an acid solution. The conversion of the 43-kDa form by hepatic factors was accompanied by a marked increase in hemoglobin-hydrolytic activity.     

Unique cathepsin D-type proteases in rat thoracic duct lymphocytes and in rat lymphoid tissues.

Two unique cathepsin D-type proteases apparently present only in rat thoracic duct lymphocytes and in rat lymphoid tissues are described. One, termed H enzyme, has an apparent molecular weight of similar to95,000; the other, termed L enzyme, has an apparent molecular weight of similar to45,000, in common with that of most cathepsins D from other tissues and species. Both enzymes differ from cathepsin D, however, by a considerably greater sensitivity to inhibition by pepstatin and by a smaller degree of inhibition by an antiserum which inhibits rat liver cathepsin D. H enzyme is converted to L enzyme by treatment with beta-mercaptoethanol; the relationship between the two enzymes remains unknown. H and L enzyme have been detected in rat lymphoid tissues and in mouse spleen, but they are not present in other rat tissues (liver, kidney, adrenals), rabbit tissues, calf thymus, bovine spleen, or human tonsils. As measured on acid-denatured bovine hemoglobin as substrate, both enzymes have pH activity curves identical with that of rat liver cathepsin D, with optimal activity at pH 3.6. Activity on human serum albumin is much less and also shows an optimum at pH 3.6; hence, neither enzyme has the properties of cathepsin E. Thiol-reactive inhibitiors have no effect on the activity of H and L enzyme; thus they do not belong to the B group of cathepsins. Additional information, discussed in this paper, leads us to conclude that partially purified H and L enzymes are cathepsin D-type proteases.     

Are Z-Arg-Gly-Phe-Phe-Leu-MNA and Z-Arg-Gly-Phe-Phe-Pro-MNA suitable substrates for the demonstration of cathepsin D activity?

Summary The suitability of Z-Arg-Gly-Phe-Phe-Leu-MNA and Z-Arg-Gly-Phe-Phe-Pro-MNA for the assessment of cathepsin D activity was tested in biochemical and histochemical experiments. Substrates were dissolved in dimethylformamide and used at 0.1–0.5 mM in various buffers over a pH range of 3.5–7.4. Homogenates of various rat organs and isolated purified enzymes [cathepsin D from bovine spleen, dipeptidyl peptidase (DPP) I.V from porcine kidney and rat lung] were used as enzyme sources. Pepstatin, di-isopropylfluorophosphate (DFP),p-chloromercuribenzoate,o-phenanthroline and a series of DPP IV inhibitors were used in inhibitor experiments. At pH 3.5 and 5.0, substrates were used in a two-step postcoupling procedure with aminopeptidase M and dipeptidyl peptidase IV as auxiliary enzymes and Fast Blue BB as coupling agent. Results were compared with those obtained with haemoglobin. Above pH 5.0 substrates were used in a one-step postcoupling procedure.Cryostat sections of snap-frozen or cold aldehyde-fixed tissue pieces of various rat organs and biopsies of human jejunal mucosa were used in histochemical experiments. As in biochemical tests a two-step procedure was used in the pH range 3.5–5.0, but Fast Blue B was used in the second step for the simultancous coupling. Above pH 5.0 a onestep simultaneous azo coupling procedure was used with Fast Blue B as coupling agent.At pH 3.5 the hydrolysis rate of both synthetic substrates was about 100 x lower than that of haemoglobin when cathepsin D from bovine spleen was used. The activity was inhibited by pepstatin. With increasing pH the hydrolysis rate of Z-Arg-Gly-Phe-Phe-Pro-MNA increased, while that of Z-Arg-Gly-Phe-Phe-Leu-MNA decreased when organ homogenates were used as enzyme sources. However, the activity was not inhibited by pepstatin. It was inhibited by DFP. The extent of the inhibition with other substances was species and organ dependent. Z-Arg-Gly-Phe-Phe-Pro-MNA was also cleaved by isolated and purified DPP IV of porcine kidney and rat lung and the activity was inhibited by DFP and DPP IV inhibitors.In histochemical experiments the staining obtained with both synthetic substrates at pH 3.5 was weak and rather diffuse, with only slight accentuation or none at all in the lysosomal region of cells. In the pH range 5.5–7.4 a very distinct reaction was observed with Z-Arg-Gly-Phe-Phe-Pro-MNA only. The reaction product was localized in the brush border of enterocytes and of cells of the proximal kidney tubules. Endothelial cells of glomeruli and capillaries of the propria of the human jejunum also displayed a positive reaction. Lymphocytes in the propria of rat small intestine reacted to some extent. The reaction was inhibited by DFP. The extent of the inhibition with other substances varied.Z-Arg-Gly-Phe-Phe-Leu-MNA and Z-Arg-Gly-Phe-Phe-Pro-MNA are not efficient substrates for the assessment of cathepsin D activity. In histochemical studies diffusion artifacts must always be considered. In the pH range 5.5–7.4, Z-Arg-Gly-Phe-Phe-Pro-MNA is cleaved by a serine endopeptidase and by a metalloendopeptidase. It remains to be established whether prolyl endopeptidase or DPP IV (or both) and which metalloendopeptidase are responsible for the cleavage. In the evaluation of enterobiopsies the demonstration of this activity is a sensitive means for the assessment of the state of the brush border.Dedicated to Professor Dr. T.H. Schiebler on the occasion of his 65th birthday.     

Characterization of hemoglobin-hydrolyzing acidic proteinases in human and rat neutrophils

The nature and levels of hemoglobin (Hb)-hydrolyzing acidic proteinases including cathepsin D and cathepsin E, which were most active at pH 3.5-4.0, were enzymatically and immunochemically compared between human and rat neutrophils. By subcellular fractionation and immunoprecipitation with discriminative antibodies specific for each enzyme, cathepsin D was shown to be present in the granular content fraction of both human and rat neutrophils and to account for about 35% of the total Hb-hydrolyzing activity. Cathepsin E was observed mainly in the cytoplasmic fraction of rat neutrophils from peripheral blood and peritoneal exudates and accounted for about 65% of the total activity, but it was not detected in human blood neutrophils. Immunoelectron microscopy on rat neutrophils revealed that cathepsin D was exclusively confined to lysosomes, whereas cathepsin E was localized mainly in the cytoplasmic matrix and often in the perinuclear spaces and the rough endoplasmic reticulum. The non-cathepsin D activity in human neutrophils, which represented about 65% of the total activity, appeared to be due to a serine proteinase, since it was inhibited by diisopropyl fluorophosphate and phenylmethylsulfonyl fluoride and was not inhibited by agents specific for aspartic-, cysteine-, or metallo proteinases. The enzyme(s) responsible for this activity was largely associated with the granular membranes, and a half of it could be described as an integral membrane protein on the basis of phase separation with Triton X-114 at 35 degrees C. The levels of these Hb-hydrolases in gingival crevicular fluid from human chronic inflammatory periodontitis patients were examined in order to clarify their participation in the periodontal tissue breakdown.(ABSTRACT TRUNCATED AT 250 WORDS)     

The use of biochemical solid-phase techniques in the study of alcohol dehydrogenase. 1. Some studies on subunit interactions in alcohol dehydrogenase with subunits covalently bound to agarose

The EE and SS isozymes of horse liver alcohol dehydrogenase have been immobilized separately to weakly CNBr-activated Sepharose 4B. The resulting immobilized dimeric preparations lost practically all of their activity after treatment with 6 M urea. However, enzyme activity was regenerated by allowing the urea-treated Sepharose-bound alcohol dehydrogenase to interact specifically with either soluble subunits of dissociated horse liver alcohol dehydrogenase or soluble dimeric enzyme. The regeneration of steroid activity in the immobilized preparations after treatment of the bound S subunits with soluble E subunits seems to show that true reassociation of the enzyme had taken place on the solid phase, since only isozymes with an S-polypeptide chain are active when using 5 beta-dihydrotestosterone as substrate. The results presented in this paper indicate that immobilized single subunits of horse liver alcohol dehydrogenase are inactive and that dimer formation is a prerequisite for the enzymic activity.     

Identification and partial purification of an ATP-stimulated alkaline protease in rat liver.

Extracts from rat liver contain a sulfhydryl-dependent endoprotease which degrades [methyl-14C]globin or 125I-hemoglobin to acid-soluble peptides. This enzyme was isolated from the 100,000 x g supernatant of the homogenate. It showed a pH optimum between 7.5 and 9.5 and very little activity below pH 7.0. The enzyme has an apparent molecular weight of 550,000 as determined on Sepharose 6B column chromatography and sucrose density gradient centrifugation. ATP, at physiological concentrations, as well as pyrophosphate, stimulated the protease activity in these partially purified preparations up to 3-fold. Nonionic detergents such as Triton X-100 increased proteolytic activity and the stimulation by ATP. Other nucleotide triphosphates and ADP also increased proteolysis but less effectively than ATP. Sodium phosphate, creatine phosphate, and EDTA had no stimulatory effect.     

Hydrolysis of rice hull by crosslinked Aspergillus niger cellulase

A. niger cellulase was crosslinked by glutaraldehyde to obtain a heat-stable enzyme preparation for rice hull cellulose hydrolysis. Under optimized crosslinking conditions of 0.12 M glutaraldehyde, pH 7.0, temperature 40 degrees C and at 45 min of crosslinking, a preparation having 15% more activity than free enzyme was obtained which also had considerable improvement in heat stability at 65 degrees C and 70 degrees C. Whereas the free enzyme lost 80% of its activity in 4 h at 65 degrees C, the crosslinked preparation lost only 30% activity. The crosslinked preparation hydrolyzed cellulosic biomass more effectively giving 2.2 mg/ml glucose and 52% corresponding saccharification in 4 h at 65 degrees C as compared to 14% saccharification by free enzyme under similar conditions.