Sepharose-bound trypsin and activated sepharose-bound trypsinogen. Studies with small and large substrates

Several enzymic and physical properties of Sepharose-bound trypsin and activated Sepharose-bound trypsinogen have been compared to those of the soluble enzyme. Sepharose-bound trypsinogen could be activated to the same extent as soluble trypsinogen; the release of the activation peptide and formation of the active site occurred as expected in the presence of catalytic amounts of trypsin. With synthetic substrates, the relative activity and pH dependence of both immobilized trypsin preparations were essentially identical and nearly the same as the soluble enzyme. Sepharose-trypsin also formed an inactive complex with soybean trypsin inhibitor, with 85% of the active sites participating. In contrast, the activity of Sepharose-trypsin with chymotrypsinogen and with trypsinogen as substrates was only 40% that of soluble trypsin. There is evidence for some catalytic heterogeneity of active sites of bound trypsin; probably those sites buried within the gel have a limited catalytic efficiency with macromolecular substrates. The immobilized enzyme is more stable than the soluble enzyme at elevated temperatures and to concentrated urea, and denaturation by urea at pH 8 is fully reversible since the loss of molecules by autolysis is eliminated.     

Human alpha 2-macroglobulin as an inhibitor of insoluble trypsin

alpha 2-Macroglobulin binds to insoluble trypsin bound on agarose beads inducing a reduction of proteolytic activity of the enzyme towards large substrates such as azocasein. When trypsin was bound on other matrices like sheep red blood cells or latex beads, the inhibition of proteolytic activity by alpha 2-macroglobulin was complete. These results show that alpha 2-macroglobulin inhibits similarly both soluble and insoluble proteinases.     

Effects of acrosin inhibitors on the soluble and membrane-bound forms of ram acrosin, and a reappraisal of the role of the enzyme in fertilization.

When denuded ram spermatozoa were suspended in weakly buffered 0.25M sucrose, the acrosin remained bound to the acrosomal membranes of the sperm heads. Media containing CaCl2 caused complete solubilization of the enzyme. Effects of acrosin inhibitors on soluble and bound enzyme were studied in Tris HCl(pH 8.2) containing sucrose. Denuded spermatozoa were used as a preparation of bound acrosin. Trasylol (Kunitz basic pancreatic trypsin inhibitor) acted more strongly on bound scrosin than on soluble acrosin, but soya-bean trypsin inhibitor acted more strongly on soluble acrosin. At concentrations 0.5 - 2.0muM, the inhibitors isolated from ram acrosomes and from ram seminal plasma inhibited soluble acrosin but had negligible effects on bound acrosin. However, bound acrosin was sensitive to high concentrations of the acrosomal inhibitor. The two forms of acrosin were inhibited to about the same degree by p-aminobenzamidine and also by Tos-Lys-CH2Cl. It is proposed that membrane-bound acrosin is the form that functions in penetration of the zona pellucida, and that a role for acrosin inhibitors is suppression of an antifertility effect of soluble acrosin on mammalian eggs. This hypothesis is supported by 1) the results of work on the impaired fertilizing capacity of rabbit spermatozoa that have been treated with acrosin inhibitors, 2) the anti-fertility effects on hamster eggs of solutions of acrosin and of bovine trypsin, and 3) the results in this paper.     

Immobilization of proteinases on Chitosan

Summary Trypsin, pronase and subtilisin were immobilized on chitosan by glutaraldehyde coupling. Significant retention of activity was observed when synthetic substrates as well as casein were used. The specific activities of the bound proteinases ranged from 38% to 79% of their initial specific activities. The pH-activity profile of trypsin was slightly shifted toward alkaline values, and its thermal stability was increased. Immobilized trypsin was found to be less sensitive to its natural inhibitors than the soluble enzyme.A preliminary report of this work has already been presented at the First European Congress on Biotechnology (September 25–30, 1978, Interlaken, Switzerland).     

Soluble precursor of membrane-associated protein kinase in uterine smooth muscle cells

Incubation of smooth muscle strips from rat uterus with isoproterenol resulted in redistribution of protein kinase activity between the cytosol and a 20,000 to 50,000g membrane fraction. Similarities in the elution properties of the cytosolic and membrane-associated forms of the enzyme on DEAE-cellulose ion exchange chromatography further suggested the two forms were the same. The nature of membrane binding of the soluble enzyme was investigated using smooth muscle microsomal and cytosol fractions. Membranes readily bound the soluble enzyme when the two subcellular compartments were reconstituted and incubated at 30 °C for 10 min. The extent of binding was proportional to the ratio of membranes to cytosol and was characterized by the inhibition of soluble enzyme activity toward exogenous substrates in a Triton X-100 reversible manner. In marked contrast to the binding of soluble protein kinase to heart particulate fractions, binding of the cytosol enzyme to smooth muscle cell membranes was unaffected by ionic strength or cAMP. The latter property indicated holoenzyme was bound in a manner similar to the free catalytic subunit of cAMP-dependent protein kinase and suggested the enzyme was bound by association between the membrane and the catalytic subunit. Binding of cytosol protein kinase to the membranes rendered the enzyme insensitive to trypsin digestion and the capacity of the smooth muscle cell membranes to bind the soluble enzyme exceeded that of other rat tissue fractions. Resistance to salt extraction and proteolysis, as well as its detergent dependence, suggested the soluble enzyme became an integral or intrinsic membrane protein following association with the membrane. The ability of membranes to incorporate [γ-³²P]ATP into phosphoprotein was lost on detergent extraction of protein kinase and restored in an apparently specific manner when extracted and washed membranes were reconstituted with soluble enzyme. The intrinsic nature of membrane protein kinase and the apparent specificity with which the soluble enzyme was hound by membranes further indicated that, in myometrium. hormone-induced translocation of protein kinase is an important mechanism by which enzyme activity is increased in the vicinity of its in situ substrates.     

Reversibly soluble biocatalyst: optimization of trypsin coupling to Eudragit S-100 and biocatalyst activity in soluble and precipitated forms

Eudragit S-100, a copolymer of methacrylic acid and methyl methacrylate is soluble at pH above 5 and insoluble at pH below 4.5. pH-dependent solubility of the polymer is used for the development of reversibly soluble biocatalyst, which combines the advantages of both soluble and immobilized biocatalysts. Activity of trypsin, covalently coupled to Eudragit S-100, was improved by protecting the active site of the enzyme with benzamidine and removing the noncovalently bound proteins with Triton X-100 in 0.15 M Tris buffer (pH 7.6). Accurate choice of coupling conditions combined with proper washing protocol produced highly active enzyme-polymer conjugate with no noncovalently bound protein. Two conjugates with 100-fold difference in the content of trypsin coupled to Eudragit S-100 were studied when the preparations were in soluble and precipitated forms. The K(m)values of the soluble enzyme to the lower molecular weight substrate was less than that of the free enzyme, whereas that to the higher molecular weight substrate was closer to that of the free enzyme. Activities of the soluble and precipitated immobilized trypsin with higher molecular weight substrate were completely inhibited by soy bean trypsin inhibitor, whereas complete inhibition with soy bean trypsin inhibitor was never achieved with lower molecular weight substrate, indicating reduced access of high-molecular weight substrate/inhibitor to some of the catalytically active enzyme molecules in trypsin-Eudragit conjugate.     

Polyclonal antibodies mediated immobilization of a peroxidase from ammonium sulphate fractionated bitter gourd (Momordica charantia) proteins

Polyclonal antibody bound Sepharose 4B support has been exploited for the immobilization of bitter gourd peroxidase directly from ammonium sulphate precipitated proteins. Immunoaffinity immobilized bitter gourd peroxidase exhibited high yield of immobilization. IgG-Sepharose 4B bound bitter gourd peroxidase showed a higher stability against heat, chaotropic agents (urea and guanidinium chloride), detergents (cetyl trimethyl ammonium bromide and Surf Excel), proteolytic enzyme (trypsin) and water-miscible organic solvents (propanol, THF and dioxane). The activity of immobilized bitter gourd peroxidase was significantly enhanced in the presence of cetyl trimethyl ammonium bromide and after treatment with trypsin as compared to soluble enzyme.     

Isolation of a protease from sea urchin eggs before and after fertilization.

Upon fertilization, sea urchin eggs (Stronglyocentrotus pupuratus) release a protease into the surrounding sea water. This protease is in a particulate form which can be solubilized. The soluble form was purified by affinity chromatography on columns of immobilized soybean trypsin inhibitor. The purified enzyme is similar to bovine trypsin both in molecular weight (22500) and in susceptibility to inhibitors such as diisopropyl phosphofluoridate and soybean trypsin inhibitor. In contrast, extracts of unfertilized eggs appear to contain an inactive form of the enzyme which can be activated by dialysis at pH 4.6. The enzyme, as purified from extracts activated in this manner, was similar in its properties to that from fertilized eggs.     

Studies on the influence of Trasylol on the partition of trypsin between the human plasma protease inhibitors in vitro.

The distribution of trypsin between the protease inhibitors of human serum with and without Trasylol was studied in vitro. 1) Trypsin was preferentially bound by alpha2-macroglobulin on addition of small amounts of the enzyme to normal serum in both the presence and absence of Trasylol in a molar concentration equal to that of alpha2-macroglobulin. 2) On saturation of alpha2-macroglobulin, a considerable amount of trypsin was bound by Trasylol even when most of the serum alpha1-antitrypsin was in a free form. 3) In reaction mixtures containing small amounts of trypsin, Trasylol was identified in a free form as well as in complex with trypsin-alpha2-macroglobulin complex and to a limited extent with trypsin. 4) With larger amounts of trypsin, sufficient to saturate alpha2-macroglobulin, increasing amounts of Trasylol were bound to trypsin. The relative amount of Trasylol bound to trypsin-alpha2-macroglobulin complexes was now smaller. This was explained by a higher affinity (or binding rate) of Trasylol for trypsin than for trypsin-alpha2-macroglobulin complexes. 5) Trypsin-Trasylol complexes showed no signs of dissociation after 5 h incubation at 37 degrees C in serum.     

Solubilization of cheese whey protein by trypsin and a process to recover the active enzyme from the digest

Porcine trypsin (EC 3.4.4.4) converted, within approximately 2 hr at 50°C, its 1000-fold weight of water-insoluble, heat-denaturated cheese whey protein into a water-soluble product. In the course of this digestion, the enzyme increased the α-amino nitrogen of the protein by a factor of >20, from 0.40 to 9.40%. After digesting the water-insoluble whey protein, fully active trypsin could be recovered from the soluble digest with the aid of a cellulose-based affinity adsorbent. The enzyme which was eluted from a column of p-aminobenzamidine, bound to succinylated aminododecylcellulose, was fully active and showed essentially unchanged kinetic properties with a synthetic substrate, L -benzoyl-arginine p-nitroanilide. It was possible to perform, with the same amount of trypsin, three subsequent and equally effective solubilizations of whey protein, followed by a fourth digestion which still yielded a soluble product, but was considerably slower and incomplete. During each digestion, an estimated 30% of the trypsin was lost. The was not due to a decreased efficiency of the affinity adsorbent, as its trypsin-binding capacity was essentially unaffected after over 10 cycles of use.     

Digestive enzymes in midgut cells,endo-and ectoperitrophic contents,and peritrophic membranes of Spodoptera frugiperda (lepidoptera) larvae

In the midgut of Spodoptera frugiperda larvae, subcellular fractionation data suggest that aminopeptidase and part of amylase, carboxypeptidase A, dipeptidase, and trypsin are bound to the microvillar membranes; that major amounts of soluble dipeptidase, cellobiase, and maltase are trapped in the cell glycocalyx; and finally that soluble carboxypeptidase, amylase, and trypsin occur in intracellular vesicles. Most luminal acetylglucosaminidase is soluble and restricted to the ectoperitrophic contents. Aminopeptidase occurs in minor amounts bound to membranes both in the ectoperitrophic contents and incorporated in the peritrophic membrane. Amylase, carboxypeptidase A, and trypsin are found in minor amounts in the ectoperitrophic contents (both soluble and membrane-bound) and in major amounts in the peritrophic membrane with contents. Part of the activities recovered in the last mentioned contents corresponds to enzyme molecules incorporated in the peritrophic membrane. The results suggest that initial digestion is carried out in major amounts by enzymes in the endoperitrophic space and, in minor amounts, by enzymes immobilized in the peritrophic membrane. Intermediate and final digestion occur at the ectoperitrophic space or at the surface of midgut cells. The results also lend support to the hypothesis that amylase and trypsin are derived from membrane-bound forms, are released in soluble form by a microapocrine mechanism, and are partly incorporated into the peritrophic membrane. © 1994 Wiley-Liss, Inc.     

Partial characterization of the polyisoprenoid carrier of N-acetylglucosamine in Glycine max (soya bean).

Radiolabelled anhydrotrypsin was bound by alpha 2M (alpha 2-macroglobulin) sufficiently tightly to resist separation during gel electrophoresis; 2 mol of anhydrotrypsin were bound/mol of alpha 2M, but the interaction differed in important respects from that between active proteinases and alpha 2M. Anhydrotrypsin was bound by the electrophoretically 'fast' form of alpha 2M, although much less effectively than by the 'slow' form. The inactive enzyme was displaced from alpha 2M by trypsin inhibitor, the order of effectiveness being aprotinin > soya-bean trypsin inhibitor > benzamidine. Saturation of alpha 2M with anhydrotrypsin did not prevent subsequent binding and inhibition of active trypsin by the alpha 2M, and the anhydrotrypsin was not displaced during this reaction. Anhydrotrypsin bound by alpha 2M retained its ability to react with antibodies against trypsin, whereas bound trypsin did not.     

Effect of alpha2 macroglobulin on some kinetic parameters of trypsin.

1. Complex formation of trypsin with alpha2 macroglobulin results in marked changes of the Michaelis-Menten constant, pH optimum and sensitivity to ionic strength in a system using N-carbobenzoxy-glycylglycyl-L-arginine-2-naphthylamide as substrate. 2. In contrasts to the inhibition (50%) observed when alpha2 macroglobulin-bound trypsin is assayed under conditions optimal for the free enzyme, there is minimal reduction of activity when determinations are performed at a substrate concentration and pH optimal for the bound enzyme. 3. The changes in substrate concentration and ionic environment required for maximum activity of alpha2 macroglobulin-bound trypsin are similar to those observed with enzymes embedded in polyelectrolyte matrices and may reflect alterations in the microenvironment of the enzyme resulting from conformational changes of the macromolecule during interaction with trypsin. 4. Enzymatic activity of trypsin towards casein is greatly reduced by alpha2 macroglobulin, even under assay conditions optimal for the bound enzyme, confirming previous findings that access to the active center for high-molecular weight substrates is sterically hindered by alpha2 macroglobulin.     

Characterization of 2'':3''-Cyclic Nucleotide 3''-Phosphodiesterase: Rapid Isolation, Native Enzyme Analysis, Identification of a Serum-Soluble Activity, and Kinetics

The enzyme 2':3'-cyclic nucleotide 3'-phosphodiesterase (CNPase) was isolated from bovine brain white matter by a rapid (72 h) procedure. The minimum molecular weight (MW) of the enzyme was approximately 52,500 as estimated by sucrose density gradient analysis. When this isolated enzyme was stimulated with bovine serum albumin (BSA), the peak of activity was shifted to approximately 90,000 MW. Prior treatment by trypsin blocked the expression of the higher MW form of CNPase, but not the BSA activation of the enzyme. If the trypsin digestion was allowed to progress, the MW was gradually lowered to a broad peak sedimenting between 20,000 and 50,000 MW. An apparently soluble form of CNPase found in serum is described. Kinetic and MW comparisons between the serum soluble enzyme and CNPase isolated from bovine brain, as well as an analysis of substrate specificity, were made and it was concluded that the two enzymes were identical.     

Kinetic studies on soluble and insoluble urokinases.

A water-insoluble urokinase (ins-UK) was prepared by covalent coupling to an electrostatically neutral polyacrylamide derivative. The esteratic activity retained by the bound enzyme is about 70 percent of that of the soluble urokinase (UK). Comparative kinetic studies of these two forms of the enzyme were undertaken on lysine esters: N-alpha-acetyl-L-lysine-methyl ester (ALEe) and N-alpha acetylglycyl-L-lysine methyl ester (AGLMe). It was first observed that these substrates both exhibit a marked inhibitory effect toward soluble UK, whereas this phenomenon was less manifest with the insoluble form of the enzyme. Michaelis constants and maximal velocities measured at 33 degrees C, for UK and ins-UK, were identical when ALMe was used, but slightly different with AGLMe. Determination of initial velocities, at a series of pH values shows only minimal differences in the behavior of the soluble enzyme with respect to that of the insoluble form. However, over a range of temperatures, differing Km values for these two enzyme forms were obtained using AGLMe as the substrate. These last results suggest possible interactions between the substrate and the insoluble carrier of the enzyme.     

Porphyrin biosynthesis: immobilized enzymes and ligands. VI. Studies on succinyl CoA synthetase from cultured soya bean cells

Soybean callus succinyl CoA synthetase (succinate: CoA ligase, (ADP-forming), EC 6.2.1.5), has been chemically bound to Sepharose 4B and some of its properties have been studied. The optimal conditions for binding have been determined. The immobilized enzyme retained 48% of the activity of the soluble enzyme and the coupling yield amounted to 50%. Sepharose-succinyl CoA synthetase can be stored at 4 degrees C for periods up to 90 days with only 25% loss of activity; it can also be repeatedly used without alteration of its enzymic activity. The complex showed enhanced thermal stability; pH optimum was between 7.0 and 8.0 for the bound enzyme, and 8.0 for the free enzyme. A general decrease in the Michaelis-Menten constants for the different substrates of the insoluble enzyme, as compared with values obtained for the free enzyme, was found. Plots of the rate product formation against ATP concentration changed from sigmoideal for the soluble succinyl CoA synthetase to hyperbolic for the immobilized enzyme.     

Choline acetyltransferase binding to and release from membranes

1. The binding of non-occluded choline acetyltransferase to synaptosome membranes is a reversible process that is primarily dependent on the pH and ionic strength of the suspending medium. 2. The distribution of soluble enzyme bound to synaptosome membranes was studied by density-gradient centrifuging. 3. Choline acetyltransferase shows enzyme activity both in the free and in the membrane-bound form. 4. Varying the temperature or prolonged hypo-osmotic treatment does not release the membrane-bound enzyme. 5. The release of choline acetyltransferase from membranes by different anions, thiols, adenosine nucleotides and enzyme substrates was studied.     

Globulin-specific Proteolytic Activity in Germinating Pumpkin Seeds as Detected by a Fluorescence Assay Method

The proteolytic activities of α-chymotrypsin, trypsin, pepsin, bromelain, and an extract from germinating pumpkin seeds (Cucurbita moschata) were determined by their ability to effect the release of 1-anilino-8-naphthalenesulfonate bound to internal hydrophobic sites in intact protein substrates. Casein, glyceraldehyde-3-P dehydrogenase, urease, catalase, pumpkin seed globulin, and bovine serum albumin enhanced the fluorescence of 1-anilino-8-naphthalenesulfonate sufficiently to be used as proteolytic substrates. Chymotrypsin, trypsin, pepsin, and bromelain exhibited activity against all or almost all of the protein substrates. The activity of 1 μg of α-chymotrypsin or trypsin and 100 ng of pepsin could be easily detected by this method of assay within 4 to 5 minutes depending upon the substrate. The enzyme extracted from 3-day germinated pumpkin seeds exhibited strong activity only against pumpkin seed globulin, weak activity against the globulins of squash and cucumber and casein, and no activity against the other protein substrates. Activity against pumpkin globulin was maximal at pH 7.4. When assayed by an increase in ninhydrin-positive products, the enzyme extract from pumpkin seeds also showed strong activity against pumpkin globulin and weak activity against casein. The 1-anilino-8-naphthalenesulfonate-fluorescence method was at least 20 times more sensitive than the ninhydrin method and was 10 to 20 times more rapid.     

Kinetic properties of membrane dopamine-beta-hydroxylase.

We studied membrane bound dopamine-beta-hydroxylase (DBH) from chromaffin granules, in order to determine whether a biological form of immobilization of the enzyme altered its kinetic properties. The results obtained suggested that DBH either in soluble or solubilized form showed a ping-pong mechanism whereas the membrane bound DBH did not. Affinity for the substrate and the pH stability were lower in soluble or solubilized form than in membrane bound DBH.     

Adenosine 3'5'-monophosphate phosphodiesterase of buffalo spermatozoa.

The cyclic AMP-phosphodiesterase (EC 3.1.4.17) of buffalo spermatozoa is distributed in the head, mid-piece and tail fractions and has multiple forms, 70% of which is in the bound form. The bound enzyme was not solubilized by Triton X-100, lubrol or hyamine 2389. Kinetic measurements of the soluble enzyme showed two apparent Km values for low and high cAMP concentrations, i.e. 4.5 and 100 micro M with Vmax values of 0.25 and 2.0 nmol cAMP hydrolysed min-1 mg protein-1. The bound enzyme had an apparent Km of 66.6 microM with a Vmax of 0.75 nmol cAMP hydrolysed min-1 mg protein-1. The pH for optimum enzyme activity was 7.5 and Mg2+ was essential for the activity of the soluble and bound enzymes. Methylxanthines, ATP, ADP and ppi inhibited the soluble and bound enzymes, ATP being the most potent inhibitor.