Modulation of the biologic activities of IgE binding factor. VI. The activation of phospholipase by glycosylation enhancing factor

Glycosylation enhancing factor (GEF) from rat T cells is a kallikrein-like enzyme and enhances the assembly of N-linked oligosaccharides to IgE binding factors during their biosynthesis, whereas another T cell factor, i.e., glycosylation inhibiting factor (GIF), is a fragment of phosphorylated lipomodulin (i.e., phospholipase inhibitor), which when dephosphorylated inhibits phospholipase and the glycosylation process. The two T cell factors compete with each other when they are added to normal mesenteric lymph node cells during the formation of IgE binding factors. The addition of GEF to T cell hybridoma 23A4 cell switches the cells from the formation of unglycosylated IgE binding factor to the formation of N-glycosylated IgE binding factor. However, GEF neither inactivated GIF nor inhibited the formation of GIF by the T cell hybridoma. Stimulation of the T cell hybridoma with either affinity-purified GEF or bradykinin resulted in the release of GIF from the cells. GIF released by GEF stimulation had a m.w. of approximately 15,000 and bound to monoclonal antibody against lipomodulin. GEF and bradykinin also induced normal mesenteric lymph node cells to release GIF. Incorporation of 14C-arachidonic acid into 23A4 cells, followed by stimulation of the cells with GEF, resulted in the release of 14C-arachidonate. The results suggest that lipomodulin, a phospholipase inhibitory protein, is present in lymphocytes, and indicate that GEF and bradykinin induce the activation of phospholipase by stimulating cells to release lipomodulin.     

Modulation of the biologic activities of IgE-binding factor. II. Physicochemical properties and cell sources of glycosylation-enhancing factor

T lymphocytes of rats treated with Bordetella pertussis vaccine (BP) formed a soluble factor that enhanced the glycosylation of IgE-binding factors during their biosynthesis, and provided the latter factors with the biologic activity to potentiate the IgE response. The present experiments demonstrated that pertussigen (leukocytosis-promoting factor) from BP induced normal rat spleen cells to form the glycosylation-enhancing factor. The same factor was obtained by incubation of normal spleen cells with 5 micrograms/ml, but not 2 micrograms/ml, concanavalin A. When normal rat mesenteric lymph node cells were incubated with the glycosylation-enhancing factor together with IgE, IgE-binding factors formed by the cells selectively potentiated the IgE response. The IgE-binding factors formed by the same cells upon incubation with IgE alone neither enhanced nor suppressed the IgE response. The glycosylation-enhancing factor changed the nature of IgE-binding factors formed by the rat-mouse T cell hybridoma, 23A4. IgE-binding factors induced by IgE alone lacked affinity for lentil lectin, whereas those induced by IgE in the presence of the glycosylation-enhancing factor had affinity for the lectin. The cell source of the glycosylation-enhancing factor appeared to be W 3/25+ Fc gamma R+ T cells. The glycosylation-enhancing factor was protein in nature and had a m.w. of about 25,000. The factor had affinity for acid-treated Sepharose and could be recovered from the beads by elution with lactose. The factor was different from interleukin 2 with respect to both its affinity for galactose and its isoelectric point.     

Purification of rat urinary kallikrein: comparative studies with rat submandibular gland kallikrein-like serine protease.

A 427-fold purification of rat urinary kallikrein (RUK) was achieved in three steps involving chromatography on columns of DEAE-Sepharose CL-6B, gel filtration on Sephadex G-100 and affinity chromatography on a column of benzamidine-Sepharose. Purified enzyme showed a single band on SDS-PAGE with an estimated molecular weight of 43,000. The amino-terminal sequences of the first 25 residues of RUK resemble the reported sequence for true kallikrein and share 80% identity with rat submandibular gland (RSMG) kallikrein-like serine protease. The RUK is highly reactive towards kallikrein substrates Bz-pro-phe-arg-pNA and DL-val-leu-arg-pNA, and plasmin substrate D-val-leu-lys-pNA. RSMG enzyme is more reactive towards Bz-val-gly-arg-pNA and tosyl-gly-pro-arg-pNA, preferential chromogenic substrates for trypsin-like proteases and thrombin, respectively. Both leupeptin and aprotinin inhibit RUK strongly, but soy bean trypsin inhibitor has no effect on this enzyme. RSMG enzyme is poorly inhibited by any of these inhibitors. The data suggest that although both enzymes are members of tissue kallikrein multigene family, urinary enzyme is a true kallikrein and RSMG enzyme is a kallikrein-like serine protease with different substrate specificity.     

Release of histamine and arachidonate from mouse mast cells induced by glycosylation-enhancing factor and bradykinin

Stimulation of normal rat splenic T cells with pertussigen (lymphocytosis-promoting factor from Bordetella pertussis) resulted in the release of a soluble factor that enhanced the assembly of N-linked oligosaccharides to IgE-binding factors during their biosynthesis. The glycosylation-enhancing factor (GEF) is a kallikrein-like enzyme and is purified by absorption to p-aminobenzamidine-Agarose followed by elution with benzamidine. Incubation of normal mouse mast cells with affinity-purified GEF or bradykinin, a product of cleavage of kininogen by kallikrein, resulted in the release of histamine and arachidonate from the cells. Passive sensitization of mast cells with mouse IgE antibody, followed by pretreatment of the cells with a suboptimal concentration of GEF, resulted in an enhancement of antigen-induced histamine release. It was found that GEF and bradykinin induced the same biochemical events in mast cells as those induced by bridging of IgE receptors. Both GEF and bradykinin induced phospholipid methylation and an increase in intracellular cyclic AMP (cAMP). Incorporation of 3H-methyl groups into phospholipids and intracellular cAMP levels both reached a maximum 30 sec after challenge with GEF or bradykinin, and then declined to base-line levels within 2 to 3 min. These biochemical events were followed by 45Ca influx and histamine release; 45Ca uptake reached a plateau value at 2 min, and histamine release reached a maximum at 5 to 8 min. The initial rise in cAMP induced by GEF (or bradykinin) was not inhibited by indomethacin, indicating that the activation of adenylate cyclase is not the result of prostaglandin synthesis. In both IgE-mediated and GEF-induced histamine release, inhibitors of methyltransferases, such as 3-deaza adenosine and L-homocysteine thiolactone, inhibited not only phospholipid methylation but also the cAMP rise and subsequent Ca2+ uptake and histamine release. The results indicate that GEF induces activation of methyltransferases and that phospholipid methylation is involved in the cAMP rise, Ca2+ uptake, and histamine release. The induction of the same biochemical events in the same sequence by bridging of IgE receptors and by GEF (bradykinin) supports the hypothesis that receptor bridging induces the activation of serine protease(s) and cleavage products of this enzyme in turn activate methyltransferases in mast cells.     

Relationship between T cell receptors and antigen-binding factors. I. Specificity of functional T cell receptors on mouse T cell hybridomas that produce antigen-binding T cell factors

Upon antigenic stimulation with OVA-pulsed syngeneic macrophages, the mouse T cell hybridoma 231F1 produced glycosylation inhibiting factor (GIF) having affinity for OVA and IgE-suppressive factors, whereas another T cell hybridoma, 12H5, cells produced OVA-binding glycosylation enhancing factor (GEF) and IgE-potentiating factor. The OVA-binding GIF from the 231F1 cells is an Ag-specific Ts cell factor, whereas OVA-binding GEF from the 12H5 cells is an Ag-specific augmenting factor. Both hybridomas express CD3 complex and functional TCR-alpha beta. Cross-linking of TCR-alpha beta or CD3 molecules on the hybridomas by anti-TCR-alpha beta mAb or anti-CD3 mAb and protein A resulted in the formation of the same factors as those obtained by the stimulation of the cells with OVA-pulsed syngeneic macrophages. It was also found that both the 231F1 cells and 12H5 cells formed IgE-binding factors upon incubation with H-2d and H-2b APC, respectively, with a synthetic peptide corresponding to residues 307-317 in the OVA molecules (P307-317). Six other synthetic peptides, including those containing the major immunogenic epitope, i.e., P323-339, failed to stimulate the hybridomas in the presence of APC. Indeed, all of the 10 T cell hybridoma clones, which could produce either OVA-binding GIF or OVA-binding GEF, responded to P307-317 and APC for the formation of IgE-binding factors. In contrast, GIF/GEF derived from six other hybridoma clones, whose TCR recognized P323-339 in the context of a MHC product, failed to bind to OVA-coupled Sepharose. The results indicate the correlation between the fine specificity of TCR and the affinity of GIF/GEF to the nominal Ag. The amino acid sequence of P307-317 suggested that TCR on the cell sources of Ag-binding factors are specific for an external structure of the Ag molecules.     

Purification of Rat Urinary Kallikrein: Comparative Studies with Rat Submandibular Gland Kallikrein-Like Serine Protease

Abstract

A 427-fold purification of rat urinary kallikrein (RUK) was achieved in three steps involving chromatography on columns of DEAE-Sepharose CL-6B, gel filtration on Sephadex G-100 and affinity chromatography on a column of benzamidine-Sepharose. Purified enzyme showed a single band on SDS-PAGE with an estimated molecular weight of 43,000. The amino-terminal sequences of the first 25 residues of RUK resemble the reported sequence for true kallikrein and share 80% identity with rat submandibular gland (RSMG) kallikrein-like serine protease. The RUK is highly reactive towards kallikrein substrates Bz-pro-phe-arg-pNA and DL-val-leu-arg-pNA, and plasmin substrate D-val-leu-lys-pNA. RSMG enzyme is more reactive towards Bz-val-gly-arg-pNA and tosyl-gly-pro-arg-pNA, preferential chromogenic substrates for trypsin-like proteases and thrombin, respectively. Both leupeptin and aprotinin inhibit RUK strongly, but soy bean trypsin inhibitor has no effect on this enzyme. RSMG enzyme is poorly inhibited by any of these inhibitors. The data suggest that although both enzymes are members of tissue kallikrein multigene family, urinary enzyme is a true kallikrein and RSMG enzyme is a kallikrein-like serine protease with different substrate specificity.     

Modulation of the biologic activities of IgE-binding factors. VII. Biochemical mechanisms by which glycosylation-enhancing factor activates phospholipase in lymphocytes

Cells of the T cell hybridoma 23A4 produce IgE-binding factors lacking N-linked oligosaccharides (unglycosylated form) when they are incubated with IgE alone. In the presence of glycosylation-enhancing factor (GEF) or bradykinin, however, the same cells produce IgE-binding factors with N-linked oligosaccharides (glycosylated form). Switching the cells from the formation of unglycosylated IgE-binding factors to the formation of glycosylated factors was accompanied by the release of both glycosylation-inhibiting factor (GIF) in its phosphorylated form, i.e., phosphorylated lipomodulin, and arachidonate from the cells. Analysis of the biochemical processes for the release of GIF from 23A4 cells showed that affinity-purified GEF or bradykinin induced transient phospholipid methylation and diacylglycerol (DAG) formation, and enhanced 45Ca uptake into the cells. Inhibitors of methyltransferases, i.e., 3-deaza-adenosine plus L-homocysteine thiolactone, inhibited not only phospholipid methylation but also DAG formation and GIF release. Exogenously added 1-oleoyl-2-acetyl glycerol, i.e., a DAG that is permeable to the plasma membrane, induced the release of GIF from the cells. It was also found that 12-O-tetradecanoyl-phorbol 13-acetate (TPA) switched 23A4 cells and normal lymphocytes to the selective formation of N-glycosylated IgE-binding factor, and induced the release of GIF from the cells. 32PO4-labeled lipomodulin was detected in the extract of 23A4 cells 3 to 5 min after the addition of GEF, bradykinin, or TPA. These results indicate that GEF and bradykinin induced the activation of methyltransferases and phospholipase C for the formation of DAG, which in turn activated Ca2+-activated, phospholipid-dependent protein kinase (protein kinase C) for the phosphorylation of lipomodulin. Because lipomodulin loses phospholipase inhibitory activity after phosphorylation, increased phospholipase A2 activity would be expressed by this process.     

Modulation of the biologic activities of IgE-binding factor. V. The role of glycosylation-enhancing factor and glycosylation-inhibiting factor in determining the nature of IgE-binding factors

Glycosylation-enhancing factor (GEF) and IgE-potentiating factor were detected in culture supernatants of rat mesenteric lymph nodes (MLN) cells obtained 14 days after infection with Nippostrongylus brasiliensis (Nb), but not in supernatants of MLN cells of 8-day Nb-infected rats. Both factors were also released from T cells upon antigenic stimulation of KLH + alum-primed spleen cells. The GEF from the Nb-infected rats and KLH + alum-primed spleen cells had affinity for p-aminobenzamidine agarose and were inactivated by phenylmethylsulfonylfluoride, an inhibitor of serine proteases. These results indicate that the GEF obtained in the two systems is a serine protease and is identical to that obtained by stimulation of normal T cells with lymphocytosis-promoting factor (LPF) from Bordetella pertussis. The concomitant formation of IgE-potentiating factor and GEF by Nb infection, by antigenic simulation of KLH + alum-primed spleen cells, and by treatment of rats with Bordetella pertussis vaccine suggests that the serine protease is involved in a common pathway leading to the selective formation of IgE-potentiating factor. In contrast, glycosylation-inhibiting factor (GIF) is always found during the selective formation of IgE-suppressive factor. IgE-suppressive factor and GIF were formed by MLN cells of 8-day Nb-infected rats and KLH-CFA-primed spleen cells. GIF was detected in culture supernatants of T cell hybridomas 23A4 and 23B6, which form unglycosylated IgE-binding factors upon incubation with IgE. GIF obtained from all of these sources bound to monoclonal anti-lipomodulin. These findings indicate that GIF or lipomodulin is involved in all systems, which leads to the selective formation of IgE-suppressive factor. However, the formation of GIF was not restricted to those conditions in which IgE-suppressive factor was selectively formed. The culture supernatants of MLN cells of 14-day Nb-infected rats and antigen-stimulated KLH + alum-primed spleen cells contained a small amount of GIF, which could be detected after inactivation of GEF. It appears that T cells from these sources formed GEF and GIF, but that GEF overcame the effect of GIF on glycosylation of IgE-binding factors. The results indicate that the nature and biologic activities of IgE-binding factors are decided by the balance between GEF and GIF formed by T cells.     

Presence of an antigen-specific T cell subset that forms IgE-suppressive factor and IgG-suppressive factor on antigenic stimulation

B6D2F1 mice were given three i.v. injections of ovalbumin (OA), and antigen-specific T cell clones were established from their spleen cells. One of the FcR+ T cell clones formed IgE-binding factors on incubation with OA-pulsed syngeneic macrophages. Neither soluble antigen nor macrophages alone induced factor formation. T cell hybridomas were constructed by fusion of the antigen-specific T cell clone with BW 5147 cells. Among 11 T cell hybridomas established, six clones produced IgE-binding factors on incubation with OA-pulsed BDF1 macrophages. Mouse IgE also induced the same hybridoma to form IgE-binding factors. The majority of IgE-binding factors formed by two T hybridomas and by those produced by the parent T cell clone had affinity for peanut agglutinin but for neither lentil lectin nor Con A. These hybridomas and the original T cell clone spontaneously released glycosylation-inhibiting factor, which inhibits the assembly of N-linked oligosaccharide(s) on IgE-binding factors. On antigenic stimulation, the T cell hybridomas produced both IgE-binding factors and IgG-binding factors. The IgE-binding factors consisted of three species with m.w. of 60,000, 30,000, and 15,000. Both the 60K and 15K IgE-binding factors selectively suppressed the IgE response of DNP-OA-primed rat mesenteric lymph node cells, whereas IgG-binding factors selectively suppressed the IgG response. The results indicate that antigen-primed FcR+ T cells produced IgE-suppressive factors and IgG-suppressive factors on antigenic stimulation. However, the T cell hybridomas were not committed to suppressive activity. When the hybridomas were stimulated by antigen in the presence of glycosylation-enhancing factor (GEF), the 60K, 30K, and 15K IgE-binding factors formed by the cells selectively potentiated the IgE response. IgG-binding factors formed by the cells in the presence of GEF failed to suppress the IgG response. It appears that antigen-specific FcR+ T cells regulate the antibody response through the formation of Ig-binding factors, but that the function of the cells could be switched from suppression to enhancement, depending on the environment of the cells.     

Antigen-specific T cells that form IgE-potentiating factor, IgG-potentiating factor, and antigen-specific glycosylation-enhancing factor on antigenic stimulation

BDF1 mice were immunized with alum-absorbed OVA and T cell hybridomas were constructed from their splenic T cells. Many of the hybridomas constitutively produced glycosylation enhancing factor (GEF), which could switch the T cell hybridoma 23A4 cells from the formation of IgE-suppressive factors to the formation of IgE-potentiating factors. When one of the hybridoma clones, 12H5, was incubated with OVA-pulsed syngeneic or semi-syngeneic (H-2b) macrophages, the hybridoma produced GEF that have affinity for OVA, but not for either keyhole limpet hemocyanin or BSA. However, the same hybridoma constitutively produced nonspecific GEF, that lacked affinity for OVA. Upon incubation with OVA-pulsed macrophages, the same hybridoma produced both IgE-potentiating factors and IgG-potentiating factors which selectively enhance the IgE response and IgG response, respectively. Both Ag-specific GEF and nonspecific GEF from the hybridoma bind to p-aminobenzamidine-agarose, and are recovered by elution with benzamidine. It was also found that both OVA-specific GEF and nonspecific GEF from the hybridoma induced the release of arachidonic acid from phospholipids of mouse fibrosarcoma cell line, HSDM1C1 cells. GEF formed by the 12H5 hybridoma bound to alloantibodies reactive to the product(s) of the I-Ab subregion of major histocompatibility complex. The Ag-specific GEF consisted of two Mr species, of 70 to 90 kDa and 50 to 60 kDa, whereas nonspecific GEF consisted of 50 to 60 kDa and 25 to 30 kDa molecules. Reduction and alkylation treatment of the OVA-specific GEF resulted in the formation of nonspecific GEF, suggesting that Ag-specific GEF is composed of Ag-binding polypeptide chain and nonspecific GEF.     

Studies on the effect of serine protease inhibitors on activated contact factors. Application in amidolytic assays for factor XIIa, plasma kallikrein and factor XIa

Amidolytic assays have been developed to determine factor XIIa, factor XIa and plasma kallikrein in mixtures containing variable amounts of each enzyme. The commercially available chromogenic p-nitroanilide substrates Pro-Phe-Arg-NH-Np (S2302 or chromozym PK), Glp-Pro-Arg-NH-Np (S2366), Ile-Glu-(piperidyl)-Gly-Arg-NH-Np (S2337), and Ile-Glu-Gly-Arg-NH-Np (S2222) were tested for their suitability as substrates in these assays. The kinetic parameters for the conversion of S2302, S2222, S2337 and S2366 by beta factor XIIa, factor XIa and plasma kallikrein indicate that each active enzyme exhibits considerable activity towards a number of these substrates. This precludes direct quantification of the individual enzymes when large amounts of other activated contact factors are present. Several serine protease inhibitors have been tested for their ability to inhibit those contact factors selectively that may interfere with the factor tested for. Soybean trypsin inhibitor very efficiently inhibited kallikrein, inhibited factor XIa at moderate concentrations, but did not affect the amidolytic activity of factor XIIa. Therefore, this inhibitor can be used to abolish a kallikrein and factor XIa contribution in a factor XIIa assay. We also report the rate constants of inhibition of contact activation factors by three different chloromethyl ketones. D-Phe-Pro-Arg-CH2Cl was moderately active against contact factors (k = 2.2 X 10(3) M-1 s-1 at pH 8.3) but showed no differences in specifity. D-Phe-Phe-Arg-CH2Cl was a very efficient inhibitor of plasma kallikrein (k = 1.2 X 10(5) M-1 s-1 at pH 8.3) whereas it slowly inhibited factor XIIa (k = 1.4 X 10(3) M-1 s-1) and factor XIa (k = 0.11 X 10(3) M-1 s-1). Also Dns-Glu-Gly-Arg-CH2Cl was more reactive towards kallikrein (k = 1.6 X 10(4) M-1 s-1) than towards factor XIIa (k = 4.6 X 10(2) M-1 s-1) and factor XIa (k = 0.6 X 10(2) M-1 s-1). Since Phe-Phe-Arg-CH2Cl is highly specific for plasma kallikrein it can be used in a factor XIa assay selectively to inhibit kallikrein. Based on the catalytic efficiencies of chromogenic substrate conversion and the inhibition characteristics of serine protease inhibitors and chloromethyl ketones we were able to develop quantitative assays for factor XIIa, factor XIa and kallikrein in mixtures of contact activation factors.     

Trypsin-like Hatching Enzyme of Mouse Blastocysts: Evidence for Its Participation in Hatching Process before Zona Shedding of Embryos6

Effects of twelve protease inhibitors on hatching of mouse embryos were investigated. Mouse hatching was strongly or moderately inhibited by trypsin inhibitors including p-toluenesulfonyl-Lys-CH₂Cl (TLCK) and chicken ovomucoid, while inhibitors for chymotrypsin and elastase showed weak or no inhibition. These results indicate the participation of a trypsin-like protease in the hatching of mouse embryos as a hatching enzyme., Since TLCK is the strongest and an irreversible inhibitor for the enzyme, timing of the participation of the hatching enzyme in the hatching process was examined by pulse treatment of embryos with TLCK before and during the zona shedding. The results indicated that a trypsin-like hatching enzyme functions before, but not during, the zona shedding of embryos, especially during a 15 h period immediately before the beginning of the shedding.     

Bauhinia proteinase inhibitor-based synthetic fluorogenic substrates for enzymes isolated from insect midgut and caterpillar bristles

Bauhinia ungulata factor Xa inhibitor (BuXI) inactivates factor Xa and LOPAP, a prothrombin activator proteinase isolated from the venom of Lonomia obliqua caterpillar bristles. The reactive site of the enzyme-inhibitor interaction was explored to design specific substrates for both enzymes. Methionine is crucial for LOPAP and factor Xa substrate interaction, since the change of both Met residues in the substrates abolished the hydrolysis. Synthetic substrates containing the sequence around the reactive site of BbKI, a plasma kallikrein inhibitor, were shown to be specific for trypsin hydrolysis. Therefore, these substrates may be an alternative in studies aiming at a characterization of trypsin-like enzyme activities, especially non-mammalian enzymes.     

Crystal structure of recombinant human tissue kallikrein at 2.0 A resolution.

Human tissue kallikrein, a trypsin-like serine protease involved in blood pressure regulation and inflammation processes, was expressed in a deglycosylated form at high levels in Pichia pastoris, purified, and crystallized. The crystal structure at 2.0 A resolution is described and compared with that of porcine kallikrein and of other trypsin-like proteases. The active and S1 sites (nomenclature of Schechter I, Berger A, 1967, Biochem Biophys Res Commun 27:157-162) are similar to those of porcine kallikrein. Compared to trypsin, the S1 site is enlarged owing to the insertion of an additional residue, cis-Pro 219. The replacement Tyr 228 --> Ala further enlarges the S1 pocket. However, the replacement of Gly 226 in trypsin with Ser in human tissue kallikrein restricts accessibility of substrates and inhibitors to Asp 189 at the base of the S1 pocket; there is a hydrogen bond between O delta1Asp189 and O gammaSer226. These changes in the architecture of the S1 site perturb the binding of inhibitors or substrates from the modes determined or inferred for trypsin. The crystal structure gives insight into the structural differences responsible for changes in specificity in human tissue kallikrein compared with other trypsin-like proteases, and into the structural basis for the unusual specificity of human tissue kallikrein in cleaving both an Arg-Ser and a Met-Lys peptide bond in its natural protein substrate, kininogen. A Zn+2-dependent, small-molecule competitive inhibitor of kallikrein (Ki = 3.3 microM) has been identified and the bound structure modeled to guide drug design.     

Thiobenzyl benzyloxycarbonyl-L-lysinate, substrate for a sensitive colorimetric assay for trypsin-like enzymes.

Thiobenzyl benzyloxycarbonyl-l-lysinate (Z-Lys-SBzl), a substrate for trypsin-likeproteases, was synthesized. In the presence of 5,5′-dithiobis(2-nitrobenzoic acid) the hydrolysis of the thiol ester by trypsin-like enzymes provides a continuous colorimetric assay with a sensitivity comparable to the best fluorometric substrates. Z-Lys-SBzl is readily synthesized in good yield, is water soluble, and has a low rate of spontaneous hydrolysis even at pH 8.0. This assay procedure has been routinely used with urokinase, human urinary and human plasma kallikrein, thrombin, plasmin, β-trypsin, factor Xa, and crotalase. Levels of detection of these enzymes are in the range 10^?14 to 10^?13 mol.     

The possible involvement of trypsin-like enzymes in germination of spores of Bacillus cereus T and Bacillus subtilis 168.

Germination of spores of Bacillus cereus T and Bacillus subtilis 168 was inhibited by the trypsin inhibitors leupeptin and tosyllysine chloromethyl ketone (TLCK) and by the substrates tosylarginine methyl ester (TAME), benzoyl-L-arginine-p-nitroanilide (L-BAPNA) and D-BAPNA. Potencies of these inhibitory compounds were estimated by finding the concentration which inhibited 50% germination (ID50), as measured by events occurring early (loss of heat resistance), at an intermediate stage [dipicolinic acid (DPA) release], and late in germination (decrease in optical density). In B. cereus T, all the compounds inhibited early and late events with the same ID50. In B. subtilis, TAME inhibited early and late events at the same ID50, but all other inhibitors had a lower ID50 for late events than for early events. This suggests that a trypsin-like enzyme activity is involved at two sequential stages in the germination of B. subtilis spores, one occurring at or before the loss of heat resistance and one at or before the decrease in optical density. Different trypsin-like activities were detected in broken dormant spores and germinated spores of B. cereus T and in germinated spores of B. subtilis by means of three chromogenic substrates: benzoyl-L-phenylalanyl-L-valyl-L-arginine-p-nitroanilide (L-PheVA), L-BAPNA and D-BAPNA. Separation of extracts of germinated spores on non-denaturing polyacrylamide gels showed that in both species the substrates were hydrolysed by three distinct enzymes with different electrophoretic mobilities. The three enzymes had different Ki values for the above inhibitors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proteinase inhibitory spectrum of mouse murinoglobulin and alpha-macroglobulin

The interactions of mouse murinoglobulin and alpha-macroglobulin with several proteinases were investigated by filtration and by assays of amidolytic activity towards synthetic substrates in the presence of proteinaceous enzyme inhibitors as well as assays of the inhibition of proteolytic activity. Mouse alpha-macroglobulin formed complexes with thrombin, clotting factor Xa, plasmin, pancreatic kallikrein, plasma kallikrein, submaxillary gland trypsin-like proteinase, neutrophil elastase, and pancreatic elastase. These complexes lost the proteolytic activities against high-molecular-weight substrates, but protected the active sites of the enzymes from inactivation by their proteinaceous inhibitors. Mouse murinoglobulin showed essentially the same properties except (i) that it did not form a complex with the clotting factor Xa, and (ii) that it did not protect plasma kallikrein, neutrophil elastase or submaxillary proteinase from inactivation by their proteinaceous inhibitors, although it formed complexes with these proteinases. No interaction was detected between Clostridium histolyticum collagenase and murinoglobulin or alpha-macroglobulin. These results indicate (i) that murinoglobulin has a proteinase-binding spectrum similar to that of alpha-macroglobulin, but is weaker in the ability to protect the bound proteinases from inactivation by the proteinaceous inhibitors than alpha-macroglobulin and (ii) that mouse alpha-macroglobulin has essentially the same inhibitory spectrum as the human homologue.     

TMOF-like factor controls the biosynthesis of serine proteases in the larval gut of Heliothis virescens.

Proteolytic enzyme biosynthesis in the midgut of the 4th instar larva of Heliothis virescens is cyclical. Protease activity increases immediately after the molt from the 3rd to the 4th instar larvae and declines just before the molt into the 5th instar. Characterization of the midgut proteases using soybean tryspin inhibitor (SBTI) Bowman Birk Inhibitor (BBI) 4-(2-aminoethyl)benzensulfonylfluoride (AEBSF) and N-tosyl-L-phenylalanine chloromethylketone (TPCK) indicate that protease activity is mostly trypsinlike (80%) with a small amount of chymotrypsinlike activity (20%). Injections of late 3rd and 4th instar larval hemolymph into H. virescens larvae inhibited tryspin biosynthesis in the larval midgut. Similar results were obtained when highly purified 4th instar larval hemolymph that crossreacted with Aea-TMOF antisurm using ELISA was injected into 2nd instar larvae. Injections of Aea-TMOF and its analogues into 2nd instar, and Aea-TMOF alone into 4th instar larvae stopped trypsin biosynthesis 24 and 48 h after the injections, respectively. Injections of 4th instar H. virescens larval hemolymph into female Aedes aegypti that took a blood meal stopped trypsin biosynthesis and egg development. These results show that the biosynthesis of trypsin-like enzymes in the midgut of a lepidoptera is modulated with a hemolymph circulating TMOF-like factor that is closely related to Aea-TMOF. Arch.     

Collagenolytic serine proteinase from Euphausia superba Dana (Antarctic krill).

1. A serine proteinase isolated from E. superba shows collagenolytic properties: it acts on collagens from Achilles tendon (type I and V) and reconstituted fibrils of calf skin collagen under conditions that do not denature the substrates. 2. At 25 degrees C and pH 7.5 the enzyme both splits the calf skin collagen in solution to the fragments TCA and TCB and catalyses the conversion of dimeric molecules to monomeric chains. 3. The enzyme exhibits strong chymotrypsin-like and lower trypsin-like activities. 4. All the enzyme activities are inhibited to the same degree by diisopropylfluorophosphate (DFP), phenylmethylsulphonyl fluoride (PMSF), N alpha-tosyl-L-lysine chloromethyl ketone (TLCK), soybean trypsin inhibitor (SBTI), chicken ovomucoid (CHOM), chymostatin and leupeptin. None of the activities is inhibited by chelating agents and L-cysteine. 5. pH-Optima of the proteinase in protein substrates hydrolysis (6.0-6.2) are lower than those of synthetic substrates cleavage (7.8-8.0 in the case of BzTyrOEt and 8.7-8.9 for BzArgOEt). 6. Four from nine cysteine residues present in the enzyme molecule possess free thiol-groups. Since the enzyme is inhibited by p-chloromercuribenzoate (pCMB), N-ethylmaleimide (NEM) and iodoacetic acid (IAA), the role of its thiol-groups has been discussed.