Identification and characterization of trypsin, chymotrypsin and elastase inhibitors in porcine serum.

Characterization of the trypsin-, chymotrypsin- and elastase-inhibiting properties of porcine serum was carried out by gel filtration on Ultrogel, AcA 44, and agarose gel electrophoresis with subsequent processing for protease-inhibiting activity. Moreover, by allowing the fractions obtained from gel filtration to react with antibodies to porcine serum protease inhibitors, the specific inhibiting properties of these inhibitor molecules were identified. At least six protease inhibitors were identified and partially characterized in porcine serum. Two alpha 2 -macroglobulins (alpha 2 Mf and alpha 2 Ms), homologues to human alpha 2 -macroglobulin, with slightly different electrophoretic mobilities, were both found to exhibit trypsin, chymotrypsin and elastase inhibiting activity. Alpha 1 -Protease inhibitor (Mr 51 000), a homologue to human alpha 1 -protease inhibitor (alpha 1 -antitrypsin), also showed trypsin-, chymotrypsin- and elastase-inhibiting properties. Inter-alpha-trypsin inhibitor (Mr 162 000 and 129000), a porcine serum counterpart to human inter-alpha-trypsin inhibitor, showed trypsin- and chymo-trypsin-inhibiting properties. In addition, a specific trypsin inhibitor, alpha 2 -antigrypsin (Mr 58 000), and a specific elastase inhibitor, beta-elastase inhibitor, were characterized in porcine serum, and these seem to have no counterparts in human serum.     

Identification and characterization of trypsin, chymotrypsin and elastase inhibitors in the hedgehog, Erinaceus europaeus, and their immunological relationships to those of other mammals (rat, pig and human)

1. Hedgehog plasma was separated by gel filtration on Sephacryl S-200, the fractions resolved by electrophoresis and the electrophoregrams characterized for trypsin, chymotrypsin and elastase inhibiting activities with both low and high molecular weight substrates. Approximate molecular weights were also determined. 2. At least ten protease inhibitors were characterized in hedgehog plasma including three macroglobulins. 3. The hedgehog protease inhibitors were identified by immunoelectrophoresis. Four protease inhibitors showed homologies with specific human, rat or swine antisera. These were alpha 2-and beta-macroglobulins, alpha 1-protease inhibitor, and alpha 2-antithrombin.     

Interactions in vitro and in vivo between rat serum protease inhibitors and anodal and cathodal rat trypsin and chymotrypsin.

Reaction mixtures of increasing amounts of the pancreatic homologous proteases, anodal and cathodal chymotrypsin and trypsin, respectively, and normal rat serum were analyzed by immunoelectrophoretic methods in order to determine their distribution on serum protease inhibitors. This paper concerns three proteins occurring in normal serum and capable of binding protease viz. alpha1-macroglobulin, alpha1-antitrypsin and alpha1-inhibitor 3. The distribution of the enzymes among these protease inhibitors differed significantly from one protease to another. The distribution of the proteases among the serum protease inhibitors following intravenous injection of 125I-labelled proteases corresponded to that in vitro. Complexes formed with alpha1-macroglobulin and alpha1-inhibitor 3 were quickly eliminated irrespective of the enzyme species used, whereas those formed with alpha1-antitrypsin persisted much longer in the circulation.     

Affinity chromatography of alpha-1-protease inhibitor using Sepharose-4B-bound anhydrochymotrypsin

Sepharose 4B-bound bovine anhydrochymotrypsin (AnhCT), a catalytically inactive form of chymotrypsin, was shown to be effective for retaining active alpha-1-protease inhibitor (alpha-1-PI, also alpha-1-antitrypsin) from human plasma, while showing no measurable affinity for oxidized or protease complexed alpha-1-PI, or for most other plasma proteins. alpha-1-PI eluted from this resin with 0.1 M chymostatin retained full activity against trypsin, chymotrypsin, and elastase. In addition to alpha-1-PI, AnhCT-Sepharose binds a limited number of other plasma proteins. Using monospecific antisera to plasma protease inhibitors, one of these proteins was identified as inter-alpha-trypsin inhibitor, and it was recoverable in active form. Therefore, an AnhCT-Sepharose 4B resin has been demonstrated to be of value for isolating active forms of alpha-1-PI from solutions, and may also be useful for the isolation of inter-alpha-trypsin inhibitor.     

Evaluation of assays for detecting alpha-1-protease inhibitor during purification from rat serum

We purified the R1 alpha-1-protease inhibitor from rat serum and developed a convenient assay for its detection during purification procedures. Purification was accomplished by desalting, DEAE-Sephacel, zinc chelate, and reactive green-agarose columns. The resultant antiprotease had a molecular weight of 54,000 and inhibited elastase, chymotrypsin, and trypsin. By isoelectric focusing, five bands were produced with pI values from 4.3 to 4.7. Functional assays utilizing protease substrates imbedded in agarose plates were evaluated for the ability to distinguish the R1 alpha-1-protease inhibitor from the other serum antiproteases eluted in column chromatography fractions. This technique of screening for anti-protease activity was compared to conventional spectrophotometric methods and was found to correlate well when quantifying inhibition of elastase and chymotrypsin, but not trypsin. The presence of alpha-1-protease inhibitor was most reliably detected by testing for anti-elastase activity. Technician time and expense were saved by employing protease substrate plates to test chromatogrpahy fractions. This technique may facilitate purification of other protease inhibitors.     

Inhibitory spectrum of mouse contrapsin and alpha-1-antitrypsin against mouse serine proteases

Contrapsin and alpha-1-antitrypsin have been recently characterized as major protease inhibitors in mouse plasma (Takahara, H. & Sinohara, H. (1982) J. Biol. Chem. 257, 2438-2446). We have studied the effects of the two inhibitors upon various serine proteases prepared from mouse tissues. Trypsin, plasmin and trypsin-like proteases of the submaxillary gland were inhibited by contrapsin but not by alpha-1-antitrypsin. On the other hand, chymotrypsin, elastase, and thrombin were inactivated by alpha-1-antitrypsin but not by contrapsin. Thus, their inhibitory spectra did not overlap each other in spite of their broad specificities. The inhibition of trypsin, chymotrypsin, and elastase was rapid and stoichiometric, whereas the inhibition of the other proteases was relatively slow. Contrapsin accounted for almost the total capacities of mouse plasma to inhibit both trypsin and submaxillary gland trypsin-like proteases, whereas alpha-1-antitrypsin was responsible for nearly all the capacities of plasma to inhibit both chymotrypsin and elastase.     

The inhibition of human leucocyte elastase and chymotrypsin-like protease by elastatinal and chymostatin.

The ability of elastatinal and chymostatin, protease inhibitors of microbial origin, to inhibit human leucocyte proteases (EC 3.4.-) was studied. Elastatinal and chymostatin are capable of inhibiting the pancreatic enzymes elastase and chymotrypsin, respectively. It was found in these studies, with synthetic substrates, that elastatinal is a much weaker inhibitor of human leucocyte elastase than it is of porcine pancreatic elastase. Elastatinal caused no inhibition of the activity of human leucocyte chymotrypsin-like protease. Chymostatin was found to be a powerful inhibitor of human leucocyte chymotrypsin-like protease. Its affinity to the leucocyte protease was higher than its affinity to bovine pancreatic alpha-chymotrypsin. Chymsotatin had a weak inhibitory effect on the activity of human leucocyte elastase. Studies were also carried out on the ability of chymostatin to inhibit the release of 35SO2-4 from rabbit articular cartilage by human leucocyte chymotrypsin-like protease. Preincubation of the chymostatin with the protease before the latter was added to the 35SO2-4 -labeled cartilage caused inhibition of proteolysis as measured by 35SO2-4 release. Preincubation of chymostatin with 35SO2-4 -labeled cartilage prior to addition of the human chymotrypsin-like protease to the tissue also inhibited 35SO2-4 release. However, in the case of preincubation of cartilage with alpha1 -antitrypsin there was no such inhibition. It therefore appeared that chymostatin, unlike alpha1 -antitrypsin, was capable of penetrating the cartilage matrix and exerting its inhibitory effect upon the human leucocyte chymotrypsin-like protease that was subsequently added to the tissue.     

Serum elastase 1 and immunoreactive trypsin in chronic pancreatic disease: is there any relationship with trypsin inhibitors?

In order to investigate modifications of serum levels of elastase 1, immunoreactive trypsin, alpha 1-antitrypsin and alpha 2-macroglobulin in chronic pancreatic disease, and to speculate on the possible relationships among these parameters, the enzymes and inhibitors were assayed in the sera of 33 control subjects, 34 pancreatic cancer, 28 chronic pancreatitis and 36 extra-pancreatic diseases. An increase of elastase 1, alpha 1-antitrypsin and alpha 2-macroglobulin was detected in pancreatic cancer, chronic pancreatitis and extra-pancreatic diseases; no changes were found for serum immunoreactive trypsin. Multiple regression analyses showed that only 7% of elastase 1 was explained by inhibitors with alpha 1-antitrypsin playing a major role. Inhibitors did not influence immunoreactive trypsin. Our data indicate that the variations of the serum levels of proteases and antiproteases in chronic pancreatic disease are probably independent of each other.     

Structure of human alpha 2-plasmin inhibitor deduced from the cDNA sequence

We have isolated three cDNA clones for human alpha 2-plasmin inhibitor (alpha 2-PI). Two clones are from human hepatoma cell line, Hep G2, and cover the entire protein coding region plus the 3'-flanking region up to the poly(A) sequence, and the other clone is from human liver and contains the carboxyl-terminal half. The total length of the cDNAs is 2.29 kb, corresponding to more than 95% of the full-length mRNA. alpha 2-PI seems to consist of 452 amino acid residues plus 39 amino acid residues for the signal peptide. The amino acid sequence shows 23 to 28% homology to those of five other protease inhibitors, plasminogen activator inhibitor (PAI), protein C inhibitor (PCI), alpha 1-antitrypsin (alpha 1-AT), antithrombin III (AT III), and alpha 1-antichymotrypsin (alpha 1-AC). alpha 2-PI seems to be the most distantly related among these inhibitors. Comparison of the phylogenetic trees of proteases and their inhibitors indicates that four proteases, namely elastase (or trypsin), chymotrypsin, plasminogen activator, and thrombin, may have evolved concurrently with the corresponding inhibitors. However, alpha 2-PI and PCI seem to have evolved asynchronously from their substrates. The data suggest that alpha 2-PI may originally have inhibited some protease other than plasmin, and protein C may have had an inhibitor different from the present one early in its evolutionary history.     

Characterisation of the alpha 1-protease inhibitor system in Thoroughbred horse plasma by horizontal two-dimensional (ISO-DALT) electrophoresis. 2. Protease inhibition

The protease inhibitory spectra of the eight homozygous Thoroughbred Pi types against trypsin, elastase and chymotrypsin have been determined. The alpha 1-protease inhibitor proteins exhibit three classes of inhibitory specificity towards these enzymes. The Pi types F, I, N and U exhibit class I (trypsin, elastase and chymotrypsin) and class II (trypsin and elastase) types of inhibition and fit Juneja et al.'s (1979) classification of two separate genetic systems Pi 1 and Pi 2 based on differences in the inhibitory spectra against trypsin and chymotrypsin. The remaining four Pi types are exceptions to Juneja et al.'s (1979) classification. Types G, L, S1 and S2 possess class I but not class II proteins. A third class of proteins (class III) which exclusively inhibit chymotrypsin was detected in all eight protease inhibitor types. Type G is well represented by class III proteins because two of the three major proteins of the ISO-DALT pattern inhibit only chymotrypsin and is thus an exception to Juneja et al.'s (1979) classification.     

New human colorectal carcinoma cell lines that secrete proteinase inhibitors in vitro

Two new human cell lines, RCM-1 and CoCM-1, have been established from primary colorectal adenocarcinomas. Both cell lines were unique in that the cultures secreted trypsin inhibitors in vitro. The activities of these inhibitors were accumulated in serum-free media of both cell lines over a period of several days. Two inhibitors (PI-1 and PI-2) were isolated from serum-free conditioned medium in which RCM-1 was grown by anion-exchange and gel filtration high-performance liquid chromatography. PI-1 inhibited trypsin and chymotrypsin strongly, and pancreatic elastase weakly. Its molecular weight was about 57 kilodaltons (Kd) as determined by gel filtration chromatography. It cross-reacted with the antiserum elicited against human alpha 1-antitrypsin in double immunodiffusion. PI-1 corresponding to alpha 1-antitrypsin was also demonstrated immunohistochemically in both cell lines. PI-2 inhibited trypsin strongly, and chymotrypsin, kallikrein and plasmin weakly. It had higher molecular weight (200-300 Kd) than that of PI-1, and did not cross-react with antisera against human alpha 1-antitrypsin, alpha 2-macroglobulin, alpha 1-antichymotrypsin, alpha 2-plasmin inhibitor, inter-alpha-trypsin inhibitor and urinary trypsin inhibitor. RCM-1 and CoCM-1 are the first colorectal adenocarcinoma cell lines that secrete functionally active trypsin inhibitors, including alpha 1-antitrypsin in vitro, and are useful for the study of tumor-cell derived proteinase inhibitors.     

A unique trypsin-like protease associated with plasma membranes of rat liver

One way in which serum promotes survival of primary cultured hepatocytes is by inhibiting plasma membrane protease (Nakamura, T., Asami, O., Tanaka, K., and Ichihara, A. (1984) Exp. Cell Res. 155, 81-91). One of these proteases was solubilized from the plasma membranes of rat liver with 4% octyl glucoside and purified to a homogeneous state by affinity chromatography on bovine pancreatic trypsin inhibitor linked to Sepharose 4B. The protease had an apparent Mr = 120,000 by Sephacryl S-200 gel filtration and the Mr of its subunits was 30,000, as determined by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. It appeared to be a glycoprotein. A high concentration of detergent was necessary to keep the protein soluble. The purified enzyme readily hydrolyzed synthetic tripeptide nitroanilides at sites adjacent to Arg or Lys residues, but did not degrade synthetic substrates of chymotrypsin, elastase, or aminopeptidase. It showed endopeptidase activity, hydrolyzing various proteins such as casein, hemoglobin, and denatured albumin. The enzyme was strongly inhibited by diisopropyl fluorophosphate, phenylmethanesulfonyl fluoride, bovine pancreatic trypsin inhibitor, leupeptin, antipain, and alpha 1-antitrypsin, but not by chymostatin, elastatinal, or inhibitors of carboxyl, thiol, or metallo proteases, suggesting that it is a seryl trypsin-like protease. This protease was found in plasma membranes of rat and mouse liver and in small amounts in those of kidney, but not in those of brain, red cells, Ehrlich ascites tumor, or two Morris hepatomas, suggesting that it may be involved in differentiated functions of normal hepatocytes.     

The interaction in human plasma of antiplasmin, the fast-reacting plasmin inhibitor, with plasmin, thrombin, trypsin and chymotrypsin.

The inhibition of plasmin, (EC 3.4.21.7), thrombin (EC 3.4.21.5), trypsin (EC 3.4.21.4) and chymotrypsin (EC 3.4.21.1) by antiplasmin, the recently described fast-reacting plasmin inhibitor of human plasma, was studied. To determine the quantitative importance of antiplasmin relative to the other plasma protease inhibitors, enzyme inhibition assays were performed on whole plasma and on plasma specifically depleted in antiplasmin, after addition of excess enzyme. Plasmin was the only enzyme for which the inhibitory capacity of antiplasmin-depleted plasma was lower than that of normal plasma. To determine the affinity of the enzymes for antiplasmin, as compared to the other inhibitors, various amounts of enzymes were added to normal plasma and the formation of enzyme-antiplasmin complexes studied by crossed immunoelectrophoresis using specific antisera against antiplasmin. Plasmin and trypsin, but not thrombin or chymotrypsin formed complexes with antiplasmin. It is concluded that antiplasmin is the only fast-reacting plasmin inhibitor of human plasma. It is also a fast-reacting inhibitor of trypsin but only accounts for a very small part of the fast-reacting trypsin-inhibitory activity of plasma. This can be explained by the low concentration of antiplasmin (1 muM) in normal plasma, compared to the other inhibitors (e.g. alpha1-antitrypsin: 40-80 muM).     

Interactions of alpha1-antitrypsin with trypsin and chymotrypsin.

The interaction of alpha1-antitrypsin with trypsin and chymotrypsin has been investigated by protease activity assays, by electrophoretic analysis, by CD and absorption difference spectra, and by gel filtration of reaction mixtures containing excess inhibitor or excess protease. When alpha1-antitrypsin is present in excess, only one stable inhibitor - protease complex is formed. In the presence of excess protease, however, this primary complex is degraded relatively rapidly to one or more secondary complexes. These latter conversions are more pronounced in the case of the antititrypsin-chymotrypsin system. The greater lability of the antitrypsin-chymotrypsin system is evidenced by the relatively rapid release of inactive chymotrypsin from the secondary antitrypsin - chymotrypsin complex. Only minimal amounts of active protease were released from the complexes on the addition of excess protease and one protease could not displace the other from the complex, although competition experiments showed that chymotrypsin reacted more rapidly with the inhibitor than trypsin.     

Characterisation of the α1-protease inhibitor system in Thoroughbred horse plasma by horizontal two-dimensional (ISO-DALT) electrophoresis. 2. Protease inhibition

The protease inhibitory spectra of the eight homozygous Thoroughbred Pi types against trypsin, elastase and chymotrypsin have been determined. The α1-protease inhibitor proteins exhibit three classes of inhibitory specificity towards these enzymes. The Pi types F, I, N and U exhibit class I (trypsin, elastase and chymotrypsin) and class II (trypsin and elastase) types of inhibition and fit Juneja et al.s (1979) classification of two separate genetic systems Pi 1 and Pi 2 based on differences in the inhibitory spectra against trypsin and chymotrypsin. The remaining four Pi types are exceptions to Juneja et al.s (1979) classification. Types G, L, S₁ and S₂ possess class I but not class II proteins. A third class of proteins (class III) which exclusively inhibit chymotrypsin was detected in all eight protease inhibitor types. Type G is well represented by class III proteins because two of the three major proteins of the ISO-DALT pattern inhibit only chymotrypsin and is thus an exception to Juneja et al.s (1979) classification.     

Protease inhibitors from the parasitic worm Parascaris equorum

Two proteic inhibitors (I and II) of serine proteases have been purified from the parasitic worm Parascaris equorum by affinity chromatography on immobilized trypsin followed by preparative electrophoresis. They have an apparent relative molecular mass of 9000 and 7000 as determined by gel filtration, a slightly acid isoelectric point (5.5 and 6.1) and a similar amino acid composition. Both inhibitors lack serine, methionine and tyrosine. They bind bovine trypsin extremely strongly with an association constant, Ka, larger than 10(9) M-1, and form a 1:1 complex with this protease. The Ka values for the binding to bovine chymotrypsin are approximately 3.3 X 10(8) M-1 (inhibitor I) and approximately 2 X 10(6) M-1 (inhibitor II). Inhibitor I interacts also with porcine elastase (Ka approximately 5 X 10(7) M-1), while inhibitor II is inactive towards this enzyme.     

Proteinase inhibitors in rat serum. Purification and partial characterization of three functionally distinct trypsin inhibitors.

Three different serine proteinase inhibitors were isolated from rat serum and purified to apparent homogeneity. One of the inhibitors appears to be homologous to alpha 1-proteinase inhibitor isolated from man and other species, but the other two, designated rat proteinase inhibitor I and rat proteinase inhibitor II, seem to have no human counterpart. alpha 1-Proteinase inhibitor (Mr 55000) inhibits trypsin, chymotrypsin and elastase, the three serine proteinases tested. Rat proteinase inhibitor I (Mr 66000) is active towards trypsin and chymotrypsin, but is inactive towards elastase. Rat proteinase inhibitor II (Mr 65000) is an effective inhibitor of trypsin only. Their contributions to the trypsin-inhibitory capacity of rat serum are about 68, 14 and 18% for alpha 1-proteinase inhibitor, rat proteinase inhibitor I and rat proteinase inhibitor II respectively.     

Novel secretory vesicle serpins,endopin 1 and endopin 2: endogenous protease inhibitors with distinct target protease specificities

Secretory vesicles of neuroendocrine cells possess multiple proteases for proteolytic processing of proteins into biologically active peptide components, such as peptide hormones and neurotransmitters. The importance of proteases within secretory vesicles predicts the presence of endogenous protease inhibitors in this subcellular compartment. Notably, serpins represent a diverse class of endogenous protease inhibitors that possess selective target protease specificities, defined by the reactive site loop domains (RSL). In the search for endogenous serpins in model secretory vesicles of neuroendocrine chromaffin cells, the presence of serpins related to alpha1-antichymotrypsin (ACT) was detected by Western blots with anti-ACT. Molecular cloning revealed the primary structures of two unique serpins, endopin 1 and endopin 2, that possess homology to ACT. Of particular interest was the observation that distinct RSL domains of these new serpins predicted that endopin 1 would inhibit trypsin-like serine proteases cleaving at basic residues, and endopin 2 would inhibit both elastase and papain that represent serine and cysteine proteases, respectively. Endopin 1 showed selective inhibition of trypsin, but did not inhibit chymotrypsin, elastase, or subtilisin. Endopin 2 demonstrated cross-class inhibition of the cysteine protease papain and the serine protease elastase. Endopin 2 did not inhibit chymotrypsin, trypsin, plasmin, thrombin, furin, or cathepsin B. Endopin 1 and endopin 2 each formed SDS-stable complexes with target proteases, a characteristic property of serpins. In neuroendocrine chromaffin cells from adrenal medulla, endopin 1 and endopin 2 were both localized to secretory vesicles. Moreover, the inhibitory activity of endopin 2 was optimized under reducing conditions, which required reduced Cys-374; this property is consistent with the presence of endogenous reducing agents in secretory vesicles in vivo. These new findings demonstrate the presence of unique secretory vesicle serpins, endopin 1 and endopin 2, which possess distinct target protease selectivities. Endopin 1 inhibits trypsin-like proteases; endopin 2 possesses cross-class inhibition for inhibition of papain-like cysteine proteases and elastase-like serine proteases. It will be of interest in future studies to define the endogenous protease targets of these two novel secretory vesicle serpins.     

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.     

Interaction between leukocytic elastase and Kunitz-type inhibitors from bovine spleen

The four Kunitz-type protease inhibitors purified from bovine spleen, which include the basic pancreatic trypsin inhibitor (BPTI), form stable complexes with human leukocytic elastase. The values of the affinity constants of these complexes are similar, in agreement with the great structural similarity of the four inhibitors, but are lower than those measured for the complexes with other serine proteases. Two main factors appear to be responsible for the stability of these complexes, i.e., hydrophobic interactions and ionization phenomena that take place during complex formation. These two factors have been analyzed in terms of the general model previously used for describing the interaction between the serine proteases and their natural inhibitors.