Substrate properties of C1 inhibitor Ma (alanine 434----glutamic acid). Genetic and structural evidence suggesting that the P12-region contains critical determinants of serine protease inhibitor/substrate status

The serine protease inhibitor (serpin) C1 inhibitor inactivates enzymes involved in the regulation of vascular permeability. A patient from the Ma family with the genetic disorder hereditary angioedema inherited a dysfunctional C1 inhibitor allele. Relative to normal plasma, the patients's plasma contained an additional C1 inhibitor immunoreactive band, which comigrated with normal C1 inhibitor cleaved by plasma kallikrein, C1s, or factor XIIa. C1 inhibitor Ma did not react with a monoclonal antibody to a neoepitope that is present in complexed and cleaved normal C1 inhibitor, suggesting conformational differences between cleaved normal C1- inhibitor and cleaved C1 inhibitor Ma. Molecular cloning and sequencing of exon 8 of the C1 inhibitor Ma allele revealed a single C to A mutation, changing alanine 434 to glutamic acid. Ala 434 of C1 inhibitor aligns with the P12 residue of the prototypical serpin alpha 1-antitrypsin. The P12 amino acid of all inhibitory serpins is alanine, and it is present in a highly conserved region on the amino-terminal side of the serpin-reactive center loop. Whereas normal C1 inhibitor expressed by transfected COS-1 cells formed complexes with and was cleaved by kallikrein, fXIIa, and C1s, COS-1-expressed Ala434---Glu C1 inhibitor was cleaved by these enzymes but did not form complexes with them. These results, together with evidence from other studies, suggest that serpin protease inhibitor activity is the result of protein conformational change that occurs when the P12 region of a serpin moves from a surface location, on the reactive site loop of the native molecule, to an internal location within sheet A of the complexed inhibitor.     

C1 inhibitor cross-linking by tissue transglutaminase

C1 inhibitor, a plasma proteinase inhibitor of the serpin superfamily involved in the regulation of complement classical pathway and intrinsic blood coagulation, has been shown to bind to several components of the extracellular matrix. These reactions may be responsible for C1 inhibitor localization in the perivascular space. In the study reported here, we have examined whether C1 inhibitor could function as a substrate for plasma (factor XIIIa) or tissue transglutaminase. We made the following observations: 1) SDS-polyacrylamide gel electrophoresis and autoradiography showed that C1 inhibitor exposed to tissue transglutaminase (but not to factor XIIIa) incorporated the radioactive amine donor substrate [(3)H]putrescine in a calcium-dependent manner; 2) the maximum stoichiometry for the uptake of [(3)H]putrescine by C1 inhibitor was 1:1; 3) proteolytic cleavage and peptide sequencing of reduced and carboxymethylated [(3)H]putrescine-C1 inhibitor identified Gln(453) (P'9) as the single amine acceptor residue; 4) studies with (125)I-labeled C1 inhibitor showed that tissue transglutaminase was also able to cross-link C1 inhibitor to immobilized fibrin; and 5) C1 inhibitor cross-linked by tissue transglutaminase to immobilized fibrin had inhibitory activity against its target enzymes. Thus, tissue transglutaminase-mediated cross-linking of C1 inhibitor to fibrin or other extracellular matrix components may serve as a mechanism for covalent serpin binding and influence local regulation of the proteolytic pathways inhibited by C1 inhibitor.     

Differential inhibitory properties of dog and human alpha 1-proteinase inhibitors

Dog alpha 1-proteinase inhibitor (alpha 1-PI) was found to be an effective inhibitor of bovine chymotrypsin and also of porcine pancreatic elastase as in the case of human inhibitor. The dog inhibitor inactivated both proteinases at a molar ratio of 1:1. However, compared to the human inhibitor, dog alpha 1-PI was a relatively poor inhibitor of bovine trypsin. The association rate constants (kass) of the interactions of dog alpha 1-PI with bovine chymotrypsin and with porcine elastase were determined to be 6.9 +/- 0.3 X 10(6) M-1 s-1 and 6.4 +/- 0.1 X 10(5) M-1 s-1, respectively. These values are 1.3- and 2.7-fold higher than the corresponding values for the human inhibitor. On the other hand, kass for the dog inhibitor with bovine trypsin (2.6 +/- 0.3 X 10(4)M-1 s-1) was found to be about 5 times smaller than that of the human inhibitor.     

Structural and functional differences in H+-ATPases with native and reconstituted inhibitor protein

Anti F1 antibodies that react with the alpha and beta subunits of the mitochondrial F0-F1 ATPase complex do not interfere with the natural inhibitor protein-ATPase interaction as revealed by inhibitor peptide titration curves. Submitochondrial particles with endogenous or added bound inhibitor protein show differences in immunoprecipitation. Submitochondrial particles which are partially depleted of inhibitor protein gave the same immunoprecipitation curve as the Mg-ATP particle. Anti F1 antibodies induce differential effects in ATP hydrolysis and ATP-Pi exchange. ATP hydrolysis is stimulated in Mg-ATP particles to 200%, while inhibitor depleted and inhibitor reconstituted particles are inhibited by the presence of the antibodies. ATP-Pi exchange is stimulated in inhibitor reconstituted particles and inhibited in Mg-ATP and inhibitor depleted particles. These results suggest that the inhibitor protein when endogenously bound confers a different conformation to the F1-ATPase than that of the F1 ATPase with added bound inhibitor protein.     

Secretion of high-mannose-type alpha 1-proteinase inhibitor and alpha 1-acid glycoprotein by primary cultures of rat hepatocytes in the presence of the mannosidase I inhibitor 1-deoxymannojirimycin

Two different forms of alpha 1-proteinase inhibitor and alpha 1-acid glycoprotein were found in primary cultures of rat hepatocytes. After a 2.5-h labeling period with [35S]methionine the high-mannose-type precursor of alpha 1-proteinase inhibitor (Mr 49000) and alpha 1-acid glycoprotein (Mr 39 000) and the mature-complex-type alpha 1-proteinase inhibitor (Mr 54 000) and alpha 1-acid glycoprotein (Mr 43 000-60 000) could be immunoprecipitated from the cells, but only the complex-type forms of the two glycoproteins were secreted into the hepatocyte media. When hepatocytes were incubated with the mannosidase I inhibitor 1-deoxymannojirimycin at a concentration of 4 mM, the 49 000-Mr form of alpha 1-proteinase inhibitor and the 39 000-Mr form of alpha 1-acid glycoprotein could be detected in the cells as well as in their media. Neither the secretion of alpha 1-proteinase inhibitor nor that of alpha 1-acid glycoprotein was impaired by 1-deoxymannojirimycin. While alpha 1-proteinase inhibitor and alpha 1-acid glycoprotein, secreted by control cells, were resistant to endoglucosaminidase H, alpha 1-proteinase inhibitor and alpha 1-acid glycoprotein, secreted by hepatocytes treated with 4 mM 1-deoxymannojirimycin, could be deglycosylated by endoglucosaminidase H. When the [3H]mannose-labeled oligosaccharides of alpha 1-proteinase inhibitor, secreted by 1-deoxymannojirimycin-treated hepatocytes, were cleaved off by endoglucosaminidase H and analyzed by Bio-Gel P-4 chromatography, they eluted at the position of Man9GlcNAc, indicating that mannosidase I had been efficiently inhibited. 1-Deoxymannojirimycin did not inhibit the synthesis or the cotranslational N-glycosylation of alpha 1-proteinase inhibitor or alpha 1-acid glycoprotein.     

Functional and structural similarities between protease nexin I and C1 inhibitor

Protease nexin I is a proteinase inhibitor that is secreted by human fibroblasts and forms stable complexes with certain serine proteinases; the complexes then bind to the fibroblasts and are rapidly internalized and degraded. In this report, we show that this inhibitor, which is present in very low concentrations in plasma, has functional and structural similarities to C1 inhibitor, an abundant proteinase inhibitor in plasma. Both inhibitors complex and inactivate certain proteinases that previously were known to rapidly react only with C1 inhibitor. Kinetic inhibition studies show that protease nexin I inhibits Factor XIIa and plasma kallikrein with second-order rate constants of 2.3 x 10(3) and 2.5 x 10(5) M-1 s-1, respectively, which are similar to the rate constants for inhibition of these proteinases by C1 inhibitor. Protease nexin I inhibits C1s about one-tenth as rapidly as does C1 inhibitor. Alignment of the amino acid sequences of protease nexin I and C1 inhibitor shows that these proteins have similarity at their reactive centers (from sites P7 to P1). The remaining regions of the two proteins share much less similarity. In contrast to protease nexin I, C1 inhibitor is not secreted by human fibroblasts. Although 125I-C1s-protease nexin I complexes readily bind to human fibroblasts, binding of 125I-C1s-C1 inhibitor complexes or other 125I-proteinase-C1-inhibitor complexes to these cells is not detectable. Thus, protease nexin I and C1 inhibitor may control some common regulatory proteinases in the extravascular and vascular compartments, respectively.     

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.     

Ribonuclease inhibitor from pig brain: purification, characterization, and direct spectrophotometric assay

The ribonuclease inhibitor from pig brain has been purified 1,500-fold by a combination of ammonium sulfate fractionation, ion-exchange chromatography, hydroxylapatite chromatography, and gel filtration. The inhibitor has a Mr 50,000. It is a noncompetitive inhibitor for pancreatic ribonuclease A with a Ki of 1 nM, forming a 1:1 complex. Both ribonuclease A and B, but not ribonuclease U1 and T1, are inactivated by the inhibitor. The inhibition capacity was abolished by sulfhydryl reagents such as p-chloromercuribenzoate. Incubation of the enzyme-inhibitor complex with the sulfhydryl reagent caused dissociation into active ribonuclease and inactive inhibitor. Dithiothreitol was required during purification to retain the activity of the inhibitor.     

Evidence for an endogenous ATPase inhibitor protein in plant mitochondria. Purification and characterization

An endogenous ATPase inhibitor protein has been identified and isolated for the first time from plant mitochondria. The inhibitor protein was isolated from potato (Solanum tuberosum) tuber mitochondria and purified to homogeneity. The isolated inhibitor is a heat-stable, trypsin-sensitive, basic protein, with a molecular mass approximately 8.3 kDa. Amino acid analysis reveals a high content of glutamic acid, lysine and arginine and the absence of proline; threonine and leucine. The interaction of the inhibitor with F1-ATPase requires the presence of Mg2(+)-ATP in the incubation medium. The ATPase activity of isolated F1 is inhibited to 50% in the presence of 14 micrograms inhibitor/mg F1. A stoichiometry of 1.3 mol inhibitor/mol F1 for complete inhibition can be calculated from this value. The potato ATPase inhibitor is also a potent inhibitor of the ATPase activity of the isolated yeast F1. The inhibitor resembles the ATPase inhibitors of yeast and mammalian mitochondria, and does not seem to be related to the inhibitory peptide, epsilon subunit, of chloroplast ATPase.     

Resistance of horse alpha 1-proteinase inhibitor to perchloric acid denaturation and a simplified purification procedure resulting therefrom

Addition of perchloric acid (6.4% w/v final concentration) to horse alpha 1-proteinase inhibitor or to horse plasma neither precipitated nor inactivated alpha 1-proteinase inhibitor. None of the isoinhibitors of alpha 1-proteinase inhibitor was altered by dilute perchloric acid. This unexpected behavior led to a simplified procedure for the purification of horse alpha 1-proteinase inhibitor, consisting of removal of the bulk of plasma proteins, by perchloric acid precipitation and by gel filtration on Sephadex G-75 and G-200. The resulting preparations of alpha 1-proteinase inhibitor were immunogenically pure. The simplified purification procedure permitted the immunochemical comparison of the isoinhibitors of alpha 1-proteinase inhibitor, which proved to be immunologically identical.     

Comparative characteristic of serpin--alpha-1 proteinase inhibitor in human and mice serum

Serpin alpha-1-proteinase inhibitor have been studied in human subjects and in mice of different lines as acute phase reactant and during tumor development. In humans, there was no difference of serpin activity between men and women. Increased activity was noted in men with acute trauma (acute phase reaction). Comparatively to male, in female mice of different lines decreased activity of serum alpha-1-proteinase inhibitor, was shown. There was no increase of alpha-1-proteinase inhibitor activity during inflammation induced by zymosan administration in mice. alpha-1-proteinase inhibitor belongs to acute phase reactants in humans but not in mice; for mice alpha-2-macroglobulin is a more typical acute phase reactant as compared to alpha-1-proteinase inhibitor. Murine tumor development (hepatoma HA-1, lymphosarcoma LS, Lewis lung adenocarcinoma) was followed by a decreased activity of serum alpha-1-proteinase inhibitor both in successfully treated and untreated groups. According to data of literature, similar dated were obtained in humans with tumors. It was suggested that changes of expressiln of alpha-1-proteinase inhibitor by tumors and its secretion were involved in decreased activity of alpha-1-proteinase inhibitor.     

Kinetics of binding of bovine trypsin-killikrein inhibitor (K unitz) in which the reactive-site peptide bond Lys-15--Ala-16 is cleaved, to alpha-chymotrypsin and beta-trypsin.

Equilibrium measurements of the binding of reactive-site-cleaved (modified) bovine trypsin-kallikrein inhibitor (Kunitz) to alpha-chymotrypsin and beta-trypsin show a stoichiometric 1:1 association with high binding constants. At least in the case of chymotrypsin much evidence is presented that the reaction with modified inhibitor leads to the same complex as the reaction with virgin inhibitor does. The association rate constant of modified inhibitor with chymotrypsin at pH 7, 22.5 degrees C is 15.8 M-1 S-1. This is about 2 x 10(4) times slower than the binding of virgin inhibitor to that enzyme. In the analogous reaction of modified inhibitor with beta-trypsin, however, the association rate constant (1.2 x 10(4) M-1 s-1 at pH 6.9, 22.5 degrees C) is of about the same order of magnitude as it is in the reaction of virgin inhibitor and trypsin. These and analogous phenomena observed in the reactions of virgin and modified soybean trypsin inhibitor (Kunitz) with alpha-chymotrypsin and beta-trypsin suggest that the specificity of both inhibitors to trypsin is strongly reflected in the association rate constants of the modified forms. The dissociation rate constants of the complexes of trypsin-kallikrein inhibitor with chymotrypsin or with trypsin towards the modified inhibitor are estimated to be unmeasurably slow (half-life times of 45 or 1.5 x 10(4) years, respectively).     

Inactivation of human thrombin in the presence of human alpha1-proteinase inhibitor.

Both the clotting and esterase activities of thrombin are inhibited by alpha1-proteinase inhibitor (alpha1-antitrypsin). The inhibition is a time-and temperature-dependent reaction which is proportional to the molar ratio of thrombin to inhibitor. Both the active-site serine residue of thrombin and the reactive-site lysine residue of alpha1-proteinase inhibitor are involved. alpha1-Proteinase inhibitor forms a 1:1 complex with thrombin that is comparable with the complex formed with trypsin and other proteinases. Incubation of the inhibitor with excess of thrombin, however, results in inactivation of nearly all the enzyme, even though only as much complex is formed as alpha1-proteinase inhibitor present. A portion of the remaining thrombin apparently aggregates. These results suggest that the mechanism for inhibition of thrombin may not be exactly the same as for trypsin, which is inhibited only to the extent to which complex is formed.     

Inhibition of human blood coagulation factor XIa by C-1 inhibitor

The inactivation of activated factor XI (factor XIa) and of its isolated light chain by C-1 inhibitor was studied. Irreversible inhibition was observed in a reaction in which no reversible enzyme-inhibitor complex was formed. The second-order rate constants for the inactivation of factor XIa or its light chain by C-1 inhibitor were 2.3 X 10(3) and 2.7 X 10(3) M-1 s-1, respectively. High molecular weight kininogen did not affect the rate of inactivation. The nature of the complexes formed between factor XIa or its light chain and C-1 inhibitor was studied by using sodium dodecyl sulfate gradient polyacrylamide slab gel electrophoresis. Under nonreducing conditions, two factor XIa-C-1 inhibitor complexes were observed with apparent molecular weights of 230,000 and 300,000. Reduction of these complexes resulted in the formation of a single band with a molecular weight of 130,000. This band is also formed in the reaction of the isolated light chain of factor XIa with C-1 inhibitor. These results demonstrate that two C-1 inhibitor molecules can become bound to the light chains of a factor XIa molecule. In addition, the mechanism of interaction of factor XIa or its isolated light chain with C-1 inhibitor appears identical, and the rate of inactivation of the enzyme by C-1 inhibitor is very similar. Neither the heavy chain of factor XIa nor high molecular weight kininogen is significantly involved in the inactivation of factor XIa by C-1 inhibitor.     

Comparison of properties of thiol proteinase inhibitors from rat serum and liver

Thiol proteinase inhibitors in rat serum were purified and their properties were compared with those of rat liver thiol proteinase inhibitor. The inhibitors in rat serum were separated into three forms (S-1, S-2, and S-3) by linear gradient elution from a DE52 column. One inhibitor (S1) was purified to homogeneity by chromatography on ficin-bound Sepharose and Sephadex G-150 columns. The apparent molecular weights of S1, S2, and S3 on Sephadex G-150 columns were 90,000, 95,000, and 160,000, respectively. Serum thiol proteinase inhibitor and liver thiol proteinase differed in the following: 1) all three forms of serum inhibitor had much higher molecular weights than the liver thiol proteinase inhibitor (Mr = 12,500); 2) no cross-reactivity was observed between serum inhibitors and liver inhibitor in tests with either antiserum inhibitor or anti-liver antiserum; 3) both serum inhibitor and liver inhibitor were specific for thiol proteinases, but had different inhibition spectra; 4) the liver inhibitor did not bind to concanavalin A-Sepharose, whereas the serum inhibitor bound and was eluted with alpha-methyl mannoside. A thiol proteinase inhibitor of high molecular weight detected in tissue homogenates inhibited papain markedly but did not inhibit cathepsin H. Its activity was diminished by perfusion of the organ, indicating that it is derived from serum.     

Physiologic inhibition of human activated protein C by alpha 1-antitrypsin

The plasma antithrombotic enzyme activated protein C (APC) has two major plasma inhibitors. One is heparin-dependent, has been characterized, and is known as protein C inhibitor. The second inhibitor was isolated based on its heparin-independent ability to inhibit and complex with APC. The purified inhibitor had the amino acid composition and NH2 terminus of alpha 1-antitrypsin and reacted with monoclonal antibodies to alpha 1-antitrypsin. The inhibitor was greater than 95% pure alpha 1-antitrypsin as judged by electroimmunoassay, inactivation of trypsin, and electrophoresis in two gel systems. To identify the second major plasma inhibitor of APC, immunoblot studies of enzyme-inhibitor complexes were made to compare APC addition to normal plasma and to plasma deficient in protein C inhibitor or alpha 1-antitrypsin. The results showed that alpha 1-antitrypsin is the second major plasma APC inhibitor. Given the association rate constant of alpha 1-antitrypsin for APC of 10 M-1 s-1 and its plasma concentration of approximately 40 microM, it accounts for approximately half of the heparin-independent APC inhibitory activity of plasma. Based on immunoblot analysis plasmas of 15 patients with intravascular coagulation contained APC-alpha 1-antitrypsin complexes suggesting that this inhibition reaction occurs in vivo. Thus, alpha 1-antitrypsin is a major physiologic inhibitor of APC.     

Influence of elastin on the inhibition of leucocyte elastase by alpha 1-proteinase inhibitor and bronchial inhibitor. Potent inhibition of elastin-bound elastase by bronchial inhibitor.

We have investigated the effect of human lung elastin on the inhibition of human leucocyte elastase by human alpha 1-proteinase inhibitor and bronchial inhibitor. Elastin was unable to dissociate the elastase-inhibitor complexes during the 150 min of the elastolysis reaction. When elastase was added to mixtures of elastin and alpha 1-proteinase inhibitor, it was fully bound to the latter. The competition between elastin and bronchial inhibitor was also in favour of the latter, but a 1.5 molar excess of inhibitor over elastase was required to achieve total binding of the enzyme. About 25% of elastin-bound elastase was found to be resistant to the inhibitory effect of alpha 1-proteinase inhibitor. The major isoenzyme and the mixture of the three minor isoenzymes of elastase exhibited similar behaviour. By contrast, bronchial inhibitor was as efficient in inhibiting the elastin-bound elastase as it was in inhibiting the free enzyme. This inhibitor was also able to inhibit fully the fraction of elastin-bound elastase that was resistant to alpha 1-proteinase inhibitor. We also describe a rapid procedure for the isolation of gram quantities of alpha 1-proteinase inhibitor.     

1-deoxynojirimycin impairs oligosaccharide processing of alpha 1-proteinase inhibitor and inhibits its secretion in primary cultures of rat hepatocytes

1-Deoxynojirimycin was found to inhibit oligosaccharide processing of rat alpha 1-proteinase inhibitor. In normal hepatocytes alpha 1-proteinase inhibitor was present in the cells as a 49,000 Mr high mannose type glycoprotein with oligosaccharide side chains having the composition Man9GlcNAc and Man8GlcNAc with the former in a higher proportion. Hepatocytes treated with 5 mM 1-deoxynojirimycin accumulated alpha 1-proteinase inhibitor as a 51,000 Mr glycoprotein with carbohydrate side chains of the high mannose type, containing glucose as measured by their sensitivity against alpha-glucosidase, the largest species being Glc3Man9GlcNAc. Conversion to complex oligosaccharides was inhibited by the drug. In addition, increasing concentrations of 1-deoxynojirimycin inhibited glycosylation resulting in the formation of some alpha 1-proteinase inhibitor with two instead of three oligosaccharide side chains. 5 mM 1-deoxynojirimycin inhibited the secretion of alpha 1-proteinase inhibitor by about 50%, whereas secretion of albumin was unaffected. The oligosaccharides of alpha 1-proteinase inhibitor secreted from 1-deoxynojirimycin-treated cells were characterized by their susceptibility to endoglucosaminidase H, incorporation of [3H]galactose, and [3H]fucose and concanavalin A-Sepharose chromatography. It was found that 1-deoxynojirimycin did not completely block oligosaccharide processing, resulting in the formation of alpha 1-proteinase inhibitor molecules carrying one or two complex type oligosaccharides. Only these alpha 1-proteinase inhibitor molecules processed to the complex type in one or two of their oligosaccharide chains were nearly exclusively secreted. This finding demonstrates the importance of oligosaccharide processing for the secretion of alpha 1-proteinase inhibitor.