Acyl-enzyme complexes between tissue-type plasminogen activator and neuroserpin are short-lived in vitro

The serine protease tissue-type plasminogen activator (t-PA) initiates the fibrinolytic protease cascade and plays a significant role in motor learning, memory, and neuronal cell death induced by excitotoxin and ischemia. In the fibrinolytic system, the serpin PAI-1 negatively regulates the enzymatic activity of both single-chain and two-chain t-PA (sct-PA and tct-PA). In the central nervous system, neuroserpin (NSP) is a serpin thought to regulate t-PA enzymatic activity. We report that although both sct-PA and tct-PA rapidly form acyl-enzyme complexes with NSP in vitro, the interactions are short-lived, rapidly progressing to complete cleavage of NSP and regeneration of fully active enzyme. All NSP molecules appear to transit through the detectable acyl-enzyme intermediate and progress to completion of cleavage; no subpopulation that functions as a pure substrate was detected. Likewise, all molecules were reactive, with no evidence of a latent subpopulation. The interactions between NSP and t-PA were distinct from those between plasmin and NSP, wherein the same peptide bond was cleaved but there was no evidence of a detectable plasmin-NSP acyl-enzyme complex. The interactions between t-PA and NSP contrast with the formation of long-lived, physiologically irreversible acyl-enzyme complexes between t-PA and PAI-1, suggesting that the physiologic effect of t-PA-NSP interactions may be more complex than previously thought.     

Structure and function of human tissue-type plasminogen activator (t-PA)

Full-length tissue-type plasminogen activator (t-PA) cDNA served to construct deletion mutants within the N-terminal "heavy" (H)-chain of the t-PA molecule. The H-chain cDNA consists of an array of structural domains homologous to domains present on other plasma proteins ("finger," "epidermal growth factor," "kringles"). These structural domains have been located on an exon or a set of exons. The endpoints of the deletions nearly coincide with exon-intron junctions of the chromosomal t-PA gene. Recombinant t-PA deletion mutant proteins were obtained after transient expression in mouse Ltk- cells, transfected with SV40-pBR322-derived t-PA cDNA plasmids. It is demonstrated that the serine protease moiety of t-PA and its substrate specificity for plasminogen is entirely contained within the C-terminal "light" (L)-chain of the protein. The presence of cDNA, encoding the t-PA signal peptide preceding the remaining portion of t-PA, suffices to achieve secretion of (mutant) t-PA into the medium. The stimulatory effect of fibrin on the plasminogen activator activity of t-PA was shown to be mediated by the kringle K2 domain and, to a lesser extent, by the finger domain. The other domains on the H-chain, kringle K1, and the epidermal growth-factor-like domain, do not contribute to this property of t-PA. These findings correlate well with the fibrin-binding properties of the rt-PA deletion-mutant proteins, indicating that stimulation of the activity is based on aligning of the substrate plasminogen and its enzyme t-PA on the fibrin matrix. The primary target for endothelial plasminogen activator inhibitor (PAI) is located within the L-chain of t-PA. Deleting specific segments of t-PA H-chain cDNA and subsequent transient expression in mouse Ltk- cells of t-PA deletion-mutant proteins did not affect the formation of a stable complex between mutant t-PA and PAI.     

Identification of determinants involved in binding of tissue-type plasminogen activator-plasminogen activator inhibitor type 1 complexes to HepG2 cells

Complexes between tissue-type plasminogen activator (t-PA) and its rapidly acting inhibitor plasminogen activator inhibitor type 1 (PAI-1) are bound, internalized, and degraded by HepG2 cells. The mechanism involves endocytosis mediated by a specific high-affinity receptor. However, the particular domains of the complex that are recognized by the receptor have not been elucidated. To identify the determinants involved in ligand binding to the receptor, several variants of t-PA were assessed for their ability to form complexes with PAI-1 and thereby to inhibit specific cellular binding of complexes between structurally unmodified 125I-t-PA and PAI-1. Catalytically active variants lacking selected structural domains form complexes with PAI-1 and inhibit 125I-t-PA.PAI-1 binding to HepG2 cells. In addition, several forms of the plasminogen activator urokinase (u-PA), which shares partial structural homology with t-PA, were evaluated as competitors of cellular binding. The catalytically active two-chain forms of u-PA, but not the inactive proenzyme single-chain form, complex with PAI-1 and inhibit specific binding of 125I-t-PA.PAI-1, suggesting that the serine protease domain, rather than other domains, may confer the determinants required for cellular binding. However, a mutant t-PA with markedly reduced catalytic activity, resulting from replacement of the active site serine with threonine, not only forms complexes with PAI-1 but also inhibits specific cellular binding of unmodified 125I-t-PA.PAI-1. These data indicate that specific binding of t-PA.PAI-1 to HepG2 cells does not require a serine-containing catalytic site in the protease domain. To determine whether binding of the complex is mediated through other components of t-PA or through structural elements of PAI-1, both t-PA and PAI-1 were examined separately for capacity to bind directly to HepG2 cells. To exclude potential interactions with components of the extracellular matrix which contains binding sites for PAI-1, ligand binding to HepG2 cells in suspension was assessed. Although neither t-PA nor PAI-1 alone binds specifically to HepG2 cells, the preformed t-PA.PAI-1 complexes do. These findings suggest that specific binding of t-PA.PAI-1 requires elements of the PAI-1 moiety and/or parts of the protease domain of t-PA.     

Artificial exon shuffling between tissue-type plasminogen activator (t-PA) and urokinase (u-PA): a comparative study on the fibrinolytic properties of t-PA/u-PA hybrid proteins

We constructed two human tissue-type plasminogen activator/urokinase (t-PA/u-PA) hybrid cDNAs which were expressed by transfection of mouse Ltk- cells. The properties of the secreted proteins were compared with those of recombinant t-PA (rt-PA) and high molecular weight (HMW) u-PA. The hybrid proteins each contain the amino-terminal fibrin-binding chain of t-PA fused to the carboxy-terminal serine protease moiety of u-PA but differ by a stretch of 13 amino acid residues between kringle 2 of t-PA and the plasmin cleavage site of u-PA. Hybrid protein rt-PA/u-PA I contains amino acids 1-262 of t-PA connected with amino acids 147-411 of u-PA, whereas hybrid protein rt-PA/u-PA II consists of the same t-PA segment and residues 134-411 of u-PA. We demonstrated fibrin binding for rt-PA, whereas the hybrid proteins bind to a lesser extent and HMW u-PA has no affinity for fibrin. Plasminogen activation by either one of the hybrid proteins in the absence of a fibrin substitute was similar to that by HMW u-PA, while rt-PA was much less active. The catalytic efficiency, in the presence of a fibrin substitute, increases more than 2000-fold for rt-PA, about 250-fold for hybrid proteins I and II, and 12-fold for HMW u-PA, respectively. Under these conditions the hybrid proteins are more efficient plasminogen activators than the parental ones. The hybrid molecules form a 1:1 molar complex with the human endothelial plasminogen activator inhibitor (PAI-1), analogous to that formed by rt-PA and HMW u-PA. The relative affinity of rt-PA for PAI-1 is 4.6-fold higher than that of HMW u-PA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of interaction of active-site serine mutants of tissue-type plasminogen activator with plasminogen activator inhibitor-1

To define determinants of interactions of tissue-type plasminogen activator (t-PA) with plasminogen activator inhibitor type-1 (PAI-1), we utilized site-directed mutagenesis to substitute either threonine or glycine for the active-site serine of tissue-type plasminogen activator. Assays of conditioned media of transfected cells demonstrated that the threonine substitution markedly decreased but did not entirely abolish plasminogen activating activity. In contrast, the glycine substitution yielded a mutant with absolutely no detectable plasminogen activating activity. Wild-type t-PA formed stable complexes with PAI-1. However, even when exogenous inhibitor was present in the medium or purified mutant was added to plasma that had been rendered PAI-1-rich in vivo, the mutants were present in the free form exclusively judging from results of fibrin autography and Western blot analysis. Thus, despite maintenance of some residual plasminogen-activating activity associated with preservation of the hydroxyl group at the active site, the threonine mutant did not form stable complexes with inhibitor. The glycine mutant, developed so that steric hindrance or other unfavorable interactions at the modified active site would be minimal, was similarly incapable of forming complexes with PAI-1. These results show that the presence of an active site serine residue is necessary for formation of stable complexes between t-PA and PAI-1.     

15N NMR spectroscopy of hydrogen-bonding interactions in the active site of serine proteases: evidence for a moving histidine mechanism

Nitrogen-15 NMR spectroscopy has been used to study the hydrogen-bonding interactions involving the histidyl residue in the catalytic triad of alpha-lytic protease in the resting enzyme and in the transition-state or tetrahedral intermediate analogue complexes formed with phenylmethanesulfonyl fluoride and diisopropyl fluorophosphate. The 15N shifts indicate that a strong hydrogen bond links the active site histidine and serine residues in the resting enzyme in solution. This result is at odds with interpretations of the X-ray diffraction data of alpha-lytic protease and of other serine proteases, which indicate that the serine and histidine residues are too far apart and not properly aligned for the formation of a hydrogen bond. In addition, the nitrogen-15 shifts demonstrate that protonation of the histidine imidazole ring at low pH in the transition-state or tetrahedral intermediate analogue complexes formed with phenylmethanesulfonyl fluoride and diisopropyl fluorophosphate triggers the disruption of the aspartate-histidine hydrogen bond. These results suggest a catalytic mechanism involving directed movement of the imidazole ring of the active site histidyl residue.     

Identification of a conformationally distinct form of plasminogen activator inhibitor-1, acting as a noninhibitory substrate for tissue-type plasminogen activator.

Plasminogen activator inhibitor-1 (PAI-1), the primary physiological inhibitor of tissue-type plasminogen activator (t-PA) in plasma, is a serine proteinase inhibitor (serpin) that forms a 1:1 stoichiometric complex with its target proteinase leading to the formation of a stable inactive complex. The active, inhibitory form of PAI-1 spontaneously converts to a latent form that can be reactivated by protein denaturants. In the present study we have isolated another molecular form of intact PAI-1 that, in contrast with active PAI-1, does not form stable complexes with t-PA but is cleaved at the P1-P1' bond (Arg346-Met347). Other serine proteinases, e.g. urokinase-type plasminogen activator and thrombin, also cleaved this "substrate" form of PAI-1. Fluorescence spectroscopy revealed conformational differences between the latent, active, and substrate forms of PAI-1. This observation confirms our hypothesis that the three functionally different forms of PAI-1 are the consequence of conformational transitions. Thus PAI-1 may occur in three interconvertible conformations: latent, inhibitor, and substrate PAI-1. The identification of two distinct conformations of PAI-1 which interact with their target protease either as an inhibitor or as a substrate is a previously unrecognized phenomenon among the serpins. Conversion of substrate PAI-1 to its inactive degradation product may constitute a pathway for the physiological regulation of PAI-1 activity.     

Identification of serine and histidine adducts in complexes of trypsin and trypsinogen with peptide and nonpeptide boronic acid inhibitors by 1H NMR spectroscopy.

We have previously shown, in 15N NMR studies of the enzyme's active site histidine residue, that boronic acid inhibitors can form two distinct types of complexes with alpha-lytic protease. Inhibitors that are structural analogs of good alpha-lytic protease substrates form transition-state-like tetrahedral complexes with the active site serine whereas those that are not form complexes in which N epsilon 2 of the active site histidine is covalently bonded to the boron of the inhibitor. This study also demonstrated that the serine and histidine adduct complexes exhibit quite distinctive and characteristic low-field 1H NMR spectra [Bachovchin, W. W., Wong, W. Y. L., Farr-Jones, S., Shenvi, A. B., & Kettner, C. A. (1988) Biochemistry 27, 7689-7697]. Here we have used low-field 1H NMR diagnostically for a series of boronic acid inhibitor complexes of trypsin and trypsinogen. The results show that H-D-Val-Leu-boroArg and Ac-Gly-boroArg, analogs of good trypsin substrates, form transition-state-like serine adducts with trypsin, whereas the nonsubstrate analog inhibitors boric acid, methane boronic acid, butane boronic acid, and triethanolamine borate all form histidine adducts, thereby paralleling the previous results obtained with alpha-lytic protease. However, with trypsinogen, Ac-Gly-boroArg forms predominantly a histidine adduct while H-D-Val-Leu-boroArg forms both histidine and serine adducts, with the histidine adduct predominating below pH 8.0 and the serine adduct predominating above pH 8.0.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional role of proteolytic cleavage at arginine-275 of human tissue plasminogen activator as assessed by site-directed mutagenesis

Activation of the zymogen form of a serine protease is associated with a conformational change that follows proteolysis at a specific site. Tissue-type plasminogen activator (t-PA) is homologous to mammalian serine proteases and contains an apparent activation cleavage site at arginine-275. To clarify the functional consequences of cleavage at arginine-275 of t-PA, site-specific mutagenesis was performed to convert arginine-275 to a glutamic acid. The mutant enzyme (designated Arg-275----Glu t-PA) could be converted to the two-chain form by Staphylococcus aureus V8 protease but not by plasmin. The one-chain form was 8 times less active against the tripeptide substrate H-D-isoleucyl-L-prolyl-L-arginine-p-nitroanilide (S-2288), and the ability of the enzyme to activate plasminogen in the absence of fibrinogen was reduced 20-50 times compared to the two-chain form. In contrast, one-chain Arg-275----Glu t-PA has equal activity to the two-chain form when assayed in the presence of physiological levels of fibrinogen and plasminogen. Fibrin bound significantly more of the one-chain form of t-PA than the two-chain form for both the wild-type and mutated enzymes. One- and two-chain forms of the wild-type and mutated plasminogen activators slowly formed complexes with plasma protease inhibitors, although the one-chain forms showed decreased complex formation with alpha 2-macroglobulin. The one-chain form of t-PA therefore is fully functional under physiologic conditions and has an increased fibrin binding compared to the two-chain form.     

Characterization of a plasma membrane-associated plasminogen activator on thymocytes

Plasma membranes isolated from normal thymocytes of hamster and rats were found to exhibit neutral protease activity toward 125I-labeled casein. The plasma membrane-associated proteases were completely inhibited by the serine protease inhibitors, diisopropyl fluorophosphate, phenylmethylsulfonyl fluoride and p-nitrophenyl-p-guanidinobenzoate, partially inhibited by soybean trypsin inhibitor and antipain, but were only weakly inhibited by L-1-tosylamino-2-phenylethyl chloromethyl ketone. The plasma membrane-associated proteases were also completely inhibited by ZnCl2 (75--100 mu M), but they were not affected by several other divalent cations. The plasma membrane fraction contained a plasminogen activator activity which was specifically localized in this fraction. The plasma membrane-associated plasminogen activator activity was inhibited by all of the inhibitors which inhibited plasma membrane-associated proteases except L-1-tosylamido-2-phenylethyl chloromethyl ketone. Labeling of plasma membrane-associated serine esterases with [3H] diisopropyl fluorophosphate followed by separation of the proteins by sodium dodecyl sulfate polyacrylamide gel electrophoresis revealed that this fraction contained a single major 3H-labeled protein of Mr 105 000. Both the plasminogen activator and the Mr 105 000 esterase were shown to be glycoproteins by affinity chromatography on lentil lectin-Sepharose. These results indicate that the plasminogen activator of thymocytes is a glycosylated serine protease with an active site-containing subunit of Mr 105 000 which is specifically localized in the plasma membrane.     

Transforming growth factor-beta1 as a regulator of the serpins/t-PA axis in cerebral ischemia.

The tissue type plasminogen activator (t-PA) is a serine protease that is involved in neuronal plasticity and cell death induced by excitotoxins and ischemia in the brain. t-PA activity in the central nervous system is regulated through the activation of serine protease inhibitors (serpins) such as the plasminogen activator inhibitor (PAI-1), the protease nexin-1 (PN-1), and neuroserpin (NSP). Recently we demonstrated in vitro that PAI-1 produced by astrocytes mediates the neuroprotective effect of the transforming growth factor-beta1 (TGF-beta1) in NMDA-induced neuronal cell death. To investigate whether serpins may be involved in neuronal cell death after cerebral ischemia, we determined, by using semiquantitative RT-PCR and in situ hybridization, that focal cerebral ischemia in mice induced a dramatic overexpression of PAI-1 without any effect on PN-1, NSP, or t-PA. Then we showed that although the expression of PAI-1 is restricted to astrocytes, PN-1, NSP, and t-PA are expressed in both neurons and astrocytes. Moreover, by using semiquantitative RT-PCR and Western blotting, we observed that only the expression of PAI-1 was modulated by TGF-beta1 treatment via a TGF-beta-inducible element contained in the PAI-1 promoter (CAGA box). Finally, we compared the specificity of TGF-beta1 action with other members of the TGF-beta family by using luciferase reporter genes. These data show that TGF-beta and activin were able to induce the overexpression of PAI-1 in astrocytes, but that bone morphogenetic proteins, glial cell line-derived neutrophic factor, and neurturin did not. These results provide new insights into the regulation of the serpins/t-PA axis and the mechanism by which TGF-beta may be neuroprotective.     

Proteolytic activity of the Glu-plasminogen complex with fibrinogen fragment E

Glu-plasminogen interaction with fibrinogen fragment E results in the alteration of its adsorptive capacity. During this interaction in the absence of plasmin and tissue activator of plasminogen, Glu-plasminogen is transformed into a partly degraded form. Glu-plasminogen complexes with soluble and immobilized fibrinogen fragment E. contain a serine proteinase-specific activity which is inhibited by diisopropylfluorophosphate. The complexes under study are active towards fibrin and the plasmin-specific tripeptide substrate, D-Val-L-Leu-L-Lys-p-nitroanilide. It is concluded that fibrinogen fragment E induces structural changes in the enzyme molecule which eventually result in the formation of an active center.     

Exploring protein conformations in vitro and in cell with EPR distance measurements

The electron–electron double resonance (DEER) method, which provides distance distributions between two spin labels, attached site specifically to biomolecules (proteins and nucleic acids), is currently a well-recognized biophysical tool in structural biology. The most commonly used spin labels are based on nitroxide stable radicals, conjugated to the proteins primarily via native or engineered cysteine residues. However, in recent years, new spin labels, along with different labeling chemistries, have been introduced, driven in part by the desire to study structural and dynamical properties of biomolecules in their native environment, the cell. This mini-review focuses on these new spin labels, which allow for DEER on orthogonal spin labels, and on the state of the art methods for in-cell DEER distance measurements.     

Active Plasma Kallikrein Localizes to Mast Cells and Regulates Epithelial Cell Apoptosis, Adipocyte Differentiation, and Stromal Remodeling during Mammary Gland Involution

The plasminogen cascade of serine proteases directs both development and tumorigenesis in the mammary gland. Plasminogen can be activated to plasmin by urokinase-type plasminogen activator (uPA), tissue-type plasminogen activator (tPA), and plasma kallikrein (PKal). The dominant plasminogen activator for mammary involution is PKal, a serine protease that participates in the contact activation system of blood coagulation. We observed that the prekallikrein gene (Klkb1) is expressed highly in the mammary gland during stromal remodeling periods including puberty and postlactational involution. We used a variant of ecotin (ecotin-PKal), a macromolecular inhibitor of serine proteases engineered to be highly specific for active PKal, to demonstrate that inhibition of PKal with ecotin-PKal delays alveolar apoptosis, adipocyte replenishment, and stromal remodeling in the involuting mammary gland, producing a phenotype resembling that resulting from plasminogen deficiency. Using biotinylated ecotin-PKal, we localized active PKal to connective tissue-type mast cells in the mammary gland. Taken together, these results implicate PKal as an effector of the plasminogen cascade during mammary development.The plasminogen cascade of serine proteases regulates both development and tumorigenesis in the mammary gland (1, 2). The ultimate effector in this cascade, plasminogen as its active form, plasmin, is mediated by an intricate cascade of plasminogen activators and protease inhibitors. Plasminogen-deficient mice exhibit significant defects in lactational competence and post-lactational mammary gland involution (2), the process by which the differentiated, lactating gland remodels after the cessation of lactation to a state approaching that of the non-pregnant animal. The effect of plasminogen loss is exacerbated after a round of pregnancy and lactation: plasminogen-null mammary glands have poorly developed secretory alveoli during lactation, and upon involution, never fully involute. Instead, the secretory alveoli fail to regress normally. Moreover, the stroma becomes fibrotic and is cleared incompletely of partially degraded epithelial basement membrane. Because plasminogen-deficient mice largely are unable to support a second round of pregnancy and lactation (2), this suggests that the involution defect is not overcome by activities of other proteases eventually. These studies establish plasminogen as a crucial protease in normal mammary gland biology.Plasminogen is synthesized in the liver and circulates as a zymogen through blood plasma to all vascularized tissues of the body. As this expression and circulation are constant, activation of the plasminogen cascade must be controlled locally to avoid rampant tissue proteolysis. Accordingly, plasminogen can be activated to plasmin by urokinase-type plasminogen activator (uPA),² tissue-type plasminogen activator (tPA), and plasma kallikrein (3). Though tPA and uPA are efficient and well characterized plasminogen activators, studies of mice singly as well as doubly targeted for deficiency of these plasminogen activators show they do not recapitulate the mammary gland phenotype of plasminogen deficiency (4). Instead, through use of variants of ecotin, a macromolecular inhibitor for serine proteases derived from Escherichia coli, we have previously suggested that the dominant plasminogen activator for mammary stromal involution is plasma kallikrein (PKal) (4).PKal, the activated form of the zymogen prekallikrein encoded by the Klkb1 gene, is an 80-kDa serine protease that also is synthesized in the liver and circulates in plasma at about 40-50 μg/ml. PKal participates in the contact activation system of intrinsic coagulation by activating high molecular weight kininogen into bradykinin (5-8). While plasma kallikrein is so-named due to its bradykinin-generating ability, it is in fact structurally and catalytically distinct from the large family of tissue kallikreins, which activate an alternate form of bradykinin from both high and low molecular weight kininogen (9). Moreover, PKal activates plasminogen into plasmin in vitro (3), albeit less efficiently than uPA and tPA.To determine the role of PKal in plasminogen activation in vivo in mammary gland involution, we used a variant of ecotin that was engineered to be highly specific for active PKal (10). This ecotin variant, named ecotin-PKal, inhibits plasminogen activation in vivo in a model of wound healing (11). In this study, we demonstrate that inhibition of PKal significantly delays mammary gland involution.     

Intracellular localization of protein C inhibitor (PCI) and urinary plasminogen activator in renal tubular epithelial cells from humans and human PCI gene transgenic mice

Urinary plasminogen activator (uPA) is a serine protease that plays important roles in various extracellular proteolytic processes. In humans, protein C inhibitor (PCI) is known to regulate the activity of the serine proteases involved in blood coagulation, wound healing, and tumor metastasis, whereas PCI is not present in murine plasma or tissues other than the reproductive tissues. The large amount of uPA–PCI complexes found in human urine suggests that these complexes are formed in the kidneys. In the present study, we performed immunofluorescence double labeling and electron microscopic immunocytochemistry using renal tissues from humans and human PCI gene transgenic (PCI-TG) mice. In human renal tissues, PCI and uPA colocalized in the cytoplasm of renal proximal tubular epithelial cells (RPTECs), and juxtaposition of PCI and uPA immunoreactive particles was detected in the microvilli and lysosomes in the RPTECs. The intracellular distributions of PCI and uPA in the RPTECs from PCI-TG mice were similar to those observed in human RPTECs. These findings hint at the physiological roles of uPA and PCI in human kidneys, and also suggest that the PCI-TG mice will be useful for evaluating the roles of PCI in human physiological and pathological conditions.     

An inhibitor of plasminogen activation from human placenta. Purification and characterization

Placental extracts contain inhibitors of human urinary urokinase. These extracts form a heterogeneous population of complexes with 125I-urokinase that are recognizable by changes in gel filtration profile and mobility during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Treatment with reducing agents eliminated the size heterogeneity without loss of activity, thereby allowing the placental inhibitor to be purified. Active inhibitor has been isolated in apparently homogeneous form after an eight-step procedure that included salt extraction, ammonium sulfate fractionation, column chromatography on CM-cellulose, DEAE-Sepharose, and hydroxylapatite, chromatofocusing, preparative gel electrophoresis, and hydrophobic chromatography. The purified inhibitor has Mr = 47,000. The inhibitor is relatively specific for plasminogen activators since it does not inhibit the action of plasmin, factor XIIa, plasma kallikrein, or thrombin. The inhibitor forms complexes with 1:1 stoichiometry that block the active sites of urokinase (but not prourokinase) and both one- and two-chain forms of tissue plasminogen activator. The stability of these complexes in sodium dodecyl sulfate-polyacrylamide gel electrophoresis suggest that they are based on covalently bonded structures. Although both types of plasminogen activator are inhibited, the rate of interaction is significantly faster with urokinase, tissue plasminogen activator being inhibited less efficiently. The complexes formed can be dissociated by mild alkali or hydroxylamine, thereby regenerating both enzymes and inhibitor at their original molecular weights. The results suggest that the complexes are stabilized by ester-like bonds; these might involve the hydroxyl of serine at the active site of the proteases and a carboxyl group in the inhibitor.     

Expression of recombinant human plasminogen in mammalian cells is augmented by suppression of plasmin activity.

We present evidence that over-expression of human plasminogen, the precursor to the serine protease plasmin, can be cytotoxic to mammalian cells. When an expression vector containing plasminogen cDNA is transfected into baby hamster kidney cells, the number of drug-resistant colonies as well as the levels of plasminogen secreted by those colonies is lower than observed in similar transfections of other protease precursor genes. The recombinant plasminogen accumulates intracellularly as degraded NH2-terminal fragments. In contrast, a mutant of plasminogen that produces inactive plasmin (active site Ser740 changed to Ala) is synthesized by these cells as a full-length plasminogen molecule, and the colony numbers and expression levels are normal. Thus, the generation of plasmin activity is responsible for the cytotoxic phenomena and the degradation associated with plasminogen expression. In addition, experiments using a plasminogen mutant that cannot be activated to plasmin (activation cleavage site Arg560 to Gly) or using coexpression of antisense urokinase RNA indicate that an endogenous plasminogen activator is responsible for converting newly synthesized plasminogen to plasmin. Finally, coexpression of plasminogen with alpha 2-plasmin inhibitor, a serpin which is the physiologic inhibitor of plasmin, prevents the toxic effects of intracellular plasmin activity and allows the synthesis and secretion of native human plasminogen.     

Purification from human milk of matriptase complexes with secreted serpins: mechanism for inhibition of matriptase other than HAI-1

Matriptase, a type 2 transmembrane serine protease, is predominately expressed by epithelial and carcinoma cells in which hepatocyte growth factor activator inhibitor 1 (HAI-1), a membrane-bound, Kunitz-type serine protease inhibitor, is also expressed. HAI-1 plays dual roles in the regulation of matriptase, as a conventional protease inhibitor and as a factor required for zymogen activation of matriptase. As a consequence, activation of matriptase is immediately followed by HAI-1-mediated inhibition, with the activated matriptase being sequestered into HAI-1 complexes. Matriptase is also expressed by peripheral blood leukocytes, such as monocytes and macrophages; however, in contrast to epithelial cells, monocytes and macrophages were reported not to express HAI-1, suggesting that these leukocytes possess alternate, HAI-1-independent mechanisms regulating the zymogen activation and protease inhibition of matriptase. In the present study, we characterized matriptase complexes of 110 kDa in human milk, which contained no HAI-1 and resisted dissociation in boiling SDS in the absence of reducing agents. These complexes were further purified and dissociated into 80-kDa and 45-kDa fragments by treatment with reducing agents. Proteomic and immunological methods identified the 45-kDa fragment as the noncatalytic domains of matriptase and the 80-kDa fragment as the matriptase serine protease domain covalently linked to one of three different secreted serpin inhibitors: antithrombin III, 1-antitrypsin, and 2-antiplasmin. Identification of matriptase-serpin inhibitor complexes provides evidence for the first time that the proteolytic activity of matriptase, from those cells that express no or low levels of HAI-1, may be controlled by secreted serpins. protease; type 2 transmembrane serine protease; protease inhibitor; ST-14; hepatocyte growth factor activator inhibitor 1     

Serine and cysteine proteases are translocated to similar extents upon formation of covalent complexes with serpins. Fluorescence perturbation and fluorescence resonance energy transfer mapping of the protease binding site in CrmA complexes with granzyme B and caspase-1

CrmA is a "cross-class" serpin family inhibitor of the proapoptotic serine protease, granzyme B, as well as cysteine proteases of the caspase family. To determine whether crmA inhibits these structurally diverse proteases by a common conformational trapping mechanism, we mapped the position of the protease in crmA complexes with granzyme B or caspase-1 by fluorescence perturbation and fluorescence resonance energy transfer (FRET) analyses of site-specific fluorophore-labeled crmAs. A reactive loop P6 NBD label underwent similar large fluorescence enhancements (>200%) either upon reactive loop cleavage by AspN protease or complex formation with granzyme B or caspase-1, consistent with the insertion of the cleaved reactive loop into sheet A in both types of crmA-protease complexes. NBD labels on the noninserting part of the reactive loop docking site for protease (P1' residue) or midway between the two ends of sheet A (helix F residue 101) showed no significant perturbations due to protease complexation. By contrast, labels at positions 68 and 261, lying at the end of sheet A most distal from the reactive loop, showed marked perturbations distinct from those induced by AspN cleavage and thus ascribable to granzyme B or caspase-1 proximity in the complexes. Substantial FRET between protease tryptophans and 5-dimethylaminonaphthalene-1-sulfonyl-labeled crmAs occurred in protease complexes with crmAs labeled at the 68 and 261 positions, but not the P1' position. These results suggest that granzyme B and caspase-1 are inhibited by crmA by a common mechanism involving full reactive loop insertion into sheet A and translocation of the protease to the distal end of the sheet as previously found for inhibition of other serine proteases by serpins.     

Spin-labeling of porcine pepsin and rhizopus chinensis acid protease by diazoketone reagents

The active site of porcine pepsin and that of rhizopus chinensis acid protease were labeled with diazoketone type spin labels, 4-(3-diazo-2-oxopropylidene)-2,2,6,6-tetramethylpiperidine-1-oxyl (I) and 3-(4-diazo-3-oxo-cis-1-butenyl)-2,2,5,5-tetramethylpyrroline-1-oxyl (II), respectively. The values of τ_c showed that the nitroxide motion was only slightly restricted in the I bound enzymes. The trans isomer of II bound to another site of the enzymes. Addition of pepstatin reduced the nitroxide motion in all the labeled enzymes.