Host cell factor requirement for hepatitis C virus enzyme maturation.

The cellular chaperone, HSP90, is identified here as an essential factor for the activity of NS2/3 protease of hepatitis C virus. The cleavage activity of NS2/3 protease synthesized in reticulocyte lysate is ATP-dependent, as evidenced by ATP depletion experiments and inhibition with nonhydrolyzable ATP analogs. Geldanamycin and radicicol, ATP-competitive inhibitors of the chaperone HSP90, also inhibit the cleavage of in vitro-synthesized NS2/3. Furthermore, these HSP90 inhibitors prevent NS2/3 cleavage when the protease is expressed in mammalian cells. The physical association of NS2/3 with HSP90 is demonstrated by immunoprecipitation. Thus, by way of a chaperone/folding activity, an HSP90-containing complex is required for maturation of the polyprotein that encodes the enzymes essential for hepatitis C virus replication.

Inhibition of hepatitis C virus NS2/3 processing by NS4A peptides. Implications for control of viral processing.

The NS2/3 protease of hepatitis C virus is responsible for a single cleavage in the viral polyprotein between the nonstructural proteins NS2 and NS3. The minimal protein region necessary to catalyze this cleavage includes most of NS2 and the N-terminal one-third of NS3. Autocleavage reactions using NS2/3 protein translated in vitro are used here to investigate the inhibitory potential of peptides likely to affect the reaction. Peptides representing the cleaved sequence have no effect upon reaction rates, and the reaction rate is insensitive to dilution. Both results are consistent with prior suggestions that the NS2/3 cleavage is an intramolecular reaction. Surprisingly, peptides containing the 12-amino acid region of NS4A responsible for binding to NS3 inhibit the NS2/3 reaction with K(i) values as low as 3 microM. Unrelated peptide sequences of similar composition are not inhibitory, and neither are peptides containing incomplete segments of the NS4A region that binds to NS3. Inhibition of NS2/3 by NS4A peptides can be rationalized from the organizing effect of NS4A on the N terminus of NS3 (the NS2/3 cleavage point) as suggested by the known three-dimensional structure of the NS3 protease domain (Yan, Y., Li, Y., Munshi, S., Sardana, V., Cole, J. L., Sardana, M., Steinkuhler, C., Tomei, L., De Francesco, R., Kuo, L. C., and Chen, Z. (1998) Protein Sci. 7, 837-847). These findings may imply a sequential order to proteolytic maturation events in hepatitis C virus.

Activation of the multicatalytic endopeptidase by oxidants. Effects on enzyme structure.

It is well established that the functional properties of proteins can be compromised by oxidative damage and, in vivo, proteins modified by oxidants are rapidly degraded. It was hypothesized that oxidants may also affect the ability of proteases to hydrolyze peptides and proteins. We therefore examined the effect of oxidants on the endopeptidase activities of the 650 kDa 20S proteasome or multicatalytic endopeptidase (MCP), which is thought to play a central role in nonlysosomal protein breakdown. Treatment of the MCP with the oxidant system, FeSO4-EDTA-ascorbate, stimulated the peptidase activities of the MCP while H2O2 treatment showed little or no stimulation. However, treatment of the MCP with FeSO4-EDTA-ascorbate or H2O2 stimulated proteinase activity by 480% and 730%, respectively. An endogenous activator of the MCP, PA28, stimulated the acidic, basic, and hydrophobic peptidase activities of the MCP, but had no effect on proteolytic activity. Treatment of PA28 with oxidants in the presence of MCP or alone did not greatly affect PA28's ability to activate the peptidase activities of the MCP. Using nondenaturing polyacrylamide gel electrophoresis, structural alterations in the enzyme which may be responsible for the activation of peptidase and protease activities following exposure to oxidants were investigated. Treatment of the MCP with reagents that activate proteolysis, including H2O2, as well as the serine protease inhibitor 3,4-dichloroisocoumarin and the cysteine protease inhibitor p-(chloromercuri) benzenesulfonic acid, all caused dissociation of the 650 kDa MCP. However, exposure to FeSO4-EDTA-ascorbate resulted in little or no dissociation of the complex. The MCP complex dissociated by p-(chloromercuri) benzenesulfonic acid could be reassociated upon treatment with the reducing agent dithiothreitol, but dithiothreitol failed to completely reassociate 3,4-dichloroisocoumarin- or H2O2 treated MCP. Therefore, chemical modification of the MCP can cause activation with varying degrees of complex dissociation. These results suggest that metabolites, such as reactive oxygen species, in addition to endogenous proteins, such as PA28, are capable of modulating MCP activity.

The subcellular distribution of eukaryotic translation initiation factor, eIF-5A, in cultured cells.

To gain insight into the role of the eukaryotic translation initiation factor, eIF-5A, we investigated the subcellular distribution of this protein in several cultured cell types and at different stages of the cell cycle using a highly potent monospecific polyclonal antibody to eIF-5A. Studies using indirect immunofluorescence and confocal microscopy in conjunction with subcellular fractionation demonstrate that eIF-5A is primarily localized in the cytoplasm of cells. This cytoplasmic location of eIF-5A is not significantly altered in different stages of the cell cycle and the subcellular distribution pattern of eIF-5A is not changed by viral oncogene transformation. Cell fractionation experiments identified two populations of eIF-5A in the cytoplasm, a soluble fraction and a fraction bound to internal membranes. By double immunofluorescence staining with an antibody against calnexin, a resident protein of the endoplasmic reticulum (ER), we demonstrate that the membrane-bound fraction of eIF-5A colocalizes with the ER and not with the cytoskeleton. Expression of Rev, a regulatory protein of human immunodeficiency virus type 1 (HIV-1), does not alter the subcellular distribution of endogenous eIF-5A in these cells. eIF-5A is detected in all tissues and cells examined including extracts prepared from Xenopus oocytes. Our results indicate that eIF-5A is a ubiquitous cytoplasmic protein and suggest that a site of eIF-5A function is likely to be in association with the ER.

ATP-stimulated degradation of oxidatively modified superoxide dismutase by cathepsin D in cardiac tissue extracts.

Proteins modified by oxidants are rapidly degraded by intracellular proteases. Oxidatively modified superoxide dismutase (Ox-SOD) was degraded 2-8 times faster at both acidic and alkaline pH than the native protein in bovine cardiac tissue extracts. At acidic pH, Ox-SOD hydrolysis was stimulated by ATP and by non-hydrolyzable ATP analogs by up to 50%, but degradation was not stimulated by ATP at alkaline pH. The aspartic protease inhibitor pepstatin completely inhibited the acid Ox-SOD hydrolyzing activity and its stimulation by ATP. This activity eluted from gel filtration with a molecular size of 34-48 kDa and contained the single chain and two mature forms of cathepsin D. Purified cathepsin D degraded Ox-SOD and ATP enhanced the affinity of cathepsin D for oxidatively modified proteins. Thus cardiac tissue proteins modified by oxidants may be substrates for the lysosomal protease cathepsin D.

Effects of N1-guanyl-1,7-diaminoheptane, an inhibitor of deoxyhypusine synthase, on the growth of tumorigenic cell lines in culture.

N1-guanyl-1,7-diaminoheptane (GC7) is a potent inhibitor of deoxyhypusine synthase (DHS), the enzyme that catalyzes the first step in the hypusination of eukaryotic translation initiation factor 5A (eIF-5A). Since eIF-5A is the only known cellular substrate for DHS and GC7 has been reported to block the proliferation of CHO cells, it has been suggested that DHS may be a novel target for anti-cancer therapy. In the present study we investigated the antiproliferative effect of GC7 on several tumorigenic cell lines under various growth conditions. We found that this compound inhibits the proliferation of H9 cells in suspension culture and the growth of HeLa cells and v-src-transformed NIH3T3 cells under both anchorage-dependent and anchorage-independent conditions. Moreover, studies with NIH3T3 cells and v-src-transformed NIH3T3 cells show that GC7 inhibits the growth of both cell lines in monolayer culture with similar potency and could not reverse the transformed phenotype. In addition, the v-src-transformed cells grown under both anchorage-dependent and anchorage-independent conditions showed similar sensitivity toward GC7. These data indicate that GC7 acts as a general antiproliferative agent and does not appear to preferentially target tumorigenic cell types. Cell cycle analysis show that GC7 reduces the CHO-K1 cell population in the G1-phase of the cell cycle by 42% and increases the number of cells in the S-phase by 44%. This cell cycle distribution profile strikingly resembles the distribution of cells treated with puromycin. This result supports the hypothesis that the synthesis of a subset of proteins important for the S-phase progression of CHO-K1 cells might be dependent upon hypusinated eIF-5A. Thus the antiproliferative effect of GC7 appears to be related to its interference with the progression of cell cycle, which also provides a possible explanation for the lack of selectivity of GC7 between nontransformed and transformed cell types tested in this study.

Spectroscopic characterization of tick anticoagulant peptide.

Tick anticoagulant peptide (TAP) is a disulfide rich potent inhibitor of factor Xa. Although this peptide is of potential clinical utility, very little is known about its higher order structure. Therefore, the secondary structure of recombinant TAP (rTAP) has been examined by circular dichroism (CD) and Fourier transform infrared (FTIR) spectroscopy. Both techniques suggest that rTAP is rich in beta-sheet structure. Disulfide bonds play a significant role in the folding and structural stability of rTAP. This is apparent from the resistance of rTAP to fluorescence-detected unfolding by guanidinium chloride (Gdn-HCl), unless disulfides are first reduced. The protein's tryptophan and tyrosine residues exhibit greater solvent exposure upon reduction of the cystines as indicated by fluorescence spectra and second derivative UV spectroscopy. A considerable amount of beta-structure appears to be retained after reduction of disulfides, although the CD spectrum manifests an increased amount of disordered structure in the reduced peptide. While rTAP does not bind the hydrophobic fluorescence probe 2-p-toludinylnaphthalene-6-sulfonate (TNS) at neutral or acidic pH, the reduced peptide binds TNS at pH 2.0 but not at pH 7.0. The secondary structure of the reduced peptide at pH 2 is, however, similar to that at pH 7 as judged by CD spectroscopy. The reduced form of rTAP at acidic pH thus resembles a molten globule-like state.

Identification and characterization of endothelin converting activity from EAHY 926 cells: evidence for the physiologically relevant human enzyme.

A neutral proteolytic activity that converts human Big endothelin-1 (Big Et-1) to endothelin-1 has been identified from a human endothelial hybrid cell line, EAHY 926. This enzyme is an integral membrane protein and cofractionates with other enzymes typically found in the plasma membrane. The activity has been solubilized with nonionic detergents and purified 1000-fold by a combination of lectin affinity chromatography, ion-exchange chromatography, and chromatography on red-dye agarose. The partially purified activity is a metalloenzyme based upon its sensitivity to chelating agents, competitive inhibition by phosphoramidon, and reconstitution with ZnCl2 or CoCl2 following EDTA inactivation. The enzyme appears to be unique, however, as it is not inhibited by specific inhibitors of known metalloproteases. It correctly processes Big Et-1 to Et-1 and the complementary C-terminal fragment with a sharp pH optimum near 7.0. Both the Km for Big Et-1 and the Ki for phosphoramidon are pH-dependent, with values of 5-7 and 3.5 microM, respectively, at pH 7.0. The enzyme also cleaves Big Et-2 with a Km of 27.9 microM and a Vmax one-third that for Big Et-1 but has no appreciable activity toward Big Et-3. An s20,w of 9.5 S was determined by sucrose density ultracentrifugation in H2O and D2O. When combined with a Stokes radius of 56 A determined by gel filtration, the enzyme had a calculated apparent molecular weight of 250,000. Conditions have been established to renature the activity after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Under nonreducing conditions activity was detected in a protein band at 280 kDa, in agreement with the aforementioned molecular weight determination. From these results, a kcat/Km of 1 x 10(6) M-1 s-1 was estimated for the purified enzyme with Big Et-1 as a substrate, which is a reasonable value for a protease acting upon its physiologic substrate. Several criteria indicate that the activity isolated from EAHY cells is the physiologically relevant endothelial-derived endothelin converting enzyme. On the basis of our results, this enzyme is present in low abundance in endothelial cells and at least a 100,000-fold purification will be required to obtain a homogeneous preparation. However, because EAHY cells can be grown in large numbers, they can supply the quantities of enzyme required both for biochemical studies and for the development of specific inhibitors.

Site-directed analysis of the functional domains in the factor Xa inhibitor tick anticoagulant peptide: identification of two distinct regions that constitute the enzyme recognition sites.

Recombinant tick anticoagulant peptide (rTAP) is a highly selective inhibitor of blood coagulation factor Xa. rTAP has been characterized kinetically as a slow, tight-binding, competitive inhibitor of the enzyme. We used an approach consisting of both recombinant, site-directed mutagenesis and solid-phase chemical synthesis to generate 31 independent mutations in rTAP to identify those regions of the molecule which contribute to the specific, high-affinity binding interaction with factor Xa. Our results demonstrate that the four amino-terminal residues of rTAP constitute the primary recognition determinant necessary for the formation of the high-affinity enzyme-inhibitor complex. The Arg residue in position three is probably not interacting with the S1-specificity pocket of factor Xa in a substrate-like manner since substitution at this position with a D-Arg amino acid produced only a modest decrease in affinity (5-fold). An additional domain in the rTAP molecule located between residues 40 and 54 was identified as a probable secondary binding determinant. Interestingly, this region in rTAP shares significant amino acid sequence homology with a sequence in prothrombin immediately amino-terminal to the factor Xa cleavage site that generates meizothrombin. These observations indicate that specific segments within two different regions of the rTAP molecule contribute to the potent binding interaction between rTAP and factor Xa.

The ATP-independent pathway in red blood cells that degrades oxidant-damaged hemoglobin.

Studies were carried out to characterize further the cytoplasmic ATP- and ubiquitin-independent proteolytic system in red blood cells that degrades hemoglobin damaged by exposure to oxidants (Fagan, J. M., Waxman, L., and Goldberg, A. L. (1986) J. Biol. Chem. 261, 5705-5713). Several proteases were ruled out as having a major role in the degradation of oxidant-treated hemoglobin (Ox-Hb). Acid hydrolases are not active in this process since the degradation of Ox-Hb has a pH optimum between 6 and 8. The calpains are also not involved since inhibitors of cysteine proteases (leupeptin and trans-epoxysuccinyl-L-leucylamido-(3-methyl)butane) did not diminish the increased proteolysis in intact erythrocytes treated with oxidants or in lysates to which Ox-Hb was added. The degradation of Ox-Hb was unaffected by inhibitors of serine and aspartic proteases. Removal of the high M(r) multicatalytic proteinase by immunoprecipitation also did not significantly affect the degradation of Ox-Hb in erythrocyte lysates. The degradation of Ox-Hb was sensitive to metal chelators and sulfhydryl-modifying reagents but not to specific inhibitors of known metalloproteases. Insulin, which is rapidly degraded in lysates, completely blocked the degradation of Ox-Hb. Insulin- and Ox-Hb-hydrolyzing activity was also inhibited following immunoprecipitation of the 100-kDa metalloinsulinase. The metalloinsulinase, which is inhibited by sulfhydryl-modifying reagents and which requires divalent metals, may therefore participate in the degradation of hemoglobin damaged by oxidants in erythrocytes.

Comparison of the multicatalytic proteinases isolated from the nucleus and cytoplasm of chicken red blood cells.

1. Two chromatographically distinct multicatalytic proteinases (MCP's) were isolated from the cytoplasm of chicken red blood cells and one MCP was purified from the nuclei. 2. The nuclear and the majority (97-99%) of the cytoplasmic multicatalytic proteolytic activity were chromatographically similar and differed from the minor cytoplasmic activity in their elution from hydroxylapatite, number of subunits on 2D-SDS-PAGE, and in their sensitivity to proteinase inhibitors. 3. Dichloroisocoumarin, a serine proteinase inhibitor, inhibited the hydrolysis of fluorogenic peptides but stimulated the degradation of casein by the multicatalytic proteinases suggesting that this enzyme has distinct active sites for protein and peptide hydrolysis.

ATP depletion stimulates calcium-dependent protein breakdown in chick skeletal muscle.

The contribution of metabolic energy to the degradation of intracellular proteins in skeletal muscle was investigated. Isolated chick skeletal muscles deprived of oxygen and muscles incubated in buffer under nonphysiological conditions containing inhibitors of glycolysis and mitochondrial respiration had lower concentrations or undetectable levels of ATP and faster rates of proteolysis. Both total protein breakdown and the breakdown of myofibrillar proteins were stimulated 35-124% in ATP-depleted tissues. However, ATP-depleted muscles incubated in buffer to which no Ca2+ was added showed slower rates of total protein breakdown and no significant change in myofibrillar proteolysis compared with control muscles. Trans-epoxysuccinyl-L-leucylamido(4-guanidino)butane (E-64), a compound that inhibits the calpains and the lysosomal cysteine proteases, completely blocked the Ca(2+)-stimulated breakdown of nonmyofibrillar and myofibrillar proteins in ATP-depleted muscles. However, Ca(2+)-stimulated proteolysis was not inhibited in ATP-depleted muscles incubated with weak bases to prevent lysosome function. These data suggest that intracellular proteins can be degraded in skeletal muscle in the absence of metabolic energy and that the calpains play a major role in the enhanced proteolysis in skeletal muscles depleted of ATP.

Purification of a protease in red blood cells that degrades oxidatively damaged haemoglobin.

Haemoglobin damaged by exposure of red blood cells to oxidants is rapidly degraded by a proteolytic pathway which does not require ATP [Fagan, Waxman & Goldberg (1986) J. Biol. Chem. 261, 5705-5713]. By fractionating erythrocyte lysates, we have purified two proteases which hydrolyse oxidatively damaged haemoglobin (Ox-Hb). One protease hydrolysed small fluorogenic substrates in addition to Ox-Hb. Its molecular mass was approximately 700 kDa and it consisted of several subunits ranging in size from 22 to 30 kDa. This enzyme may be related to the high-molecular-mass multicatalytic proteinase previously isolated from a variety of tissue and cell types. The other Ox-Hb-degrading activity had an apparent molecular mass of 400 kDa on gel filtration, a subunit size of 110 kDa and an isoelectric point between 4.5 and 5.0. This protease also hydrolysed the small polypeptides insulin and glucagon, as well as other large proteins such as lysozyme. Insulin blocked the degradation of Ox-Hb and Ox-Hb blocked the hydrolysis of insulin by the purified protease. Thiol reagents and metal chelators strongly inhibited the hydrolysis of both Ox-Hb and insulin, whereas inhibitors of serine, aspartic and thiol proteases had little effect. These properties suggest that the Ox-Hb-degrading activity purified from rabbit erythrocytes is the cytosolic insulin-degrading enzyme that is believed to play a role in the metabolism of insulin in several tissues. We propose that this enzyme may also function as a key component in a cytoplasmic degradative pathway responsible for removing proteins damaged by oxidants.

Identification of a soluble enzyme from C3H/10T1/2 cells which is inhibited by the Bowman-Birk proteinase inhibitor.

The anticarcinogenic Bowman-Birk proteinase inhibitor (BBI) inhibits a 70-kDa serine proteinase in C3H/10T1/2 transformed fibroblasts. Two serine proteinases, the proline endopeptidase and a novel neutral proteolytic activity, both having a mass of approximately 70-kDa, were isolated from the cytoplasm of C3H/10T1/2 cells. BBI did not inhibit diisopropylfluorophosphate binding to the proline endopeptidase or its ability to hydrolyze peptides. However, BBI blocked the binding of diisopropylfluorophosphate and inhibited the cleavage of peptides by the novel cytoplasmic enzyme. Thus BBI does not inhibit the proline endopeptidase but another soluble 70-kDa serine proteinase from C3H/10T1/2 cells.

Determination of disulfide bond pairs and stability in recombinant tick anticoagulant peptide.

Tick anticoagulant peptide (TAP) is a potent and selective inhibitor of blood coagulation factor Xa (Waxman, L., Smith, D.E., Arcuri, K.E., and Vlasuk, G.P. (1990) Science 248, 593-596). The 60-amino acid sequence of TAP shows limited homology to Kunitz-type inhibitors, including cysteines at positions 5, 15, 33, 39, 55, and 59. For detailed biochemical and pharmacological studies, a recombinant version of TAP (rTAP) has been produced in yeast. To determine the arrangement of the disulfide bonds, rTAP was cleaved with trypsin and chymotrypsin and the purified peptides sequenced using a gas-phase sequenator. The positions of the disulfide bonds were assigned by identifying the cycle(s) at which di-phenylthiohydan-toin-cystine was released. The specific disulfide bridges, Cys-5 to Cys-59, Cys-15 to Cys-39, and Cys-33 to Cys-55, are analogous to those in the prototype Kunitz-type inhibitor, bovine pancreatic trypsin inhibitor (BPTI). While treatment of BPTI with dithiothreitol rapidly and specifically reduced one disulfide bond, the reduction of disulfide bonds in rTAP proceeded at a slower rate and appeared to be nonspecific, reaching a maximum of two disulfides reduced. Reduced rTAP derivatized with either iodoacetic acid or iodoacetamide lost 59% of its inhibitory activity. In contrast, BPTI alkylated with iodoacetic acid inhibited trypsin half as well as the iodoacetamide derivative. Although the arrangement of disulfides in the two inhibitors is the same, their susceptibility to reduction is markedly different.

Purification of the multicatalytic proteinase from the nucleus and cytoplasm of chicken red blood cells.

We have purified the multicatalytic proteinase from the nucleus and cytoplasm of chicken red blood cells. Both enzymes have an Mr of 700 kDa and can be separated into 8-10 bands (22-32 kDa) on 1D-SDS-PAGE.

Tick anticoagulant peptide: kinetic analysis of the recombinant inhibitor with blood coagulation factor Xa.

Tick anticoagulant peptide (TAP) is a 60 amino acid protein which is a highly specific inhibitor of human blood coagulation factor Xa (fXa) isolated from the tick Ornithodoros moubata [Waxman, L., Smith, D. E., Arcuri, K. E., & Vlasuk, G. P. (1990) Science 248, 593-596]. Due to the limited quantities of native TAP, a recombinant version of TAP produced in Saccharomyces cerevisiae was used for a detailed kinetic analysis of the inhibition interaction with human fXa. rTAP was determined to be a reversible, slow, tight-binding inhibitor of fXa, displaying a competitive type of inhibition. The binding of rTAP to fXa is stoichiometric with a dissociation constant of (1.8 +/- 0.02) x 10(-10) M, a calculated association rate constant of (2.85 +/- 0.07) x 10(6) M-1 s-1, and a dissociation rate constant of (0.554 +/- 0.178) x 10(-3) s-1. Binding studies show that 35S-rTAP binds only to fXa and not to DFP-treated fXa or zymogen factor X, which suggests the active site of fXa is required for rTAP inhibition. That rTAP is a unique serine proteinase inhibitor is suggested both by its high specificity for its target enzyme, fXa, and also by its unique structure.

Characterization of recombinant tick anticoagulant peptide. A highly selective inhibitor of blood coagulation factor Xa.

Tick anticoagulant peptide (TAP) is a potent, highly selective inhibitor of blood coagulation factor Xa (Waxman, L., Smith, D. E., Arcuri, K. E., and Vlasuk, G. P. (1990) Science, 248, 593-596). Further detailed studies pertaining to the in vitro and in vivo evaluation of TAP require quantities of the inhibitor which cannot be isolated from ticks. To overcome this limitation we describe here the characterization of recombinant TAP (rTAP) secreted by Saccharomyces cerevisiae. Expression of rTAP was obtained using a chimeric gene containing a fusion between sequences encoding the secretory preproleader of the yeast mating pheromone alpha-factor and a synthetic sequence encoding the 60-amino acid inhibitor under the transcriptional control of a galactose-inducible promoter. Recombinant S. cerevisiae were found to secrete biologically active rTAP into the extracellular medium at levels of 0.1-0.15 g/liter. The secreted inhibitor was purified to homogeneity and found to be indistinguishable from the native inhibitor with respect to several criteria, including primary structure, amino acid composition, and electrophoretic mobility. In addition, purified rTAP and native TAP exhibited similar stoichiometric inhibition of factor Xa in vitro. The in vivo efficacy of rTAP was demonstrated using a model of low grade disseminated intravascular coagulation where the purified inhibitor was shown to significantly inhibit thromboplastin-induced fibrinopeptide A generation following an infusion into conscious rhesus monkeys. The availability of rTAP will allow a detailed evaluation of the in vitro and in vivo properties of this highly specific and potent factor Xa inhibitor.

Tick anticoagulant peptide (TAP) is a novel inhibitor of blood coagulation factor Xa.

A low molecular weight serine protease inhibitor (TAP) was purified from extracts of the soft tick, Ornithodoros moubata. The peptide is a slow, tight-binding inhibitor, specific for factor Xa (Ki = 0.588 +/- 0.054 nM). The inhibitor also acts as an anticoagulant in several human plasma clotting assays in vitro. Its amino acid sequence (60 residues) has limited homology to the Kunitz-type inhibitors. However, unlike other inhibitors of this class, TAP inhibits only factor Xa. It had no effect at a 300-fold molar excess on factor VIIa, kallikrein, trypsin, chymotrypsin, thrombin, urokinase, plasmin, tissue plasminogen activator, elastase, or Staphylococcus aureus V8 protease. TAP's specificity and size suggest that it may have therapeutic value as an anticoagulant.

A novel ATP-requiring protease from skeletal muscle that hydrolyzes non-ubiquitinated proteins.

Previously, we isolated an ATP-dependent proteolytic pathway in muscle, liver, and reticulocytes that requires ubiquitin and the enzymes which conjugate ubiquitin to proteins. We report here that skeletal muscle contains another soluble alkaline energy-dependent (but ubiquitin-independent) proteolytic activity. The cleavage of non-ubiquitinated protein substrates by the partially purified protease requires ATP hydrolysis since ATP in the absence of Mg2+, nonhydrolyzable ATP analogs, and pyrophosphate all fail to stimulate proteolysis. Proteolytic activity is also stimulated by UTP, CTP, and GTP, although not as effectively as by ATP (Km(ATP) = 0.027 mM). The enzyme is inactivated by the serine protease inhibitors diisopropyl fluorophosphate and 3,4-dichloroisocoumarin, but not by specific inhibitors of aspartic, thiol, or metalloproteases. It is maximally active at pH 8 and has a molecular weight of approximately 600,000. This new activity differs from the 720-kDa multicatalytic proteinase, but resembles the soluble ATP-dependent proteolytic system that we previously isolated from murine erythroleukemia cells.