Immunological identity of heparin-dependent plasma and urinary protein C inhibitor and plasminogen activator inhibitor-3

Purified plasma and urinary protein C inhibitors (PCI) formed heparin-dependent complexes with activated protein C (APC) which were detected by immunoblotting after nondenaturing gel electrophoresis. Bands representing APC.PCI complexes were also seen on immunoblots after incubation of plasma with APC and heparin. The same immunoblot pattern of complexes was detected by three different methods: method A, monoclonal antibody to plasminogen activator inhibitor-3 (PAI-3, urinary urokinase inhibitor) + 125I-labeled anti-mouse IgG; method B, polyclonal antibodies to PCI + 125I-labeled purified plasma PCI; and method C, monoclonal antibody to protein C + 125I-protein C. Plasma depleted of PAI-3 by immunoadsorption with insolubilized monoclonal antibody to PAI-3 showed no detectable antigen or complexes with APC as visualized by methods A or B. This PAI-3-depleted plasma had less than 10% of the heparin-dependent inhibitory activity of normal plasma toward APC. Purified plasma PCI was fully reactive in an enzyme-linked immunoabsorbent assay for PAI-3, and plasma and urinary PCI inhibited urokinase activity in a heparin-dependent manner. These data indicate that heparin-dependent plasma and urinary PCI and PAI-3 are immunologically and functionally very similar if not identical. This observation identifies a new interrelation between the protein C anticoagulant and the fibrinolytic systems. In addition, plasma contains a heparin-independent inhibitor of APC which is not immunologically related to plasma PCI or to PAI-3.     

A new and simple isolation procedure for human protein C inhibitor. Evidence for a second inhibitor for activated protein C present in human plasma

Human plasma contains an inhibitor of activated protein C (APC) which is termed according to its function protein C inhibitor (PCI). High purification of functionally active PCI with a yield of 18% is achieved by an improved procedure consisting of 4 steps: precipitation by rivanol, fractionation with ammonium sulfate, ion-exchange chromatography on DEAE Sephacel and chromatography on dextran sulfate Sepharose. This purification results in the isolation of a homogeneous PCI which migrates in immunoelectrophoresis with the beta-globulins of human plasma and in SDS PAGE as one single band at Mr = 57,000 both under reducing and nonreducing conditions. The specific activity of the highly purified PCI was determined to be 226 units/mg, 1 unit being equivalent to the activity of 1 ml fresh human citrated plasma. PCI forms complexes with 1:1 stoichiometry (Ki: 1.4 x 10(-8) M) resulting in a loss of the amidolytic activity of APC as measured on Tos-Glu-Pro-Arg-pNA (S 2366). The inhibition rate of APC by PCI (k: 7.5 x 10(5) M-1 min-1) is significantly increased in the presence of 5 i.u./ml heparin (kH: 2.2 x 10(7) M-1 min-1). PCI also blocks the amidolytic activities of urokinase plasminogen activator (u-PA), thrombin and factor Xa on their chromogenic substrates in a heparin-dependent manner. According to the Ki-values measured for these reactions PCI is a noncompetitive inhibitor of these proteases. The Ki-values calculated do not differ significantly from those obtained for the inhibition of APC by PCI. Immunodepleted PCI-deficient plasma still contains an inhibitory activity against APC which, however, only slowly inactivates the amidolytic activity of APC and in a time and concentration-dependent manner. Addition of heparin has no influence on the inhibition rate. This finding suggests the existence of a second, heparin-independent PCI present in human plasma.     

Platelet plasminogen activator inhibitor: purification and characterization of interaction with plasminogen activators and activated protein C

Plasminogen activator inhibitor (PAI) was purified in active form from porcine platelets under nondenaturing conditions. The purified inhibitor (Mr 47,000) reacts with tissue-type plasminogen activator (t-PA), urokinase (UK), and activated protein C (APC) to yield both SDS-stable complexes and a modified PAI of slightly reduced molecular weight. The second-order rate constants for the inhibition of t-PA and UK by PAI are 3.5 X 10(7) and 3.4 X 10(7) M-1 s-1, respectively. Activated protein C reacts with PAI with a second-order rate constant of 1.1 X 10(4) M-1 s-1. This rate is not accelerated by protein S, phospholipid, and calcium, or heparin. It is concluded that (1) PAI can function as both inhibitor and substrate of its target proteases, (2) if APC promotes fibrinolysis via inactivation of PAI, then APC must be present in concentrations several orders of magnitude greater than t-PA, or the interaction of APC and PAI must be accelerated by presently unknown mechanisms, and (3) in the absence of heparin, platelet PAI is the most rapid inhibitor of APC yet described.     

Structural and energetic characteristics of the heparin-binding site in antithrombotic protein C

Human activated protein C (APC) is a key component of a natural anticoagulant system that regulates blood coagulation. In vivo, the catalytic activity of APC is regulated by two serpins, alpha1-antitrypsin and the protein C inhibitor (PCI), the inhibition by the latter being stimulated by heparin. We have identified a heparin-binding site in the serine protease domain of APC and characterized the energetic basis of the interaction with heparin. According to the counter-ion condensation theory, the binding of heparin to APC is 66% ionic in nature and comprises four to six net ionic interactions. To localize the heparin-binding site, five recombinant APC variants containing amino acid exchanges in loops 37, 60, and 70 (chymotrypsinogen numbering) were created. As demonstrated by surface plasmon resonance, reduction of the electropositive character of loops 37 and 60 resulted in complete loss of heparin binding. The functional consequence was loss in heparin-induced stimulation of APC inhibition by PCI, whereas the PCI-induced APC inhibition in the absence of heparin was enhanced. Presumably, the former observations were due to the inability of heparin to bridge some APC mutants to PCI, whereas the increased inhibition of certain APC variants by PCI in the absence of heparin was due to reduced repulsion between the enzymes and the serpin. The heparin-binding site of APC was also shown to interact with heparan sulfate, albeit with lower affinity. In conclusion, we have characterized and spatially localized the functionally important heparin/heparan sulfate-binding site of APC.     

Inhibition of tissue kallikrein by protein C inhibitor. Evidence for identity of protein C inhibitor with the kallikrein binding protein.

We studied the inhibition of tissue kallikrein by protein C inhibitor (PCI), a relatively unspecific heparin-dependent serine protease inhibitor present in plasma and urine. PCI inhibited the amidolytic activity (cleavage of H-D-valyl-L-leucyl-arginine-p-nitroaniline) of urinary kallikrein with an apparent second order rate constant of 2.3 x 10(4) M-1 s-1 and formed stable complexes (85 kDa) with urinary kallikrein as judged from silver-stained sodium dodecyl sulfate-polyacrylamide gels. Complex formation was time-dependent and was paralleled by a decrease in the intensity of the main PCI protein band (Mr = 57,000) and an increase in the intensity of the lower Mr (54,000) PCI form (cleaved inhibitor). Heparin interfered with the inhibition of tissue kallikrein by PCI and with the formation of tissue kallikrein-PCI complexes in a dose-dependent fashion and completely abolished PCI-tissue kallikrein interaction at 300 micrograms/ml. This is in contrast to findings on the interaction of PCI with all other target proteases studied so far (i.e. stimulation of inhibition by heparin) but is similar to the reaction pattern of 125I-labeled tissue kallikrein with so called kallikrein binding protein described in serum and other systems. To study a possible relationship between PCI and this kallikrein binding protein we incubated 125I-labeled urinary kallikrein in serum and in PCI-immunodepleted serum in the absence and presence of heparin and analyzed complex formation using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In normal serum, formed complexes co-migrated with complexes of purified PCI and 125I-kallikrein and were less intense in the presence of heparin. No complex formation at all was seen in PCI-depleted serum. Our data indicate that PCI may be a physiologically important endogenous inhibitor of tissue kallikrein and provide evidence that PCI may be identical to the previously described kallikrein binding protein.     

Purification and characterization of a novel inhibitor of urokinase from human urine. Quantitation and preliminary characterization in plasma

Urokinase-related proteins in human urine occur mainly as a 1:1 complex of urokinase with an inhibitor (Stump, D. C., Thienpont, M., and Collen, D. (1986) J. Biol. Chem. 261, 1267-1273). BALB/c mice were immunized with this urokinase-urokinase inhibitor complex and spleen cells fused with mouse myeloma cells, resulting in hybridomas producing monoclonal antibodies. Three antibodies reacting with the complex but not with urokinase were utilized to develop a sensitive (0.5 ng/ml) enzyme-linked immunosorbent assay for the urokinase inhibitor, which was used for monitoring its purification by chromatography on zinc chelate-Sepharose, concanavalin A-Sepharose, SP-Sephadex C-50, and Sephadex G-100. A homogenous glycoprotein of apparent Mr 50,000 was obtained with a yield of 40 micrograms/liter urine and a purification factor of 320. One mg of the purified protein inhibited 35,000 IU of urokinase within 30 min at 37 degrees C. This protein was immunologically related to both the purified urokinase-urokinase inhibitor complex and to the inhibitor portion dissociated from it by nucleophilic dissociation. It was immunologically distinct from all known protease inhibitors, including the endothelial cell-derived fast-acting inhibitor of tissue-type plasminogen activator, the placental inhibitor of urokinase and protease nexin. In electrophoresis the protein migrated with beta-mobility. Inhibition of urokinase occurred with a second order rate constant (k) of 8 X 10(3) M-1 s-1 in the absence and of 9 X 10(4) M-1 s-1 in the presence of 50 IU of heparin/ml. The urokinase inhibitor was inactive towards single-chain urokinase-type plasminogen activator and plasmin, but it inhibited two-chain tissue-type plasminogen activator with a k below 10(3) M-1 s-1 and thrombin with a k of 4 X 10(4) M-1 s-1 in the absence and 2 X 10(5) M-1 s-1 in the presence of heparin. The concentration of this urokinase inhibitor in plasma from normal subjects determined by immunoassay was 2 +/- 0.7 micrograms/ml (mean +/- S.D., n = 25). The protein purified from plasma by immunoabsorption had the same Mr, amino acid composition, and immunoreactivity as the urinary protein. Furthermore, when urokinase was added to plasma, time-dependent urokinase-urokinase inhibitor complex formation was observed at a rate similar to that observed for the inhibition of urokinase by the purified inhibitor from urine. This urokinase inhibitor, purified from human urine, most probably represents a new plasma protease inhibitor.     

Urinary protein C inhibitor. Glycosaminoclycans synthesized by the epithelial kidney cell line TCL-598 enhance its interaction with urokinase.

Protein C inhibitor (PCI), also known as plasminogen activator inhibitor 3, inhibits a variety of serine proteases by forming sodium dodecyl sulfate-stable 1:1 complexes. In purified systems PCI is only a weak inhibitor of urokinase. Nevertheless, complexes between PCI and urokinase are found in appreciable amounts in native human urine. Since PCI activity is stimulated by heparin and other glycosaminoglycans, we investigated the presence of stimulating glycosaminoglycans on cells lining the urinary tract. We chose the epithelial kidney tumor cell line TCL-598 as a model and isolated metabolically labeled glycosaminoglycans. TCL-598 incorporated [35S] sulfate into high Mr components (Mr greater than 200,000 and approximately 75,000) as judged from sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography of cell extracts; the Mr greater than 200,000 component bound specifically to PCI-Sepharose 4B and was eluted either with heparin (5 mg/ml) or with NaCl (2.0 M). Treatment of this PCI-binding material with chondroitinase ABC, but not with chondritinase AC or heparitinase, abolished binding to PCI-Sepharose, confirming the glycosaminoglycan nature of this material and suggesting the involvement of dermatan sulfate in binding. These glycosaminoglycans eluted from PCI-Sepharose stimulated urokinase inhibition by PCI in a dose-dependent way and enhanced complex formation of 125I-urokinase and PCI as did in control experiments dermatan sulfate from porcine skin and from bovine mucosa. Our results suggest that PCI activity might be regulated also in vivo by the presence or absence of stimulating glycosaminoglycans; dermatan sulfate-containing glycosaminoglycans associated with kidney cells might be responsible for stimulation of the urokinase inhibitory activity of PCI in the urinary tract; the type of glucosaminoclycans might furthermore regulate enzyme specificity of PCI.     

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.     

Evidence for essential lysines in heparin cofactor II

Covalent modification with pyridoxal 5'-phosphate was used to study the function of lysyl residues in heparin cofactor II, a heparin-dependent plasma protease inhibitor. Reduction of the Schiff base with sodium borohydride resulted in modification of 3-4 lysyl residues of heparin cofactor II at high concentrations of pyridoxal 5'-phosphate, one of which was protected in the presence of heparin. The antithrombin activity of modified heparin cofactor II was enhanced compared to the native protein. However, the heparin cofactor activity for thrombin inhibition was reduced significantly or completely eliminated in the modified protease inhibitor depending on the extent of phosphopyridoxylation. In contrast to native heparin cofactor II, the modified protease inhibitor did not bind to a heparin-agarose column. The results suggest that lysyl residues are essential for heparin cofactor activity during thrombin inhibition.     

Identification of surface epitopes of human coagulation factor Va that are important for interaction with activated protein C and heparin

Inactivation of factor Va (FVa) by activated protein C (APC) is a key reaction in the down-regulation of thrombin formation. FVa inactivation by APC is correlated with a loss of FXa cofactor activity as a result of three proteolytic cleavages in the FVa heavy chain at Arg306, Arg506, and Arg679. Recently, we have shown that heparin specifically inhibits the APC-mediated cleavage at Arg506 and stimulates cleavage at Arg306. Three-dimensional molecular models of APC docked at the Arg306 and Arg506 cleavage sites in FVa have identified several FVa amino acids that may be important for FVa inactivation by APC in the absence and presence of heparin. Mutagenesis of Lys320, Arg321, and Arg400 to Ala resulted in an increased inactivation rate by APC at Arg306, which indicates the importance of these residues in the FVa-APC interaction. No heparin-mediated stimulation of Arg306 cleavage was observed for these mutants, and stimulation by protein S was similar to that of wild type FVa. With this, we have now demonstrated that a cluster of basic residues in FVa comprising Lys320, Arg321, and Arg400 is required for the heparin-mediated stimulation of cleavage at Arg306 by APC. Furthermore, mutations that were introduced near the Arg506 cleavage site had a significant but modest effect on the rate of APC-catalyzed FVa inactivation, suggesting an extended interaction surface between the FVa Arg506 site and APC.     

Heparin binding to protein C inhibitor.

Protein C inhibitor is a plasma protein whose ability to inhibit activated protein C, thrombin, and other enzymes is stimulated by heparin. These studies were undertaken to further understand how heparin binds to protein C inhibitor and how it accelerates proteinase inhibition. The region of protein C inhibitor from residues 264-283 was identified as the heparin-binding site. This differs from the putative heparin-binding site in the related proteins antithrombin and heparin cofactor. The glycosaminoglycan specificity of protein C inhibitor was relatively broad, including heparin and heparan sulfate, but not dermatan sulfate. Non-sulfated and non-carboxylated polyanions also enhanced proteinase inhibition by protein C inhibitor. Heparin accelerated inhibition of alpha-thrombin, gamma T-thrombin, activated protein C, factor Xa, urokinase, and chymotrypsin, but not plasma kallikrein. The ability of glycosaminoglycans to accelerate proteinase inhibition appeared to depend on the formation of a ternary complex of inhibitor, proteinase, and glycosaminoglycan. The optimum heparin concentration for maximal rate stimulation varied from 10 to 100 micrograms/ml and was related to the apparent affinity of the proteinase for heparin. There was no obvious relationship between heparin affinity and maximum inhibition rate or degree of rate enhancement. The affinity of the resultant protein C inhibitor-proteinase complex was also not related to inhibition rate enhancement, and the results showed that decreased heparin affinity of the complex is not an important part of the catalytic mechanism of heparin. The importance of protein C inhibitor as a regulator of the protein C system may depend on the relatively large increase in heparin-enhanced inhibition rate for activated protein C compared to other proteinases.     

Protein C is an autocrine growth factor for human skin keratinocytes

The protein C (PC) pathway plays an important role in coagulation and inflammation. Many components of the PC pathway have been identified in epidermal keratinocytes, including endothelial protein C receptor (EPCR), which is the specific receptor for PC/activated PC (APC), but the core member of this pathway, PC, and its function in keratinocytes has not been defined. In this study, we reveal that PC is strongly expressed by human keratinocytes at both gene and protein levels. When endogenous PC was blocked by siRNA the proliferation of keratinocytes was significantly decreased. This inhibitory effect was restored by the addition of recombinant APC. PC siRNA treatment also increased cell apoptosis by 3-fold and inhibited cell migration by more than 20%. When keratinocytes were pretreated with RCR252, an EPCR-blocking antibody, or PD153035, an epidermal growth factor receptor (EGFR) inhibitor, cell proliferation was hindered by more than 30%. These inhibitors also completely abolished recombinant APC (10 mug/ml)-stimulated proliferation. Blocking PC expression or inhibiting its binding to EPCR/EGFR decreased the phosphorylation of ERK1/2 but increased p38 activation. Furthermore, inhibition of ERK decreased cell proliferation by approximately 30% and completely abolished the stimulatory effect of APC on proliferation. Taken together, these results indicate that keratinocyte-derived PC promotes cell survival, growth, and migration in an autocrine manner via EPCR, EGFR, and activation of ERK1/2. Our results highlight a novel role for the PC pathway in normal skin physiology and wound healing.     

Effects of forskolin on adenylate cyclase,cyclic AMP,protein kinase and intermediary metabolism of the thyroid gland

Forskolin (40 μM) stimulated adenylate cyclase activities of bovine thyroid plasma membranes without pthe addition of guanine nucleotides. GDP had little effect on the forskolin-stimulated adenylate cyclase activity while Gpp[NH]p (0.1–1.0 μM) decreased it. In the presence of TSH (10 mU/0.11), Gpp[NH]p no longer caused inhibition. Forskolin did not affect phosphodiesterase activities of thyroid homogenates. Forskolin (10 μM) rapidly increased cAMP levels in bovine thyroid slices both in the absence and presence of a phosphodiesterase inhibitor. The effect of TSH (50 mU/ml) on cAMP levels was additive or greater than additive to that of forskolin. An initial 2-h incubation of slices with forskolin did not decrease their subsequent cAMP responses to either forskolin and/or TSH while similar treatment of slices with TSH induced desensitization of the cAMP response to TSH, but not to forskolin. Forskolin (10 μM) as well as TSH (50 mU/ml) activated cAMP-dependent protein kinase of slices in the absence of a phosphodiesterase inhibitor. Although forskolin activated the adenylate cyclase cAMP system, it did not stimulate iodide organification or glucose oxidation, effects which have been attributed to cAMP. In fact, forskolin inhibited these parameters and ³²P incorporation into phospholipids as well as their stimulation by TSH. These results indicate that an increase in cAMP levels and cAMP-dependent protein kinase activity in thyroid slices may not necessarily reproduce the effects of TSH on the thyroid.     

Inhibition of factor IXa and factor Xa by antithrombin III/heparin during factor X activation

We investigated the kinetics of the inhibitory action of antithrombin III and antithrombin III plus heparin during the activation of factor X by factor IXa. Generation and inactivation curves were fitted to a three-parameter two-exponentional model to determine the pseudo first-order rate constants of inhibition of factor IXa and factor Xa by antithrombin III/heparin. In the absence of heparin, the second-order rate constant of inhibition of factor Xa generated by factor IXa was 2.5-fold lower than the rate constant of inhibition of exogenous factor Xa. It appeared that phospholipid-bound factor X protected factor Xa from inactivation by antithrombin III. It is, as yet, unclear whether an active site or a nonactive site interaction between factor Xa and factor X at the phospholipid surface is involved. The inactivation of factor IXa by antithrombin III was found to be very slow and was not affected by phospholipid, calcium, and/or factor X. With unfractionated heparin above 40 ng/ml and antithrombin III at 200 nM, the apparent second-order rate constant of inhibition of exogenous and generated factor Xa were the same. Thus, in this case phospholipid-bound factor X did not protect factor Xa from inhibition. In the presence of synthetic pentasaccharide heparin, however, phospholipid-bound factor X reduced the rate constant about 5-fold. Pentasaccharide had no effect on the factor IXa/antithrombin III reaction. Unfractionated heparin (1 micrograms/ml) stimulated the antithrombin III-dependent inhibition of factor IXa during factor X activation 400-fold. In the absence of reaction components this stimulated was 65-fold. We established that calcium stimulated the heparin-dependent inhibition of factor IXa.     

The heparin binding site of protein C inhibitor is protease-dependent

Protein C inhibitor (PCI) is a member of the serpin family of protease inhibitors with many biological functions and broad inhibitory specificity. Its major targets in blood are thrombin and activated protein C (APC), and the inhibition of both enzymes can be accelerated by glycosaminoglycans, including heparin. Acceleration of thrombin and APC inhibition by PCI requires that both protease and inhibitor bind to the same heparin chain to form a bridged Michaelis complex. However, the position of the heparin binding site of APC is opposite to that of thrombin, and formation of the bridged complexes must require either radical reorientation of the proteases relative to PCI or alternate heparin binding modes for PCI. In this study, we investigate how heparin bridges thrombin and APC to PCI by determining the effect of mutations in and around the putative heparin binding site of PCI. We found that heparin binds PCI in a linear fashion along helix H to bridge thrombin, consistent with our recent crystal structure (3B9F), but that it must rotate by approximately 60 degrees to engage Arg-229 to bridge APC. To gain insight into the possible modes of heparin binding to PCI, we solved a crystal structure of cleaved PCI bound to an octasaccharide heparin fragment to 1.55 angstroms resolution. The structure reveals a binding mode across the N terminus of helix H to engage Arg-229 and align the heparin binding site of APC. A molecular model for the heparin-bridged PCI.APC complex was built based on mutagenesis and structural data.     

Inactivation of human plasma kallikrein and factor XIa by protein C inhibitor

The inhibition of kallikrein and factor XIa by protein C inhibitor (PCI) was studied. The method of Suzuki et al. [Suzuki, K., Nishioka, J., & Hashimoto, S. (1983) J. Biol. Chem. 258, 163-168] for the purification of PCI was modified in order to avoid the generation of proteolytic activity and subsequent inactivation of PCI. With the use of soybean trypsin inhibitor, an efficient inhibitor of kallikrein and factor XIa, the generation of proteolytic activity was avoided. The kinetics for the inactivation of activated protein C (APC), kallikrein, and factor XIa by PCI were determined. In the absence of heparin, no inactivation of APC was observed, in contrast to kallikrein and factor XIa, which are inhibited with second-order rate constants of (11 +/- 4) X 10(4) and (0.94 +/- 0.07) X 10(4) M-1 s-1, respectively. Addition of heparin potentiated the inhibition of APC [(1.2 +/- 0.2) X 10(4) M-1 s-1] and factor XIa [(9.1 +/- 0.7) X 10(4) M-1 s-1] by PCI, whereas the inhibition of kallikrein by PCI was unchanged [(10 +/- 1) X 10(4) M-1 s-1]. The second-order rate constants for the inhibition of kallikrein or factor XIa by PCI were similar to the second-order rate constants for the inhibition of their isolated light chains by PCI, indicating a minor role for the heavy chains of both molecules in the inactivation reactions. With sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis and immunoblotting, complex formation of APC, kallikrein, and factor XIa with PCI could be demonstrated. APC and kallikrein formed 1:1 molar complexes with PCI.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure-function relationships in heparin cofactor II: chemical modification of arginine and tryptophan and demonstration of a two-domain structure

Heparin cofactor II and antithrombin III are plasma proteins functionally similar in their ability to inhibit thrombin at accelerated rates in the presence of heparin. To further characterize the structural and functional properties of human heparin cofactor II as compared to antithrombin III, we studied the possible significance of arginyl and tryptophanyl residues and the changes in protein structure and activity during guanidinium chloride (GdmCl) denaturation. Both antithrombin and heparin cofactor activities of heparin cofactor II are inactivated by the arginine-specific reagent, 2,3-butanedione. Saturation kinetics are observed during modification and suggest formation of a reversible protease inhibitor-butanedione complex. Quantitation of arginyl residues following butanedione modification shows a loss of about four residues for total inactivation, one of which is essential for antithrombin activity. Arginine-modified heparin cofactor II did not bind to heparin-agarose and implies a role for the other modified arginyl residues during heparin cofactor activity. N-Bromosuccinimide oxidation (20 mol of reagent/mol of protein) of heparin cofactor II results in modification of approximately two tryptophanyl residues with no concomitant loss of heparin cofactor activity. Moreover, there is no enhancement of intrinsic protein fluorescence during heparin binding to the native inhibitor. Circular dichroism measurements show that the structural transition of heparin cofactor II during denaturation is distinctly biphasic, yielding midpoints at 0.6 and 2.6 M GdmCl. Functional protease inhibitory activities are affected to the same extent following denaturation-renaturation at various GdmCl concentrations. The results indicate that arginyl residues are critical for both antithrombin and heparin binding activities. In contrast, tryptophanyl residues are apparently not essential for heparin-dependent interactions. The results also suggest that heparin cofactor II contains two structural domains which unfold at different GdmCl concentrations.     

Glucosylceramide,a neutral glycosphingolipid anticoagulant cofactor,enhances the interaction of human- and bovine-activated protein C with negatively charged phospholipid vesicles

The effect of glucosylceramide (GlcCer) on activated protein C (APC)-phospholipid interactions was examined using fluorescence resonance energy transfer. Human APC, labeled with either fluorescein (Fl-APC) or dansyl (DEGR-APC) donor, bound to phosphatidylcholine/phosphatidylserine (PC/PS, 9:1 w/w) vesicles containing octadecylrhodamine (OR) acceptor with a K(d) (app) = 16 micro g/ml, whereas Fl-APC (or DEGR-APC) bound to PC/PS/GlcCer(OR) (8:1:1) vesicles with a K(d) (app) = 3 micro g/ml. This 5-fold increase in apparent affinity was not species-specific since bovine DEGR-APC also showed a similar GlcCer-dependent enhancement of binding of APC to PC/PS vesicles. From the efficiency of fluorescence resonance energy transfer, distances of closest approach of approximately 63 and approximately 64 A were estimated between the dansyl on DEGR-APC and rhodamine in PC/PS/GlcCer(OR) and PC/PS(OR), respectively, assuming kappa(2) = 2/3. DEGR-APC bound to short chain C8-GlcCer with an apparent K(d) of 460 nm. The presence of C8-GlcCer selectively enhanced the binding of C16,6-NBD-phosphatidylserine but not C16,6-7-nitrobenz-2-oxa-1,3-diazole (NBD)-phosphatidylcholine to coumarin-labeled APC. These data suggest that APC binds to GlcCer, that PC/PS/GlcCer vesicles like PC/PS vesicles bind to the N-terminal gamma-carboxyglutamic acid domain of APC, and that one mechanism by which GlcCer enhances the activity of APC is by increasing its affinity for membrane surfaces containing negatively charged phospholipids.     

Rapid fibroblast growth factor-induced increases in protein phosphorylation and ornithine decarboxylase activity: regulation by heparin and comparison to nerve growth factor-induced increases.

Fibroblast growth factors (FGFs), like nerve growth factor (NGF), induce morphological differentiation of PC12 cells. This activity of FGF is regulated by glycosaminoglycans. To further understand the mechanisms of FGF and glycosaminoglycan actions in PC12 cells, we studied the regulation of protein phosphorylation and ornithine decarboxylase (ODC) activity by FGF in the presence and absence of heparin. As with NGF, aFGF and bFGF increased the incorporation of radioactive phosphate into the protein tyrosine hydroxylase (TH). The increase in TH phosphorylation was localized to the tryptic peptide, T3. Both T3 and T1 phosphorylations occur in response to NGF, but there was no evidence that aFGF or bFGF stimulated the phosphorylation of the T1 peptide. This result suggests differential regulation of second messenger systems by NGF and FGF in PC12 cells. Heparin, at a concentration that potentiated aFGF-induced neurite outgrowth 100-fold (100 micrograms/ml), did not alter the ability of aFGF to increase S6 phosphorylation or ODC activity. One milligram per milliliter of heparin, a concentration that inhibited bFGF-induced neurite outgrowth, also inhibited bFGF-induced increases in S6 phosphorylation and ODC activity. These observations suggest (i) that acidic and basic FGF activate a protein kinase, possibly protein kinase C, resulting in the phosphorylation of peptide T3 of TH; (ii) that the FGFs and NGF share some but not all second messenger systems; (iii) that heparin potentiates aFGF actions and inhibits bFGF actions in PC12 cells via distinct mechanisms; (iv) that heparin does not potentiate the neurite outgrowth promoting activity of aFGF by enhancing binding to its PC12 cell surface receptor; and (v) that heparin may coordinately regulate several activities of bFGF (induction of protein phosphorylation, ODC and neurite outgrowth) via a common mechanism, most likely by inhibiting the productive binding of bFGF to its PC12 cell surface receptor.     

Surfactant-associated protein inhibits phospholipid secretion from type II cells

Secretion of [3H]phosphatidylcholine ([3H]PC) from isolated rat pulmonary type II epithelial cells was inhibited by the surfactant-associated protein of Mr = 35,000 (SAP-35) purified from canine lung surfactant. SAP-35 inhibited [3H]PC secretion in a dose-dependent manner and significantly inhibited basal, phorbol ester, beta-adrenergic, and P2-purinergic agonist-induced [3H]PC secretion. SAP-35 significantly inhibited [3H]PC secretion from 1 to 3 h after treatment. The IC50 for inhibition of [3H]PC secretion by canine SAP-35 was 1-5 X 10(-6) g/ml and was similar for inhibition of both basal and secretagogue-stimulated release. Heat denaturation of SAP-35, addition of monoclonal anti-SAP-35 antibody, reduction and alkylation of SAP-35, or association of SAP-35 with phospholipid vesicles reversed the inhibitory effect on secretagogue-induced secretion. Inhibitory effects of SAP-35 were observed 3 h after cells were washed with buffer that did not contain SAP-35. Although SAP-35 enhanced reassociation of surfactant phospholipid with isolated type II cells, its inhibitory effect on secretion of [3H]PC did not result from stimulation of reuptake of secreted [3H]PC by type II cells. The inhibition of phospholipid secretion by SAP-35 was also not due to inhibition of PC or disaturated PC synthesis by SAP-35. SAP-35, the major phospholipid-associated protein in pulmonary surfactant, is a potent inhibitor of surfactant secretion from type II cells in vitro and may play an important role in homeostasis of surfactant in the alveolar space.