(Received for publication, August 5, 1996, and in revised form, November 8, 1996)
From the Division of Molecular Biology and Biochemistry, School of Biological Sciences, University of Missouri, Kansas City, Missouri 64110
Histidine-proline-rich glycoprotein (HPRG), also
known as histidine-rich glycoprotein, is a major plasminogen-binding
protein. In this work we characterized extensively the circumstances
under which HPRG accelerates plasminogen activation and the specificity of this effect. Soluble HPRG did not significantly influence
plasminogen activation. In contrast, native HPRG bound to hydrazide or
nickel chelate surfaces strongly stimulated the activation of
plasminogen by tissue plasminogen activator, but not by urokinase or
streptokinase. The efficiency of activation on surface-bound HPRG was
increased for Glu-plasminogen (41-fold), Lys-plasminogen (17-fold), and cross-linked Glu-plasminogen (11-fold) but not for mini-plasminogen, and was mainly due to a decrease in the apparent
Km. A reduced susceptibility to inhibition by
chloride ions contributed to the higher activation rate of
Glu-plasminogen on an HPRG surface. The immobilized N- and C-terminal
domains, but not the histidine-proline-rich domain of HPRG, also bound
plasminogen and stimulated its activation. HPRG-enhanced plasminogen
activation was proportional to the quantity of HPRG immobilized and was
abolished by anti-HPRG antiserum, by low concentrations of
-aminocaproic acid, by methylation of lysine residues in HPRG, and
by treatment of HPRG with carboxypeptidase B. Soluble HPRG and a
plasminogen fragment, kringle 1-2-3, acted as competitive inhibitors by
binding to plasminogen and immobilized HPRG, respectively. The
interaction of the conserved C-terminal lysine of HPRG with the high
affinity lysine binding site of plasminogen is necessary and sufficient
to accelerate plasminogen activation. Unlike other stimulators of
plasminogen activation, the effect of HPRG on fibrinolysis is modulated
by factors that influence the equilibrium between solution and
surface-bound HPRG.
Plasmin, the primary enzyme of the fibrinolytic system, is formed
from plasminogen by the action of plasminogen activators, such as
tissue plasminogen activator (t-PA) or urokinase. As a safeguard
mechanism to prevent undue plasmin generation under normal
physiological conditions, plasminogen is a very poor substrate for its
activators, but activation is greatly accelerated by conformational changes or interaction with other proteins (1). Instrumental in this
regulation are three of the five kringle domains (K1, K4, and K5),
which comprise the lysine binding sites (LBS) of plasminogen and bind
lysine analogues or lysine side chains in proteins. In the presence of
physiological concentrations of chloride ions,
Glu1-Pg,1 the native form of
plasminogen, adopts a closed conformation and becomes difficult to
activate, but this effect is reversed in the presence of
-aminocaproic acid (
-ACA) (2, 3). In contrast,
Lys78-Pg, generated by plasmin proteolysis of
Glu1-Pg, adopts an open conformation and is relatively
easier to activate regardless of the presence of chloride ions or
lysine analogues. Proteins that interact with the LBS on plasminogen,
most notably fibrin (4, 5) but also proteins of the extracellular
matrix (6) or cell surface (7), greatly stimulate plasminogen
activation, and this effect is competitively inhibited by
-aminocaproic acid (
-ACA) or other lysine analogues. Many of
these effectors also bind the plasminogen activator, thereby acting as
a template that brings the enzyme and its substrate in close
proximity.
HPRG is a relatively abundant protein (~1.5 µM in
normal human plasma) whose physiological function is not precisely
known. Based on its interactions with plasminogen (8), fibrinogen (9),
and heparin (10), HPRG has been suggested to play a role in the
regulation of the coagulation and fibrinolytic systems. Its relatively
high affinity for plasminogen (KD approximately 1 µM, in solution) makes HPRG one of the most important
plasminogen ligands in plasma, and it has been estimated that about
50% of plasminogen circulates bound to HPRG (8). Previous work has shown that HPRG has a complex influence on the fibrinolytic system. By
binding to plasminogen, HPRG reduces the concentration of free plasminogen, competitively inhibits binding of plasminogen to fibrin,
and retards fibrinolysis in vitro (8). These results suggested that HPRG has an anti-fibrinolytic effect similar to that of
lysine analogues, although the physiological relevance of this effect
was questioned (11). However, HPRG also exhibits pro-fibrinolytic
activities by reducing the rate of reaction between plasmin and
2-antiplasmin (8, 12). Furthermore, HPRG immobilized onto Sepharose or plastic microtiter plates increases the efficiency of
plasminogen activation by t-PA about 30-fold (12), although the authors
have not addressed whether surface-adsorbed HPRG was native or
denatured, and many denatured proteins stimulate plasmin formation
nonspecifically (13). In contrast, HPRG accelerated plasminogen
activation by urokinase in solution less than 2-fold (8).
These complex and apparently contradictory effects of HPRG on fibrinolysis prompted us to investigate in more detail the interaction between plasminogen and HPRG, and especially its influence on plasminogen activation. First, we aimed to define the structural features of HPRG required for its interaction with plasminogen by assaying the binding to plasminogen of various HPRG domains and chemical derivatives. Second, we sought to characterize the conditions under which HPRG stimulates plasminogen activation and the specificity of this process by using different plasminogen and plasminogen activator species in the activation assay in the presence of HPRG and HPRG derivatives, either immobilized on various surfaces or in solution. Finally, we investigated how immobilized HPRG accelerates plasminogen activation by comparing the activation rates of different plasminogen forms under various experimental conditions.
Two-chain human recombinant t-PA (specific
activity 630,000 units/mg relative to the International Standard), a
t-PA mutein (BM06.022) containing only the kringle 2 and the protease
domain of human t-PA (K2P t-PA), t-PA standard, and
cyanogen bromide fragments of fibrinogen were generous gifts from Drs.
U. Kohnert and S. Fischer (Boehringer, Mannheim, Germany).
Two-chain human urokinase and bovine serum albumin (BSA) were from
Calbiochem. Streptokinase, carboxypeptidase B (CPB), goat anti-human
plasminogen antiserum,
D-valyl-leucyl-lysyl-p-nitroanilide (S-2251),
-ACA, p-nitrophenyl phosphate, 5-bromo-4-chloro-3-indolyl
phosphate (BCIP), and nitroblue tetrazolium (NBT) were from
Sigma. Affinity-purified, alkaline
phosphatase-conjugated rabbit anti-goat IgG was from Cappel.
Lysine-Sepharose and cyanogen bromide-activated Sepharose were from
Pharmacia and nickel-NTA-agarose from QIAGEN. Nickel chelate-coated
microtiter plates were purchased from Xenopore and hydrazide-coated
plates from Costar.
Human HPRG was isolated from human plasma by metal-chelate affinity chromatography on nickel-NTA-agarose.2 Briefly, 10 volumes of human plasma containing 5 mM imidazole were applied to one volume of Ni-NTA-agarose, and after washing with 20 mM and 80 mM imidazole buffer, pH 7.5, human HPRG was eluted with 250 mM imidazole, pH 7.5. The procedure for "clipping" human HPRG with plasmin-Sepharose was similar to that described for rabbit HPRG (14), but the reaction time was reduced to 2 h.
Because rabbit HPRG can be obtained in larger quantities than the human
counterpart and its domains have been relatively well characterized
(14), the HPRG derivatives have been prepared starting from the rabbit
protein, unless otherwise indicated. Reduction of plasmin-clipped HPRG
with dithiothreitol under non-denaturing conditions releases the 30-kDa
histidine-proline-rich domain of HPRG and the remaining N/C fragment
can be further reduced under denaturing conditions to yield the 45-kDa
N-terminal and the 20-kDa C-terminal domains (see Fig. 1
for a schematic representation of rabbit HPRG domains, including the
plasmin cleavage sites). Fully or partially
reduced-and-carboxamidomethylated HPRG (RCAM-HPRG and PRCAM-HPRG) were
obtained by reduction of disulfide bonds in HPRG with dithiothreitol in
the presence or absence of 3 M guanidinium hydrochloride,
respectively (14). Reductive methylation of lysine residues in HPRG was
carried out using a 10-fold molar excess of formaldehyde and sodium
borohydride (15); 85% of surface lysine residues were found to be
modified as assessed by reaction with trinitrobenzenesulfonate (16).
Removal of the C-terminal lysine residue of HPRG was achieved by
treatment with carboxypeptidase B (CPB, 1:25 molar ratio) in 0.1 M Tris buffer, pH 8.8, for 30 min at room temperature,
followed by purification of CPB-treated HPRG on heparin-Sepharose.
Carbohydrate-oxidized HPRG was obtained by incubation of a 2 mg/ml
protein solution in 0.2 mg/ml sodium periodate in 0.1 M
sodium acetate, pH 4.5, for 1 h at room temperature, followed by
desalting on a gel-filtration column. The preparation of goat antisera
against rabbit or human HPRG was described previously (17).
Glu1-Pg was purified from human plasma by affinity chromatography on lysine-Sepharose (18). Lys78-Pg was prepared by continuously mixing a Glu1-Pg solution (2 mg/ml in 0.1 M sodium phosphate, pH 8.0) with plasmin-Sepharose (ratio 1:30 v/v) for 3 h at room temperature; after removing the gel by centrifugation, Lys78-Pg was isolated from the supernatant by affinity chromatography on lysine-Sepharose. Val442-plasminogen (mini-Pg) and plasminogen kringle domains (K1-2-3 and K4) were obtained from Glu1-Pg by digestion with elastase, followed by affinity purification on lysine-Sepharose and gel filtration on Ultrogel AcA54 (19). Cross-linked plasminogen (XGlu1-Pg) was prepared from Glu1-Pg and 1,5-dinitro-2,4-difluoro-benzene, as described (20).
Concentrated stock solutions of all proteins were dialyzed against 5 mM sodium phosphate, pH 7.2, and stored frozen in aliquots at 20 °C. The concentrations of the HPRG and plasminogen
derivatives were determined spectrophotometrically using published
values for the extinction coefficients and molecular weights (21), and
those of plasminogen activators using the BCA Protein Assay Kit
(Pierce).
HPRG (10 µg/ml in 0.1 M carbonate buffer, pH 9.6) was passively adsorbed to polystyrene microtiter plates (Corning) by overnight incubation at ambient temperature. The unoccupied sites in the wells were blocked by subsequent treatment with 1 mg/ml BSA for at least 3 h. The following steps were carried out at ambient temperature (except the ligand binding step) using 100 µl of solution/well, and between the incubation steps the wells were washed three times for 1 min with TBS (Tris-buffered saline: 15 mM Tris and 150 mM sodium chloride, pH 7.4). All solutions were made in TBS containing 1 mg/ml BSA and 0.05% Tween 20. For the direct binding assay, solutions containing various concentrations of Glu-Pg were incubated in the HPRG-coated wells for 1 h at 37 °C. For the competitive binding assay, solutions containing a fixed amount of Glu-Pg (0.2 µM) and various concentrations of HPRG (or its derivatives) were incubated in the HPRG-coated wells for 3 h at 37 °C. The amount of plasminogen bound to each well was estimated from the rate of hydrolysis of p-nitrophenol phosphate (5 mg/ml in 0.1 M glycine, pH 10.5, containing 1 mM magnesium chloride and 0.5 mM zinc chloride) after sequential incubation with primary antibody (1:500 dilution of goat anti-human plasminogen for 1 h) and secondary antibody (1:1000 dilution of alkaline phosphatase-conjugated rabbit anti-goat IgG for 30 min). The absorbance change at 405 nm was recorded with a plate reader (Thermomax, Molecular Devices).
Ligand BlotsHPRG domains were separated under reducing conditions by SDS-PAGE on 14% acrylamide gels and electrotransferred onto a polyvinylidene difluoride membrane (Immobilon P, Millipore) for 1 h at 25 V/cm inter-electrode distance. The membrane was then blocked with 10 mg/ml BSA and 0.05% Tween 20 in TBS buffer (1 h at ambient temperature) and incubated with ligand (0.5 µM plasminogen in blocking buffer overnight at 4 °C on a rocking platform), primary antibody (1:500 dilution of goat anti-human plasminogen antiserum in blocking buffer for 1 h at ambient temperature), and secondary antibody (1:2000 dilution alkaline phosphatase-conjugated rabbit anti-goat IgG in blocking buffer for 1 h at ambient temperature). The blots were visualized with BCIP and NBT (0.2 mg/ml each in 0.1 M Tris buffer, pH 9.5, containing 0.1 M sodium chloride and 5 mM magnesium chloride).
Plasminogen Activation AssayPlasminogen activation was
carried out at 37 °C in microwell plates and monitored by recording
the hydrolysis of the chromogenic plasmin substrate S-2251 with a
kinetic plate reader (Thermomax, Molecular Devices). Absorbance at 405 nm was recorded every 30 s over a period of 1-2 h, and the plate
was shaken before each reading. The reaction was initiated by addition
of the plasminogen activator after the other ingredients were
preincubated at 37 °C for at least 10 min to achieve thermal
equilibration. The plasminogen activator solution was dispensed from a
repetitive multi-channel pipettor to insure speed and reproducibility.
Less than 30 s passed between the addition of the reagent and the
start of the assay, which was negligible compared with the total length
of the assay. Typically, the reaction mixture consisted of 0.2 µM Glu-plasminogen, 0.36 nM t-PA, 0.25 mM S-2251 in 100 µl of "mass buffer" (15 mM sodium phosphate, 150 mM sodium chloride,
0.01% Triton X-100, and 1 mg/ml BSA, pH 7.2). Additional reagents
included in the reaction mixture, such as -ACA or fibrinogen
fragments, or different reaction conditions are specified in the figure
legends. In some experiments, different species of plasminogen or
plasminogen activator were used as noted.
For assaying the rates of plasminogen activation in solution, the microtiter plates used in the assay were blocked by passive adsorption of BSA. This as well as incorporation of BSA and detergent in the mass buffer was necessary to prevent nonspecific adsorption of proteins to the microtiter plates and consequent spuriously high activation rates. Different methods were used to coat HPRG on the surface of the wells: passive adsorption (as described above for plasminogen binding assays), binding of HPRG to nickel-chelate microtiter plates (following the manufacturer's protocol), or coupling of periodate-oxidized HPRG to hydrazide-coated plates (a 10 µg/ml protein solution in 0.1 M sodium acetate, pH 5.2, was incubated in the wells overnight at ambient temperature, followed by washing and blocking for 1 h with a 5 mg/ml BSA solution in PBS). Plates coated passively with HPRG constantly yielded relatively poor results in this assay and were not used further. The other surfaces yielded comparable results, although nickel chelate-coated plates, which bind HPRG derivatives directly without requiring derivatization of the carbohydrate groups, are more convenient.
Assuming a constant rate of plasminogen activation, the concentration
of plasmin increases linearly with time and that of the
p-nitroaniline follows a parabolic curve (5). With the boundary condition that no plasmin is present at time zero, the change
of absorbance at 405 nm with time is given by
A(t) = A(t)
A(0) = k · t2 = 1/2 · k1 · k2
· t2, where k is the apparent
plasminogen activation rate in mA/min2,
k1 is the plasminogen activation rate in
nM/min, and k2 represents plasmin
activity toward S-2251 under given experimental conditions, expressed
as mA/min·nM. Using active-site titrated plasmin as standard, we determined a value k2 of 1.15 mA/min·nM plasmin under our assay conditions (0.25 mM S-2251 in 100 µl of mass buffer, 37 °C). A plot of
A(t) versus t2 yields a
straight line with a slope k. Since the software provided by
Molecular Devices did not support this type of analysis, a program was
written in Visual Basic 4.0 (Microsoft) to analyze the plate reader
data files after export to ASCII (text) format. The activation rate,
k, was obtained by least squares regression of
A(t) versus t2 through
data points at low substrate conversion. In practice, a limit of 70 mA
for
A (corresponding to the hydrolysis of ~10% of
S-2251) was selected as the cut-off value, providing between 20 and 120 data points/well for analysis. The amount of plasmin generated at the
end of the interval used for analysis did not exceed 6 nM,
or about 3% of the initial substrate concentration.
Both human HPRG (8) and rabbit HPRG (22) interact
with the LBS of human plasminogen with comparable affinity
(KD approximately 1 µM). Since the
HPRG-plasminogen interaction does not appear to be species-specific,
and since rabbit HPRG domains can be reproducibly prepared in large
quantities by limited proteolysis with plasmin (14), we aimed to
identify the conserved lysine residues of HPRG involved in the
interaction with plasminogen. In the following experiments, rabbit HPRG
and its derivatives were used unless otherwise indicated. The ligand
blot in Fig. 2 shows that reductive methylation of
lysine residues in HPRG or treatment with CPB abolishes plasminogen
binding, indicating that the C-terminal lysine of HPRG
(Lys518 in rabbit) is required for the interaction. Among
the HPRG domains generated by limited proteolysis with plasmin, the
C-terminal and the N-terminal but not the His-Pro-rich domain of HPRG
bound plasminogen. Since CPB treatment also abrogates plasminogen
binding to the HPRG domains (lane b in Fig. 2), the probable
new plasminogen binding sites generated by plasmin digestion are
Lys242 or Lys261 (Fig. 1), the putative
C-terminal residue sites of the N-terminal domain (14). Comparable
results were obtained by affinity chromatography of the same HPRG
species on plasminogen-Sepharose (data not shown), suggesting that
binding was not affected by plasminogen immobilization.
To quantify the interaction, the data obtained in a solid-phase binding
assay were fitted to a binding isotherm using non-linear least square
regression analysis (Fig. 3A). As with other
plasminogen ligands, Lys-Pg had higher affinity for immobilized rabbit
HPRG (KD = 13.8 ± 1.6 nM) than for
Glu-Pg (72.4 ± 5.4 nM), and similar values were
obtained using immobilized human HPRG (13.7 and 60.7 nM,
respectively). Since the binding of plasminogen to immobilized HPRG
could be competitively inhibited by -ACA (Fig. 3A,
inset), which binds to the LBS of plasminogen, soluble HPRG
species that interact with plasminogen should also prevent its binding
to immobilized HPRG. Indeed, the results of competitive binding
experiments (Fig. 3B) agreed with those obtained in ligand blots. The efficiency of the inhibition, reflecting the affinity for
plasminogen, was: N-terminal domain ~ N/C fragment ~ clipped HPRG > C-terminal domain ~ rabbit HPRG ~ human HPRG > histidine-proline-rich domain ~ CPB-treated
HPRG ~ methylated HPRG.
Effect of HPRG in Solution on Plasminogen Activation
Proteins like HPRG, which bind to the LBS of plasminogen, usually influence plasminogen activation. The influence of HPRG and HPRG derivatives in solution-phase on plasminogen activation was measured in BSA-coated wells (Table I). In a series of control experiments carried out in parallel, HPRG derivatives did not influence the amidolytic activity of t-PA toward S-2444 (0.5 mM), and only RCAM-HPRG and the N-terminal domain of HPRG had a significant effect on plasmin activity toward S-2251 (0.25 mM), inhibiting by 50% at 1 µM concentration. Interestingly, the same two HPRG derivatives stimulated plasminogen activation severalfold. However, the preparation of these two derivatives requires denaturation and renaturation, and the near UV-CD spectrum of RCAM-HPRG resembles that of denatured HPRG more than that of native protein (14). Since denatured proteins stimulate plasminogen formation nonspecifically (13), the effect of the two HPRG derivatives may simply reflect partial misfolding upon renaturation. In these cases, the A versus t2 plots were not linear but curved upward (data not shown), indicating a biphasic activation with an initial slow step ("lag phase") similar to that observed with fibrin or fibrinogen fragments (23). This implies that in situ plasmin digestion of the HPRG derivatives increases their stimulatory potency by generating new plasminogen binding sites, a phenomenon facilitated by the absence of disulfide bonds and potential misfolding. Inhibition of plasmin activity in the presence of these two derivatives supports this interpretation, since good plasmin substrates would compete with the chromogenic substrate.
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Plastic-immobilized HPRG has been reported to stimulate
the activation of Glu-Pg by t-PA (12). To address the mechanism of this
phenomenon and characterize its specificity, we carried out plasminogen
activation in the presence of immobilized HPRG, using various
plasminogen or plasminogen activator species, and the results were
compared with those obtained with other known stimulators of
plasminogen activation. Several plasminogen species were used to assess
the role of plasminogen conformation in this effect: Glu-Pg is flexible
and its conformation is influenced by chloride ions and -ACA, Lys-Pg
prefers an open conformation, XGlu-Pg is locked into a closed one (20),
and mini-Pg lacks kringles 1-4 of the regulatory region.
Of the three plasminogen activators tested, t-PA was the most sensitive
to the effect of surface-bound HPRG. In the presence of immobilized
HPRG, the activation of Glu-Pg, Lys-Pg, and XGlu-Pg by t-PA was
accelerated 15-, 5-, and 2-fold, respectively (Table II). The activation of mini-Pg was not affected,
suggesting that at least one of the plasminogen kringles 1-4 is
required for the effect. It is remarkable that HPRG stimulated the
activation of Lys-Pg and XGlu-Pg, derivatives whose conformation and
activability is not influenced by -ACA. However, immobilized HPRG
did not stimulate plasminogen activation by urokinase, and it had only a limited effect when streptokinase or a K2P t-PA mutant
(containing the t-PA kringle 2 and the protease domain) were used,
indicating that the effect of immobilized HPRG on plasminogen
activation is specific for t-PA and involves one of the fibronectin,
epidermal growth factor, or kringle 1 domains of t-PA. As effector,
immobilized HPRG more closely resembled the fibrinogen fragments. Apart
from the stronger effect of the fibrinogen fragments, which may be attributed in part to the larger amount of protein used in the assay,
the most important differences between the two effectors were the shape
of the A(t) versus t2
plots (linear for the immobilized HPRG, but curved up for the fibrinogen fragments) and the activation of mini-Pg by t-PA (stimulated by fibrinogen fragments, but not by the immobilized HPRG).
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The kinetic parameters for the activation of Lys-, Glu-, and XGlu-Pg by t-PA were determined in the presence or absence of immobilized HPRG (Table III). These apparent values facilitate a comparison between the activation processes in solution and on a surface, although the first order reaction rates for plasminogen activation in the presence of immobilized HPRG are likely to be underestimated due to the concurrent, inefficient activation in solution. The catalytic efficiency of Glu-Pg activation was enhanced significantly more (41-fold) than that of either Lys-Pg (17-fold) or XGlu-Pg (11-fold), but with all derivatives a decrease in the apparent Km was the main factor responsible for the acceleration effect. To explore whether Glu-Pg was more sensitive to the surface effect because of its conformational flexibility, the three plasminogen species were activated at different concentrations of chloride ions in solution or on the HPRG surface (Fig. 4). Only the activation of Glu-Pg was inhibited by chloride ions, but interestingly, this effect was diminished in the presence of immobilized HPRG, particularly at low concentrations of chloride ions.
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Plasminogen Activation on an HPRG Surface: the Effect of HPRG and the Surface
Next we examined how the enhancement of plasminogen activation depends on the quantity and nature of the immobilized HPRG. When increasing amounts of periodate-oxidized HPRG were immobilized onto hydrazide plates, the accelerating effect of surface-bound HPRG was initially proportional to the amount of protein immobilized, but a plateau was reached around 150 ng (2 pmol) of rabbit HPRG/well, presumably because the surface became saturated. Since 100 µl of solution/well wets an area of 0.94 cm2, and assuming that all HPRG added to the wells was immobilized, a surface concentration of about 2.2 pmol/cm2 HPRG can be computed, in good agreement with the value of 2.5 pmol/cm2 expected for a monolayer of protein of this size.3
To rule out the possibility that the effect of immobilized HPRG on plasminogen activation is due to denaturation upon adsorption, we coupled HPRG to the surface of microtiter plates by three distinct methods and assayed plasminogen activation. The overall results indicate that stimulation of plasminogen activation by surface-bound HPRG is in fact specific and not due to surface denaturation (vide infra). The strongest stimulation, 30-50% of the effect of fibrinogen fragments, was obtained in the presence of nickel chelate-bound HPRG. This method of immobilization relies on the binding of histidine residues of the protein to tetradentate nickel chelates (24) and is mild and directional, since the histidine-proline-rich domain of HPRG contains almost all metal-binding sites (25). HPRG bound to hydrazide-coated plates via periodate-oxidized sugar residues was half as efficient as HPRG bound to nickel chelate, presumably because there are several carbohydrate moieties in HPRG (14) that can be used for immobilization and thus several possible orientations. HPRG adsorbed to polystyrene, the most likely to be denatured, had the weakest effect and stimulated plasminogen activation only 2-fold relative to the control.
Interestingly, immobilized native HPRG was twice as active as
RCAM-HPRG, opposite to the activation efficiency in solution, further
indicating that the effect of surface-bound HPRG was not caused by
denaturation (Fig. 5). Further supporting this
assertion, anti-rabbit HPRG antiserum specifically inhibited the effect
of native, but had little effect on denatured, HPRG. The antibodies appeared to inhibit by blocking the binding of plasminogen to the
immobilized protein, since the effects were both protein- and
species-specific. Anti-HPRG antisera were effective only against the
cognate protein, but not against immobilized fibrinogen fragments, and
anti-fibrinogen antibodies did not inhibit the activation effect of
surface-bound HPRG from either species.
A series of chemical derivatives and isolated domains of HPRG were used to further characterize the relationship between HPRG structure and the acceleration of plasminogen activation. As shown in Table IV, there is a strong positive correlation between plasminogen binding by immobilized HPRG species and plasminogen activation, suggesting that plasminogen bound to HPRG is activated more efficiently than in solution phase. Human HPRG was about 40% more efficient than rabbit HPRG, perhaps due to a smaller area occupied per molecule and thus, higher density on the plate surface. Although the number of amino acid residues is similar in human and rabbit HPRG, the former is less glycosylated and has an apparent Mr of 70,000 by SDS-PAGE compared with 90,000 of the latter. Plasmin-clipped forms of rabbit or human HPRG were 30-50% more active than the native counterparts, likely due to the presence of additional binding sites for plasminogen (vide supra). Stimulation by the N- and C-terminal HPRG domains was much greater than that by histidine-proline-rich domain and represented about 75% of the native HPRG effect, despite the lower amounts of immobilized protein (61 and 32%, respectively) assessed by immunoassay.
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Finally, neither immobilized CPB-treated HPRG nor methyl-HPRG had any effect on plasminogen activation, in good agreement with the lack of plasminogen binding ability. Treatment of immobilized HPRG or plasmin-clipped HPRG with CPB reduced the surface activation effect gradually (data not shown). Sensitivity to CPB treatment of intact HPRG indicates that the original COOH-terminal lysine of HPRG, and not internal lysine residues exposed by plasmin digestion, is responsible for enhanced plasminogen activation, opposite to the behavior observed when fibrin is used as stimulator. In a separate experiment (data not shown), plasminogen activation was carried out in the presence of a mixture of immobilized native and methylated HPRG, and the stimulation was roughly proportional to the percentage of native protein on the surface, showing that the stimulatory effect was not saturated with regard to the immobilized HPRG and the amount of protein that can be bound onto the surface was the limiting factor.
Inhibition of Plasminogen Activation on an HPRG Surface by Competition for Plasminogen or HPRGTo confirm that the
stimulation of plasminogen activation in the presence of immobilized
HPRG requires binding of plasminogen to the HPRG surface, the
inhibition by ligands of either plasminogen or HPRG was tested. As
shown in Fig. 6A, the effect of -ACA in the activation assay was closely similar to that in the plasminogen binding assay (Fig. 3A, inset), providing further
evidence that plasminogen binding to immobilized HPRG via LBS is
required for activation. The low concentration of
-ACA required to
achieve 50% inhibition, near 0.2 mM for both Glu and
Lys-Pg, suggests that only the high affinity LBS located on kringle 1 is involved in the interaction. The increase in the activation rate of
Glu-Pg at higher concentrations of
-ACA (above 2 mM) is
due to occupancy of the lower affinity LBS in plasminogen, causing
Glu-Pg to assume a more open conformation and abrogating the inhibitory
effect of chloride ions (2, 26).
Binding of plasminogen to immobilized HPRG could also be prevented by soluble HPRG. The overall effect was an inhibition of plasminogen activation (Fig. 6B), since the interaction between HPRG and plasminogen in solution does not increase plasminogen activability but does prevent plasminogen binding to the stimulatory, immobilized HPRG, causing an apparent inhibition of plasminogen activation. This inhibition effect was relatively weak due to the low Km of plasminogen activation on a surface (see Table III). Thus, a 2-fold reduction of plasminogen concentration from 2Km (approximately the concentration of Glu-Pg used in the experiment shown in Fig. 6B) to Km will reduce the activation rate from 0.66Vmax to 0.5Vmax, only a 25% decrease. It has been previously shown that soluble HPRG weakly inhibits fibrinolysis (8) or plasminogen activation in the presence of fibrin (11).
The activation assay was carried out also in the presence of
plasminogen kringles, to identify which LBS of plasminogen bind to the
immobilized HPRG. The data in Fig. 7A show
that plasminogen kringle 1-2-3 inhibited stimulation and hence bound to
immobilized HPRG, while the kringle fragment 4 did not have any effect,
providing additional evidence that HPRG interacts with the high
affinity LBS on kringle 1. The effect of plasminogen kringle 5 could
not be assessed in this inhibition assay, since mini-Pg was efficiently activated in solution. However, kringle 5 does not appear to be involved in HPRG-enhanced plasminogen activation, since the activation of mini-Pg by t-PA was stimulated by fibrinogen fragments only and
kringles 1-5 but not kringles 1-3 inhibited plasminogen activation in
the presence of fibrin (21).
When XGlu-Pg was used in the activation assay together with fixed amounts of Glu-Pg or Lys-Pg, the activation effect was reduced in a concentration-dependent manner (Fig. 7B). XGlu-Pg is activated very slowly since it is locked in the closed conformation (20), but it can compete with the other plasminogen forms for binding to the stimulatory HPRG surface. Glu-Pg and Lys-Pg activation were inhibited by 50% at about 0.5 µM and 1.0 µM XGlu-Pg, respectively, denoting that Lys-Pg has a higher affinity than Glu-Pg for the HPRG surface.4 XGlu-Pg minimally affected the activation rate of Glu-Pg or Lys-Pg in solution (data not shown), indicating that it inhibits plasminogen activation in the presence of immobilized HPRG by binding to HPRG and not to t-PA.
HPRG is arguably the most abundant plasminogen ligand in plasma, and as much as 50% of plasminogen is estimated to circulate as a complex with HPRG. The proposed anti-fibrinolytic role of this interaction was recently questioned (11), since HPRG only retards fibrinolysis by 15-30%. Indeed, since the concentration of plasminogen in normal human plasma is about 2 µM, halving the concentration of free plasminogen cannot have a large effect on the fibrin-stimulated plasminogen activation, whose Km is at least 1 order of magnitude lower. The data we present in this paper support the earlier proposal that HPRG is pro-fibrinolytic rather than anti-fibrinolytic (12). Apparently contradictory results have been reported earlier regarding the effect of HPRG on plasminogen activation; almost no effect was seen when soluble HPRG and u-PA were used (8), but a strong acceleration was noticed with immobilized HPRG and t-PA (12). This discrepancy is easily accounted for in view of our observations that HPRG-enhanced plasminogen activation is activator-specific and also depends on the physical state of HPRG. Since t-PA is associated with intravascular fibrinolysis and urokinase with plasmin generation in the extravascular milieu, the HPRG effect is relevant only in the former setting. In this paper, we characterized in detail the features of plasminogen activation in the presence of HPRG.
First, there is a marked difference between the effects of HPRG in solution and on a surface. In solution, native HPRG alone has little effect on plasminogen activation, but inhibits the acceleration effect of strong stimulators. However, immobilized HPRG has a clear pro-fibrinolytic activity, strongly enhancing plasminogen activation. The differences between surface-bound and soluble HPRG are probably caused by the much higher local concentration of the former and not by a conformational change induced upon binding to the surface, because similar results were obtained with HPRG immobilized by distinct, mild methods.
Second, the active species on the surface is native, not denatured HPRG. This was demonstrated by specific inhibition by antisera to HPRG, by the higher rate of activation in the presence of immobilized native HPRG as compared with RCAM-HPRG, and by the correspondence between the activity of surface-bound HPRG and the mildness of the immobilization method used. In contrast, only non-native HPRG species stimulate plasminogen activation in solution, and since denatured proteins are often aggregated, it is tempting to speculate that micro-heterogeneity plays a role in this effect.
Third, only plasminogen bound to immobilized HPRG is activated efficiently, as shown by the correlation between the HPRG species active in plasminogen binding and activation assays, as well as by the decrease in stimulation upon competition with ligands for either plasminogen or HPRG. The interaction occurs between the C-terminal lysine residue of native HPRG and sites newly created by plasmin in the N-terminal domain on one hand, and the high affinity LBS of plasminogen situated on kringle 1-2-3 on the other. Indeed, the C-terminal lysine residue preceded by a proline is conserved in human (27) and bovine (28) HPRG. However, the weak effect of immobilized histidine-proline-rich domain or RCAM-HPRG on plasminogen activation illustrates that a C-terminal lysine residue alone, in the absence of an appropriate structural context, does not confer stimulatory properties. Notably, immobilized HPRG exerts its effect via plasminogen kringle 1-2-3, whereas with fibrin, binding to kringle 5 (21) is important for enhanced plasminogen activation.
Fourth, immobilized native HPRG has an intrinsic, immediate stimulatory activity on plasminogen activation (showed by linear A(t) versus t2 plots) since it possesses the requisite C-terminal lysine residue and its effect is abolished by prior treatment with CPB. In contrast, other effectors such as fibrin or fibrinogen fragments exhibit a lag period during which the internal lysine residues are exposed by plasmin to form new plasminogen binding sites that accelerate the activation process. Although clipping HPRG with plasmin prior to the assay increased the stimulatory activity, the difference was small (about 50%) and immobilized HPRG is only slowly digested by plasmin.
Finally, the high specificity for the plasminogen activator species but
not for plasminogen offers clues to the mechanism of plasminogen
activation on an HPRG surface. A mere conformational change in
plasminogen, such as that induced in Glu-Pg by -ACA in the presence
of chloride ions, cannot explain why the activation of Lys-Pg or
XGlu-Pg (found in the open and closed conformation, respectively) is
enhanced, nor can it explain why urokinase is not stimulated by
immobilized HPRG. For the same reason we can rule out a conversion of
Glu-Pg to Lys-Pg on the HPRG surface as the sole accelerating factor.
The latter two mechanisms may be responsible in part for the stronger
stimulation observed with Glu-Pg, especially since the inhibition by
chloride ions was reduced in the presence of immobilized HPRG.
Simultaneous binding of plasminogen and activator, as shown for fibrin (4), extracellular matrix proteins (29), or cell surfaces (30), greatly accelerates plasminogen activation. However, HPRG does not appear to bind t-PA directly (12), and, in addition, we were not able to detect binding of HPRG to t-PA in ligand blot experiments (data not shown). We cannot rule out that t-PA and HPRG interact with low affinity, below our detection limit. In fact, a comparison among t-PA, the K2P t-PA mutant, and u-PA strongly suggests that, in addition to the interaction between the active site of the activator and the scissile bond of the immobilized plasminogen, t-PA also binds to one of the proteins on the surface (either HPRG or another plasminogen molecule) via one of its N-terminal domains. Even a low affinity interaction would increase the avidity of binding to the surface, where the local concentration of immobilized molecules is very high, but would have a limited effect in solution due to the translation and rotation entropy. A tetra-molecular activation complex (HPRG ... Pg ... t-PA ... HPRG or Pg) could explain why the activation is accelerated by immobilized but not soluble HPRG, and also the reduced Km value on the HPRG surface. Yet another effect arising from the high local concentration of protein on the surface can also contribute to the enhanced activation: "trapping" of t-PA by the plasminogen layer bound to the HPRG-coated surface. Diffusion of a ligand from a compartment containing a high concentration of protein, [P], to the bulk solution is slowed down by a factor of 1 + [P]/Kd (where Kd is the dissociation constant of the protein-ligand complex) when the protein is in excess over the ligand (31). These conditions are met for plasminogen bound to the HPRG surface, which achieves a high local concentration and is in excess over t-PA. Thus, the activator molecules near the surface are likely to bind repeatedly to new substrate molecules and turn over many times before they diffuse back into the bulk solution. Such an effect was described for phospholipase A, an enzyme that hydrolyzes its substrate slowly in solution, but whose activity is greatly increased efficiently at interfaces (32).
At this point, we can only speculate on the physiological significance of our findings. Although in this work, HPRG was immobilized by non-physiological and quasi-irreversible methods, one or more of the several HPRG ligands, e.g. thrombospondin (33) or vitronectin (34), may act as an anchor to immobilize HPRG in vivo. Particularly attractive for this role are negatively charged glycosaminoglycans found on cell surfaces. HPRG has been shown to interact with heparin (10, 35), heparan sulfate (36, 37), and dermatan sulfate (38). Binding of heparin to HPRG requires histidine residues (39), is sensitive to pH changes in the physiological range (40), and appears to involve the histidine-proline-rich domain (14). Interestingly, in our experiments, the maximal stimulation effect was obtained with HPRG immobilized onto a nickel chelate surface, and divalent metal ions bind also to the histidine-proline-domain of HPRG (25). It is also possible for HPRG to become immobilized on the cell surface of activated platelets (41) or T-cells (42).
Although many surface-bound proteins (e.g. cell surface or extracellular matrix proteins) accelerate plasminogen activation, they are invariably immobilized. In contrast, HPRG is a plasma protein found in solution phase and only accelerates plasminogen activation when immobilized. Thus, its activity can be modulated by factors that affect the HPRG equilibrium between solution and surfaces, for example an enhanced binding of HPRG to glycosaminoglycans upon a decrease in the local pH. This hypothesis can account for the modular structure of HPRG in terms of its function and bears a striking resemblance to the structure-function relationships of kininogen, another member of the cystatin superfamily. When immobilized to negative surfaces via its lysine-histidine-rich domain (somewhat reminiscent of the histidine-proline-rich domain of HPRG), kininogen optimally positions kallikrein and factor XI, thereby facilitating their activation by surface-bound factor XIIa, and hence triggers the intrinsic coagulation pathway (43, 44). Further experiments are needed to characterize the binding of HPRG to surfaces under physiological and pathophysiological conditions.