(Received for publication, May 13, 1996, and in revised form, November 29, 1996)
From the Department of Biochemistry, American Red Cross Holland Laboratory, Rockville, Maryland 20855, ¶ Departments of Internal Medicine and Human Genetics and Howard Hughes Medical Institute, University of Michigan, Ann Arbor, Michigan, 48109-0650, ** Center for Molecular Biology of Oral Diseases, University of Illinois, Chicago, Illinois 60612-7213, and Henry Ford Health System, Detroit, Michigan 48202-3450
Plasminogen activator inhibitor type 1 (PAI-1),
the primary physiologic inhibitor of plasminogen activation, is
associated with the adhesive glycoprotein vitronectin (Vn) in plasma
and the extracellular matrix. In this study we examined the binding of
different conformational forms of PAI-1 to both native and urea-purified vitronectin using a solid-phase binding assay. These results demonstrate that active PAI-1 binds to urea-purified Vn with
approximately 6-fold higher affinity than to native Vn. In contrast,
inactive forms of PAI-1 (latent, elastase-cleaved, synthetic reactive
center loop peptide-annealed, or complexed to plasminogen activators)
display greatly reduced affinities for both forms of adsorbed Vn, with
relative affinities reduced by more than 2 orders of magnitude.
Structurally, these inactive conformations all differ from active PAI-1
by insertion of an additional strand into -sheet A, suggesting that
it is the rearrangement of sheet A that results in reduced Vn affinity.
This is supported by the observation that PAI-1 associated with
-anhydrotrypsin, which does not undergo rearrangement of
-sheet
A, shows no such decrease in affinity, whereas PAI-1 complexed to
-trypsin, which does undergo sheet A rearrangement, displays reduced
affinity for Vn similar to PAI-1·plasminogen activator complexes.
Together these data demonstrate that the interaction between PAI-1 and
Vn depends on the conformational state of both proteins and suggest
that the Vn binding site on PAI-1 is sensitive to structural changes associated with loss of inhibitory activity.
Plasminogen activators (PAs)1 are
specific serine proteinases that activate the proenzyme plasminogen to
the broad specificity enzyme plasmin (1). There are only two known
physiologic activators of plasminogen, tissue-type PA (tPA) and
urokinase-type PA (uPA) (2). In addition to their role in vascular
fibrinolysis (3), PAs are thought to critically influence many other
biological processes involving cell migration or tissue remodeling (4). These include ovulation (5), inflammation (6), tumor metastasis (7),
and angiogenesis (8). The serpin PAI-1, the most efficient inhibitor
known of both tPA and uPA, is thus a critical regulator of the PA
system (9). PAI-1 is present in plasma at nM concentrations (10) and in platelets at a much higher concentration (11). This latter
pool has been shown to contribute to clot stabilization in
vivo (12). In plasma and the extracellular matrix, PAI-1 is
associated with Vn (13-15), and this association may be involved in
maintaining the integrity of the cell substratum in vivo.
PAI-1 exists in at least three distinct conformational forms: active, latent, and cleaved (16, 17). Active PAI-1 decays to the latent form
with a half-life of approximately 1-2 h at 37 °C (18). After
treatment with denaturants, latent PAI-1 can be partially returned to
the active form (19). Although the biologic significance of the latent
conformation remains unknown, it may contribute to the regulation of
PAI-1 activity (20). Cleaved PAI-1 can be generated either by the slow
deacylation of the enzyme inhibitor complex (21, 22) or by reaction of
PAI-1 with a nontarget protease such as elastase, which cleaves the
reactive center loop (RCL) at a site other than the
P1-P1 reactive center bond (17). The latent
and cleaved forms of PAI-1 are inactive due to full insertion of the
RCL into
-sheet A of the inhibitor and therefore are unavailable for
reaction with proteinases (16, 23). In contrast, the active form of
PAI-1 is thought to have its RCL fully exposed and thus available for
interaction with proteinases (21). Complex formation with a target
proteinase is associated with a rapid conformational change in the
inhibitor that results in RCL insertion (21, 24).
The adhesive glycoprotein, Vn, is present in plasma at µM
concentrations and is also associated with the extracellular matrix of
many tissues. Like PAI-1, Vn can also exist in multiple conformational states (25, 26). In addition to stabilizing PAI-1, Vn has been shown to
alter the PAI-1 specificity, converting it to an efficient inhibitor of
thrombin (27, 28). Vitronectin-bound PAI-1 has a 270-fold greater
second order rate constant toward thrombin than does free PAI-1.
However, this increase depends upon the conformational form of Vn (28).
Vitronectin also promotes the clearance of PAI-1·thrombin complexes
by the low density lipoprotein receptor-related protein (29). Recently,
PAI-1 bound to vitronectin in the extracellular matrix has been shown
to block the binding of integrins (30) and the uPA receptor (31) to
vitronectin, and this interaction was shown to inhibit cell adhesion
and migration on vitronectin. The precise nature of the PAI-1/Vn
interaction has been the subject of considerable debate and was
recently reviewed (32). Using solid-phase binding assays to quantitate
this interaction, several studies have suggested that only active PAI-1
binds Vn (13, 33, 34); however, other investigators have reported no
apparent difference in the binding of active and latent PAI-1 (35, 36).
In addition, the reported dissociation constant for PAI-1 binding to
immobilized Vn ranges from 0.3 to 190 nM (34, 35, 37). The
Vn binding domain within PAI-1 was recently localized to a region on
the surface of PAI-1 that includes -strand 1A (37-39). The Vn
binding site for PAI-1 appears to be localized to the somatomedin B
domain at the N terminus of Vn (40-42). However, other reports suggest
that PAI-1 binds to the C terminus of Vn between residues 348 and 370 (36) or to a site near the center of Vn between amino acids 115 and 121 (43).
A critical dependence of the PAI-1/Vn interaction on the PAI-1 and/or Vn conformation could explain these conflicting reports. To test this hypothesis we examined the binding of PAI-1 in six different conformations to both native and urea-purified immobilized Vn. Our results indicate that the two forms of Vn bind to PAI-1 with markedly different affinities and that the Vn binding domain on PAI-1 is very sensitive to the PAI-1 conformation. We suggest that there may have been an evolutionary selection of the PAI-1 structure to permit efficient removal of inactive PAI-1 at sites of subcellular attachment.
Purified PAI-1 (44), either active (>95%) or
latent (>95%), were obtained from Molecular Innovations (Royal Oak,
MI). To eliminate any active PAI-1 present in the latent preparations, latent PAI-1 was treated with a 0.01 molar eq of elastase for 30 min at
23 °C in Tris-buffered saline, pH 7.5 (TBS), followed by
inactivation of the elastase with 1 mM (final
concentration) phenylmethylsulfonyl fluoride. nVn (28) was a generous
gift of Dr. D. Mosher, and uVn (45) was either a generous gift from Dr.
T. Podor or purchased from Calbiochem. Recombinant high molecular weight uPA was a generous gift of Dr. J. Henkin of Abbott, and tPA
(Activase) was from Genentech. Porcine pancreatic elastase was from
Elastin Products, and bovine -trypsin and
-anhydrotrypsin were
prepared as described (17, 46). The eight-residue synthetic peptide
Ac-Thr-Val-Ala-Ser-Ser-Ser-Thr-Ala corresponding to the PAI-1 reactive
center loop from P14 to P7, residues 333-340,
was synthesized by the University of Michigan Biomedical Research Core
Facilities.
PAI-1
cleaved at the P4 position of the reactive center loop (17)
was produced by treatment of 4.6 µM active PAI-1 with a
0.1 molar eq of elastase for 30 min at 23 °C in TBS followed by
treatment of the sample with 1 mM (final concentration)
phenylmethylsulfonyl fluoride to inactive the elastase. PAI-1 complexes
with uPA and tPA were formed by incubation of 1.5 molar eq of either
enzyme with 4.6 µM active PAI-1 for 30 min at 23 °C in
TBS followed by inactivation of residual enzyme by 1 mM
(final concentration) 4-(amidinophenyl)methanesulfonyl fluoride. After
incubation with either {phenylmethylsulfonyl fluoride or
4-(amidinophenyl)methanesulfonyl fluoride all samples were shown
to contain no detectable enzymatic activity by chromogenic assay.
Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis
indicated only trace amounts of unreacted PAI-1 in each sample, most
likely representing the small amount of latent PAI-1 contained in the
active PAI-1 preparation. Complexes with bovine -trypsin were formed
by reacting 26 µM active PAI-1 with 13 µM
trypsin in 25 mM sodium phosphate, 125 mM NaCl,
0.5 mM EDTA, 10 mM CaCl2, pH 6.6, for 30 min at 23 °C, after which the remaining active PAI-1 was
removed by chromatography on uPA-agarose. Sodium dodecyl
sulfate-polyacrylamide gel electrophoresis analysis indicated that the
complexes contained no detectable uncleaved PAI-1 and ~20% free
cleaved PAI-1. The PAI-1·peptide complex was produced by incubating
6.4 µM active PAI-1 with 200 µM peptide in
0.1 M HEPES, 0.1 M NaCl, 0.1% PEG-8000, 0.1%
Tween 80, pH 7.4, at 25 °C until no detectable PAI-1 inhibitory
activity remained (approximately 20 h). The free peptide was then
removed by chromatography on heparin-Sepharose. PAI-1·peptide complex
formation was confirmed by thermodenaturation (18), mass spectra
analysis (47), and sodium dodecyl sulfate-polyacrylamide gel
electrophoresis with or without tPA (48). This latter analysis
indicated that the peptide-annealed PAI-1 was a substrate for tPA and
contained approximately 15% latent PAI-1, consistent with previous
studies (48).
PAI-1 binding to immobilized Vn was determined either functionally (49) or in a vitronectin-specific ELISA, as described previously (37). Briefly, Vn at 1 µg/ml in phosphate-buffered saline was coated overnight onto Immulon 2 (Dynatech Laboratories Inc.) microtiter plates in a volume of 100 µl at 4 °C, and all subsequent steps were performed at room temperature. The plates were washed with phosphate-buffered saline followed by distilled H2O, allowed to air dry for 15 min, and then blocked with 200 µl of 3% bovine serum albumin in phosphate-buffered saline for 30 min. Next, PAI-1 samples in TBS containing 100 µg/ml BSA and 0.01% Tween 80 were added in a final volume of 100 µl, and incubation continued for 1 h, after which the unbound PAI-1 was washed away. During this incubation period <15% of the active PAI-1 should have converted to the latent form since we have determined the t1/2 for this conversion to be ~8 h at 25 °C in the absence of vitronectin (data not shown). In the functional assay, PAI-1 binding was determined by reacting the bound PAI-1 with 0.7 nM uPA for 30 min followed by the addition of the chromogenic substrate S-2444 (Kabi Pharmacia/Chromogenix) as described (49). The bound PAI-1 was then calculated from the loss of uPA amidolytic activity. Kd values for the solid-phase binding of PAI-1 to immobilized Vn were calculated using the following form of the standard binding equation from the GraFit program (Erithacus Software),
![]() |
(Eq. 1) |
The Vn-dependent ELISA assay was performed as above except that bound PAI-1 was detected with affinity-purified, biotinylated, rabbit anti-PAI-1 antibodies (50) and streptavidin conjugated to alkaline phosphatase using the substrate p-nitrophenyl phosphate, disodium hexahydrate (Sigma) at a concentration of 4 mg/ml in 100 mM Tris-HCl, pH 9.5, 5 mM MgCl2. To control for nonspecific binding, all assays were simultaneously analyzed on plates coated with BSA alone and processed in parallel. The background binding to BSA was subtracted from all samples before data analysis. For examination of the PAI-1·anhydrotrypsin complex binding to Vn, 1 µM (final concentration) anhydrotrypsin was included in all wells during the PAI-1 incubation step. This concentration of anhydrotrypsin was 20-fold higher than the highest concentration of PAI-1 tested and 10-fold higher than the reported Kd for the interaction of PAI-1 and anhydrotrypsin (17). For data analysis of ELISA experiments, the Kd was estimated for active PAI-1 with Equation 1 above by assuming that PAI-1 bound as a percent of the maximal binding was proportional to the actual PAI-1 bound and that free PAI-1 was approximately equal to PAI-1 added. For the inactive PAI-1 samples examined, no value for Kd could be established since none of these samples achieved saturation at the concentrations tested.
Competitive Inhibition of PAI-1 Binding to Immobilized Vitronectin by Solution-phase VitronectinMicrotiter plates were
coated with nVn and blocked with BSA as above. Next, either native or
urea-purified Vn was added to the plates and serially diluted 3-fold in
TBS containing 100 µg/ml BSA and 0.01% Tween 80 after which active
PAI-1 was added to a final concentration of 2 nM (final
volume, 100 µl). The samples were allowed to react for 1 h at
23 °C and washed, and bound PAI-1 was determined as in the ELISA
assay as above. IC50 values for the inhibition by
solution-phase Vn were calculated using a four-parameter logistic fit
(51) from the GraFit program (Erithacus Software). The
Kd for solution-phase interactions of PAI-1 with vitronectin was determined by analysis of competition data by methods
previously described (52). According to this analysis, the
concentration of PAI-1 bound to the competitor Vn in solution is equal
to the difference between the total PAI-1 concentration used in the
presence of the competitor and the total PAI-1 concentration yielding
an equivalent extent of saturation of the immobilized vitronectin in
the absence of the competitor. The latter was calculated based on the
fit of binding data in the absence of competitor Vn (Fig. 3) by
Equation 1. Knowledge of the concentration of PAI-1 bound to competitor
Vn in solution allowed calculation of the concentrations of free PAI-1
and free competitor Vn for the solution interaction from which
Kd was calculated. Reasonable agreement was obtained
for Kd values determined at competitor Vn
concentrations yielding significant extents of displacement of PAI-1
from the immobilized Vn (>15%).
Tomasini and Mosher (26) and Deng et al. (32) suggest
that the controversy surrounding the interaction between Vn and PAI-1
results from the conformational variability of both proteins. In the
current study we directly examined the binding of alternative conformations of PAI-1 to both native and urea-purified Vn. Previously we described a functional assay for PAI-1 binding to Vn in which active
PAI-1 was shown to bind specifically to surface-adsorbed nVn in a
dose-dependent and saturable manner (49). This assay was
used to compare the binding of active wtPAI-1 with both forms of
immobilized Vn (Fig. 1). These data demonstrate that
both urea-purified and native Vn have a similar binding capacity for
active PAI-1 and that active PAI-1 binds to both forms of Vn with high
affinity. However, the calculated Kd for the
immobilized uVn is approximately 6-fold lower than for immobilized nVn
(127 ± 20 pM compared with 825 ± 190 pM). This difference may reflect the different
conformational states of the two Vn preparations since nVn is
predominately monomeric (53), whereas uVn is a disulfide-linked multimer (54). The observation that PAI-1 has a higher affinity for
immobilized multimeric Vn than for immobilized monomeric Vn is
consistent with the result that PAI-1 isolated from plasma is
predominately in complex with a high molecular weight form of Vn (13)
even though the majority of Vn in plasma is monomeric (55). Therefore,
to see if solution-phase multimeric Vn also bound PAI-1 with higher
affinity than solution-phase monomeric Vn, competitive inhibition
assays were performed with both nVn and uVn competing for PAI-1 binding
to immobilized nVn. These data are shown in Fig. 2 and
demonstrate that both uVn and nVn compete for PAI-1 binding to
immobilized nVn. This suggests that PAI-1 is binding to the same site
on both nVn and uVn either when the Vn is in solution or immobilized.
Furthermore, solution-phase uVn is a more efficient competitor for
PAI-1 binding (IC50, 65 nM) than is
solution-phase nVn (IC50, 375 nM). This
approximate 6-fold difference is similar to that observed in Fig. 1 and
suggests that either in solution or when immobilized uVn has a higher
affinity for PAI-1 than does nVn. Kd values of
20 ± 1.4 nM and 125 ± 12 nM for the
interaction of PAI-1 with solution forms of uVn and nVn, respectively,
were calculated from these data (see "Experimental Procedures").
This indicates that PAI-1 binds to immobilized Vn with a significantly
higher affinity than to solution-phase Vn and has an approximately
150-fold higher Kd for the solution-phase
interaction with either form of Vn. This enhanced binding to
immobilized Vn may result from the different conformation that Vn is
known to assume when it adsorbs to a surface (56, 57).
To examine the binding of alternative conformational forms of PAI-1, an ELISA-based assay was performed. This assay is similar to the solid-phase assay shown in Fig. 1 except that PAI-1 is detected with an anti-PAI-1 antibody, permitting analysis of inactive conformations of PAI-1. Fig. 3 shows the binding of both active and latent PAI-1 to surface-adsorbed urea-purified and native Vn. Analysis of the binding of active PAI-1 to the two forms of immobilized Vn yields calculated Kd values of 150 ± 16 pM with uVn and 1300 ± 200 pM with nVn. These values are similar to those calculated using the PAI-1 functional assay (Fig. 1), indicating that the indirect antibody assay is also suitable for evaluating PAI-1 binding to immobilized Vn. In contrast to active PAI-1, latent PAI-1 binds to both forms of immobilized vitronectin with much lower affinity. In this case no Kd could be determined since saturable PAI-1 binding was not obtained at the concentrations tested. However, if we assume that latent PAI-1 is binding with the same stoichiometry as active PAI-1, then we can estimate a minimum value for Kd of >225 nM (the highest concentration tested) in both cases (Fig. 3). These data are consistent with previous reports that only active PAI-1 binds to vitronectin with high affinity (13, 33, 34) and contradict the suggestion that both forms of PAI-1 bind to vitronectin with equal affinity (35, 36). The Kd values calculated for active PAI-1 binding to immobilized Vn are also similar to previously reported values (127 pM (this study) versus 300 pM (34) with uVn and 825 pM (this study) versus 4.4 nM (37) with nVn). An earlier report that calculated a lower affinity Kd of 55-190 nM for these interactions using a similar assay failed to account for the presence of both active and latent PAI-1 in the preparation and may have been measuring primarily the binding of latent PAI-1 (35). Consistent with this interpretation, the reported Kd of 190 nM is similar to our estimated minimum Kd for latent PAI-1 binding to either native or uVn (Kd > 225 nM) (Fig. 3). These authors also noted a high affinity, "low capacity" binding site (Kd < 100 pM) that may have represented the active PAI-1 in their preparation (35).
The observation that latent PAI-1 binds to Vn with a much lower
affinity than active PAI-1 suggests that the conformational change
associated with conversion to the latent form may be responsible for
the reduced affinity. In a previous study (37) we suggested that the
stabilization of PAI-1 by Vn occurs when Vn binding to strand 1 of
-sheet A limits the mobility of
-sheet A necessary for insertion
of the PAI-1 RCL during transformation to the latent conformation. This
model is compatible with the observation that conversion of the serpin
-sheet A from a 5-stranded to a 6-stranded antiparallel
-sheet by
insertion of the RCL as strand 4 of
-sheet A requires extensive
rearrangement of
-strands 1, 2, and 3 (58). Restriction of this
rearrangement by Vn could retard loop insertion and thus the conversion
of PAI-1 to the latent form. Also consistent with this model is the
apparent modification of the Vn binding site on PAI-1 following RCL
insertion, as indicated by the reduced affinity of latent PAI-1 for Vn
(Fig. 3).
We next examined the binding of native and uVn to PAI-1 complexed to
tPA or uPA, cleaved by elastase, or inactivated by insertion of a
synthetic RCL peptide. Each of these conformers is thought to have its
-sheet A in the 6-stranded form, similar to the structure of latent
PAI-1 (17, 21, 24, 48). The results of these studies are shown in Fig.
4. Like latent PAI-1, none of these RCL-inserted forms
of PAI-1 bind to immobilized nVn with high affinity, with all having
estimated Kd values >112-225 nM (the
highest concentrations tested). Similar results were also obtained with
immobilized uVn (data not shown). The relatively low affinity observed
for both the tPA·PAI-1 and uPA·PAI-1 complexes with both forms of
Vn is consistent with previous reports that tPA dissociates PAI-1 from
solution-phase Vn (13) and that PAI-1 can be removed from extracellular
matrix by treatment with uPA (59). Of note, PAI-1 in complex with the
synthetic RCL peptide shows a reduced affinity for Vn similar to the
other loop-inserted forms. This indicates that it is not the loss of an
exposed RCL that results in a reduction of binding affinity for Vn
since in the PAI-1·peptide complex the natural RCL remains intact and
fully accessible (48). Instead, these data suggest that it is the reorganization of
-sheet A that leads to the reduced affinity.
To confirm that rearrangement of sheet A is responsible for the loss of
affinity and not simply the association of PAI-1 with an enzyme, the
relative binding affinity of PAI-1 in complex with either trypsin or
anhydrotrypsin was tested. PAI-1 is an efficient inhibitor of trypsin
and forms sodium dodecyl sulfate-stable, RCL-inserted complexes, as
with uPA or tPA (46). In contrast, anhydrotrypsin binds to the PAI-1
RCL in a noncovalent association that does not result in cleavage of
the RCL or its insertion into -sheet A (46). Like uPA and tPA,
PAI-1·trypsin complexes were observed to have a very low affinity for
immobilized nVn (Fig. 5). However, PAI-1 in association
with anhydrotrypsin bound to immobilized nVn with nearly the same
affinity as active PAI-1 alone. This confirms that it is not simply the
association of an enzyme with the RCL that leads to a loss of Vn
affinity, but instead it is the enzyme-induced insertion of the RCL
into
-sheet A.
Recent studies of the serpin mechanism of inhibition indicate that it
is a complex process that requires an exposed RCL (21, 22, 24, 60).
Upon association with a target proteinase, the serpin RCL is cleaved at
its P1-P1 bond, and the RCL is inserted into
-sheet A, yielding the stable serpin·proteinase complex. In the
present study we demonstrate that the PAI-1 Vn binding site on the edge
of
-sheet A is sensitive to this conformational change in
-sheet
A as well as to similar changes associated with conversion of PAI-1 to
the latent form or cleavage in the RCL by a nontarget proteinase. This
sensitivity may provide a way to ensure the expression of PAI-1
activity at specific sites of action. For example, it is thought that
Vn serves to localize PAI-1 to the extracellular matrix where it
regulates local proteolytic activity (59) and blocks cell adhesion and
migration (30, 31). In this setting it may be beneficial to permit only
functionally active PAI-1 to bind to vitronectin. On a cell surface an
inactive ligand can be internalized and degraded. However, this type of regulation may not be as efficient on the less dynamic extracellular matrix. Therefore, to prevent Vn from becoming saturated with inactive
forms of PAI-1, a system may have been selected that is sensitive to
the conformational state of PAI-1, which in turn is closely linked to
its activity state.
We thank S. Muhammad for excellent technical assistance, M. Sandkvist for helpful discussions, and K. Ingham for a critical reading of the manuscript.