(Received for publication, February 13, 1996, and in revised form, November 1, 1996)
From the Department of Vascular Biology, The Scripps
Research Institute, La Jolla, California and the
§ Max-Planck Institut fur Biochemie, Am Klopferspitz 18a,
D-82152 Martinsried, Germany
A wide variety of important biological processes, including both the formation and dissolution of blood clots, depend on specific cleavage of individual target proteins by serine proteases. For example, tissue type plasminogen activator (t-PA), a trypsin-like enzyme that catalyzes the rate-limiting step of the endogenous fibrinolytic cascade, has only one known substrate in vivo, a single peptide bond (Arg561-Val562) in the proenzyme plasminogen. We have previously suggested that the specificity of t-PA for plasminogen is mediated in part by direct protein-protein interactions between the protease domain of t-PA and plasminogen that are distinct from those occurring within t-PA's active site. We demonstrate in this study that residues 420-423 of t-PA, which form a fully solvent-exposed, hydrophobic region of a surface loop mapping near one edge of the active site of t-PA, form, or are essential for the integrity of, an important, secondary site of interaction between t-PA and plasminogen that significantly modulates the rate of plasminogen activation in the absence, but not the presence, of fibrin. Identification of this secondary site of interaction between t-PA and plasminogen provides new insight into molecular details of the evolution of stringent substrate specificity by t-PA and suggests a novel strategy to enhance the fibrin dependence of plasminogen activation by t-PA. While the activity of wild type t-PA is stimulated by fibrin by a factor of approximately 650, the activity of two variants characterized in this study, t-PA/R275E,P422G and t-PA/R275E,P422E, is stimulated by a factor of approximately 39,000 or 61,000, respectively. It is therefore possible that, compared with wild type t-PA, the two variants would display enhanced "clot selectivity" in vivo due to reduced activity in the circulation but full activity at a site of fibrin deposition.
Tissue type plasminogen activator (t-PA)1 has been widely and successfully used as a therapeutic agent to treat acute myocardial infarction (1). t-PA does not, however, dissolve blood clots directly; instead, the enzyme catalyzes conversion of the zymogen plasminogen into the active protease plasmin, which efficiently degrades the fibrin mesh forming the core of a thrombus (2). Both of these critical fibrinolytic enzymes, t-PA and plasmin, are members of the chymotrypsin family of serine proteases (3, 4). Unlike plasmin, however, t-PA is a remarkably specific enzyme. Because such highly restricted substrate specificity is in striking contrast to the broad specificity of well studied serine proteases such as trypsin, chymotrypsin, and elastase (5), the molecular basis of the selectivity of t-PA for plasminogen is of considerable interest. A detailed understanding of the mechanisms employed by t-PA to ensure selectivity would provide new insight into the evolution of the endogenous fibrinolytic cascade and might suggest effective new strategies for the rational design of novel, highly selective proteases with unique specificities as well as novel plasminogen activators.
The specificity of t-PA for plasminogen is enhanced by the co-factor fibrin. Fibrin, t-PA, and plasminogen form a specific, ternary complex, which serves to reduce the Km of t-PA for plasminogen by a factor of greater than 400 (6-8). Even in the absence of fibrin, however, t-PA maintains stringent specificity for plasminogen, and this specificity is an inherent property of the protease domain of t-PA (8).
Although it is the only known efficient substrate for t-PA in vivo, we have presented evidence that the primary sequence surrounding the cleavage site in plasminogen is actually a poor match to optimal subsite occupancy for t-PA (9). When placed into synthetic linear or cyclic peptides or into a trypsin-accessible site in an unrelated protein, this target sequence is cleaved extremely inefficiently by t-PA (10). By contrast, target sequences that do represent optimal subsite occupancy for t-PA, which were identified by screening a large peptide library containing random hexapeptide sequences, can be efficiently cleaved by t-PA in all three of these structural contexts (10). Catalysis of plasminogen by t-PA, therefore, appears to be accelerated not only by the co-factor fibrin but also by productive, protein-protein interactions between t-PA and plasminogen that occur at a site or sites distinct from the enzyme's active site.
We have previously observed that disruption of a surface loop that maps
to one edge of the active site of t-PA and is homologous to the
"autolysis loop" of trypsin dramatically reduces the catalytic efficiency of t-PA for plasminogen.2
Examination of this region of the protease domain of t-PA in the
crystal structure revealed the presence of three hydrophobic residues,
Leu420,3 Pro422,
and Phe423, that were fully exposed to solvent, and
therefore candidates for interaction with substrates, inhibitors,
and/or co-factors (Fig. 1) (11). Consequently, we
hypothesized that this region of the "autolysis loop" of t-PA,
residues 420-423, may form an important secondary site of interaction
between t-PA and plasminogen. To test this hypothesis, we used
site-specific mutagenesis to construct a series of nine single-chain
and nine two-chain variants of t-PA containing point mutations at
positions 420-423.
Point mutations mapping to residues 420-423 of t-PA significantly decreased the catalytic efficiency of t-PA for plasminogen activation in the absence of fibrin. The activity of all nine single-chain variants was reduced in this assay by factors varying from 2 to 14. The activity of eight of the nine two-chain variants was also reduced by factors of approximately 2-7 compared with wild type t-PA. These data suggest that residues 420-423, particularly Leu420, Pro422, and Phe423, form, or are critical for the integrity of, an important, secondary site of interaction between t-PA and plasminogen in the absence of fibrin.
Oligonucleotide-directed
site-specific mutagenesis was performed by the method of Zoller and
Smith (12) as modified by Kunkel (13). Mutations were introduced into
the 290-base pair SacI-SmaI fragment of cDNA
encoding t-PA that had been previously subcloned into bacteriophage
M13mp18. The nine point mutations introduced into t-PA and the
corresponding mutagenic oligonucleotides were as follows: L420A,
5-AAGCATGAGGCCGCATCTCCTTTCTATT-3
; L420E, 5
-AAGCATGAGGCCGAGTCTCCTTTCTATT-3
; S421G,
5
-CATGAGGCCTTGGGACCTTTCTATTCGG-3
; S421E,
5
-CATGAGGCCTTGGAGCCTTTCTATTCGG-3
; P422A,
5
-GAGGCCTTGTCTGCATTCTATTCGGAG-3
; P422G,
5
-GAGGCCTTGTCTGGATTCTATTCGGAG-3
; P422E,
5
-GAGGCCTTGTCTGAGTTCTATTCGGAG-3
; F423A,
5
-GGCCTTGTCTCCTGCATATTCGGAGCGG-3
; F423E,
5
-GGCCTTGTCTCCTGAGTATTCGGAGCGG-3
.
Following mutagenesis, ssDNA corresponding to the entire 290-base pair SacI-SmaI fragment was fully sequenced to assure the presence of the desired mutation and the absence of any additional mutations. Replicative form DNA was prepared for appropriate phage, and the mutated 290-base pair SacI-SmaI fragments were recovered after digestion of the replicative form DNA with SacI and SmaI and electrophoresis of the digestion products on a 1.8% agarose gel. Each isolated 290-base pair SacI-SmaI fragment was used to replace the corresponding fragment of cDNAs encoding both t-PA and t-PA/R275E, thereby reconstructing full-length cDNAs encoding the following 18 variants of t-PA: t-PA/L420A; t-PA/R275E,L420A; t-PA/L420E; t-PA/R275E,L420E; t-PA/S421G; t-PA/R275E,S421G; t-PA/S421E; t-PA/R275E,S421E; t-PA/P422A; t-PA/R275E,P422A; t-PA/P422G; t-PA/R275E,P422G; t-PA/P422E; t-PA/P422E,R275E; t-PA/F423A; t-PA/R275E,F423A; t-PA/F423E; and t-PA/R275E,F423E.
Expression of Wild Type and Mutated Enzymes by Transient Transfection of COS CellscDNAs encoding all 18 variants
described above were ligated into the transient expression vector pSVT7
(14) and then introduced into COS 1 cells by electroporation using a
Bio-Rad Gene Pulser. 20 µg of cDNA, 100 µg of carrier DNA, and
approximately 107 COS cells were placed into a 0.4-cm
cuvette, and electroporation was performed at 320 V, 960 microfarads,
and =
. Following electroporation, cells were incubated
overnight at 37 °C in Dulbecco's modified Eagle's medium
containing 10% fetal calf serum and 5 mM sodium butyrate.
Cells were then washed with serum-free medium and incubated in
Dulbecco's modified Eagle's medium for 48 h at 37 °C. After
the incubation with serum-free media, conditioned media were collected,
and enzyme concentrations were determined by enzyme-linked
immunosorbent assay.
Wild type and mutated variants of t-PA were purified using a fast protein liquid chromatography system and a 1-ml HiTrap chelating column (Pharmacia Biotech Inc.). The column was charged with 0.1 M CuSO4 solution, washed with 5-10 ml of distilled water, and equilibrated with start buffer (0.02 M NaHPO4, pH 7.2, 1 M NaCl, and 1 mM imidizole). Conditioned medium containing wild type or variants of t-PA was adjusted to 1 M NaCl and injected into the column with a 50-ml superloop (Pharmacia). The column was then washed with 10 column volumes of start buffer and eluted using a 0-0.32 M linear gradient of imidizole in the same buffer. Peak fractions were collected and pooled. Purified t-PA samples were concentrated, and buffer was exchanged to 25 mM Tris (pH = 7.5), 50 mM NaCl, 1 mM EDTA, using a Centriplus 30 concentrator (Amicon).
Kinetic Analysis of t-PA Activity Using Small Synthetic SubstratesThe direct chromogenic assay utilized the substrate methylsulfonyl-D-cyclohexyltyrosyl-glycyl-arginine-p-nitroaniline (Spectrozyme t-PA; American Diagnostica) and was performed as described previously (15-18).
Kinetic Analysis of Plasminogen Activation Using Indirect Chromogenic AssaysIndirect chromogenic assays of t-PA utilized the substrates Lys-plasminogen (American Diagnostica) and H-D-norleucyl-hexahydrotyrosyl-lysine-p-nitroaniline diacetate salt (Spectrozyme PL; American Diagnostica) and were performed as described previously (18-20). Assays were performed both in the presence and absence of the co-factor DESAFIB (American Diagnostica). The concentration of Lys-plasminogen was varied from 0.0125-0.2 µM in the presence of DESAFIB and from 0.9 to 15 µM in the absence of the co-factor.
Inhibition of Wild Type and Mutated Variants of t-PA by PAI-1Approximately 0.25-1 ng of wild type or mutated variant of t-PA was preincubated at 23 °C for 15 min with varying concentrations of highly purified, active PAI-1. Following this preincubation, each mixture was diluted, and the residual enzymatic activity was measured using a standard indirect chromogenic assay as described previously (14-16).
Kinetics of the Inhibition of t-PA by PAI-1Second order
rate constants for inhibition of t-PA by PAI-1 were measured under
pseudo-first order conditions as described previously (15, 16, 19-22).
Briefly, enzyme and inhibitor were preincubated at 23 °C for periods
of time varying from 0 to 30 min. Following preincubation, the mixtures
were diluted, and residual enzymatic activity was measured in the
indirect chromogenic assay and compared with control reactions in which
PAI-1 was either omitted from the reaction or added after
preincubation, dilution, and the addition of fibrin, plasminogen, and
Spectrozyme PL to the reaction mixture. For each enzyme, the
concentrations of enzyme and inhibitor were chosen to yield several
data points for which the residual enzymatic activity varied between 20 and 80% of the initial activity, and the molar excess of PAI-1 over
t-PA was always more than 20-fold. Data were analyzed by plotting
ln(residual activity/initial activity) versus time of
preincubation and calculating the resulting slope. Division of this
slope by [PAI-1] produced the second order rate constant
(M
1 s
1).
To investigate the functional significance of residues 420-423 in the "autolysis loop" of t-PA, we used oligonucleotide-directed site-specific mutagenesis to introduce point mutations at each of these four positions. A total of nine variants were constructed; Leu420 was replaced by alanine or glutamic acid, Ser421 was replaced by glycine or glutamic acid, Pro422 was replaced by glycine, alanine, or glutamic acid, and Phe423 was replaced by alanine or glutamic acid. Because it has been demonstrated that activation cleavage of both trypsinogen and chymotrypsinogen resulted in a striking rearrangement of the autolysis loop of these enzymes, it is quite possible that the interactions formed by residues 420-423 will differ for single- and two-chain t-PA (23-26). It was therefore essential to assay both the single- and two-chain form of each variant of t-PA containing a mutation in the autolysis loop. Accurate measurement of the enzymatic activity toward plasminogen of the single-chain form of these variants proved difficult, however, because plasmin produced during the assay rapidly and efficiently converted the enzymes into their mature, two-chain form by cleaving the Arg275-Ile276 bond of the single-chain t-PA. Consequently, to overcome this technical difficulty, we also constructed noncleavable forms of the nine mutated enzymes by introducing the additional mutation R275E into the new variants, a strategy that was first described by Tate and co-workers (27).
Wild type t-PA, t-PA/R275E, and all 18 variants containing mutations in the autolysis loop were cloned into the expression vector pSTV7 and produced by transient expression in COS cells. Since this procedure yielded predominantly single-chain enzymes, two-chain t-PAs were generated by treating the enzyme preparations with plasmin-Sepharose. Quantitative conversion of the enzymes into their two-chain forms was confirmed by SDS-PAGE and Western blotting. As previously demonstrated (27), variants containing the mutation R275E were not cleaved by plasmin-Sepharose (data not shown).
Kinetic Analysis of Catalytic Activity toward a Small, Synthetic SubstrateNone of the nine point mutations in the autolysis loop of t-PA significantly affected the catalytic activity of the mature, two-chain form of the enzyme toward a small, synthetic substrate (Table I). Six of the two-chain variants possessed at least 92% of the activity of two-chain t-PA in this assay, and all nine of these variants displayed at least 75% of the activity of the corresponding wild type enzyme.
|
The nine point mutants mapping to residues 420-423 had slightly larger effects on the activity of the single-chain form of t-PA toward the synthetic substrate (Table I). Although six of the single-chain variants maintained at least 82% of the activity of single-chain t-PA, one of the variants, t-PA/S421G, displayed only 15% of the activity of the wild type enzyme in this assay. The catalytic activity of the remaining two variants, t-PA/R275E,P422G and t-PA/R275E,S421E, was 25 or 33%, respectively, that of single-chain t-PA.
Fibrin did not stimulate the activity of t-PA, t-PA/R275E, or any of the 18 new variants toward the synthetic substrate Spectrozyme t-PA (data not shown). Interaction of these enzymes with fibrin, therefore, does not appear to significantly influence the conformation of the active site.
Kinetic Analysis of Catalytic Activity toward the Physiological Substrate PlasminogenIn the presence of the co-factor fibrin, point mutations in residues 420-423 have very small effects on plasminogen activation by either single- or two-chain t-PA (Table II). Six of the nine two-chain variants possessed at least 86% of the activity of two-chain, wild type t-PA, and the catalytic efficiency of the least active two-chain variant, t-PA/P422E, was reduced by a factor of less than 2 compared with the wild type enzyme. Similarly, five of the nine single-chain variants had at least 70% of the activity of single-chain t-PA in this assay, and the catalytic efficiency of the least active single-chain variant was reduced by a factor of approximately 2 compared with the single-chain wild type enzyme (Table II). As observed with the two-chain variants, the least active single-chain variant contained the P422E mutation.
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The catalytic efficiency for plasminogen activation in the absence of fibrin of the two-chain form of variants containing point mutations in residues 420-423 varied from 15 to 100% that of two-chain, wild type t-PA (Table III). Eight of the nine variants possessed higher affinity for plasminogen than wild type t-PA. This property was particularly evident for t-PA/L420E, t-PA/P422E, and t-PA/P422G, whose Km for plasminogen was reduced by factors of 7-8 compared with that of the wild type enzyme. kcat values for the two-chain variants, however, were all reduced, by factors varying from 2.4 to 45, compared with wild type t-PA (Table III).
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All nine mutations in the autolysis loop of t-PA that we characterized significantly decreased plasminogen activation by single-chain t-PA in the absence of fibrin (Table III). For individual variants, kcat values for this reaction were decreased by factors varying from 3 to 48, resulting in catalytic efficiencies that were reduced by factors varying from 1.6 to 14. The affinity of the variants for plasminogen under these conditions was actually enhanced; Km values for the mutated enzymes were decreased by factors varying from 1.3 to 4.6.
Fibrin Stimulation of Plasminogen Activation by the Variants of t-PAMolecular details of the stimulation of t-PA by fibrin, a complex process that almost certainly involves multiple points of contact between the two proteins, remain obscure (1, 28-32). Fibrin stimulation of two-chain t-PA may occur through a single mechanism; stimulation of single-chain t-PA by fibrin co-factors, however, appears to utilize at least two distinct mechanisms. First, fibrin apparently stimulates both single- and two-chain t-PA through a templating mechanism, resulting in formation of a ternary complex, which greatly augments the local concentration of enzyme and substrate. Second, because single- and two-chain t-PA have equivalent activity in the presence but not in the absence of fibrin (19, 27, 33, 34), it seems likely that binding to fibrin induces a conformational change in the activation domain of single-chain t-PA. Induction of this conformational change in the absence of activation cleavage and concomitant generation of the mature amino terminus is particularly intriguing but not unprecedented. Similar activation of plasminogen upon binding to streptokinase (35-40) as well as activation of prothrombin by binding to staphylocoagulase (41, 42) have been described previously. Although the mechanism of this nonclassical, nonproteolytic activation of serine protease zymogens remains completely unclear, the behavior of the single-chain variants of t-PA containing mutations in the autolysis loop suggests that Leu420, Ser421, Pro422, and Phe423 do not play an essential role in this process. The properties of the corresponding two-chain variants suggest, in addition, that these residues do not play an essential role during zymogen activation of t-PA through the classical, proteolytic mechanism.
The extent of fibrin stimulation displayed by the single-chain form of the variants carrying mutations in the autolysis loop is significantly greater than that displayed by wild type t-PA. Wild type two-chain t-PA possesses a fibrin stimulation factor, defined as the ratio of the catalytic efficiencies in the presence and absence of fibrin, of approximately 650 (Table V). Single-chain wild type t-PA, with a fibrin stimulation factor of 9300, is stimulated to a substantially greater degree than the two-chain enzymes, presumably reflecting the ability of fibrin to stimulate the single-chain enzyme not only through a templating mechanism but also by inducing nonproteolytic zymogen activation. Stimulation of single-chain t-PA is further enhanced by mutations in the autolysis loop. The fibrin stimulation factors for single-chain t-PA/R275E,S421E and t-PA/R275E,P422E, for example, are 31,400 and 61,000, respectively. Enhanced fibrin stimulation of the variants did not result from increased activity in the presence of fibrin but rather from decreased activity in the absence of a stimulator, an observation consistent with our proposal that the effects of these mutations are mediated by disruption of contacts between t-PA and plasminogen that are functionally significant in the absence, but not the presence, of fibrin.
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To test whether any of the nine mutations in the autolysis loop of t-PA affected the interaction of either single- or two-chain t-PA with PAI-1, the primary inhibitor of t-PA present in human plasma, we preincubated a fixed amount of enzyme with varying concentrations of highly purified, active PAI-1 and then diluted each mixture and measured the residual enzymatic using a standard, indirect chromogenic assay. The behavior of all nine two-chain variants in this assay was indistinguishable from that of two-chain t-PA (data not shown). We conclude, therefore, that the solvent-exposed, hydrophobic region of the autolysis loop of two-chain t-PA does not form significant interactions with PAI-1.
Similar results were obtained when the nine single-chain variants were
subjected to this assay. None of the single-chain variants behaved
significantly differently from single-chain wild type t-PA (data not
shown); however, these data did suggest that two of the single-chain
variants, t-PA/R275E,S421G and t-PA/R275E,P422G, might be inhibited by
PAI-1 slightly less rapidly than single-chain t-PA. To examine this
possibility, we measured the rate of inhibition by PAI-1 for
t-PA/R275E, t-PA/R275E,S421G, and t-PA/R275E,P422G, and these data
indicated that the second order rate constants for inhibition of the
single-chain form of t-PA/R275E,S421G and t-PA/R275,P422G were,
respectively, 3.4 × 105 and 5.0 × 105 M1 s
1, or
approximately 2-3-fold lower than that observed with single-chain t-PA
(Table IV).
The chymotrypsin family has evolved to contain many members functioning in the same milieu (e.g. human plasma) that are exclusive in their reactivity toward both substrates and inhibitors. While the role of the "specificity pocket" of a serine protease in determining the "primary" or P1 specificity of the enzyme has long been appreciated (43-45), additional determinants of protease specificity remain largely obscure. Although both the location and mechanism of action of these additional determinants of enzyme specificity remain unclear, their existence and critical importance are well established. For example, t-PA and almost all other proteases that participate in the fibrinolytic cascade, the coagulation cascade, and complement activation possess virtually identical, trypsin-like primary specificity pockets and exhibit identical P1 specificity (i.e. they cleave COOH-terminal to arginine and lysine residues). Nevertheless, most of these enzymes display very different substrate and inhibitor specificity.
Previous studies have strongly suggested that the stringent specificity of t-PA for plasminogen is mediated in part by productive protein-protein interactions that are distinct from those occurring in the enzyme's active site (8-10). In the presence of fibrin, plasminogen activation by t-PA is an extremely complex reaction that appears to occur after formation of a ternary complex involving multiple sites of contact among enzyme, substrate, and co-factor (6). While sites within all five structural domains of t-PA have been implicated in interaction of the enzyme with fibrin (29, 30, 46), the importance, and even the existence, of direct, secondary contacts between t-PA and plasminogen in the ternary complex remain obscure.
In the absence of fibrin, plasminogen activation by t-PA is a significantly less complex but also less efficient reaction. Nevertheless, even in the absence of co-factor, t-PA retains stringent specificity for plasminogen (8). Since the target sequence present in plasminogen appears to be a very poor match to optimal subsite occupancy for a t-PA (9), the specificity of t-PA for plasminogen under these conditions seemed very likely to be mediated by a direct, secondary interaction or interactions between t-PA and plasminogen. The goal of this investigation was to identify regions of t-PA that participated in these interactions, and our major finding is that residues 420-423 of t-PA, a solvent-exposed, hydrophobic region of the "autolysis loop" of t-PA, forms, or is critical for the integrity of, an important, secondary site of interaction between t-PA and plasminogen.
During their evolution from a trypsin-like progenitor, serine proteases have acquired amino acid substitutions, deletions, and insertions most often at the protein surface, and these mutations frequently map to surface loops located near the enzyme's active site (47). We have previously suggested that the recruitment of these substituted or inserted residues, located in surface loops near the active site, to participate in specific enzyme-substrate and enzyme-inhibitor interactions is an important and recurring theme in the evolution of specificity by chymotrypsin family enzymes (14-16, 18, 29). Our studies of the determinants of specificity for t-PA have proved consistent with this hypothesis. We have previously reported that residues located on one surface loop near the enzyme's active site modulate the interaction of t-PA with its primary endogenous inhibitor PAI-1 (14, 16), and this study demonstrated that residues mapping to another surface loop near the active site can modulate the interaction of the enzyme with substrate.
The elucidation of a secondary site of interaction between t-PA and plasminogen that exerts a substantial effect in the absence, but not the presence, of fibrin provides new insight into molecular details of the evolution of stringent substrate specificity by t-PA and also suggests a novel strategy to enhance the co-factor dependence of t-PA. In fact, several of the variants described in this initial study already possess this property. While plasminogen activation by wild type t-PA is stimulated by a factor of approximately 650, the corresponding fibrin stimulation factors for t-PA/R275E,S421G; t-PA/R275E,S421E; t-PA/R275E,P422G; and t-PA/R275E,P422E, for example, are 29,200, 31,400, 39,000, and 61,000, respectively (Table V). It is therefore possible that, compared with wild type t-PA, these variants would display enhanced "clot selectivity" in vivo due to reduced activity in the circulation but full activity at a site of fibrin deposition. Whether enhanced clot selectivity would improve the enzyme as a thrombolytic agent remains extremely controversial; however, this property may assume increased importance as variants of t-PA with a prolonged circulating half-life are administered as a single bolus.