(Received for publication, August 19, 1996, and in revised form, March 11, 1997)
From the Department of Microbiology, University of Virginia Health
Sciences Center, Charlottesville, Virginia 22908 and
Science Institute, University of Iceland,
Reykjavik, Iceland
Snake venom hemorrhagic metalloproteinase toxins that have metalloproteinase, disintegrin-like and cysteine-rich domains are significantly more potent than toxins with only a metalloproteinase domain. The disintegrin-like domains of these toxins differ from the disintegrin peptides found in crotalid and viperid venoms by the nature of their different disulfide bond structure and, in lieu of the disintegrins' signature Arg-Gly-Asp (RGD) integrin binding sequence, there is an XXCD disulfide-bonded cysteinyl sequence in that region. Due to these apparent differences, the contribution to the overall function of the hemorrhagic metalloproteinases by the disintegrin-like domain has been unknown. In this investigation we have expressed in insect cells the disintegrin-like/cysteine-rich (DC) domains of the Crotalus atrox hemorrhagic metalloproteinase atrolysin A and demonstrated that the recombinant protein (A/DC) can inhibit collagen- and ADP-stimulated platelet aggregation. Using synthetic peptides, we have evidence that the region of the disintegrin-like domain that is positionally analogous to the RGD loop of the disintegrins is the site responsible for inhibition of platelet aggregation. For these synthetic peptides to have significant inhibitory activity, the -RSECD- cysteinyl residue must be constrained by participation in a disulfide bond with another cysteinyl residue. The two acidic amino acids adjacent to the middle cysteinyl residue in these peptides are also important for biological activity. These studies emphasize a functional role for the disintegrin-like domain in toxins and suggest structural possibilities for the design of antagonists of platelet aggregation.
The distinctive characteristic of envenomation by a crotalid or viperid snake is local and in severe cases systemic hemorrhage. The profuse hemorrhage observed is usually due to the synergistic action of a large number of toxins in the venom (1, 2). However, the toxins primarily responsible for hemorrhage are snake venom zinc metalloproteinases (SVMPs),1 which are members of the reprolysin subfamily of the M12 family of metalloproteinases (3-5). These toxins, as isolated from crude venom, belong to one of three related structural classes, P-I, -II, and -III, which primarily differ from one another by the presence of additional domains on the carboxyl side of the metalloproteinase domain (4). The P-I class has only a metalloproteinase domain, whereas the P-II class has a disintegrin or disintegrin-like domain carboxyl to the proteinase domain. The P-III class metalloproteinases have yet another domain, the cysteine-rich domain, which is found carboxyl to the disintegrin-like domain.
The P-III class of venom metalloproteinases is related to the ADAMs/MDCs group of type I integral membrane protein. These protein groups have homologous proteinase, disintegrin-like and cysteine-rich domain structures, and these proteinases are classified as members of the reprolysin subfamily of metalloproteinases (5). However, the ADAMs/MDC proteinases possess additional carboxyl-terminal structures comprised of epidermal growth factor-like, transmembrane, and cytoplasmic domains (6-9).
The biological function of many of the ADAMs/MDCs proteins is unclear,
except for the fertilins and
, which are involved in egg-sperm
fusion (10), meltrins, which are involved in myoblast fusion (11), and
KUZ, a Drosophila protein which participates in neurogenesis
(12). In the case of the fertilins, which are the most functionally
characterized of the group, the disintegrin-like domain of fertilin is
thought to modulate egg-sperm fusion by interaction of the
disintegrin-like domain of the sperm fertilin with the
6
1 integrin on the egg (13). The
structural features of the disintegrin-like domain important in this
interaction are not known with certainty but may involve a specific
sequence of the disintegrin-like domain of fertilin (13).
Disintegrins are peptides, isolated from the venoms of crotalid and
viperid snakes, and range in length from 49 to 84 amino acid residues.
They function as potent inhibitors of platelet aggregation (14-16).
The RGD sequence in a 13-residue -loop structure (the RGD loop) is
the critical structural moiety responsible for biological activity and
is central to the interaction of the disintegrins with the platelet
integrin
IIb
3 (17, 18). The disulfide bond structure of these peptides also contributes to the activity of
the disintegrins (19, 20). The disintegrins are derived from homologous
precursors of the P-II class of snake venom metalloproteinases by the
processing of precursors comprised of pre-, pro-, metalloproteinase, and disintegrin domains (21).
The homologous region of the class P-III SVMPs differs from the
disintegrins and their P-II precursors in several ways. Due to these
differences, we have termed them "disintegrin-like" domains. Disintegrin-like domains have two additional cysteinyl residues compared with the disintegrins, and therefore the disulfide bond arrangement is likely to be different. We hypothesize that one of these
cysteines is involved in a disulfide bond with a region amino-terminal
to the disintegrin-like domain (the spacer region) which links the
disintegrin-like domain with the proteinase domain (Fig.
1). The other cysteinyl residue is thought to be in a disulfide bond
linkage with a cysteinyl residue in the cysteine-rich domain carboxyl
to the disintegrin-like domain (22). This would form the spacer region,
the disintegrin-like domain, and cysteine-rich domain into one
continuous, disulfide bond-interconnected structure. The other notable
difference between the disintegrin-like domains of the SVMPs and the
disintegrin peptides is that while most disintegrins contain the RGD
integrin-binding consensus sequence, to date no disintegrin-like domain
of the class P-III SVMPs has been reported with the RGD consensus
sequence. Furthermore, the additional cysteinyl residue found in the
XXCD sequence described above for disintegrin-like
domains lies in the middle of the loop where in the disintegrins the
RGD sequence is located. Therefore, the topology of the
disintegrin-like domain in this area is probably very different from
that observed in the disintegrins proper (23, 24). This would certainly
be the case if that cysteinyl residue were involved in a disulfide
bond.
Since the class P-III hemorrhagic proteinases are significantly more potent than the class P-I toxins, we hypothesize that the additional carboxyl domains in the P-III toxins make an important contribution to the overall higher potency of this class of hemorrhagic toxins (22). To explore this concept, we have expressed in insect cells the combined disintegrin-like/cysteine-rich domains (A/DC) of atrolysin A, the most potent hemorrhagic toxin from the western diamondback rattlesnake Crotalus atrox. We now report on the ability of the recombinant A/DC protein as well as synthetic peptides designed from the SECD sequence region of the disintegrin-like domain to inhibit platelet aggregation. The structural role of the middle cysteinyl residue and adjacent acidic residues in the SECD loop region of disintegrin-like domains is also described.
Standard recombinant DNA techniques were used to clone the
A/DC fragment into the baculovirus pMbac vector (Stratagene Cloning Systems, La Jolla, CA). The DNA fragment encoding the disintegrin-like and cysteine-rich domains of atrolysin A was generated by polymerase chain reaction from an atrolysin A cDNA clone (4). Two
oligonucleotide primers were designed for the polymerase chain reaction
amplification and cloning. The upstream primer was
5-CAATGACCCGGGGCAAACAGATATAATTTCAC-3
and the downstream primer used
was 5
-GATCTGGATCCTCAAATCTGAGAGAAGCCAGA-3
. These two primers were
designed to include SmaI and BamHI restriction sites, respectively, for in-frame insertion into the
SmaI/BamHI-linearized pMbac vector. The pMbac
vector contains the signal sequence for melittin so that the
recombinant protein should be secreted into the media. Prior to
ligation into the pMbac vector, the A/DC polymerase chain reaction
fragment (657 base pairs) was ligated into the pCR II TA cloning vector
(Invitrogen) for propagation and then restriction with
SmaI/BamHI. The accuracy and frame information of
A/DC in the pMbac vector was confirmed by complete DNA sequence and
restriction analysis of the insert (25). Recombinant baculoviruses were
generated by co-transfection of Sf9 (Spodoptera frugiperda) cells with the pMbac vector containing the A/DC insert (pMbac/A/DC) and
AcNMPV nuclear polyhedrosis virus according to manufacturer's instructions (BaculoGold Transfection Kit, PharMingen). Plaque assays
were performed, and following three rounds of plaque purification a
population of homogeneous, recombinant A/DC baculovirus particles were
obtained.
Sf9 cells at a cell density of 2-3 × 106 cell/ml were transfected with the recombinant
baculovirus at a ratio of 10 plaque-forming units per insect cell. The
infected cells were harvested after 4 days by centrifugation at 4 °C
for 15 min at 3000 rpm. The pelleted cells were resuspended in lysis
buffer (10 mM Tris-HCl buffer, pH 8.0, 1 mM
EDTA, 0.2 mM phenylmethylsulfonyl fluoride) and then disrupted in a French press. The suspension was centrifuged at 4 °C
for 30 min at 15,000 × g and the resultant supernatant
dialyzed against 20 mM Tris-HCl buffer, pH 8.0 at 4 °C.
The dialyzed solution was then loaded onto a DEAE-cellulose
ion-exchange column (1.5 × 40 cm) equilibrated with dialysate
buffer, and the column was developed with a linear gradient of 0-1
M NaCl in the equilibration buffer. Fractions were
monitored by SDS-PAGE on 12% gels (26) and by Western blot analysis
using an anti-atrolysin A polyclonal antibody (27). The fractions
identified as containing A/DC were pooled and dialyzed against the
standard equilibration buffer. This dialyzed solution was then applied
to a MonoQ 5/5 column (Pharmacia Biotech Inc.), and the column was
developed with a 0-1 M NaCl gradient in the equilibration
buffer. Pooled fractions containing A/DC were concentrated using a
Centricon-30 concentrator (Amicon) and then loaded onto a Sephacryl
S200 (Pharmacia) column (1.5 × 150 cm) developed with a 20 mM Tris-HCl buffer, pH 8.0, 100 mM NaCl, at a
flow rate of 15 ml/h. Fractions containing the A/DC protein, which were
homogeneous by SDS-PAGE and Western blot analysis following this
chromatography, were pooled, concentrated with a Centricon-30
cartridge, and stored at
20 °C.
Isolated A/DC protein
was subjected to amino-terminal sequence analysis on an ABI 470A
protein sequencer operated according to manufacturer's instructions.
The molecular mass of A/DC was determined by MALD-TOF mass spectrometry
using a Finnigan Lasermat 1000 mass spectrometer with
-cyano-4-hydroxycinnamic acid as the matrix. Atrolysin A and
recombinant A/DC were alkylated under nonreducing conditions with
[14C]iodoacetate (53 mCi/mmol, DuPont NEN) in a 6 M guanidine HCl, 100 mM Tris-HCl, pH 7.5, alkylation buffer. Following alkylation, the proteins were desalted by
reverse-phase chromatography on a C-8 (5 µm) column (5 × 30 mm)
with a two-buffer gradient elution (buffer A, 0.1% trifluoroacetic
acid in H2O and buffer B, 0.1% trifluoroacetic acid in
80% CNCH3 and 20% H2O). Fractions containing 14C-labeled A/DC were detected by absorbance at 214 nm,
SDS-PAGE/autoradiography and by scintillation counting. Another
C. atrox hemorrhagic metalloproteinase, atrolysin E, which
has been demonstrated to contain a free cysteinyl residue (28), was
subjected to the same alkylation procedure for use as a positive
control.
All peptides were synthesized at the
50-µmol scale on a Symphony multiple peptide synthesizer (Rainin)
using Fmoc (N-(9-fluorenyl)methoxycarbonyl) chemistry as
suggested by the manufacturer and modified according to individual
peptide sequences (29). Peptide amide linker resin with 0.37 mmol/g
substitution (PerSeptive Biosystems) was used as the solid support.
Cleavage and deprotection of the peptides were performed on the
synthesizer using 88% trifluoroacetic acid, 2% diisopropylsilane, 5%
H2O, and 5% phenol. Following cleavage, the
ether-extracted crude peptide product was desalted and purified on a
preparative C18 reverse-phase column (250 × 21.4 mm, Rainin) using a 0.1% trifluoroacetic acid/H2O buffer with a
gradient in acetonitrile (5-80%). The purity of all peptides was
assessed by analytical reverse phase-high performance liquid
chromatography and MALD-TOF mass spectrometry using previously
established methods (29). Only peptides deemed greater than 98% pure
by reverse phase-high performance liquid chromatography were used in
the platelet aggregation studies. Following synthesis, all peptides were lyophilized and stored under N2 at 30 °C until
used.
In peptide 1 (see Table I) the carboxyl-terminal cysteinyl residue was protected with an Acm group, and the cysteinyl residues at positions 1 and 8 were protected with trityl groups that were removed during cleavage of the peptide from the resin. A disulfide from Cys1 to Cys8 was introduced by air oxidation. Similarly, peptide 2 was synthesized by protection of cysteinyls 8 and 14 with trityl groups and cysteinyl 1 with an Acm group.
|
Peptide 3 was synthesized by protection of Cys1 and Cys14 with Acm groups and Cys8 with a trityl group. Following cleavage and deprotection, Cys8 was alkylated with iodoacetic acid (30). Peptide 4, is based on the peptide 3 sequence except that the cysteinyl residue at position 8 is substituted by serine. Peptide 5 is based on peptide 1 structure except that the glutamyl residue at position 7 is substituted with an alanyl residue. Peptide 6 is also based on peptide 1 structure except the aspartyl residue at position 9 is substituted with an alanyl residue. Peptide 7 is the double alanyl-substituted peptide at positions 7 and 9. Peptide 8 is the Arg-Gly-Asp-Ala-substituted form of Arg-Ser-Glu-Cys sequence in peptide 3.
Platelet Aggregation AssaysHuman blood was obtained from healthy donors who had not taken any medications within the previous 10 days. Blood was drawn into Becton Dickinson VACUTANER 228 containing 0.129 M sodium citrate with a final ratio of buffer to blood of 1:9. The tube was then centrifuged at 500 × g for 5 min. The platelet-rich plasma was transferred into a clean tube. Platelet concentration was measured with a Cell-Dyn-3000 cell counter (Abbott Diagnostics). The assay for platelet aggregation was conducted at 37 °C in an aggregometer (Payton, CO). The concentration of platelets used in each assay was 250,000 cells/µl at a final assay volume of 0.5 ml. The extent of platelet aggregation was quantitated by measuring the total amplitude at a predetermined time interval following addition of the platelet stimulant (collagen, 0.5 µg/ml, or ADP, 1 µM; ChronoLog Corp.). To assay for the ability of atrolysin A, the recombinant protein A/DC or the synthetic peptides, to inhibit platelet aggregation, the antagonists were dissolved in phosphate-buffered saline at pH 7.4, 20 mM MgCl2 immediately before use. The antagonist solution was preincubated with platelet-rich plasma for 4 min at 37 °C prior to stimulation of platelet aggregation by collagen or ADP. The extent of the inhibition of platelet aggregation was assessed by comparison with the maximal aggregation induced by the control dose of agonist (1 µM ADP or 0.5 µg/ml collagen) and then expressed as a percentage. IC50 values were determined from dose-response curves generated from the various concentrations used for the antagonists. All experiments were performed in triplicate on blood from at least three different donors.
The translated DNA sequence for A/DC that was inserted into
the pMbac vector is shown in Fig. 2. The expression of
recombinant A/DC in transfected Sf9 cells was followed over time, and
it was determined by Western blot analysis of Sf9 cells that day 4 post-transfected cells yielded the most product (Fig.
3). Little product was observed secreted into the medium even though a
secretion expression vector had been used.
The chromatograms seen in Fig. 4 represent a typical
isolation of A/DC from a 1-liter culture of Sf9 cells (2 × 106 cells/ml). From a 1-liter culture of transfected cells,
the typical yield of purified A/DC was approximately 1 mg. The
homogeneity of purified A/DC following the chromatography is seen in
Fig. 5. Purified atrolysin A (4) was used as a standard
for molecular weight comparison and Western blot analysis.
The amino-terminal sequence of A/DC determined from Edman degradation
is given in Fig. 6. The first five residues are derived from the signal sequence of melittin, as coded for by the expression vector, and are then followed by the A/DC sequence. The MALD-TOF mass
spectrum of A/DC is also shown in Fig. 6. The experimental mass was
determined to be 24,479 (M+H ion) compared with 24,154 for
the calculated mass, a difference of approximately 300 mass units or
1.3%. The explanation for this small discrepancy is unclear; however,
there is a possibility for glycosylation of this protein. From protein
sequence studies of atrolysin A, there are two N-linked
glycosylation consensus sequences in the cysteine-rich domain,
GSNVT and SGNNS (Fig. 2 and Ref. 4).
Deglycosylation of A/DC with N-glycanase (Genzyme) caused a
decrease in mass of approximately 278 mass units (data not shown)
suggesting that glycosylation at one or both of those sites gives rise
to the difference in the experimental versus the calculated
mass of A/DC. The peak at 12314 mass units is the M2+H
ion.
14C-Carboxymethylation of nonreduced A/DC yielded product with no incorporation of label. Atrolysin E, which is known to have one "free" cysteine, incorporated approximately 26 mCi of 14C per mmol, which relates to 0.8 cysteines/molecule of atrolysin E. This was similar to the 30 mCi of 14C per mmol found in atrolysin A. The complete sequence of mature atrolysin A also has an odd number of cysteinyl residues (4). Since both atrolysin E and atrolysin A were approximately equally labeled, we concluded that atrolysin A has a single free cysteine. Furthermore, based on the lack of counts associated with the alkylation of A/DC, it was therefore concluded that all the cysteinyl residues of recombinant A/DC are involved in disulfide bonds and that the unpaired cysteinyl residue in atrolysin A resides in the metalloproteinase domain.
Platelet Aggregation Inhibition by Atrolysin A and A/DCAs
seen in Figs. 7A and
8A and Table I, the hemorrhagic
metalloproteinase atrolysin A was a potent inhibitor of collagen and
ADP-stimulated platelet aggregation. The recombinant A/DC protein was
also a potent inhibitor of platelet aggregation (Figs. 7B
and 8B and Table I) but not to the same extent as atrolysin A, having a 4.3-fold greater IC50 value than atrolysin A
for collagen-stimulated platelets. The IC50 of A/DC was of
the same order of magnitude as observed for the disintegrins. Reduction
and carboxyamidomethylation of A/DC caused a loss of all inhibitory
activity (data not shown).
Platelet Aggregation Inhibition by Synthetic Peptides
The
IC50 values for inhibition of collagen-stimulated platelet
aggregation by synthetic peptides are seen in Table I. Peptide 1, which is the cyclized Cys1-Cys8
disintegrin-like region was a potent inhibitor of collagen-stimulated platelet aggregation with an IC50 of 218 ± 42 µM (Fig. 9). Peptide 2, which was the
Cys8-Cys14 form of the peptide, also was
demonstrated to be an inhibitor of platelet aggregation with an
IC50 of 391 ± 31 µM. Peptide
3 which is a linear peptide where the Cys8 is
alkylated and hence not constrained in a disulfide bond lacks inhibitory activity. Similarly, peptide 4, in which the Cys8 of peptide 3 is substituted by a serinyl
residue, also lacks activity. Peptides 5, 6, and
7 represent an alanine scanning substitution for the
Glu7 and Asp9 residues adjacent to
Cys8. In peptide 5, which has a Glu7
Ala substitution, there is an approximate 2.5 decrease in
activity compared with peptide 1. Peptide 6,
which has an Asp9
Ala substitution, the
IC50 value is approximately 1000 µM. When
both the Glu7 and Asp9 are substituted with
alanyl residues there is an even greater decrease in activity, with an
apparent IC50 value significantly greater than 1 mM; however, due to peptide solubility, a more precise
value could not be obtained. Peptide 8, which is the
RGDA-substituted form of the RSEC residues in peptide 1, was
demonstrated to have potent collagen and ADP-stimulated platelet aggregation inhibition activity. The IC50 values for both
collagen and ADP-stimulated platelet aggregation inhibition by peptide 1 are of the same order of magnitude for those observed with
linear RGD containing peptides (14).
The protein inhibitors of platelet aggregation, such as atrolysin A, the recombinant A/DC protein, and the disintegrins themselves are significantly more active than their RGD/RGD-like loop peptide derivatives. Therefore, upon consideration of these data, it may be concluded that additional structural features other than those represented simply by a linear array of amino acids in the synthetic peptides, even though they are somewhat structurally constrained, are essential for the full inhibitory potential of these proteins.
It is generally observed that the higher molecular weight hemorrhagic metalloproteinases from snake venoms, as represented by the class P-III toxins, are significantly more toxic than the P-I class toxins (1). For example, the minimum hemorrhagic dose of atrolysin E, the most potent class P-II hemorrhagic toxin from the western diamondback rattlesnake C. atrox, is 1 µg/mouse. Atrolysin A, also from C. atrox venom, is a P-III toxin, which in addition to its proteinase domain has disintegrin-like and cysteine-rich domains. Its minimum hemorrhagic dose is 0.04 µg, making atrolysin A 25 times more hemorrhagic than atrolysin E, which in its mature form contains only a metalloproteinase domain. This observation led to our hypothesis that the additional domains of the P-III toxins contribute to their greater hemorrhagic potency. The functionality explored in this study is whether the disintegrin-like domain of the P-III toxins can serve to inhibit platelet aggregation and thus potentiate the production of hemorrhage.
The ability of atrolysin A to inhibit platelet aggregation is an interesting and novel observation stemming from this study. Unfortunately, due to the presence of three domains in atrolysin A, each with its own potential biological activity, it is unclear which domain(s) is responsible for the inhibition of platelet aggregation. The investigation into the contribution of the disintegrin-like domain of atrolysin A to inhibit platelet aggregation required expression of that recombinant domain. Expression of the disintegrin-like domain of atrolysin A failed to produce monomer product; therefore, we constructed and expressed in insect cells a recombinant protein comprised of the spacer region/disintegrin-like and the cysteine-rich domains of atrolysin A. The failure to express the disintegrin-like domain alone may be attributed to the possibility that there is one disulfide bond linking the spacer region with the disintegrin-like domain and one disulfide bond linking the disintegrin-like domain with a cysteinyl residue in the cysteine-rich domain (Fig. 2 and Ref. 22). This hypothesis is based on the comparison of the structures of disintegrin-like domains of the SMVPs and the ADAMs groups of the reprolysins to the structures of various venom disintegrins (4, 8, 14, 22, 31, 32). Ultimately, determination of the disulfide bond arrangement in the disintegrin-like and cysteine-rich domains of the P-III class of snake venom metalloproteinases will be necessary to prove the hypothesis.
Baculovirus expression of recombinant A/DC in insect cells was
successful, ultimately yielding a protein with the ability to inhibit
both collagen- and ADP-stimulated platelet aggregation. This suggests
that A/DC is acting at the level of the
2
1 collagen integrin and/or the
fibrinogen receptor,
IIb
3, on platelets (33-35). From the studies with the synthetic peptides one may conclude that the functional portion of A/DC involved in platelet binding resides in the disintegrin-like domain. However, at this point we have
no direct evidence to exclude interactions with platelet integrins
through the cysteine-rich domain of A/DC. The hemorrhagic toxin
jararhagin, which is a structural homologue of atrolysin A, has been
demonstrated to bind to the
2 subunit of the
2
1 integrin to inhibit platelet adhesion
to collagen (36). Jararhagin has also been shown to cause the
proteolytic loss of the platelet collagen receptor,
2
1, and to degrade the adhesive plasma
protein von Willebrand factor (37).
Although A/DC blocked platelet aggregation, it was somewhat less potent
than atrolysin A. Whether this reflects the presence of additional
inhibitory motifs in the structure of atrolysin A or the proteolytic
effects of the metalloproteinase domain of atrolysin A, as appears to
be the case with jararhagin, is unknown. Alternatively, the recombinant
structure may not reflect the actual structure of the disintegrin-like
domain as found in the P-III toxins. IC50 values for
ADP-stimulated platelet aggregation inhibition by snake venom
disintegrins range from approximately 100 to 555 nM (14,
16). The IC50 values of atrolysin A and recombinant A/DC
for ADP-stimulated platelet aggregation inhibition determined in this
study were 240 and 320 nM, respectively, which are
comparable to those observed for the disintegrins. This similarity of
potency of A/DC to the disintegrins is of great interest given the
significant differences in the sequences in this region of the
disintegrin (-like) domains of these proteins, particularly in the
sense that A/DC lacks the cell-binding RGD consensus sequence. However,
it has been reported that the RGD sequence need not be strictly
conserved in the disintegrins for a potent ability to inhibit platelet
aggregation (38, 39). In the case of barbourin, the disintegrin
isolated from Sistrurus miliarus barbouri, in lieu of the
RGD sequence, there is a conserved substitution of the arginine with
lysine (39). This disintegrin has an IC50 value for
inhibition of platelet aggregation similar to that observed for
RGD-containing disintegrins (14). In another example, using a murine
Fab fragment specific for the integrin
IIb
3, Kunicki and colleagues (40)
demonstrated that the cognate RGD sequence could be exchanged with RYD
without an alteration in integrin recognition. These data suggest that some limited diversity in this sequence region may be tolerated and
still give rise to a ligand with reasonable potency for inhibiting aggregation.
From structural studies of several disintegrins, the RGD sequence is
found positioned within an extended, flexible -loop structure where
there is only limited conformational restriction of the RGD sequence
(24, 32, 41, 42). Unfortunately, no similar structural information is
available for disintegrin-like domain containing proteins. Reduction
and alkylation of disintegrins cause a significant loss of platelet
aggregation inhibition activity (19, 20), which is also the case with
A/DC. Therefore, as in the disintegrins, the constrained display in
this region in the disintegrin-like domain of A/DC is critical for
activity. Nevertheless, there remain structural differences between
these regions of the disintegrin-like domain and the disintegrins based on their differences in sequence, disulfide bonding patterns, and
biological activities.
Using synthetic peptides, we have shown that the SECD
sequence region in the disintegrin-like domain of A/DC is involved in
platelet aggregation inhibitory activity. This region is the positional
homologue of the RGD loop of the disintegrins. The two significant
differences between this region of the disintegrin-like domains of the
SVMPs and the RGD region of the disintegrins are the
XX(E/D)CD substitution for RGDXX
sequences observed in the disintegrins and the presence of a disulfide
bonded cysteinyl residue (SECD) in the disintegrin-like
domain region. Given these significant differences, it is very
interesting that A/DC should have any ability to inhibit platelet
aggregation and suggests a somewhat different interaction of this
region of the disintegrin-like domain with the platelet
IIb
3 integrin compared with that for the
RGD disintegrins.
We have shown that the RSECD cysteinyl residue in atrolysin A and the recombinant A/DC is constrained by a disulfide bond. Although the synthetic peptides we tested were disulfide bonded from Cys1 to Cys8 or Cys8 to Cys14, this does not suggest that it is the same bonding pattern that occurs in the protein. However, since the RSECD cysteinyl residue is disulfide bonded in atrolysin A and A/DC, that region must be conformationally constrained with a quite different topology compared with the 13-member RGD loop of the disintegrins. This structural difference of the XXCD region of the disintegrin-like domain appears to be crucial for activity since the synthetic, linear peptides, which lack disulfide bonds or a free sulfhydryl, did not inhibit platelet aggregation.
A protein containing a disintegrin-like domain, which lacks a metalloproteinase domain, has been isolated and characterized from Bothrops jararaca venom and has a similar structure to the recombinant A/DC protein constructed for this study. This protein, jararhagin-C, begins with an amino-terminal sequence homologous to the spacer region of the P-III toxins followed by disintegrin-like and cysteine-rich sequences (43). Jararhagin-C can inhibit ADP- and collagen-induced platelet aggregation. The sequence of jararhagin-C is identical to the spacer/disintegrin-like/cysteine-rich domains of jararhagin, a 55-kDa hemorrhagic toxin from B. jararaca (44). Therefore, jararhagin-C is a proteolytically processed form of jararhagin. In this study, we have demonstrated that atrolysin A and the recombinant protein A/DC, comprised of the spacer/disintegrin-like/cysteine-rich domains, have potent platelet aggregation inhibitory activities. These data suggest an increased complexity for the venom of crotalid snakes from the standpoint of hemorrhagic toxicity. The high molecular weight P-III toxins can cause hemorrhage by direct proteolytic disruption of capillary basement membranes (31). They may also synergize hemorrhage production by inhibiting platelet aggregation via their disintegrin-like domain and by proteolysis of integrins and plasma adhesive proteins with their metalloproteinase domain. Indeed, the disintegrin-like and cysteine-rich domains may participate in the proteolytic specificity of these P-III toxins by directing them to the appropriate substrates. Hemorrhagic toxins are present in crotalid venoms, and their proteolytically processed fragments are comprised of spacer/disintegrin-like/cysteine-rich domains, as well as the disintegrins proper, all of which give rise to a very potent mixture of active proteins contributing to hemorrhage production and inhibition of platelet aggregation. Therefore, it is understandable that hemorrhage production is one of the foremost pathological consequences of crotalid snake envenomation.
In summary we have shown that the class P-III hemorrhagic toxin, atrolysin A from C. atrox, is a potent inhibitor of platelet aggregation. Our studies with synthetic peptides demonstrate that the region of the disintegrin-like domain of atrolysin A which is positionally analogous to the RGD loop of the disintegrins is primarily responsible for blocking platelet aggregation. The RSECD sequence in the disintegrin-like domain requires conformational restriction through disulfide bonding of the cysteinyl residue for biological activity. These considerations, plus the fact that the critical sequence is not an RGD sequence, suggest that different structural parameters are responsible for the biological activity of the disintegrin-like domains of the P-III toxins and the disintegrin-like domains of the ADAMs/MDC proteins. The data reported in this study provide a new structural framework for the development of novel integrin antagonists.
We thank Dr. John Humphries and John Sanders, University of Virginia Health Sciences Center, for their assistance with the platelet aggregation studies and Dr. Adrian Gear, University of Virginia Health Sciences Center, for the scientific discussions of the data and critical reading of the manuscript.