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J Biol Chem, Vol. 274, Issue 34, 24080-24086, August 20, 1999
From the Laboratory of Pathology, NCI, National Institutes of
Health, Bethesda, Maryland 20892
A synthetic peptide containing amino acid
residues 190-201 of thrombospondin-1 (TSP1) promoted adhesion of
MDA-MB-435 breast carcinoma cells when immobilized and inhibited
adhesion of the same cells to TSP1 when added in solution. Adhesion to
this peptide was enhanced by a Expression of the The We recently found that Proteins and Peptides--
Calcium replete TSP1 was purified
from human platelets (15). Synthetic peptides containing TSP1 sequences
were prepared as described previously (16-21). Recombinant fragments
(provided by Dr. Tikva Vogel) and GST fusion proteins expressing
fragments of TSP1 (provided by Dr. Jack Lawler, Harvard University)
were prepared as described previously (22, 23). Bovine type I collagen and murine Type IV collagen were obtained from Becton Dickinson Labware
division, and human vitronectin was from Sigma. Fibronectin was
purified from human plasma (National Institutes of Health Blood Bank)
as described (24). Murine laminin-1 purified from the EHS tumor was
provided by Dr. Sadie Aznavoorian (NCI, National Institutes of Health).
Recombinant human insulin-like growth factor-1 (IGF1) was from Bachem.
Adhesion Assays--
Adhesion was measured on polystyrene or
glass substrates coated with peptides or proteins as described
previously (16). Inhibition assays were performed using the following
function-blocking antibodies: 6D7 ( Motility Assays--
Chemotaxis of MDA-MB-435 cells to TSP1
peptides was measured in modified Boyden chambers using
polylysine-coated 8 µm polycarbonate filters as described previously
for intact TSP1 (14).
Multiple Sequence Alignment--
Protein sequences were compared
using MACAW software (National Center for Biotechnology Information,
National Library of Medicine, version 2.0.5) by the segment pair
overlap and Gibbs sampler methods (27, 28).
In initial attempts to localize the region of TSP1 recognized by
the A multiple alignment search using MACAW software was used to identify
TSP1 sequences that might be related to the
Identification of an 
3
1 Integrin
Recognition Sequence in Thrombospondin-1*
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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1 integrin-activating
antibody, Mn2+, and insulin-like growth factor I and
was inhibited by an 
31 integrin
function-blocking antibody. The soluble peptide inhibited adhesion of
cells to the immobilized TSP1 peptide or spreading on intact TSP1 but
at the same concentrations did not inhibit attachment or spreading on
type IV collagen or fibronectin. Substitution of several residues in
the TSP1 peptide with Ala residues abolished or diminished the
inhibitory activity of the peptide in solution, but only substitution
of Arg-198 completely inactivated the adhesive activity of the
immobilized peptide. The essential residues for activity of the peptide
as a soluble inhibitor are Asn-196, Val-197, and Arg-198, but flanking
residues enhance the inhibitory activity of this core sequence, either
by altering the conformation of the active sequence or by interacting
with the integrin. This functional sequence is conserved in all known
mammalian TSP1 sequences and in TSP1 from Xenopus laevis.
The TSP1 peptide also inhibited adhesion of MDA-MB-435 cells to the
laminin-1 peptide GD6, which contains a potential integrin-recognition
sequence Asn-Leu-Arg and is derived from a similar position in a
pentraxin module. Adhesion studies using recombinant TSP1 fragments
also localized 1 integrin-dependent adhesion to residues
175-242 of this region, which contain the active sequence.
INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
31 integrin is
essential for normal development in the kidney and lungs (1). Targeted
mutation of the murine 3 integrin gene
resulted in abnormal branching morphogenesis of kidney capillary loops
and lung bronchi. Based on antibody inhibition, this integrin may also
be important for branching morphogenesis in mammary epithelia (2). In
addition to its essential roles in normal development, the
31 integrin may play important roles in
disease processes, such as cancer. Loss of integrin 3
subunit expression is a negative prognostic factor in lung
adenocarcinoma (3). Conversely, overexpression of
31 integrin in a human rhabdomyosarcoma
line suppressed tumor formation in mouse xenografts (4).
31 integrin has been reported to
recognize several extracellular matrix ligands, including some
laminins, type IV collagen, fibronectin, thrombospondin-1, and
entactin/nidogen (5-8). Although short peptide recognition motifs have
been identified in ligands for some integrins (reviewed in Ref. 9),
previous attempts to define recognition sequences for binding of matrix
ligands to the 31 integrin have produced
conflicting results. High affinity binding of recombinant soluble
31 could be detected only to laminin-5
(10), so binding to other matrix ligands may be of relatively low
affinity. Under specific conditions, this integrin can recognize the
common integrin binding sequence RGD in fibronectin (6). However,
recombinant entactin with the RGD sequence deleted (11) and synthetic
peptides from laminin-1 and type IV collagen that lack the RGD motif
(12, 13) also bound specifically to the
31 integrin. Laminin peptide GD6
(KQNCLSSRASFRGCVRNLRLSR) and the type IV collagen peptide affinity
purified 31 integrin from cell extracts
when immobilized on agarose beads (12, 13), but the active peptides
from these two proteins share no apparent sequence homology. These
data, combined with the evidence that RGD-dependent and
RGD-independent adhesion are differentially regulated in
31 integrin (6), have led to the proposal
that the 31 integrin uses distinct
mechanisms to interact with each of its ligands and that no conserved
binding motif may exist (6).
31 is the major
TSP11-binding integrin on
several human breast carcinoma cell lines (14). We have further
examined this interaction and report the identification of a peptide
sequence from TSP1 that supports
31-dependent adhesion and
chemotaxis and is a potent inhibitor of adhesion to TSP1.
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ABSTRACT
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EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
21),
P1B5 (Life Technologies, Inc., 31), 407279 (Calbiochem, 41), and P1D6 (Life
Technologies, Inc., 51). The
1 integrin-activating antibody TS2/16 (25) was prepared from the hybridoma obtained from the American Type Culture Collection. Immunofluorescence analysis of cell adhesion was performed as described
previously, using BODIPY TR-X phallacidin (Molecular Probes, Inc.,
Eugene, OR) to visualize F-actin or using murine primary antibodies
followed by BODIPY FL anti-mouse IgG to localize integrins, vinculin
(Sigma), or focal adhesion kinase (clone 77, Transduction Laboratories)
(26).
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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31 integrin, we tested approximately
85% of the TSP1 sequence in the form of synthetic peptides or GST or
T7 fusion proteins for promotion of 1
integrin-dependent adhesion of MDA-MB-435 cells (Fig.
1). Among the recombinant fragments
tested, only an 18-kDa fragment of the N-terminal heparin-binding
domain had significant adhesive activity, although the recombinant type
I repeats had adhesive activity for MDA-MB-435 cells in some
experiments (results not shown). A recombinant GST fusion of the type 3 repeats of TSP1 including the RGD sequence had minimal adhesive
activity for MDA-MB-435 cells (Fig. 1), in contrast to human melanoma
cells, which avidly attached on substrates coated with the same
concentrations of this fragment (26). The 1
integrin-activating antibody TS2/16 did not enhance cell attachment to
any of these recombinant fragments but reproducibly stimulated
attachment on intact TSP1 (Fig. 1). Synthetic heparin-binding peptides
from the type 1 repeats (peptide 246) (16) and the CD47-binding peptide
4N1K (21) also promoted adhesion, but TS2/16 did not enhance adhesion
of MDA-MB-435 cells to these peptides. CD36-binding peptides from the
procollagen domain (peptide 500) or the type 1 repeats (Mal-II) (29)
had weaker adhesive activities and were also insensitive to TS2/16. The
focal adhesion disrupting peptide Hep1 from the N-terminal domain of
TSP1 (20) did not promote MDA-MB-435 cell adhesion. Although these
experiments did not detect a 1
integrin-dependent adhesive sequence in TSP1, the
possibility remains that these regions of TSP1 contain a
conformation-dependent recognition motif that is inactive
in the recombinant fusion proteins due to misfolding.
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Fig. 1.
Adhesion of MDA-MB-435 breast carcinoma cells
to recombinant TSP1 fragments and synthetic TSP1 peptides.
Adhesion to synthetic TSP1 peptides adsorbed at 10 µM
(246, KRFKQDGGWSHWSPWSS; 500, NGVQYRNC;
Mal II, SPWSSCSVTCGDGVITRIR; 4N1K, KRFYVVMWKK;
HepI, ELTGAARKGSGRRLVKGPD), TSP1 (0.11 µM), recombinant 18-kDa heparin-binding domain
(HBD) (2.7 µM), or GST fusion proteins
expressing the TSP1 procollagen domain (procoll.), type 1, 2, or 3 repeats, or GST alone (2 µM) was measured in the
absence (solid bars) or presence (striped bars)
of 20 µg/ml of the 1 integrin-activating antibody
TS2/16. Results (mean ± S.D) are presented for a representative
experiment performed in triplicate.
31 integrin-binding GD6 peptide derived
from the A chain of murine laminin-1 (12), which strongly promoted
MDA-MB-435 cell adhesion (Fig.
2A). This search identified
four TSP1 sequences related to the laminin peptide (Table
I). The single peptide identified by the
Gibbs sampler method, derived from the C-terminal domain of TSP1
(residues 1059-1077), did not support adhesion or inhibit adhesion of
MDA-MB-435 cells to TSP1 or other 31
integrin ligands (Fig. 2A and results not shown). Because a
synthetic peptide containing the last 12 residues of peptide GD6
(peptide 679, Table I) had similar activity to the intact peptide (see
below), we did not test the two peptides identified by segment pair
overlap that aligned outside this sequence. Both of these peptides were
derived from regions of the type 1 (residues 392-405) or type 2 (residues 598-608) repeat sequences that did not support
31-dependent adhesion when
expressed as GST fusion proteins (Fig. 1).
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Fig. 2.
MDA-MB-435 adhesion to TSP1 peptides and
laminin-1 peptide GD6. A, MDA-MB-435 breast carcinoma
cell attachment (closed symbols) and spreading (open
symbols) was determined on polystyrene substrates coated with the
indicated concentrations of TSP1 peptide 678 (FQGVLQNVRFVF)
(circles), TSP1 peptide 701 (TPGQVRTLWHDP)
(squares), or the murine laminin-1 peptide GD6
(KQNCLSSRASFRGCVRNLRLSR) (triangles). Results are
presented as mean ± S.D. (n = 3). B,
spreading of MDA-MB-435 or MDA-MB-231 cells on substrates coated with
3.3 µM TSP1 peptide 678, 1.1 µM laminin-1
peptide GD6, or 50 µg/ml TSP1 was determined using untreated cells
(black bars) or cells treated with 5 µg/ml of the
1-activating antibody TS2/16 (gray bars) or 3 nM IGF1 (striped bars) (MDA-MB-435 cells only);
mean ± S.D. (n = 3).
TSP1 sequences related to murine laminin-1 peptide GD6
The remaining sequence is from a region of the N-terminal domain of
TSP1 (residues 188-199) that was not covered by the recombinant fragments tested in Fig. 1 and conserves most of the hydrophilic residues in the laminin-1 GD6 peptide that could mediate
protein-protein interactions. This sequence also overlaps with a region
identified in a screen of N-terminal TSP1 peptides as having
heparin-independent adhesive activity (30). A synthetic peptide
containing this TSP1 sequence (peptide 678) had strong adhesive
activity for MDA-MB-435 cells (Fig. 2A). Spreading of two
breast carcinoma cell lines on this peptide, laminin peptide GD6, and
TSP1 was enhanced in the presence of the 1
integrin-activating antibody TS2/16 (Fig. 2B). We previously
found that IGF1 strongly stimulated 1 integrin-mediated adhesion to TSP1 (14). IGF1 similarly stimulated spreading of MDA-MB-435 cells on the TSP1 peptide 678 and to the laminin peptide GD6
(Fig. 2B).
The TSP1 peptide 678 strongly inhibited spreading of MDA-MB-435 cells
on TSP1 and murine EHS tumor-derived laminin-1/entactin but did not
inhibit spreading of the same cells on the
51 integrin ligand fibronectin or on type
IV collagen (Fig. 3A). The
TSP1 peptide in solution strongly inhibited MDA-MB-435 cell attachment to itself and to GD6 (Fig. 3B), a known
31 integrin-binding peptide from murine
laminin-1 (12). In contrast, the laminin peptide was a relatively weak
inhibitor of adhesion to either peptide or TSP1 when tested in solution
(IC50 = 700 µM, data not shown).
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The TSP1 peptide 678 sequence was not in the recombinant N-terminal
fragment tested in Fig. 1, but the previously reported 28-kDa
N-terminal fragment of TSP1 contains this sequence (22). Adhesion
assays using MDA-MB-231 (Fig. 3C) and MDA-MB-435 breast carcinoma cell lines (data not shown) verified that the larger fragment, expressing residues 1-242, contains a 1
integrin-dependent adhesion sequence that is not present in
residues 1-174. Adhesion to the longer fragment was stimulated by the
1-activating antibody TS2/16 and inhibited by peptide
678 (Fig. 3C). Therefore, a 1 integrin-binding site is present in residues 175-242 of TSP1 and is
functional when expressed as a recombinant protein.
To verify that the TSP1 peptide 678 contains an
31 integrin recognition sequence,
integrin -subunit antibodies were tested for blocking adhesion to
the peptide (Fig. 4). The
3-specific blocking antibody P1B5, which we have shown
to inhibit adhesion of the same cells to intact TSP1 (14), partially
inhibited adhesion of MDA-MB-435 cells on peptide 678 and completely
reversed the enhancement of MDA-MB-435 cell adhesion to the same
peptide stimulated by the 1 integrin-activating antibody
TS2/16. In a further control experiment, the
21-blocking antibody 6D7 inhibited
adhesion of MDA-MB-435 cells to type I collagen but not to peptide 678 (Fig. 4B). Function-blocking antibodies for
41 and 51
integrins also had no effect on adhesion to peptide 678 (data not
shown). Therefore, the peptide does not support adhesion mediated by
41 or 51
integrins or inhibit adhesion to other integrin ligands.
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Divalent cation dependence is also characteristic for binding of
integrin ligands. Although Mn2+ but not Ca2+
induced the expected increase in MDA-MB-435 cell spreading on TSP1
peptide 678 and intact TSP1 (Fig. 4C), addition of EDTA only minimally inhibited basal spreading on peptide 678. EDTA completely inhibited the spreading on TSP1 observed in medium containing Mg2+ as the sole divalent cation, although it did not
inhibit cell attachment on TSP1 (Fig. 4C and results not
shown). This residual adhesion probably results from the significant
contribution of proteoglycans to adhesion of MDA-MB-435 cells on TSP1
(14). Spreading on peptide 678 with Mg2+ as the divalent
cation became partially sensitive to EDTA, however, in the presence of
the 1-activating antibody TS2/16. Addition of
Mn2+ further stimulated spreading on peptide 678 and intact
TSP1 in the presence of TS2/16, but addition of Ca2+
produced a dose-dependent inhibition of spreading on both
substrates. Specific inhibition by Ca2+ is consistent with
previous data for the 31 integrin (31). These results suggest that integrin binding to peptide 678 is partially
independent of divalent cations, but MDA-MB-435 cell spreading on this
peptide may involve both 31
integrin binding and divalent cation-independent interactions
with another cell surface molecule.
Truncated peptides that contained portions of peptide 678 were
synthesized to identify essential residues (Fig.
5). Truncation of the N-terminal Phe or
the C-terminal Val-Phe only moderately decreased adhesive activity, but
further truncations from either end of the peptide greatly diminished
its activity. Inhibition assays confirmed that the loss of adhesive
activity reflected loss of integrin binding rather than loss of ability
to adsorb on the substrate (Table II). As
found in the direct adhesion assays, peptides without the N-terminal
Phe or the C-terminal Val-Phe retained significant inhibitory
activities, but all shorter peptides were weak inhibitors or inactive.
These results imply that the integrin recognizes an extended sequence,
but this approach could not discriminate conformational effects of
flanking sequences from a direct contribution to integrin binding.
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To better define those residues involved in
31 integrin binding, we systematically
substituted Ala residues into the peptide 678 and tested each for
adhesive activity (Fig. 6). Based on the complete loss of adhesion activity for MDA-MB-435 cells following its
substitution, only Arg-198 was essential for adhesive activity of
peptide 678 (Fig. 6). Replacement of Arg-198 with a His also dramatically reduced adhesive activity. Ala substitutions at several other positions significantly decreased adhesive activity, except for
the two N-terminal residues, which only slightly decreased adhesive
activity.
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Although only the Arg residue was essential for direct adhesion,
substitution of several additional residues with Ala markedly decreased
or abolished inhibitory activity of the respective soluble peptides in
solution to block
31-dependent adhesion to
immobilized peptide 678 (Table III).
These experiments showed that Arg-198, Val-197, and Asn-196 are
essential for inhibitory activity of the peptides in solution.
Substitution of Phe-199 and Phe-201 decreased the inhibitory activities
of the respective peptides 5-8-fold, indicating that these flanking
residues also contribute to activity of the peptides in solution. In
contrast, peptides with Ala substitutions at four of the six N-terminal
residues in this sequence had inhibitory activities equivalent to that of the native TSP1 sequence. Therefore, NVR is the essential sequence for binding to the 31 integrin, but
flanking residues may be necessary for inducing the proper conformation
of this minimal sequence in peptide 678.
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The specificity for an Arg residue at position 198 was further examined using conservative amino acid substitutions (Table III). Substitution with Lys decreased activity approximately 2-fold, whereas substitution with Gln, to retain hydrogen-bonding ability while removing the positive charge, abolished the inhibitory activity. A His substitution showed intermediate activity, indicating that a positive charge rather than a large side chain with hydrogen bonding ability is required at this position.
The active peptides strongly promoted formation of filopodia in
MDA-MB-435 cells (Fig. 7A)
similar to those induced by attachment on intact TSP1 (14). Addition of
IGF1 enhanced spreading and increased formation of lamellipodia on the
same peptide (Fig. 7B). Phallacidin staining demonstrated
organization of F-actin at the cell periphery but no organization of
stress fibers across the cell body (Fig. 7C). Using
antibodies recognizing vinculin (Fig. 7D) and focal adhesion
kinase (data not shown) as markers of focal adhesion formation, we
could not detect any induction of focal adhesions in MDA-MB-435 cells
attaching on these peptides, although the same markers showed typical
focal adhesion staining patterns in the cells when attaching on
vitronectin or fibronectin substrates (results not shown). Staining for
the 31 integrin was punctate and
prominently localized in filopodia extended by MDA-MB-435 cells on
immobilized peptide 678 (Fig. 7F), whereas total
1 integrin staining was more diffuse and concentrated
over the cell body.
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TSP1 stimulates chemotaxis of MDA-MB-435 cells, and this response is
inhibited by the 31-blocking antibody
P1B5 (14). Peptide 678 also stimulated chemotaxis of MDA-MB-435 cells
(Fig. 8). Chemotaxis to peptide 678 was
dose-dependent with a maximal response at 10 µM (Fig. 8A). This response was specific in
that peptide 690 was inactive. In agreement with the observations that IGF1 stimulated 1 integrin-dependent
chemotaxis of MDA-MB-435 cells to TSP1 (14) and adhesion of the same
cells to peptide 678 (Figs. 2 and 7), the chemotactic response of
MDA-MB-435 cells to peptide 678, but not to peptide 690, was increased
in the presence of IGF1 (Fig. 8B).
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DISCUSSION |
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
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Based on examination of synthetic peptides and recombinant
fragments representing approximately 90% of the TSP1 sequence, only
the sequence FQGVLQNVRFVF from the N-terminal domain exhibited activities that are expected for an 31
integrin binding sequence in TSP1. A recombinant fragment of TSP1
containing this sequence also promoted 1
integrin-dependent adhesion. In solution, this peptide
specifically inhibited adhesion to TSP1 but not to ligands recognized
by other integrins. Adhesion to this peptide and to TSP1 was stimulated
by IGF1 receptor ligands that stimulate integrin-dependent adhesion to intact TSP1, by Mn2+, and by a 1
integrin-activating antibody and partially inhibited by an
31 function-blocking antibody. Based on
systematic amino acid substitutions in the active sequence, NVR appears
to be the essential core sequence in this TSP1 peptide for recognition
by the 31 integrin.
Adhesive activities of the immobilized peptides imply that only Arg-198
may directly participate in this interaction, although the partial
resistance to inhibition by an 31
integrin antibody and EDTA suggest that the peptides with Arg may also
support adhesion independent of integrin binding. The context
surrounding the Arg is important, however, because other peptides with
similar sequences (such as peptide 701, with a QVRT sequence) had no
activity, and Ala substitutions of the flanking residues in peptide 678 eliminated or markedly decreased its inhibitory activity in solution.
The essential amino acid residues are completely conserved in human, murine, bovine, and Xenopus TSP1, but in chicken TSP1, a His
replaces the Arg. A similar motif is found in murine and human TSP2,
with a His residue replacing the Arg. As a free peptide, the TSP1
sequence with a His substitution was much less active, so it is not
clear whether the TSP2 sequence could be recognized by
31 integrin. Activity of the latter
sequence may be increased in an environment that increases protonation
of the imidazole in His.
Previous publications have not identified a consensus
31 integrin recognition sequence in its
ligands. One hypothesis is that different ligands have unrelated
binding sequences, which is supported by a recent mutagenesis study
(32). However, other recent data have raised questions about whether
all of the proteins reported to mediate
31-dependent adhesion are
true 31 ligands (33). LamA2 and LamA3
were verified to bind 31 integrin. These have potential binding motifs based on our data, but human LamA1, which
was found not to bind 31 with high
avidity, has an Ala in the position occupied by the essential Arg in
the TSP1 sequence. Substitution of Ala for the Arg in the TSP1 sequence
abolished all activity of the synthetic TSP1 peptide. Among the five G
domain modules of LamA3, G2 has a better consensus sequence based on our results (NLK) than does G4 (NFQ) or G5 (NIH). Expressed as recombinant proteins, only the G2 module promoted
31-dependent adhesion (34).
Although RGD was reported to be an 31
ligand, the RGD in entactin is not required for recognition, and the
RGD in the type 3 repeats of TSP1 is not recognized by this integrin. A
binding site for the 31 integrin in
entactin was mapped to the G2 domain (residues 301-647) (11). Multiple
alignment of this region of entactin against the TSP1 sequence and the
murine laminin-1 peptide GD6 identified a related sequence,
FSGIDEHGHLTI, but this sequence lacks all of the essential residues in
the TSP1 sequence. This domain of entactin also contains two
NXR sequences: NNRH and NGRQ. It remains to be determined
whether either of these can function as an
31 integrin recognition sequence.
The absence of an Asp residue in peptide 678 may account for its partial independence of divalent cations. An Asp residue is usually considered an essential element for integrin peptide ligands (35, 36). According to one model for integrin ligand binding, the divalent cation participates directly in binding an Asp-containing peptide ligand (reviewed in Ref. 37). Thus an integrin peptide ligand without a carboxyl side chain cannot coordinate with a bound divalent cation and therefore may not have a divalent cation requirement for binding to the integrin. The alternate model, proposing an indirect role of divalent cations in integrin activation (37), would be consistent with the observed stimulation of cell spreading on peptide 678 by Mn2+ but not Ca2+ and the partial inhibition following chelation of divalent cations.
Another interpretation of the partial divalent cation independence for
the adhesive activity of peptide 678 is that ionic interactions of the
Arg side chain in the TSP1 peptide with the negatively charged cell
surface contribute to the adhesive activity of this peptide. Weak ionic
interactions could promote adhesion to the immobilized peptide through
multivalent interactions with negatively charged glycoproteins and
proteoglycans on the cell but would not significantly contribute to
binding of the same monovalent peptide to the cell in solution. This
hypothesis would explain why the Arg-containing peptides 686 and 691, in which the essential Val or Asn residues were substituted with Ala,
lacked activity in solution to inhibit adhesion to
31 ligands but retained some adhesive
activity when immobilized. Thus, inhibitory activities in solution may
provide a more reliable assessment of integrin binding specificity for
Arg-containing peptides.
Spreading of MDA-MB-435 breast carcinoma cells on intact TSP1 (14) or
the 31 integrin-binding peptide 678 induces formation of filopodia. In cells plated on peptide 678, these
structures are enriched in the 3 integrin subunit,
suggesting that engagement of this integrin by TSP1 triggers formation
of filopodia. Formation of filopodia or microspikes has been noted
during attachment of other cell types on TSP1 (38). This response may
be mediated by the 31 integrin, because
lamellar spreading rather than formation of filopodia was typically
observed on melanoma cells that predominantly use the
v3 integrin receptor for spreading on
TSP1 (26).
Using multiple sequence alignment, the N-terminal domains of
thrombospondins were recently shown to contain a module related to
pentraxins and to the G domain modules of laminins (39). Based on this
alignment, both the 31 integrin-binding
sequence from TSP1 identified here and the GD6 sequence of laminin are located at the C terminus of a pentraxin module. The known
three-dimensional structures of other members of the same superfamily
(40, 41) lead to the prediction that both potential integrin binding
sequences are located in the last -strand of a pentraxin module and
therefore may be presented with similar topologies on the laminin G
domain and the N-terminal domain of TSP1. This observation suggests an evolutionary relationship between the thrombospondin N-terminal domains
and laminin G domains that is consistent with their proposed common
function as recognition sites for a 1 integrin receptor.
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ACKNOWLEDGEMENTS |
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We thank Drs. Ken Yamada and Harvey Gralnick for providing antibodies and Jack Lawler and Tikva Vogel for providing recombinant TSP1 fragments and fusion proteins.
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FOOTNOTES |
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* This work was supported in part by United States Department of Defense Grant DAMD17-94-J-4499.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed: Bldg. 10, Rm. 2A33, 10 Center Dr., MSC 1500, NIH, Bethesda, MD 20892-1500. Tel.: 301-496-6264; Fax: 301-402-0043; E-mail: droberts@helix.nih.gov.
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ABBREVIATIONS |
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The abbreviations used are: TSP, human thrombospondin; GST, glutathione S-transferase; IGF1, insulin-like growth factor-1.
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REFERENCES |
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
REFERENCES
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) or laminin peptide GD6 (
) was
measured in the presence of the indicated concentrations of peptide 678 added in solution. C, adhesion of MDA-MB-231 cells to the
indicated recombinant TSP1 fragments was measured in RPMI medium
containing 0.1% bovine serum albumin (black bars) or the
same medium containing 5 µg/ml of the 
