Department of Cell Biology, Box 3709, Duke University Medical Center,
Durham, NC 27710, USA
* Present address UMR CNRS 5091, Université de Bordeaux 2, Institut
François Magendie, 33077 Bordeaux, France
Present address: Department of Biological Sciences, Columbia University, New
York, NY 10027, USA
Author for correspondence (e-mail:
h.erickson{at}cellbio.duke.edu
)
Accepted 8 April 2002
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Summary |
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Key words: Fibronectin, Cell adhesion, Signalling, Multivalent, Dimerization, Oligomer
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Introduction |
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Two types of movement have been observed when beads are attached to
integrins on the dorsal surface. Random diffusion is the initial and sometimes
only movement, and is thought to indicate lack of attachment of the integrins
to the cytoskeleton. When the bead-bound integrins attach to the cytoskeleton
they stop diffusive movements and begin a rearward translocation at a constant
velocity, typically 1-2 µm/minute
(Schmidt et al., 1993). Two
factors are important for attachment to the cytoskeleton and rearward
translocation clustering of the integrins and occupancy of the
integrin by its matrix ligand. Felsenfeld et al. found that large (1 µm)
latex beads coated with a non-interfering antibody against ß1 integrin
demonstrated rearward translocation, while small (40 nm) gold beads coated
with the antibody showed only diffusive movements
(Felsenfeld et al., 1996
). When
the concentration of antibody was reduced, even the large beads showed only
diffusive movement, suggesting that integrin clustering was essential for
cytoskeletal attachment. The study went on to show that small gold beads
coated with FN7-10, a four-domain segment containing the central cell adhesion
domain of fibronectin (FN), showed rearward translocation, implying that
cytoskeletal attachment was significantly enhanced when the integrin was
occupied by its FN ligand. Clustering was still essential, since beads coated
with a low concentration of FN, probably one active molecule per bead, bound
transiently to the cell but did not attach to the cytoskeleton or
translocate.
Translocating beads coated with FN7-10 at first form a relatively weak
attachment to the cytoskeleton, and they can be pulled off by a modest force
using a laser trap (Choquet et al.,
1997). However, when beads were subjected to a sustained force for
10 seconds or more, the cell increased the strength of the bond. The cell thus
seems to be able to recruit additional cytoskeleton to attach a bead, allowing
it to overcome an applied force and continue rearward translocation. This
recruitment of cytoskeleton may be related to the findings that when FN-coated
beads were placed in contact with a cell they induced formation of an actin
cytoskeleton immediately beneath the point of bead binding
(Miyamoto et al., 1995a
;
Miyamoto et al., 1995b
). The
formation of actin cytoskeleton upon bead contact, and the strengthening of
attachment required both ligand binding and integrin clustering.
How many integrins are required to form a cluster that will attach to the cytoskeleton? To address this question we have made soluble oligomeric constructs with one, two, three and five copies of the cell adhesion domain of FN, with the idea that these would form small clusters of two to five integrins. We found that clusters as small as three integrins rapidly bound to and decorated a set of actin fiber bundles, and mediated translocation when bound in single copies to small beads.
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Materials and Methods |
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FN7-10 tandem dimer is a single polypeptide comprising two FN7-10 sequences separated by a GSGSHM linker. The second copy was amplified by PCR using pET-FN7-10 as a template, a forward primer inside the pET11b expression vector, and a reverse primer (5'-ATCATATGGGATCCCGAGCCTGTTCGGTAATTAATGGAAAT-3'). The reverse primer codes for ISINYRTGSGSHM, comprising the last seven amino acids of FN10, and a GSGSHM spacer (the final HM corresponds to the NdeI site added at the 3' end). The PCR product was subcloned into the TA vector (Stratagene) and sequenced. The insert, containing NdeI at both the 5' and 3' ends, was cut out and inserted into the single NdeI site of pET-FN7-10. A clone with the correct orientation was selected.
FN-TN trimer was constructed to have FN7-10 at the N-terminus, followed by
a spacer arm TN3-8 [comprising FN-III domains 3-8 from tenascin
(Aukhil et al., 1993)] followed
by the C-terminal trimer-forming sequence of chicken CMP (residues 451-492
EEDPCE...ENKII*) [for analysis of trimer assembly from the
corresponding segment of human CMP, see Beck et al.
(Beck et al., 1996
)]. The
pentamer was similar except that the oligomerization domain was the
pentamer-forming sequence of human COMP [residues 27-83
GDLAPQ...GLSV* (Efimov et al.,
1996
; Malashkevich et al.,
1996
; Tomschy et al.,
1996
)]. Domains were amplified with a 5' oligonucleotide
containing an SpeI site
(5'-TTCCTCACTAGTGAAGAAGATCCGTGCGAA-3' for CMP;
5'-TTCCTCACTAGTGGAGACCTAGCCCCACAG-3' for COMP) and a
3' oligonucleotide containing a stop and BamHI site
(5'-GGATCCGAATTCCTAGATGATTTTGTTTTC-3' for CMP;
5'-TCTCTCGGATCCGAATTCCTACACGCTCAGACC-3' for COMP),
subcloned in the TA vector and sequenced. Inserts were cut out and subcloned
in a Litmus-29 vector containing SpeI and BamHI sites in the
polycloning site. DNA corresponding to FN-III domains 3-8 of tenascin was
amplified with a 5' oligonucleotide containing an NdeI site and
a 3' oligonucleotide containing an SpeI site, and subcloned
into the Litmus-29 vector in front of CMP or COMP cDNA. Inserts were cut out
of Litmus-29 with NdeI and BamHI and ligated into pET 11b
vector cut by NdeI and BamHI. Control proteins TN3-8CMP and
TN3-8COMP (lacking the FN7-10 segment) were expressed from these vectors.
Finally, FN7-10 DNA with NdeI at each end was ligated into the
NdeI site of these vectors, and clones with the correct orientation
were selected.
FN-TN dimer utilized the 28 amino acid model coiled-coil segment
(EIEALKAEIEALKAEIEALKAEIEALKA) from the K6 peptide
(Tripet et al., 1997), which
was designed to form a stable two-stranded coiled coil. This segment was
constructed by a set of PCR reactions. The first PCR used as template an
oligonucleotide corresponding to the central segment of the K6 peptide
(5'-GAAGCATTAAAGGCTGAAATTGAGGCTCTAAAGGCTGAAATC-3') and primers
overlapping this and extending it in both directions: forward
(5'-GCACTCAAGGCTGAAATCGAAGCATTAAAGGCTGAA-3') and reverse
(5'-TAGAGCTTCGATTTCAGCCTTTAGAGC-3'). This first PCR product was
then amplified with a set of two primers containing the 5'
(5'-ACTAGTGAGATAGAAGCACTCAAGGCTGAAATC-3') and 3'
(5'-GGATCCCTATGCCTTTAGAGCTTCGATTTCAGC-3') ends with the
corresponding SpeI and BamHI restriction sites. The final
PCR product was subcloned in the TA vector and sequenced, and then inserted
into the trimer vector, replacing the SpeI-BamHI segment
containing CMP. Finally, the FN-TN monomer was constructed by subcloning the
FN7-10 segment into a pET11b containing TN fn3-8, using appropriate
restriction fragments.
FN-MukBcoil is a construct that places an FN7-10 at each end of a long
antiparallel coiled coil, with a flexible hinge in the middle. Construction
and purification of the dimeric FN-MukBcoil has been described previously
(Melby et al., 1998).
Expression in E. coli and purification of the proteins
Plasmids were transformed into E. coli BL21(DE3). Protein
expression was induced at A600=0.7 by adding 0.4 mM IPTG for 3 hours. Bacteria
were extracted with lysozyme and 0.1% Triton X-100, followed by two cycles of
freeze-thaw. Following centrifugation, all expressed proteins were in the
bacterial supernatant. Proteins were precipitated with ammonium sulfate, using
the following percentage saturation: FN7-10 monomer, 40%; FN-FN tandem dimer,
40%; FN-TN monomer, 40%; FN-TN dimer 35%; FN-TN trimer 30%; and FN-TN
pentamer, 25%. The ammonium sulfate pellets were resuspended in column buffer
(0.02 M Tris, pH 8, containing 0.1 M NaCl if it is to be run over a Sephacryl
column). FN7-10 monomer and FN-FN tandem dimer proteins were run directly over
a mono Q column (Amersham-Pharmacia; or resource Q, which seems equivalent).
All proteins containing TN spacer arm were run over a Sephacryl 100 or
Sephacryl 500 column (Amersham-Pharmacia) following ammonium sulfate
precipitation, and the peak fractions were applied to the mono Q column. All
the proteins eluted from the mono Q between 0.2 and 0.3 M NaCl. With the
trimer and pentamer we had the highest yield (5-10 mg per liter of bacteria)
when the purification was completed in 1 day; storing or freezing samples
before the mono Q step resulted in precipitation and loss of protein, as did
diluting the salt below 0.1 M. We discovered that the FN trimer and pentamer
precipitated in low salt, so we introduced a final purification step dialyzing
them into 20 mM Tris with no salt, collecting the precipitate by
centrifugation and resuspending it in Tris containing 0.2 M NaCl. On
non-reducing gels, the trimer and pentamer showed a mixture of oligomers (up
to trimer and pentamer, respectfully), suggesting only partial formation of
disulfide bonds. Other studies have shown that oligomerization is driven
primarily by the formation of the coiled coil, and that disulfide bond
formation is not essential (Beck et al.,
1996; Efimov et al.,
1996
).
Electron microscopy
HPLC fractions containing the proteins of interest were further purified by
gradient sedimentation on a 15-40% glycerol gradient in 0.2 M ammonium
bicarbonate. Peak fractions were rotary shadowed and examined by electron
microscopy (Fowler and Erickson,
1979).
Cell surface localization
Experiments were performed on NIH 3T3 mouse fibroblasts transfected with a
cDNA encoding the chick integrin ß1 subunit as described
(Choquet et al., 1997). Cells
were cultivated in DMEM supplemented with 10% fetal calf serum, 1%
penicillin/streptomycin/glutamine, kept at 37°C in a 5% CO2
incubator and passaged every 3-4 days. The day before the experiment, cells
were plated at 104 cells/ml on laminin-coated, silanized glass
coverslips in the same culture medium without phenol red and with 10 mM Hepes,
pH 7.2 (Schmidt et al.,
1993
).
Proteins were dialyzed in phosphate buffered saline (PBS: 8 g/l NaCl, 0.2
g/l KCl, 0.2 g/l KH2PO4, 1.15 g/l NaHPO4, pH
7.2) overnight and biotinylated as described
(Choquet et al., 1997). An
important point was to centrifuge the protein (13,000 g for 15
minutes) after biotinylation and prior to the experiment. Without the
centrifugation a weak staining of streaks was also seen with monomeric and
tandem-dimer FN7-10 preparations, probably due to a small quantity of protein
aggregates produced during the biotinylation. Unless otherwise indicated,
cells were incubated at 37°C with media containing 700 µl of 3 µM
purified proteins. Molarity refers to the concentration of FN7-10 subunits, so
3 µM is 120 µg/ml for FN7-10 monomer and tandem dimer, and 300 µg/ml
for FN-TN dimer, trimer and pentamer. After 30 seconds to 10 minutes, cells
were directly fixed by addition of 4 ml of 3% paraformaldehyde at 37°C for
10 minutes. Coverslips were rinsed with PBS containing 0.1 M glycine and 2%
bovine serum albumin (BSA) for 10 minutes and with PBS-BSA for 5 minutes. They
were then incubated for 20 minutes with 5 µg/ml fluorescent avidin
neutralite (Molecular Probes, Eugene, OR) in PBS/BSA buffer, and were washed
with PBS buffer before mounting.
Under some culture conditions the cells assembled a FN matrix. When FN
fibrils were present they decorated strongly with all of the vectors that
contained TN3-8, regardless of the presence of FN7-10. TN3-8 is known to bind
FN fibrils (Chung et al.,
1995), so this decoration was not surprising. We found that it
could be inhibited by adding an excess of TN3-8 pentamer to the labeling
mixture, so this was included in most of the decoration experiments.
For phalloidin staining of actin, cells were permeabilised with 0.3% Triton
X-100 for 5 minutes, rinsed in PBS/BSA buffer and incubated simultaneously
with Alexa 568-phalloidin (Molecular Probes) and fluorescent avidin.
Phalloidin concentration was adjusted so there was no bleed-through on the
green channel. Staining with anti integrin-5 antibody (monoclonal,
hamster anti-mouse CD49, Pharmingen) was carried out after fixation for 30
minutes at room temperature. Secondary antibody (Texas Red goat
anti-Armenian-hamster antibody) was incubated together with the FITC-avidin,
to provide double labeling of bound FN oligomers and
5 integrin. In
both cases the incomplete overlap shows that the co-localization is not due to
bleed-through of the fluorescent labels.
Video-microscopy of bead binding
Carboxylated latex beads (Polyscience, Warrington, PA) were coated with
biotinylated BSA using a carbodiimide linkage
(Kuo and Sheetz, 1993) and
stored at 4°C. Prior to the experiment, beads were incubated overnight at
4°C with 2 mg/ml avidin neutralite (Molecular Probes). After PBS-BSA
washes, beads (2% solution) were incubated for 1 hour at room temperature with
the various biotinylated FN7-10 proteins (30-100 ng/ml), and then washed with
PBS-BSA. Coated beads were made freshly every day.
Before the experiments, cells were mounted in a chamber consisting of two coverslips separated by 1 mm spacers. The cells were mounted with 200 µl centrifuged culture medium supplemented with 1 µl of a 2% solution of beads. Cells were visualized with a 1.3 NA 100 X plan-neofluar objective on an Axiovert 100 TV inverted microscope, equipped with Nomarski optics. The chamber and objective were maintained at 37°C by flowing heat regulated air.
The experimental setup for optical tweezers was essentially as described
(Kuo and Sheetz, 1993). An
Innova 70 Argon laser pumped an 890 Titanium-Sapphire laser (Coherent, Bowie,
MD) set at 800 nm and 100-150 mW of output power. The expanded beam was used
to form an optical trap. Video frames were digitized and a single particle
tracking program used to detect bead position with a sensitivity of 5-10 nm
for 1 µm beads (Gelles et al.,
1988
; Schmidt et al.,
1993
). The 2D diffusion coefficient D and bead velocity V were
computed by fitting the function f(t)=4Dt+bt2 to the curve of mean
squared displacement versus time, f(t)
(Qian et al., 1991
). If b was
negative or null, the track was said to be purely diffusive movement,
otherwise, the velocity of directed displacement was taken as the square root
of b. We have performed Student's t-tests on the different sets of
data.
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Results |
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FN7-10 monomer is the cell adhesion domain of FN, whose structure was
determined by X-ray crystallography (Leahy
et al., 1996). EM shows short rods close to the expected 14 nm
length (Fig. 2). FN-FN tandem
dimer consists of two of these segments connected by a short flexible linker.
EM shows these to be about twice the length of FN7-10 monomer, sometimes bent
into a V.
FN-TN monomer should have a length of 35 nm (3.5 nm per domain), but electron microscopy revealed a bimodal distribution, with peak lengths of 32 nm and 60-70 nm. Fig. 2 shows examples of the short and longer molecules in this fraction. The short molecules correspond to true monomers, while the longer molecules appear to be end-to-end dimers. A number of strands with a length of 90-100 nm, and a few longer ones, were found, which are apparently trimers and larger strands. The presence of these larger strands suggests a head to tail association of the C-terminal interface of TN8 with the N-terminal interface of FN7. The tendency of FN-TN monomer to dimerize was also indicated in sedimentation equilibrium, and by the fact that it sedimented in glycerol gradients at 4.6S, exactly the same as FN-TN dimer (data not shown). About 60% of the molecules in a typical FN-TN monomer preparation appeared to be dimers and 30% were monomers. Therefore this FN-TN monomer is not a good control as a monomer, but rather provides an additional construct that is mostly dimeric.
The FN-TN dimer based on the coiled coil also showed two peaks of lengths, with a major peak at 65 nm and a smaller peak at 33 nm. The monomers in this fraction could result from incomplete association of the coiled coils or from proteolysis. About 60% of the molecules in the dimer preparation appeared to be dimers (65±10 nm). Almost all of the dimers showed the two arms projecting in opposite directions in a straight line, with rarely a hint of a bend at the middle. This suggests that the C-terminal interfaces of TNfn8 have a tendency to associate with each other.
EM of the trimer and pentamer showed multi-arm oligomers (Fig. 2). The control proteins with the tenascin spacer arms (lacking the FN7-10 segment) gave the most reproducible structures, with most of the molecules having the expected 3 or 5 arms. The FN-TN constructs frequently appeared to be missing an arm. We estimate that more than half of the trimers and pentamers showed the full complement of arms, and only a small fraction were missing more than one arm, as observed by EM. Because the control TN trimers and pentamers showed mostly the correct number of arms, we believe the apparent missing arms in the FN-TN constructs may be due to a weak association of the FN segments within the oligomer. If the missing arms are obscured by binding to each other, the fraction of intact trimers and pentamers is probably near 100%. Gel electrophoresis showed no evidence of proteolysis, consistent with this prediction.
Given that the FN-TN monomer tended to dimerize, it was important to establish that the other constructs did not associate into complexes larger than the trimer or pentamer. Glycerol gradient sedimentation gave sedimentation coefficients of 4.6S for both FN-TN monomer and dimer (consistent with the EM results that the monomer is actually a dimer), 5.8-5.2S for trimer and 7.7S for pentamer. We found that at higher protein concentrations both the trimer and pentamer tended to aggregate, especially in low salt. Gradient sedimentation and high speed centrifugation experiments performed in DMEM demonstrated significant aggregation of trimer at 2 mg/ml (20 µM subunits), but negligible aggregation at 1, 0.5 and 0.25 mg/ml. The experiments reported here were all done at a maximum concentration of 0.3 mg/ml, where we found no indication of aggregation.
One of the most important points of the geometry of the constructs is the spacing of bound integrins. The integrin should be centered between FN10 (with the RGD) and FN9 (the synergy domain), which is 24.5 nm from the hinge region of the FN-TN oligomers. The maximum separation of bound integrins will therefore be 49 nm, while an `average' spacing of 35 nm will be obtained when the arms are at a 90 degree angle. For FN-MukBcoil the maximum spacing will be 113 nm. All of the constructs were designed to have flexible hinges, and can bring integrins into contact with each other. For reference, the width of an integrin head is 8-12 nm (Fig. 1B).
Binding and distribution of FN7-10 on the surface of fibroblasts
Binding of FN7-10 constructs to motile, non-confluent fibroblasts was
tested by adding the biotinylated proteins at 3 µM (the concentration of
FN7-10 subunits) for 2.5 minutes (Fig.
3), followed by fixation and staining with FITC-avidin. FN7-10
monomer stained the cells weakly, showing some binding to the apical membrane
and some dots on the lamellipodia. Increasing the concentration of FN7-10
monomer by tenfold increased the level of staining, but the pattern remained
diffuse. FN-FN tandem dimer gave a diffuse staining pattern very much like
that of the monomer, but the staining was sometimes more intense. The number
and intensity of dots on the lamellipodia were the same with monomer and
tandem dimer. The monomer and dimer panels showed some localization to streaks
(Figs 4,
5) but these were always much
weaker and fewer in number than with the trimer and pentamer.
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The binding and distribution of the FN-TN trimer was strikingly different. Between 80 and 90% of the cells displayed streaks of intense staining running from the leading edge of the cell across the lamellipodia towards the center of the cell. The intensity of staining was very high compared with cells stained with monomer or tandem dimer. Confocal microscopy indicated that these streaks were on the top of the cells (not shown).
FN-TN pentamer gave a staining pattern similar to that of the trimer, but the streaks were even more intense. Many streaks ran all the way from the leading edge to the center of the cell. Even at 2.5 minutes of incubation with the pentamer, some cells started to retract their lamellipodia and round up. These cells often displayed hot spots of staining at the base of the lamellipodia, perhaps representing internalized protein (Fig. 3, right-hand images of tandem dimer and pentamer). In cells treated with FN7-10 pentamer almost all of the fiber bundles were visible by DIC. This may be because the lamellapodia were starting to contract and had less cytoplasm, but it is also possible that the fiber bundles had got thicker due to contraction or accumulation of extra actin.
We were surprised that the tandem dimer had no activity, since we expected
receptor dimerization to be the principle of activation. We therefore
constructed two new dimers: one had a TN spacer arm identical to that of the
trimer and pentamer; and the other was based on the antiparallel coiled coil
MukB, and had longer arms than the FN-TN dimer
(Fig. 1). These new dimer
constructs gave a weak and mostly diffuse staining pattern identical to that
of the tandem dimer. In order to verify the specificity of the staining, we
constructed a control trimeric protein containing the TN3-8 spacer arms, but
lacking the FN7-10 domains. This construct gave negligible binding to cells
(Fig. 3, bottom left). However,
we should note that under some cell culture conditions the cells assembled FN
matrix fibrils, and these fibrils stained strongly with all constructs
containing the TN spacer arm, consistent with the known affinity of TN for FN
fibrils (Chung et al., 1995).
We have not discovered the conditions favoring or inhibiting FN matrix
assembly.
Competition of FN7-10 monomer
We also tested the ability of FN7-10 monomer to compete for binding of the
FN-TN trimer. When cells were treated with labeled FN-TN trimer at 3 µM,
plus unlabeled FN7-10 monomer at 30 µM, the staining of the streaks was
completely inhibited (Fig. 3,
bottom-right).
The above experiments were done with subunit concentrations of 3 µM, but Fig. 4A shows that binding and labeling of streaks can be obtained at lower concentrations. FN-TN trimer gave very little labeling of streaks at 0.1 and 0.2 µM, but streaks were prominently labeled at 0.5 and 1.0 µM. We explored the competition by monomer using 0.5 µM FN-TN trimer. Fig. 4B shows that labeling of streaks is unaffected by up to 0.75 µM FN7-10 monomer, but is reduced somewhat at 2.25 µM, a 4.5-fold excess. Staining is greatly reduced at 3.0 µM or greater concentration of monomer, a sixfold excess. This is consistent with the results in Fig. 3, where a tenfold excess of monomer completely blocked staining by 3 µM trimer.
Time course of the binding for the different proteins
To study the behavior of the cells as they bind the proteins, we incubated
them with 3 µM protein for 30 seconds to 10 minutes at 37°C. For the
monomer, only weak staining was apparent at 30 seconds and 2.5 minutes. At 5
and 10 minutes some small spots were observed on the lamellipodia although
they were weak. FN-FN tandem dimer gave almost the same pattern except for a
higher staining at the tip of the leading edge and the appearance of a few
weak streaks.
FN-TN trimer give the characteristic pattern of streaks for the whole time course of the experiment. At 30 seconds of incubation the intensity of staining was weak, but the pattern of streaks was already visible. At 2.5 minutes the staining of streaks was increased substantially in intensity, and was present on almost all cells. These streaks were stable and tended to be more intense after 10 minutes.
FN-TN pentamer gave a pattern of streaks very similar to the trimer, but the staining was even more intense. The streaks stained by pentamer were deeper than with the trimer, extending closer to the cell nucleus. In contrast to the trimer, where the cells and pattern of streaks remained static for 10 minutes, the pentamer caused cells to round up and aggregate the bound FN-TN at the base of the nucleus. This was already apparent for some cells at 5 minutes, and at 10 minutes almost 80% of the cells were rounded.
FN7-10 trimer localizes 5 ß1 integrin to actin
bundles
We confirmed the expectation that the FN-TN constructs are binding to
integrins by colocalization. Fig.
5 shows that cells treated with FN-TN monomer or dimer had a
diffuse distribution of 5-integrin. In cells treated with FN-TN trimer
or pentamer the diffuse distribution of integrin remained, but some integrin
was now associated into streaks. These streaks of integrin coincided with the
streaks of FN-TN. The distribution of plasma FN (bottom two panels) was
notably different. It generated streaks of
5 integrin and co-localized
with them, but there were also substantial patches of FN located outside these
streaks.
The pattern of streaks resembles that of actin fiber bundles, and indeed in
many cells the fibers showed visible contrast with differential interference
optics. To confirm the identity of these fibers, cells were stained
simultaneously for bound FN-TN and with phalloidin to stain F-actin
(Fig. 6). All the streaks of
FN-TN trimer and pentamer were localized over F-actin fibers, but the actin
was more extensive than the labeled streaks. Thus some actin fibers were not
labeled at all, and most were labeled only over a portion of their length. The
occasional small streaks on cells labeled with FN-TN monomer or dimer were
also localized over actin fibers. In cells labeled with plasma FN some of the
FN localized over actin fibers, but there were some patches of FN elsewhere.
The binding of whole FN dimers may involve receptors in addition to
5ß1. The pattern of actin fibers appeared to be the same in cells
treated with all the constructs (Fig.
6), and in untreated cells (not shown). This suggests that the
FN-TN multimers are localizing to pre-existing actin fibers, rather than
inducing their assembly.
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Particle tracking of FN7-10-coated latex beads
To follow the movement of integrins on the cell surface we performed single
particle tracking experiments with beads coated with the monomeric and
multivalent FN. Our aim was to ensure that beads were bound to the cell
through a single protein complex, in order to vary the aggregation level of
the integrins solely by changing the valency of the protein. For that purpose,
we coated the beads with a low protein concentration, so that on a given
experiment only 20-25% of the beads displayed binding to the cell. We reasoned
that a high fraction of beads would then be bound to cells through a single
complex.
An optical laser trap was used to pick floating beads in the medium and put them in contact with the lamellipodia for a fixed time (4 seconds). The trap was then released and the behavior of the bead was followed by single particle tracking (Fig. 7).
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Beads coated with FN7-10 or FN-TN monomer behaved identically, displaying very short binding to the cell surface (mean binding 1-2 seconds) and diffusive movements while bound. This means that the association of monomeric FN7-10 to integrins is rapidly reversible, and the engaged integrin does not show sustained binding to the cytoskeleton. Beads carrying the FN-FN tandem dimer, or the FN-TN dimer, frequently displayed a peculiar behavior: a low diffusion coefficient, suggesting binding to cytoskeletal elements, but no rearward movement. In contrast, beads coated with trimeric FN7-10 remained bound for longer than 10 seconds, and displayed a reproducible rearward movement. We had problems coating beads with the FN-TN pentamer, but the small number of bound beads behaved similarly to the trimer beads.
The collected observations of beads coated with different constructs are given in Table 1. These observations of bead tracking confirm that a monomeric FN7-10 produced a transient binding with free diffusion, while a single trimeric FN7-10 induced attachment of the integrin complex to the cytoskeleton, which is moving rearward.
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Discussion |
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We considered the possibility that the trimer and pentamer might be aggregating, so that the active complex is actually larger than a trimer. Gradient sedimentation and high speed sedimentation demonstrated aggregation of trimer and pentamer at 2 mg/ml protein concentrations, but not at the 0.3 mg/ml used for the experiments. Finally, we note that the activity of the soluble complexes was confirmed in the bead translocation, where we believe only a single molecule is on the bound bead.
We tested the ability of FN7-10 monomer to compete with binding of the
trimer, expecting the trimer to bind with much higher avidity than monomer.
Martin et al. tested the ability of ICAM to block rhinovirus infection, and
found that a bivalent IgA construct inhibited different viral activities at
40-200-fold lower concentrations than the monomer
(Martin et al., 1993). Yet in
our studies we found that 0.5 µM trimer could be competed by only an
approximately fivefold excess of FN7-10 monomer. One difference is that the
virus presented a rigid, multivalent target, whereas the integrin receptors on
cells are diffusing in the plane of the membrane. When one arm of a trimer is
released from the virus, its receptor on the virus remains in place
facilitating rebinding. When one arm of a trimer is released from the cell
surface, its integrin receptor is free to diffuse away. It can only rebind
when an unbound integrin diffuses back into range. Thus the avidity may be
much less for binding multivalent constructs to freely diffusible cell surface
receptors than to a virus.
We had expected the dimeric constructs to produce most of the effects of
the trimer and pentamer, as receptor dimerization is an established paradigm
for activation (Heldin, 1995).
It seems that a pair of integrins, like the monomer, may be too weak to form a
stable attachment to the cytoskeleton, while a trimer, and even more a
pentamer, provide sufficient contact sites to form a stable complex. Another
possibility is that a dimer is the active species, but the formation of a
dimeric complex of integrins is inefficient and requires three or more FN arms
to get two efficiently bound to integrins.
Integrins localize to focal adhesions when activated by ligand occupancy or
by exposing the ß1 tail, and there is no requirement for clustering
(Briesewitz et al., 1993;
LaFlamme et al., 1992
). The
localization to actin fibers that we observed required clustering. This
suggests that focal adhesions may present stronger binding sites for activated
integrins than the actin fibers. We can conclude from the present studies that
these actin fibers do have an affinity for activated integrins, but it
generates a strong binding only when they are in clusters.
The existence of a rearward-moving cytoskeleton with integrin-binding
capacity was suggested as the basis for the movement of beads coated with
FN7-10 (Felsenfeld et al.,
1996). These beads at first moved randomly on the cell surface,
then began a linear, rearward movement. Attachment of the beads to these
cytoskeletal tracks required clustering as well as integrin activation, since
beads coated with a low concentration of FN7-10 showed only transient,
diffusive movement. The clusters required for this attachment had to be small,
since the beads were only 40 nm in diameter. Given the 8-12 nm size of the
integrins, no more than five to ten FN7-10 molecules could be arranged on one
side of the bead to form an integrin cluster. We believe that the soluble
FN7-10 oligomers we have tested here are behaving like the beads. The soluble
oligomers provide the important advantage that they can decorate completely
the cytoskeletal tracks responsible for bead movement.
Two studies have investigated the effects of clustering integrins or their
ligands. Hato et al. made a chimera of FK506-binding proteins with the
integrin cytoplasmic tail, and used this to form clusters of integrins
(Hato et al., 1998). These
clusters failed to decorate an actin cytoskeleton. This may be due to the
absence of a cytoskeleton in these suspended cells, or may indicate that
ligand binding is required in addition to clustering. Stupack et al. showed
that adhesion of lymphoid cells to a multivalent fibrin matrix stimulated syk
kinase, which in turn substantially enhanced the integrin affinity and
adhesion (Stupack et al.,
1999
). It is becoming clear that integrin clustering, signalling
and affinity modulation are complementary processes in adhesion.
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