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First published online 16 August 2006
doi: 10.1242/dev.02543
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Laboratory of Developmental Biology, National Heart, Lung and Blood Institute, National Institutes of Health, Bethesda, MD 20850, USA.
* Author for correspondence (e-mail: loc{at}nhlbi.nih.gov)
Accepted 20 July 2006
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SUMMARY |
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 TOP SUMMARY INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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1KO) mice have conotruncal heart defects
that are associated with a reduction in the abundance of cardiac neural crest
cells (CNCs) targeted to the heart. In this study, we show CNCs can respond to
changing fibronectin matrix density by adjusting their migratory behavior,
with directionality increasing and speed decreasing with increasing
fibronectin density. However, compared with wild-type CNCs, Cx431KO
CNCs show reduced directionality and speed, while CNCs overexpressing
Cx431 from the CMV43 transgenic mice show increased directionality and
speed. Altered integrin signaling was indicated by changes in the distribution
of vinculin containing focal contacts, and altered temporal response of
Cx431KO and CMV43 CNCs to ß1 integrin function blocking antibody
treatment. High resolution motion analysis showed Cx431KO CNCs have
increased cell protrusive activity accompanied by the loss of polarized cell
movement. They exhibited an unusual polygonal arrangement of actin stress
fibers that indicated a profound change in cytoskeletal organization.
Semaphorin 3A, a chemorepellent known to inhibit integrin activation, was
found to inhibit CNC motility, but in the Cx431KO and CMV43 CNCs, cell
processes failed to retract with semaphorin 3A treatment. Immunohistochemical
and biochemical analyses suggested close interactions between Cx431,
vinculin and other actin-binding proteins. However, dye coupling analysis
showed no correlation between gap junction communication level and fibronectin
plating density. Overall, these findings indicate Cx431 may have a
novel function in mediating crosstalk with cell signaling pathways that
regulate polarized cell movement essential for the directional migration of
CNCs.
Key words: Connexin 43, Neural crest cell, Focal contact, Actin cytoskeleton, Cell motility
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INTRODUCTION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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). This
is mediated by a subpopulation of neural crest cells derived from the
post-otic hindbrain neural fold to somite level 3, referred to as the cardiac
neural crest cells (CNCs). Ablation studies as well as various mutant animal
models have shown that perturbation or deletion of CNCs can lead to
cardiovascular defects involving outflow tract septation anomalies, such as
persistent truncus arteriosus as well as various aortic arch anomalies
(Kirby and Waldo, 1995). In
addition, CNCs play an essential role in patterning of coronary arteries. Thus
appropriate targeting of CNCs to the heart is of crucial importance for
survival of the animal.
Neural crest cells from different axial levels of the neural tube employ
different migratory pathways, with cardiac CNCs shown to migrate along a
circumpharyngeal pathway to reach the aortic arches and heart
(Kirby et al., 1983;
Lumsden et al., 1991). The
deployment of CNCs to the heart has been shown to be modulated by interactions
mediated by connexin 43 (Cx431) gap junctions. Gap junctions are
specialized cell junctions encoded by connexin proteins that contain membrane
channels that mediate the movement of ions and small molecules between cells.
CNCs express Cx431, and are functionally well-coupled through gap
junction channels (Lo et al.,
1999). Cx431 knockout (Cx431KO) mice die at birth
with conotruncal heart malformations, outflow obstructions and coronary
anomalies (Huang et al.,
1998b; Li et al.,
2002; Reaume et al.,
1995). Studies carried out using the Cx431KO mice and
transgenic mice overexpressing Cx431 or expressing a dominant-negative
form of Cx431 showed CNC motility is dependent on the precise level of
Cx431 function. Thus, loss or dominant-negative inhibition of
Cx431 inhibited neural crest cell migration, resulting in fewer CNCs
targeted to the outflow tract (Huang et
al., 1998a; Sullivan and Lo,
1995). By contrast, in CMV43 transgenic mice overexpressing
Cx431, neural crest cell migration was enhanced, and this was
associated with an excess of CNCs in the outflow tract
(Huang et al., 1998a). Motion
analysis using timelapse videomicroscopy showed Cx431-deficient CNCs
have reduced directionality (Xu et al.,
2001). Although these studies provide compelling evidence of a
role for Cx431 in modulating cell motility, the underlying mechanism is
unknown.
In this study, we examined whether the altered motile behavior of CNCs from
the Cx431KO and CMV43 transgenic mice may involve perturbation in
integrin signaling. Integrins are heterodimeric receptors that, upon matrix
binding, cluster to form focal contacts that link the extracellular matrix to
the actin cytoskeleton. The dynamic assembly and disassembly of focal contacts
play an essential role in polarized cell movement and directional cell
migration. Neural crest cells are known to express multiple integrins
(Delannet et al., 1994;
Monier-Gavelle and Duband,
1997). Perturbation studies have shown integrins play an essential
role in modulating the migratory behavior of neural crest cells
(Alfandari et al., 2003;
Strachan and Condic, 2003).
Our studies suggest altered integrin signaling in CNCs from the Cx431KO
and CMV43 CNCs. Changes in motile behavior was associated with altered
regulation of polarized cell movement. This was accompanied by changes in the
distribution of focal contacts, and also marked changes in the organization of
the actin cytoskeleton in the Cx431KO CNCs. However, we found no
correlation between the level of gap junction communication and changes in
motile cell behavior. Given these observations, we considered the possibility
that Cx431 may modulate cell motile behavior through crosstalk with
proteins that dynamically regulate the actin cytoskeleton. Consistent with
this, we observed colocalization of Cx431 with many actin-binding
proteins.
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MATERIALS AND METHODS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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1KO embryos were generated from interbreeding heterozygous
Cx431KO animals, and CMV43 transgenic mice were bred to obtain
homozygous and heterozygous CMV43 embryos
(Huang et al., 1998a). PCR
genotyping was carried using DNA obtained from yolk sac tissue. The protocol
used for genotyping the Cx431KO mice were modified as previously
reported (Reaume et al.,
1995). Primer pairs for detecting the CMV43 transgene are: CMV-F1,
5'-TGTTCCCATAGTAACGCCAATAGG-3'; CMV-B7,
5'-ATATAGACCTCCCACCGTACACGC-3'. Homozygous CMV43 embryos were
identified by quantitative real time PCR using primer pairs: DHFR-F3,
5'-CGAAACTGACAGCACATCGTAGG-3'; DHFR-B4,
5'-CACTCGTGAATGCGTTATCGTTC-3'; GAPDH-F9,
5'-ATGTTCCAGTATGACTCCACTCACG-3'; GAPDH-B6,
5'-GAAGACACCAGTAGACTCCACGACA-3'.
Neural tube explant cultures
Embryos used for neural tube explant cultures were harvested at E8.5 day as
described previously (Moiseiwitsch and
Lauder, 1995). The hindbrain neural folds were collagenase/dispase
(Roche, Indianapolis, IN) treated, and the dorsal ridge of the neuroepithelium
spanning the postotic region of the hindbrain neural fold was surgically
removed from the surrounding tissue and cultured on plates coated with human
plasma fibronectin (Life Technologies or Sigma) in Dulbecco's modified Eagle's
medium (DMEM) with high glucose and 10% fetal bovine serum (FBS).
Cell adhesion assay
CNCs were isolated from 46-hour explant cultures and were resuspended in
0.1 ml of DMEM containing 10% FBS. Cell suspensions were plated in five or
more replicates and allowed to attach for 20 minutes at 37°C in 96-well
plates coated with 15 µg/ml fibronectin and blocked with 1% BSA for 1 hour
at room temperature. Cell attachment was measured by assaying for ATP levels
of adherent cells divided by total cells seeded. ATP was detected using
ATPlite Kit from Perkin Elmer (Wellesley, MA).
Motion analysis
Neural tube explants were cultured in phosphate buffered L-15 medium
(Sigma) containing 10% FBS and placed on a 37°C heated stage of the Leica
DMIRE2 inverted microscope. Timelapse images were captured using an Orca-ER
camera. For monitoring the directionality (net path length/total path length)
and speed of cell locomotion, images were captured using a 10x objective
every 10 minutes over a 20 hour interval, while cell protrusive activity was
monitored using a 63x objective with images captured every 5 minutes
over a 2-hour interval or every minute over 20 minutes with or without
semaphorin 3a (Sema3a). Sema3a/FC chimeric protein was obtained from R&D
(Minneapolis, MN), and used at a final concentration of 500 ng/ml in culture
medium. Quantitative motion analysis was carried out using Dynamic Image
Analysis Software (Solltech, Oakdale, IA). For this analysis, the outline of
individual cells located at or near the migration front of the emerging
explant were traced frame by frame. Using these tracings, the DIAS software
calculated the speed and directionality of cell movement by tracking the
change in the position of the centroid of the cell at each time point. Using
DIAS, the protrusive activity of the cell was quantitatively assessed by
measuring the amount of new cell area formed versus cell area lost. This is
expressed as percent area expansion or contraction and is referred to as
`positive' versus `negative' flow. In addition, using these same cell
tracings, roundness was calculated, which is defined as 100 x 4
(area/perimeter2) (Stites et
al., 1998), which is a measure of how efficiently a given amount
of perimeter encloses area: a circle has the largest area for any given
perimeter with a roundness of 100%. Thus, the greater the number of cell
protrusions, the lower the roundness. All of the data obtained from these
quantitative assessments were evaluated by ANOVA using Statview (SAS
Institute, Cary, NC).
Antibodies and reagents
Antibodies used included: rabbit polyclonal 18-A8 recognizing cytoplasmic
tail of Cx431 (1:1500; kindly supplied by Dr Elliot Hertzberg, Albert
Einstein College of Medicine), mouse monoclonal anti-vinculin antibody (Sigma;
1:500), rat monoclonal anti-ß1 integrin antibody (Chemicon; 1:100), mouse
monoclonal anti-ezrin antibody (Transduction Lab; 1:100), mouse monoclonal
anti--actinin (Sigma; 1:500), mouse monoclonal anti-IQGAP-1 (Upstate
Technology, 1:100), rhodamine-phalloidin (Sigma; 1:500) and Drebrin (Stressgen
Biotechnology, 1:100). The fluorescence-conjugated secondary antibodies were
obtained from Jackson ImmunoResearch Laboratories. Goat anti-rat ß1
integrin function blocking antibody was provided by Dr Borg's laboratory
(Gullberg et al., 1989).
Cytochalasin D was purchased from Sigma.
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Immunoprecipitation and western immunoblotting
CNCs in explant cultures were cell surface biotinylated using 1 mM NHSLC
Biotin (Pierce Chemical, IL) for 15 minutes followed by wash with buffer
containing 50 mM NH4Cl to remove non-incorporated biotin. The cells
were then solubilized with 400 µl cold lysis buffer (50 mM Tris, pH 7.5
containing 0.15 M NaCl, 1% Triton X-100, 1 mM CaCl2, 1 mM
MgCl2 and 2 mM PMSF). After centrifugation at 12,000
g for 10 minutes at 4°C, supernatant was removed and
incubated with 2.5 µl goat anti-integrin antibody (5 mg/ml) overnight at
4°C followed by adding 50 µl protein G-agarose (1:1 in PBS) for 2 hours
at 4°C (rocking). After extensive washing (five times in 50 mM Tris pH
7.5, 0.15 M NaCl, 0.1% Tween-20, twice in same buffer containing 0.5 M NaCl,
and once in 0.05 M Tris pH 6.8), the immunoprecipitates were separated by 10%
SDS-PAGE and blotted onto PVDF membrane, followed by immunodetection using
streptavidin HRP and enzyme-linked chemiluminescence detection system
(Amersham Biosciences). The co-immunoprecipitation experiment was carried out
as described previously (Wei et al.,
2005).
Quantitative analysis of gap junction communication
To assess gap junction communication in CNCs, dye-coupling experiments were
carried out with microelectrode impalements and iontophoretic injections of
carboxyfluorescein. Neural tube explant cultures were plated in L-15 medium
and placed on 37°C heated Leica DMLFSA microscope stage. Dye
injections were carried out using microelectrodes back filled with 2%
carboxyfluorescein. After intracellular microelectrode impalement,
iontophoretic dye injection was carried out for 2 minutes and then the
microelectrode was removed. After a further 2 minutes for additional
cell-to-cell spread of the dye, dark-field image and DIC images were captured
for the quantitative assessment of the extent of dye spread. Using the DIC
image, the outlines of individual cells were traced and merged with the
dark-field image. Using this merged image, the number of dye filled cells
versus non-dye filled cells were counted, and the percentage of dye-filled
primary neighbors (directly adjacent to injected cell), secondary neighbors
(directly adjacent to primary neighbors) and tertiary neighbors (directly
adjacent to secondary neighbors) was calculated.
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RESULTS |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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). To confirm the identity of these outgrowth as neural crest
cells, we immunostained these explants with antibodies to retinoic acid
binding protein 1 (Crabp1) (Lee et al.,
1995) or Sox10 (De Bellard et
al., 2002; Southard-Smith et
al., 1998). Both proteins were found to be expressed at high
levels in cells emerging from these explant cultures, with Sox10 showing
nuclear localization as expected (Fig.
1). We found no difference in the pattern of immunostaining in
wild-type versus Cx431KO explants
(Fig. 1), and similar results
were also obtained for CMV43 CNC explants (not shown). Immunostaining of mouse
fibroblast cells using these same antibodies resulted in only nonspecific
background staining (not shown).
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1KO CNCs showed a 25%
reduction in adhesion compared with wild-type cells (P<0.05),
while CMV43 CNCs showed no change compare with their nontransgenic control.
Using timelapse videomicroscopy, we further assessed motile behavior of CNCs
with different expression level of Cx431 on different fibronectin
density using dishes coated with 1, 15, 25 or 50 µg/ml fibronectin.
Analysis of the migratory paths of individual neural crest cells revealed
increased directionality, but decreased speed of cell locomotion as
fibronectin density increased (Fig.
2A,B). In contrast to wild-type cells, homozygous Cx431KO
CNCs failed to achieve high directionality, even at high fibronectin density,
while their speed decreased more rapidly with increasing fibronectin density
(Fig. 2A). However, CMV43 CNCs
showed enhanced cell motility, exhibiting high directionality even at low
fibronectin density (1 µg/ml), while maintaining high speed even as
fibronectin density was elevated (15 µg/ml)
(Fig. 2B).
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1, we quantitatively assessed cell protrusive activity by
monitoring the extension and retraction of cell processes using time lapse
imaging, with images captured at either 1 or 5 minute intervals over a period
of 2 hours (see Movies 1 and 2 in the supplementary material). Using these
time lapse images, the outlines of individual cells were manually traced and
the percent cell area expansion versus contraction between two consecutive
time frames were used to calculate `positive flow' (shown in green in
Fig. 3A) versus `negative flow'
(shown in red in Fig. 3A).
Cx431KO CNCs showed an increase in both positive and negative flow when
compared with CNCs from wild-type littermate controls
(Fig. 3B), while CMV43 CNCs
were indistinguishable from CNCs from nontransgenic littermate controls
(Fig. 3C). We also measured the
roundness of the cells using the formula 100% x 4
(area/perimeter2), such that a circle would have maximal roundness
at 100% (Stites et al., 1998).
Consistent with increased protrusive activity, the Cx431KO CNCs showed
a decrease in roundness, while no change in roundness was observed for the
CMV43 CNCs (Fig. 3C). Wild-type
and CMV43 CNCs showed a distinct polarized distribution of green positive flow
at the leading edge and red negative flow at the trailing edge of the cell, as
would be expected for directional cell movement
(Fig. 3A,C). However in the
Cx431KO CNCs, the areas of positive and negative flow were distributed
nearly symmetrically around the entire cell periphery (see red and green areas
in Fig. 3A). The lack of
polarity in cell protrusive activity is consistent with the decrease in the
directionality of cell movement in Cx431KO CNCs
(Fig. 2).
Cx431 perturbation alters the distribution of ß1-integrin and focal contacts
Using immunohistochemistry, we examined expression of ß1 integrin in
CNCs, as ß1 integrin is known to play an important role in mediating
fibronectin binding. Double immunostaining was carried out with ß1
integrin and vinculin antibodies. Wild-type CNCs showed discrete ß1
integrin membrane localization largely towards the cell periphery, at regions
overlapping with vinculin containing focal adhesions
(Fig. 4A). In Cx431KO
CNCs, we observed a reduction in ß1 integrin and vinculin immunostaining
(Fig. 4B), while in CMV43 CNCs,
ß1 integrin and vinculin immunostaining remained abundant
(Fig. 4C). To investigate if
cell surface expression of ß1 integrin might be altered by Cx431
perturbation, western immunoblotting analysis was carried out. CNCs in
explants were cell-surface biotinylated, then cell extracts were made and
immunoprecipitated with a ß1 integrin antibody, followed by western
immunoblotting with streptavidin. A predominant band at 120 kDa was obtained,
the molecular weight expected for ß1 integrin
(Fig. 4D). Quantitative
analysis showed no difference in the abundance of this 120 kDa band in the
wild-type versus CMV43 CNCs (Fig.
4D). Comparable analysis of ß1 integrin expression in
Cx431KO CNCs was not feasible, given the limited abundance of KO
CNCs.
As vinculin containing focal contacts provide the actin cytoskeletal
linkages essential for matrix adhesion and cell motility, we quantitatively
assessed the distribution of vinculin containing focal contacts in wild-type,
Cx431KO and CMV43 CNCs plated on different fibronectin matrix density
(1, 15 and 50 µg/ml). Compared with wild-type CNCs, Cx431KO CNCs
exhibited a reduction in the mean area and mean intensity of vinculin
immunostaining at all fibronectin coating densities
(Fig. 4E). By contrast, CMV43
CNCs showed an increase in vinculin intensity, with the mean area showing a
decrease at 15 µg/ml fibronectin (Fig.
4F). These findings suggest Cx431 deficiency versus
overexpression has differing effects on the organization of focal contacts in
the Cx431KO versus CMV43 CNCs.
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1 modulates the actin cytoskeleton1KO CNCs exhibited an alignment
of 83±4°, when compared with 39±5° for wild-type CNCs.
This increase in alignment angle reflects the polygonal arrangement of actin
stress fibers in the KO CNCs. Cx431KO CNCs also exhibited significantly
shorter stress fiber bundles, together with an increase in the number of
stress fiber bundles per cell (Table
1). Double staining of cells with phalloidin and a vinculin
antibody showed stress fiber bundles in wild-type CNCs were anchored
terminally by vinculin containing focal adhesions
(Fig. 5C), but stress fiber
bundles in the Cx431KO CNCs did not always terminate in focal adhesions
(see white arrowhead in Fig.
5D). Similar analysis of actin stress fibers in CMV43 CNCs showed
no detectable difference when compared with their control nontransgenic CNCs
(Table 1).
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1KO deficiency. To further evaluate the
changes in actin organization in the Cx431KO CNCs, we also examined the
reorganization of actin filaments in CNCs recovering from cytochalasin D
treatment, which causes actin filament depolymerization. As expected, CNCs
treated with cytochalasin D showed a rapid and dramatic change to a round cell
morphology together with the complete loss of actin filaments
(Fig. 5E,F). One hour after
cytochalasin removal, as cells begin to recover their normal morphology
(Fig. 5G), reassembly of actin
filaments can be observed by phalloidin staining
(Fig. 5H,I). In such
Cx431KO CNCs, typically four or five actin organizing centers can be
seen associated with a polygonal network of forming actin filaments that
encircled the cell cortex (Fig.
5I; Table 1). By
contrast, wild-type CNCs typically exhibited two or three actin organizing
centers with forming actin filament bundles that are aligned in parallel
(Fig. 5H;
Table 1). These differences in
the pattern of actin filament reassembly in the wild-type versus KO CNCs are
consistent with the differences seen in the organization of actin stress
fibers in the untreated CNCs.
Cx431 modulation of neural crest cell migration is ß1-integrin dependent
To further evaluate the role of integrins in Cx431 modulation of CNC
motility, we analyzed the effects of ß1 integrin function blocking
antibody on the motile behavior of CNCs. Timelapse videomicroscopy and motion
analysis were carried out to quantitate the speed and directionality of cell
movement at 1 hour, 2 hour and 3 hours post-antibody treatment
(Fig. 6). Overall, ß1
integrin function blocking antibody treatment caused a marked reduction in the
speed and directionality of CNC motility, confirming a functional requirement
for ß1 integrin in CNC migration on fibronectin
(Fig. 6). The speed of cell
locomotion showed reduction in wild-type, KO and CMV43 CNCs 1 hour
post-antibody treatment; by 3 hours, all three were maximally inhibited
(Fig. 6B). By contrast, only
wild-type CNCs showed a significant reduction in the directionality of cell
locomotion after 1 hour of antibody treatment. Cx431KO cells showed no
significant change in directionality until 2 hours post-antibody treatment,
and not until 3 hours post-antibody treatment in CMV43 CNCs
(Fig. 6A,B). This delay in the
inhibition of directional cell movement in response to function blocking
antibody treatment suggests regulation of polarized cell movement may be
disturbed in the Cx431KO and CMV43 CNCS.
Sema3a inhibition of cardiac neural crest cell adhesion and migration
To further evaluate Cx431 in modulating integrin-mediated motile
cell behavior, we assessed the effects of Sema3a on CNC migration on
fibronectin. Recent studies indicate semaphorins play an important role in CNC
migration (Brown et al., 2001;
Feiner et al., 2001), and
semaphorins have been shown to inhibit cell migration on fibronectin through
antagonizing integrin activation (Osborne
et al., 2005; Pasterkamp et
al., 2003; Serini et al.,
2003). Timelapse videomicroscopy showed Sema3a reduced both
positive and negative cytoplasmic flows in wild-type, CMV43, and
Cx431KO CNCs (Fig.
7A,B). In wild-type CNCs, there was a concomitant increase in
roundness of the cell that is consistent with the retraction of cell
processes. This is reminiscent of semaphorin induced growth cone collapse in
neurons (Luo et al., 1993).
However, in Sema3atreated Cx431KO and CMV43 CNCs, there was little
change in roundness (Fig.
7A,B). This would suggest that the overall reduction in cell
protrusive activity in the Cx431KO and CMV43 CNCs was not accompanied
by the retraction of cell processes. These findings suggest a role for
Cx431 in modulating the retraction of cell processes.
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1 interactions with vinculin and actin-binding proteins1 might interact with integrin or vinculin, we
carried out double immunostaining to examine the subcellular distribution of
Cx431 with ß1 integrin or vinculin. Cx431 and ß1
integrin did not colocalize (data not shown), while colocalization was
observed for Cx431 and vinculin
(Fig. 8A-C). This was largely
at regions of cell-cell contact (white arrowheads in
Fig. 8C). To further
investigate the nature of this interaction biochemically, we performed
co-immunoprecipitation and western immunoblotting using NIH3T3 cells, which,
like neural crest cells, are highly motile and mesenchymal in cell morphology.
NIH3T3 cell lysates were immunoprecipitated with a Cx431 antibody,
followed by western immunoblotting with a vinculin antibody. Both proteins
were co-immunoprecipitated (Fig.
8S). By contrast, similar analysis showed ß1 integrin did not
co-immunoprecipitate with Cx431, consistent with the fact that ß1
integrin and Cx431 did not colocalize by immunohistochemistry (data not
shown).
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1 might interact
with other actin-binding proteins. Using rhodamine phalloidin to delineate the
actin cytoskeleton, we showed punctate regions of Cx431
co-immunolocalization with actin filaments in CNCs
(Fig. 8D-F). This was largely
in extended cell processes encompassing regions of cell-cell contact. Double
immunostaining further showed colocalization of Cx431 with several
actin-binding proteins such as ezrin (Fig.
8G-I), IQGAP (Fig.
8J-L), -actinin (Fig.
8M-O) and drebrin (Fig.
8P-R). Drebrin was recently identified as a new
Cx431-binding partner (Butkevich et
al., 2004). IQGAP (Fig.
8T), as well as -actinin (data not shown) and drebrin
(Butkevich et al., 2004), were
all found to co-immunoprecipitate with Cx431. Overall, these findings
suggest Cx431 is closely associated with multiprotein complexes
containing vinculin and a variety of other actin-binding proteins.
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; Lampe et al.,
1998; Shanker et al.,
2005). CNCs were impaled with microelectrodes and the gap junction
permeable fluorescent tracer, carboxyfluorescein, was iontophoretically
injected (Fig. 9). Upon
impalement, the fluorescent dye quickly filled the impaled cell; over a period
of 4 minutes, the injected dye rapidly spread to the surrounding cells,
providing a direct visual display of gap junction mediated cell-cell
communication (Fig. 9A-C). To
quantitatively assess the extent of dye coupling, standard dye injection
conditions were used (see Materials and methods), and the number of dye-filled
cells was counted and expressed as a percentage of the total number of
primary, secondary and tertiary neighbors
(Fig. 9D;
Table 2). Neural crest cells
migrating on low concentration of fibronectin matrix were well coupled with
dye spread to 78±8% primary, 45±15% secondary and
5.1±5.1% tertiary neighbors, respectively
(Table 2). With fibronectin
concentration elevated to 15 or 50 µg/ml, dye-coupling levels were not
significantly changed (Table
2). These findings indicate no correlation between gap junction
communication level and the fibronectin density.
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|
DISCUSSION |
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TOPSUMMARYINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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).
The unique motile behavior of CNCs may facilitate their targeting to the
heart, and perhaps underlie the sensitivity of this relatively small
subpopulation of neural crest cells to developmental perturbations, whether
genetically or environmentally induced. It is interesting that CNCs, when
ablated, cannot be regenerated from the postotic hindbrain neural tube, nor
from the mesencephalic or trunk neural crest cells
(Kirby, 1989;
Suzuki and Kirby, 1997). By
contrast, hindbrain derived cephalic neural crest cells can regulate to
reconstitute ablated neural crest cells
(Baker et al., 1997;
Saldivar et al., 1997;
Scherson et al., 1993;
Sechrist et al., 1995).
We showed that Sema3a can inhibit the adhesion and migration of CNCs on
fibronectin. Sema3a significantly inhibited the extension and retraction of
cell processes, and this was associated with an increase in the roundness of
the cell. These effects are reminiscent of the growth cone collapse seen in
neurons treated with semaphorins (Luo et
al., 1993). They suggest semaphorins can regulate the deployment
of CNCs by modulating motile cell behavior. Consistent with this, the
Sema3c knockout mice exhibit persistent truncus arteriosus, an
outflow septation defect similar to that seen in cardiac neural crest-ablated
embryos (Feiner et al.,
2001).
Our studies showed Cx431KO CNCs have poor motile function. They
exhibited low directionality even on high fibronectin density, and this was
associated with a reduction in vinculin immunostaining. By contrast, CMV43
CNCs show enhanced cell motility, with high directionality even at low
fibronectin concentration. This was associated with increased vinculin
immunostaining. These findings suggest alterations in cell surface linkage to
the actin cytoskeleton may contribute to the changes in cell motility
exhibited by the Cx431KO and CMV43 CNCs. Previous studies have shown
that molecular changes affecting the strength of integrin-cytoskeletal
linkages can alter the speed of cell locomotion
(Lauffenburger and Horwitz,
1996; Schmidt et al.,
1995). Although changes in the abundance of integrins also can
affect cell motility, our cell surface biotinylation experiments indicated no
change in cell surface ß1 integrin expression level in the CMV43
CNCs.
Despite the poor motile function exhibited by Cx431KO CNCs, it is
interesting to note that the Cx431KO CNCs actually showed increased
protrusive activity. This was associated with a loss of polarized cell
morphology. The latter is consistent with the reduced directionality of cell
movement. Directional cell locomotion depends on the coordinated polarized
assembly of new focal complexes at the leading edge of the cell and the
disassembly of focal complexes at the cell rear
(Huttenlocher et al., 1995;
Lauffenburger and Horwitz,
1996). A defect in the release of cell processes was indicated by
the effects of Sema3a on Cx431KO and CMV43 CNCs. Actin stress fibers
play an important role in the retraction of the trailing edge of the cell and
contraction of the cell body
(Etienne-Manneville, 2004). In
Cx431KO cells, the actin cytoskeleton showed a marked change, with
stress fibers exhibiting a polygonal arrangement around the cell cortex, and
with some stress fibers not anchored in focal adhesions. Cx431 was
found to be closely associated with actin stress fibers at regions of
cell-cell contact. Although Cx431 has not been shown to bind actin,
Cx431 co-immunolocalized and co-immunoprecipitated with vinculin, and a
number of other actin-binding proteins, including IQGAP-1, drebrin and
-actinin. Together with previous reports showing binding of
Cx431 with ZO-1, and the close association of Cx431 with
ß-catenin and -catenin
(Giepmans and Moolenaar, 1998;
Ai et al., 2000;
Govindarajan et al., 2002;
Wei et al., 2005;
Wu et al., 2003), an important
role is indicated for Cx431 in the dynamic regulation of the actin
cytoskeleton.
Our studies showed no correlation between the level of dye coupling and
changes in motile cell behavior. This is similar to the results of our earlier
studies examining motile cell behavior and dye coupling levels in CNCs derived
from a variety of different transgenic and knockout mouse models
(Xu et al., 2001). Overall,
these findings do not support a role for cell-cell communication via gap
junction channels in modulating cell motility. However, we cannot exclude a
role for gap junction mediated coupling, and a recent study reported that
migrating neural crest cells maintain short and long distance cell-cell
contacts with other migrating crest cells
(Teddy and Kulesa, 2004).
Based on our present studies, we suggest Cx431 may serve a novel
signaling function that entails crosstalk with cell signaling pathways that
regulate polarized cell morphology. Overall, these findings provides a
framework for future investigations into the dynamic regulation of the actin
cytoskeleton and motile cell behavior by Cx431.
Supplementary material
Supplementary material for this article is available at
http://dev.biologists.org/cgi/content/full/133/18/3629/DC1
|
ACKNOWLEDGMENTS |
|---|
1 antibody and
Dr Diana Walker for helpful discussions. This work was supported by funding
from the Division of Intramural Research of NHLBI/NIH. |
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