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 Previous Article | Next Article 
The Journal of Neuroscience, March 15, 1999, 19(6):1965-1975
Myelin and Collapsin-1 Induce Motor Neuron Growth Cone Collapse
through Different Pathways: Inhibition of Collapse by Opposing Mutants
of Rac1
Thomas B.
Kuhn1,
Michael D.
Brown2,
Christine L.
Wilcox3,
Jonathan A.
Raper4, and
James R.
Bamburg1
Departments of 1 Biochemistry and Molecular Biology,
2 Anatomy and Neurobiology, and 3 Microbiology,
Colorado State University, Fort Collins, Colorado 80523, and
4 Department of Neurosciences, University of Pennsylvania,
School of Medicine, Philadelphia, Pennsylvania 19104
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ABSTRACT |
Precise growth cone guidance is the consequence of a continuous
reorganization of actin filament structures within filopodia and
lamellipodia in response to inhibitory and promoting cues. The small
GTPases rac1, cdc42, and rhoA are critical for regulating distinct
actin structures in non-neuronal cells and presumably in growth cones.
Collapse, a retraction of filopodia and lamellipodia, is a typical
growth cone behavior on contact with inhibitory cues and is associated
with depolymerization and redistribution of actin filaments. We
examined whether small GTPases mediate the inhibitory properties of CNS
myelin or collapsin-1, a soluble semaphorin, in chick embryonic motor
neuron cultures. As demonstrated for collapsin-1, CNS myelin-evoked
growth cone collapse was accompanied by a reduction of
rhodamine-phalloidin staining most prominent in the growth cone
periphery, suggesting actin filament disassembly. Specific mutants of
small GTPases were capable of desensitizing growth cones to CNS myelin
or collapsin-1. Adenoviral-mediated expression of constitutively active
rac1 or rhoA abolished CNS myelin-induced collapse and allowed
remarkable neurite extension on a CNS myelin substrate. In contrast,
expression of dominant negative rac1 or cdc42 negated
collapsin-1-induced growth cone collapse and promoted neurite outgrowth
on a collapsin-1 substrate. These findings suggest that small GTPases
can modulate the signaling pathways of inhibitory stimuli and,
consequently, allow the manipulation of growth cone behavior. However,
the fact that opposite mutants of rac1 were effective against different
inhibitory stimuli speaks against a universal signaling pathway
underlying growth cone collapse.
Key words:
growth cone; actin filaments; small GTPases; myelin; collapsin-1; rac1; semaphorin
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INTRODUCTION |
The function of the adult nervous
system depends on the precise guidance of neuronal growth cones to
their appropriate target by a myriad of attractive and inhibitory cues
(Kolodkin, 1996 ; Tessier-Lavigne and Goodman, 1996). Sensory capacity,
adhesion, and motility of growth cones all reside in lamellipodia and
filopodia. The dynamics and morphology of these highly motile
structures is almost universally coupled to a coordinated assembly,
disassembly, and retrograde flow of actin filaments (Stossel, 1993;
Tanaka and Sabry, 1995). The small GTPases rac1, cdc42, and rhoA
represent key regulators of distinct actin filament structures in
non-neuronal cells in response to extrinsic signals (Nobes and Hall,
1995; for review, see Hall, 1998). Recently, their importance has been demonstrated in neurons as well (for review, see Luo et al., 1997). Rac1 is involved in neurite outgrowth (Luo et al., 1994; Kuhn et al.,
1998), correct target innervation (Kaufmann et al., 1998), formation of
dendritic arbors (Luo et al., 1996), differentiation of neurites
(Threadgill et al., 1997), and growth cone collapse (Jin and
Strittmatter, 1997). Depending on the mode of interaction, inhibitory
cues typically elicit growth cone repulsion, a local retraction of
lamellipodia and filopodia, as opposed to growth cone collapse, a total
loss of lamellipodia and filopodia. In the case of collapsin-1, a
concomitant disassembly of actin filaments has been demonstrated (Fan
et al., 1993). Conversely, an accumulation of actin filaments in
filopodia that contact attractive cues precedes turning of growth cones
toward the guidance source (O'Connor and Bentley, 1993).
To interfere with the detrimental effects of inhibitory cues, both
receptor complexes and associated signaling pathways represent suitable
targets, yet are poorly understood both for collapsin-1 and CNS
myelin-associated factors. The CNS myelin-derived inhibitors NI35/250
and myelin-associated glycoprotein (MAG) elicit rises in free
intracellular Ca2+, whereas collapsin-1 acts via
Ca2+-independent pathways (Ivins et al., 1991;
Bandtlow et al., 1993; Song et al., 1998). Only recently have
neuropilins been identified as receptors for semaphorin family members
(Chen at al., 1997; Kolodkin et al., 1997). Because of the
actin-dependent changes in growth cone morphology associated with
collapse and repulsion, small GTPases represent excellent candidates.
It is conceivable that small GTPases directly participate in the
intracellular signaling of inhibitory cues as suggested by Jin and
Strittmatter (1997). However, their effects on distinct actin filament
structures could simply prove beneficial in the presence of inhibitory cues.
The present investigation demonstrates that adenoviral-mediated
expression of specific constitutively active and dominant negative
mutants of small GTPases in chick motor neurons can compensate for the
inhibitory properties of CNS myelin-associated factors and a soluble
semaphorin, collapsin-1. In particular, opposing rac1 mutants
interfered with growth cone collapse induced by CNS myelin and
collapsin-1 and allowed neurite outgrowth in the presence of either
growth inhibitor, respectively. These results further support a model
in which different inhibitory stimuli elicit distinct intracellular
signals rather than a universal response.
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MATERIALS AND METHODS |
Reagents. Unless specified otherwise, all reagents
were purchased from Sigma (St. Louis, MO).
Cell culture. Spinal cords were dissected from 6- to 7-d-old
chick embryos (White leghorn). The ventral halves of spinal cords, containing mostly motor neurons, were trypsinized (4% trypsin, 0.2 gm/ml EDTA, 15 min, 37°C) and triturated, and the dissociated cells
were preplated (1 hr, 37°C) in high glucose DMEM (Life Technologies, Gaithersburg, MD) and 10% FBS (Hyclone, Logan, UT). Nonadherent cells
were resuspended in DMEM, pH 7.3 (325 ± 5 mOsm), 10% FBS, 12 nM fluorodeoxyuridine, and 1% N3 supplement (10 µg/ml
bovine serum albumin, 100 µg/ml transferrin, 10 µg/ml insulin, 32 ng/ml putrescine, 20 ng/ml triiodothyronine, 10 ng/ml sodium selenite, 12.6 ng/ml progesterone, 200 ng/ml corticosterone) and plated at either
50,000/ml (collapse assay) or 100,000/ml (stripe assay). Glass
coverslips (22 × 22 mm; Carolina Biological Supply, Burlington, NC) or 24-well plates were pretreated with poly-D-lysine
(PL) (10 µg/ml, borate buffer, pH 8.4) and coated with 2 µg/cm2 fibronectin (FN) (Boehringer Mannheim,
Indianapolis, IN) for 1 hr at 37°C.
Collapse assay and stripe assay. For collapse assays, CNS
myelin, enriched collapsin-1, or recombinant collapsin-1 were added in
soluble form to motor neuron cultures. Protein concentrations were
adjusted such that a 10 µl aliquot of CNS myelin or enriched collapsin-1 was added to 500 µl culture medium. In the case of recombinant collapsin-1, protein concentration was adjusted (15 µg/ml, addition of 75 ng) so that ~70% of growth cones collapsed. After incubation for 1 hr at 37°C, cultures were washed with PBS (37°C) and fixed with 2% glutaraldehyde in PBS (37°C), and the percentage of collapsed growth cones was determined. In stripe assays,
2 × 5 mm stripes of filter paper (Whatman #50) were UV-sterilized and saturated with CNS myelin (100 µg/ml) or recombinant collapsin-1 (15 µg/ml) supplemented with 15% rhodamine-labeled dextran
(Molecular Probes, Eugene, OR). Filter stripes were placed on
FN-coated (CNS myelin stripes) or
poly-D-lysine-coated glass coverslips (collapsin-1 stripes)
for 15 min in a humidified incubator at 37°C and removed before
plating of cells. Borders between CNS myelin and FN or collapsin-1 and
PL were visible under fluorescence or even under phase (CNS myelin).
Recombinant adenoviruses. Recombinant adenoviruses were
generated as described by Becker et al. (1994) using an adenovirus subtype 5 deletion mutant (Ad5 dl309). Briefly, c-myc-tagged
constitutively active (V12rac, V12cdc42, V14rhoA) or dominant negative
(N17rac1, N17cdc42) mutants of small GTPases (generous gift from Dr. A. Hall, Cambridge, UK) or lacZ (control) were subcloned into the pMLE1A
shuttle plasmid (kindly provided by Dr. I. Maxwell, Denver, CO) under
the viral E1A promoter. In the shuttle plasmid, the transcription
cassettes were flanked by the Ad5 fragment ranging from map unit 0 to
1.3 and the Ad5 fragment ranging from map unit 9.1 to 15.9. Shuttle
plasmids were linearized at a unique XhoI restriction site
and 10 µg of each was co-transfected with 10 µg of pJM17 (McGrory
et al., 1988) (Microbix Biosystems, Toronto, Ontario, Canada) into
293 cells (ATCC CRL 1573). Homologous recombination rescued
viral sequences with the expression cassette, containing c-myc-tagged
small GTPase mutants, inserted into the left end of the truncated viral
genome resulting in replication-deficient adenoviruses
(V12rac-AdE1A,
V12cdc42-AdE1A,
V14rhoA-AdE1A,
N17rac1-AdE1A,
N17cdc42-AdE1A,
lacZ-AdE1A). Routinely, titers were 1 × 108 to 1 × 109, and
aliquots of viral stocks were stored at  80°C. Long-term storage and
repetitive freeze-thawing had no effect on virus titers. Motor neuron
cultures were infected 4 hr after plating with 200 plaque-forming units
per neuron [multiplicity of infection (moi)] of recombinant
adenovirus in 300 µl of culture medium. Cultures were supplemented
with 700 µl of fresh medium 16 hr after infection. We were unable to
generate recombinant adenoviruses for expression of small GTPases under
the cytomegalovirus (CMV) immediate early promoter. Mutants of
small GTPases were toxic for proliferating cells, even bacteria,
possibly because of leaky expression under the CMV promoter. However,
using the E1A promoter we successfully generated recombinant adenovirus
vectors expressing the small GTPases. Expression of genes under the E1A
promoter is downregulated in 293 cells because the presence of the E1A
transgene product in these cells represses E1A promoter activity
(Schaack et al., 1998). Therefore, the E1A promoter was suitable for
use to construct adenovirus vectors to express proteins that were toxic
for cell proliferation.
Immunocytochemistry and histochemistry. Cultured motor
neurons were fixed in 4% paraformaldehyde, 0.1% glutaraldehyde, 100 mM Na-phosphate, pH 7.4, 120 mM sucrose for 30 min at room temperature, washed three times with PBS, and permeabilized
with 0.5% Triton X-100 in PBS. Primary antibodies or
rhodamine-phalloidin were added for 2 hr at room temperature.
Secondary antibodies diluted in PBS/2%BSA were incubated for 1 hr at
room temperature. Cultures were stored in 90% glycerol/PBS at
20°C. The following primary antibodies were used: a monoclonal
mouse anti-c-myc IgG (9E10) (1 µg/ml; Santa Cruz Biotechnology, Santa
Cruz, CA), a rabbit polyclonal anti-c-myc IgG (0.5 µg/ml; Upstate
Biotechnology, Lake Placid, NY), rhodamine-phalloidin (1:50; Molecular
Probes, Eugene, OR), and a monoclonal mouse anti-tubulin (1:250; Sigma,
St. Louis, MO). A Texas Red-labeled polyclonal goat anti-mouse IgG
(Molecular Probes) and a fluorescein-labeled polyclonal goat anti-mouse
IgG (Molecular Probes) were used as secondary antibodies (1:500). Alternatively for histochemical staining, cultures were fixed, permeabilized, and incubated with anti-c-myc IgG (0.5 µg/ml) followed by a biotinylated goat anti-mouse IgG (Pierce, Rockford, IL).  -Galactosidase coupled to avidin (0.2 U/ml; Pierce) was added (1 hr,
37°C), and cultures were incubated overnight with 0.5 mg/ml 5-bromo-4-chloro-3-indolyl--D-galactoside (Life
Technologies, Gaithersburg, MD), 5 mM potassium
ferricyanide, 5 mM potassium ferrocyanide, 2 mM
MgCl2, 150 mM NaCl, and 15 mM sodium phosphate, pH 7.3.
Preparation and characterization of growth cone particles.
Highly enriched preparations of growth cone particles (GCPs) were obtained as described in Pfenninger et al. (1983) with modifications according to Lockerbie et al. (1991). Briefly, fresh brains from 10- to
14-d-old chick embryos were homogenized (on ice) in 6-8 vol (wet
weight to volume) of 5 mM HEPES, pH 7.3, 1 mM
MgCl2, and 0.32 M sucrose. After a
low-speed centrifugation of the crude homogenate (1500-1660 × gmax, 15 min, 4°C), the
resulting supernatant was overlaid onto 5 mM HEPES, pH 7.3, 1 mM MgCl2, and 0.75 M
sucrose and centrifuged at 150,000 × gmax
(1 hr, 4°C). Material at the interface was collected, diluted six- to
sevenfold with 5 mM HEPES, pH 7.3, 1 mM
MgCl2, and 0.32 M sucrose (added
dropwise on ice), overlaid onto 2 ml of Maxidense (Sigma), and
centrifuged at 40,000 × gmax (1 hr,
4°C). Sealed GCPs were collected from the interface between load and
Maxidense cushion, gently resuspended in Krebs' buffer (145 mM NaCl, 5 mM KCl, 1.2 mM
NaH2PO4, 1.2 mM
MgCl2, 5 mM HEPES, pH 7.3), and stored
at 80°C. Freshly prepared GCPs (100 µg total protein) were
treated with various conditions for 1 hr at 37°C. Samples were
solubilized in 1% Triton X-100/0.02% saponin and separated by
high-speed centrifugation (1 hr, 4°C, 100,000 × gmax) into a cytoskeletal (pellet) and a
cytosol (supernatant) fraction. Proteins in the supernatant were
precipitated with chloroform/methanol (Wessel and Flügge, 1984),
resuspended in SDS sample preparation buffer (250 mM
Tris-Cl, pH 6.8, 10% glycerol, 1% SDS, 10% 2-mercaptoethanol, 0.01%
bromophenol blue), and boiled for 5 min. Protein pellets were directly
resuspended in this buffer.
Gel electrophoresis and Western blotting. Cell cultures were
extracted with 2% SDS, 10 mM Tris-Cl, pH 7.5, 10 mM NaF, 5 mM dithiothreitol, and 2 mM EGTA. Soluble protein was boiled (5 min), precipitated
with chloroform/methanol, and resuspended in SDS sample preparation
buffer. Protein from GCPs was prepared as detailed above. All protein
concentrations were determined as described by Minamide and Bamburg
(1990). SDS-PAGE was performed according to Laemmli (1970), and
gels were stained with Coomassie blue or silver (Oakley et al., 1980).
Western blotting onto polyvinylidene difluoride (PVDF) membranes
(Gelman Sciences, Ann Arbor, MI) was performed as detailed in Towbin et
al. (1979). Membranes were blocked with 5% nonfat dry milk in TBS (10 mM Tris-Cl, pH 8.0, 150 mM NaCl), washed with
TBS/0.05% Tween 20, and incubated for 1 hr with primary antibody
diluted in TBS/0.05% Tween 20/1% BSA. The primary antibody used was a
monoclonal mouse anti-Rac1 (1 µg/ml; Upstate Biotechnology) or a
monoclonal mouse anti-actin (ICN Biomedicals, Aurora, OH). Membranes
were washed with TBS/0.05% Tween-20 and incubated with secondary
antibodies for 1 hr (alkaline phosphatase conjugated to goat
anti-rabbit IgG or anti-mouse IgG, 1:10,000), and bands were visualized
with Nitroblue tetrazolium chloride and
5-bromo-4-chloro-3-indolylphosphate p-toluidine salt (Life Technologies).
Preparation of CNS myelin and enriched collapsin-1. CNS
myelin was prepared from adult rat brain as reported by Norton and Poduslo (1973). Briefly, adult rat brain was homogenized in 0.32 M sucrose, and the homogenate was overlaid onto 0.85 M sucrose and centrifuged for 30 min (75,000 × gmax). Crude CNS myelin was collected
from the interface and washed twice in ice-cold water (25,000 × gmax, 30 min). The resulting pellet was
resuspended in 0.32 M sucrose, overlaid onto 0.85 M sucrose, and centrifuged for 1 hr (75,000 × gmax). Purified CNS myelin was collected
from the interface, washed twice in ice-cold water, and stored at
80°C. Before addition to cell cultures, purified CNS myelin was
resuspended in PBS. Protein extracts were prepared from purified CNS
myelin by solubilizing in 2% octylglucoside followed by centrifugation (1 hr, 4°C, 100,000 × gmax) and
dialysis of the resulting supernatant overnight against PBS. Enriched
collapsin-1 was obtained according to Fan et al. (1993). Briefly,
purified chick brain membranes from 10- to 14-d-old chick embryos were
solubilized in 2% 3-[(3-cholamidopropyl)dimethylammonio]-1-propane sulfonate and centrifuged (1 hr,
4°C, 100,000 × gmax), and the resulting supernatant was dialyzed overnight against PBS. This protein
extract was used immediately thereafter or stored for a maximum of
3 d at 4°C. Dialyzed extraction buffer was used as control
condition. Purified recombinant collapsin-1 was prepared as described
previously (Luo et al., 1995) and used at a concentration to collapse
70% of motor neuron growth cones as was obtained with enriched
collapsin-1 or purified CNS myelin.
Image analysis and statistics. Analysis of growth cone
collapse was performed on a Nikon inverted microscope (Diaphot 300) using a 40× oil objective (Nikon) and a Dage MTI tube video camera (Vidicon VT-1000). Quantitative analysis of rhodamine-phalloidin was
performed on a Nikon inverted microscope (Diaphot 200) equipped with a
computer controlled CCD camera (PXL Photometrics, Tucson, AZ) using a
60× oil objective (Nikon). Images were captured with Metamorph imaging
software run on a Pentium PC (Universal Imaging Corporation, West
Chester, PA). Images were acquired using identical parameters, and
total fluorescence intensity was measured on a pixel-by-pixel basis
after background subtraction. Growth cones were subdivided into a
peripheral region, a central region (defined by microtubule bundles),
and the proximal neurite. All measurements were normalized to the
average of the peripheral region under control conditions. One-way
ANOVA analysis and a Kruskal-Wallis test were used when comparing
multiple samples. Dunnett's test was used when comparing the means of
multiple conditions with a single control. In both cases, a
p value < 0.01 was considered significant.
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RESULTS |
Adenoviral-mediated expression of small GTPases in primary chick
motor neurons
We used recombinant, replication-deficient adenoviruses to express
c-myc-tagged constitutively active and dominant negative mutants of
rac1 (V12rac1, N17rac1), cdc42 (V12cdc42, N17cdc42), and rhoA (V14rhoA)
in dissociated, embryonic chick motor neurons. Two to three days after
infection with a recombinant adenovirus carrying V12rac1 or
V12cdc42 under the viral E1A promoter
(V12rac1-AdE1A or
V12cdc42-AdE1A), V12rac1 and
V12cdc42 proteins were present in motor neuron growth cones
as revealed by indirect immunofluorescence against c-myc. We measured a
2.7-fold increase in the total fluorescence intensity per square
micrometer in growth cones of
V12rac1-AdE1A-infected motor neurons
(4.96 ± 0.5, n = 36, p < 0.01)
compared with lacZ-AdE1A-infected cultures
(1.86 ± 0.9, n = 24), which was our control. A
1.83-fold increase in total fluorescence intensity per square micrometer was measured in growth cones of neurons infected with V12cdc42-AdE1A (3.30 ± 0.31, n = 27, p < 0.01) compared with
uninfected controls (1.80 ± 0.24, n = 20).
Quantitative Western blotting revealed a total rac1 immunoreactivity
proportional to the moi. There was a 20-50% increase in
immunoreactivity in
V12rac1-AdE1A-infected cultures compared
with controls (Fig.
1B). An moi-dependent increase in expression was also measured for V12cdc42 and
N17cdc42. Adenoviral expression of small GTPase mutants was
maximal 3 d after infection, increasing from 35 ± 5%
(n = 208) c-myc-positive motor neurons at 1 d
after infection to 88 ± 7% (n = 176, p < 0.05) at 3 d after infection, as illustrated
for V12rac1 (Fig.
2A). Over a time period
of 3 d, the percentage of neurite-bearing neurons remained
constant regardless of infection with recombinant adenovirus (200 moi)
and expression of small GTPase mutants, suggesting that motor neuron
survival was not affected. However, neuronal survival was diminished
3 d after infection with higher mois, in particular for cdc42
mutants.
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Figure 1.
Adenoviral-mediated expression of c-myc-tagged
mutants of small GTPases in chick motor neurons. A,
Motor neurons from 6-d-old chick embryos were plated on fibronectin and
infected with a recombinant adenovirus carrying c-myc-tagged
constitutively active rac1 under the viral E1A promoter
(V12rac1-AdE1A). Three days after
infection, c-myc immunoreactivity is present in growth cones and cell
bodies (data not shown) of motor neurons. B, In
lacZ-AdE1A-infected cultures, c-myc immunostaining
was very faint, indicating very little unspecific staining using the
anti-c-myc antibody. C, Motor neuron cultures were
infected with V12rac1-AdE1A using a
multiplicity of infection (moi or ratio of virus
particles to neurons) of 20, 50, and 100. Three days after infection,
cultures were solubilized, and extracted proteins were separated by
15% SDS-PAGE. After transfer to PVDF membranes, the presence of
V12rac1 was demonstrated using a rac1-specific antibody.
D, Rac1-immunoreactive bands were quantified by
densitometric analysis and normalized to the values at 20 moi. Total
rac1 immunoreactivity was proportional to the moi.
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Figure 2.
Mutants of small GTPases expressed via recombinant
adenoviruses are functional. A, Motor neurons were
infected with c-myc V12rac1-AdE1A (200 moi) and stained for c-myc using -galactosidase-enhanced
histochemistry. The percentage of c-myc-positive motor neurons is
plotted against days after infection in c-myc
V12rac1-AdE1A-infected cultures ( )
compared with controls ( ). More than 90% of c-myc
V12rac1-AdE1A-infected motor neurons
were c-myc positive 3 d after infection. B, Motor
neurons were grown on FN and infected with
V12rac1-AdE1A (, 200 moi) or
lacZ-AdE1A ( , 200 moi) at the time of plating.
The longest neurite per neurons was measured, and their distribution in
a motor neuron population was plotted. Only neuronal processes >10
µm long were considered neurites. Expression of V12rac1
attenuates 1 integrin-mediated neurite outgrowth on the FN substrate
(2 day postinfection), which is consistent with previous
findings using trituration loading of motor neurons with purified
recombinant V12rac1 protein (Kuhn et al., 1998).
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Adenoviral-mediated expression of rac1 mutants affected growth cone
advance and actin filament distribution of growth cones as shown
previously by trituration loading of chick motor neurons with purified,
recombinant rac1 mutants (Kuhn et al., 1998). Expression of
V12rac1 attenuated 1 integrin-mediated neurite outgrowth
of motor neurons on FN (Fig. 2B). Average neurite
length was significantly reduced to 29 ± 2 µm
(n = 107, p < 0.001) at 1 d after
infection and 38 ± 2 µm (n = 111, p < 0.001) at 2 d after infection compared with
lacZ-AdE1A-infected cultures 1 d after
infection (39 ± 2 µm, n = 64) or 2 d after
infection (76 ± 4 µm, n = 74), respectively.
Accumulation of actin filaments occurred in the presence of
V12rac1 as suggested by a significant increase of the total
rhodamine-phalloidin fluorescence per growth cone (1.25 + 0.06, n = 32, p < 0.01; normalized to
control) in V12rac1-AdE1A-infected
cultures. Infection of motor neuron cultures with mutants of cdc42 and
rhoA also resulted in changes in growth cone morphology, neurite
outgrowth, and actin filament distribution (data not shown). In
summary, adenoviral-mediated gene transfer allows the effective expression of constitutively active and dominant negative mutants of
small GTPases in dissociated, embryonic chick motor neurons. Behavioral
and morphological changes of growth cones in conjunction with a
redistribution of actin filaments provide strong evidence that small
GTPases are functional.
CNS myelin induces a loss of actin filaments in growth cones
Growth cone collapse, a loss of lamellipodia and filopodia, is
inherently connected to severe alterations in the distribution of actin
filaments as has been demonstrated for collapsin-1 (Fan et al., 1993).
To test whether CNS myelin-associated inhibitors evoke similar effects,
we visualized actin filament distribution in motor neurons exposed to
CNS myelin using rhodamine-labeled phalloidin.
In the presence of purified CNS myelin (100 µg/ml), motor neuron
growth cones displayed a collapsed morphology. A decrease in
rhodamine-phalloidin fluorescence suggested a CNS myelin-induced rearrangement of actin filaments (Fig.
3). We quantified changes in
rhodamine-phalloidin staining by integrating the fluorescence intensity on a pixel-by-pixel basis over the area of three growth cone
regions: a central region defined by microtubule bundles, a peripheral
region containing filopodia and lamellipodia, and 15 µm of the
proximal neurite. All values were normalized to the average integrated
fluorescence intensity of the peripheral region under control
conditions. CNS myelin caused a substantial loss of actin filaments
throughout the entire growth cone but was most pronounced in the
periphery (Fig. 4A). We
detected a large reduction of rhodamine fluorescence intensity in the
peripheral region of CNS myelin-treated growth cones (0.17 ± 0.03, n = 23, *p < 0.001) and, to a
lesser degree, in the central region (0.35 ± 0.06, n = 23, *p < 0.001) and in the
proximal neurite (0.18 ± 0.03, n = 23, *p < 0.001) compared with the same regions in controls
(1.0 ± 0.11, n = 20, peripheral region; 0.69 ± 0.11, n = 20, central region; 0.45 ± 0.06, n = 20, proximal neurite).
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Figure 3.
CNS myelin-associated growth inhibitors cause a
rearrangement of actin filaments in motor neuron growth cones. Motor
neurons were grown on FN for 2 d and then treated with PBS
(A, B) or 100 µg/ml CNS myelin
(C-F). Cultures were fixed and stained for actin
filaments with rhodamine-labeled phalloidin (A, C, E) or
for microtubules using a monoclonal anti-tubulin antibody followed by a
fluorescein-conjugated secondary antibody (B, D,
F). In controls, growth cones displayed many actin
filament-rich filopodia and lamellipodia (A) with
a dense bundle of microtubules defining the central region of the
growth cones (B). On exposure to CNS myelin,
growth cones retracted both lamellipodia and filopodia concomitant with
a decrease in rhodamine fluorescence predominantly in the periphery.
C, Often motor neuron growth cones responded to CNS
myelin by retracting the entire peripheral region using the tubulin
staining as our criteria. E, In some cases, motor neuron
growth cones displayed stubby filopodial remnants with decreased
rhodamine fluorescence in the peripheral region. Images were acquired
using identical parameters. Scale bar, 10 µm.
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Figure 4.
CNS myelin-associated growth inhibitors signal a
disassembly of actin filaments. A, Motor neurons were
grown on FN for 2 d, treated with PBS (open bars)
or 100 µg/ml CNS myelin (filled bars), and
actin filaments were visualized with rhodamine-labeled phalloidin.
Growth cones were divided into a peripheral region, a central region
defined by intense microtubule staining, and 15 µm of the proximal
neurite. Images were acquired using identical parameters, and the total
fluorescence intensity was analyzed in each growth cone region on a
pixel-by-pixel basis after background subtraction. All values were
normalized to the total fluorescence intensity of the peripheral region
in control growth cones. CNS myelin caused a significant reduction of
rhodamine fluorescence in the peripheral region (*p < 0.001) and also in the central region (*p < 0.001) and the proximal neurite (*p < 0.001). The
loss of rhodamine fluorescence suggests a net disassembly of actin
filaments signaled by CNS myelin as reported for collapsin-1 (Fan et
al., 1993). B, Freshly prepared, intact growth cone
particles were incubated with 100 µg/ml CNS myelin
(My), 15 µg/ml enriched collapsin-1
(CLP), a mixture of 2 mM CaCl2
and 10 µM A23187 (A23), 50 µg/ml laminin
(LN), or PBS (Con). After 1 hr,
samples were solubilized and separated into a cytoskeletal fraction and
cytosol fraction by high-speed centrifugation (100,000 × gmax). Proteins were separated on
10% SDS-PAGE and blotted onto PVDF membranes. The percentage of total
actin in each fraction was determined by densitometry. Plotted is the
percentage of total actin immunoreactivity in the cytoskeletal
fraction, most likely actin filaments of various lengths, for each
treatment. A significant decrease in filamentous actin occurred during
incubation with CNS myelin (*p < 0.0001) or
enriched collapsin-1 (*p < 0.01). As our control,
large increases in the free intracellular Ca2+
concentration results in an almost complete depletion of actin
filaments (*p < 0.0001). In contrast, incubation
with LN caused an increase in actin immunoreactivity in the
cytoskeletal fraction, suggesting a net polymerization of actin
filaments (**p < 0.01).
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A biochemical assay further supported a CNS myelin-induced loss of
actin filaments. Highly enriched, sealed GCPs (100 µg of total
protein) were treated with CNS myelin (100 µg/ml), purified recombinant collapsin (750 ng/ml), laminin (50 µg/ml),
CaCl2 (2 mM)/A23187 (10 µM), or
buffer. A cytoskeletal fraction, containing insoluble actin, was
separated from a cytosol fraction, containing soluble actin, by
high-speed centrifugation (Helmke and Pfenninger, 1995). Relative actin
content in each fraction was determined by quantitative Western
blotting (Fig. 4B). Incubation of GCPs with CNS
myelin reduced the relative actin content in the cytoskeletal fraction
(33 ± 2%, n = 6, *p < 0.0001)
compared with control (51 ± 2%, n = 6), implying
a depolymerization of actin filaments. Also, treatment with 2 mM CaCl2 and 10 µM A23187
resulted in an almost complete depletion of actin in the cytoskeletal
fraction (4 + 2%, n = 3, *p < 0.0001). In contrast, laminin increased actin in the cytoskeletal
fraction (65 + 4%, n = 3, p < 0.01).
Taken together, these results suggest that changes in growth cone
morphology and behavior induced by CNS myelin originate, at least
partially, from a loss of actin filament structures.
V12Rac1 and V14rhoA protect motor neurons
from CNS myelin-induced growth cone collapse
CNS myelin as well as a protein extract obtained from CNS myelin
caused a dose-dependent growth cone collapse when added in soluble form
to motor neuron cultures (Fig.
5A). In the presence of 80 µg/ml CNS myelin, a maximum of 72 ± 2% (open bars;
n = 100, *p < 0.01) of growth cones
investigated displayed a collapsed morphology compared with PBS, our
control (26 ± 4% collapsed growth cones; n = 70). Similarly, 80 µg/ml of CNS myelin-derived protein extract
collapsed 69 ± 7% of growth cones (n = 103, **p < 0.01) compared with 24 ± 5% collapsed
growth cones (n = 127) in controls (dialyzed extraction
buffer). It is noteworthy that a fair number of motor neuron growth
cones exhibited a collapsed morphology under normal culture
conditions.
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Figure 5.
Dose-dependent CNS myelin-induced collapse of
motor neuron growth cones is abolished by expressing
V12rac1 or V14rhoA. A, Motor
neurons were grown on FN for 2 d and then treated with CNS myelin
(open bars) or a protein extract obtained from CNS
myelin (hatched bars). In the case of CNS myelin,
concentration of 20 µg/ml or higher achieved significant numbers of
collapsed growth cones (*p < 0.01), whereas as
little as 10 µg/ml CNS myelin protein extract induced significant
growth cone collapse (**p < 0.01). Importantly, a
basal level of collapsed growth cones existed in these motor neuron
cultures. B, Motor neurons were infected at the time of
plating with recombinant adenovirus carrying mutants of small GTPases
and grown for 3 d. Cultures were treated with 100 µg/ml CNS
myelin (stippled and filled bars) or with
PBS (open bars). The percentage of collapsed growth
cones was determined as a function of small GTPase mutants that were
expressed. Only expression of constitutively active rac1
(V12rac1, filled bar) and rhoA
(V14rhoA, filled bar) inhibited
CNS myelin-induced growth cone collapse (*p < 0.01). Expression of other small GTPase mutants or lacZ was ineffective
(stippled bars). It is noteworthy that a fraction of
motor neuron growth cones exhibited a collapsed morphology regardless
of proteins expressed (open bars). C,
Motor neurons were plated on FN-coated dishes containing stripes of CNS
myelin (100 µg/ml), infected with recombinant adenovirus carrying
mutants of small GTPases, and grown for 3-4 d. The length of neurites
grown entirely on CNS myelin stripes or grown into CNS myelin stripes
was measured. Neurite length per 500 µm2 CNS
myelin is plotted as a function of small GTPase mutants expressed.
Expression of either V12rac1 or V14rhoA
(open bars) resulted in considerable neurite
outgrowth on CNS myelin (*p < 0.01) compared
with lacZ or the other small GTPase mutants (filled
bars). Con, PBS; lacZ, reporter
gene coding -galactosidase; V12rac1,
constitutively active rac1; N17rac1, dominant
negative rac1; V12cdc42, constitutively active
cdc42; N17cdc42, dominant negative cdc42;
V14rhoA, constitutively active rhoA.
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Motor neurons expressing mutants of small GTPases were exposed to
soluble CNS myelin to elucidate their potential role in CNS
myelin-induced growth cone collapse. Dissociated motor neurons were
infected with V12rac1-AdE1A,
N17rac1-AdE1A,
V12cdc42-AdE1A,
N17cdc42-AdE1A,
V14rhoA-AdE1A, or
lacZ-AdE1A (200 moi) and treated with 100 µg/ml
CNS myelin 3 d after infection, and the percentage of collapsed
growth cones was determined (Fig. 5B). Importantly,
expression of V12rac1 (24 ± 2% collapsed growth
cones; n = 75, *p < 0.01) and
V14rhoA (55 ± 4% collapsed growth cones;
n = 113, *p < 0.01) protected motor
neuron growth cones from CNS myelin-induced collapse compared with
lacZ-AdE1A-infected cultures (82 ± 1%
collapsed growth cones; n = 82) or uninfected cultures
(79 ± 3% collapsed growth cones; n = 95), respectively. An identical correlation was evident when distinguishing between motor neurons expressing the c-myc tag and noninfected motor
neurons using -galactosidase-enhanced histochemistry. In the case of
V12rac1, 12 ± 5% (n = 100, p < 0.05) of c-myc-positive motor neurons (i.e., those
expressing the viral-encoded rac1 mutants) had collapsed growth cones
as opposed to 78 ± 8% (n = 100) of
c-myc-negative motor neurons. In
N17rac1-AdE1A-infected cultures, the
fraction of collapsed growth cones of c-myc-positive motor neurons
(90 ± 4%, n = 90) was indistinguishable from
that of c-myc-negative motor neurons (85 ± 6%, n = 100) or lacZ-AdE1A-infected cultures (80 ± 5%, n = 100). Because -galactosidase-enhanced histochemistry is a nonlinear amplification, and given the tight correlation of both analyses, evaluation of collapse of all growth cones is a much less biased approach. None of the other small GTPase
mutants tested interfered with CNS myelin-induced collapse or affected
the basal level of collapsed growth cones (Fig. 5A, open
bars). Taken together, constitutively active mutants of rac1 and
rhoA specifically compensated for the collapsing activity of CNS
myelin. These findings suggest either that rac1 and rhoA participate in
CNS myelin signaling through their inactivation or their constitutively
active mutants preferentially alter growth cone behavior to resist
collapse, probably through their effects on actin organization.
Expression of V12rac1 or V14rhoA enables
motor neurons to extend neurites in the presence of CNS myelin
Because V12rac1 and V14rhoA protected
growth cones against the effects of CNS myelin, we tested whether these
mutants would permit neurite outgrowth in the presence of CNS myelin.
Motor neurons were plated on FN-coated dishes containing stripes of CNS
myelin (100 µg/ml) and infected with
V12rac1-AdE1A,
N17rac1-AdE1A,
V12cdc42-AdE1A,
N17cdc42-AdE1A,
V14rhoA-AdE1A, or
lacZ-AdE1A (200 moi). As illustrated in Figure
6A,
V12rac1-expressing motor neuron cultures and also
V14rhoA-expressing motor neurons (data not shown) exhibited
considerable neurite outgrowth 3 d after infection in the presence
of CNS myelin (55 and 33% of fields investigated, respectively). In
contrast, only marginal neurite outgrowth was achieved by expressing
N17rac1 (Fig. 6C), V12cdc42,
N17cdc42, or lacZ (17% of fields investigated). Neurite
outgrowth on FN-coated areas was comparable among cultures infected
with mutants of small GTPases or lacZ (Fig. 6B,D). To
quantify these effects, we determined the length of neuronal process
either grown entirely on or extending into CNS myelin-coated regions
(area surveyed, >100,000 µm2) (Fig.
5C). Expression of V12rac1 achieved an average
neurite length per 500 µm2 of CNS myelin of
64 ± 6 µm (*p < 0.01) or an almost sixfold
increase compared with controls (lacZ-AdE1A, 11 ± 2 µm/500 µm2 CNS myelin). The presence of
V14rhoA also achieved considerable neurite outgrowth on CNS
myelin (25 ± 4 µm/500 µm2 CNS myelin). On
FN, motor neurons established a rather elaborate network of processes
after 3 d in culture (100,000 cells/ml); thus, length of
individual neurites, grown entirely on FN, could not be determined.
Taken together, motor neurons extend neurites in the presence of CNS
myelin only when expressing V12rac1 or V14rhoA,
supporting our findings with regard to CNS myelin-induced growth cone
collapse.
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Figure 6.
Motor neurons only establish neurites on CNS
myelin when expressing V12rac1. Motor neurons were plated
on FN-coated dishes containing stripes of CNS myelin (100 µg/ml) and
infected (200 moi) with V12rac1-AdE1A
(A, B) or N17rac1-AdE1A
(C, D). A, Three days after infection,
motor neurons expressing V12rac1 exhibit neurites grown
entirely (asterisk) on CNS myelin-coated areas
(My) as well as crossing into CNS myelin stripes
(arrowheads). Dotted line marks the
FN-CNS myelin border. B, Neurites grown exclusively on
FN, however, are much longer and more branched (same cultures as in
A), forming a rather intricate network.
C, Despite N17rac1-expressing motor neurons
extending neurites toward CNS myelin stripes (My),
neurite growth into or entirely on CNS myelin stripes was only marginal
(arrowhead) or even absent. The dashed
line indicates the border between CNS myelin and FN.
D, Nevertheless, on FN (same culture as in
C), N17rac1-expressing motor neurons
established a network of neurites comparable to that in
V12rac1-infected cultures. Scale bar, 20 µm.
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N17Rac1 and N17cdc42 protect motor neuron
growth cones from the inhibitory effects of collapsin-1
In dorsal root ganglion (DRG) neuron cultures, rac1 mediates
collapsin-1-induced growth cone collapse (Jin and Strittmatter, 1997).
Therefore, we tested whether, in motor neuron cultures, collapsin-1-induced growth cone collapse was also associated with rac1
and possibly cdc42 and rhoA.
Enriched collapsin-1 (200 µg/ml) caused a dose-dependent collapse of
motor neurons reaching 62 ± 3% (n = 124, p < 0.01) collapsed growth cones (Fig.
7A). Incubation of GCPs with
enriched collapsin-1 reduced the relative actin content in the
cytoskeletal fraction (40 ± 4%, n = 3, p < 0.01; control = 51 ± 2%,
n = 6) supporting a depolymerization of actin filaments
as described in DRG growth cones (Fan et al., 1993). To investigate the
role of small GTPases in mediating the action of collapsin-1, motor
neurons expressing mutants of small GTPases were treated with 200 µg/ml enriched collapsin-1 or 150 ng/ml purified recombinant
collapsin-1 3 d after infection (Fig. 7B). Expression
of N17rac1 drastically reduced the fraction of collapsed
growth cones (32 ± 3%, n = 134, *p < 0.01) compared with
lacZ-AdE1A-infected cultures (71 ± 2%
collapsed growth cones; n = 152), confirming previous
observations by Jin and Strittmatter (1997). In our study,
expression of N17cdc42 also effectively abolished growth
cone collapse (39 ± 3%, n = 145, *p < 0.01). Furthermore, we coated collapsin-1 in
small stripes onto poly-D-lysine to assess a potential
stimulation of neurite outgrowth by N17rac1 or
N17cdc42 or both. In accordance with our results in
the collapse assay, motor neurons expressing N17rac1 or
N17cdc42 displayed significant neurite outgrowth in the
presence of collapsin-1 (Figs. 7C,
8). Outgrowth on collapsin-1 (95 ± 7 µm, n = 61, *p < 0.001 in the case
of N17rac1 and 91 ± 5 µm, n = 75, *p < 0.001 in the case of N17cdc42,
respectively) was comparable to that on PL in the same cultures
(N17rac1: 98 ± 7 µm, n = 59 and
N17cdc42: 92 ± 6 µm, n = 68).
However, in our culture system, a basal level of neurite outgrowth was
observed on collapsin-1 stripes regardless of the expression of mutants
of small GTPases or lacZ (57 ± 5 µm, n = 72).
In summary, only N17rac1 or N17cdc42 negate
collapsin-1-induced collapse and support growth on collapsin-1. This
finding suggests either that cdc42 and rac1 are constituents of a
signaling cascade activated by collapsin-1 or their dominant negative
mutants alter actin filament organization favorably to protect against
collapse.
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Figure 7.
N17rac1 and
N17cdc42 protect motor neuron growth cones from
collapsin-1-induced collapse and support neurite outgrowth on a
collapsin-1 substrate. A, Motor neurons grown on FN for
2 d were treated with increasing concentrations of enriched
collapsin-1, and the number of collapsed growth cones was determined.
Growth cone collapse was dose-dependent. A minimal concentration of 50 µg/ml was required for a significant number of collapsed growth cones
(*p < 0.01). B, Motor neurons were
plated on FN and infected with recombinant adenovirus carrying mutants
of small GTPases. Three days after infection, cultures were treated
with purified recombinant collapsin-1 (75 ng, 150 ng/ml). The
percentage of collapsed growth cones is plotted as a function of the
small GTPase expressed. Only N17rac1 or
N17cdc42 reduced the fraction of collapsed growth cones
(*p < 0.01) (filled bars),
whereas other small GTPase mutants and lacZ expression were ineffective
(open bars). In particular, the protective effect of
N17rac1 has been reported previously in DRG neurons (Jin
and Strittmatter, 1997). Even in the absence of collapsin-1, a fraction
of motor neuron growth cones was collapsed, independent of proteins
expressed as shown for CNS myelin in Figure 5B.
C, In a similar experiment, motor neurons were plated on
poly-D-lysine-coated dishes containing collapsin-1
stripes and infected with recombinant adenovirus carrying mutants of
small GTPases. The neurite length of the longest neurite per neuron was
measured on polylysine alone (open bars) or on
collapsin-1 (hatched bars and filled
bars), and the average length was plotted as a function of
expressed proteins. Neurite outgrowth on polylysine was
comparable among conditions (open bars). In particular,
expression of N17rac1 or N17cdc42 supported
neurite outgrowth on collapsin-1 (filled bars)
that was indistinguishable from growth on polylysine alone
(*p < 0.001). Neither of the other small GTPase
mutants that were tested significantly increased neurite length on
collapsin-1 (hatched bars). It is noteworthy that motor
neurons exhibited a basal outgrowth on collapsin-1.
lacZ, Control; V12rac1,
constitutively active rac1; N17rac1, dominant
negative rac1; V12cdc42, constitutively active
cdc42; N17cdc42, dominant negative cdc42;
V14rhoA, constitutively active rhoA.
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Figure 8.
Dominant negative mutants of rac1 and cdc42
abolish the growth inhibitory effect of collapsin-1. Motor neurons
expressing V12rac1 (A, D),
N17rac1 (B, E), or N17cdc42
(C, F) were plated on polylysine-coated
dishes containing collapsin-1 stripes. A-C, On
polylysine, motor neurons formed neurites (arrows)
regardless of expressing V12rac1 (A),
N17rac1 (B), or N17cdc42
(C). D-F, On collapsin-1,
expression of V12rac1 (D) achieved
only basal outgrowth (asterisk), whereas both
N17rac1 (E) and N17cdc42
(F) supported neurite outgrowth
(arrowheads) comparable to levels observed on polylysine
alone. Scale bar, 30 µm.
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DISCUSSION |
During development, inhibitory cues direct advancing growth cones
via repulsion and comprise one fundamental guidance force (Tessier-Lavigne and Goodman, 1996; Kolodkin et al., 1997). In the
adult organism, an excessive presence of similar inhibitory cues is
suspected of impairing regeneration of nerve fibers by inducing the
collapse of growth cones. CNS myelin-associated factors, including
NI35/250 and MAG, are potent growth inhibitors both in vitro
and in vivo (Caroni and Schwab, 1988; Schnell and Schwab, 1990; McKerracher et al., 1994; Mukhopadhyay et al., 1994; Tang et al., 1997). Retraction of lamellipodia and filopodia are typical growth cone behaviors on contact with inhibitory cues, reflecting a
substantial rearrangement of actin filaments (Kapfhammer et al., 1987;
for review, see Luo and Raper, 1994). CNS myelin-induced growth cone
collapse is associated with a reduction of rhodamine-phalloidin staining that is most prominent in the growth cone periphery, suggesting a loss of actin filaments (this report). A similar correlation has been demonstrated in growth cones of sensory neurons exposed to collapsin-1 (Fan et al., 1993). Nevertheless, partial loss
of actin filaments is not a universal prerequisite of collapse. The
Eph-ligand AL-1 induces growth cone collapse attributable to
redistribution of actin filaments with no overall loss (Meima et al.,
1997).
We tested whether modulating the activity of small GTPases could
compensate for actin rearrangements in growth cones exposed to
inhibitory cues. We used recombinant, replication-deficient adenoviruses to express constitutively active or dominant negative mutants of epitope-tagged small GTPases in embryonic chick motor neurons. The expression of virally encoded small GTPases was revealed by immunocytochemistry and Western blotting (Fig. 1). The function of
small GTPases requires isoprenylation in the C-terminal region (Adamson
et al., 1992). Attenuation of neurite outgrowth on fibronectin and
changes in the actin filament distribution in motor neuron growth cones
indicated that virally expressed small GTPases were functional.
Identical observations have been obtained previously using trituration
loading with recombinant V12rac1 protein (Kuhn et al.,
1998). In support of these interpretations, microinjection of small
GTPases in the form of protein or DNA into fibroblasts induced changes
in cell behavior and morphology, suggesting successful isoprenylation
(Paterson et al., 1990; Ridley et al., 1992). Furthermore,
isoprenylation of small GTPases has been directly demonstrated in
vitro and in vivo (Birchmeier et al., 1985; Kinsella
and Maltese, 1992; Lang et al., 1996).
Inhibitory stimuli mediated by small GTPases
Our results in combination with previous reports provide evidence
that small GTPases participate in mediating growth cone collapse.
Expression of V12rac1 and V14rhoA but not
V12cdc42 compensated for CNS myelin-induced growth cone
collapse and supported neurite extension in the presence of CNS myelin. Motor neurons expressing dominant negative mutants of rac1 and cdc42
remained sensitive to CNS myelin. In sensory neurons, neither N17rac1 nor wild-type rac1 impaired CNS myelin-dependent
collapse, whereas V12rac1 and V14rhoA have not
been tested (Jin and Strittmatter; 1997). Only recently, LIM-kinase 1 has been identified as a rac1 target. LIM-kinase 1 phosphorylates
cofilin and probably actin depolymerizing factor (ADF), thereby
inactivating these proteins (Arber et al., 1998; Yang et al., 1998).
Increases in the activity of cofilin/ADF support neurite outgrowth
(Meberg et al., 1998). Presently, the role of rhoA in growth cone
collapse is at best controversial. Inhibition of rhoA blocked
lysophosphatidic acid-mediated growth cone collapse in neuronal cell
lines but also caused massive collapse of sensory neuron growth cones
(Jalink et al., 1994; Jin and Strittmatter, 1997). The following
processes are thought to support recruitment/activation of rhoA to the
plasma membrane and cell motility. Phosphorylation of rhoA by protein
kinase A, caused by increases in cAMP, enables a GDP dissociation
inhibitor (rho-GDI) to bind the active, membrane-bound form of rhoA
(Lang et al., 1996; Dong et al., 1998). Association of rho-GDI with
radixin, an ezrin family protein, facilitates rhoA activation, possibly
in a cAMP- and/or Ca2+-dependent manner (Takahashi
et al., 1997). Interestingly, a depletion of radixin in the growth cone
periphery has been observed in collapsing growth cones, and MAG and
NI35/250 stimulate decreases in cAMP and increases in
Ca2+ (Bandtlow et al., 1993; Gonzalez-Agosti and
Solomon, 1996; Song et al., 1998).
Collapsin-1-dependent growth cone collapse and inhibition of neurite
outgrowth was compensated by expressing N17rac1 and
N17cdc42. Similar findings have been reported in sensory
neurons using trituration loading of purified recombinant mutants (Jin and Strittmatter, 1997). N17Rac1 but not
N17cdc42 blocked collapsin-1-induced growth cone collapse.
This discrepancy might be attributable to the rather broad range of
loading efficiency by trituration compared with viral expression, which
achieves more constant levels in the majority of infected cells.
Nevertheless, these results suggest that collapsin-1 causes growth cone
collapse in a rac1/cdc42-dependent manner via increased activity of
small GTPases. This is intriguing because increased GTPase activity usually relates to actin filament formation, whereas collapse usually
correlates with actin filament reduction. However, altering the
coordinated assembly and disassembly of actin filaments by disrupting
either process could contribute to collapse. Small GTPases modulate
both protein kinases (including LIM-kinase 1) and protein phosphatases
such as calcineurin and phosphatase 1, which could influence actin
filament dynamics via the degree of phosphorylation of cofilin/ADF
(Meberg et al., 1998). Indeed, it has been shown that myosin
light-chain phosphatase is inactivated in a rhoA-dependent manner
(Kimura et al., 1996). Thus, in different neuronal cell types, the
relative amounts and localization within the growth cones of different
components of the same signaling pathway could bring about opposite
affects on actin filament dynamics or myosin activation.
Inhibitory stimuli simply compensated by small GTPase
Our findings demonstrated that only certain small GTPase mutants
abolished inhibitory effects of CNS myelin or collapsin-1, whereas
their corresponding opposite mutants neither mimicked nor enhanced the
inhibitory stimuli. There are two explanations for this phenomenon,
both of which are likely occurring. First, the regulation of the
GTP/GDP cycling of small GTPases is tightly regulated by multiple
factors, including GDP/GTP exchangers (GEFs), GDIs, and
GTPase-activating proteins (GAPs) (Boguski and McCormick, 1993).
Constitutively active mutants elicit their effects in the absence of
GEFs, whereas dominant negative mutants act by sequestering endogenous
GEFs. Furthermore, there are regulatory factors that interact with
subsets of small GTPases. Pertinent to our finding, rac1 and cdc42
share a GEF, TIAM-1, which has been implicated in neurite outgrowth,
and rac1 and rhoA share yet another GEF, Trio (Ehler et al., 1997;
Bellanger et al., 1998). Thus, signals that modulate TIAM-1 or Trio
could simultaneously target both rac1 and cdc42 or rac1 and rhoA,
respectively. Second, multiple parallel pathways may be stimulated by
inhibitory cues. Thus, a single small GTPase mutant could abolish an
inhibitory signal, whereas the opposite mutant might have no effect.
For instance, MAG and NI-35/250 alter levels of cAMP and
Ca2+ but collapsin-1 affects cGMP levels and
heterotrimeric G-proteins (Song et al., 1998). These data
suggest that different inhibitory cues elicit distinct intracellular
signaling pathways and are supported by our finding that opposite rac1
mutants impaired CNS myelin- versus collapsin-1-induced collapse.
However, our data do not exclude the alternative that small GTPase
mutants indirectly interfere with collapse via a beneficial
reorganization of the actin cytoskeleton.
Downstream targets of rac1 and cdc42 include N-WASP and IQGAP, two
actin-associated components, and several protein kinases such as
p65PAK, p120ACK, PI-3-kinase, and
S6 kinase (Tapon and Hall, 1997). RhoA-dependent inactivation of myosin
phosphatase strengthens myosin-actin interactions that could alter
retrograde actin filament flow and filopodial motility (Lin et al.,
1996; Wang et al., 1996). Also, GAP-43-induced filopodial formation and
stabilization of microtubules requires rhoA (Aarts et al., 1998; Cook
et al., 1998). Finally, collapsin-1 stimulates anterograde and
retrograde axoplasmic transport, and inhibition of vesicle fusion at
the tip of growth cones induces collapse, suggesting that axonal
transport represents another aspect of collapse (Igarashi et al., 1996,
Goshima et al., 1997).
Conversion of an inhibitory into a permissive environment
Our results provide evidence that small GTPases mediate the
inhibitory effects of CNS myelin and collapsin-1, a soluble semaphorin. As a consequence, inhibitory properties of CNS myelin and collapsin-1 are switched to a permissive environment. An analogous situation exists
in netrin-dependent growth cone guidance. Commissural neurons are
attracted by netrin, whereas thoracic neurons are repelled (Kennedy et
al., 1994; Colamarino and Tessier-Lavigne, 1995). Such a switch in the
nature of the guidance stimuli can be mimicked simply by inhibiting
protein kinase A (Ming et al., 1997). Song et al. (1998) demonstrated
that growth cones, in the presence of a cGMP agonist, are attracted by
collapsin-1. Similarly, growth cones become attracted to MAG by
elevating cAMP levels. In conclusion, modulating signaling pathways
linked to inhibitory stimuli might represent an alternative to
achieving neurite outgrowth in an inhibitory environment. In
particular, small GTPases are ideal candidates because of their
regulation by multiple upstream factors and their influence on actin
filament dynamics.
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FOOTNOTES |
Received Aug. 7, 1998; revised Dec. 9, 1998; accepted Dec. 30, 1998.
This work was supported by Grant 1643 from the Paralyzed Veterans of
America Spinal Cord Research Foundation to T.B.K. and National
Institutes of Health Grants GM35126 and GM54004 to J.R.B. We gratefully
acknowledge Dr. Alan Hall (Cambridge, UK) for his generous contribution
of G-protein expression plasmids. We also thank Don Traul and Dr. Peter
Meberg for critical advice and help in the production of recombinant
adenovirus, and Laurie Minamide for technical advice and assistance.
Correspondence should be addressed to Dr. James R. Bamburg, Department
of Biochemistry and Molecular Biology, Colorado State University, Fort
Collins, CO 80523.
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A. E. Fournier, F. Nakamura, S. Kawamoto, Y. Goshima, R. G. Kalb, and S. M. Strittmatter
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Top
Abstract
Introduction
