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The Journal of Neuroscience, October 1, 1998, 18(19):7847-7855
Genetic Analysis on the Role of Integrin during Axon Guidance
in Drosophila
Bao
Hoang and
Akira
Chiba
Department of Cell and Structural Biology, University of Illinois,
Urbana, Illinois 61801
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ABSTRACT |
Heterodimeric cell surface receptor integrin is widely expressed in
the nervous system, but its specific role during axon development has
not been directly tested in vivo. We show that the
Drosophila nervous system expresses low levels of
positron-specific (PS) integrin subunits  PS1, PS2, and
 PS during embryonic axogenesis. Furthermore, certain subsets of
neurons express higher levels of integrin mRNAs than do the rest. Null
mutations in either the PS1 or PS2 subunit gene cause widespread
axon pathfinding errors that can be rescued by supplying the wild-type
integrin subunit to the mutant nervous system. In contrast,
misexpressing either the PS1 or PS2 integrin subunit in all
neurons leads to no obvious axon pathfinding errors. We propose that
integrin does not itself serve as either a "clutch" constituting
molecule or a specific growth cone "receptor," as proposed
previously, but rather as part of a molecular network that
cooperatively guarantees accurate axon guidance.
Key words:
PS1; PS2; axon guidance; PS; Drosophila; growth cone; inflated; integrin; multiple edematous wings; myospheroid; neuromuscular; pathfinding
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INTRODUCTION |
Axon guidance relies on the
activation of cell surface receptors that translate extrinsic cues into
directed cytoskeletal rearrangement within a growth cone (Chiba and
Keshishian, 1996 ; Goodman, 1996; Jay, 1996). Recent studies establish
that many members of integrin, a cell adhesion/signaling molecule, are
widely distributed in developing nervous systems (Schmidt et al., 1995; Varnum-Finney et al., 1995; Jones, 1996; Lallier et al., 1996; Martin
et al., 1996; Shaw et al., 1996; Wu et al., 1996; Grotewiel et al.,
1998). In vitro studies show that integrin is enriched at
the tip of a growing axon, suggesting a role in axon guidance (Wu et
al., 1996; Grabham and Goldberg, 1997; Takagi et al., 1998). One model
proposes that integrin is an important component of the "clutch," a
molecular complex that is responsible for growth cone advancement by
anchoring cytoplasmic actin filaments to the extracellular substrate
(C. H. Lin et al., 1994; Schmidt et al., 1995). Another model
predicts that integrin serves as a cell-specific recognition
"receptor" that biases growth cone movement toward the ligand
source (Kuhn et al., 1995, 1998). These ideas have not been tested
in vivo.
We chose Drosophila as a model system for studying integrins
because its nervous system consists of well-defined axon pathways (Chiba, 1998) and because it has a small set of integrin subunits similar in structure and function to those in vertebrates
(MacKrell et al., 1988; Leptin et al., 1989; Wilcox, 1990; Brown,
1993, 1994; Yee and Hynes, 1993; Gotwals et al., 1994a,b; Brower et al., 1995; Bunch et al., 1998). A positron-specific (PS) PS1 subunit (structurally similar to vertebrate laminin-responsive 3,
6, and 7 subunits) dimerizes with an PS subunit (similar to
the vertebrate 1 subunit) to form the laminin-binding PS1 integrin.
An PS2 subunit (similar to vertebrate RGD-dependent 5, 8,
v, and IIb subunits) also dimerizes with the PS subunit to
form PS2 integrin that binds to molecules with the amino acid triplet
RGD (e.g., tiggrin). These PS integrins serve as major cell adhesion
molecules during embryogenesis, with PS1 integrin concentrated in
ectodermal and endodermal tissues and PS2 integrin being most abundant
in mesodermal tissues (Zusman et al., 1990; Bunch et al., 1992; Roote
and Zusman, 1996). A role for PS integrins in embryonic neuronal
differentiation has been speculated because PS loss-of-function
mutants fail to condense the CNS normally during early larvagenesis and
primary neuronal culture from these mutants fail to develop normally on
a laminin substrate (Donady and Seecof, 1972; Brown, 1994). The PS3
subunit, a new member of the PS integrin family that dimerizes with a
PS subunit, has also been detected in the embryonic nervous system
(Stark et al., 1997). Both laminin and tiggrin, known ligands for PS1
and PS2 integrins, respectively, are present along the embryonic axon pathways (Montell and Goodman, 1989; Fogerty et al., 1994). Despite all
circumstantial evidence that they may be involved in neural development, expression patterns of PS integrins as well as their specific role during neuronal development have not yet been
examined.
In this study, we show that PS integrins (PS1, PS2, and PS
subunits) are expressed in the embryonic nervous system, starting during the period of axogenesis, and we provide genetic evidence that
neuronally expressed integrins are directly involved in axon development.
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MATERIALS AND METHODS |
Fly stocks. Null alleles for the PS1 integrin
subunit gene multiple edematous wings are
y1
mewM6 f36a
p[ry+t7.2:newFRT]18A/FM7cftz'-lacZ
(a null allele) and y1
mew498
p[ry+t7.2:newFRT]18A/FM7c
(a protein null allele); loss-of-function alleles for the PS2
integrin subunit gene inflated are
g2
ifK27E
f36a/FM7cftz'-lacZ (a
null allele) and g2
ifB2
f36a/FM7c (a hypomorphic allele with
an ~10% protein expression level) (Brabant and Brower, 1993;
Brower et al., 1995) (source, K. Stark, Massachusetts Institute of
Technology, and Bloomington Fly Stock Center, Bloomington, IN). All of
these mutations reach lethality by early larval stages. The genotypes
of individual embryos examined were confirmed immunologically using the
appropriate PS subunit antibodies, which reveal the presence or absence
of particular PS subunits, and/or -galactosidase antibodies, which
detect the FM7c balancer chromosome that carries the marker
transgene ftz'-lacZ (see Immunocytochemistry). For
"neuron" rescue experiments, wild-type PS2 gene was supplied to
the nervous system in PS2 null mutants (ifK27E) by the use of the GAL4
misexpression system (Brand et al., 1994) that combines a genomic
neurotopic enhancer "elav'-GAL4III"
(Sone et al., 1997) (source, E. Suzuki, University of Tokyo) to the
GAL4-responsive transgene
"UAS-PS2wt" (Roote and Zusman,
1996) (source, D. Brower, University of Arizona): ifK27E/Y;
UAS-PS2wt/elav'-GAL4III.
Misexpression of PS1 and PS2 was achieved by, respectively, GAL4C155/+ (or Y);
UAS-PS1wt/+ and
GAL4C155/+ (or Y);
UAS-PS2wt/+, in which
GAL4C155, a GAL4 "enhancer trap" line
(D. M. Lin et al., 1994) (source, C. Goodman, University of
California at Berkeley), targets misexpression to all neurons similar
to the "elav'-GAL4III" line.
Canton S strain was used as a wild-type control. In
addition, the PS null mutant line
(mysxb87/Y) (Leptin et
al., 1989) (source, K. Stark) was examined as a negative control for
the immunocytochemistry data.
In situ hybridization. cDNAs for PS1 (multiple
edematous wings gene), PS2 (inflated gene), and
PS (myospheroid gene) were subcloned into pBluescript to
prepare digoxygenin-labeled antisense and sense (negative control) RNA
probes (Bogaert et al., 1987; MacKrell et al., 1988; Wehrli et al.,
1993) (source, D. Brower). Wild-type 9-18 hr whole embryos were
processed for in situ hybridization and probed with RNA at
concentrations of ~1 ng/ml (PS and PS1) and ~5 ng/ml
(PS2) for 2-3 hr (Broadus and Doe, 1995). The entire set of
in situ hybridization experiments was repeated independently three times to confirm reproducibility of the staining patterns.
Immunocytochemistry. Primary antibodies were as follows: mAb
CF.6G11 (PS subunit; 1:1000 dilution), mAb DK.1A4 (PS1 subunit; 1:500 dilution), mAb CF.2C7 (PS2 subunit; 1:500 dilution) (Wilcox et
al., 1981; Brower et al., 1984) (source, D. Brower), mAb 1D4 (1:4
dilution) (Grenningloh et al., 1991) (source, C. Goodman), and
anti--galactosidase (1:5000 dilution) (source, Promega, Madison, WI). Embryos were immunoprocessed as whole embryos or after fillet dissection on glass slides with "minipools" (Chiba et al., 1993). The mutant embryos were analyzed by double-immunolabeling with mAb 1D4
that stains CNS axon fascicles and motoneuron axons and an antibody
against the respective integrin subunit and/or -galactosidase (see
Fly stocks). To preserve antigenicities for the PS subunits, we
incubated the embryos with the primary antibodies before fixation. Analysis was based on abdominal A2-A7 segments of
fillet-dissected preparations.
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RESULTS |
Embryonic neurons express PS integrins during axogenesis
We examined the expression pattern of PS1, PS2, and PS
subunits using in situ hybridization and immunocytochemistry
in the embryonic nervous system (see Materials and Methods). All three
PS subunit mRNAs are expressed widely in the nervous system (Fig.
1). Their expression levels during hours
9-18 of embryogenesis are notably low compared with that in the other
tissues that have been studied previously, such as muscles and apodemes
(Fig. 1A-C, asterisks). PS1
mRNA is detected widely in the CNS at a steady level during hours
13-18 (Fig. 1A). During this period, axogenesis occurs within the CNS as well as in the periphery. At the ventral midline, cells appear to accumulate slightly higher levels of PS1
compared with most other cells in the CNS (Fig. 1A,
open arrowheads). The PS2 mRNA expression pattern differs
somewhat from that of PS1. Specific clusters of cells, one near the
midline and a bilateral pair at mediolateral sites, express at
relatively high levels of PS2 in each segment of the CNS (Fig.
1B, arrowheads). The PS2 expression in
the CNS peaks during hours 9-15 of embryogenesis. The PS mRNA
expression pattern partially overlaps with those of PS1 and PS2
mRNA in the CNS, with one prominent cluster of cells expressing
relatively high levels at the ventral midline (Fig. 1C,
open arrowheads). PS mRNA expression in the CNS persists through hours 9-18. These in situ hybridization data
suggest that the embryonic CNS expresses both PS1 (PS1/PS
heterodimer) and PS2 (PS2/PS heterodimer) integrins during the
period of axogenesis.
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Figure 1.
PS integrin mRNA in the wild-type
Drosophila embryonic CNS at hour 15. Embryos were probed
with either antisense or sense (control) mRNA for the PS integrin
subunits (see Materials and Methods). Panels show five
abdominal segments of the CNS and surrounding mesoderm and/or
ectodermal tissues in fillet-dissected preparations. All photos were
taken at the focal planes slightly above the ventral surface of the
CNS, except for (B) and (E)
that are focused ~10 µm below the dorsal surface of the CNS. The
ventral midline and the lateral edges of the CNS are indicated by
thick and thin vertical lines,
respectively, at the bottom of each
panel. Anterior is to the top of each
panel. A, PS1 mRNA is expressed widely
within the CNS, with slightly higher expression in a cluster of cells
at the ventral midline (open arrowheads). Expression in
the peripheral tissues (asterisks) is higher than that
in the CNS. B, PS2 mRNA is also widely expressed in
the CNS. A midline cluster (open arrowheads) and
bilaterally paired mediolateral clusters (closed
arrowheads) of unidentified cells have noticeably high levels
of expression. Muscles express PS2 at very high levels
(asterisks). C, PS mRNA expression is
also widespread. Relatively high levels of expression are seen in the
CNS cells near the ventral midline (open arrowheads).
Outside the CNS, both apodemes and muscles show high expression levels
(asterisks). D-F, Sense mRNA for each of
the three PS subunits served as negative controls for the in
situ hybridization procedures. Scale bar: vertical
line in F, 20 µm.
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Consistent with the mRNA data, immunocytochemistry shows that the PS
protein subunit is unambiguously revealed on neuronal cell surfaces
during hours 16-18 (Fig.
2A). The major axon
fascicles within the CNS, including the longitudinal connectives and
the anterior and posterior nerve tracts (Fig. 2A), as
well as the cell surfaces of at least some identified neurons, are
labeled with the PS antibodies (Fig. 2A,
arrowheads). Unfortunately, both PS1 and PS2 subunits
are below the threshold of detection with available antibodies.
However, the detection of the PS protein subunit on the neuronal
cell surfaces suggests that the PS subunits are likely forming
functional heterodimers with the PS subunit in those cells. These
observations with in situ hybridization and
immunocytochemistry have led us to conclude that, similar to vertebrate
neurons, many Drosophila neurons express relatively low
levels of integrin on the neuronal surface during axogenesis.
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Figure 2.
PS integrin protein subunit in the embryonic
CNS at hour 18. Fillet-dissected embryos were processed for PS
immunocytochemistry (see Materials and Methods). Panels
show four abdominal CNS segments. A, In a wild-type
embryo (FM7c/Y), the PS protein subunit is
detected in the major axon tracts that include the pair of longitudinal
connectives (LC) as well as the anterior nerve tract
(ANt) and the posterior nerve tract
(PNt). The latter two axon tracts contain motoneuron
axons. In addition, surfaces of many neuronal cell bodies, including
those of the pair of RP3 motoneurons at this focus
(arrowheads), accumulate low levels of the PS protein
subunit. B, PS null embryo
(mysxb87/Y),
which has been dissected and immunoprocessed in the same minipool as
the wild-type control, shows only the nonspecific background staining
and serves as a negative control. Scale bar, 20 µm.
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Loss of integrin disrupts axon guidance
To analyze the role of the PS integrins in developing axons, we
examined mutant embryos lacking the functional gene for either the
PS1 or PS2 subunit. In these mutants, unlike in the PS null
mutants that exhibit grossly abnormal muscle development (Leptin et
al., 1989), muscles develop apparently normally up to hour 18 through
the major period of embryonic axogenesis. There is little sign that
neuronal cell bodies have migrated to incorrect positions, in addition
to the fact that the entire nervous system develops relatively
normally. On closer examinations, however, both PS1 and PS2
loss-of-function mutant alleles exhibit similarly widespread and
variable axon guidance defects (Fig.
3B,C).
In the CNS, the longitudinal connective normally contains three
prominent axon fascicles that are easily visualized by mAb 1D4 (Fig.
3A). Axons in the mutants appear somewhat wiggly (Fig.
3C, circle) or partially disconnected (Fig.
3B, arrows). The results are summarized in Figure
4.
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Figure 3.
CNS axon defects in loss-of-function mutants at
hour 18. Whole embryos were processed for mAb 1D4 immunocytochemistry
(see Materials and Methods). Panels show five abdominal
CNS segments in fillet-dissected embryos. A, In wild
type (Canton S), each of the bilaterally paired
longitudinal connectives (LC) contains three discrete
axon fascicles that show little crossover among themselves.
B, C, Axon fascicles are disorganized in
the CNS. The two most common defects are "gaps" in the longitudinal
fascicles (B, arrows) and "wiggles"
within the axon fascicles (C, circle).
With the level of analysis, it is difficult to resolve whether the gaps
represent axons stalling or axons changing the fascicles. See Figure 4
for summary. Scale bar, 20 µm.
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Figure 4.
Summary of axon defects in loss-of-function
mutants. Data are based on the hour 18 embryos after immunoprocessing
with mAb 1D4 and fillet dissection. CNS axon fascicles were analyzed
only in the longitudinal connectives (LC). Various
classes of defects, such as the gaps and wiggles shown in Figure 3,
B and C, are included as axon
"errors." In the periphery, all five groups of motoneuron axons
(ISN, SNa, SNb,
SNc, and SNd) were examined. In each
group, axon defects are collectively summarized as errors. Examples of
various peripheral nervous system (PNS) axon defects are shown below
(see Fig. 5G-L). Both the error rates and sample sizes
(the numbers of abdominal hemisegments scored; numbers
in parentheses below each bar) are
indicated in the charts. The data for the PS1 mutants are based on
10 mewM8 and eight
mew498 embryos, and the penetrance of
the axon errors either in the CNS or PNS in each allele is ~90%.
Similarly, the data for the PS2 mutants are based on nine
mewM8 and eight
mew498 embryos, and the penetrance of
the axon errors either in the CNS or PNS ranges between 78 and 100%.
There is no obvious correlation between the CNS and PNS segments in
which axon defects occur. Taken together, these observations support
the idea that the loss of integrin leads to widespread and stochastic
axon guidance errors throughout the nervous system. A,
B, Wild type (Canton S) shows very low
axon error rates (0-5%) in the CNS (A) as well
as in the periphery (PNS) (B). The data are based
on eight embryos. C, D, PS1 null
mutants (mewM6/Y and
mew498/Y) both
show low-to-medium rates (0-24%) of axon errors in the CNS
(C) and PNS (D).
E, F, The PS2 null mutant allele
(ifK27E/Y)
exhibits medium-to-high rates (8-69%) of axon errors in the CNS
(E) and PNS (F). The
hypomorphic allele
(ifB2/Y) shows
similar defects at slightly reduced rates (1-37%).
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In the PNS, one can visualize specific groups of motoneuron axons with
higher cellular resolution than is possible in the CNS. Null mutations
in PS1 and PS2 subunit genes both result in similarly widespread
axon pathfinding defects for all five known motoneuron groups, despite
apparently normal muscle development (Fig.
5G-L). The axon defects
observed can be interpreted as a consequence of failing to turn at
choice points and/or invading into neighboring muscle fields (Fig. 5,
arrows, circles). These defects are most
frequently detected in the SNb group (Fig.
4D,F). It is important to
note that the axons in these loss-of-function mutants can extend as far
as in wild type and sometimes up to 30 µm beyond their normal
stopping points (Fig. 5J, circle). This suggests
that integrin is unlikely to serve simply as a
clutch-constituting molecule, on which growth cones depend for
the adequate traction needed to extend forward. Another point is that
each axon group selects a range of alternative pathways without obvious
preferences. It is therefore likely that the loss of integrin leads to
losses in the responsiveness of an axon to a large array, rather than a
small specific set, of guidance cues. Finally, in general, loss of PS2
integrin (PS2 null mutation) leads to higher axon guidance errors
than does loss of PS1 integrin (PS1 null mutation). Future analysis
is needed to determine specific contributions of these two forms of
integrin. On the basis of the current data, we suggest that both the
laminin-binding PS1 and RGD-dependent PS2 integrins are necessary for
accurate axon guidance.
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Figure 5.
PNS axon defects in loss-of-function mutants at
hour 18. Embryos were processed for mAb 1D4 immunocytochemistry and
fillet-dissected. B-L show parts of the motoneuron axon
pathways in a right PNS hemisegment. Boxes in the
schematics above and below B-J
approximately correspond to the areas shown in the
panels. A, Each hemisegment
contains 30 uniquely identified muscles and is innervated by five
groups (fascicles) of motoneuron axons: SNd,
SNc, SNb, SNa, and
ISN. The muscles that are targeted by each motoneuron
group are labeled with identification numbers (13 of
30). B-F, In wild type (Canton S),
SNd targets the ventral- (proximal) most muscles
including 15 and 16 (B). SNc
targets the next ventral-most muscles including 26 (C). SNb branches into several
subfascicles and innervates ventrolateral muscles including 6, 7, 12, and 13 (D). The SNa motoneuron
group extends toward the lateral muscles and bifurcates into two
subfascicles; one subfascicle reaches transverse muscles 21, 22, and others, whereas another turns posteriorly to innervate 5 and 8 (E). ISN extends farthest and
targets the dorsal- (distal) most muscles such as 1, 2, and 3 (F). G-L, In the null mutant
embryos, the PNS axon fascicles exhibit various defects. The types of
axon pathfinding defects seen for the PS1 and PS2 null mutants
are very similar. SNd and SNc are
sometimes missing (G, H,
arrows). Axons that would normally reach this muscle
region may be either stalling or bypassing. SNb
frequently extends beyond the normal stopping point and invades into
the neighboring segment (J, circle) or
fails to form sub-branches at muscles 6 and 7 (I,
arrow). SNa occasionally misses its
posteriorly directed sub-branch and fails to innervate muscles 5 and 8 (K, arrow). ISN sometimes
fails to obey segmental boundaries and merges with the ISN from
adjacent segments (L, circle). See Figure
4 for data summary. Scale bar, 20 µm.
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Axon guidance defects are rescued by supplying the
wild-type integrin
To test the direct role of integrin in axon development further,
we attempted to rescue the axon defects by using a genomic neurotopic
enhancer to drive expression of wild-type integrin gene in the nervous
system of the null mutant (see Materials and Methods). We chose to
focus on the PS2 null mutants because they showed more severe PNS
defects than did the PS1 null mutants (Fig.
6). The overall expression levels of the
PS2 protein subunit in this neuron rescue experiment were low and
hardly detectable via immunocytochemistry, approximately mimicking
endogenous expression in the CNS (data not shown). Consistent with a
direct role for integrin, guidance defects are primarily rescued in
both the CNS longitudinal connectives and the peripheral motor pathways
(Figs. 6, 7). This result suggests that
axons rely on their own integrin while responding accurately to local
guidance cues.
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Figure 6.
A, B, The axon
defects in PS2 null mutants
(ifK27E/Y) can
be partially rescued by supplying wild-type PS2 gene to the nervous
system in the mutant background (striped bars;
ifK27E/Y;
UAS-PS2wt/elav'-GAL4III;
see Materials and Methods). In this neuron rescue experiment, the rates
of axon defects in both the CNS (A) and PNS
(B) revert toward those of wild type, yielding
error rates significantly lower than those in PS2 null mutants
(asterisks; p < 0.001 by
Chi2 t test). (See Fig. 7 for
examples.) The parental lines used for the neuron rescue experiment
were either wild-type-like
(UAS-PS2wt and
elav'-GAL4III) or indistinguishable
from the PS2 null mutants
(ifK27E/Y;
UAS-PS2wt) in their axon fascicle
organizations.
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Figure 7.
Neuron rescue experiment. Axon fascicle
organizations in the PS2 null mutant embryos (hour 18) after neuron
rescue (see Materials and Methods) were visualized using mAb 1D4.
A, Four abdominal CNS segments in a fillet-dissected
embryo are shown. The longitudinal connectives (LC)
revert to virtually wild type and exhibit three discrete fascicles
(compare with Fig. 3A). B-F, In the PNS,
axon fascicle organizations are very similar to that in wild type
(compare with Fig. 5B-F). Both
SNd (B) and SNc
(C) innervations are present at high frequencies.
SNb axons show much-reduced error rates
(D) compared with those in the PS2 null
mutants (compare with Fig. 5I, J).
SNa increases its rate of forming the posteriorly
directed sub-branch that reaches muscles 5 and 8 (E). ISN obeys the segment
boundaries and looks very similar to wild type
(F). See Figure 6, A and
B, for data summary. Scale bar, 20 µm.
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Integrin misexpression results in little growth cone
guidance errors
How does neuronal integrin facilitate accurate axon guidance? A
simple model is that integrin itself serves as a receptor for specific
guidance cues, in much the same way as do a number of cell surface
receptors (see Discussion). To test this idea, we expressed integrin
ubiquitously in the wild-type CNS so that it would be present in
neurons that normally express little or no integrin. We predicted that,
if integrin serves as a receptor for specific growth cone guidance
cues, many neurons with normally low or no integrin expression would
alter their axon pathways. Contrary to our prediction, we found that
axons exhibit little pathfinding error in either the CNS or periphery
when either the PS1 or PS2 gene is misexpressed ubiquitously in
the nervous system (Fig. 8). These
results, as well as the results from the loss-of-function analysis
described above, suggest that integrin is not likely to serve as a
specific guidance receptor in vivo.
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Figure 8.
Summary of axon defects in gain-of-function
experiments. Data are based on the 18 hr embryos (see Materials and
Methods) that were immunoprocessed (mAb 1D4) and fillet-dissected,
similar to those in Figures 4 and 6. A,
B, Low-level neurotopic misexpression of either the
PS1 or PS2 gene results in no apparent axon defects in the CNS
(A) or PNS (B).
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DISCUSSION |
In this study, we have shown that integrin (PS1, PS2, and
PS subunits) is present in the developing Drosophila
nervous system and have provided evidence that neuronal integrin is
required for accurate axon guidance in vivo.
Neuronal integrin guides axons
Integrin, one of the best-studied classes of cell
adhesion/signaling molecules in animals, has been shown to link
intercellular signaling systems to a number of intracellular signaling
pathways (Parsons, 1996; Schlaepfer and Hunter, 1998). It is expressed dynamically in a variety of cells during development wherein extensive intercellular communication is required. Evidence of potential roles of
integrin during axon development is available from in vitro
experiments (Schmidt et al., 1995; Varnum-Finney et al., 1995;
Felsenfeld et al., 1996; Shaw et al., 1996; Wu et al., 1996; Grabham
and Goldberg, 1997). However, recent mouse knock-out experiments fail
to demonstrate the specific in vivo role of integrin during axon development, primarily because of the large number of integrin isoforms and their widespread expression patterns (Hynes, 1996). Therefore, to date, an in vivo demonstration of the roles of
integrin in axon guidance has not been available.
Our genetic analysis on the Drosophila embryonic nervous
system provides two lines of evidence that neuronal integrin is
essential for accurate axon guidance. First, in the loss-of-function
mutants for the PS1 or PS2 subunit gene, axons in the CNS and the
periphery both exhibit widespread guidance errors (see Fig. 4 for
summary). In the PNS, with its relatively simple cellular landscape,
the miswired axons are seen frequently to extend beyond normal target regions (Fig. 5J,L). Therefore,
although lack of integrin does not reduce general motility of growth
cones, the accuracy of their guidance is diminished. Second, genetic
rescue reverts the axonal defects toward the wild type (Figs. 6, 7).
The fact that this is achieved by resupplying low levels of the
wild-type integrin gene specifically to the nervous system of
otherwise null mutant embryos strongly suggests that integrin is
directly involved in the axon guidance.
Neuronal integrin and its low expression levels
Previous studies on Drosophila PS integrins
have focused mostly on their involvement during the development of
non-neuronal tissues, including wing epithelia, muscle attachment
sites, dorsal vessels, and gut (Leptin et al., 1989; Wilcox et al.,
1989; Wilcox, 1990; Zusman et al., 1990; Brown, 1993; Gotwals et al.,
1994b; Brower et al., 1995; Fernandes et al., 1996; Stark et al., 1997; Bunch et al., 1998). The primary function of integrin is thought to be
that of cell adhesion in these nonmigratory cells. Much less is known
about the roles of integrin in the nervous system, where it is
expressed at relatively low levels. In vitro work with chick
dorsal root ganglion neurons shows that protein kinase C-dependent
cytoplasmic signaling is involved in the behavioral modification of
growth cones that occurs after their contacting laminin, the major
ligand for integrin (Kuhn et al., 1995). This suggests that in axons,
with its relatively low expression levels, integrin may primarily serve
as a mediator of cell signaling via its specific association with a
variety of cytoplasmic proteins. In vivo analysis on the
physiological functions of the cytoplasmic domains of the PS integrin
subunits in Drosophila have just begun in a variety of
tissues (Martin-Bermudo et al., 1997; Li et al., 1998). It would be
interesting to extend such analysis and test the roles of the
cytoplasmic domains of integrin in the context of axon guidance.
New models for the role of integrin in axon guidance
Although our genetic analysis demonstrates that neuronally
expressed integrin is essential for accurate axon guidance, the results
are inconsistent with some of the previously proposed models concerning
the role of integrin in axon development. One model, known as the
clutch model, stems from the in vitro observations that,
when a growth cone advances, actin filaments inside filopodia are held
down to the substrate (Lin and Forscher, 1995). When applied to
integrin, this clutch model proposes that integrin, an integral
membrane molecule, serves as a mechanical link between specific
extracellular substrates and the cytoskeleton and thus provides the
traction necessary for growth cone advancement. Support for this
"integrin-as-clutch" model comes from an in vitro study in which integrin activation is suggested to lock integrin to actin
filaments in filopodia (Felsenfeld et al., 1996). The model predicts
that, when integrin is missing, growth cones will lose much of their
traction and will reduce their forward motility. However, our in
vivo analysis has revealed little reduction in growth cone
motility as a result of genetic deletion of the integrin subunits.
Instead, there is an increase in growth cone targeting errors. Thus, a
simple clutch model does not seem to adequately explain the role of
integrin in axon development.
In the alternative receptor model, neuronal integrin itself is proposed
to serve a pivotal role in turning a growth cone by reacting to
specifically localized extrinsic cues (Kuhn et al., 1995). This model
predicts that, when integrin is lacking, growth cones that normally
express integrin will select alternative pathways at the choice points
where the ligands of integrin are normally present. Along the same line
of logic, if integrin is misexpressed in growth cones that normally do
not express it, this will alter the pathfinding of these growth cones
in specific ways as well. Our observations suggest that this receptor
model is not predictive of the role of integrin in axon guidance. It is
noteworthy that, in vitro, integrin is clearly capable of
exerting enough biases on a growth cone to turn it toward the source of
specific ligands such as laminin (Kuhn et al., 1998). However, whether
the natural ligands of integrin are distributed in specific patterns
in vivo is still not clear. Available evidence hints that
laminin and tiggrin, the known ligands for the PS integrins in
Drosophila, are both rather ubiquitously expressed along the
entire substrate that the majority of neuronal axons grow over
(Montell and Goodman, 1989; Fogerty et al., 1994). Therefore, we favor
the view that, in vivo, integrin is unlikely to serve as a
specific axon guidance receptor.
What then is the role of integrin in the axon guidance, because its
absence does lead to widespread loss of guidance accuracy? In one
simple model, integrin functions as an adhesion molecule that controls
the speed of growth cone advancement. In this "speed control"
model, low levels of integrin are necessary to prevent the axons from
extending too fast and missing the chance to interact with guidance
cues. In a more elaborate model, integrin serves as an interface that
links a specific cue recognition at the surface of the growth cone to
internal cytoplasmic and cytoskeletal signaling events. In this
"interface" model, integrin cooperates with a number of other
growth cone receptors, such as EphR family receptor tyrosine kinases,
DCC-type netrin receptors, receptor-type phosphotyrosine phosphatases, Fasciclin III, Connectin, and other unknown receptors (Speicher et al., 1998; Treubert and Brummendorf, 1998). Activation of
any of these specific growth cone receptors is coupled to
integrin-mediated intracellular signaling systems. The model predicts
that integrin and associated molecules are rapidly recruited to, and/or
activated at, particular filopodia that have contacted a specific
target or guidepost cell. It also anticipates that mutations that
delete only one of the many different growth cone receptors that
are interfaced by integrin do not always produce pronounced axon
guidance errors. On the other hand, deleting integrin would cause
widespread axon defects, as observed in this study. Integrin, with its
extensive opportunity to work with a large array of molecules (Clark
and Brugge, 1995; Schlaepfer and Hunter, 1998), seems to be in an ideal
position to signal-amplify a local event of minimal amplitude and to
generate a bias large enough to steer a growth cone with accuracy.
| |
FOOTNOTES |
Received April 21, 1998; revised July 13, 1998; accepted July 17, 1998.
This work was supported by National Institutes of Health Grant NS35049,
National Science Foundation Grant IBN-95-14531, and the Lucille P. Markey Charitable Trust (A.C.). We thank Dan Brower and Mike Graner
(University of Arizona), Karen Stark (Massachusetts Institute of
Technology), Corey Goodman (University of California at Berkeley), and
Emiko Suzuki (University of Tokyo) for generous gifts of reagents. We
also thank Hiroyuki Kose (National Institute of Genetics, Japan) and
Yasumitsu Takagi (Tsukuba Research Consortium, Japan) for discussion
and Anna Huttenlocher, Steven Kaufman, Xiaomao Zhu, and the current
members of the Chiba Lab (University of Illinois) for comments on this
manuscript.
Correspondence should be addressed to Dr. Akira Chiba, B605 Chemical
and Life Science Laboratory, 601 South Goodwin Avenue, Urbana,
IL 61801.
| |
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Top
Abstract
Introduction
