myospheroid
The Myospheroid cytoplasmic tail is sufficient to direct the localization of MYS to muscle termini. This localization does not occur via an association with structures set up by endogenous integrins, since it can occur even in the absence of the MYS protein. The subcellular localization of alphaPS2betaPS integrin is not dependent on any other interaction between the muscles and the tendon cells. In embryos that lack the segmental tendon cells, due to a mutation removing engrailed and invected, alphaPS2betaPS is still localized to the muscle termini even though the ventral longitudinal muscles are not attached to the epidermis, but instead are attached end to end. Thus the alphaPS2betaPS integrin can be localized by an intracellular mechanism within the muscles. These results challenge the view that the extracellular environment via integrins is required for the organization of the cytoskeleton and the resultant polarity (Martin-Bermudo, 1996).
The integrins are a family of transmembrane heterodimeric proteins that mediate adhesive
interactions and participate in signaling across the plasma membrane. The conserved and charged membrane proximal portion of vertebrate beta1 subunit cytoplasmic tail is important in the association of integrins to the cytoskeleton. This region has been implicated in the binding of signaling molecules and cytoskeletal proteins (e.g. focal adhesion kinase, paxillin and alpha-actinin). In this study the functional significance of the cytoplasmic domains of the (alpha)PS1, (alpha)PS2
and ßPS subunits of the Drosophila Position Specific (PS) integrin family were examined by analyzing the
relationship between cytoplasmic domain structure and function in the context of a
developing organism. By examining the ability of ßPS molecules lacking the cytoplasmic domain to rescue
embryonic abnormalities associated with PS integrin loss, it was found that although many
embryonic events require the ßPS cytoplasmic domain, this portion of the molecule is not
required for at least two processes requiring PS integrins: formation of midgut constrictions
and maintaining germband integrity. The cytoplasmic domain is required for migration of midgut primordia along visceral mesoderm, elongation of the midgut into a convoluted tube, and somatic muscle attachment. Mutant proteins affecting four highly conserved amino acid residues in the cytoplasmic tail function
with different efficiencies during embryonic development, suggesting that interaction of PS
integrins with cytoplasmic ligands is developmentally modulated during embryogenesis (Li, 1998).
The ability of (alpha)PS1 and (alpha)PS2 to function without their
cytoplasmic domains was also analyzed. By analyzing the ability of transgenes producing truncated (alpha)PS
molecules to rescue abnormalities associated with integrin loss, it was found that the cytoplasmic
tail of (alpha)PS2 is essential for both embryonic and postembryonic processes, while this
portion of (alpha)PS1 is not required for function in the wing and in the retina. (alpha)PS2 is not required to maintain attachment of the germband germlayers.
Temperature-shift experiments suggest roles for the (alpha)PS2 cytoplasmic domain in
signaling events occurring in the developing wing. Under low expression conditions blisters are found on approximately 12% of (alpha)PS2 cytoplasmic domain null mutant wings, while in high expression conditions, significantly fewer wing blisters are observed. The extracellular and transmembrane domains of (alpha)PS1 are sufficient for function in retinal maintenance (Li, 1998).
Broad-Complex transcription factors regulate muscle attachment in Drosophila. In Brc mutants of the rbp complementation group, dorsoventral indirect flight muscles (DVM) are largely absent and the dorsal longitudinal indirect flight muscles, tergotrochanteral muscles (TTM), and remaining DVM often select incorrect attachment sites. One striking aspect of the rbp phenotype is that dorsal attachments are defective while ventral attachments seem normal. This phenomenon has also been observed in the TTM of bendless and myospheroid mutant adults. It is also noted that all the susceptible attachment sites are derived from the wing imaginal disc, while the unaffected sites are derived from leg discs. Analysis of the Derailed receptor tyrosine kinase suggests that muscles use different molecules for making attachments at dorsal and ventral ends of their fibers. Derailed is localized to the ventral ends of a subset of embryonic muscles; derailed mutations cause ectopic ventral attachment of these muscles. The stripe dorso-longitudinal indirect flight muscle phenotype resembles the rbp DVM phenotype, in that normal initial development is followed by degeneration and disappearance. Although stripe does not appear to be under rbp control at head eversion, the two genes may regulate overlapping subsets of downstream targets (Sandstrom, 1997).
In the embryo, PS1 (alphaPS1 betaPS)
is found on the surface of the epidermis and endoderm, while PS2 (alphaPS2 betaPS) is restricted to the mesoderm.
The integrins are concentrated at the sites where the somatic muscles attach to the epidermis and at
the interface between the visceral mesoderm and the endoderm. In myospheroid mutant embryos,
which lack the betaPS subunit, the adhesion between the mesoderm and the other cell layers fails (Brown, 1993).
inflated is
the gene encoding the alphaPS2 subunit of the PS1 integrin of Drosophila. A comparison of the null
inflated phenotype with that of the locus that encodes the betaPS subunit myospheroid
reveals that while the betaPS subunit is required for the adhesion of the epidermis along the dorsal
midline, the alphaPS2 subunit is not. In if mutant embryos, the muscles remain attached to the
other cell layers significantly longer than in a mys mutant embryo. This shows that the alphaPS2
betaPS integrin only contributes part of the adhesive activity at the sites of PS integrin adhesion,
and rules out a model where PS integrin function occurs solely by the direct interaction of the two
PS integrins (Brown, 1994).
multiple edematous wings (mew) is
the gene encoding the alphaPS1 subunit of the PS1 integrin of Drosophila.
In contrast to if (alphaPS2) and mys (betaPS) mutants, most mutant mew embryos hatch, only to die
as larvae. Mutant mew embryos display abnormal gut morphogenesis but, unlike mys or if
embryos, there is no evidence of defects in the somatic muscles. Thus, the complementary
distributions of PS1 (alphaPS1 betaPS) and PS2 (alphaPS2 betaPS) integrin on tendon cells
and muscle, respectively, do not reflect equivalent requirements at the myotendinous junction.
Dorsal herniation, characteristic of the mys lethal phenotype, is not observed in mew or in mew/if double mutants. Clonal analysis experiments indicate that eye morphogenesis is disrupted in mew clones,
but if clones show relatively normal eye morphology. Adult wings display blisters around
large dorsal (but not ventral) mew clones. In contrast to dorsal mys clones, small mew patches do
not necessarily display morphogenetic abnormalities. Thus, another integrin in addition to PS1
appears to function on the dorsal wing surface (Brower, 1995).
The Drosophila position-specific (PS) antigens are homologous to the vertebrate
fibronectin receptor family, or integrins. A Drosophila gene required for embryonic
morphogenesis, l(1)myospheroid, codes for a product homologous to the beta subunit
of the vertebrate integrins. l(1)myospheroid mutants die during embryogenesis. These mutants lack the beta subunit of the PS antigens. In the absence of the
beta subunit in mutant embryos, the PS alpha subunits are not expressed on the cell
surface. It is concluded that the l(1)myospheroid phenotype represents the
lack-of-function phenotype for these Drosophila integrins. In wild-type embryos, PS
antigens are found at the interface between mesoderm and ectoderm, and later mainly
at muscle attachment sites in the epidermis and gut. Together these results
indicate that during embryogenesis, Drosophila integrins are used to attach mesoderm
to ectoderm, and are required for the proper assembly of the extracellular matrix and
for muscle attachment (Leptin, 1989).
Nine alleles have been characterized of myospheroid, which encodes
the beta PS subunit of the Drosophila PS integrins. The mysXB87,
mysXN101 and mysXR04 genes yield restriction digest patterns similar to those seen
for wild-type chromosomes, however the mys1 and mysXG43 genes contain
detectable deletions. mys1, mysXB87 and mysXG43 make little or no stable protein
product, and genetically behave as strong lethal alleles. For the mysXN101 mutation,
protein product is seen on immunoblots and a reduced amount of beta PS protein is
seen at the muscle attachment sites of embryos. This mutant protein retains some
wild-type function, as revealed by complementation tests with weak alleles. Protein is
also seen on immunoblots from mysXR04 embryos; this allele behaves as an
antimorph, being more deleterious in some crosses than the complete deficiency of
the locus. mysts2 and mysnj42 are typically lethal in various combinations with other
alleles at high temperatures only, but even at high physiological temperatures, neither
appears to eliminate gene function completely. The complementation behaviors of
mysts1 and mysts3 are quite unusual and suggest that these mutations involve
regulatory phenomena. For mysts3, the data are most easily explained by postulating
transvection effects at the locus. The results for mysts1 are less straightforward, but
point to the possibility of a chromosome pairing-dependent negative interaction (Bunch, 1992).
Southern blot analysis of heterozygous scab adults using the
complete alpha probe reveals DNA polymorphisms in 6 alleles.
Mutant embryos homozygous for l19 or 1035 alleles of scab,
sometimes undergo a secondary closure after the initial failure of dorsal closure. Unlike myospheroid (mys) mutant embryos, whose muscles detach from the body wall, scb embryos show vigorous
muscular movements of the cuticle; some of those undergoing secondary dorsal closure actually do hatch. In addition to dorsal closure, another phenotype observed in
embryos lacking betaPS, but not observed in embryos null for alphaPS1, alphaPS2 or both, is a twisting of the germ band. Time-lapsed videomicroscopy reveals that during germ-band extension in scb X5, scb X6, and scb 2 embryos, and in embryos deficient for scb, the germ band twists laterally
rather than extending dorsally, as in wild-type embryos, so that the ventral side of the posterior midgut is visible from the lateral side of the embryo. As in myospheroid mutant embryos,
proper orientation of the germ band is recovered by the completion of germ-band extension (Stark, 1997).
The strong expression of Scab in the dorsal vessel
led to an examination of scab embryos for defects in this tissue. Defects
in the dorsal vessel have not been reported for myospheroid mutant embryos,
although a detachment of alary muscles from the heart (posterior dorsal vessel) and its failure to mature at late stages has been identified in embryos lacking zygotic,
but not maternal betaPS. myospheroid mutant
embryos lacking both maternal and zygotic betaPS were examined to preclude
the possibility of maternal rescue. The heart and dorsal vessel form from two types of cells: the external pericardial cells and the internal cardioblasts. myospheroid minus, scb X5, scb X6, scb 2
and scb-deficient embryos were all stained with antibodies that recognize pericardial
cells. Embryos from scb and deficiency lines show
mislocalization of the pericardial cells, which normally organize in a line along the edge of the dorsal cuticle, and appear to have fewer of these cells in this area than wild type
at the same stage. A similar (although more severe) defect could be seen in mys- embryos: the pericardial cells appear to dissociate, migrate randomly and are
sparse. The increase in severity of the defect suggests the possibility that either alphaPS1 or alphaPS2 may function in this process as well. The defect in mys- is also strikingly similar to
that published for laminin A mutations (Yarnitzky, 1995).
The forces that connect the genetic program of development to morphogenesis in Drosophila have been investigated. Focus was placed on dorsal closure, a powerful model system for development and wound healing. The bulk of progress toward closure is driven by contractility in supracellular 'purse strings' and in the amnioserosa, whereas adhesion-mediated zipping coordinates the forces produced by the purse strings and is essential only for the end stages. Quantitative modeling was applied to show that these forces, generated in distinct cells, are coordinated in space and synchronized in time. Modeling of wild-type and mutant phenotypes is predictive; although closure in myospheroid mutants ultimately fails when the cell sheets rip themselves apart, the analysis indicates that ßPS integrin has an earlier, important role in zipping (Hutson, 2003).
Changes in the extracellular matrix (ECM) govern the
differentiation of many cell types during embryogenesis.
Integrins are cell matrix receptors that play a major role
in cell-ECM adhesion and in transmitting signals from the
ECM inside the cell to regulate gene expression. In this
paper, it is shown that the PS integrins are required at the
muscle attachment sites of the Drosophila embryo to
regulate tendon cell differentiation. The analysis of the
requirements of the individual alpha subunits, alphaPS1 and alphaPS2,
demonstrates that both PS1 and PS2 integrins are involved
in this process. In the absence of PS integrin function, the
expression of tendon cell-specific genes such as stripe and
beta1 tubulin is not maintained. In addition, embryos lacking
the PS integrins also exhibit reduced levels of activated
MAPK. This reduction is probably due to a downregulation
of the epidermal growth factor receptor (Egfr) pathway,
since an activated form of the Egfr can rescue the
phenotype of embryos mutant for the PS integrins.
Furthermore, the levels of the Egfr ligand Vein at the
muscle attachment sites are reduced in PS mutant embryos.
Altogether, these results lead to a model in which integrin-mediated
adhesion plays a role in regulating tendon cell
differentiation by modulating the activity of the Egfr
pathway at the level of its ligand Vein (Martin-Bermudo, 2000a).
Cell culture experiments have shown that integrins can
regulate activation of the Egfr pathway at the level of the
ligand, or at the level of the receptor. In the first case, integrins
can regulate ligand activity through modulation of the
composition and assembly of the ECM. There is increasing
evidence suggesting that the binding of growth factors to the
extracellular matrix is a major mechanism regulating growth
factor activity. The largest group
of ECM proteins that interact with growth factors include the
heparan sulfates, which are the major components of the
basement membrane -- indeed
integrins contribute to the stabilization of the epidermal
basement membrane. Integrins can also
exert control on the Egfr pathway at the level of the receptor.
In this scenario, the adhesion sites formed upon integrin
activation (focal adhesions) can serve as recruitment points that
bring together structural and signaling proteins, thus enhancing
their ability to interact with the right partner, and therefore to
be activated. Indeed clustering of integrins results in co-clustering of epidermal
growth factor receptor molecules leading to receptor activation,
and enhanced EGF-dependent activation of MAPK. In another example, integrins can also enhance
the efficiency of signal transduction between the Egfr and
MAPK by promoting the recruitment and activation of Raf (Martin-Bermudo, 2000a).
The data presented here supports a model by which the PS
integrins regulate Egfr signaling pathway at the level of its
ligand Vein. This regulation involves the ability of the PS
integrins to organize the tendon matrix and the basement
membrane at the basal surface of muscles and tendon cells. In
fact, integrin function in regulating assembly of the ECM,
rather than integrin signaling, has been shown to be crucial in
keratinocyte differentiation. In the absence of integrin function the levels
of Vein at the muscle attachment sites are decreased compared
to wild type. Therefore, it is proposed that integrins are required
for the proper assembly of the basement membrane and the
tendon matrix, which in turn regulates Vein activity. A role for
PS2 in matrix assembly is in agreement with results showing
a requirement for alpha3beta1 integrin in mediating assembly of
basement membrane between the epidermis and the dermis in
mice. Furthermore, results in Drosophila showing
that defects in tendon cell-specific gene expression are stronger
when both integrins are eliminated are consistent with data
showing that the failure in assembly of the matrix is more
severe in embryos lacking both PS1 and PS2 integrins than in
single mutants. The basement membrane
and the tendon matrix could then regulate Vein activity in
different ways. (1) They could promote a higher affinity of Vein
for the Egfr. In fact, heparan sulfate has been reported to
promote high-affinity binding of the fibroblast growth factor 2
(FGF2) and hepatocyte growth factor (HGF) to their receptors. (2) They could also
direct the movement of Vein by limiting its diffusion. This
could be a mechanism for muscles to specifically transmit
signals to those epidermal cells that are in contact with the
same matrix, the tendon cells. (3) They could promote the
accumulation or clustering of Vein to specific levels required
for the activation of its receptor. And finally, (4) binding of
integrins to the ECM might either protect Vein from proteolysis
or lead to the production of proteolytic enzymes that release
Vein from the tendon matrix and activate it. Several of these
mechanisms could be operating at the same time. Thus,
organization and assembly of the tendon matrix via the PS
integrins would ensure the localized production and
concentration of an active ligand for the Egfr at the muscle
attachment sites (Martin-Bermudo, 2000a).
In addition, or alternatively, the PS integrins could be
required in the tendon cells to regulate Egfr function at the level
of the receptor. At the muscle attachment sites of the Drosophila
embryo, there are special cell junctions, called hemiadheren
junctions (HAJs), which form between the ends of the muscles
and the basal surface of the tendon cells in opposing pairs. HAJs are
organized sites of membrane-cytoskeletal linkage which have
been proposed to recruit integrins. It is
worth mentioning here that although PS2 has been shown to be
expressed only in the muscles, loss of PS2 integrin function
affects adhesion of both muscle and epidermal HAJs. This can explain why lack of PS2 alone leads to a reduction in the expression of tendon cell-specific genes. At
this level for integrin modulation of the Egfr signaling, a first
step requires that epidermal HAJs act as recruitment centers for
the Egfr or other signaling molecules, in the same way as focal
adhesions. In this case, the detachment of the epidermal HAJs
from the matrix found in embryos lacking the integrins results
in the disorganization of these adhesion centers leading to a
failure to cluster the Egfr and/or signaling molecules, and
therefore, to activate the Egfr pathway. In this scenario it is also
possible that integrins and the Egfr activate parallel pathways
needed to reach the threshold level of MAPK activation,
required for optimal transcription of tendon cell-specific genes (Martin-Bermudo, 2000a).
This is consistent with the results presented here where
over activation of the Egfr pathway can compensate for lack of
integrin function. Thus, integrin-mediated cell adhesion might
produce a long-lasting activation of MAPK, which cooperates
with the fast and short stimulation of MAPK normally induced
by activation of growth factor pathways. Experiments were performed to try to determine the
relative roles of integrin adhesion versus signaling in
modulating the Egfr pathway in the process of tendon cell
differentiation. One of the best characterized integrin signaling
events involves tyrosine phosphorylation of the focal adhesion
kinase, FAK. This pathway can be mimicked by clustering the
cytoplasmic domain of the betaPS subunit. It has been shown previously that
clustering of the cytoplasmic tail of the bPS subunit is
sufficient to initiate a signaling pathway that regulates gene
expression in the Drosophila midgut. However, this signaling pathway is found to be
insufficient to regulate tendon cell differentiation in the
embryo. These results suggest that integrin-mediated adhesion,
rather than signaling, is required to regulate tendon cell
differentiation. Some experiments have shown that clustering
of the cytoplasmic domain of the beta subunits does not fully
mimic integrin signaling, the alpha subunits are also important and,
in some cases sufficient. A
pathway from integrins to MAPK has been identifed that is mediated by
interactions between the transmembrane and/or extracellular
domains of the alpha subunit and the adaptor protein Shc. The
pathway from integrins to MAPK is alpha subunit specific, being
alpha5 and alphav, which belong to the same family as the alphaPS2, the
alpha subunits that signal through Shc. Therefore, it still remains
possible that PS2 integrin requirements to regulate tendon cell
differentiation include a signaling function through Shc (Martin-Bermudo, 2000a).
Nonmuscle myosin-II is a key motor protein that drives cell shape change and cell movement. The function of nonmuscle myosin-II has been analyzed during Drosophila embryonic myogenesis. Nonmuscle myosin-II and the adhesion molecule, PS2 integrin (Myospheroid), colocalize at the developing muscle termini. In the paradigm emerging from cultured fibroblasts, nonmuscle actomyosin-II contractility, mediated by the small GTPase Rho, is required to cluster integrins at focal adhesions. In direct opposition to this model, it has been found that neither nonmuscle myosin-II nor RhoA appear to function in PS2 clustering. Instead, PS2 integrin is required for the maintenance of nonmuscle myosin-II localization and the cytoplasmic tail of the ßPS integrin subunit is capable of mediating this PS2 integrin function. Embryos that lack zygotic expression of nonmuscle myosin-II fail to form striated myofibrils. In keeping with this, a PS2 mutant that specifically disrupts myofibril formation is unable to mediate proper localization of nonmuscle myosin-II at the muscle termini. In contrast, embryos that lack RhoA function do generate striated muscles. Finally, nonmuscle myosin-II localizes to the Z-line in mature larval muscle. It is suggested that nonmuscle myosin-II functions at the muscle termini and the Z-line as an actin crosslinker and acts to maintain the structural integrity of the sarcomere (Bloor, 2001).
The myogenic function of nonmuscle myosin-II has been analyzed by using Drosophila genetics to manipulate the levels of nonmuscle myosin-II heavy chain, PS2 integrin, and RhoA GTPase in vivo in the developing larval muscles.
Both nonmuscle myosin-II and PS2 colocalize
at muscle termini. However, in contrast to models based on
cultured fibroblasts, there is no evidence for either
nonmuscle myosin-II or RhoA function in PS2 clustering.
Instead, the maintenance of nonmuscle
myosin-II localization at muscle termini is dependent on
the presence of PS2 integrin and the cytoplasmic tail of
the ßPS integrin subunit is sufficient for this. Further,
nonmuscle myosin-II maintenance at the muscle termini is compromised in ifSEF, a ßPS2 integrin subunit mutant that specifically disrupts myofibril formation. Through the analysis of actin distribution in the musculature of living wild-type and mutant embryos, it has been demonstrated that RhoA-independent nonmuscle myosin-II function is required for the proper sarcomeric organization of the muscle cytoskeleton. Finally, since nonmuscle myosin-II localizes to the Z-line in late larval muscle, it has been suggested that nonmuscle myosin-II functions at both the muscle termini and the Z-line to maintain the structural integrity of the sarcomere (Bloor, 2001).
When fibroblasts in culture attach to ECM substrates
through their cell surface integrin receptors, they dramatically
redistribute these receptors such that they become
clustered at focal adhesions. Integrin ligand binding also
induces the actin cytoskeleton to rearrange into stress
fibers, which terminate at focal adhesions and connect to
the cytoplasmic domains of the clustered integrins. Pharmacological
inhibitors of contractility block this complex
cellular response, providing evidence that nonmuscle myosin-II driven
contractility is essential for integrin clustering. At least a
subset of nonmuscle myosin-II based contractility is dependent
on RhoGTPase-mediated phosphorylation events. This suggests a model for focal
adhesion and stress fiber formation in which, when diffuse
cell surface integrins bind ECM ligand, they associate with
actin filaments and activate Rho. In turn, Rho activates
nonmuscle myosin-II, driving the formation of nonmuscle
myosin-II filaments and increasing contractility. This increases
the tension exerted on the actin cytoskeleton causing
actin filaments to bundle and align into stress fibers (Bloor, 2001).
Bundling drives actin-associated cell surface integrins into
clusters and focal adhesions are formed.
The localization of PS2 integrin at Drosophila muscle
termini is an ideal system in which to test this model in
vivo. Indeed, consistent with the possibility that RhoA-mediated
nonmuscle myosin-II contractility drives PS2 integrin clustering in the larval musculature, genetic evidence implicates RhoA-dependent activation of nonmuscle
myosin-II in multiple morphogenetic pathways during Drosophila
development. Furthermore, previous studies have shown that an
uncharacterized intracellular mechanism is capable of driving
integrin localization to the muscle termini. Despite this, this study shows that
genetic depletion of either nonmuscle myosin-II or RhoA
fails to disrupt PS2 localization (Bloor, 2001).
Maternally contributed RNAs and proteins support the
early stages of Drosophila embryogenesis. Both zip and
RhoA are maternally expressed and, in the absence of
zygotic expression, this maternal contribution is sufficient
for development to proceed normally until stage 14. Subsequent to this, depletion of maternal gene product results in defects in epidermal morphogenesis. Since the localization of PS2 integrin to the muscle termini occurs during stages
15 and 16, it seems likely that maternally contributed gene product is depleted
from zip and RhoA mutant embryos prior to PS2 clustering.
Thus, the presence of PS2 at muscle termini in zip and
RhoA mutants suggests that neither nonmuscle myosin-II
nor RhoA are required for PS2 clustering. However, the
absolute amount of these gene products required to localize
PS2 may be lower than that required for continued epidermal
morphogenesis. Alternatively, these gene products may
perdure longer in the mesoderm than in the developing epidermis (Bloor, 2001).
It is possible to eliminate the maternal contribution of a
gene by generating mutant clones in the female germline.
However, germline clones of zip and RhoA null mutations
fail to make eggs. A novel technique was used to address the role
of maternal nonmuscle myosin-II in PS2 localization. p127-l(2)gl, a nonmuscle myosin-II heavy chain binding protein, was overexpressed in a zip2 mutant background. The
p127-l(2)gl protein binds and sequesters maternal non-muscle
myosin-II heavy chain, effectively titrating the
available levels of nonmuscle myosin-II and antagonizing
its function. In these embryos, the epidermal
morphogenesis defects associated with zip2
mutations are enhanced; however, muscle attachment and PS2 localization
are unaffected. Muscle abnormalities are, however, observed in these and in zip zygotic null embryos: a variable subset of ventral muscles is deleted. Interestingly the affected muscles, VA1, VA2, and VA3, are derived from
two muscle progenitors that arise from the same cluster of
mesodermal cells. One progenitor divides to produce the muscle founder cells for VA1 and VA2. Subsequently, the other progenitor divides to produce
the VA3 muscle founder and an adult muscle founder cell. The lineage and temporal
relationships between these cells are reflected in the frequency
at which these muscles are deleted: VA3 is more
commonly deleted than VA1 and VA2, which are always
either both present or both deleted. Although it is unclear
whether these are the last progenitors to divide, it seems
likely that defects in nonmuscle myosin-II-dependent cytokinesis are the basis of this phenotype. The fact that depletion of nonmuscle myosin-II can affect myogenic events occurring during stages 11 and 12 without affecting the localization of PS2 that occurs during stages 15 and 16 further supports the contention that nonmuscle myosin-II is not required for PS2 localization (Bloor, 2001).
An alternative approach to the analysis of gene function is the ectopic expression of dominant negative constructs. Although the interpretations of such experiments are not always unambiguous, ectopic expression of the dominant negative RhoAN19 construct has implicated RhoA function in biological processes not revealed by maternal and zygotic mutational analyses. For example, driving RhoAN19 expression in the early mesoderm disrupts invagination of this tissue, phenocopying embryos that lack both maternal and zygotic DRhoGEF2 expression. In this study, the 24B GAL4 driver was used to express UAS-RhoAN19 in the mesoderm during later stages of development (Bloor, 2001).
24B-driven expression can be detected by stage 10 and strong expression occurs from stage 13 onward. Thus, this approach will compromise endogenous RhoA function during late stages of mesoderm development. Indeed 24B-driven
UAS-RhoAN19 expression affects the development of the
visceral mesoderm and causes defects in somatic muscle
patterning similar to those seen in zip mutant embryos. However, no defects were detected in somatic muscle attachment or PS2 localization in these embryos.
Thus, while it is not absolutely certain that maternally
supplied nonmuscle myosin-II or RhoA do not contribute to PS2 localization, these experiments provide strong evidence against this possibility (Bloor, 2001).
To exert tension on an underlying substrate, a cell must
form a strong transmembrane connection between the
substrate and its contractile cytoskeleton. At Drosophila
muscle attachments this connection is mediated by localized
PS2 integrin. As such, these structures superficially resemble focal adhesions,
a point further emphasized by the localization of the
focal adhesion protein integrin-linked kinase (ILK) to these
sites. In contrast to the recruitment of intracellular proteins to focal adhesions, it has been shown that the
initial localization of nonmuscle myosin-II to Drosophila
muscle termini is not dependent on integrin clustering.
Similarly, the localization of PAK and ILK are both independent of PS2 integrin.
Furthermore, PS2 is also not required for the formation of
an electron-dense hemiadherens junction at the muscle
termini. However, among the proteins known to localize to the muscle termini, nonmuscle myosin-II is so far unique in that only it is dependent on
PS2 integrin for its continued localization at these sites (Bloor, 2001).
Interestingly, the localization of nonmuscle myosin-II becomes
PS2-dependent at the same developmental stage at
which the PS2-dependence of muscle adhesion becomes
apparent. When integrins bind ECM ligand, they are thought to undergo a
conformational change that displaces the cytoplasmic tail
of the integrin alpha subunit, exposing protein binding sites on
the cytoplasmic tail of the ß subunit, a process known as
outside-in signaling. It is possible that the accessibility of
the ßPS cytoplasmic tail for protein-protein binding regulates
PS2-dependent nonmuscle myosin-II localization.
This is supported by the observation that, in the absence of
endogenous PS2, the ßPS cytoplasmic tail is sufficient to
keep nonmuscle myosin-II at the muscle termini. Excitingly,
biochemical studies show that peptides derived from
the cytoplasmic tail of the vertebrate integrin ß3 subunit are
able to interact with the tail of nonmuscle myosin-II. In addition, this interaction has recently been demonstrated in cultured cells, suggesting that the maintenance of nonmuscle myosin-II localization might occur through a direct binding reaction with the ßPS cytoplasmic tail (Bloor, 2001).
PS2 integrin is required in muscle both for attachment to
the epidermis and for the generation of sarcomeric ultrastructure.
These data suggest that the sarcomeric function of
PS2 is due, at least in part, to its role in maintaining
nonmuscle myosin-II at the muscle termini. A possible
function for nonmuscle myosin-II at the muscle termini is
to physically link PS2 integrin to the muscle cytoskeleton
by directly binding both PS2 and actin. One prediction of
this model is that, in the absence of nonmuscle myosin-II,
the muscle cytoskeleton will detach from the muscle
termini, but that PS2 will continue to mediate adhesion of
the muscle sarcolemma to the tendon matrix of the muscle-attachment
site. Such a phenotype is observed in embryos
mutant for ilk, the gene that encodes ILK. However, this disconnection of the muscle cytoskeleton from the muscle termini is clearly distinct from that
observed in the muscles of zip mutant embryos, where
muscle actin remains connected to the muscle termini, but
fails to organize into sarcomeres. While this does not rule
out a role for nonmuscle myosin-II in connecting PS2 and
actin, it certainly argues against nonmuscle myosin-II being
the primary component of this link (Bloor, 2001).
An alternative function for nonmuscle myosin-II is suggested
by the demonstration that nonmuscle myosin-II
localizes to the Z-line in the somatic muscles of third instar
larvae. Both the Z-line and the muscle termini are ultrastructural
elements that transmit tensile stress during muscle contraction. It is possible that nonmuscle myosin-II might function as an actin-crosslinking protein at these
sites to help maintain their structural integrity. This role is
generally assumed to be a function of alpha-actinin, an actin
crosslinking protein that is the major component of muscle
termini and Z-lines in both vertebrates and invertebrates.
Mutations in the single Drosophila alpha-actinin gene do cause
terminal defects and sarcomeric abnormalities. Surprisingly though, embryos that lack both maternal and zygotic alpha-actinin expression hatch and lethality
does not occur until the end of the first larval instar. Furthermore, the organization of actin into a striated pattern of I-bands is unaffected in alpha-actinin mutants. This implicates other actin-binding proteins in the maintenance of actin organization at the muscle termini and Z-line and the data
suggest that nonmuscle myosin-II maybe one such protein (Bloor, 2001).
There is no clear model of how nonmuscle myosin-II
might fulfill this function. Intriguingly, myosin heads from
a single filament have been shown to be able to bind parallel
actin thin filaments of opposite orientation. One speculation is that nonmuscle myosin-II might be capable of such behavior, but how such cross-links
would occur at cellular levels of ATP is not clear. One
possibility is that nonmuscle myosin-II in the muscle
termini and Z-line is in a 'catch' muscle state in which
tension is maintained without turnover of ATP. By this scenario,
nonmuscle myosin-II would not function in contraction,
but would serve as an effective actin crosslinker. A noncontractile
function for nonmuscle myosin-II in myofibrillogenesis would explain why RhoA appears to have no role in this process. It is interesting to note that, in Dictyostelium, a contraction-independent function of non-muscle myosin-II has been shown to be important for the generation of cortical tension (Bloor, 2001).
Finally, PS2 has been shown to be present at the sarcolemma
above the Z-line in cultured Drosophila myotubes. It is therefore possible that PS2 somehow functions to maintain nonmuscle myosin-II within the
Z-line. Indeed, adhesion between Z-line-associated hemiadherens
junctions and the muscle basement membrane fails in the absence of PS2. This suggests that the integrity of the sarcomeric muscle cytoskeleton requires it to be connected to the ECM at both the muscle termini and the Z-line and that this connection is mediated by nonmuscle myosin-II and PS2 integrin (Bloor, 2001).
Cell migration during embryogenesis involves two
populations of cells: the migrating cells and the underlying
cells that provide the substratum for migration. The
formation of the Drosophila larval midgut involves the
migration of the primordial midgut cells along a visceral
mesoderm substratum. Integrin adhesion
receptors are required in both populations of cells for
normal rates of migration. In the absence of the PS
integrins, the visceral mesoderm is disorganized, the
primordial midgut cells do not display their normal motile
appearance and their migration is delayed by 2 hours.
Removing PS integrin function from the visceral mesoderm
alone results in visceral mesoderm disorganization, but
only causes a modest delay in migration and does not affect
the appearance of the migrating cells. Removing PS
integrin function from the migrating cells causes as severe
a delay in migration as the complete loss of PS integrin
function. The functions of PS1 and PS2 are specific in the
two tissues, endoderm and mesoderm, since one cannot
substitute for the other. In addition, there is a partial
redundancy in the function of the two PS integrins
expressed in the endoderm: PS1 (alphaPS1betaPS) and PS3
(alphaPS3betaPS: alpha PS3 is Scab), since loss of just one alpha subunit in the midgut
results in either a modest delay (alphaPS1) or no effect (alphaPS3).
Thus, the migration
of primordial midgut cells along a substratum provided by the
visceral mesoderm requires the coordinated function of all
three PS integrins. The PS2 integrin is required in the visceral mesoderm for the formation of an optimal substratum for
migration. The PS1 and PS3 integrins are required in the
endodermal cells for their migration over the visceral
mesoderm. These two integrins are partially redundant in the
midgut, but PS3 cannot fully replace PS1 integrin function. The roles of small GTPases in
promoting migration of the primordial midgut cells were also examined. Dominant negative versions of Rac and
Cdc42 cause a very similar defect in migration as does the loss of
integrins, while dominant negative versions of Rho and Ras have no effect. Thus
integrins are involved in mediating migration by creating
an optimal substratum for adhesion, adhering to that
substratum and possibly by activating Rac and Cdc42 (Martin-Bermudo, 1999b).
The separate loss of either alphaPS1 or alphaPS2 does not produce the
same migration phenotype as loss of betaPS. However, loss of the
PS2 integrin does produce the same defects in the organization
of the visceral mesoderm as loss of all PS integrins.
There are at least two possible explanations for this result:
(1) either the alphaPS subunit is sufficient to mediate migration, or (2)
there is another a subunit that can partially compensate for the
loss of alphaPS1 or alphaPS2. In order to distinguish between these
possibilities, embryos mutant for both alphaPS1 and
alphaPS2 were examined. If the first explanation were correct then one
would expect the double mutant phenotype to be as
strong as the loss of betaPS. Endodermal cells from
alphaPS1alphaPS2 minus embryos show a greater delay in cell
migration than that observed in the single alpha subunit
mutants. This can be seen when only one or two
cells are found in contact in the middle in the double
mutant embryos at a time when several cells have
met in the single mutant embryos. Nevertheless,
in this double mutant combination, the endodermal cells send
projections and the delay in cell migration (1 hour) is still less
severe than that observed in betaPS minus embryos. This situation is
different from the role played by the integrins in muscle attachment,
where the loss of PS1 and PS2 integrins is equivalent to the loss
of all PS integrins.
Therefore, these results suggest that additional alpha subunits
exist that can compensate for the loss of alphaPS1 and alphaPS2. These
alpha subunits could be required in the endoderm, in the visceral
mesoderm or in both tissues (Martin-Bermudo, 1999b).
Since loss of PS2 appears to affect
the formation of the visceral mesoderm substratum as strongly
as loss of the betaPS subunit, and this does not substantially delay
migration, a model is favored in which other alpha subunits are
required in the endoderm. Since alphaPS3 (Scab) is also expressed in the
endoderm, it is an obvious candidate for a
second alpha required in the endoderm for cell migration.
Therefore, as the next step in analyzing the role of integrins in
midgut migration, the specific
requirements of the betaPS subunit in the two different tissues was examined, as was
the role of alphaPS3 (Martin-Bermudo, 1999b).
Analysis of embryos mutant for alphaPS3 supports previous evidence indicating that there is no defect in
midgut migration, showing that the PS3
integrin is not essential for midgut migration. However, it is
possible that there is some redundancy between the two alpha
subunits expressed in the endoderm, so that alphaPS1 compensates
for the lack of alphaPS3 and vice versa. To test this,
embryos lacking both PS1 and PS3 integrins were generated and
midgut migration was examined. Because alphaPS1 and alphaPS3 genes are on different
chromosomes, it was difficult to use the GAL4 system to
express any marker, so an enhancer trap line, 258,
was used that is expressed in the endodermal cells as they migrate.
This is a nuclear marker that allows identification of the position
of the endodermal cells and therefore the monitoring of their
migration, although it does not reveal the morphology of the
cells. In the absence of both alphaPS1 and alphaPS3
subunits, the defect in the migration of the midgut is as strong
as in the absence of the betaPS subunit,
consisting of a delay of approximately 2 hours. Embryos doubly mutant for alphaPS3 and alphaPS2 subunits,
were examined and no difference in midgut development was found as compared to
the loss of alphaPS2: this shows that there is no overlap in function
of the PS2 and PS3 integrins. In
conclusion, the main requirement for PS integrins during
migration is provided by the combination of PS1 and PS3
integrins. To
investigate whether PS3 is required to regulate gene
expression in the midgut, the patterns of
expressions of the two integrin target genes were examined. Loss of
PS3 function does not cause any change in their expression. Thus, PS1 function in
migration can also be partially performed by the PS3 integrin
(there is a small delay in the absence of PS1), while PS1
function in the regulating gene expression or adhesion to the
visceral mesoderm cannot be performed by PS3 (Martin-Bermudo, 1999b).
Two integrin ß subunits are encoded in the Drosophila genome.
The ßPS subunit is widely expressed and heterodimers containing this
subunit are required for many developmental processes. The second ß
subunit, βInt-ν (ßNeu), is a divergent integrin expressed primarily in the midgut
endoderm. To elucidate its function, null mutations in the gene
encoding βInt-ν were generated. βInt-ν is not required for viability or
fertility, and overall the mutant flies are normal in appearance. However, βInt-ν function could be observed in the absence of ßPS. Consistent with
its expression, removal of βInt-ν only enhanced the phenotype of ßPS
in the developing midgut. In embryos lacking the zygotic contribution of
ßPS, loss of βInt-ν resulted in enhanced separation between the
midgut and the surrounding visceral mesoderm. In the absence of both maternal
and zygotic ßPS, a delay in midgut migration was observed, but removing
ßNu as well blocked migration completely. These results demonstrate
that the second ß subunit can partially compensate for loss of ßPS
integrins, and that integrins are essential for migration of the primordial
midgut cells. The two ß subunits mediate midgut migration by distinct
mechanisms: one that requires talin and one that does not. Other examples of
developmental cell migration, such as that of the primordial germ cells,
occurred normally in the absence of integrins. Having generated the tools to
eliminate integrin function completely, it was confirmed that Drosophila
integrins do not control proliferation as they do in mammals, and have
identified alphaPS3 as a heterodimeric partner for βInt-ν (Devenport, 2004).
This genetic analysis of the second of the two ß integrin subunits
encoded in the Drosophila genome has resulted in three main findings.
(1) The ßν integrin subunit makes a minor contribution
to development and viability of Drosophila.
ßν integrins can contribute to the development of the tissue in which
it is highly expressed, but only when the function of
the other ß integrin subunit, ßPS was reduced or eliminated. (2) The
alphaPS3ßν (Scabßν) integrin (possibly in combination with other
ßν-containing integrins) is the missing receptor that mediates
primordial midgut cell migration in the absence of ßPS-containing
integrins, and thus the migration of these cells over the visceral mesoderm
substrate is completely integrin dependent. (3) It was possible to eliminate
concerns that the ßν subunit might be compensating for the absence
of the ßPS subunit in a variety of developmental events that apparently
occur normally in the absence of ßPS. By removing the maternal and
zygotic contributions of both integrin ß subunits, embryos completely
lacking integrin function have been generated for the first time. The only
difference noted in the development of these embryos, in comparison with
those lacking ßPS alone, was the complete failure of the primordial
midgut cells to move. Notably, a second migration event occurring at the same
time, the migration of the primordial germ cells, occurred normally without
integrins. Although every developmental
event during embryogenesis was not exhaustively examined, what is important is that the
genetic tools have been generated to allow the examination of developmental events in the complete
absence of integrins. By also analyzing clones of cells lacking both ß
integrin subunits, it was confirmed that in Drosophila integrins are not
required for proliferation of epithelial cells, nor for the initial
establishment of apicobasal polarity within epithelial layers (Devenport, 2004).
One of the key questions to emerge from this work is what changes ~2
hours after the time when primordial midgut migration is normally initiated,
so that ßν can now mediate migration? It seems likely that the
developmental change that permits ßν integrin-dependent migration is
the synthesis of an essential protein or proteins. It is not just the timing
of ßν synthesis itself that is regulated, because expression of ßν
earlier than normal did not alleviate the delay in migration, even though
expression of ßPS with the same approach did successfully restore
migration at the normal time in embryos lacking endogenous ßPS.
Therefore, at least one additional protein is required for ßν-mediated
migration. This protein could have one of several possible functions: an
alpha integrin subunit heterodimeric partner; an extracellular matrix
ligand; an intracellular protein required to link integrins to the
cytoskeleton, vital for cell movement, and/or a regulator of any of these
proteins. The alphaPS3 subunit is known to be present in the midgut at the
early stages of migration because eliminating it along with the alphaPS1
subunit results in delayed migration,
so the possibility that alphaPS3 is a limiting factor for
ßν-mediated migration can be ruled out. Curiously, eliminating the alphaPS1 and alphaPS3 subunits zygotically did not block migration completely,
as might be expected if alphaPS3 is the major alpha subunit partner for
ßν. Either there is a substantial maternal contribution of the
alphaPS3 subunit or perhaps the alphaPS4 or alphaPS5 subunits also
function in the midgut (Devenport, 2004).
Evidence to suggest that integrins containing the two ß subunits
mediate migration by interacting with different cytoplasmic linker proteins
came from an analysis of the role of talin in midgut migration. Talin binds
directly to integrins, with more than one binding site, and the detailed
nature of one crucial interaction has been characterized at high resolution.
The defect in midgut migration caused by the loss of talin
resembles the defect caused by the loss of ßPS rather than both ß
subunits. This is consistent with the divergence of the ßν cytoplasmic
tail, particularly a lack of conservation of a tryptophan that makes a key
contact with talin in ß3. Therefore, it seems likely that ßν
makes interactions with an alternate cytoplasmic linker, and it may be that
the synthesis of this protein is what permits ßν-dependent migration.
One candidate protein, filamin 1, appears to be ruled out by the observation
that its localization is not ßν dependent (Devenport, 2004).
The functions observed for ßν are seen only in the absence
of ßPS, so it is still unclear what ßν does under normal,
wild-type conditions. Although a relatively divergent integrin, other insect
genomes that have been sequenced also contain an orthologue of the ßν
gene, suggesting that it does have a function
worthy of retaining through evolution. One possibility is that ßν
contributes to the architecture of the midgut in way that is not obvious by
appearance but that makes an important contribution to the physiology of this
organ. If the flies lacking ßν integrin are unable to digest their
food as well as their wild-type counterparts, this would probably make these
flies less competitive in the wild (Devenport, 2004).
Creating the tools to eliminate all integrin heterodimers allowed the
addressing of whether some integrin functions that are well-established in
vertebrates and cell culture are important in Drosophila. For
example, cell cycle progression in cultured mammalian cells is absolutely
dependent on their adhesion to an extracellular matrix and, consequently,
cells in suspension will arrest their cell cycle. Integrins are
the major adhesion molecules that control this phenomenon called
'anchorage-dependent growth'. However, the developmental relevance of this phenomenon is not completely clear because in an intact organism most cell types, other than those of the circulatory system, will never be in suspension. Genetic
experiments in mouse are beginning to address this issue and have demonstrated
that integrins are important for proliferation during the development of a
number of tissues including skin, bone and embryonic ectodermal ridge cells. Whether integrins are required for cells to divide in
Drosophila was tested, and, surprisingly, they are not. By
comparing the size of clones of cells generated by mitotic recombination, it was
found that double integrin mutant epithelial cells are able to proliferate at
approximately the same rate as their siblings that just lack ßν. Thus,
it appears that integrins have adapted an additional function in regulating
cell proliferation during the evolution of the vertebrate lineage. Perhaps
this additional level of cell cycle regulation arose with the massive increase
in the number of cell divisions that mammals undergo throughout their
development. It is clearly advantageous for cells to arrest proliferation in
the absence of adhesion to prevent the growth of metastatic tumours, so
perhaps another, non-integrin adhesion molecule is permissive for growth in
Drosophila epithelia (Devenport, 2004).
There is a substantial amount of data to suggest that integrins play a role
in epithelial architecture and polarity, but the
data are conflicting regarding the precise roles. Experiments using 3D
epithelial cysts demonstrated a role for integrins in orienting the direction
of polarity, but not for establishing distinct apical and lateral membrane domains. However, experiments in vivo suggest that integrins maybe required for the
initial establishment of polarity. For example, epiblasts derived from
laminin-/- or ß1 integrin-/- ES cells fail to form
a polarized epithelium or a proamiotic cavity. Furthermore,
laminin mutants in C. elegans show numerous polarity defects, such as
non-basal integrin adhesions and ectopic adherens junctions. Advantage was taken of the double ß integrin mutants to address the role of
integrins in Drosophila epithelia; they are important
for the maintenance, but not the establishment of polarity in secondary
epithelia. In embryos lacking ßν and zygotic ßPS, the integrity
of the endoderm is severely compromised, although its polarity is initially
established. Furthermore, when integrin heterodimers were eliminated in clones
of cells, the initial distribution of apicolateral markers in the
follicular epithelium was observed to be normal. However, epithelial integrity was
compromised because cells eventually rounded up and formed multiple layers, a
common phenotype seen in mutants that disrupt polarity or epithelial integrity.
Thus, cells cannot retain their polarity without basal adhesion, but integrins
are not necessary to set up the establishment of apical and lateral domains in
Drosophila (Devenport, 2004).
Although the roles of ßν during Drosophila morphogenesis
are found to be minor, the important findings of this study are twofold.
(1) The presence of another integrin ß subunit in Drosophila
had required cautious interpretation of previous genetic analyses of PS
integrin mutants. Therefore, it was important to establish whether redundancy
by ßν masked any important roles for the PS integrins in
Drosophila. However, this study has shown that removal of ßν
does not enhance ßPS mutant phenotypes in the muscle, CNS or embryonic
epidermis. It can now be said with confidence that in tissues other that the
midgut, ßPS-containing integrins are the primary players in cell-matrix
adhesion in Drosophila. Hence, for all practical purposes, germline
depletion of ßPS essentially eliminates integrin function in all
embryonic tissues other than the midgut. (2) It is now established that
Drosophila integrins are important for some but not all of the functions that they mediate in vertebrates. Although important for muscle cell fusion, establishment of epithelial polarity and cell proliferation in mammals, integrins are not required for these processes in Drosophila (Devenport, 2004).
Three position-specific (PS) integrins are
expressed at the Drosophila neuromuscular junction
(NMJ): a beta subunit (betaPS known as Myospheroid), expressed in both presynaptic
and postsynaptic membranes, and two alpha subunits
(alphaPS1, alphaPS2), expressed at least in the postsynaptic
membrane. PS integrins appear at postembryonic NMJs
coincident with the onset of rapid morphological growth
and terminal type-specific differentiation, and are
restricted to type I synaptic boutons, which mediate fast,
excitatory glutamatergic transmission. Two
distinctive hypomorphic mutant alleles of the beta subunit
gene myospheroid (mysb9 and mysts1), differentially affect
betaPS protein expression at the synapse to produce
distinctive alterations in NMJ branching, bouton
formation, synaptic architecture and the specificity of
synapse formation on target cells. The mysb9 mutation
alters betaPS localization to cause a striking reduction in NMJ
branching, bouton size/number and the formation of
aberrant 'mini-boutons'; this may represent a
developmentally arrested state. The mysts1 mutation
strongly reduces betaPS expression to cause the opposite
phenotype of excessive synaptic sprouting and
morphological growth. NMJ function in these mutant
conditions is altered in line with the severity of the
morphological aberrations. Consistent with these mutant
phenotypes, transgenic overexpression of the betaPS protein
with a heat-shock construct or tissue-specific GAL4 drivers
causes a reduction in synaptic branching and bouton
number. It is concluded that betaPS integrin at the
postembryonic NMJ is a critical determinant of
morphological growth and synaptic specificity. These data
provide the first genetic evidence of a functional role for
integrins at the postembryonic synapse (Beumer, 1999).
At the Drosophila larval NMJ, motor axons contact specific
target muscles and form characteristic arborizations at defined
locations on the muscle surface. These
arborizations consist of branches forming numerous
varicosities (boutons) falling into two primary classes:
glutamatergic type I boutons (2-5 mm diameter) innervate
all muscles and mediate fast, excitatory transmission;
octopaminergic type II boutons (~1 mm diameter) are found on
a subset of muscles, and appear to have a primarily modulatory
function.
Growth at all arbors is activity dependent
and a number of molecules involved in regulating this
morphological plasticity have been identified.
The possible function of integrins
in morphological synaptic plasticity in this system becomes apparent with the isolation of Volado, an alpha integrin subunit
required for Drosophila memory. Additionally, expression of one subunit, alphaPS2,
at the NMJ has been reported. To assay synaptic integrin expression, larval preparations were probed with specific antibodies
against alphaPS1, alphaPS2, betaPS and betannu integrin subunits. The alphaPS1, alphaPS2 and betaPS subunits are
clearly detectable; only the betanu subunit does not appear
to be present in the NMJ. PS integrin
expression is restricted to type I boutons in a halo
surrounding an unlabeled center, suggesting primarily
postsynaptic localization. In double-labeled
confocal sections, alphaPS and betaPS integrin staining overlaps
anti-DLG (discs-large), a primarily postsynaptic marker,
although the PS integrin expression appears to be less
uniform than the anti-DLG staining. alphaPS1
integrin staining is consistently fainter and less extensive
than alphaPS2 and betaPS integrin staining. In addition
to the intense betaPS localization at the NMJ, fainter staining is
observed throughout the muscle. This is interpreted to be
sarcomeric expression of betaPS dimerized with alphaPS2 (Beumer, 1999).
In order to localize PS integrins expression more precisely,
mature larval NMJs were probed with anti-PS integrin
antibodies and embedded for ultrastructural analysis.
Antibody staining against alphaPS1, alphaPS2 and betaPS integrin
subunits all show
expression throughout the subsynaptic reticulum (SSR), a
system of postsynaptic foldings of the muscle membrane that
surrounds the presynaptic boutons in type I arbors. These results clearly confirm that
all three PS integrins occur at least postsynaptically. In
additional experiments, pre-embedding-anti-betaPS staining
can be achieved in the absence of detergent, thus preserving
the cell membranes. In these specimens, unopposed
presynaptic membranes often reveal staining deposits
suggesting that at least betaPS integrin is expressed in the
presynaptic membrane in addition to the postsynaptic SSR.
Developmentally, all three PS integrins become detectable
at the NMJ in late first or early second instar larvae, although others
have reported earlier expression in the CNS. No expression in embryos or
hatching first instar larvae could be detected in the peripheral nerves or NMJ,
although the expected expression at the muscle attachment
sites is clearly visible for all three subunits.
Thus, PS integrin expression becomes concentrated at NMJs
only after they have been differentiated and stabilized during
embryogenesis. This late onset of expression coincides with
the appearance of the SSR, the period when different
morphological classes of NMJs first appear and the terminals
first become subject to measurable activity-dependent
morphological plasticity (Beumer, 1999).
Because errors in pathfinding have been reported in
animals lacking alpha integrin subunits, third instar larvae with altered
integrin expression at the NMJ were examined
for aberrations that might be the result of either
errors in pathfinding or in synapse remodeling
or maturation. For this
analysis, the complex, muti-innervated
muscle 12 NMJ was analyzed. Three types of gross patterning
abnormalities, designated as backbranched, pulled away or
multiple insertions, were noted and quantified in a blind study. The first of these phenotypes, backbranched, consists
of at least one arboreal branch leaving muscle 12 and
branching back onto muscle 13 from a site away from the
point of nerve entry onto muscle 12. This
architecture is very rare in normal animals but occurs
at abnormally high levels in all mys mutant animals;
the error is most common in mysb9 and mysb9 /mysXG43 (both
greater than 30%). The second phenotype, pulled away, is
characterized by boutons suspended in the space between
muscles 12/13, and defasciculation, or branching, beginning
before the nerve has actually reached the point of insertion
on the muscle. This phenotype is rare in
controls but common in all genotypes with severely
reduced betaPS expression; mysts1/mysXG43 mutant larvae
show a 50% incidence of this defect. Finally, the
third phenotype, multiple insertions, is characterized by two
or more separate and distinct nerve entry points on muscle 12. In these junctions, both nerves can frequently be
traced back to a point of separation above muscle 13, though
occasionally the separation occurs after the nerve has
left muscle 13. The appearance of multiple nerve entry points
is rare in controls and is not significantly
increased in mysb9 and mysb9 /mysXG43 mutants. However,
multiple nerve entry points are a common consequence of
severe betaPS loss in both mysts1 and mysts1/mysXG43 animals. It is concluded that alterations in betaPS expression also
exert effects on the pattern of innervation and synaptic
specificity during NMJ development (Beumer, 1999).
These observations demonstrate that the level of PS integrins
at postembryonic NMJs is a critical determinant of
morphological sprouting, growth and bouton differentiation.
(1) Moderate decrease in the detection of betaPS expression at
the NMJ accompanied by an increase in extrasynaptic muscle
expression (in mysb9) results in undergrowth and compaction
of the terminal, loss of boutons, a decrease in overall bouton
size and the proliferation of a new class of 'mini-boutons'.
(2) In contrast, severe reduction in the detection of betaPS
expression at the NMJ, unaccompanied by a detectable
increase in extrasynaptic expression (in mysts1), results in an
increase in sprouting and morphological growth to cause
overgrowth and an increase in terminal complexity. (3) Overexpression of betaPS, generalized or nerve/muscle-specific,
reduces branching complexity and bouton numbers. In
agreement with the mysb9 observations, early betaPS
overexpression in the muscle also increases the frequency of
mini-boutons. Thus, the subcellular distribution of betaPS in both
the motor neuron and its muscle partner is an important
determinant of morphological development at the
postembryonic NMJ (Beumer, 1999).
The identity of the mini-boutons is of particular interest.
Mini-boutons are found very abundantly in mysb9 and betaPS-overexpressing
terminals, but are also observed at a low frequency in wild-type
NMJs. Molecularly, these
structures show the hallmarks of type I boutons but are many-fold
smaller. An exciting recent study (Zito, 1999) using
confocal imagery of live synapses has suggested that these
structures may represent immature type I boutons and/or new
terminal branches. Molecular labeling, presented in the Beumer study (1999), defines these
structures as nascent type I boutons. It appears, therefore, that
decreased betaPS integrin expression triggers the differentiation
process for these bouton precursors, but that some subsequent
condition required for maturation is not being met. These
observations suggest that proliferation of these immature type I
boutons is correlated with extrasynaptic expression of betaPS.
Thus, it is suggested that bouton formation is developmentally
arrested when presented with the incorrect expression of betaPS
in the target membrane, leading to a failure of terminal bouton
maturation (Beumer, 1999).
Calcium/calmodulin dependent kinase II (CaMKII), PDZ-domain scaffolding protein Discs-large (Dlg), immunoglobin superfamily cell adhesion molecule Fasciclin 2 (Fas2) and the position specific (PS) integrin
receptors, including ßPS (Myospheroid) and its alpha partners (alphaPS1, alphaPS2, PS3/alpha Volado), are all known to regulate the postembryonic development of synaptic terminal arborization at the Drosophila neuromuscular junction (NMJ). Recent work has shown that Dlg and Fas2 function together to modulate
activity-dependent synaptic development and that this role is regulated by activation of CaMKII. PS integrins function upstream of CaMKII in the development of synaptic architecture at the NMJ. ßPS integrin physically associates with the synaptic complex anchored by the Dlg scaffolding protein, which contains CaMKII and Fas2. This study demonstrates an alteration of the Fas2 molecular cascade in integrin regulatory mutants, as a result of CaMKII/integrin interactions. Regulatory ßPS integrin mutations increase
the expression and synaptic localization of Fas2. Synaptic structural defects in ßPS integrin mutants are rescued by transgenic
overexpression of CaMKII (proximal in pathway) or genetic reduction of Fas2 (distal in pathway). These studies demonstrate that ßPS
integrins act through CaMKII activation to control the localization of synaptic proteins involved in the development of NMJ synaptic morphology (Beumer, 2002).
ßPS integrin is a transmembrane receptor present in both pre- and post-synaptic membranes at the larval NMJ. Dlg is a synaptic scaffolding protein associated with both pre-and post-synaptic membranes and is also involved in the regulation of synaptic morphology, through the localization of diverse transmembrane proteins (including Fas2). Studies were undertaken to determine whether ßPS integrin associates with the DLG complex to tie together these disparate receptor components in a common molecular machine. In confocal analyses, ßPS integrin and Dlg co-localize at the larval NMJ. Dlg clearly has less extensive expression, more tightly localized at NMJ boutons, whereas ßPS is more extensive through the subsynaptic reticulum (SSR) and also localized at extrasynaptic sites in the muscle, including the muscle sarcomere and attachment sites. However, both proteins are most intensively expressed at the NMJ presynaptic/postsynaptic interface, where they co-localize. Therefore, tests were performed to determine if ßPS integrins form part of the synaptic complex linked by Dlg. Protein immunoprecipitation assays were performed using rabbit anti-DLG to probe Oregon R head extracts. Dlg antibodies clearly co-immunoprecipitate Dlg and ßPS integrin protein, consistent with co-localization observed in confocal analysis. Inspection of the ratio of both bound proteins and proteins not bound to beads (immunoprecipitation versus flow through lanes) indicates that a large portion of the ßPS integrin protein associates with a complex containing Dlg. The fact that ßPS was found to co-immunoprecipitate with the complex mediated by Dlg provides support for integrins existing in a synaptic complex with Fas2 and CaMKII at the synapse (Beumer, 2002).
To assay the mys requirement in synaptic development comprehensively, two regulatory alleles of mys with opposing structural phenotypes were compared and contrasted: mysb9, which causes NMJ undergrowth, and mysts1, which causes NMJ overgrowth. In both mutants, a correlation was observed between the morphological alterations and synaptic function, in contrast to the homeostasis seen in Fas2 mutant synapses but consistent with the parallel alterations seen in CaMKII-inhibited synapses. However, the correlation between synaptic structural and functional alterations in mys mutants is not striking, and it is clear that integrins primarily mediate architectural regulation. Therefore, the focus in this study was exclusively on the mechanism(s) by which integrins modulate NMJ structural development. This article presents molecular and genetic evidence that strongly support the hypothesis that synaptic integrin receptors containing ßPS modulate CaMKII activation on both sides of the synaptic cleft and, through CaMKII, control both the expression and the synaptic localization of Fas2 at the synapse. The primary experimental results supporting these conclusions are detailed below (Beumer, 2002).
(1) Transgenic expression of CaMKII is sufficient to completely rescue all synaptic structure defects in mys mutants. Genetically increasing CaMKII in postsynaptic muscle, but not presynaptic neuron, completely rescues the structural undergrowth of the mysb9 integrin mutant, whereas it is necessary to elevate CaMKII both pre- and post-synaptically to rescue structural overgrowth in the mysts1 mutant. These results are consistent with the postsynaptic mislocalization of ßPS integrin in the mysb9 mutant, as opposed to the global loss of synaptic integrin in the mysts1 mutant. These data indicate that coordinate regulation of CaMKII in the muscle and motoneuron is necessary for proper development of synaptic architecture (Beumer, 2002).
(2) At the distal end of the cascade, both the expression and synaptic localization of Fas2 are increased in mys mutants, although the extent of Fas2 misregulation is significantly different between the two regulatory mutants. Importantly, both the NMJ overgrowth (mysts1) and undergrowth (mysb9) phenotypes are rescued towards wild-type structure by genetically reducing the amount of Fas2 available at the synapse to near normal levels. In mysts1 mutants, correcting for Fas2 level suppresses the synaptic overgrowth, while in mysb9 mutants, correcting the Fas2 level suppresses the synaptic undergrowth. These results support the conclusion that Fas2 is centrally involved in mediating synaptic growth, but suggest that the Fas2-mediated mechanism is more complex than previously thought (Beumer, 2002).
The results demonstrate that integrins regulate morphological growth at the postembryonic NMJ through activation of CaMKII in both pre- and post-synaptic compartments. One important target of CaMKII is Fas2 and it is clear that regulation of Fas2 expression and localization is an important component of integrin regulation. However, the modulation of Fas2 levels alone is unlikely to account fully for the alterations in synaptic architecture in integrin mutants. In particular, both mysts1 and mysb9 upregulate synaptic Fas2 levels, albeit to different degrees, yet show opposite alterations in synaptic growth. Moreover, reducing Fas2 levels rescues both under- and overgrowth defects, but the rescue is not perfect (Beumer, 2002).
Precise control of Fas2 levels finely tunes morphological development at the NMJ. Different degrees of reduced Fas2 expression can either facilitate or inhibit the growth/maintenance of the NMJ, and reduced Fas2 expression has been demonstrated in other overgrowth mutants. However, overexpression of Fas2 in specific muscles drives increased NMJ elaboration/bouton differentiation and selective preference for a high-expressing muscle over a low-expressing muscle. How can this complexity be interpreted? One likely explanation is interaction between Fas2 and other developmental pathways regulated by CaMKII. To date, the only known Fas2-independent regulation of synaptic morphology involves a deubiquitinating protease encoded by fat facets (faf), and a putative ubiquitin ligase encoded by highwire (hiw), which have been shown to work together to modulate the degree of NMJ growth. Loss-of-function hiw mutants display NMJ structural overgrowth, importantly without a concomitant decrease in Fas2. Indeed, overexpression of Fas2 cannot suppress the overgrowth seen in hiw mutants. These observations are consistent with the overgrowth combined with overexpression of Fas2 observed in mysts1 mutants in this study. However, any putative interaction between Fas2-dependent and -independent mechanisms of morphological growth regulation at the Drosophila NMJ synapse remain to be elucidated. It is expected that further study will reveal an additional structural control mechanism regulated by CaMKII, acting in parallel to and interacting with Fas2. The ubiquination mechanism discussed here is one candidate mechanism, but as CaMKII is known to have many synaptic targets, it is clearly not the only candidate (Beumer, 2002).
In summary, it is concluded that architectural developmental defects observed in NMJ synapses mutant for ßPS integrin are due to the loss of the ability to regulate synaptic CaMKII properly. One function of CaMKII is to phosphorylate the scaffolding protein Dlg, and thus regulate the proteins synaptically localized by this scaffold. Fas2 is the central known output of this regulatory cascade. Loss of this regulation is central to the mys mutant defects in the postembryonic elaboration of NMJ structure. It is clear from this study, however, that regulation of Fas2 localization via CaMKII is only one facet of how integrins function at the synapse (Beumer, 2002).
Mechanisms that regulate axon branch stability are largely unknown. Genome-wide analyses of Rho GTPase activating protein (RhoGAP) function in Drosophila using RNA interference has identified p190 RhoGAP as essential for axon stability in mushroom body neurons, the olfactory learning and memory center. RhoGAP inactivation leads to axon branch retraction, a phenotype mimicked by activation of GTPase RhoA and its effector kinase Drok and modulated by the level and phosphorylation of myosin regulatory light chain. Thus, there exists a retraction pathway from RhoA to myosin in maturing neurons, which is normally repressed by RhoGAP. Local regulation of RhoGAP could control the structural plasticity of neurons. Indeed, genetic evidence supports negative regulation of RhoGAP by integrin and Src, both implicated in neural plasticity (Billuart, 2001).
Tests were performed to see if integrin could regulate p190 activity in MB neurons, since mammalian studies suggest potential links between integrin and p190, as well as integrin and Src. Integrins function as heterodimers of one alpha and one ß subunit. Drosophila has five genes for integrin alpha subunits, including one, volado (vol), also called scab, which is preferentially expressed in MB neurons and, when mutated, results in a short-term memory defect. No significant modification of the p190 RNAi phenotype was observed in flies heterozygous for a null mutation of vol (vol4). This may be because vol is not dosage sensitive or because it functions redundantly with other integrin alpha subunits in regulating p190 activity. Only two genes encode integrin ß subunits in the fly, ßPS and ßnu; ßnu may not associate with an alpha subunit. The myospheroid (mys) gene, encoding ßPS, shows robust genetic interaction with p190. In flies with one wild-type copy of mys, the p190 RNAi phenotype is markedly suppressed for each of the three mys alleles tested, suggesting that p190 is negatively regulated by integrin (Billuart, 2001).
Finally, MB neuroblast clones homozygous for mys1 were examined using the MARCM system. Twelve of 52 neuroblast clones exhibited obvious dorsal lobe axon overextension not seen in control flies. These include overextension of thin axon bundles near the tip of dorsal lobe similar to those seen in Drok2 clones, or overextension of a large portion of the dorsal axons similar to those seen in MB neurons overexpressing p190. This experiment indicates that integrins are essential negative regulators of axon extension in MB neurons (Billuart, 2001).
Integrins are concentrated within growth cones, but their contribution to axon extension and pathfinding is unclear. Genetic lesion
of individual integrins does not stop growth cone extension or motility, but does increase axon defasciculation and axon tract displacement. In this study, a dosage-dependent phenotypic interaction is documented between genes for the integrins, their ligands, and the midline growth cone repellent, Slit, but not for the midline attractant, Netrin. Longitudinal tract axons in Drosophila embryos doubly heterozygous for slit and an integrin gene, encoding alphaPS1, alphaPS2, alphaPS3, or ßPS1, take ectopic trajectories across the midline of the CNS. Drosophila doubly heterozygous for slit and the genes encoding the
integrin ligands Laminin A and Tiggrin reveal similar errors in midline axon guidance. It is proposed that the strength of adhesive signaling from integrins influences the
threshold of response by growth cones to repellent axon guidance cues (Stevens, 2002).
Axon fasciculation and guidance were studied in the CNS of embryos
mutant for the ß integrin gene myospheroid (mys) and three alpha integrins, alphaPS1 (mew), alphaPS2 (if),
and alphaPS3/4 (scb). It is not known whether the
scb locus affects alphaPS3 or alphaPS4 or both, because the
alphaPS4 locus is separated from alphaPS3 by 259 bp.
Variation in penetrance of mutant phenotype was observed with all
integrin alleles. The three longitudinal fascicles are intact in loss-of-function mutations in mys, which encodes the only ß integrin expressed in the
CNS; however, midline fusions of the most
medial tract are seen in some segments. Axon tract structure is least
disrupted in mew mutant embryos. No midline guidance errors
are seen; however, the longitudinal fascicles appeared to be thinner,
with occasional defasciculation. if mutant embryos are similar in
phenotype to mew, but also reveal a low frequency of
midline crossover errors. Midline fusions as well as transient merging of lateral fascicles are seen in scb mutant embryos (Stevens, 2002).
Axon tract fasciculation appears normal in embryos heterozygous
for mutations in one integrin gene and also in embryos heterozygous for
mutations in two integrin genes. However, all four
integrin mutations reveal a semidominant phenotype when doubly
heterozygous with slit. In all instances, the frequency of
midline guidance errors is increased over the levels seen in homozygous
integrin mutants. Apart from midline axon crossings in one-third of the segments, the LT appeared normal in mys/+;sli/+ embryos. Less than 10% of segments revealed midline guidance errors in mew/+;sli/+ embryos. In contrast, 40% and 58% of segments had midline guidance errors in if/+;sli/+ and scb/sli embryos. Only in scb/sli double heterozygotes are the middle and most lateral axon tracts affected, indicating a strong phenotypic interaction between scab and slit (Stevens, 2002).
Midline guidance phenotypes are observed in integrin homozygotes that
are also haplosufficient for slit. In particular, the
frequency of midline crossing is much higher in
mew/Y;sli/+ and if/Y;sli/+
mutants and also involves more lateral axon tracts (Stevens, 2002).
Thus, a reduced level of expression of
the genes for four integrins (alphaPS1, alphaPS2, alphaPS3/4, and ßPS1) or
two integrin ligands (Tiggrin and Laminin) increases the probability that CNS axons make pathfinding errors when slit expression
is reduced. Expression of the integrins Tiggrin and Laminin A has been
demonstrated in the CNS. Integrin
expression is not localized and may be expressed in both glia and
neurons. Overexpression of alphaPS3 or Laminin A in motoneurons affects
axon guidance. Loss of function of the integrins
disrupts axon fasciculation and longitudinal axon fascicle placement in
the embryonic nerve cord but does not clearly affect axon guidance. These observations have been extended in this study,
with different alleles of the integrins, demonstrating a similar
function for alphaPS3/4, and revealing axon fascicle phenotypes for loss
of function of integrin ligands Tiggrin and Laminin A. The mutant
phenotypes share common elements: mild phenotypes show wavy axon tracts
and reduced Fas II labeling between segments, whereas severe phenotypes
include defasciculation and fascicle displacement, including midline
axon guidance errors. The integrins have different extracellular
ligands. Therefore, the integrins contribute similarly to axon tract
integrity, independent of the ligand that they bind (Stevens, 2002).
Integrins are concentrated in the growth cones of Drosophila axons, and their ligands are uniformly distributed over pathways of axon extension. Integrins
facilitate the growth of axons by providing a link between the ECM and
the cytoskeleton of the growth cone. Defasciculation and guidance errors seen in integrin mutants reflect decreased adhesion to the ECM
and a lower threshold to errors in guidance. Axon extension is not
impaired in Drosophila integrin mutants, although it is possible that a maternal contribution of integrin may mask this requirement (Stevens, 2002).
Part of the adhesive function of integrins is to activate intracellular
signals that alter motility and axon outgrowth. During ligand binding,
ß integrins may activate Focal Adhesion Kinase and Rho, which
stabilize actin structures, permit actin filament growth, and
facilitate the formation of focal adhesions. Intracellular signals can also modify adhesiveness by altering the affinity of integrins for their ligands. These signals can combine to cluster integrins and strengthen their attachment to the
ECM. This increased adhesiveness can act in opposition to factors that
decrease adhesion and axon extension, such as myelin or aggrecan. Furthermore, integrin signaling can influence other adhesion systems active in the growth cone (Stevens, 2002).
Similarly, integrin function alters the sensitivity of growth cones to
repellent signaling by Slit. When slit expression and integrin function are both reduced, growth cones are more likely to
respond to attractive guidance from the midline. Signals from axon
guidance receptors promote growth cone reorientation and remodeling of
the growth cone cytoskeleton. Integrin adhesion promotes local
stabilization of cytoskeletal links to the ECM, which antagonizes
growth cone reorientation. The threshold of response of growth cones to
axon guidance signals is therefore regulated by the ability of guidance
signals to reduce the stability of ECM to cytoskeletal linkages. This
threshold may be reached at axon guidance choice points, including the
segment boundary and the commissures, where clustering of errors in
axon guidance occur. The efficacy of guidance signals may be reduced
between choice points by local increases in ECM affinity (Stevens, 2002).
Integrin-ligand affinity and integrin-cytoskeletal linkages are
logical targets of axon guidance signals. Further studies of the
targets of integrin and guidance signals should reveal how growth cones
integrate information from the ECM (Stevens, 2002).
Regulation of actin structures is instrumental in maintaining proper cytoarchitecture in many tissues. In the follicular epithelium of Drosophila ovaries, a system of actin filaments is coordinated across the basal surface of cells encircling the oocyte. These filaments have been postulated to regulate oocyte elongation; however, the molecular components that control this cytoskeletal array are not yet understood. The receptor tyrosine phosphatase (RPTP) Dlar and integrins are involved in organizing basal actin filaments in follicle cells. Mutations in Dlar and the common ß-integrin subunit mys cause a failure in oocyte elongation, which is correlated with a loss of proper actin filament organization. Immunolocalization shows that early in oogenesis Dlar is polarized to membranes where filaments terminate but becomes generally distributed late in development, at which time ß-integrin and Enabled specifically associate with actin filament terminals. Rescue experiments point to the early period of polar Dlar localization as critical for its function. Furthermore, clonal analysis shows that loss of Dlar or mys influences actin filament polarity in wild-type cells that surround mutant tissues, suggesting that communication between neighboring cells regulates cytoskeletal organization. Two integrin alpha subunits encoded by mew
and if are required for proper oocyte elongation, implying that multiple components of the ECM are instructive in coordinating actin fiber polarity.
It is concluded that Dlar cooperates with integrins to coordinate actin filaments at the basal surface of the follicular epithelium. This is the first direct demonstration of an RPTP's influence on the actin cytoskeleton (Bateman, 2001).
Wild-type oocytes stained with anti-ß-integrin show intense labeling at the basal surface throughout development, consistent with a strong association with basal actin structures and the underlying laminin-rich ECM. Higher magnification views of stage 7-8 follicles show that ß-integrin staining is somewhat diffuse at the basal surface, with significant staining over cell-cell contacts and where actin filaments terminate. Often, integrin staining is observed along an individual actin filament, reflecting a close association with the actin cytoskeleton. A similar pattern of staining is observed for the ECM component laminin, a ligand for PS1 integrin heterodimers. As with Dlar, integrin staining is intense at cell-cell contacts where 3 cells meet at this early stage. However, unlike the pattern observed for Dlar, ß-integrin remains localized to the terminals of actin bundles until late stages of oogenesis, primarily highlighting cell membranes parallel to the A-P axis. This continued association of ß-integrin with actin bundles throughout development is consistent with a role in actin filament formation and maintenance, as observed between stress fibers and focal adhesions (FAs) in cultured cells (Bateman, 2001).
The coupling of integrins to the cytoskeleton is mediated by a group of intracellular proteins that bind the cytoplasmic tails of receptors and interact with actin filaments. For example, members of the Vasodilator-stimulated phosphoprotein (VASP) family localize to FAs, where they are thought to regulate actin assembly. To explore the relationship between stress fibers and basal actin filaments of follicle cells, oocytes were stained with antibodies to the Drosophila VASP homolog Enabled (Ena). At early stages (stage 7-8), Ena is relatively diffuse throughout the cytoplasm, with little obvious concentration at cell membranes. However, at stages 10-12, significant Ena staining at actin filament terminals is observed, coinciding with the period of specific ß-integrin association with filaments. Staining was also observed along actin filaments that traverse the cell, consistent with the VASP family's proposed role in actin regulation. The association of actin bundles with multiple FA markers supports the hypothesis that the basal cytoskeleton of Drosophila follicle cells is analogous to stress fibers observed in vitro (Bateman, 2001).
Due to the association between actin filaments and ß-integrin in late-stage oocytes, it was asked if integrin staining was affected in cells within and surrounding Dlar mutant clones. Indeed, cells lacking Dlar show improper localization of integrin associated with a loss of F-actin polarity. ß-integrin staining remains highest at the filament terminals of mutant cells regardless of their orientation, resulting in a loss of staining at membranes parallel to the A-P axis. In some cases, ß-integrin staining shows no restriction to opposite sides of a cell as it does in the wild-type but instead appears generally distributed around the cell border (Bateman, 2001).
Because strong defects in ß-integrin localization are only observed in cells with actin defects, it is unclear whether these errors reflect a direct effect of Dlar on integrins or whether integrin localization is dependent upon prior orientation of F-actin by Dlar. To address this issue, it was asked whether integrins determine the polarity of basal actin filaments, which would suggest an upstream instructive role rather than a downstream dependence. Strong integrin mutants do not survive to adulthood, therefore, clones of mutant tissue were created. A screen for genes required in follicular development identified a mutation (968) with a round-egg phenotype indistinguishable from Dlar mutants; mapping data placed the insertion near the myospheroid (mys) locus encoding ß-integrin. The 968 mutant was shown to be allelic to mys by its failure to complement the allele mysnj42 and by loss of ß-integrin staining within 968 clones. As observed with Dlar, Texas Red-phalloidin staining of oocytes carrying mys968 clones shows disruptions in basal actin fiber polarity within mutant cells and in wild-type cells beyond the clonal boundary. Follicle cell clones of the independent allele mys10 also result in round eggs, confirming that integrins are required in follicle cells for elongation of the oocyte (Bateman, 2001).
Drosophila integrins function as heterodimers of a common ß subunit (mys) with a series of alpha subunits, creating functional receptors with different binding properties. For example, the alpha integrin encoded by multiple edematous wings (mew) is a receptor for laminin when combined with ß-integrin, while the alpha-integrin encoded by inflated (if) confers specificity to ECM components carrying the amino acid motif RGD. To determine if these ligands are relevant to integrin function in follicle cells, clones of if and mew were created. Rounded eggs were observed in oocytes with clones of either subunit, implying that both laminin and RGD components of the ECM are involved in mediating follicle cell control of oocyte shape (Bateman, 2001).
The similarity in phenotypes caused by loss of either Dlar or integrins suggests a cooperative relationship in organizing F-actin. To explore this, whether a genetic relationship exists between Dlar and mys was investigated. It was reasoned that the mild penetrance of round eggs in Dlar mutants may be sensitive to the dosage of genes in the same pathway. Indeed, removal of half of the gene dosage of mys in a Dlar null background causes a substantial increase in the penetrance of the round egg phenotype. For example, Dlar5.5/Dlar13.2 females show defective rounding in 14.1% of their stage 14 oocytes, while in mys1/+;Dlar5.5/Dlar13.2 females, the penetrance is increased nearly 4-fold to 48.7%. This enhancement is not due to changes in the overall fitness of mutant flies since Dlar mutants carrying the balancer TM6B, which decreases the viability of Dlar escapers, show little change in mutant oocyte penetrance (22.0% round stage 14 oocytes). Thus, genetic interactions support a model wherein Dlar and integrins cooperate in organizing basal actin filaments (Bateman, 2001).
Laminin is a common ligand for integrins in vertebrates. Since Scab mRNA is expressed in parts of the trachea throughout embryogenesis, antibodies to examine the trachea in wild-type, mys-, scb X5, scb X6, scb 2 and both scb deficiencies. To explore further the potential of laminin as a
ligand, lamA 9-32 mutant embryos were also examined for tracheal
defects. Embryos from each of the mutant stocks have significant gaps in the dorsal trunk of the trachea, which are not present in wild-type embryos. Due to the strong expression of alphaPS3 mRNA in the salivary glands throughout development, the glands of wild-type, mys - , scb X5 , scb X6 and scb 2 embryos were examined using a reporter gene. mys and scb embryos frequently show one gland to be misshapen and smaller than the other. The salivary gland is sometimes shifted closer to the midline. In conclusion, several defects are seen in scb mutant embryos, all of which are shared with mys and some with lamA; among them are defects previously reported in mys, but not in multiple edematous wings (aPS1) or inflated (aPS2) mutations. Noteworthy is the fact that these defects arise in areas where Scab is strongly expressed (Stark, 1997).
Migration of the Drosophila tracheal cells relies on cues provided by nearby cells; however, little is known about how
these signals specify a migratory path. The role of cell surface proteins in the definition of such a
pathway has been examined. The PS1 integrin is required in the tracheal cells of the visceral branch, whereas the PS2
integrin is required in the visceral mesoderm; both integrins are necessary for the spreading of the visceral branch over its
substratum. This is the first identification of a cell surface molecule with expression restricted to a subset of tracheal cells
that all migrate in a given direction. Expression of PS1 in the visceral branch is regulated by the genes that direct tracheal cell
migration, showing that integrin expression is part of the cell-fate program that they specify. These results support a model in which signal transduction
determines the tracheal migratory pathways by regulating the expression of cell surface proteins, which in turn interact with surface molecules on the
surrounding cell population (Boube, 2001).
Tracheal cells migrate over the visceral mesoderm to form the visceral branches, the ramifications of the tracheal tree that transport oxygen to the gut. They arise as small bulges in some of the centrally located pairs of tracheal pits (TP). In particular, visceral branches arise from six pairs of tracheal pits, TP2 and TP4 to TP8. A distinctive feature of these branches
is their direction of migration; whereas formation of the other primary
branches is guided by branchless (bnl) expression in small clusters of epidermal cells, the outgrowth of the visceral branch is directed
toward clusters of bnl-expressing cells in the mesoderm. At stage 11, the tracheal pits are located just over the clusters of the fat body precursor cells that are organized in metameric primordia. It
is between these discrete regions of fat body precursors that the cells
of the visceral branch contact the cells of the visceral mesoderm. Next, the cells of most visceral branches migrate anteriorly along the visceral mesoderm,
with the exception of some cells of the branch derived from TP8, which
migrate posteriorly. As development of the gut progresses,
the visceral branches remain in contact with the visceral mesoderm and
follow the convolutions that occur during formation of gut
constrictions. Subsequently, fine branches form at
positions in which visceral branches contact the gut (Boube, 2001).
Only the tracheal cells that will form the visceral branch establish
a distinct association with the visceral mesoderm. A mechanism to
explain such a specific association could involve particular cell
surface proteins being expressed in a complementary way in both the
visceral mesoderm substrate and the migrating tracheal cells. A similar scenario exists in which the visceral mesoderm serves as a substrate for the migrating primordial midgut cells. In this case, the migration requires a combination of PS1 and PS3 integrins in the migrating cells, and the PS2 integrin in the visceral mesoderm substratum. Integrins are a class
of cell surface molecules formed as heterodimers of two single-pass
type I transmembrane proteins, an alpha and a ß subunit. The Drosophila position-specific (PS) integrins are most similar to the ß1 family of vertebrate integrins, and one ßPS subunit is likely to form heterodimers with all five of the alphaPS subunits encoded by the Drosophila genome. As with the majority of integrins, the PS
integrins are thought to function by binding ligands within the
extracellular matrix. To see whether integrins might be playing a role
in tracheal migration, their expression in the tracheal
cells was examined. Around stage 11, the alphaPS1 mRNA is
specifically expressed in those tracheal cells that give rise to the
visceral branch, although weak expression is detected in the dorsal
cells. Localized expression in the visceral branch is more clearly evident at stage 12, during germ-band retraction, when the main branches appear as protrusions. alphaPS1 mRNA expression is maintained during stage 13 as the
visceral branch grows, and is lost by stage 14. Whether there is expression of the alphaPS2 subunit in the
tracheal cells was examined, and no expression was detected (Boube, 2001).
The specific expression of the alphaPS1 subunit prompted an analysis of
its role in the development of the visceral branch. The alphaPS1 subunit
is encoded by the multiple edematous wings (mew) gene. In mew mutant embryos the visceral branches fail to develop properly. Although the visceral branches migrate normally toward the gut and reach and contact the visceral mesoderm, they do not migrate normally along the
visceral mesoderm. At a stage when the cells of the visceral branches have migrated along the visceral mesoderm in wild-type embryos, in mew mutant embryos, the cells of the visceral branches remain at their initial points of contact
with the visceral mesoderm. Some delayed migration can also
be observed at later stages. Other aspects of visceral branch development are not affected in mew mutant embryos; for instance, the mispositioned visceral branches form fine branches later in development (Boube, 2001).
Since the PS2 integrin is expressed in the visceral mesoderm (the
substrate of visceral branch migration), it was asked whether PS2 integrin is
also required for visceral branch formation. The alphaPS2 subunit is
encoded by the inflated (if) gene and in if mutant embryos, visceral branch formation is also impaired. As is the case for mew mutant embryos, the visceral branches of if mutant embryos reach the visceral
mesoderm, but fail to migrate over it. However,
the defects are usually milder than in mew mutant embryos. Later branching is not affected. The defect in visceral branch formation in if mutant embryos is not due to a failure of bnl expression, as it appears at the right position in the visceral mesoderm (Boube, 2001).
Because both alphaPS1 and alphaPS2 subunits form heterodimers with the ßPS
subunit, mutations in the myospheroid (mys) gene
encoding this subunit will also simultaneously eliminate the PS1 and
PS2 integrins. The ßPS subunit is maternally deposited in the embryo, and,
therefore, to examine the effect of complete loss of the ßPS subunit,
embryos were generated lacking both maternal and zygotic
mys expression by making germ-line clones (referred to
as mys mutant embryos). All mys mutant embryos exhibit a failure in the migration of the cells of the visceral branches along the visceral mesoderm similar to those observed in the alphaPS mutants. However, in
mys mutant embryos, some visceral branches detach from the
visceral mesoderm, suggestive of a more extensive failure in
the establishment of cell-cell interactions than in mutants for
individual alphaPS subunits. Some mys- embryos also
show gaps in the dorsal trunk, the more prominent branch of the
tracheal tree, and defects in the dorsal branches. Thus, the
loss of all PS integrins produces stronger migration defects than the
loss of alphaPS1 or alphaPS2 individually (Boube, 2001).
The above results suggest that PS1 (alphaPS1ßPS) integrin is required
in the migrating cells of the visceral branches, and PS2 (alphaPS2ßPS)
integrin, in the visceral mesoderm substrate. If this is the case, it should be possible to rescue the visceral branch phenotype of mutant
embryos for each alpha subunit by expressing the appropriate subunit
specifically in the cell population in which it is required. Expression of alphaPS1 just in the tracheal cells can rescue the visceral branch phenotype of the mew (alphaPS1-) mutant embryos, although it causes some
defects in the other branches. Similarly, the visceral
branch phenotype of if (alphaPS2-) mutant embryos can
be rescued by targeted expression of alphaPS2 just in the mesodermal
cells. These results rule out the possibility that the
defects in the visceral branches observed in integrin mutants are due
to secondary consequences of disruption of other tissues. Furthermore,
they also show that migration of the visceral branches requires the
coordinated functions of PS1 integrin in the visceral branch and PS2
integrin in the visceral mesoderm (Boube, 2001).
Whether the complementary expression of these two
integrins is essential for tracheal migration was tested. The specific
requirement of PS1 in the tracheal cells of the visceral branch was analyzed by
assessing whether the PS2 integrin could fulfill the role of PS1. Expression of alphaPS2 in the tracheal cells does not rescue
the defects in visceral branch migration caused by the lack of alphaPS1
in mew mutant embryos. This result indicates that
PS1 function in particular, rather than PS integrin function in
general, is required in the cells of the visceral branch for them to
migrate along the visceral mesoderm. In contrast, expression of alphaPS1 in place of alphaPS2 in the mesoderm does substantially rescue the visceral branch phenotype caused by lack of alphaPS2. This finding suggests that either integrin can assemble a suitable substrate for PS1-dependent tracheal migration (Boube, 2001).
Previous clonal analysis has shown that cell lineage does not play
an important role in the specification of the distinct identity of the
different tracheal cells. Instead, different
signaling pathways act to spatially subdivide the tracheal placode by
inducing groups of cells to migrate in a particular direction and
acquire a specific morphology. This inductive process appears to be
mediated by the differential activation of a set of transcription
factors in discrete groups of tracheal cells. Therefore,
whether these transcription factors regulate the specific expression of
the alphaPS1 subunit was examined (Boube, 2001).
The transcription factors knirps (kni) and
knirps-related (knrl) are expressed in overlapping
patterns during tracheal development in which they share redundant
functions. They are both required in two phases of tracheal
development. The initial tracheal expression of kni/knrl
appears around stage 10 and their activity is required early in the
tracheal placode for primary branching outgrowth. Subsequently,
kni/knrl expression becomes restricted to some branches, among
them the visceral branches, and they are required for the directed
outgrowth of these tracheal branches. Since kni and knrl share redundant functions, an examination was made of mutant embryos homozygous for a deficiency that uncovers both genes and whose effect on tracheal development is due solely to the lack of
kni and knrl. In this mutant
background, it was found that alphaPS1 is no longer expressed in the tracheal
cells, indicating that these genes act as positive regulators of alphaPS1. To further assess the specific role of the late expression of kni/knrl in the expression of alphaPS1 in the visceral branch, a mutant
combination was examined that provides the segmentation and early tracheal
kni expression, but not the later branch-specific expression
of kni. In these mutant embryos, there are also defects in visceral branch development and expression of alphaPS1 is either absent or very much reduced. Thus, the late phase of kni/knrl
branch-specific expression is specifically required for the proper
expression of alphaPS1 in the cells of the visceral branches. However,
kni/knrl are not sufficient to drive alphaPS1
expression, as they are expressed in other branches that do not express
alphaPS1. Similarly, the alphaPS1 gene is not the only target of these
transcription factors, since GAL4-driven expression of alphaPS1 is not able
to rescue the phenotype of the deficiency (Boube, 2001).
Another transcription factor that has an important role in specifying
cell fate within the tracheal branches is encoded by spalt
(sal). The expression of sal is restricted to the
dorsal cells in the developing tracheal tree. By stage 12, sal
is expressed only in the dorsal parts of the tracheal metameres, that
is, in the cells of the dorsal trunk and the dorsal branches. By stages 14 and 15, sal expression declines in the cells of the dorsal branches, but remains high in the cells of the dorsal trunk. In sal mutant embryos there is ectopic expression of alphaPS1 in the cells of the dorsal trunk and in the dorsal branches, indicating that sal
activity is required to inhibit alphaPS1 expression in the dorsal
tracheal structures. In summary, these results indicate that alphaPS1
expression is restricted to the cells of the visceral branches by the
direct or indirect activities of the transcription factors that
spatially subdivide the tracheal placode. The fact that alphaPS1
expression is regulated by the same genes that specify a particular
cell fate, rather than independently, suggests that integrin expression is an important part of the cell fate decision (Boube, 2001).
To investigate the functional significance of the restricted
expression of PS1, whether it is important that the other
tracheal branches do not express the PS1 integrin was examined. The
expression of alphaPS1 construct was induced in all of the tracheal cells and
several defects were found in tracheal development, mainly in the dorsal branches. In wild-type embryos, each dorsal branch grows toward the dorsal
midline, where it meets and fuses with the dorsal branch coming from
the contralateral hemi segment. However, in embryos with ubiquitous
tracheal alphaPS1 expression, many dorsal branches fail to fuse with
their contralateral counterpart or fuse with an inappropriate branch. Occasional interruptions are seen in the dorsal trunk of
these embryos. However, no redirection
of migration is observed in this situation. These results suggest that different groups of tracheal cells need
to express different distinct adhesion molecules to migrate on the
correct substrate. If this is the case, one would expect changes in the
migratory behavior of these cells to be accompanied by changes in the
expression of the adhesion molecules. A change in the path of migration
of some tracheal cells has been observed in particular mutant
combinations of the wingless (wg) pathway. The
wg pathway is required for the formation of the dorsal trunk,
and upon ubiquitous tracheal activation of the wg pathway, cells that would normally contribute to the visceral branch appear to
adopt a dorsal trunk fate and change their path of migration accordingly. As a result, the dorsal trunk becomes larger and fewer cells migrate along the
visceral mesoderm. In these mutant embryos, fewer cells
express alphaPS1. Thus, the signaling pathways that mediate the
choice between alternative paths of migration regulate the appropriate
expression of adhesion molecules in subsets of the tracheal cells (Boube, 2001).
It has been shown that the alternative migratory pathways of
the tracheal cells are associated with distinct subsets of mesodermal
cells. This study provides the first identification of cell surface receptors that mediate these specific interactions. These results support a model in which signaling by transduction pathways specifies the particular migratory pathways of
tracheal cells by regulating a precise array of adhesion proteins such
as integrins at their surface. This can be a very general mechanism to regulate integrin expression in distinct subpopulations of cells within a wider field. For instance, many genes operating in the morphogenesis of the insect tracheal system
and in the vertebrate lung are functionally conserved despite the
important differences that exist between the two systems. In this scenario, it is worth noting that distinct integrin subunits are differentially expressed in the cells involved in mesenchymal/epithelial interactions during lung development. Thus, as in the case of the Drosophila tracheal
system, control of cell surface molecules by signaling pathways in
other systems may be involved in the mechanism conferring the specificity of cell-cell adhesions in migration and in other biological processes (Boube, 2001).
Epithelial tubes that compose many organs are typically long lasting,
except under specific developmental and physiological conditions when network
remodeling occurs. Although there has been progress elucidating mechanisms of
tube formation, little is known of the mechanisms that maintain tubes and
destabilize them during network remodeling. This study describes Drosophila
tendrils mutations that compromise maintenance of tracheal terminal
branches, fine gauge tubes formed by tracheal terminal cells that ramify on
and adhere tightly to tissues in order to supply them with oxygen. Homozygous
tendrils terminal cell clones have fewer terminal branches than
normal but individual branches contain multiple convoluted lumens. The
phenotype arises late in development: terminal branches bud and form lumens
normally early in development, but during larval life lumens become convoluted
and mature branches degenerate. Their lumens, however, are retained in the
remaining branches, resulting in the distinctive multi-lumen phenotype.
Mapping and molecular studies demonstrate that tendrils is allelic to
rhea, which encodes Drosophila talin, a large cytoskeletal
protein that links integrins to the cytoskeleton. Terminal cells mutant for
myospheroid, the major Drosophila ß-integrin, or doubly
mutant for multiple edematous wings and inflated
α-integrins, also show the tendrils phenotype, and localization
of myospheroid ß-integrin protein is disrupted in
tendrils mutant terminal cells. The results provide evidence that
integrin-talin adhesion complexes are necessary to maintain tracheal terminal
branches and luminal organization. Similar complexes may stabilize other
tubular networks and may be targeted for inactivation during network
remodeling events (Levi, 2006; full text of article).
The defects observed in the gynandromorphs of myospheroid demonstrate widespread
requirements for PS integrins during development especially in ventrally derived structures, which
also show strong expression of betaPS integrin. Smaller myospheroid clones induced
during larval development result in blister and vein defects in the wings and aberrant development
of photoreceptor cells, demonstrating roles for PS integrins during development of both wings and
eyes. PS integrins are required for the close apposition of the dorsal and ventral wing epithelia and
for the proper arrangement of photoreceptor cells. However, many other differentiation processes proceed normally in the absence of integrins containing Myospheroid (Zusman, 1990).
blistered, coding for Drosophila serum response factor is required during metamorphosis for the initiation of intervein development and
the concomitant inhibition of vein development.
Integrin mutants interact with blistered mutants to increase the frequency of intervein
blisters but do not typically enhance vein defects (Fristrom 1994)
Morphogenesis of the Drosophila wing depends on a series of cell-cell and cell-extracellular matrix interactions. During pupal wing development, two secreted proteins, encoded by the short gastrulation (sog) and decapentaplegic (dpp) genes, vie to position wing veins in the center of broad provein territories. Expression of the Bmp4 homolog dpp in vein cells is counteracted by expression of the secreted Bmp antagonist sog in intervein cells, which results in the formation of straight veins of precise width. A screen was performed for genetic interactions between sog and genes encoding a variety of extracellular components and interactions were uncovered between sog and myospheroid (mys), multiple edematous wing (mew) and scab (scb), which encode ßPS, alphaPS1 and alphaPS3 integrin subunits, respectively. Clonal analysis reveals that integrin mutations affect the trajectory of veins inside the provein domain and/or their width and that misexpression of sog can alter the behavior of cells in such clones. In addition, a low molecular weight form of Sog protein has been shown to bind to alphaPS1ßPS. Sog can diffuse from its intervein site of production into adjacent provein domains, but only on the dorsal surface of the wing, where Sog interacts functionally with integrins. Finally, it has been shown that Sog diffusion into pro-vein regions and the reticular pattern of extracellular Sog distribution in wild-type wings requires mys and mew function. It is proposed that integrins act by binding and possibly regulating the activity/availability of different forms of Sog during pupal development through an adhesion independent mechanism (Araujo, 2003).
Because diffusion of Sog into provein domains is restricted to the dorsal surface of the wing where integrins interact with Sog, it was asked whether integrins play a role in regulating the distribution of Sog protein on the dorsal surface of pupal wings. Marked mys minus or mew minus clones were generated in an otherwise wild-type background and Sog staining was examined. In control wings, double-labeling with anti-ß integrin and anti-Sog antisera confirmed that the dorsally restricted pattern of reticular Sog staining extends beyond ß-integrin staining into provein domains. By contrast, Sog staining has a patchy intracellular appearance in dorsal mys minus clones, and is excluded from wild-type provein cells on the dorsal surface that are adjacent to mys minus clones. In such cases where mys minus clones are located on one side of a provein domain, Sog is still able to enter the provein region from the opposite mys+ side of the same vein. These results demonstrate that mys is required for diffusion or transport of Sog into the vein competent domain. Consistent with the observation that only dorsally located integrin minus clones can alter the course of veins, it was found that only dorsal mys minus clones modify Sog distribution in the pupal wing. Similarly altered Sog staining was observed within mew minus clones on the dorsal wing surface resulting in punctate rather than reticular staining and lack of Sog diffusion into the provein region. These results demonstrate that the ßPS and alphaPS1 integrins play an important role in determining the distribution of Sog protein in the pupal wing (Araujo, 2003).
In this study, three primary lines of evidence are provided that integrins play an important role in regulating Bmp signaling in provein regions of the pupal wing: (1) integrin minus clones generated on the dorsal surface of the wing alter the trajectory and/or width of adjacent veins; (2) a truncated form of Sog present in pupal wings binds to alphaPS1; (3) diffusion of Sog into provein domains, which is restricted to the dorsal surface of the wing, depends on integrin function. Cumulatively, these results strongly suggest that the ability of Sog to diffuse or to be transported into provein regions on the dorsal surface depends on an interaction with integrins (Araujo, 2003).
Consistent with Sog interacting genetically with integrins to alter the course of veins on the dorsal surface of the wing, it was found that the alphaPS1 and ßPS-integrins are required for the diffusion or transport of Sog from dorsal intervein cells where sog mRNA is expressed into adjacent provein regions. Since alphaPS1 binds Sog, this physical interaction may contribute to regulating the distribution of Sog. The 8B anti-Sog antiserum used in this study, that recognizes Sog protein in intervein cells and inside the provein domain, detects an epitope located near the second cystein repeat (CR2). Consequently, Sog fragments that diffuse or that are delivered to provein cells must be either full length, which weakly binds to alphaPS1 in co-immunoprecipitation experiments, or fragments that contain CR2. The truncated Supersog-like fragment that binds strongly to alphaPS1 in coimmunoprecipitation experiments should not be recognized by the 8B antiserum. Therefore, integrins may differentially regulate the distribution of Sog fragments on the dorsal surface of the pupal wing, restraining the movement of broad spectrum Bmp inhibitory Sog fragments (such as Supersog-like molecules) and allowing or mediating transport of other fragments to provein cells, such as full-length Sog, which also has a vein inhibitory function. Unfortunately, it is not possible currently to examine the diffusion of Supersog-like fragments directly because the 8A antiserum is not suitable for staining pupal wings. These findings suggest that integrins regulate the delivery or diffusion of active Sog protein from intervein cells into the vein competent domain. In contrast to the dorsally restricted functions of integrins required for vein development, the adhesive functions of integrins depends on subunits functioning on both surfaces of the wing (Araujo, 2003).
There are several possible mechanisms by which interaction with integrins could modulate Sog activity in pupal wings. Elevated sog expression results in vein truncation, while misexpression of dpp induces ectopic veins, indicating that sog restricts vein formation by opposing Bmp signals emanating from the center of the vein (Yu, 1996). One possibility is that such a Bmp inhibitory form(s) of Sog must interact with integrins in order to diffuse or be transported into provein domains (on the dorsal surface of the wing only). This hypothesis would be consistent with the finding that veins appear to be attracted to integrin minus clones. Such a vein repulsive form(s) of Sog would presumably act as a Bmp antagonist (Araujo, 2003).
According to the simple model in which integrins are essential for delivering a Bmp inhibitory form of Sog to provein cells, one would expect that integrin minus and sog minus clones would generate similar phenotypes in which veins deviated towards the mutant clones and/or broadened within them. However, sog minus clones induce meandering of veins (Yu, 1996) -- veins show only a weak tendency to track along the outside of sog minus clones, in contrast to integrin minus clones, which bend or widen veins in a more dramatic fashion. One possible explanation for the differences between the sog minus and integrin minus phenotypes is that there are several different endogenous forms of Sog in pupal wings, which might exert opposing activities. If multiple Sog fragments exert effects on vein development, some providing repulsive and others attractive activities on vein formation, the differences between the behaviors of sog- and integrin- clones could be explained by a repulsive (Bmp inhibitory) form(s) of Sog selectively requiring an interaction with integrins. The possibility that a positive Bmp-promoting activity of Sog might also be present that acts as a vein attractant has precedent in that a positive Sog activity has been proposed to explain a requirement for Sog in activating expression of the Dpp target gene race in early embryos. Structure/function studies of Sog have also revealed a potential Bmp promoting form of Sog, which is longer than Supersog forms. According to this model, altering the balance between repulsive and attractive Sog activities would generate different vein phenotypes. In the total absence of sog, both repulsive and attractive activities would be lost, generating a mild meandering vein phenotype in which neither attraction nor repulsion clearly dominates, as is observed in sog minus clones (Yu, 1996). If an interaction with integrins were required only for production or delivery of Bmp inhibitory forms of Sog into the vein, then integrin minus clones, which still contain the Bmp-activating forms of Sog, could exert a net attractive influence on veins, leading to more pronounced deviation of veins toward the clones. This hypothesis is consistent with vein phenotypes observed associated with integrin minus clones that cross over veins or run along both sides of the vein, such as narrowing, bending and wandering of veins; these phenotypes are similar to those observed in correspondingly located sog minus clones. The existence of different Sog fragments bearing opposing activities would also explain the different phenotypes obtained upon ectopic Sog expression in some sogEP lines (Yu, 1996), such as sporadic ectopic vein material between L3 and L2 and meandering L2 veins in addition to vein loss in other areas (Araujo, 2003).
Another possible explanation for the differences between the sog minus and integrin minus phenotypes is that integrins may regulate the activity of extracellular signals in addition to Sog. One hint of such an activity is that when a scb minus clone falls within the provein area, the vein splits around the border of the clone in a cell autonomous fashion. Since this later phenotype is enhanced by ectopic sog expression in veins (e.g., in a sogEP background), alphaPS3 may normally promote Bmp signaling within the vein. Although the identity of such potential targets is unknown, candidates would include Bmps (e.g. Dpp or Gbb) or Bmp receptors. Further analysis will be needed to explain the basis for the different behaviors of sog minus and integrin minus clones, as well as the variations observed in different integrin minus clones (Araujo, 2003).
In summary, it is proposed that Sog fragments with differential activities may regulate vein formation. The vein bending phenotype observed in the absence of alphaPS1 would result from a remaining attractive Sog activity that outweighs the activity of a repulsive form of Sog, which can no longer be delivered from intervein cells. Since ßPS integrin forms heterodimers with both alphaPS1 and alphaPS3 mys would be expected to be required for the activity of both alphaPS chains. Consistent with this expectation, the phenotype of mys minus clones (i.e., broad poorly defined veins) resembles a hybrid of those observed for mew minus and scb minus clones (Araujo, 2003).
Endocytosis has been shown to play an important role in the establishment of Bmp activity gradients. The endocytic pathway has been implicated in transport of Dpp between cells by transcytosis during larval wing development. During early embryonic development, formation of a Sog protein gradient in dorsal regions also relies on the action of Dynamin, although in this preblastoderm context, it has been proposed that endocytosis limits the dorsal diffusion of Sog, which is essential for