National Centre for Biological Sciences, Tata Institute of Fundamental Research, Bangalore 560012, India
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Abstract |
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Pattern formation in muscle development is often mediated by special cells called muscle organizers. During metamorphosis in Drosophila, a set of larval muscles function as organizers and provide scaffolding for the development of the dorsal longitudinal flight muscles. These organizers undergo defined morphological changes and dramatically split into templates as adult fibers differentiate during pupation. We have investigated the cellular mechanisms involved in the use of larval fibers as templates. Using molecular markers that label myoblasts and the larval muscles themselves, we show that splitting of the larval muscles is concomitant with invasion by imaginal myoblasts and the onset of differentiation. We show that the Erect wing protein, an early marker of muscle differentiation, is not only expressed in myoblasts just before and after fusion, but also in remnant larval nuclei during muscle differentiation. We also show that interaction between imaginal myoblasts and larval muscles is necessary for transformation of the larval fibers. In the absence of imaginal myoblasts, the earliest steps in metamorphosis, such as the escape of larval muscles from histolysis and changes in their innervation, are normal. However, subsequent events, such as the splitting of these muscles, fail to progress. Finally, we show that in a mutant combination, null for Erect wing function in the mesoderm, the splitting of the larval muscles is aborted. These studies provide a genetic and molecular handle for the understanding of mechanisms underlying the use of muscle organizers in muscle patterning. Since the use of such organizers is a common theme in myogenesis in several organisms, it is likely that many of the processes that we describe are conserved.
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Introduction |
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MANY major themes of developmental biology are illustrated by the formation of skeletal muscles. Myogenesis involves a precisely choreographed sequence of cell lineage-dependent specification, cell proliferation, migration, cell-cell interactions, and differentiation. Multinucleated muscle fibers arise from the fusion and differentiation of mononucleated progenitors, myoblasts. Muscle fibers differ from each other in their position, innervation, patterns of gene expression, and physiological properties. Myoblasts must be able to seek out epidermal sites of muscle formation, fuse to form properly oriented fibers, and get appropriately innervated to give rise to the precise pattern that is observed in the mature animal. One way to understand how such diversity is generated and how muscle pattern is organized is to systematically screen for mutations that affect different developmental stages of particular muscle fibers and then analyze what roles these genes play during the normal development of these muscles.
A system ideally suited for such analyses are the indirect
flight muscles (IFMs)1 of the fruit fly Drosophila melanogaster. The two groups of the IFMs, the dorsal longitudinal
muscles (DLMs) and the dorso-ventral muscles (DVMs)
have distinct developmental histories: the DLMs develop
using persistent larval muscles as scaffolds (Tiegs, 1955; Shatoury, 1956
; Shafiq, 1963
; for review see Crossley,
1978
), whereas the DVMs are constructed de novo by the
fusion of imaginal myoblasts (Fernandes et al., 1991
). The
availability of several reporter genes and antibody probes
that label to reveal different stages of development of these
muscles (Fernandes et al., 1991
; Barthmaier and Fyrberg,
1995
), their innervation (Fernandes and VijayRaghavan,
1993
), and attachment (Fernandes et al., 1996
), thus provide
important tools for a molecular and genetic analysis of the
mechanism of their development (Fernandes et al., 1994
; DeSimone et al., 1996
; Roy and VijayRaghavan, 1997
; Roy
et al., 1997
; Sandstrom et al., 1997
).
The progenitors of the IFMs are associated with the
wing imaginal disc during larval life and, during early pupation, these myoblasts divide and spread over the developing dorsal mesothorax at the sites of muscle formation
(Bate et al., 1991; Fernandes and VijayRaghavan, 1993
).
At the onset of pupation, while all other larval muscle fibers in the thoracic segments undergo histolysis, three
muscles, dorsal oblique 1, 2, and 3 persist and split into six
templates that serve as scaffolds for DLM development
(for larval muscle nomenclature see review by Bate, 1993
).
Further fusion of myoblasts with these templates results in
the elaboration of the final DLM pattern of six fibers
(Fernandes et al., 1991
). These early events in the development of the DLMs are summarized diagrammatically in
Fig. 1. The transformation of larval muscles into DLM
templates is best visualized by staining for
-galactosidase activity that perdures after larval expression of the enzyme
from the myosin heavy chain (MHC) promoter has ceased
(Fernandes et al., 1991
). During early pupation, at ~10-12 h
after puparium formation (APF), the persistent larval
muscles appear vacuolated (see Fig. 2 a). These vacuoles
are probably the surface blebbing described in early studies of the transformation of these muscles, and of similar
muscles in other dipterans (for review see Crossley, 1978
).
Subsequently, at ~15 h APF, each muscle fiber splits
along its longitudinal axis, the dorsal-most muscle splitting
last, resulting in the formation of six templates (see Fig. 2
b). At the time these changes take place in the larval muscles, metamorphic changes occur in the motor nerves that
innervate these muscles. The motor innervation of the persistent larval muscles that form part of the intersegmental
nerve fiber withdraw their neuromuscular synaptic contacts and, as the muscles split and myoblasts fuse to form
the DLM fibers, new axonal branches develop to innervate them (see Fig. 1; also see Fernandes and VijayRaghavan, 1993
). An analogous series of events that delineate
the attachment of the DLM fibers to the epidermis with
particular reference to the stripe gene has been described
(Fig 1; also see Fernandes et al., 1996
) and a detailed and
critical electron and light microscopic analysis of this process is also available (Reedy and Beall, 1993b
).
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The role of the persistent larval muscles in the development of the DLMs has been addressed systematically only
recently. Laser ablation experiments have suggested that
although DLM development can proceed apparently normally in their absence, the larval muscles are required for
regulating the numbers of DLM fibers formed, and in this
sense are important in determining certain aspects of pattern in the developing DLMs (Farrell et al., 1996; Fernandes and Keshishian, 1996
). The molecular mechanisms involved in the splitting of the larval muscles into templates
for DLM development are unknown. From the sequence
of events and interactions of various tissues alluded to
above, at least three mechanisms, not mutually exclusive,
appear plausible: (a) the splitting process is an autonomous property of the persistent larval muscles, additionally involving its interaction with the epidermis and perhaps even the nervous system, but not the imaginal myoblasts
themselves; (b) inductive instructions from the metamorphosing motor nerves mediate splitting and are essential
for the process to proceed. The close apposition of myoblasts and nerves, both in larval life as evidenced by nerve-associated myoblasts in the thorax and during pupal development (Fernandes and VijayRaghavan, 1993
) further
strengthen this possibility; and (c) interactions with imaginal myoblasts are essential, and somehow engender the
transformation of these muscles.
In this study we show that the transformation of residual larval muscles during DLM development is mediated by the activity of imaginal myoblasts and is not an autonomous property of the larval muscles themselves. We show that the Erect wing (Ewg) protein is expressed in larval muscle nuclei remaining in the developing adult fiber. This, and the absence of splitting in an ewg mutant combination, suggests that myoblasts and templates interact actively to pattern the DLM fibers. Our results throw light on the cellular processes involved in the early morphogenetic events of a set of adult muscles in Drosophila that develop using muscle organizers, and sets the stage for the identification and analysis of other genes that regulate such processes.
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Materials and Methods |
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Fly Strains
The Canton S strain was used as the wild-type strain in all control experiments unless otherwise mentioned. The MHC-lacZ transgenic strain contains the regulatory regions of the Drosophila muscle MHC gene fused to
the lacZ reporter and is expressed in all embryonic, larval, and adult muscle fibers (Hess et al., 1989; Fernandes et al., 1991
). The actin (88F)-lacZ
strain has an in-frame gene fusion of the IFM-specific actin (88F) gene to
the lacZ gene (Hiromi et al., 1986
; Fernandes et al., 1991
). The twist-lacZ
transformant strain carries a transgene that consists of the regulatory domains of the twist gene fused to the lacZ gene (Thisse et al., 1991
; DeSimone et al., 1996
).
The X chromosome 1151-GAL4 enhancer trap strain was obtained
from L.S. Shashidhara (Centre for Cellular and Molecular Biology, Hyderabad, India) and its expression pattern was examined by using the reporter strain upstream activating sequence UAS-lacZ (Brand and Perrimon, 1993). We have found that this strain can drive
-galactosidase
expression from this reporter in the adult muscle precursors associated
with the imaginal discs and nerves in the larvae, and in almost all the developing and differentiated adult muscle fibers (Roy and VijayRaghavan,
1997
; Anant et al., 1998
).
The UAS-p21 strain was kindly provided by I. Hariharan (Massachusetts General Hospital Cancer Centre, Charlestown, MA). This strain carries a transgene insert on the X chromosome that consists of a cDNA of
the human cyclin dependent kinase inhibitor p21 gene (Harper et al., 1993)
placed under the control of the GAL4 protein-responsive UAS.
Two different strains containing a null allele of ewg (ewgl1)were used:
ewgl1, y, cho, sn; NS4 and ewgl1, y, w, sn; NS4. NS4 represents a transgene
that consists of an ewg cDNA under the control of the regulatory regions
of the Drosophila neuron-specific gene embryonic lethal abnormal visual
system (DeSimone et al., 1996). This transgene provides ewg vital function
that is required in neurons for embryonic viability, and since its expression
is restricted only to neurons, the presence of this transgene in the background of the ewgl1 null allele effectively produces an ewg null condition
in the mesoderm.
Antibody Labeling and -Galactosidase Histochemistry
Pupal and larval tissues were prepared for immunohistochemistry as described previously (Fernandes et al., 1991). Anti-Ewg antibody raised in
rabbit was used at a dilution of 1:500 (DeSimone et al., 1996
), an anti-
-galactosidase monoclonal antibody (Promega Corp., Madison, WI) was used at
a dilution of 1:250, an anti-Twist antibody raised in rabbit (gift of S. Roth,
Max Planck Institute, Tübingen, Germany) was used at a dilution of 1:5,000
and an antihorseradish peroxidase antibody raised in rabbit (Sigma
Chemical Co., St. Louis, MO), was used at a dilution of 1:4,000. The labeling reactions were developed using either the Vectastain ABC immunoperoxidase kit (Vector Labs, Inc., Burlingame, CA) according to the manufacturer's instructions, or using appropriate fluorophore-conjugated
secondary antibodies (Jackson ImmunoResearch Laboratories, Inc., West
Grove, PA). Histochemical staining for
-galactosidase expression was done according to standard procedures (Fernandes et al., 1991
).
Microscopy
After antibody labeling and -galactosidase histochemistry, tissue preparations were mounted in 75% glycerol and examined using a Leitz Aristoplan microscope (Wetzlar, Germany) equipped with Nomarski (differential interference contrast) optics or laser scanning confocal microscopy
(MRC-600; Bio-Rad Laboratories, Hercules, CA) using a Zeiss Axiophot
microscope (Carl Zeiss, Inc., Thornwood, NY).
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Results |
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Postfusion Columnar Organization of Ewg-expressing Myoblast Nuclei Marks the Onset of DLM Differentiation
Our earlier studies have shown that the ewg gene is required for IFM development (DeSimone et al., 1996).
These experiments also showed that ewg expression can
be detected in the imaginal myoblasts as early as 10 h APF
when these cells are swarming over the persistent larval
muscles. We therefore used antibodies to the Ewg protein
to label myoblasts and antibodies to
-galactosidase to label the persistent larval muscles in pupae of flies expressing the reporter enzyme from the MHC promoter to examine the process of splitting more closely. Optical
sections of double-labeled pupal preparations with antibodies to Ewg and
-galactosidase at 10-12 h APF revealed Ewg expression in the nuclei of the imaginal myoblasts that have fused with the larval muscles (Fig. 3 a). Similar labeling experiments at a later developmental
stage (15-16 h APF) showed Ewg-expressing myoblast nuclei and associated cytoplasm organizing themselves into
two neat longitudinal columns in each larval muscle (Fig. 3
b). These longitudinal columns of imaginal myoblast nuclei with the associated cytoplasm actually represent the
splitting larval muscles that are observed on histochemical staining for
-galactosidase in the MHC-lacZ transformant strain (Fig. 2 b; also see Fernandes et al., 1991
).
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Ewg and Actin (88F)-lacZ Labeling Reveal That the Columnar Organization of Nuclei Are Early Differentiating DLMF Fibers
The splitting of the persistent larval muscles can also be
revealed using histochemical staining for -galactosidase
expression from the actin (88F) promoter that is first expressed at ~14-15 h APF in the splitting larval muscles
(Fig. 3 c; Fernandes et al., 1991
). This actin gene is predominantly expressed in the IFMs, and the initiation of the
actin (88F)-lacZ reporter activity is an indication of the
onset of flight muscle differentiation programme (Hiromi
et al., 1986
; Fernandes et al., 1991
). Double-labeling experiments with antibodies specific to Ewg and
-galactosidase on 14-15 h APF pupae carrying the actin (88F)-lacZ
transgene revealed that the longitudinal columns that
form by the aggregation of Ewg-expressing nuclei actually
represent nascent myofibers that have begun to differentiate and express the actin (88F) gene (Fig. 3 d). This analysis of the behavior of Ewg expressing myoblasts during
early stages of DLM development suggests that the process of larval muscle splitting involves myoblast fusion
with the persistent larval muscles, and the organization of
their nuclei into longitudinal columns with the associated
cytoplasm, followed by the expression of structural components of the myofiber.
Larval Muscle Nuclei Do Not Degenerate and Express Ewg during Metamorphosis
Interestingly, Ewg expression is seen in the nuclei of the
larval muscles themselves during early development of the
DLMs (refer to Fig. 3 a). The polyploid larval muscle nuclei are larger than imaginal myoblast nuclei and can be
easily distinguished from the latter (Crossley, 1978). During development of the DLMs, the larval muscle nuclei
align themselves with the columns of imaginal nuclei in the
cytoplasm of the larval muscles as they split into two longitudinal strands enveloping the nuclei (refer to Fig. 3, b and d).
At the very least, these results identify larval nuclei as
present during adult muscle development and show that
the remnant larval muscles are not mere bags of membrane. In addition, they suggest that these nuclei may not
merely have the ability to localize Ewg protein from fusing
myoblasts, but perhaps themselves are transcriptionally active. These possibilities are discussed later (see Discussion).
Larval Muscles Do Not Split in Absence of Imaginal Myoblasts
Imaginal myoblasts, specified in the embryo, divide actively during larval life to produce large clusters of cells
that remain associated with the imaginal discs and motor
nerves innervating larval muscles (Bate et al., 1991; Fernandes and VijayRaghavan, 1993
). During pupal development, these cells exit from cell cycle and fuse to form adult
muscles. To investigate the role of imaginal myoblasts in
the splitting of the larval muscles into DLM templates, we
selectively eliminated these cells during larval development by inhibiting their proliferation. To do this, we ectopically expressed a cell cycle inhibitor protein, the human cyclin dependent kinase inhibitor, p21 (Harper et al.,
1993
), in proliferating imaginal myoblasts during larval
life. A previous study has shown that p21, when ectopically
expressed in dividing precursor cells in the eye imaginal
disc of Drosophila, can strongly inhibit their proliferation (de-Nooij and Hariharan, 1995
). We have used the GAL4-UAS system (Brand and Perrimon, 1993
) to target p21 expression to imaginal myoblasts during early larval development using an enhancer-trap GAL4 strain 1151 (refer to
Materials and Methods and the references therein on the
characterization of the domains of expression of 1151) and
a UAS-p21 transgene. The effect of p21 misexpression on
the proliferation of myoblasts associated with wing imaginal discs was assayed using the twist-lacZ reporter gene
and also with antibodies raised against the Twist protein. Ectopic expression of p21 in the wing disc-associated myoblasts strongly inhibited their proliferation, and very few
cells on the wing discs of late third instar larvae labeled
with the above markers were detected (Fig. 4, a-d). Similar results were obtained when these discs were labeled with antibodies against the Cut protein that is expressed in
the disc-associated adult myoblasts in a pattern similar to
Twist (Blochlinger et al., 1993
; data not shown). These observations demonstrate the efficacy of ectopic expression
of p21 in arresting division and thereby eliminating the
bulk of imaginal myoblasts.
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We next examined the effects of myoblast depletion on
transformation of the persistent larval muscles into DLM
templates. First, the larval muscles escape histolysis as in
the normal development, indicating that this process is not
mediated by myoblasts. This is pertinent because the 1151 driver is also expressed in nerve-associated myoblasts, although not in larval muscles themselves (Anant et al.,
1998). Examination of 1151/UAS-p21 pupae at ~16 h APF
revealed that, in the absence of myoblasts, the splitting
process was inhibited (Fig. 5 a). Using antibodies against
the Ewg protein few, if any, myoblasts were found to be associated with these muscles (Fig. 5, b and c). At a slightly later time in development, the muscles degenerated (data
not shown). This result suggests that the transformation of
the larval muscles into templates for DLM development is
mediated by interactions with imaginal myoblasts and is
not an autonomous property of the larval muscles themselves. It also emphasizes the fact that the predominant
function of the persistent larval muscles could be to function as positional cues for the imaginal myoblasts for DLM
development, and they are, by themselves, incapable of
developing into even rudimentary adult muscles although
they have remnant larval nuclei and are innervated.
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Larval Muscles Do Not Split in an Ewg Mesoderm-null Mutant
The accessibility, with antibody probes and reporter genes,
of cellular events involved in the early stages of DLM patterning using larval organizers led us to investigate the
possible genetic basis of this elaborate process. The close
correspondence of the spatio-temporal expression of ewg
and the transformation events in the larval muscles prompted
us to investigate the role of this gene in larval muscle splitting. ewg has a sustained and ubiquitous expression in all
postmitotic neurons in the embryo, and this expression is
essential for embryonic viability (DeSimone and White,
1993; DeSimone et al., 1996
). To examine the role of ewg in flight muscle development, we had constructed a transgenic strain (ewgl1, y, w, sn; NS4; refer to Materials and
Methods) that carries an ewg transgene consisting of an
ewg cDNA under the control of the neural-specific regulatory elements of the Drosophila embryonic lethal abnormal visual system gene in the null background of the ewgl1
allele (DeSimone et al., 1996
). This neural-specific transgene provides essential ewg function required for viability,
but since these flies completely lack ewg expression in the
mesoderm they are mesoderm-null, and they lack most of
the IFMs. We examined the early events in larval muscle
transformation in this ewg mesoderm-null background to
elucidate the role of this gene in this process. Examination
of the larval muscles in 14-16 h APF pupae of ewg mutant
flies show that although myoblasts are present, migrate normally, and get distributed over the larval muscles, the
splitting process is aborted (Fig. 6 a). Optical sections of
the unsplit muscles revealed that fusion of imaginal myoblasts with the larval muscles was not affected in this ewg
mutant background (Fig. 6 b). However, the progressive
alignment of the fused myoblast nuclei into longitudinal
columns was not observed in this situation. The unsplit
muscles initiate differentiation as revealed by the normal
onset of actin (88F)-lacZ expression, but by 26 h APF, begin to fragment and degenerate (data not shown). Although this mutant phenotype in the developing DLMs
clearly justifies the role of ewg in mediating the splitting
process, the situation is complicated by our observation
that this phenotype is sensitive to genetic background.
Thus, although strains that are ewgl1, y, w, sn; NS4 exhibit
this phenotype consistently, strains carrying the same ewg
allele in a different genetic background, ewgl1, y, cho, sn;
NS4, however are not affected in the splitting process. Further, animals carrying a viable allele of ewg, ewg1, which
exhibits no Ewg immunoreactivity in the mesodermal
cells, are also not affected in the splitting process (Coelho,
1994
). The developing DLMs nevertheless degenerate at
similar stages in all these strains.
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Given that there is a genetic background-dependent variation of the effect of removal of ewg function during IFM development, and given the complex nature of products from the locus (Fleming et al., 1993), the most parsimonious conclusion, consistent with the pattern of expression of the gene during IFM development, is that ewg removal can, at least in one genetic background, affect splitting of the larval muscles. We discuss this in relation to IFM differentiation below (see Discussion).
Early Events of Nervous System Metamorphosis Are Normal in the Absence of Imaginal Myoblasts
Unlike the Drosophila embryo, where muscles are patterned independently of the developing innervation, muscle development in the imago presents a contrasting situation where myogenesis and development of the innervation
proceed in synchronicity (Broadie and Bate, 1993; Fernandes
and VijayRaghavan, 1993
). This process has been best investigated for the developing DLMs, and it begins with the
withdrawal of synaptic contacts of the nerves from the persistent larval muscle targets, followed by the elaboration of new arborizations over these muscles as these muscles
split and develop into templates for DLM development
(refer to Fig. 1). It has been suggested that cues emanating
from the metamorphosing innervation could play an important role in the splitting of the larval muscles into DLM
templates (Fernandes et al., 1991
; Fernandes and VijayRaghavan, 1993
). This proposition is based on the following observations: new arborizations from the motor
nerves are observed at a time when the larval muscles are
splitting, and these could, by some unknown mechanism,
instruct the larval muscles to split. Moreover, during larval
life, apart from imaginal myoblasts on the wing imaginal
discs, a subset of imaginal myoblasts remain associated
with the larval nerves (Bate et al., 1991
; Fernandes and VijayRaghavan, 1993
). These myoblasts could derive essential patterning signals from the motor nerves and somehow be involved in the transformation of the remnant
larval muscles. If neural signals are important for larval
muscle transformation, then selective ablation of these
neurons during imaginal development should affect DLM
development. However, laser ablation of the flight muscle motor nerve does not seem to affect the normal development of the DLMs (Fernandes and Keshishian, 1998
). This
would suggest that innervation does not play a crucial role
in the development and patterning of the DLMs.
Given this scenario, we decided to examine whether
metamorphic changes in the larval motor nerves that occur during pupal development could proceed in the absence of imaginal myoblasts in 1151/UAS-p21 animals, or
whether cues from these myoblasts dictate patterning events in the developing innervation. We therefore examined the motor nerves of 1151/UAS-p21 pupae at 14 h APF
for withdrawal of their larval neuromuscular contacts and
for the development of neurite outgrowths over the unsplit larval muscles using antihorseradish peroxidase immunohistochemistry that fortuitously labels all neurons
and their arborizations in Drosophila (Jan and Jan, 1982).
We found that even in the absence of imaginal myoblasts
in 1151/UAS-p21 animals, the motor nerves were able to
withdraw their synaptic contacts from the larval muscles
on schedule, and were also able to send out neurite processes over the degenerating unsplit muscles (Fig. 7, a-c).
These observations demonstrate that much of the early
metamorphic changes of the flight muscle innervation
such as withdrawal of synaptic terminals from their target
larval muscles and elaboration of neurites over the developing DLMs are autonomous properties of the nerves,
most likely induced by hormonal changes during early pupation and are not dictated by cues from the developing DLMs, a situation similar to hormonally mediated reprogramming of motor neurons in the tobacco moth, Manduca sexta (Truman and Reiss, 1995
). However, the evolution of the final innervation pattern is likely to be dictated
by cues from the developing DLM fibers (Fernandes et al.,
1994
; DeSimone et al., 1996
).
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Discussion |
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In this study, we have focused on the cellular mechanisms
of pattern formation in the developing DLMs using larval
muscle fibers as scaffolds. The use of larval muscles for the
development of the DLMs has long been recognized, not
only in Drosophila and other related dipterans, but in
other insects as well (for review see Crossley, 1978; also
see Smit and Velzing, 1986
; Cifuentes-Diaz, 1989
). With
reporter genes that allowed the visualization of the early
events during flight muscle development in Drosophila,
Fernandes et al. (1991)
first documented the transformation of the larval muscles into templates for the development of the DLMs. However, the mechanisms by which
the larval muscles are modified into templates have always
remained an enigmatic problem. Early observations (for
review see Crossley, 1978
), coupled with more recent electron microscopic studies (Reedy and Beall, 1993a
) have
revealed that imaginal myoblasts invade the larval muscles
during early pupal development. In this study, we were
able to demonstrate that the transformation of residual
larval fibers into templates for DLM development is dependent on the invasion and fusion of the imaginal myoblasts with these fibers. In addition, we identify a role for the ewg gene in this process.
The events in the transformation of the larval muscle organizers can be examined in a step-wise manner. Their escape from histolysis must be a consequence of autonomous properties of the muscles themselves. Transforming
the segmental identity of the nervous system and the epidermis, but not the mesoderm, of the third thoracic segment towards the second, does not result in the formation
of larval templates, in the transformed segment (Fernandes
et al., 1994). The mechanism of splitting of the muscles themselves can most simply be explained as a consequence
of a precisely choreographed set of events that occur during onset of differentiation. The end requirements are six
DLM fibers, innervated correctly and attached to specific
sites, and whose appropriate formation requires myoblasts, templates, epidermal cues, and the nervous system.
Thus, at the onset of metamorphosis, Twist-expressing myoblasts swarm over the templates and Ewg expression
is seen in myoblasts just before fusion (Fernandes et al.,
1991
; DeSimone et al., 1996
). Fusion of myoblasts and the
concomitant onset of differentiation, in addition to active
processes autonomous to the templates must be involved
in the recognition of attachment sites on the epidermis. It
is this precise juxtaposition of developing muscle fibers
and their epidermal attachment sites that has been well
documented (Fernandes et al., 1996
) and is essential for the generation of the six DLM fibers seen in the adult. In
the absence of the templates (Farrell et al., 1996
; Fernandes
and Keshishian, 1996
) two effects are noteworthy. First,
muscle development is greatly delayed. Ewg expression is
delayed in the myoblasts in the region where the templates
are absent, suggesting that the proper onset of Ewg expression is mediated by interactions of the myoblasts with
the larval muscles. Thus, templates provide both spatial
and temporal cues. Second, delayed muscle development is aberrant, and the six DLM units are not correctly generated. These results, along with our observations on the expression pattern of Ewg (Fig. 3) suggest that, in normal development, the onset of muscle differentiation mediated
by Ewg, together with the definition of a correct subset of
stripe-expressing attachment cells for the muscles in the
epidermis (Fernandes et al., 1996
) are essential events in
DLM patterning. Once distinct pairs of muscle-epidermal attachment positions have been precisely defined for each
fiber, subsequent splitting may be a consequence of the
forces resulting from fiber differentiation. These forces
must also be specifically regulated during early myogenesis
and cannot be merely the contractile activity of the muscle
in response to neuronal input as neuromuscular activity is
first detected late in pupal development (Salkoff, 1985
).
In an earlier study, we had reported the expression pattern of Ewg during flight muscle development and had described the phenotype of the developing IFMs in a viable
combination of ewg alleles (DeSimone et al., 1996). We
had also reported in the same study that in a synthetic genetic condition that completely eliminates ewg function
from the mesodermal cells (mesoderm-specific null), the
DLMs not only degenerate like in the viable allelic combination, but before degeneration they develop as three unsplit fibers. We had studied the effects of this altered DLM
pattern on the pattern of motor nerve innervation. In this
study, we have extended our previous observations on
Ewg expression and have used it as a convenient marker
to chart the cellular events during early stages of larval
muscle transformation by the imaginal myoblasts. In addition, we have studied the development of the DLMs at the cellular level in the mesoderm-specific null genetic condition and have shown a possible connection between the
pattern of Ewg expression and its mutant phenotype in the
DLMs in this genetic background. Consistent with an active role that we propose for the templates is the observation of Ewg expression in the nuclei of the larval muscles
that indicate that these muscles could possibly be transcriptionally active. The presence of Ewg in larval nuclei could be a consequence of remnant expression from the
larval stage, where we see low-level but consistent expression in somatic muscles (Roy, 1997
). Alternatively, it is
possible that the presence of Ewg immunoreactivity in
these larval nuclei during DLM formation is due to the
translocation of Ewg protein synthesized by imaginal myoblasts after they have fused with the larval muscles or the imaginal myoblast nuclei induce Ewg expression in the nuclei of the larval muscles on fusion. To resolve some aspects of this issue, we have looked for Ewg expression in
the nuclei of the unsplit larval muscles in 1151/UAS-p21 animals. We find that the nuclei of the unsplit muscles in
these animals do exhibit Ewg immunoreactivity (data not
shown). One possibility is that this could be due to transcription from the nuclei of the few imaginal myoblasts
that consistently remain in these animals and fuse with the
larval muscles, followed by nuclear translocation of Ewg
translated in the muscle cytoplasm into nuclei of the larval
muscles. The other possibility is that the Ewg protein detected in larval nuclei is a consequence of these nuclei being transcriptionally active. Thus, whereas the source of
Ewg immunoreactivity in the larval muscle nuclei during DLM development remains unresolved, the presence of
Ewg expression in these nuclei allowed us to clearly demonstrate that these nuclei actually get incorporated into
the developing DLM fibers. In addition, the ability to
maintain nuclear Ewg expression suggests that these nuclei have at least some kind of biological activity and are not mere "ghosts". This observation is particularly important because electron microscopic studies of the metamorphosing larval muscles and of homologous larval muscles
in Calliphora have shown that subcellular components
such as sarcomeric organization is lost, and there is disassembly of the contractile apparatus (Crossley, 1972
; Reedy
and Beall, 1993a
).
The onset of differentiation of the mature fiber after fusion of myoblasts is an essential requirement for the splitting of the larval muscles. This is demonstrated by ewg mutant phenotypes. In an ewg-mesoderm-null combination
(Fig. 6 a) these muscles fail to split. The pattern of Ewg expression during DLM development (DeSimone et al.,
1996; this study) is consistent with this phenotype. Ewg expression is not observed in the mature DLMs, and this
gene may therefore be a regulator of early events in muscle differentiation. The identification of target genes of
Ewg may help in deciphering the molecular events in the
process of splitting. However, the muscle phenotype in
ewg mutants appears to be sensitive to the genetic background as seen in the situation where the same mesoderm-null combination can allow splitting of the larval muscles.
Given the strong correlation between the expression pattern of Ewg in muscle development and the nonsplitting
phenotype observed in one genetic combination, we interpret our results in the following manner. We propose that
Ewg expression is required for the early steps in fiber differentiation, and splitting of the DLM templates is one of
the earliest steps in this process. However, we suggest that
other genes also play a similar spatial and temporal role in
DLM development and in corresponding early steps of
DVM development. This is reflected by the variability in
the ewg mutant phenotype. This variation is actually most
striking in the DVMs where there is a substantial variation
in the expressivity of the phenotype (Fleming et al., 1983
,
1989
; de la Pompa et al., 1989). We have used this variability to our advantage by screening for supressors of the ewg
DLM phenotype and, consistent with the above finding of
sensitivity to genetic background, several modifiers with
poor penetrance of the supressor phenotype have been
isolated (Sunanda, M.S., unpublished data).
The importance of the developing innervation in patterning imaginal muscles in the fly is emphasized by the
fact that the development of a sex-specific muscle, the
muscle of Lawrence, in the fifth abdominal segment of
male flies is critically dependent on the segmental identity
and sex of the innervating motor neuron and not on the
genetic identity of the myoblasts themselves nor that of
the epidermis to which it attaches (Lawrence and Johnston, 1986). Specific ablation of the innervation to the muscle of
Lawrence has been shown to completely arrest the development of this muscle in male flies (Currie and Bate,
1995
). A similar consequence could be envisioned for the
DLMs. In this case however, the motor nerves themselves
appear not to be directly involved in the early patterning events of these muscle fibers, since ablation of these
nerves during late larval development does not affect aspects of DLM patterning during pupation (Fernandes and
Keshishian, 1998
). Furthermore, early events in the transformation of the nervous system like the withdrawal of
synaptic contacts from the larval muscles and elaboration
of primary neurite branches are also autonomous properties and can take place in the absence of templates (Fernandes
and Keshishian, 1998
), or as we have shown in this study
(Fig. 7c), in the absence of imaginal myoblasts.
The widespread occurrence of instances where muscle
patterning is nucleated by muscle organizers suggests that
these cells do play important functions in muscle patterning and have been evolutionarily selected for (for review
see Jellies, 1990). For instance, special cells called comb
cells or C cells organize the intricate pattern of muscle fibers on the body wall of the leech (Jellies and Kristan,
1988
). In the grasshopper, each muscle is prefigured by a
single large mesodermal cell, the muscle pioneer, that recognizes attachment sites and provides cues to the developing motor neuron to establish the correct pattern of synaptic contacts (Ho et al., 1983
). Other mesodermal cells fuse
with the pioneer and give rise to the mature muscle. The
developing fiber often splits up into a set of muscle fascicles in a manner very reminiscent of the splitting process
of the larval muscles during DLM development in Drosophila. In the Drosophila embryo, muscle development is nucleated by special myoblasts called founder cells (Bate,
1990
; Rushton et al., 1995
). Myoblasts can fuse to founder
cells but not to each other and form pioneer fibers that
configure muscle pattern. Neighboring fibers with identical intrinsic properties and pattern can nevertheless attach
to distinct adjacent epidermal sites, exemplifying the importance of context in fiber formation (Ruiz-Gómez and
Bate, 1997
). One unifying function of organizers in myogenesis could be to provide myoblasts and developing motor neurons with spatial cues so that the muscle's fibers are
produced and innervated with a high level of precision.
They could act as sites of myoblast aggregation and function to partition them into groups that give rise to individual muscle fascicles. Occurrence of muscle organizers has
not been definitively proven in vertebrates, but at least in
the zebrafish embryo, there is a group of early maturing
muscle pioneers that develop along the trunk, in close apposition with the notochord (Halpern et al., 1993
). Recent
studies on the mechanisms of specification of these cells
tend to suggest that they play an important function in
somite patterning (Currie and Ingham, 1996
; van Eeden
et al., 1996
). It will be interesting to evaluate the mechanisms by which muscle organizers help to organize muscle
patterns in these diverse organisms. It is possible that muscle development in these organisms involve cellular processes that are similar to the ones that we have found to
operate during DLM development in Drosophila.
![]() |
Footnotes |
---|
Received for publication 10 December 1997 and in revised form 24 March 1998.
S. Roy's visit to K. White's laboratory as a special graduate student was supported by a traveling fellowship from the Company of Biologists Ltd., (Cambridge, England) and Brandeis University. This work was supported by grants from the National Centre for Biological Sciences (NP1) and from the Human Frontier Science Programme (HFSP/KVR/95) to K. VijayRaghavan.We thank I. Hariharan for his kind gift of the UAS-p21 fly strain before publication, S. Roth for antibodies, and V. Rodrigues (Bombay Institute, Bombay, India) for comments on the manuscript. S. Roy wishes to thank K. White for the confocal microscope facility at Brandeis University (Waltham, MA) where part of this work was done, and for her very useful suggestions and criticism.
![]() |
Abbreviations used in this paper |
---|
APF, after puparium formation; DLM, dorsal longitudinal muscle; DVM, dorso-ventral muscle; ewg, erect wing, IFM, indirect flight muscle; MHC, myosin heavy chain; UAS, upstream activating sequence.
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