Rab11 Plays an Indispensable Role in the Differentiation and Development of the Indirect Flight Muscles in Drosophila

Rab11, an evolutionary conserved, ubiquitously expressed subfamily of small monomeric GTPase has been known to regulate diverse cellular and developmental events, by regulating the exocytotic and transcytotic events inside the cell. Our studies show that Rab11 regulates Drosophila adult myogenesis by controlling proliferation and differentiation of the Adult muscle precursors (AMPs). Blocking Rab11 in the AMPs, which fuse to form the Indirect Flight Muscles (IFMs) of fly, renders flies completely flightless and non-viable. The indirect flight musculature, comprising of the differentially patterned dorsal longitudinal muscles (DLMs) and dorsal ventral muscles (DVMs), is affected to different extents. Abrogating or knocking down normal Rab11 function results in severely disrupted IFMs. DLMs forming from larval templates are reduced in number along with a significant reduction in their fibre size. The de novo developing DVMs are frequently absent. The DLMs in Rab11 hypomorphs are highly reduced, showing as a small constricted mass in one half of the thorax. Further, Rab11 function is essential for growth of these muscles during later half of adult myogenesis, as down regulation of Rab11 in IFMs results in degenerated muscles and broken fibres. Finally, we show that loss of Rab11 activity in the AMPs result in acquisition of migratory characteristic of myoblast as they show cellular protrusion at their polar ends accompanied with loss of cell-cell contacts. Our data provide the first evidence of a trafficking protein playing an indispensable role in regulating early stages of adult muscle development.


Introduction
The process of intracellular transport in multicellular organisms mediates a variety of key cellular processes, such as maintenance of homeostasis, development, uptake of nutrients and down-regulation of signal transduction which is regulated by a repertoire of interacting proteins. In eukaryotic cells, several monomeric GTPases, known as Rab proteins, are the major contributors to the process of intracellular transport through vesicles operating between distinct cellular membrane compartments. The process involves cargo selection, vesicle budding, motility, docking and fusion [1,2].
Rab11, an evolutionarily conserved, ubiquitously expressed subfamily of small monomeric GTPase has been known to regulate diverse cellular and developmental events by regulating the exocytotic and transcytotic events in cells. Rab11 localizes to the pericentriolar recycling endosomes, the trans-Golgi network and post-Golgi vesicles [3,4]. A role for Rab11 in proliferation and differentiation of retinal tissues has been demonstrated in Zebrafish [5]. In Drosophila Rab11 has been shown to be involved in polarization of oocytes [6,7], post-Golgi trafficking of rhodopsin [8], ommatidal formation, activation of JNK signalling during eye development [9,10] maintenance of germ line stem cells [11], embryonic nervous system development [12] and promoting terminal differentiation of follicle cells in egg chamber [13]. Rab11 has been recently shown to be involved in regulating cell-cell interaction during collective cell migration [14].
The complex developmental process of myogenesis is well conserved from insects to vertebrates and is regulated at different levels by a complex network of proteins. Two distinct sets of muscles are found during Drosophila development [15]. The first phase of embryonic myogenesis gives rise to multinucleated larval muscles while the pupal myogenesis gives rise to the adult muscles, which are specifically required for walking and flying. The embryonic and adult myogenesis processes are independent of each other and each involves precisely controlled sequence of events: commitment and specification of muscle precursors, their proliferation and subsequent migration to appropriate target sites, followed by their differentiation giving rise to the final muscle pattern which is accompanied with profound changes in gene expression [16].
Initial studies from our lab have shown that an optimal function of Rab11 is essential for normal myoblast fusion to occur leading to formation of Drosophila embryonic muscles [17]. In the present study, we investigated if Rab11 plays a crucial role in the precisely controlled events of adult myoblast proliferation, migration and fusion that are distinctly separated from each other as they occur over a period of several days.
The indirect flight muscles (IFM) of Drosophila, constitute more than 70% of the flight muscle mass and are located in the thorax of adult fly. The IFMs are comprised of two groups of muscles: six Dorsal Longitudinal Muscles (DLMs) extending along antero-posterior axis and three sets of Dorsal Ventral Muscles (DVMs) running from dorsal to ventral side of the thorax [18]. The IFMs are seeded by Adult Muscle Precursors (AMPs) that are associated with the presumptive notum region of the wing imaginal disc and are set aside during embryonic myogenesis [18]. These AMPs do not differentiate but undergo extensive proliferation during the larval instars persistently expressing Twist [19,20]. This proliferating myoblast population contain two distinct populations, the Founder Cell (FC) which is chosen from among the group of proliferating AMPs and determines the identity of a specific muscle; the remaining myoblast population is Fusion Competent Myoblasts (FCMs) that fuse to the larval templates to pattern the DLMs and by de novo fusion to the founder myoblast, form the DVMs. The fibre size of each muscle is precisely regulated by the number of myoblast fusing which are produced through active proliferation over a prolonged period starting in early larval stage and continuing through the first 24h of pupal myogenesis [21].
To understand the functional requirement of Rab11 during adult muscle development, we chose the large indirect flight muscles of Drosophila, because of their large size and highly organized structure with respect to number, position, attachments and innervations.
We observed significant muscle abnormality and flightlessness in flies expressing UAS-Rab11 N124I (which inhibits the normal Rab11 function by binding to the GTP binding site of the protein) and UAS-Rab11 RNAi (Rab11 reduction via dsRNA) transgenes. Severe muscle anomalies and subsequent reduced viability in such flies reflects the requirement of Rab11 during adult muscle development. Further, reduced proliferation of AMPs and their inability of establish cell-cell contacts were observed in cells deficient of this trafficking molecule. These results indicate a functional requirement of Rab11 in early stages of myogenesis.

Lethality assay
The lethality assay was done by counting the total number of embryos from the indicated genotype and placing them on separate agar plates. Embryos developing into larvae, larvae to pupae and finally eclosing as flies were counted separately. The percentage of lethality at each stage of development was calculated between the control and experimental group. Three replicates of each experiment were performed.

Flight test
Flight test was carried out at room temperature (24°C) in the flies 12h after eclosion. For flight testing, pharate pupae were collected and kept in vials. As the flies eclose, they were transferred to empty vials to acclimatize and then each fly was introduced in 1 litre glass cylinder with a centimeter scale fixed on its wall. Flies that could not fly at all and fell straight to the floor of the cylinder were scored as flightless, flies that could reach to the side walls only up to 2 cm of height were scored as having weak flight, those showed wingbeat and could reach to the height of 2 to 10cm were scored as moderate fliers while the ones that showed active wingbeat and strong ability to fly to any distance above 10cm were regarded as good fliers. The weak and moderate fliers were also tested by following the same procedure in a 1 litre glass beaker to provide them sufficient space for flight. The number of flies scored for each genotype was 75 and three replicates of each experiment were performed.

Muscle preparation
For analyzing the indirect flight muscles in the adults, hemithoraces were frozen in liquid nitrogen, cut sagitally, dehydrated through series of 50%, 70%, 90% and absolute ethanol, cleared in methyl salicylate, mounted in Canada balsam and observed in plane polarized light using a Nikon E800 microscope. 100 hemithoraxes were observed in each case. Three replicates of each experiment were performed.

Immunofluorescence and acridine orange staining
Wing imaginal disc from the larvae were dissected, fixed in 4% paraformaldehyde for 20min at room temperature (RT), washed in PBT (PBS, 0.3%, Triton X-100) thrice for 10min each, blocked in blocking solution (PBS, 0.1%, Triton X-100, 0.1% FCS and 0.02% thiomersal as antifungal agent) for 2h at RT followed by overnight incubation in the primary antibody in blocking solution at 4°C. The tissue were washed thrice in PBT and incubated in secondary antibody for 2h at RT, washed thrice in PBT and mounted in antifadant DABCO (Sigma). The following primary antibodies were used: anti-Rab11 (rabbit, To assay the extent of apoptosis, the wing imaginal discs from third instar larvae were dissected in PSS, stained with 1µg acridine orange (AO)/ml of PBS for 3 min, washed twice in PBS, mounted in PBS [23,24] and immediately viewed in the Nikon E800 microscope.

Estimation of myoblast expanse
Imaginal discs from third instar larvae were dissected and processed for immunostaining as described above. The area occupied by the myoblast was calculated as fraction of wing disc area occupied by Twist positive myoblast in control and experimental groups. The density of myoblast was measured by counting the total number of Twist positive myoblast in the notum. For each control or experimental group, wing discs from 21 larvae were sampled randomly.

Microscopy and Image analysis
For recording the flight behaviour and external morphology of wings, adult flies of the desired genotype were photographed using a Sony Digital Camera (DSC-75) attached to a Zeiss Stemi SV6 stereobinocular microscope. The light/DIC microscopic examinations were carried out with a Nikon E800 microscope with appropriate filter combinations and the images were recorded with a Nikon DXM 1200 digital camera. All GFP or immuno-fluorescence stained preparations were examined with a Zeiss LSM 510 Meta confocal microscope using appropriate lasers, dichroics and filters. The different objectives used for confocal or other microscopy were 10X (0.3NA, Plan Fluor), 20X (0.5NA, Plan, Fluor) or 40X oil (1.4NA, Plan Apo). All the images were assembled using Adobe Photoshop 7.0.

Statistical Analysis
Sigma Plot 11.0 software was used for statistical analyses. For testing the level of significance between the control and experimental groups, One-Way Annova was performed.

Blocking Rab11 function in the adult flight muscle precursors renders flightlessness and severely affects viability of the flies
In order to comprehend role of Rab11 during adult muscle development in Drosophila, the indirect flight muscles (IFMs) of the fly was used as the model for our study. We used the GAL4/UAS system for altering the levels of Rab11 protein and ectopically expressing the dominant negative allele UAS-Rab11 N124I in the AMPs, which fuse to form the IFMs of the fly. The 1151GAL4 that has been shown to specifically express in the AMPs ( Figure S1) was used to drive the expression of transgenes in the adult myoblast. 1151-GAL4 expression starts in the AMPs at the third larval instar stage and continues to express till the complete population of these precursors have fused to form the flight muscles in pupae and later in the adult fibres [25,26].
Interestingly, we observed complete flightlessness ( Figure 1) in the 1151-GAL4/+; UAS-Rab11 N124I /+ flies following eclosion. These flies remained stuck to the surface of the food, showed unopened wings and died within few hours of eclosion ( Figure  1). To further closely examine this phenotype, the 1151-GAL4/+; UAS-Rab11 N124I /+ pharate pupae were transferred to an empty vial (with no fly food) preceding eclosion and closely observed for changes during and after eclosion. Intriguingly, the pharate adults kept in the dry environment of the empty vials eclosed normally with fully opened wings but continued to show flightlessness. Also, these flies showed absence of wingbeat, had a poor sense of balance and could not return to their upright position with dorsal side up once they fall (Video S1). To substantiate the flightless phenotype, we performed flight test that demonstrated complete flightlessness (Table 1) in all 1151-GAL4/+; UAS-Rab11 N124I /+ flies observed. The control group showed good flying ability in 77.3% of the flies while 18.6% of flies showed moderate flying (Table 1).
In order to further comprehend, if there is an absolute requirement of Rab11 protein during formation of the IFMs, we used UAS-Rab11 RNAi to knock down Rab11 specifically in the myoblast, and checked if this had any effect on flight and viability of the flies. We observed that a significant (29.3%) of 1151-GAL4/+; UAS-Rab11 RNAi /+ progenies could not eclose and died as pharate adults confirming a pharate adult lethality ( Figure 1). On closely examining these flies, we found that the pharate adult struggle to move out of the puparium case and only 44% of them were able to eclose (escapers) while the rest died. 60.8% of the escaper flies showed inability to fly, and the rest 29% were weak flyers (Table 1).
Since, the hypomorphic allele of Rab11 (Rab11 mo /TM6B) is known to have reduced protein, owning to a P-element insertion in the 5' regulatory region of the Rab11 gene and reduced viability [9], we investigated these flies for any such muscle defects. Interestingly, we observed that Rab11 mo /TM6B produced significantly low (1.2%) of homozygous Rab11 mo viable adults ( Figure 1) in contrast to the expected 25%. The lethality was observed to occur at various larval and pupal stages of development. The viable flies showed complete inability to fly and subsequently died ( Figure 1, Table 1).
Also, both the 1151-GAL4/+; UAS-Rab11 N124I /+ and 1151-GAL4/+; UAS-Rab11 RNAi /+ flies showed an held-out wing position phenotype, in which the wings are held out at different angles from the body axis instead of being parallel to it ( Figure  2A, B). The held-out wing phenotype was 100% penetrant in these flies but the expressivity of the phenotype varied as the wings were held out at various angles to the body axis.
From these above phenotypic observations, we had a clear indication of Rab11 playing imperative role in attributing flight ability to Drosophila by participating in the flight muscle development which in turn affects the viability of the flies.

Rab11 is required for the differentiation and de-novo development of dorsal longitudinal and dorsal ventral muscles
The flight ability of Drosophila is attributed to the indirect flight muscles (IFMs) which are the major bulk of muscles located in the thorax. The DVMs that work as 'wing elevators' are present as three individual bundles, each consisting of three, two and two fibres, respectively, while the six dorsal longitudinal muscles (DLMs), also known as 'wing depressors, run from the anterior to the posterior of each hemithorax ( Figure 3A   Rab11 RNAi /+ flies, were due to anomalies in their flight muscle architecture, we examined the thoracic musculature in these flies, using plane polarized optics. Interestingly, substantial disorganization and several anomalies in the IFM musculature of these flies were observed. Thoraces in Rab11 mo /TM6B adults, showed intriguingly reduced DLMs, occasionally showing as three thin fibres occupying only half of the thoracic space ( Figure 3C) in comparison to the wild type controls where the DLMs span the whole thorax in longitudinal direction ( Figure 3B) and had six thick DLM fibres running across the thorax from anterior to posterior ends (indicated by asterisks in Figure 3A, B). On expressing the dominant negative Rab11 protein in the AMPs in 1151-GAL4/+; UAS-Rab11 N124I / +individuals, we observed significant reduction in the number of DLM fibres in each of the thoraces. Majority of thoraces in 1151-GAL4/+; UAS-Rab11 N124I /+ flies showed either three (39.3%) or four (30.6%) DLMs compared to the six fibres (96%) observed in wild type controls (Fig. 3D F). To check if knocking down Rab11 in the adult muscle precursors in 1151-GAL4/+; UAS-Rab11 RNAi /+ flies, showed similar muscle abnormalities, we observed the thoracic preparations of these flies and found considerable loss of muscle structure along with absence of correct number of DLMs. The DLM fibres in these thoraces appeared as 'wiggly' structures that were occasionally disconnected to the cuticle at the two ends of the thorax ( Figure 3E). Instead of presence of all six DLM fibres, we occasionally observed the remnant of first and the third larval templates in these thoraces that account for the reduced number of DLMs observed in this case ( Figure 3E, F).
Since, the second set of indirect flight muscles, the DVMs, utilize a completely distinct mode of patterning, we followed up  Figure 4D, F). DVM I also showed reduced muscles as 25.6% of the flies in 1151/+; UAS-Rab11 N124I /+ and 20% in 1151GAL4/+; UAS-Rab11 RNAi showed absence of both fibres of the bundle ( Figure  4D, F). The Rab11 mo hypomorphs showed DVMs that were drastically reduced in mass along with absence of individual DVM fibres giving the appearance of an empty thoracic space ( Figure 4C). The 1151-GAL4/+; UAS-Rab11 RNAi thoraces showed interfilament spaces between the muscle fibres with loose myotubes contact ( Figure 4E). In order to determine if the muscle phenotype observed in 1151-GAL4/+; UAS-Rab11 RNAi and 1151-GAL4/+; UAS-Rab11 N124I genotypes is due to an absolute requirement of Rab11 in the myoblast during larval stages, we used the Gal80 ts system to allow a temporal regulation of transgene expression [27]. Gal80 protein represses the GAL4 once it is bound to it. Gal80 ts is a temperature-sensitive mutation and inactivates the repressor function of Gal80 at restrictive temperatures (29°C) while at permissive temperature the GAL80 binds to GAL4 and blocks the activation of UAStransgene. The restrictive and permissive temperatures in our experiments were 29.5°C and 18°C, respectively. The embryos and larvae of 1151-GAL4; UAS-Rab11 N124I ; tubGAL80 ts were grown at 29.5°C and shifted to 18°C at 0h APF.The adult thoraces showed reduced number of DLMs and poorly developed DVMs ( Figure 5A, B) while the converse resulted in a normal IFM muscle architecture. These results show an absolute requirement of Rab11 during Drosophila IFMs development, with an important role to play during the differentiation of DLMs, as well as during the de novo formation of DVMs.

Alteration of Rab11 in the indirect flight muscles allows differentiation but subsequently induces degeneration
The adult myogenesis is broadly divided into two phases: differentiation and growth. During early stages of adult muscle development the muscle precursors actively proliferate and fuse to the larval templates to pattern the DLMs and by de novo fusion give rise to the DVMs. This process of muscle diffrentiaion is complete by 24APF and is immediately followed by the growth phase that continues till all of the myoblasts have fused to the myotubes. Since both these phases must occur for proper muscle development, we hypothesized a functional requirement of Rab11 during later stages of muscle development as well. To test this hypothesis we allowed active myoblast proliferation and subsequent differentiation of the DLMs and DVMs to advance in the presence of functional Rab11 but restricted Rab11 function by using Actin88F driver during the muscle growth phase, in which the muscles increase in size by the continuous process of myoblast fusing to the  Rab11 in Indirect Flight Muscles Development PLOS ONE | www.plosone.org muscle fibers. The Actin88F is a IFM specific actin isoform and the driver mimic the IFM expression of Act88F protein with the expression first detected at around 40h APF, soon after the differentiation of the IFMs is completed [22].
Remarkably, both the UAS-Rab11 N124I /+; Actin88F-GAL4/+ and UAS-Rab11 RNAi /+; Actin88F-GAL4/+ flies, showed significant improvement in viability at all stages of development and eclosion (Figure 1). These flies can also be maintained in viable state. However, while looking at the IFM in these hemithoraces, we observed significant degeneration and thinning, with some muscles appearing to completely degenerate at their ends. The DLMs in some of the hemithoraces were thin and gave a 'seethrough' appearance ( Figure 6B). The UAS-Rab11 RNAi /+; Actin88F-GAL4/+ hemithoraces showed extreme retardation of DLM fibre growth, to an extent that DLMs appeared as thread like structure with large spaces between two neighbouring DLMs, contrary to the closely apposed DLMs present in the controls ( Figure 6C). More interestingly, the number of DLMs in these thoraces was comparable to the control, ruling out possible splitting defects and indicating normal muscle differentiation preceding the growth. The DVMs on the other hand were less severely affected but occasionally showed degenerated fibres as well (Fig. 6E F).
To further verify that these effects are due to altered Rab11 function alone, we used mhcF3580-GAL4, recombined with RFP, which first shows its expression at about 40h APF. Supporting the above data, the mhcF3-580GAL4/UAS-Rab11 N124I flies showed reduced RFP expression in their IFMs in comparison to the intense RFP expressing IFMs of the mhcF3-580GAL4 control flies. The DLMs and the DVMs in the mhcF3-580GAL4/UAS-Rab11 N124I and mhcF3-580GAL4/UAS-Rab11 RNAi were poorly developed ( Figure S2). We also observed defects in adult muscles other than IFMs, where mhcF3-580GAL4 has a specific expression. Together, these data suggest roles for Rab11 in both early and late stages of adult muscle development.

Rab11 is required during proliferation of the indirect flight muscle precursors
The DLMs and the DVMs are formed by myoblast that are derived from the wing disc of the third instar larva [28]. To test whether the reduction in muscle number and fibre size was a consequence of transformed myoblast pool that fuse to give rise to the DLMs and DVMs, we examined the myoblast population in the notum of the wing imaginal disc by labelling it with a myoblast specific marker, Twist. The density and area of the myoblast was compared between the control and 1151/+; UAS-Rab11 N124I /+ wing disc. The myoblast expanse was calculated as the fraction of wing disc area occupied by twist positive myoblast. The myoblast occupied 23% of the total area of the wing disc in the 1151/+; UAS-Rab11 N124I /+ larvae ( Figure  7D) as compared to the 30% in controls, which was significantly different (P<0.0001). In Rab11 knockdown 1151GAL4/+; UAS-Rab11 RNAi wing disc, the area occupied by myoblast was approximately 25% of the total wing disc area, which was again significantly different (P<0.0001) from the controls ( Figure 7C). No significant difference was observed between the myoblast in 1151/+; UAS-Rab11 N124I /+ and 1151GAL4/+; UAS-Rab11 RNAi . We also observed a slight decrease in the size of the notum in 1151/+; UAS-Rab11 N124I /+ and 1151GAL4/+; UAS-Rab11 RNAi animals which may be a direct consequence of reduction in the myoblast expanse. However, there was no change in the overall size of the wing imaginal disc in the above genotypes. The density of myoblast was measured by counting the total number of myoblast in the notum and we observed a decrease in the number of AMPs. A reduction of 41.6% was observed in the number of AMPs in 1151GAL4/+; UAS-Rab11 RNAi while 37.5% reduction in the density was observed in 1151/+; UAS-Rab11 N124I /+. Reduction in the myoblast expanse and density suggested a probable role of Rab11, in regulating myoblast number either by regulating their proliferation or by inducing cell death. To check for the apoptosis occurring in 1151-GAL4/+; UAS-Rab11 N124I /+ and 1151-GAL4/+; UAS-Rab11 RNAi myoblast, we used acridine orange staining to observe the apoptotic cells and found no significant differences in the number of dead cells between the control, 1151/+; UAS-Rab11 N124I /+ and 1151GAL4/+; UAS-Rab11 RNAi , suggesting that the reduced myoblast expanse was not due to cell death ( Figure S3).
Further, we examined the proliferating myoblast by immunostaining for an M-phase marker, phospho-Histone H3 (pHisH3) that labels the cells in M-phase. The proliferation rates of the myoblast were measured as the fraction of Twist positive myoblast that also labelled with pHisH3. Since the myoblast actively proliferate through the third larval instar, we checked for the proliferating cells in the notum of the wing disc. Interestingly, the wing disc notum from 1151-GAL4/+; UAS-Rab11 N124I /+ and 1151-GAL4/+; UAS-Rab11 RNAi larvae showed reduced number of twist labelled pHisH3 positive cells in comparison to controls ( Figure 8A-C) and the difference was found to be statistically significant (p<0.001) in both the cases Rab11 in Indirect Flight Muscles Development PLOS ONE | www.plosone.org ( Figure 8D). This demonstrated an absolute requirement of Rab11 activity in proliferation of adult muscle precursors.

Altering Rab11 in muscle precursors results into changes in myoblast morphology and loss of cell adhesion
To define the requirement of Rab11 during adult muscle precursor differentiation, we studied the subcellular distribution of Rab11 in the AMPs using anti-Rab11 antibody. Rab11 exhibited a punctuate localization in the control adult muscle precursors harbouring the larval wing disc ( Figure 9A-A''). We checked if this localization is affected by altering Rab11, using 1151GAL4 driver that specifically marks the AMP population ( Figure 1). In controls, Rab11 is located in the cytoplasm and is observed as punctuate staining throughout the cytoplasm ( Figure 9A-A''). The AMPs in 1151GAL4;UAS-Rab11 N124I wing disc, showed complete loss of punctuate localization of Rab11. In these AMPs the protein was enriched at apical and subapical regions of the precursor cells instead of its typical cytoplasmic distribution observed in controls ( Figure 9C-C' D-D').
Intriguingly, we observed characteristic changes in the AMPs morphology at early stages of adult muscle development. The AMPs in 1151GAL4;UAS-Rab11 N124I wing disc were elongated and displayed a distinct pattern, where they were connected to the other AMPs of the population through long cellular protrusions. These AMPs showed loose, semi ordered contacts and were no longer seen adhering to each other ( Figure  9C''D''). The myoblast in the basal layers of the wing disc were more severely affected and showed the characteristic spindle like morphology extending at the ends while the myoblast in the inner layers showed 'tear drop' morphology and loose contacts ( Figure 9D-D"). In contrast, the AMPs in the control were closely associated and showed no protrusions at their polar ends. To observe fate of these AMPs at the time of wing disc eversion, we observed the AMPs at 2.5h APF. The myoblast in the everting disc showed long filopodial extensions at their apical ends. The everting discs in controls harboured myoblast that did not show filopodial extensions and were seen as rounded cells (Figure 10A-C). Thus, from these observations we surmise a functional requirement of Rab11 during early stages of adult muscle precursor differentiation.

Discussion
The present study demonstrates the role of Rab11 in Drosophila adult myogenesis, by participating in the differentiation and growth of the adult muscle precursors. Blocking Rab11 function in the adult muscle precursors, which fuse to form the indirect flight muscles of the fly, results in rendering the flies completely flightless and non-viable. The IFM comprising of the differentially patterned DLMs and DVMs are affected to different extents. Abrogating normal Rab11 function or knocking down its function resulted in severely disrupted IFM structure. DLMs forming from larval templates [18] are reduced in number along with a significant reduction in their fibre size. On the other hand, the de novo developing DVMs are frequently absent. The DLMs in Rab11 hypomorphs are highly reduced, showing as a small constricted mass in one half of the thorax. Furthermore, we found that, Rab11 function is not only required for proper differentiation of muscles, but also essential for their growth during later half of muscle development, as on altering Rab11 in the indirect flight muscles results in degenerated muscles, broken fibres and large interfilament spaces. We surmise that the adult muscle phenotype may in part be due to the reduced proliferation of myoblast accompanied with cell shape changes. Thus, our data provide the first evidence of a trafficking protein playing an indispensable role in during the adult muscle development.

Rab11 regulates proliferation of adult muscle precursors
The Indirect flight muscles are seeded from the adult muscle precursors that are formed in the early embryos [19]. During embryogenesis, a small population of myoblast that have persistent expression of Twist are set aside, which later function as precursors of the adult muscles. These Twist expressing cells actively proliferate during the larval instars to give rise to the adult muscles of the fly [18]. Our studies have shown that altering Rab11 in these proliferating myoblast significantly decreases their number during the extended period of myoblast proliferation. Delivery of new membranes and proteins is necessary to allow proper separation of the daughter cells, for which Rab11 activity is a prerequisite. Rab11 function during cytokinesis involves active membrane addition at the site of furrow formation during cytokinesis [29]. A similar role of Rab11 in mediating growth of lateral surfaces has been seen during cellularization in Drosophila embryo where it interacts with Nuclear fallout (Nuf) to speedup division [30,31]. Only recently, mouse homologue of human Rab11 family interacting protein 4, zRab11-FIP4 has been seen to regulate proliferation of retinal progenitors in Zebrafish embryos through Shh signalling [5]. In view of these it is most likely that over expressing the dominant negative Rab11 protein in the AMPs or knocking it down results in failure of separation of the two daughter cells, accounting for fewer number of AMPs, available at the time of fusion to form the adult muscle fibres.

Rab11 is critical for differentiation of developmentally distinct DLMs and DVMs
Once the AMPs pool is generated by active proliferation, the next step is the accumulation of these myoblasts at the site of muscle formation, where the future DLMs and DVMs will be formed. The DLMs and DVMs, which constitute the thoracic Indirect Flight Muscles, have distinct modes of formation. The DLMs are formed using the larval oblique muscles (LOMs), which escape histolysis during metamorphosis and give rise to the future DLMs. These LOMs are supposed to function as founder cells, similar to the ones found in Drosophila embryo, and act as the fusion target for the myoblast, after which splitting of each template into two is activated during early hours of pupation. Splitting of each of these larval templates requires addition of new membrane that is delivered at the site of developing fibre to compensate for increased membrane surface of the adult fibre. The reduction of DLM fibres seen in majority of the Rab11 mo , 1151/+; UAS-Rab11 N124I /+ and 1151GAL4/+; UAS-Rab11 RNAi hemithoraces was probably due to failure of the larval templates to undergo splitting in absence of delivery of additional membrane during differentiation of these muscles, as the larval templates were found to be intact in these thoraces.
It has been shown from our lab that during embryonic myogenesis Rab11 is required for the fusion of myoblast and its depletion results in myoblast fusion defects accompanied with anomalies in the shape of the embryonic muscles [17]. It is hypothesized that proliferation must occur to restock the myoblast pool which is depleted as myoblast fuse to the larval templates. Thus, there is a feedback between fusion and proliferation to control the size of the myoblast pool, which during the period of peak fusion ensures that fibres of appropriate size are generated. We surmise that the reduced myoblast pool in the case of 1151/+; UAS-Rab11 N124I /+ and 1151GAL4/+; UAS-Rab11 RNAi , along with dwindling fusion results in the formation of the thin fibres.
The DVMs that appear in three sets; DVM I consisting of 3 fibres, DVM II and DVM III with 2 fibres each, are formed using the dumbfounder positive founder cells. During adult myogenesis each individual muscle fibres of DVM bundle is seeded separately by a specific founder cell [21], in a fashion which is very similar to that in the Drosophila embryo, where a single embryonic founder cell is the precursor of a specific muscle fibre. Each of the fibre of a DVM bundle is formed using the 'Founder Cell' which is specified during development. The absence of individual fibres of DVM bundles is most likely due to the absence of the 'Founder' for the particular DVM fibre that failed to develop, at the site of muscle formation. Our studies have shown that Rab11 function is required for proper division of the muscle progenitors. It is most likely that failure of the progenitor to divide into individual founders for each of the DVM fibre results in the absence of formation of the respective DVM fibre of the bundles.

Rab11 regulates early stages of AMPs differentiation and migration
Loss of Rab11 in 1151/+; UAS-Rab11 N124I /+ resulted in myoblast that showed 'tear drop' morphology and loss of cell- cell contacts. The AMPs in the wing disc were connected to each other through long cellular protrusions at their polar ends. Few hours later at the time of wing disc eversion the myoblast showed filopodial extensions at their apical ends which is a typical characteristic of migrating cells. The actin cytoskeleton in association with adherent junction helps in the adhesion process and maintenance of cell shape and morphology. The cell cycle exit is a prerequisite both for terminal differentiation and also to start the process of fusion [32]. Studies have demonstrated a key role for Rab11 in cytoskeleton organization [7] as disorganized actin cytoskeleton leads to degenerated rhabdomeres in adult Drosophila eye [10]. Disrupted cytoskeleton was also observed in embryos, testes and ovaries of Rab11 mutant individuals [33,34]. We show that AMPs fail to proliferate in the absence of Rab11 and prematurely exit the cell cycle. It is most likely that the premature cell cycle exit of the AMPs in 1151/+; UAS-Rab11 N124I /+ activates the differentiation machinery in the myoblast leading to acquisition of tear drop morphology of AMPs and migratory characteristics. Recently, Rab11 has been shown to regulate collective cell migration in Drosophila border cells [14] which further strengthens our proposed hypothesis. In view of these results along with demonstrated role of Rab11 in regulating cytoskeleton organisation it is most likely that loss of Rab11 results in acquisition of migratory characteristic of myoblast showing long extensions.
Taken together, the present study provides the first in vivo evidence for the requirement of a GTPase Rab11 in the differentiation and growth of the indirect flight muscles of Drosophila. Further studies are needed to understand the machinery that regulates the adult muscle development in Drosophila.