Centralspindlin is required for thorax development during Drosophila metamorphosis

Epithelial morphogenesis is an essential process in all metazoans during both normal development and pathological processes such as wound healing. The coordinated regulation of cell shape, cell size, and cell adhesion during the migration of epithelial sheets ultimately gives rise to the diversity of body plans among different organisms as well as the diversity of cellular structures and tissues within an organism. Metamorphosis of the Drosophila pupa is an excellent system to study these transformative events. During pupal development, the cells of the wing imaginal discs migrate dorsally and fuse to form the adult thorax. Here I show centralspindlin, a protein complex well known for its role in cytokinesis, is essential for migration of wing disc cells and proper thorax closure. I show the subcellular localization of centralspindlin is important for its function in thorax development. This study demonstrates the emerging role of centralspindlin in regulating cell migration and cell adhesion in addition to its previously known function during cytokinesis. genesis 52:387–398, 2014. © 2014 Wiley Periodicals, Inc.     

Localization of the Antennapedia protein in Drosophila embryos and imaginal discs

Antibodies have been raised against a fusion protein containing the 3' region of the coding sequence of the Antennapedia (Antp) gene fused to β-galactosidase. The distribution of the protein on whole mount embryos and imaginal discs of third instar larvae was examined by immunofluorescence. In young embryos, expression of the Antp protein was limited to the thoracic segments in the epidermis, whereas it was found in all neuromeres of head, thorax and abdomen. At the end of embryogenesis, the Antp protein mainly accumulated in the ventral nervous system in certain parts of the thoracic neuromeres, from posterior T1 to anterior T3, with a gap in posterior T2. Comparison of Antp protein distribution in nervous systems from wild-type and Df P9 embryos, lacking the genes of the Bithorax-complex (BX-C), revealed a pattern of expression which indicated that the BX-C represses Antp in the posterior segments with the exception of the last abdominal neuromeres (A8-9) which are regulated independently. The protein pattern in nervous systems from Sex combs reduced(Scr^xF9) mutant embryos was indistinguishable from that found in wild-type embryos; thus, neurogenic expression of Antp in T1 and the more anterior segments does not appear to be under the control of Scr⁺. All imaginal discs derived from the three thoracic segments express Antp protein. The distribution was distinct in each disc; strongest expression was observed in the proximal parts of the discs. In the leg discs the protein distribution seemed to be compartmentally restricted, whereas in the wing disc this was not the case. Antp protein was not detected in the eye-antennal disc. In embryos, as well as in imaginal discs, the protein is localized in the nucleus.     

The development of adult abdominal muscles in Drosophila: myoblasts express twist and are associated with nerves.

During metamorphosis, the adult muscles of the Drosophila abdomen develop from pools of myoblasts that are present in the larva. The adult myoblasts express twist in the third larval instar and the early pupa and are closely associated with nerves. Growing adult nerves and the twist-expressing cells migrate out across the developing abdominal epidermis, and as twist expression declines, the myoblasts begin to synthesize beta 3 tubulin. There follows a process involving cell fusion and segregation into cell groups to form multinucleate muscle precursors. These bipolar precursors migrate at both ends to find their correct attachment points. beta 3 tubulin expression continues at least until 51 h APF by which time the adult muscle pattern has been established.     

The wing imaginal disc

The Drosophila wing imaginal disc is a tissue of undifferentiated cells that are precursors of the wing and most of the notum of the adult fly. The wing disc first forms during embryogenesis from a cluster of ∼30 cells located in the second thoracic segment, which invaginate to form a sac-like structure. They undergo extensive proliferation during larval stages to form a mature larval wing disc of ∼35,000 cells. During this time, distinct cell fates are assigned to different regions, and the wing disc develops a complex morphology. Finally, during pupal stages the wing disc undergoes morphogenetic processes and then differentiates to form the adult wing and notum. While the bulk of the wing disc comprises epithelial cells, it also includes neurons and glia, and is associated with tracheal cells and muscle precursor cells. The relative simplicity and accessibility of the wing disc, combined with the wealth of genetic tools available in Drosophila, have combined to make it a premier system for identifying genes and deciphering systems that play crucial roles in animal development. Studies in wing imaginal discs have made key contributions to many areas of biology, including tissue patterning, signal transduction, growth control, regeneration, planar cell polarity, morphogenesis, and tissue mechanics.     

Testing homology with morphology, development and gene expression: sex-specific thoracic appendages of the ant Diacamma

Females of the ants belonging to the queenless genus Diacamma have a pair of unique tiny thoracic appendages, called "gemmae," located on the mesothoracic segment. They are covered with sensory hairs, filled with exocrine glands and are involved in the behavioral regulation of reproduction. We report here a morphological, developmental, and genetic study of the development of the gemmae. Both male and female larvae have dorsal mesothoracic discs, although differing in shape and fate. In Diacamma ceylonense, we show that, contrary to butterflies, these discs specify parts of the adult thorax in addition to wing tissues, as in Drosophila. We have cloned and studied the expression of wingless (wg) and scalloped (sd), two genes known to play a critical role in wing morphogenesis in Drosophila. In the fly's mesothoracic dorsal disc, sd is specifically expressed in the wing pouch. In Diacamma, we show that sd is also expressed in male dorsal thoracic discs, whereas its expression was undetectable in females. From this result and observations of shape and growth of cultured isolated discs, we suggest that gemmae originate from a more ventral part of the dorsal disc than the wing pouch and discuss the pro and cons of gemma/wing homology.     

Macromolecular synthesis in wing discs of Spodoptera mauritia Boisd: effects of a juvenile hormone analogue

Last instar larvae of S. mauritia treated topically on day 0, day 1, day 2 and day 3 with a daily (dose of 25 microg juvenile hormone analogue (JHA) moulted into supernumerary larvae. The imaginal discs of the supernumerary larvae especially those of mouthparts and thoracic appendages showed pupal characteristics. However the wing discs, which showed only partial differentiation, were uneverted and highly tanned. In an effort to provide an explanation to this anomaly the RNA, DNA and protein profile in the wing discs of supernumerary larvae were studied. Quantitative analysis of DNA, RNA and protein showed a considerable increase in the amount of DNA and protein and a decline in RNA level. SDS-PAGE analysis of wing disc proteins of JHA treated larvae showed a reduction in the expression of many major proteins that were predominant in the wing discs of control larvae. The results suggest that JHA induced inactivation of genes involved in the synthesis of proteins needed for evagination process may be responsible for the formation of uneverted, partially differentiated pupal wing discs in supernumerary larvae.     

Phosphorylation of endogenous proteins by a cyclic amp-dependent protein kinase in the wing epidermis of Manduca sexta

The wing epidermis of Manduca sexta has 8 prominent proteins of molecular weights ranging from 18,000 to 55,000, the in vitro phosphorylation of which is enhanced significantly by cAMP. The level of protein phosphorylation during pupal-adult development can be correlated with the changing hemolymph ecdysteroid titer. These protein substrates are not limited to the wing epidermis, being present in the pupal brain, fat body, prothoracic gland and gut, as well as larval integumented epidermis, muscle and the wing imaginal discs. Most of the phosphoproteins stimulated by cAMP were localized in the microsomal fraction of tissue homogenates. The 31/32 kDa doublet phosphoproteins were further localized to a ribosome enriched microsomal fraction and have properties similar to those of mammalian ribosomal protein S6.     

Hormonal regulation and patterning of the broad-complex in the epidermis and wing discs of the tobacco hornworm, Manduca sexta

Expression of Manduca Broad-Complex (BR-C) mRNA in the larval epidermis is under the dual control of ecdysone and juvenile hormone (JH). Immunocytochemistry with antibodies that recognize the core, Z2, and Z4 domains of Manduca BR-C proteins showed that BR-C appearance not only temporally correlates with pupal commitment of the epidermis on day 3 of the fifth (final) larval instar, but also occurs in a strict spatial pattern within the abdominal segment similar to that seen for the loss of sensitivity to JH. Levels of Z2 and Z4 BR-C proteins shift with Z2 predominating at pupal commitment and Z4 dominant during early pupal cuticle synthesis. Both induction of BR-C mRNA in the epidermis by 20-hydroxyecdysone (20E) and its suppression by JH were shown to be independent of new protein synthesis. For suppression JH must be present during the initial exposure to 20E. When JH was given 6 h after 20E, suppression was only seen in those regions that had not yet expressed BR-C. In the wing discs BR-C was first detected earlier 1.5 days after ecdysis, coincident with the pupal commitment of the wing. Our findings suggest that BR-C expression is one of the first molecular events underlying pupal commitment of both epidermis and wing discs.     

Cell lineage of the thoracic muscles of drosophila

The thorax of the adult Drosophila contains about 80 muscles, which develop from the mesoderm. A new genetic marker was used to map the cell lineage of the myoblasts that form these muscles. Clones of marked cells were produced by irradiation of embryos and larvae, and these were detected in the adult by histochemical staining. The principal findings are that the muscles of each segment have separate origins, and that each becomes compartmented precisely into a dorsal-lineage and a ventral-lineage set of muscles, each set probably being formed by the adepithelial cells found in one imaginal disc. In contrast with the epidermis, the muscles of each thoracic segment are not subdivided into anterior and posterior compartments, and clones of muscle cells that are homozygous for recessivelethal alleles of engralled develop normally.     

Regenerative interactions between Drosophila imaginal discs of different types.

We have tested the ability of fragments of one type of imaginal disc to stimulate regeneration of another type. It has been shown by others that, when extreme proximal and distal fragments of the wing disc are combined, intercalary regeneration of the missing tissue ensues. Each fragment, if cultured alone, will merely duplicate its structures. We now find that distal fragments of other thoracic discs, haltere and leg, while retaining their autonomy for differentiation, also interact with proximal wing tissue to promote regeneration of more distal wing structures. The proximal wing tissue used in these experiments was the wingless abnormal wing disc which, in the absence of interaction, yields only proximal wing structures. These results suggest that spatial organization is controlled by similar systems in the various thoracic discs. In contrast, head and genital disc material provided no regenerative stimulus to the mutant wing disc tissue.     

Apterous mediates development of direct flight muscles autonomously and indirect flight muscles through epidermal cues

Two physiologically distinct types of muscles, the direct and indirect flight muscles, develop from myoblasts associated with the Drosophila wing disc. We show that the direct flight muscles are specified by the expression of Apterous, a Lim homeodomain protein, in groups of myoblasts. This suggests a mechanism of cell-fate specification by labelling groups of fusion competent myoblasts, in contrast to mechanisms in the embryo, where muscle cell fate is specified by single founder myoblasts. In addition, Apterous is expressed in the developing adult epidermal muscle attachment sites. Here, it functions to regulate the expression of stripe, a gene that is an important element of early patterning of muscle fibres, from the epidermis. Our results, which may have broad implications, suggest novel mechanisms of muscle patterning in the adult, in contrast to embryonic myogenesis.     

FGF is an essential mitogen and chemoattractant for the air sacs of the drosophila tracheal system

The Drosophila adult has a complex tracheal system that forms during the pupal period. We have studied the derivation of part of this system, the air sacs of the dorsal thorax. During the third larval instar, air sac precursor cells bud from a tracheal branch in response to FGF, and then they proliferate and migrate to the adepithelial layer of the wing imaginal disc. In addition, FGF induces these air sac precursors to extend cytoneme-like filopodia to FGF-expressing cells. These findings provide evidence that FGF is a mitogen in Drosophila, correlate growth factor signaling with filopodial contact between signaling and responding cells, and suggest that FGF can act on differentiated tracheal cells to induce a novel behavior and role.     

Determination and Regulation Capacities of the Wing Disc of the Fleshfly, Sarcophaga peregrina

Unilateral extirpation of the wing discs was performed on mid- and late-third instar larvae of Sarcophaga peregrina to investigate the regulation capacities of the thoracic discs. Out of 636 operated larvae, 175 became adult and all of them exhibited hemithoracic structures, lacking any adult structures in the operated side, which were normally produced from a wing disc. These findings suggest that the wing disc does not possess the capacity of bicentric regulation to produce the thoracic structures of the opposite side.     

Misregulation of homeotic gene expression in Drosophila larvae resulting from mutations at the extra sex combs locus

Using monoclonal antibodies specific for their protein products, the expression of the Ubx, Antp, and Scr genes was examined in imaginal discs and central nervous systems of esc-Drosophila larvae. In esc-mutants, both the Ubx and Scr proteins are expressed at increased levels or in new locations in the leg discs. Ubx also is expressed in new locations in the posterior wing disc and in small groups of cells in the antenna disc. The Antp protein is expressed ectopically in the eye-antenna disc; however, obvious abnormal expression of Antp was not found in the thoracic imaginal discs. Particularly striking is the fact that a single disc, such as the mesothoracic leg, can show increased expression of both a more "anterior" homeotic gene (Scr) and a more "posterior" gene (Ubx). Ectopic expression of Ubx and Antp, but not of Scr, is seen in the central nervous system of mutant larvae. These results are discussed with respect to the adult esc-phenotype and the differential effects of esc mutations on early and late development.     

Reciprocal transplantation of wing discs between a wing deficient mutant (fl) and wild type of the silkworm, Bombyx mori

The wingless mutant flügellos ( fl ) of the silkworm lacks all four wings. Although wing discs of the fl seem to develop normally until the fourth larval instar, wing morphogenesis stops after the fourth larval ecdysis, probably caused by aberrant expression of an unidentified factor, referred to as fl . To characterize factor fl , the wing discs dissected from the wild-type (WT) and fl larvae were transplanted into other larvae and developmental changes of the discs were examined. When the wing disc from a WT larva was transplanted into another WT larva and allowed to grow until emergence, a small wing appeared that was covered with scales. Thus, the transplanted wing discs can develop autonomously, form scales and evert from adult skin. The WT wing discs transplanted into the fl larvae also developed at a high rate. However, the fl wing discs transplanted into the WT larvae did not develop during the larval to pupal developmental stages. These data suggest that the fl gene product (factor fl) works in the wing disc cells during wing morphogenesis. Its function cannot be complemented by hemolymph in the WT larva. It is also implied that the level of humoral factors and hormones required for wing morphogenesis are normally maintained in the fl larva.     

Expression of the Sex combs reduced protein in Drosophila larvae

We have generated a monoclonal antibody that binds specifically to the protein product of the homeotic Sex combs reduced (Scr) gene of Drosophila, and have mapped the patterns of Scr expression in late third instar larvae. Virtually the entire prothoracic leg imaginal disc expresses the gene, although the levels of expression vary in different disc regions. This heterogeneity does not reflect the compartmental domains defined by engrailed gene expression. Expression is also observed in the cells of the humeral and labial discs, and there is a small patch of Scr-expressing cells in the antenna disc. The gene is expressed in adepithelial cells of the three thoracic leg discs, but not in the wing or haltere discs. In the central nervous system, Scr expression is confined to a narrow band of cells in the subesophageal region of the ventral ganglion. The results are discussed with respect to the known genetic requirements for Scr+ function.     

Shotgun proteomic analysis of wing discs from the domesticated silkworm (Bombyx mori) during metamorphosis

Proteomic profiles from the wing discs of silkworms at the larval, pupal, and adult moth stages were determined using shotgun proteomics and MS sequencing. We identified 241, 218, and 223 proteins from the larval, pupal, and adult moth stages, respectively, of which 139 were shared by all three stages. In addition, there were 55, 37, and 43 specific proteins identified at the larval, pupal, and adult moth stages, respectively. More metabolic enzymes were identified among the specific proteins expressed in the wing disc of larvae compared with pupae and moths. The identification of FKBP45 and the chitinase-like protein EN03 as two proteins solely expressed at the larval stage indicate these two proteins may be involved in the immunological functions of larvae. The myosin heavy chain was identified in the pupal wing disc, suggesting its involvement in the formation of wing muscle. Some proteins, such as proteasome alpha 3 subunits and ribosomal proteins, specifically identified from the moth stage may be involved in the degradation of old cuticle proteins and new cuticle protein synthesis. Gene ontology analysis of proteins specific to each of these three stages enabled their association with cellular component, molecular function, and biological process categories. The analysis of similarities and differences in these identified proteins will greatly further our understanding of wing disc development in silkworm and other insects.     

Intercellular adhesivity and pupal morphogenesis inDrosophila melanogaster

Summary Leg and wing imaginal discs of mature larvae ofDrosophila melanogaster when treated with 0.1% trypsin for 5–10 min underwent a change in shape that closely resembled normal pupal morphogenesis. Simultaneously, the cells of the disc epithelium changed in shape from tall columnar to cuboidal. Colcemid eliminated microtubules but was without effect on the shape of the imaginal discs or their cells. Tryptic digestion reduced non-junctional intercellular adhesivity but septate desmosomes and gap junctions remained intact.It is proposed that the structure of imaginal discs permits the packaging of the anlagen of the adult integument so that they can change shape and replace the larval structures in a brief period. Apparently most of the definitive form of the pupal leg is built into the disc and becomes visible within a few minutes as intercellular adhesivity is changed.     

Homologies of positional information in thoracic imaginal discs ofDrosophila melanogaster

Summary The regulative behavior of fragments of the imaginal discs of the wing and first leg was studied when these fragments were combined with fragments of other thoracic imaginal discs. A fragment of the wing disc which does not normally regenerate when cultured could be stimulated to regenerate by combination with certain fragments of the haltere disc. When combined with a haltere disc fragment thought to be homologous by the criteria of morphology and the pattern of homoeotic transformation, such stimulated intercalary regeneration was not observed. Combinations of first and second leg disc fragments showed that a lateral first leg fragment could be stimulated to regenerate medial structures when combined with a medial second leg disc fragment but not when combined with a lateral second leg disc fragment. Combinations of wing and second leg disc fragments showed that one fragment of the second leg disc is capable of stimulating regeneration from a wing disc fragment while another second leg disc fragment fails to stimulate such regeneration. It is suggested that absence of intercalary regeneration in combinations of fragments of different thoracic imaginal discs is a result of homology or identity of the positional information residing in the cells of the fragments. The pattern of correspondence of positional information revealed by this analysis is consistant with the pattern of homology determined by morphological observation and by analysis of the positional specificity of homoeotic transformation among serially homologous appendages. The implications of the existence of homologous positional information in wing and second leg discs which share a common cell lineage early in development are discussed.