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.     

Position-specific interaction between cells of the imaginal wing and haltere discs of Drosophila melanogaster.

When fragments of the imaginal wing disc from opposite ends of the disc are mixed prior to culture, intercalary regeneration occurs so that structures are produced which neither of the fragments would have produced if they had been cultured alone. I report here that fragments of the imaginal wing and haltere disc interact in a position-specific way. Mixing of homologous fragments does not result in regeneration, while mixing of fragments from opposite ends of the discs does. Thus the interaction of wing and haltere disc fragments shows the same positional specificity as the mixing of two wing fragments.     

Regulative interactions between cells of wing discs from different dipteran species

The mechanism by which patterns are produced appears to be repeated in each segment of an animal, and it has been proposed that it may even have been conserved in evolution so that different species would have the same system of positional information. This idea has been tested by mixing cells of a defined fragment of the wing disc of Drosophila melanogaster with wing disc fragments of five other dipteran species to assay the ability of these disc fragments to stimulate intercalary regeneration of the D. melanogaster cells. The genetically marked (y; mwh) D. melanogaster fragment was mechanically mixed with wing discs or wing disc fragments of four drosophilids (D. melanogaster as a control, D. virilis, D. hydei, Zaprionus vittiger), of Musca domestica, and of Piophila casei. The mixed aggregates were cultured in vivo for 7 days, then metamorphosed in D. melanogaster larval hosts. The D. melanogaster fragments were only stimulated to regenerate when combined with complementary fragments from D. melanogaster or D. virilis wing discs. In the combination between D. melanogaster and D. hydei, the tissue formed integrated mosaic patterns, but no regeneration ensued. The one positive result (D. melanogaster mixed with D. virilis) shows that positional cues can be exchanged and correctly interpreted between cells of different species. The negative results do not prove that the mechanism for establishing patterns is different in the tested species, but may be due to incompatibilities that are not related to pattern formation.     

Prospective fates and regulative capacities of fragments of the female genital disc of Drosophila melanogaster.

A fate map of the female genital disc of Drosophila melanogaster was established by examining the derivatives of fragments transplanted into host larvae for metamorphosis. The fate map is presented as a two-dimensional projection, but for several reasons it is proposed that the anal plates originate from the dorsal epithelial layer whereas the genitalia are produced from the ventral layer. Fragments produced by cuts parallel to the axis of symmetry of the disc undergo regeneration during culture in adult hosts if the fragments comprise more than half of the disc, or duplication if they comprise less than half. Most of the fragments generated by bilaterally symmetrical cuts across the line of symmetry of the disc undergo neither regeneration nor duplication during culture, but with some such fragments there is a low frequency of regeneration. It is argued that the usual lack of regeneration in these fragments results from wound healing which confronts identical positions from right and left sides, giving no growth stimulation. The fragments which regenerate might do so as a result of healing between dorsal and ventral surfaces, providing the discontinuity in positional information which is thought to be involved in growth stimulation.     

Is regeneration inDrosophila the result of epimorphic regulation?

Summary It has been known for many years that when a wing disc ofDrosophila is bisected, and the fragments cultured in adult females, regulation occurs and either a complete disc is regenerated or the fragment is duplicated. We have investigated how this regeneration process occurs. To establish which cells contribute to the regenerate, and thus determine if regeneration is the result of epimorphic regulation, fragments of discs, after culture in an adult for one to five days, were exposed to³H-thymidine to label replicating cells. Imaginal discs, both whole and as regenerating fragments, undergo some DNA replication which is distributed throughout the disc, but cut discs frequently show clusters of labelled cells around the wound, indicating that regeneration is probably epimorphic.     

Localized cell death caused by mutations in a Drosophila gene coding for a transforming growth factor-beta homolog

Recessive mutations (dppdisk) in one region of the decapentaplegic (dpp) gene of Drosophila, which codes for a transforming growth factor-beta homolog, cause loss of distal parts from adult appendages. Different dppdisk alleles cause effects of different severity, the milder alleles removing distal parts and the more severe alleles removing progressively more proximal structures. In the wing disc derivatives, the most extreme dppdisk genotype removes the entire wing and leaves only a thorax fragment. We show that structures are lost in these mutants as a result of massive apoptotic cell death in the corresponding regions of the imaginal discs during the mid-third larval instar. The remaining disc fragments do not regenerate when cultured alone in the growth-permissive environment of the adult abdomen, but they can be made to regenerate by coculturing them with appropriate fragments of wild-type wing discs. This nonautonomous development is interpreted as showing that a product of dpp+, presumably the TGF-beta homolog, is secreted by the normal cells and can rescue the mutant cells in the mixed tissue.     

Wound healing and regenerative response of fragments of the Drosophila wing imaginal disc cultured in vitro

Fragments of imaginal discs of the fruitfly Drosophila undergo growth and pattern regulation when cultured in vivo in adult female hosts for several days prior to metamorphosis in host larvae. Pattern regulation results in either regeneration of excised pattern elements or duplication of elements whose fate map positions lay within the fragment. Initial wound healing along the cut edge of a fragment is thought to be a crucial first step in the process of pattern regulation. We have examined the capacity for wound healing and pattern regulation of fragments (distal halves) of the wing disc cultured in vitro, using the culture system recently reported to support extensive growth and transdetermination of slightly wounded whole imaginal discs in vitro. Our results suggest that disc fragments and whole discs apparently respond differently in the culture system. With disc fragments, wound healing did not occur in vitro. When fragments were first cultured overnight in adult female hosts to allow initial wound healing prior to explantation in vitro, then some volume increase and regeneration of excised portions occurred during 2–3 weeks of culture in vitro. The extent of apparent growth was much less than that reported for whole discs, and the frequency of regeneration in vitro (19%), while highly significant relative to controls not cultured in vitro (0%), was much less than that observed for fragments cultured in vivo (84%). Furthermore the extent of regeneration which occurred in vitro was considerably smaller than that which occurs during regeneration in vivo.     

Leg regeneration in insects. An experimental analysis in Drosophila and a new interpretation.

Fragments from prospective distal regions of Drosophila male foreleg imaginal discs failed to undergo proximal intercalary regeneration across leg segment borders when mechanically intermixed and cultured for 8 days with various fragments from prospective proximal disc regions. The failure of the distal cells to regenerate proximal leg segments was not due to a general restriction in their developmental potentials: Distal fragments, when deprived of their distal-most tips, regenerated in the distal direction at a high frequency. It is concluded that there exist in Drosophila leg discs the same restrictions with respect to regeneration along the proximodistal leg axis as had been previously observed in legs of several hemimetabolous insect species: Intersegmental discontinuities between grafted tissue pieces are not eliminated by intercalation. Based on the available evidence in hemimetabolous insects and in Drosophila, a new interpretation of the different aspects of regeneration in insect legs is offered. It is proposed that the two categories of regulative fields observed in insect legs, the leg segment fields and the whole leg field, represent the units of regulation for two fundamentally different regulative pathways that a cell at a wound edge can follow, the intercalative pathway and the terminal pathway, respectively. It is suggested that the criterion used by cells at healing wounds to choose between the two pathways is the difference in circumferential positional information between juxtaposed cells. The intercalative regulative pathway is switched on when cells with disparities in their axial positional information, or cells with less than maximal disparities in their circumferential information, contact one another. The terminal regulative pathway is triggered whenever cells with maximal circumferential disparities come into contact.     

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.     

Regulative Properties of Wing Discs from the Vestigial Mutant of Drosophila melanogaster

The vestigial (vg) mutant of Drosophila melanogaster shows reduced wing size and lacks margin structures from the wing blade. The expressivity is temperature-sensitive, more structures being formed at 29°C than at 25°C. There is cell death in the third instar wing disc which to some extent parallels the fate map locations of the structures absent in the adult.
Vestigial wing discs are unable to regenerate margin structures even when given extra time for growth by culturing them in an adult abdomen before metamorphosis. If the region of cell death is excised from the disc before culture, there is still no regeneration of margin structures, indicating that the dead cells do not physically prevent regulation. Furthermore, by metamorphosing young vg wing discs, it was discovered that cells never acquire competence to make margin during wing disc development. Experiments mixing fragments of vg wing disc with non- vg wing disc fragments of ebony multiple wing hairs (e mwh) genotype showed that the vg cells interacted with the e mwh cells and wing blade was intercalated of both genotypes. However, structures such as wing margin, and alar lobe, usually affected in vg wings, were always made from e mwh cells and not from vg cells. Analysis of mutants which are unable to differentiate particular cell types may help us to understand the mechanism of pattern establishment in developing imaginal discs.     

A non-destructive method for identifying the sex of ant larvae

The differences between adult male and female ants are often striking and obvious, yet both sexes appear virtually identical at the larval stage. Current methods for determining larval sex rely on genetic analyses or histology, both of which require killing all larvae examined. Here, we describe a method for identifying larval sex in vivo based on visible differences in genital imaginal discs. Using a light microscope, clear differences in genital disc morphology were observed between male and female larvae of the ponerine ant Harpegnathos saltator. Next, we investigated whether this technique could be broadly applied within ants and found similar differences in genital discs between male and female larvae of Aphaenogaster cockerelli and Camponotus floridanus. Taken together, our results show that genital discs can be used as a reliable indicator of larval sex in species from at least three major ant subfamilies. This technique should facilitate research into topics where information about larval sex is required.     

Distribution of S-phase cells during the regeneration of Drosophila imaginal wing discs

We investigated the distribution of S-phase cells during regeneration of the imaginal wing disc of Drosophila melanogaster following excision of 30 degrees, 90 degrees, and 150 degrees sectors of tissue. The fragments were cultured in adult abdomens for 1-5 days, labeled in vitro with tritiated thymidine, serially sectioned, and subjected to autoradiography. There was negligible thymidine incorporation in unoperated controls and in the undamaged parts of the operated discs, indicating that DNA synthesis in undamaged tissue is terminated during the first day of the culture period. Almost all of the fragments from which tissue had been removed, as well as controls which were simply cut without the removal of any tissue, showed a cluster of labeled cells (blastema) even after only 1 day of culture. The blastemas in control discs were short-lived, with over 50% of these discs showing no blastema by the third day in culture. Blastemas in discs from which sectors were removed were more persistent; the time at which 50% of the fragments no longer showed a blastema was 4 days for the -30 degrees fragments, 5 days for the -90 degrees fragments, and greater than 5 days for the -150 degrees fragments. The average blastema size, measured as number of labeled cells, was directly related to the amount of tissue removed, and in most cases did not change significantly during the culture period. Both wound edges incorporated tritiated thymidine initially and the S-phase cells remained tightly clustered throughout regeneration; maximum blastema width varied from about 8 to 25 cell diameters. The results are consistent with the idea that regenerative cell proliferation is stimulated and maintained by positional information discontinuities, and terminated when these discontinuities are resolved by the addition of an appropriate number of new cells.     

Regulative interaction of mature imaginal disc Fragments with embryonic and immature disc tissues inDrosophila

Summary These experiments examined whether inDrosophila immature imaginal disc tissue and tissues from embryonic stages can influence pattern regulation in a disc fragment in the same way as can mature imaginal discs. Immature imaginal discs, or the cells of whole embryos, were mixed with a test fragment (presumptive notum) from a mature wing disc. The immature tissues in each mixture were genetically marked and had been heavily irradiated (25 Kr gamma) prior to mixing to prevent growth and maturation during subsequent culture in vivo. Alteration of the regulative behavior of the test fragment (that is, regeneration of wing) thus provided an assay for the communication of positional information by the immature tissues. The results suggest that this capacity arises well before competence to metamorphose, as early as the 16th hour of embryonic development, whereas prior to 16 h, essentially no stimulation of regeneration occurred. It is suggested that the imaginal disc (or presumptive disc) cells of the embryo may have been responsible for this early stimulatory capacity.     

Development of the genitalia in Drosophila melanogaster

The imaginal discs of Drosophila melanogaster are an excellent material with which to analyze how signaling pathways and Hox genes control growth and pattern formation. The study of one of these discs, the genital disc, offers, in addition, the possibility of integrating the sex determination pathway into this analysis. This disc, whose growth and shape are sexually dimorphic, gives rise to the genitalia and analia, the more posterior structures of the fruit fly. Male genitalia, which develop from the ninth abdominal segment, and female genitalia, which develop mostly from the eighth one, display a characteristic array of structures. We will review here some recent findings about the development of these organs. As in other discs, different signaling pathways establish the positional information in the genital primordia. The Hox and sex determination genes modify these signaling routes at different levels to specify the particular growth and differentiation of male and female genitalia.     

Effects of engrailed in the genital disc of Drosophila melanogaster

engrailed has been postulated to be the “selector gene” involved in the establishment of the anterior-posterior compartment border in several imaginal discs and in at least the first two abdominal segments of Drosophila melanogaster. Our study of the effects of different mutant engrailed genotypes on genital disc development provided the following major results: All three terminal primordia (female and male genitalia, and analia) were affected. Different heteroallelic combinations showed different expressivities, and the three terminal primordia were differently affected by the same mutant genotype. The engrailed genotypes deleted specific elements of the adult terminalia without causing associated pattern duplications. The reduced morphology of the male engrailed genital disc was analogous to the pattern deletions observed in the adult terminalia. That the engrailed phenotype is stable was demonstrated by culturing in vivo intact and fragmented engrailed genital discs. Cell death was found in a significant number of mature male en²/en³ genital discs. The results are discussed in terms of the segmental organization of the genital disc and in terms of the “selector gene” function postulated for the engrailed locus. The interpretation that each terminal primordium has an anterior and a posterior compartment is presented and it is assumed that in the genital disc engrailed transforms posterior cells into anterior cells that do not develop, thereby causing the deficiency pattern of the engrailed phenotype.     

Distal transformation in Drosophila leg imaginal disc fragments.

For an appendage to regenerate distal elements, it has been thought that the stump must contain a full set of circumferential positional information. We have shown that this rule is not binding for tarsus regeneration in the male foreleg imaginal disc of Drosophila melanogaster. Distal transformation was not restricted to fragments containing complete proximal segments, but was also observed in pieces with small or even substantial deficiencies that were not regenerated in their proximal segments.     

Chironomus tentans epithelial cell lines sensitive to ecdysteroids, juvenile hormone, insulin and heat shock

A new culture medium, ZW, and the preparation of an extract of adult Drosophila, FX, are described, which for the first time allow the in vitro proliferation of normal Drosophila cells in the absence of undefined heterologous components. Cells from 6-hour-old Drosophila embryos can extensively differentiate and/or proliferate in ZW supplemented with FX and insulin. Cells isolated from wing discs of 90–120-hour-old larvae require ecdysterone for proliferation in ZW, in addition to FX and insulin. Explanted ovaries, testes, genital discs and intact or halved wing discs of 100-hour-old larvae grow in the same medium, at least in part due to cell proliferation. High concentrations of ecdysterone prevent differentiation and/or proliferation of cells from embryos and from wing discs and cause the lysis of most isolated imaginal disc cells grown in vitro, while cuticular differentiations are induced in wing discs and disc fragments grown in vitro.     

Pattern Regulation of the Leg Disc of the Fleshfly, Sarcophaga peregeina

A fate map of the hind leg disc of Sarcophaga peregrina was constructed by examining the adult structures of implanted disc fragments. The locations of presumptive adult structures in the disc were similar to those of fore leg disc of Drosophila and Sarcophaga ruficornis . However, the concentric borderlines of the segments could not be ascertained in the present case.
Pattern regulation of disc fragments was studied by culturing them either in adult females for several days or for 3 days in mature larvae placed on wet condition. Cultured disc fragments regenerated or duplicated as in Drosophila , with some exceptions. For instance, the region with a high density of positional values, the upper medial quarter, of the fore leg disc of Drosophila was not found. A characteristic difference in the rate of regeneration or duplication was observed in the implanted fragments, when cultured in larvae or adult hosts. This variable pattern regulation in larval and adult hosts could be due to different compositions of the hemolymph in which would healing of the implanted disc fragments takes place.     

Allocation and specification of the genital disc precursor cells in Drosophila

The adult structures of Drosophila melanogaster are derived from larval imaginal discs, which originate as clusters of cells within the embryonic ectoderm. The genital imaginal disc is composed of three primordia (female genital, male genital, and anal primordia) that originate from the embryonic tail segments A8, A9, and A10, respectively, and produce the sexually dimorphic genitalia and analia. We show that the genital disc precursor cells (GDPCs) are first detectable during mid-embryogenesis as a 22-cell cluster in the ventral epidermis. Analysis of mutant and double mutant phenotypes of embryonic patterning genes in the GDPCs, together with their expression patterns in these cells, revealed the following with respect to the origins and specification of the GDPCs. The allocation of the GDPCs from the ventral epidermis requires the function of ventral patterning genes, including the EGF receptor and the spitz group of genes. The ventral localization of the GDPCs is further restricted by the action of dorsal patterning genes. Along the anterior-posterior axis, several segment polarity genes (wingless, engrailed, hedgehog, and patched) are required for the proper allocation of the GDPCs. These segment polarity genes are expressed in some, but not all of the GDPCs, indicating that anterior and posterior compartments are not fully established in the GDPCs. In addition, we found that the three primordia of the larval genital disc have already been specified in the GDPCs by the coordinated actions of the homeotic (Hox) genes, abdominal-A, Abdominal-B, and caudal. By identifying how these different patterning networks regulate the allocation and primordial organization of the 22 embryonic precursors of the compound genital disc, we demonstrate that at least some of the organization of the larval disc originates as positional information in the embryo, thus providing a context for further studies on the development of the genital disc.     

The development of the Drosophila genital disc

The imaginal discs of Drosophila melanogaster, which form the adult epidermal structures, are a good experimental model for studying morphogenesis. The genital disc forms the terminalia, which are the most sexually dimorphic structures of the fly. Both sexes of Drosophila have a single genital disc formed by three primordia. The female genital primordium is derived from 8(th) abdominal segment and is located anteriorly, the anal primordium (10 and 11(th) abdominal segments) is located posteriorly, and the male genital primordium from the 9(th) abdominal segment lies between them. In both sexes, only two of these three primordia develop to form the adult terminalia. The anal primordium develops in both sexes but, depending on the genetic sex, will form either male or female analia. However, only one of the genital primordia develops in each sex, forming either the male or the female genitalia. This depends on the genetic sex of the fly. Therefore, the genital disc is a very good experimental model of how the sex-determination and homeotic genes - which determine cell identity - interact to direct the development of a population of cells into male or female terminalia. It has been proposed that the sexually dimorphic development of the genital disc is the result of an integrated genetic input, made up by the sex-determination gene doublesex and the homeotic gene Abdominal-B. This input acts by modulating the response to Hedgehog, Wingless, and Decapentaplegic morphogenetic signals.