Regeneration following duplication in imaginal wing disc fragments of Drosophila melanogaster

Fragments from the imaginal wing disc of Drosophila melanogaster were cultured in vivo for periods up to 28 days. One type of edge fragment first duplicated and then ceased to grow, but others often continued to grow following initial duplication and regenerated structures characteristic of other areas of the disc. After 28 days of culture, about 50% of fragments from the presumptive ventral hinge region of the disc grew extensively and produced regenerated as well as original structures. The regenerated structures in some implants were produced at the line of mirror-image symmetry. Regeneration was associated with fragment growth and in many cases was accompanied by loss of duplicate structures. Fragments which were only duplicated after the culture period could in some cases be stimulated to grow by additional culture in fresh hosts, but the results of coculturing two fragments in each host show that culture conditions alone do not control growth and regulation in the fragments. The large, normally regenerating fragment, complementary to the ventral fragment, did not appear to grow following regeneration and only occasionally produced supernumerary structures during prolonged culture. Intact wing discs cultured under similar conditions never produced supernumerary structures. Our results suggest that a duplicated pattern is less stable than a complete, regenerated pattern, which in turn is less stable than an intact disc. We propose that the growth of duplicated disc fragments is stimulated by polarity reversals present at lines of mirror-image symmetry.     

Growth dynamics in the regeneration of a fragment of the wing imaginal disc of Drosophila melanogaster

Regen rating fragments of wing imaginal discs were cultured in vivo for various periods up to 1 week. At specified times the fragments were removed, macerated, and the resulting cell counts were compared to similar counts made on the contralateral intact disc. Significant growth was seen beginning on the second day if the hosts were transferred to fresh media daily, while seen only on Day 4 and not thereafter if hosts were maintained on the same media throughout the culture period.     

Wound healing in the imaginal discs of Drosophila. I. Scanning electron microscopy of normal and healing wing discs.

Scanning electron microscopy was used to investigate the morphology of intact imaginal wing discs of third-instar larvae of Drosophila melanogaster. The disc stalk, nerve and tracheal entries and the surface ultrastructure of the columnar cells, the peripodial membrane cells, and the adepithelial cells are described. The behavior of various fragments of the wing disc during culture in vivo was also studied. After injuring a wing disc by cuts with a tungsten needle, during the first day of culture the epithelium curls and the wound surface contracts. Subsequent closure of the wound in $\text{3}\text{4}$ and $\text{1}\text{4}$ sectors, in fragments generated by straight cuts and in central squares, leads to the confrontations of cells from formerly separate positions, as was proposed in connection with the polar coordinate model of French, Bryant, and Bryant [(1976). Pattern regulation in epimorphic fields. Science193, 969–981]. Wound healing comprises three steps: (1) Cell debris is removed; (2) occasional cell processes span the wound; (3) all cells at the wound edge contact cells on the opposite side. After 2–3 days, a continuous epithelium is re-established. The tissue distortion may lead to transient contacts of the columnar epithelium with the peripodial membrane and with itself. The latter can explain the occasional duplications of structures which, according to the fate map, arise from near the wound edge, and which have been previously reported from cultured imaginal disc fragments. The tissue movements appear to be due to the contractile properties of individual cells.     

Role of Jun N-terminal Kinase (JNK) signaling in the wound healing and regeneration of a Drosophila melanogaster wing imaginal disc

When a fragment of a Drosophila imaginal disc is cultured in growth permissive conditions, it either regenerates the missing structures or duplicates the pattern present in the fragment. This kind of pattern regulation is known to be epimorphic, i.e. the new pattern is generated by proliferation in a specialized tissue called the blastema. Pattern regulation is accompanied by the healing of the cut surfaces restoring the continuous epithelia. Wound healing has been considered to be the inductive signal to commence regenerative cell divisions. Although the general outlines of the proliferation dynamics in a regenerating imaginal disc blastema have been well studied, little is known about the mechanisms driving cells into the regenerative cell cycles. In this study, we have investigated the role of Jun N-terminal Kinase (JNK) signaling in the wound healing and regeneration of a Drosophila wing imaginal disc. By utilizing in vivo and in vitro culturing of incised and fragmented discs, we have been able to visualize the dynamics in cellular architecture and gene expression involved in the healing and regeneration process. Our results directly show that homotypic wound healing is not a prerequisite for regenerative cell divisions. We also show that JNK signaling participates in imaginal disc wound healing and is regulated by the physical dynamics of the process, as well as in recruiting cells into the regenerative cell cycles. A model describing the determination of blastema size is discussed.     

Growth during pattern regulation in imaginal discs

Fragments of imaginal discs of Drosophila regenerate or duplicate when they are cultured in vivo. This pattern regulation is generally believed to occur by epimorphosis. That is, cells at the wound edge proliferate and fill in the missing positional values by intercalation. It is suggested that no respecification of the positional values of cells away from the wound edge occurs. I report here data on fragment growth during culture that are incompatible with the epimorphic model. I argue that both respecification of existing cells and the generation of new cells by growth are involved in pattern regulation.     

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.     

Wound healing and regeneration in the imaginal wing disc ofDrosophila

Summary When complementary fragments of an imaginal disc ofDrosophila are cultured for several days prior to metamorphosis, usually one fragment will regenerate while the other will duplicate. It has been proposed that wound healing plays an important part in disc regulation (French et al. 1976; Reinhardt et al. 1977) by initiating cell proliferation and determining the mode of regulation. We tried to delay the wound healing process by leaving a region of dead cells between the wound edges. In 06 fragments (Bryant 1975a) wound healing has occurred after 1–2 days of culture and the regeneration of missing structures after 2–4 days of culture. We observed that leaving a region of dead cells between the wound edges delays both wound healing and the regeneration of missing structures by 2 days.When disc fragments are cultured in female abdomens and then exposed to³H-thymidine to label replicating cells, then the label is found to be localised around the wound. We observed that delaying wound healing does not delay this localisation of labelled nuclei indicating that wound healing may not be required to initiate DNA replication.     

Three genes control the timing, the site and the size of blastema formation in Drosophila

Regeneration is a vital process to maintain and repair tissues. Despite the importance of regeneration, the genes responsible for regenerative growth remain largely unknown. In Drosophila, imaginal disc regeneration can be induced either by fragmentation and in vivo culture or in situ by ubiquitous expression of wingless (wg/wnt1). Imaginal discs, like appendages in lower vertebrates, initiate regeneration by wound healing and proliferation at the wound site, forming a regeneration blastema. Most blastema cells maintain their disc-specific identity during regeneration; a few cells however, exhibit stem-cell like properties and switch to a different fate, in a phenomenon known as transdetermination. We identified three genes, regeneration (rgn), augmenter of liver regeneration (alr) and Matrix metalloproteinase-1 (Mmp1) expressed specifically in blastema cells during disc regeneration. Mutations in these genes affect both fragmentation- and wg-induced regeneration by either delaying, reducing or positioning the regeneration blastema. In addition to the modifications of blastema homeostasis, mutations in the three genes alter the rate of regeneration-induced transdetermination. We propose that these genes function in regenerative proliferation, growth and regulate cellular plasticity.     

Protein synthetic patterns during differentiation of imaginal discs in vitro.

Leg, wing, and eye-antennal imaginal discs of Drosophila melanogaster were obtained by dissection from late-third instar larvae and cultured in vitro in Schneider's medium containing β-ecdysone. Differentiation of adult structures was obtained in more than 90% of all cultures. Differentiation was somewhat slower than normal in vivo development, but synchronous, repeatable, and reasonably completed structures were obtained. Our initial efforts at analyzing the molecular events of imaginal disc differentiation in culture have been to study the protein synthetic pattern which occurs throughout the culture period. Discs were pulse labeled with [³⁵S]methionine, and the proteins were separated by SDS-gel electrophoresis. Analysis of the synthetic pattern was done by autoradiography of these gels using X-ray film. In all three disc types, pronounced changes in protein synthetic patterns occurred throughout the culture period. These changes appeared to be under strict temporal control. Although disc-specific differences could be seen, a comparison of the three discs types revealed a striking similarity in the changes which occurred in the patterns of protein synthesis during the 5-day culture period. In general, the protein synthetic patterns of different imaginal discs at the same period during differentiation showed greater similarities than the patterns of a single disc type at different periods. These results are consistent with a view of differentiation as a tightly controlled program of gene activation and deactivation operating throughout the differentiation process.     

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.     

Protein synthesis and accumulation in Drosophila melanogaster imaginal discs: Identification of a protein with a nonrandom spatial distribution

Proteins from Drosophila imaginal discs and disc fragments were analyzed on two-dimensional electrophoretic gels following labeling in vitro with [³⁵S]methionine. The protein synthetic pattern in autoradiograms is very complex and parallels the pattern of protein accumulation visualized in silver-stained gels. We find no reproducible qualitative differences in the proteins synthesized or accumulated by different disc types. Additionally, analysis of the proteins synthesized by different fragments of wing and haltere discs has resulted in the identification of a polypeptide which is synthesized preferentially in homologous regions of these two imaginal discs. Scanning densitometry of our autoradiograms corroborates these findings. This protein, therefore, has some of the properties one would predict for a molecule involved in the imaginal disc positional information system.     

Conditions for the primary culture of eye imaginal discs from Drosophila melanogaster

We have established a primary culture system for Drosophila eye imaginal discs. With this system, we were able to obtain neurite outgrowth from intact eye discs, eye disc fragments, and dissociated eye imaginal disc cells. Immunoreactivity to antibody 24B10 indicates that these extending neurites are photoreceptor axons. Three culture media were tested for their ability to support the survival of and neurite extension from eye disc fragments in vitro at 23°C. These, with supplements, were: five parts of Schneider's Drosophila medium with four parts of basal Eagle's medium (“4+5”); Leibovitz's L-15 medium (L-15); and Shields and Sang's M3 modified medium (MM3). We obtained the best results with MM3 supplemented with 2% fetal bovine serum (FBS). Eye disc fragments survived in this medium for at least 20 days. Pigmentation in the nonphotoreceptor pigment cells in cultures from the prepupa required the presence of 20-hydroxyecdysone (20-HE) (1 μg/ml), whereas neurite outgrowth was seen in the absence of 20-HE. Donor animals had to fall within a range of ages to obtain appropriate eye disc differentiation in vitro. Eye discs from 5-h pupae (P+5) or older commenced ommachrome synthesis in vitro, in a temporal sequence close to that found in vivo, whereas the in vitro synthesis of this pigment was delayed in eye discs from younger flies. Average neurite length was not affected by age among pupae younger than P+5; but neurite outgrowth from P+24 was scarce, probably because by this time photoreceptor axons had already grown in vivo and were severed and unable to regenerate in vitro. Eye discs taken from third instar larvae or white prepupae continued their mitotic activity in vitro. Together with the advance of the morphogenetic furrow at the leading edge of retinal development, this observation is consistent with the evidence that pattern formation continues in vitro. Morphogenetic changes were manifested in cultures. Viability tests with calcein AM and ethidium bromide revealed few dead cells in living cultures. © 1995 John Wiley & Sons, Inc.     

Innate immune cells are dispensable for regenerative growth of imaginal discs

Following tissue damage the immune response, including inflammation, has been considered an inevitable condition to build the host defense against invading pathogens. The recruitment of innate immune leukocytes to injured tissue is observed in both vertebrates and invertebrates. However, it is still not conclusive whether the inflammatory response is also indispensable for the wound healing process by itself, in addition to its role in microbial clearance. In this study we determine the requirement of innate immune cells, both hemocytes and fat body cells, in Drosophila imaginal disc regeneration. We investigate wound healing and regenerative cell proliferation of damaged imaginal discs under immunodeficient conditions. To delay development of Drosophila at matured third instar larval stage we used a sterol-mutant erg2 knock-out yeast strain in the medium. This dietary-controlled developmental arrest allowed us to generate larvae free of immune cells without interfering with their larval development. In addition, this approach allowed uncoupling regenerative cell proliferation of damaged discs from their normal developmental growth. We furthermore examined the regenerative cell proliferation of fragmented imaginal discs by transplantation into host flies deficient of immune cells. We demonstrate that the damaged/fragmented discs in immune cells deficient conditions still exhibit regenerative cell proliferation comparable to those of control samples. These results suggest that recruitment of immune cells is not a prerequisite for the regenerative growth of damaged imaginal discs.     

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.     

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.     

Transdetermination of Drosophila imaginal discs cultured in vitro

Imaginal discs of Drosophila melanogaster undergo transdetermination when cultured in vivo in the abdominal cavity of adult female hosts. We report here that leg discs cultured in vitro, in a recently developed system, also undergo transdetermination. Whether cultured in vivo or in vitro, leg discs produce a similar range of specific transdetermined structures. Moreover, in comparison to discs cultured in vivo, the discs cultured in vitro exhibit a similar correlation between the amount of growth and the total frequency of transdetermination.     

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.     

Towards Long Term Cultivation of Drosophila Wing Imaginal Discs In Vitro

The wing imaginal disc of Drosophila melanogaster is a prominent experimental system for research on control of cell growth, proliferation and death, as well as on pattern formation and morphogenesis during organogenesis. The precise genetic methodology applicable in this system has facilitated conceptual advances of fundamental importance for developmental biology. Experimental accessibility and versatility would gain further if long term development of wing imaginal discs could be studied also in vitro. For example, culture systems would allow live imaging with maximal temporal and spatial resolution. However, as clearly demonstrated here, standard culture methods result in a rapid cell proliferation arrest within hours of cultivation of dissected wing imaginal discs. Analysis with established markers for cells in S- and M phase, as well as with RGB cell cycle tracker, a novel reporter transgene, revealed that in vitro cultivation interferes with cell cycle progression throughout interphase and not just exclusively during G1. Moreover, quantification of EGFP expression from an inducible transgene revealed rapid adverse effects of disc culture on basic cellular functions beyond cell cycle progression. Disc transplantation experiments confirmed that these detrimental consequences do not reflect fatal damage of imaginal discs during isolation, arguing clearly for a medium insufficiency. Alternative culture media were evaluated, including hemolymph, which surrounds imaginal discs during growth in situ. But isolated larval hemolymph was found to be even less adequate than current culture media, presumably as a result of conversion processes during hemolymph isolation or disc culture. The significance of prominent growth-regulating pathways during disc culture was analyzed, as well as effects of insulin and disc co-culture with larval tissues as potential sources of endocrine factors. Based on our analyses, we developed a culture protocol that prolongs cell proliferation in cultured discs.