Cell competition employs comparisons of fitness to selectively eliminate cells sensed as less healthy. In Drosophila, apoptotic elimination of the weaker “loser” cells from growing wing discs is ...induced by a signaling module consisting of the Toll ligand Spätzle (Spz), several Toll-related receptors, and NF-κB factors. How this module is activated and restricted to competing disc cells is unknown. Here, we use Myc-induced cell competition to demonstrate that loser cell elimination requires local wing disc synthesis of Spz. We identify Spz processing enzyme (SPE) and modular serine protease (ModSP) as activators of Spz-regulated competitive signaling and show that “winner” cells trigger elimination of nearby WT cells by boosting SPE production. Moreover, Spz requires both Toll and Toll-8 to induce apoptosis of wing disc cells. Thus, during cell competition, Spz-mediated signaling is strictly confined to the imaginal disc, allowing errors in tissue fitness to be corrected without compromising organismal physiology.
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•In Myc super-competition, Spz signals via Toll and Toll-8 to kill loser cells•Spz is activated for competitive signaling by the proteases SPE and ModSP•Regulation of protease production and receptor expression by Myc allows “cheating”•Wing disc-restricted Spz keeps competitive signaling isolated from immune tissues
Low levels of the Toll ligand Spätzle and its activating proteases are synthesized continuously by wing disc cells, but signaling is unproductive. Alpar et al. show that Myc super-competitor cells boost production of the proteases, thereby triggering Spätzle activation and inducing a killing signal that selectively eliminates nearby wild-type cells.
Regeneration and tissue repair allow damaged or lost body parts to be replaced. After injury or fragmentation of Drosophila imaginal discs, regeneration leads to the development of normal adult ...structures. This process is likely to involve a combination of cell rearrangement and compensatory proliferation. However, the detailed mechanisms underlying these processes are poorly understood. We have established a system to allow temporally restricted induction of cell death in situ. Using Gal4/Gal80 and UAS-rpr constructs, targeted ablation of a region of the disc could be performed and regeneration monitored without the requirement for microsurgical manipulation. Using a ptc-Gal4 construct to drive rpr expression in the wing disc resulted in a stripe of dead cells in the anterior compartment flanking the anteroposterior boundary, whereas a sal-Gal4 driver generated a dead domain that includes both anterior and posterior cells. Under these conditions, regenerated tissues were derived from the damaged compartment, suggesting that compartment restrictions are preserved during regeneration. Our studies reveal that during regeneration the live cells bordering the domain in which cell death was induced first display cytoskeletal reorganisation and apical-to-basal closure of the epithelium. Then, proliferation begins locally in the vicinity of the wound and later more extensively in the affected compartment. Finally, we show that regeneration of genetically ablated tissue requires JNK activity. During cell death-induced regeneration, the JNK pathway is activated at the leading edges of healing tissue and not in the apoptotic cells, and is required for the regulation of healing and regenerative growth.
To understand the cellular parameters that govern Drosophila wing disc regeneration, we genetically eliminated specific stripes of the wing disc along the proximodistal axis and used vein and ...intervein markers to trace tissue regeneration. We found that veins could regenerate interveins and vice versa, indicating respecification of cell fates. Moreover, respecification occurred in cells close to the wound. The newly generated domains were intercalated to fill in the missing parts. This intercalation was driven by increased proliferation, accompanied by changes in the orientation of the cell divisions. This reorientation depended on Fat (Ft) and Crumbs (Crb), which acted, at least partly, to control the activity of the effector of the Hippo pathway, Yorkie (Yki). Increased Yki, which promotes proliferation, affected the final shape and size. Heterozygous ft or crb, which normally elicit size and shape defects in regenerated wings, could be rescued by yki heterozygosity. Thus, Ft and Crb act as sensors to drive cell orientation during intercalary regeneration and control Yki levels to ensure a proper balance between proliferation and cell reorientation. We propose a model based on intercalation of missing cell identities, in which a coordinated balance between orientation and proliferation is required for normal organ shape and size.
Many animals display a capacity to regenerate tissues or even a complete body. One of the main goals of regenerative biology is to identify the genes and genetic networks necessary for this process. ...Drosophila offers an ideal model system for such studies. The wide range of genetic and genomic approaches available for use in flies has helped in initiating the deciphering of the mechanisms underlying regeneration, and the results may be applicable to other organisms, including mammals. Moreover, most models of regeneration require experimental manipulation, whereas in Drosophila discrete domains can be ablated by genetically induced methods. Here, we present a summary of current research into imaginal disc regeneration and discuss the power of this tissue as a tool for understanding the genetics of regeneration.
Exploring the mechanisms involved in tissue regeneration is one of the main challenges in biology and biomedicine. Multiple examples of tissue regeneration exist across the animal phyla, ranging from ...the recovery of the whole animal (e.g. flatworms) to the limited capability of the human liver. Studies performed in the 1960s showed that Drosophila imaginal discs are able to regenerate. This property, together with multiple genetic tools available, make fly an excellent model for the study of the regenerative process. Here we present an overview of the use of Drosophila for the study of regeneration and describe major recent advances in the understanding of this process. Current studies in Drosophila have unraveled some of the pathways and factors needed for a tissue to regenerate. Many observations point to the reuse of developmental programs and genetic reprogramming to drive regeneration. We discuss how this reprogramming could be orchestrated by the initial activity of the JNK pathway.
Mosaic Analysis in Drosophila Germani, Federico; Bergantinos, Cora; Johnston, Laura A
Genetics (Austin),
02/2018, Letnik:
208, Številka:
2
Journal Article
Recenzirano
Odprti dostop
Since the founding of
genetics by Thomas Hunt Morgan and his colleagues over 100 years ago, the experimental induction of mosaicism has featured prominently in its recognition as an unsurpassed ...genetic model organism. The use of genetic mosaics has facilitated the discovery of a wide variety of developmental processes, identified specific cell lineages, allowed the study of recessive embryonic lethal mutations, and demonstrated the existence of cell competition. Here, we discuss how genetic mosaicism in
became an invaluable research tool that revolutionized developmental biology. We describe the prevailing methods used to produce mosaic animals, and highlight advantages and disadvantages of each genetic system. We cover methods ranging from simple "twin-spot" analysis to more sophisticated systems of multicolor labeling.
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