Abstract

The final body size of any given individual underlies both genetic and environmental constraints. Both mammals and insects use target of rapamycin (TOR) and insulin signaling pathways to coordinate growth with nutrition. In holometabolous insects, the growth period is terminated through a cascade of peptide and steroid hormones that end larval feeding behavior and trigger metamorphosis, a nonfeeding stage during which the larval body plan is remodeled to produce an adult. This irreversible decision, termed the critical weight (CW) checkpoint, ensures that larvae have acquired sufficient nutrients to complete and survive development to adulthood. How insects assess body size via the CW checkpoint is still poorly understood on the molecular level. We show here that the Drosophila transcription factor Snail plays a key role in this process. Before and during the CW checkpoint, snail is highly expressed in the larval prothoracic gland (PG), an endocrine tissue undergoing endoreplication and primarily dedicated to the production of the steroid hormone ecdysone. We observed two Snail peaks in the PG, one before and one after the molt from the second to the third instar. Remarkably, these Snail peaks coincide with two peaks of PG cells entering S phase and a slowing of DNA synthesis between the peaks. Interestingly, the second Snail peak occurs at the exit of the CW checkpoint. Snail levels then decline continuously, and endoreplication becomes nonsynchronized in the PG after the CW checkpoint. This suggests that the synchronization of PG cells into S phase via Snail represents the mechanistic link used to terminate the CW checkpoint. Indeed, PG-specific loss of snail function prior to the CW checkpoint causes larval arrest due to a cessation of endoreplication in PG cells, whereas impairing snail after the CW checkpoint no longer affected endoreplication and further development. During the CW window, starvation or loss of TOR signaling disrupted the formation of Snail peaks and endocycle synchronization, whereas later starvation had no effect on snail expression. Taken together, our data demonstrate that insects use the TOR pathway to assess nutrient status during larval development to regulate Snail in ecdysone-producing cells as an effector protein to coordinate endoreplication and CW attainment.

Highlights

  • Steroid hormones are phylogenetically ancient signaling molecules found in animals and plants alike, where they control a wide range of developmental and physiological processes, such as sexual maturation, reproduction, glucose, and cholesterol metabolism as well as inflammatory responses [1,2]

  • The dependency of endoreplication on target of rapamycin (TOR) was not seen after the attainment of critical weight (CW) [18,23]. These findings provide a framework for understanding the mechanisms underlying the CW checkpoint that involves (1) a downstream component that irreversibly up-regulates ecdysone production after CW attainment to trigger metamorphosis; (2) a temporary window that allows to couple nutrient sensing in the larval prothoracic gland (PG) to ecdysone synthesis; and (3) the potential importance of endoreplication as a signal that is linked to the CW checkpoint

  • We demonstrated that snail is dynamically expressed in the PG, the main endocrine organ for ecdysone biosynthesis during larval stage

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Summary

Introduction

Steroid hormones are phylogenetically ancient signaling molecules found in animals and plants alike, where they control a wide range of developmental and physiological processes, such as sexual maturation, reproduction, glucose, and cholesterol metabolism as well as inflammatory responses [1,2]. Since snail overexpression in the PG blocks developmental progression (Fig 2D), it was possible that the endocycle arrest in the PG was an unrelated defect caused by delayed development To rule out this possibility, we took advantage of the flip-out-Gal system to overexpress snail in a mosaic manner, which allowed us to compare snail-overexpressing and control cells within the same tissue. Promoting S-phase entry by overexpressing CycE-cDNA did not rescue the L3 arrest phenotype in PG>snail-RNAi animals (S4 Fig) These results suggested that snail has more complex roles in the PG than controlling ecdysone biosynthesis and endocycling. We would predict that Snail-depleted animals will keep feeding and never initiate metamorphosis because of a failure in up-regulating ecdysone biosynthesis To test this hypothesis, we measured the DNA content of PG cells for both controls and snail-RNAi animals throughout the L3 stage, when the enhanced GFP (EGFP) marks PG cells.

Discussion
Findings
Materials and methods

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