Neurotransmitters Affect Larval Development by Regulating the Activity of Prothoracicotropic Hormone-Releasing Neurons in Drosophila melanogaster.

Shun Hao,Li Liu,Julia Yvonne Gestrich,Hongying Wei,Xin Zhang,Mengbo Xu,Xinwei Wang

doi:10.3389/fnins.2021.653858

Abstract

Ecdysone, an essential insect steroid hormone, promotes larval metamorphosis by coordinating growth and maturation. In Drosophila melanogaster, prothoracicotropic hormone (PTTH)-releasing neurons are considered to be the primary promoting factor in ecdysone biosynthesis. Recently, studies have reported that the regulatory mechanisms of PTTH release in Drosophila larvae are controlled by different neuropeptides, including allatostatin A and corazonin. However, it remains unclear whether neurotransmitters provide input to PTTH neurons and control the metamorphosis in Drosophila larvae. Here, we report that the neurotransmitters acetylcholine (ACh) affect larval development by modulating the activity of PTTH neurons. By downregulating the expression of different subunits of nicotinic ACh receptors in PTTH neurons, pupal volume was significantly increased, whereas pupariation timing was relatively unchanged. We also identified that PTTH neurons were excited by ACh application ex vivo in a dose-dependent manner via ionotropic nicotinic ACh receptors. Moreover, in our Ca2+ imaging experiments, relatively low doses of OA caused increased Ca2+ levels in PTTH neurons, whereas higher doses led to decreased Ca2+ levels. We also demonstrated that a low dose of OA was conveyed through OA β-type receptors. Additionally, our electrophysiological experiments revealed that PTTH neurons produced spontaneous activity in vivo, which provides the possibility of the bidirectional regulation, coming from neurons upstream of PTTH cells in Drosophila larvae. In summary, our findings indicate that several different neurotransmitters are involved in the regulation of larval metamorphosis by altering the activity of PTTH neurons in Drosophila.

Highlights

Animal development is a precise and complex process that allows each animal to choose the optimal time and appropriate environment for completing the transition from juvenile to adult
The endocrine physiology of vertebrates and insects shows intriguing parallels and homologies. In both vertebrates and insects, steroid hormone biosynthesis is controlled by peptide hormones: for example, ecdysone synthesis is controlled by prothoracicotropic hormone (PTTH) in insects, and glucocorticoids of the adrenal glands are regulated by adrenocorticotropic hormone (ACTH), a functional ortholog of PTTH, in vertebrates
We focused on neurotransmitter signaling to PTTH neurons, through which PTTH release can be procedurally regulated in Drosophila larvae to ensure normal development before the transition to adult flies

Summary

Introduction

Animal development is a precise and complex process that allows each animal to choose the optimal time and appropriate environment for completing the transition from juvenile to adult. Adaptive mechanisms have evolved to generate optimized outputs in many species, and to maximize survival in varying natural circumstances, through neuroendocrine signaling (Gotthard and Nylin, 1995; Denver, 1997; Lessells, 2008) In insects, this transition is mainly controlled by the combined endocrine effects of several pivotal hormones and neuropeptides, including ecdysone, which is the master regulator of metamorphosis. The endocrine physiology of vertebrates and insects shows intriguing parallels and homologies In both vertebrates and insects, steroid hormone biosynthesis is controlled by peptide hormones: for example, ecdysone synthesis is controlled by PTTH in insects, and glucocorticoids of the adrenal glands are regulated by adrenocorticotropic hormone (ACTH), a functional ortholog of PTTH, in vertebrates. Both of them show a pulsatile mode of secretion and promote the release of cortisol and ecdysone, respectively, which ensures the normal development and maturation of individuals at the proper time (Lightman and Conway-Campbell, 2010; McBrayer et al, 2007; Rewitz et al, 2009a; Stavreva et al, 2009; Nässel and Winther, 2010; Tennessen and Thummel, 2011; Di Cara and King-Jones, 2016)

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Results

Conclusion