The Pleiotropic Roles of FGLamide Allatostatins in the African Migratory Locust, Locusta migratoria

The FGLa/ASTs are one family of allatostatin peptides and share an amidated C-terminal sequence (FGL-amide). The inhibitory effect of FGLa/ASTs on juvenile hormone (JH) biosynthesis in Diploptera punctata led to their discovery, but there is a lack of allatostatic function across most insect species...

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Bibliographic Details
Main Author: Robertson, Lisa
Other Authors: Lange, Angela
Language:en_ca
Published: 2013
Subjects:
Online Access:http://hdl.handle.net/1807/35942
Description
Summary:The FGLa/ASTs are one family of allatostatin peptides and share an amidated C-terminal sequence (FGL-amide). The inhibitory effect of FGLa/ASTs on juvenile hormone (JH) biosynthesis in Diploptera punctata led to their discovery, but there is a lack of allatostatic function across most insect species that suggests this function may not be their primary role. Rather, the FGLa/ASTs are implicated as brain/gut peptides, modulating gut physiology. This thesis demonstrates the pleiotropic nature of FGLa/ASTs in Locusta migratoria and emphasizes the role of FGLa/ASTs as brain/gut peptides involved in homeostatic processes. FGLa/AST-like immunoreactivity (FLI) is associated with the corpus cardiacum (CC) and corpus allatum (CA). FGLa/ASTs increase adipokinetic hormone release from the CC and alter JH biosynthesis from the CA, suggesting roles in energy utilization and in growth and metamorphosis. Each region of the gut exhibits FLI. The gut is dually innervated: neurons in the abdominal ganglia of the central nervous system (CNS) innervate the posterior gut and some contain FLI, while neurons within the stomatogastric nervous system (STNS) that innervate the anterior gut do not seem to contain FLI, indicating that source of FLI on the gut are cells within the CNS, which may release FGLa/ASTs at the gut to alter aspects of gut physiology. FGLa/ASTs are involved in peristalsis, neural control of foregut contractions, and ileal K+ transport. In particular, FGLa/ASTs inhibit contractions of each gut region and also modulate the rhythmic motor output of a central pattern generator within the ventricular ganglion of the STNS. FGLa/ASTs also inhibit ileal K+ efflux, suggesting a diuretic action and implicating FGLa/ASTs in fluid and ion homeostasis. This work provides a comprehensive picture of how FGLa/ASTs play an integral role in nutrient processing, energy mobilization, and growth and metamorphosis to contribute to the overall maintenance of homeostasis. This reinforces the role of FGLa/ASTs as brain/gut peptides and emphasizes their involvement in the flexibility of nervous communication and integration of the endocrine system with the CNS to achieve homeostasis.