Abstract
Insulin is present all across the animal kingdom. Its proper release after feeding is of extraordinary importance for nutrient uptake, regulation of metabolism, and growth. We used Drosophila melanogaster to shed light on the processes linking dietary leucine intake to insulin secretion. The Drosophila genome encodes 8 insulin-like peptides (“Dilps”). Of these, Dilp2 is secreted after the ingestion of a leucine-containing diet. We previously demonstrated that Minidiscs, related to mammalian system-L transporters, acts as a leucine sensor within the Dilp2-secreting insulin-producing cells (“IPCs”) of the brain. Here, we show that a second leucine transporter, JhI-21, of the same family is additionally necessary for proper leucine sensing in the IPCs. Using calcium imaging and ex-vivo cultured brains we show that knockdown of JhI-21 in IPCs causes malfunction of these cells: they are no longer able to sense dietary leucine or to release Dilp2 in a leucine dependent manner. JhI-21 knockdown in IPCs further causes systemic metabolic defects including defective sugar uptake and altered growth. Finally, we showed that JhI-21 and Minidiscs have no cumulative effect on Dilp2 release. Since system-L transporters are expressed by mammalian β-cells our results could help to better understand the role of these proteins in insulin signaling.
Highlights
Insulin is a major regulator of metabolism, growth, and development and is conserved in all metazoans
Juvenile hormone inducible-21 (JhI-21) is necessary for leucine sensing in insulin-producing cells (IPCs)
The indirect mechanism involves the fat body. It senses the dietary amino acids like leucine. This mechanism involves an amino acid transporter that is homologous to JhI-2117,35
Summary
Insulin is a major regulator of metabolism, growth, and development and is conserved in all metazoans In mammals it is synthesized by the β-cells of the pancreas and is released into the blood in response to a meal to regulate the cellular uptake of nutrients such as carbohydrates. IPC neuronal activity leading to the secretion of Dilp[2] is stimulated by leucine via indirect and direct pathways[17,18]. It has been shown that dietary leucine activates the TOR pathway in the fat body, which in turn releases hormonal signals to stimulate Dilp[2] secretion from the IPCs17. In this study we shed light on the role of JhI-21 in the Dilp[2] release pathway by regulating IPC leucine transport
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