A nimal growth and development rely on coordinated functions of body organs to balance energy consumption and storage under optimal or challenging conditions, such as food scarcity or pathogen attack. When adverse conditions are temporary, animals survive by lengthening development and postponing maturity, reducing their body size (16,65). In contrast, prolonged starvation or chronic inflammation may exhaust energy reserves, causing death (32, 69). The key nutrient-sensing, metabolic, and immune-signaling pathways are functionally conserved across phyla. In the fruit fly Drosophila melanogaster, as in vertebrates, insulin/insulin growth factor (IGF) signaling (IIS) primarily regulates growth and metabolic homeostasis (56). The innate immune response of the fly relies on the Toll receptor and the immune deficiency (Imd) pathways (35). In response to bacterial or fungal infection, the Toll and Imd pathways engage downstream transcription factors of the NF-B-like family (Dif, Dorsal, and Relish) that in turn trigger synthesis of a battery of antimicrobial peptides (AMPs).It has become evident that the metabolic and immune system responses are tightly interconnected. Selective activation of Toll signaling in the Drosophila fat body attenuates IIS to reduce nutrient stores and overall growth (14). Mycobacterial infection causes energy wasting due to the systemic activation of the Forkhead transcription factor FOXO (15). Activation of the Jun N-terminal kinase (JNK) pathway is a well-established example of antagonistic regulation of IIS in both flies and vertebrates (29). Chronic inflammation, accompanied by high JNK activity, is at the heart of the metabolic syndrome and type 2 diabetes (54). Interestingly, genetic removal of IIS pathway components, starvation, and DNA damage all induce AMP expression in the absence of infection. This infection-independent AMP upregulation requires both FOXO (5) and Relish (30,70), further supporting the notion that maintenance of metabolic and innate immune balance are intimately linked.The Drosophila fat body and gut integrate metabolic and inflammatory signals to coordinate energy use. The fly alimentary tract digests and absorbs nutrients, while the fat body metabolizes and stores them. In addition, both organs can mount an immune response. The fat body requires both the Toll and Imd pathways for AMP production, whereas the gut immune response relies solely on Imd signaling (35,62). In contrast to the low basal immune activity within the unchallenged fat body, the presence of commensal bacteria in the gut lumen keeps the gut epithelium permanently alert with activated nuclear Relish. In this case, additional factors, such as the homeobox gene caudal (49), control AMP expression. Tightly regulated production of positive and negative Imd modulators prevents overgrowth of pathogens while preserving beneficial commensal bacteria. Uncontrolled inflammatory response of the intestinal epithelium has a dramatic impact on gut physiology and homeostasis in both flies and humans (43,47). A ...
