Nuclear receptors are ancient ligand-regulated transcription factors that control key metabolic and developmental pathways. The fruitfly Drosophila melanogaster has only 18 nuclear-receptor genes - far fewer than any other genetic model organism and representing all 6 subfamilies of vertebrate receptors. These unique attributes establish the fly as an ideal system for studying the regulation and function of nuclear receptors during development. Here, we review recent breakthroughs in our understanding of D. melanogaster nuclear receptors, and interpret these results in light of findings from their evolutionarily conserved vertebrate homologues.
Exposure to xenobiotics such as plant toxins, pollutants, or prescription drugs triggers a defense response, inducing genes that encode key detoxification enzymes. Although xenobiotic responses have been studied in vertebrates, little effort has been made to exploit a simple genetic system for characterizing the molecular basis of this coordinated transcriptional response. We show here that approximately 1000 transcripts are significantly affected by phenobarbital treatment in Drosophila. We also demonstrate that the Drosophila ortholog of the human SXR and CAR xenobiotic receptors, DHR96, plays a role in this response. A DHR96 null mutant displays increased sensitivity to the sedative effects of phenobarbital and the pesticide DDT as well as defects in the expression of many phenobarbital-regulated genes. Metabolic and stress-response genes are also controlled by DHR96, implicating its role in coordinating multiple response pathways. This work establishes a new model system for defining the genetic control of xenobiotic stress responses.
Pulses of the steroid hormone ecdysone are turned off periodically through nucleo-cytoplasmic oscillations of a nuclear receptor that counteracts the neuropeptide signaling pathway responsible for activating hormone pulses in Drosophila melanogaster.
Cholesterol homeostasis is required to maintain normal cellular function and avoid the deleterious effects of hypercholesterolemia. Here we show that the Drosophila DHR96 nuclear receptor binds cholesterol and is required for the coordinate transcriptional response of genes that are regulated by cholesterol and involved in cholesterol uptake, trafficking, and storage. DHR96 mutants die when grown on low levels of cholesterol and accumulate excess cholesterol when maintained on a high-cholesterol diet. The cholesterol accumulation phenotype can be attributed to misregulation of npc1b, an ortholog of the mammalian Niemann-Pick C1-like 1 gene NPC1L1, which is essential for dietary cholesterol uptake. These studies define DHR96 as a central regulator of cholesterol homeostasis. Cholesterol is an essential component of cell membranes that influences the permeability and fluidity of the lipid bilayer. Cholesterol also acts as a precursor for steroid hormone biosynthesis and contributes to cell-cell signaling pathways. These critical cellular functions are supported by regulatory mechanisms that maintain normal cholesterol levels and prevent hypercholesterolemia, which is a major risk factor for cardiovascular disease in humans. Cholesterol homeostasis in vertebrates is achieved primarily through de novo synthesis and dietary uptake (Ikonen 2008). Although extensive studies have defined a central role for the sterol regulatory elementbinding protein (SREBP) family of transcription factors in controlling cholesterol synthesis (Brown and Goldstein 1997), the mechanisms that regulate dietary cholesterol absorption remain more poorly understood. One central component of this pathway is the Niemann-Pick C1-like 1 gene NPC1L1, which encodes a plasma membrane protein that mediates the uptake of dietary cholesterol by the intestine (Wang 2007;Ge et al. 2008). Mouse mutants for NPC1L1 display significantly reduced levels of cholesterol absorption and are insensitive to treatment with the anti-hypercholesterolemia drug ezetimibe, which acts as a specific NPC1L1 inhibitor (Davis et al. 2008). Another major regulator of cholesterol homeostasis is the liver X receptor a (LXRa) nuclear receptor, which binds cholesterol metabolites and regulates the transcription of genes that control cholesterol transport and metabolism, including NPC1L1 (Duval et al. 2006;Kalaany and Mangelsdorf 2006;Valasek et al. 2007).We used the fruit fly, Drosophila, as a model system to study the regulation of cholesterol homeostasis. Unlike vertebrates, insects are cholesterol auxotrophs that are unable to synthesize this essential compound (Va'nt Hoog 1936). Little is known, however, about the mechanisms that regulate the uptake of dietary cholesterol in Drosophila. A recent study showed that the fly ortholog of NPC1L1, npc1b, is expressed specifically in the midgut and is essential for dietary cholesterol absorption (Voght et al. 2007). Other NPC disease gene homologs in Drosophila also contribute to cholesterol homeostasis. The Drosophila ortholog of vert...
A critical determinant of insect body size is the time at which the larva stops feeding and initiates wandering in preparation for metamorphosis. No genes have been identified that regulate growth by contributing to this key developmental decision to terminate feeding. We show here that mutations in the DHR4 orphan nuclear receptor result in larvae that precociously leave the food to form premature prepupae, resulting in abbreviated larval development that translates directly into smaller and lighter animals. In addition, we show that DHR4 plays a central role in the genetic cascades triggered by the steroid hormone ecdysone at the onset of metamorphosis, acting as both a repressor of the early ecdysone-induced regulatory genes and an inducer of the betaFTZ-F1 midprepupal competence factor. We propose that DHR4 coordinates growth and maturation in Drosophila by mediating endocrine responses to the attainment of critical weight during larval development.
SUMMARY Steroid hormones are ancient signaling molecules found in vertebrates and insects alike. Both taxa show intriguing parallels with respect to how steroids function and how their synthesis is regulated. As such, insects are excellent models for studying universal aspects of steroid physiology. Here, we present a comprehensive genomic and genetic analysis of the principal steroid hormone-producing organs in two popular insect models, Drosophila and Bombyx. We identified 173 genes with previously unknown specific expression in steroid-producing cells, 15 of which had critical roles in development. The insect neuropeptide PTTH and its vertebrate counterpart ACTH both regulate steroid production, but molecular targets of these pathways remain poorly characterized. Identification of PTTH-dependent gene sets identified the nuclear receptor HR4 as a highly conserved target in both Drosophila and Bombyx. We consider this study to be a critical step toward understanding how steroid hormone production and release are regulated in all animal models.
Summary Steroid hormones control important developmental processes and are linked to many diseases. To systematically identify genes and pathways required for steroid production, we performed a Drosophila genome-wide in vivo RNAi screen and identified 1,906 genes with potential roles in steroidogenesis and developmental timing. Here, we use our screen as a resource to identify mechanisms regulating intracellular levels of cholesterol, a substrate for steroidogenesis. We identify a conserved fatty acid elongase that underlies a mechanism which adjusts cholesterol trafficking and steroidogenesis with nutrition and developmental programs. Additionally, we demonstrate the existence of an autophagosomal cholesterol mobilization mechanism and show that activation of this system rescues Niemann Pick type C1-deficiency that causes a disorder characterized by cholesterol accumulation. These cholesterol trafficking mechanisms are regulated by TOR and feedback signaling that couples steroidogenesis with growth and ensure proper maturation timing. These results reveal genes regulating steroidogenesis during development that likely modulate disease mechanisms.
Biological clocks allow organisms to anticipate daily environmental changes such as temperature fluctuations, abundance of daylight, and nutrient availability. Many circadian-controlled physiological states are coordinated by the release of systemically acting hormones, including steroids and insulin [1-7]. Thus, hormones relay circadian outputs to target tissues, and disrupting these endocrine rhythms impairs human health by affecting sleep patterns, energy homeostasis, and immune functions [8-10]. It is largely unclear, however, whether circadian circuits control hormone levels indirectly via central timekeeping neurons or whether peripheral endocrine clocks can modulate hormone synthesis directly. We show here that perturbing the circadian clock, specifically in the major steroid hormone-producing gland of Drosophila, the prothoracic gland (PG), unexpectedly blocks larval development due to an inability to produce sufficient steroids. This is surprising, because classic circadian null mutants are viable and result in arrhythmic adults [4, 11-14]. We found that Timeless and Period, both core components of the insect clock [15], are required for transcriptional upregulation of steroid hormone-producing enzymes. Timeless couples the circadian machinery directly to the two canonical pathways that regulate steroid synthesis in insects, insulin and PTTH signaling [16], respectively. Activating insulin signaling directly modulates Timeless function, suggesting that the local clock in the PG is normally synced with systemic insulin cues. Because both PTTH and systemic insulin signaling are themselves under circadian control, we conclude that de-synchronization of a local endocrine clock with external circadian cues is the primary cause for steroid production to fail.
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