A Non-Nuclear NF-κB Modulates Alcohol Sensitivity But Not Immunity.

NF-κB proteins are well known as transcription factors important in immune system activation. In this highly conserved role, they contribute to changes in behavior in response to infection and in response to a variety of other insults and experiences. In some mammalian neurons, NF-κBs can be found at the synapse and translocate to the nucleus to alter gene expression when activated by synaptic activity. Here, we demonstrate that, in Drosophila melanogaster, NF-κB action is important both inside and outside the nucleus and that the Dif gene has segregated nuclear and non-nuclear NF-κB action into different protein isoforms. The DifA isoform is a canonical nuclear-acting NF-κB protein that enters the nucleus and is important for combating infection. The DifB variant, but not the DifA variant, is found in the central nervous system (mushroom bodies and antennal lobes). DifB does not enter the nucleus and co-localizes with a synaptic protein. In males and females, a DifB mutant alters alcohol behavioral sensitivity without an obvious effect on combating infection, whereas a DifA mutant does not affect alcohol sensitivity but compromises the immune response. These data are evidence that the non-nuclear DifB variant contributes to alcohol behavioral sensitivity by a nongenomic mechanism that diverges from the NF-κB transcriptional effects used in the peripheral immune system. Enrichment of DifB in brain regions rich in synapses and biochemical enrichment of DifB in the synaptoneurosome fraction indicates that the protein may act locally at the synapse.SIGNIFICANCE STATEMENT NF-κBs are transcription factors used by innate immune signaling pathways to protect against infection. Alcohol abuse also activates these pathways, which contributes to the addictive process and the health consequences associated with alcohol abuse. In the mammalian nervous system, NF-κBs localize to synapses, but it is axiomatic that they effect change by acting in the nucleus. However, for the Drosophila Dif gene, immune and neural function segregate into different protein isoforms. Whereas the nuclear isoform (DifA) activates immune genes in response to infection, the CNS isoform acts nongenomically to modulate alcohol sensitivity. Immunohistochemical and biochemical assays localize DifB to synapse-rich regions. Direct synaptic action would provide a novel and rapid way for NF-κB signaling to modulate behavior.

Alcohol-Induced Neuroadaptation Is Orchestrated by the Histone Acetyltransferase CBP.

Homeostatic neural adaptations to alcohol underlie the production of alcohol tolerance and the associated symptoms of withdrawal. These adaptations have been shown to persist for relatively long periods of time and are believed to be of central importance in promoting the addictive state. In Drosophila, a single exposure to alcohol results in long-lasting alcohol tolerance and symptoms of withdrawal following alcohol clearance. These persistent adaptations involve mechanisms such as long-lasting changes in gene expression and perhaps epigenetic restructuring of chromosomal regions. Histone modifications have emerged as important modulators of gene expression and are thought to orchestrate and maintain the expression of multi-gene networks. Previously genes that contribute to tolerance were identified as those that show alcohol-induced changes in histone H4 acetylation following a single alcohol exposure. However, the molecular mediator of the acetylation process that orchestrates their expression remains unknown. Here we show that the Drosophila ortholog of mammalian CBP, nejire, is the histone acetyltransferase involved in regulatory changes producing tolerance-alcohol induces nejire expression, nejire mutations suppress tolerance, and transgenic nejire induction mimics tolerance in alcohol-naive animals. Moreover, we observed that a loss-of-function mutation in the alcohol tolerance gene slo epistatically suppresses the effects of CBP induction on alcohol resistance, linking nejire to a well-established alcohol tolerance gene network. We propose that CBP is a central regulator of the network of genes underlying an alcohol adaptation.

Endocrine network essential for reproductive success in Drosophila melanogaster.

Ecdysis-triggering hormone (ETH) was originally discovered and characterized as a molt termination signal in insects through its regulation of the ecdysis sequence. Here we report that ETH persists in adult Drosophila melanogaster, where it functions as an obligatory allatotropin to promote juvenile hormone (JH) production and reproduction. ETH signaling deficits lead to sharply reduced JH levels and consequent reductions of ovary size, egg production, and yolk deposition in mature oocytes. Expression of ETH and ETH receptor genes is in turn dependent on ecdysone (20E). Furthermore, 20E receptor knockdown specifically in Inka cells reduces fecundity. Our findings indicate that the canonical developmental roles of 20E, ETH, and JH during juvenile stages are repurposed to function as an endocrine network essential for reproductive success.

Genetics and genomics of alcohol responses in Drosophila.

Drosophila melanogaster has become a significant model organism for alcohol research. In flies, a rich variety of behaviors can be leveraged for identifying genes affecting alcohol responses and adaptations. Furthermore, almost all genes can be easily genetically manipulated. Despite the great evolutionary distance between flies and mammals, many of the same genes have been implicated in strikingly similar alcohol-induced behaviors. A major problem in medical research today is that it is difficult to extrapolate from any single model system to humans. Strong evolutionary conservation of a mechanistic response between distantly related organisms, such as flies and mammals, is a powerful predictor that conservation will continue all the way to humans. This review describes the state of the Drosophila alcohol research field. It describes common alcohol behavioral assays, the independent origins of resistance and tolerance, the results of classical genetic screens and candidate gene analysis, and the outcomes of recent genomics studies employing GWAS, transcriptome, miRNA, and genome-wide histone acetylation surveys. This article is part of the Special Issue entitled "Alcoholism".

Juvenile Hormone Is Required in Adult Males for Drosophila Courtship.

Juvenile Hormone (JH) has a prominent role in the regulation of insect development. Much less is known about its roles in adults, although functions in reproductive maturation have been described. In adult females, JH has been shown to regulate egg maturation and mating. To examine a role for JH in male reproductive behavior we created males with reduced levels of Juvenile Hormone Acid O-Methyl Transferase (JHAMT) and tested them for courtship. JHAMT regulates the last step of JH biosynthesis in the Corpora Allata (CA), the organ of JH synthesis. Males with reduced levels of JHAMT showed a reduction in courtship that could be rescued by application of Methoprene, a JH analog, shortly before the courtship assays were performed. In agreement with this, reducing JHAMT conditionally in mature flies led to courtship defects that were rescuable by Methoprene. The same result was also observed when the CA were conditionally ablated by the expression of a cellular toxin. Our findings demonstrate that JH plays an important physiological role in the regulation of male mating behavior.