Project description:High frequency of physical aggression is the central feature of severe conduct disorder and is associated with a wide range of social, mental and physical health problems. We have previously tested the hypothesis that differential DNA methylation signatures in peripheral T cells are associated with a chronic aggression trajectory in males. Despite the fact that sex differences appear to play a pivotal role in determining the development, magnitude and frequency of aggression, most of previous studies focused on males, so little is known about female chronic physical aggression. We therefore tested here whether or not there is a signature of physical aggression in female DNA methylation and, if there is, how it relates to the signature observed in males. Genome-wide promoter methylation profiles of T cell DNA from adult females on a Chronic Physical Aggression (CPA, n=5) trajectory during childhood and adolescence were compared to those on normative physical aggression trajectories (NPA, n=14). Two technical replicates were generated for each individual.

Project description:High frequency of physical aggression is the central feature of severe conduct disorder and is associated with a wide range of social, mental and physical health problems. We have previously tested the hypothesis that differential DNA methylation signatures in peripheral T cells are associated with a chronic aggression trajectory in males. Despite the fact that sex differences appear to play a pivotal role in determining the development, magnitude and frequency of aggression, most of previous studies focused on males, so little is known about female chronic physical aggression. We therefore tested here whether or not there is a signature of physical aggression in female DNA methylation and, if there is, how it relates to the signature observed in males.

Project description:High frequency of physical aggression is the central feature of severe conduct disorder and is associated with a wide range of social, mental and physical health problems. We have previously tested the hypothesis that differential DNA methylation signatures in peripheral T cells are associated with a chronic aggression trajectory in males. Despite the fact that sex differences appear to play a pivotal role in determining the development, magnitude and frequency of aggression, most of previous studies focused on males, so little is known about female chronic physical aggression. We therefore tested here whether or not there is a signature of physical aggression in female DNA methylation and, if there is, how it relates to the signature observed in males.

Project description:High frequency of physical aggression is the central feature of severe conduct disorder and is associated with a wide range of social, mental and physical health problems. We have previously tested the hypothesis that differential DNA methylation signatures in peripheral T cells are associated with a chronic aggression trajectory in males. Despite the fact that sex differences appear to play a pivotal role in determining the development, magnitude and frequency of aggression, most of previous studies focused on males, so little is known about female chronic physical aggression. We therefore tested here whether or not there is a signature of physical aggression in female DNA methylation and, if there is, how it relates to the signature observed in males. Genome-wide promoter methylation profiles of T cell DNA from adult males and females on a Chronic Physical Aggression (CPA) trajectory during childhood and adolescence were compared to adults on a normative physical aggression trajectories (NPA). Each sample was bisulphite converted gDNA pooled in equimolar amounts. Three different pools of genomic DNA were made per group: male CPA (2 or 3 different subjects per pool), male NPA (4 different subjects per pool), female CPA (2 different subjects per pool) and female NPA (4 or 5 different subjects per pool) . The Illumina Infinium 450k Human DNA methylation Beadchip was used to obtain DNA methylation profiles of the 2 groups in both sex.

Project description:The function of the central nervous system to regulate food intake can be disrupted by sustained metabolic challenges such as high-fat diet (HFD), which may contribute to the development of various metabolic disorders. In the present study, we found that HFD specifically enhanced food-seeking behavior in fruit flies without altering flies’ baseline metabolism and food consumption. Mechanistically, HFD increased the excitability of a small group of octopaminergic (OA) neurons to a hunger hormone named adipokinetic hormone (AKH), via increasing the accumulation of AKH receptor (AKHR) in these neurons. Upon HFD, excess dietary lipids are transported by a lipoprotein LTP to enter these OA+AKHR+ neurons via the cognate receptor LpR1, which in turn activated AMPK-TOR signaling and suppressed autophagy-dependent degradation of AKHR. Taken together, we uncovered a mechanism that linked HFD, AMPK-TOR signaling, neuronal autophagy, and food-seeking behavior, providing insight in the reshaping of neural circuitry under metabolic challenges and the progression of metabolic diseases.

Project description:The function of the central nervous system to regulate food intake can be disrupted by sustained metabolic challenges such as high-fat diet (HFD), which may contribute to the development of various metabolic disorders. In the present study, we found that HFD specifically enhanced food-seeking behavior in fruit flies without altering flies’ baseline metabolism and food consumption. Mechanistically, HFD increased the excitability of a small group of octopaminergic (OA) neurons to a hunger hormone named adipokinetic hormone (AKH), via increasing the accumulation of AKH receptor (AKHR) in these neurons. Upon HFD, excess dietary lipids are transported by a lipoprotein LTP to enter these OA+AKHR+ neurons via the cognate receptor LpR1, which in turn activated AMPK-TOR signaling and suppressed autophagy-dependent degradation of AKHR. Taken together, we uncovered a mechanism that linked HFD, AMPK-TOR signaling, neuronal autophagy, and food-seeking behavior, providing insight in the reshaping of neural circuitry under metabolic challenges and the progression of metabolic diseases.

Project description:Gene expression profiling of nuclei isolated from genetically defined neuronal subpopulations of the adult Drosophila brain. Gene expression profiles were generated from nuclei isolated from all neurons (R57C10-GAL4), Kenyon cells (OK107-GAL4), and octopaminergic (Tdc2-GAL4) neurons in the adult Drosophila head using a method similar to INTACT (Deal and Henikoff, 2010; Steinner et al., 2012). Sequencing was performed with an Illumina HiSeq 2000.

Project description:Chromatin profiling of nuclei isolated from genetically defined neuronal subpopulations of the adult Drosophila brain. Cell type-specific histone modification maps were generated from nuclei isolated from all neurons (R57C10-GAL4), Kenyon cells (OK107-GAL4), and octopaminergic (Tdc2-GAL4) neurons using a method similar to INTACT (Deal and Henikoff, 2010; Steinner et al., 2012). Three histone modifications were profiled: H3K4me3, H3K27ac, and H3K27me3. Sequencing was performed with an Illumina HiSeq 2000.

Project description:PeFA Ucn3 neurons were identified as a dedicated circuit component for the expression of infant-directed neglect and aggression, providing a new framework to understand the positive and negative regulation of parenting in health and disease.

Project description:Genes relevant to manifestion of and variation in aggression behavior might be differentially expressed in lines selected for divergent levels of aggression. Keywords: selection group