Project description:<h4><strong>INTRODUCTION: </strong>Approximately 1% of the world's population is impacted by epilepsy, a chronic neurological disorder characterized by seizures. One-third of epileptic patients are resistant to AEDs, or have medically refractory epilepsy (MRE). One non-invasive treatment that exists for MRE includes the ketogenic diet, a high-fat, low-carbohydrate diet. Despite the KD's success in seizure attenuation, it has a few risks and its mechanisms remain poorly understood. The KD has been shown to improve metabolism and mitochondrial function in epileptic phenotypes. Potassium channels have implications in epileptic conditions as they have dual roles as metabolic sensors and control neuronal excitation.</h4><h4><strong>OBJECTIVES: </strong>The goal of this study was to explore changes in the lipidome in hippocampal and cortical tissue from Kv1.1-KO model of epilepsy.</h4><h4><strong>METHODS: </strong>FT-ICR/MS analysis was utilized to examine nonpolar metabolome of cortical and hippocampal tissue isolated from a Kv1.1 channel knockout mouse model of epilepsy (n = 5) and wild-type mice (n = 5).</h4><h4><strong>RESULTS: </strong>Distinct metabolic profiles were observed, significant (p &lt; 0.05) features in hippocampus often being upregulated (FC ≥ 2) and the cortex being downregulated (FC ≤ 0.5). Pathway enrichment analysis shows lipid biosynthesis was affected. Partition ratio analysis revealed that the ratio of most metabolites tended to be increased in Kv1.1-/-. Metabolites in hippocampal tissue were commonly upregulated, suggesting seizure initiation in the hippocampus. Aberrant mitochondrial function is implicated by the upregulation of cardiolipin, a common component in the mitochondrial membrane.</h4><h4><strong>CONCLUSION: </strong>Generally, our study finds that the lipidome is changed in the hippocampus and cortex in response to Kv1.1-KO indicating changes in membrane structural integrity and synaptic transmission.</h4>

Project description:Altered molecular signaling pathways in the hippocampus of rhesus monkeys following chronic alcohol use

Project description:Action of alcohol on synaptic mRNA in the amygdala of mice Chronic alcohol consumption induces changes in gene expression, causing persistent long-term neuro-adaptations and the remodeling of synaptic structures. These alcohol-induced synaptic changes may rely specifically on the local translation of mRNAs in the synaptic compartments of the cell. We profiled the transcriptome from synaptoneurosomes (SN) and paired total homogenates (TH) of amygdala to analyze the synaptic adaptations induced by chronic voluntary alcohol consumption in mice. In the SN both the number of alcohol-responsive mRNAs and the magnitude of fold-change were greater than in the TH. Accordingly, the SN detected many genes with coordinated patterns of expression producing a highly connected mRNA network in gene co-expression analysis. The greater sensitivity of the SN preparation allowed for improved cell-type specificity analysis, revealing an up-regulation of alcohol-responsive astrocytic and microglial modules that correlated with alcohol consumption. Alcohol was found to induce changes in the SN functionally important biological pathways, including long-term potentiation, long-term potentiation depression, glutamate pathway, neuro-immune, RNA-processing and translational machineries and provided overlap with changes seen in human alcoholic brain. Transposable elements were responsive to alcohol and found in the down-regulated neuronal mRNA module, which may underlie some of the coordinated gene expression changes associated with alcohol. We provide evidence that enrichment of synaptic components reveals a more intricate network of coordinated gene expression. Increased resolution captures the molecular effects of synaptic manipulations and provides an improved technique for identifying therapeutic targets for alcohol abuse. Synaptoneurosomes (SN) and Paired total homogenates (TH) were prepared from the same homogenate. 42 microarrays were used in total for the alcohol-control analysis (8 alcohol treated mice and 13 controls), 21 SN and 21 paired TH. 2 TH (control) samples were found outliers and were removed from the analysis. For the SN vs. TH analysis, the 2 TH samples found outliers were removed with the 2 paired SN samples.

Project description:Action of alcohol on synaptic mRNA in the amygdala of mice Chronic alcohol consumption induces changes in gene expression, causing persistent long-term neuro-adaptations and the remodeling of synaptic structures. These alcohol-induced synaptic changes may rely specifically on the local translation of mRNAs in the synaptic compartments of the cell. We profiled the transcriptome from synaptoneurosomes (SN) and paired total homogenates (TH) of amygdala to analyze the synaptic adaptations induced by chronic voluntary alcohol consumption in mice. In the SN both the number of alcohol-responsive mRNAs and the magnitude of fold-change were greater than in the TH. Accordingly, the SN detected many genes with coordinated patterns of expression producing a highly connected mRNA network in gene co-expression analysis. The greater sensitivity of the SN preparation allowed for improved cell-type specificity analysis, revealing an up-regulation of alcohol-responsive astrocytic and microglial modules that correlated with alcohol consumption. Alcohol was found to induce changes in the SN functionally important biological pathways, including long-term potentiation, long-term potentiation depression, glutamate pathway, neuro-immune, RNA-processing and translational machineries and provided overlap with changes seen in human alcoholic brain. Transposable elements were responsive to alcohol and found in the down-regulated neuronal mRNA module, which may underlie some of the coordinated gene expression changes associated with alcohol. We provide evidence that enrichment of synaptic components reveals a more intricate network of coordinated gene expression. Increased resolution captures the molecular effects of synaptic manipulations and provides an improved technique for identifying therapeutic targets for alcohol abuse. Local translation of mRNAs in the synapse plays a major role in synaptic structure and function. Chronic alcohol use causes persistent changes in synaptic mRNA expression, possibly mediated by microRNAs localized in the synapse. We profiled the transcriptome of synaptoneurosomes (SN) from the amygdala of mice chronically consuming 20% ethanol in a continuous two-bottle choice test to identify the microRNAs that target alcohol-induced mRNAs. SN are membrane vesicles containing pre- and post-synaptic compartments of neurons and astroglia and are a unique model for studying the synaptic transcriptome. We previously showed that chronic alcohol regulates mRNA expression in a coordinated manner. Here, we examine microRNAs and mRNAs from the same samples to define alcohol-responsive synaptic microRNAs and their predicted interactions with targeted mRNAs. We used a combination of unbiased bioinformatic methods (differential expression, correlation, co-expression, microRNA-mRNA target prediction, co-targeting and cell type specific analyses) to identify key alcohol-sensitive microRNAs. Bidirectional mRNA-microRNA prediction analysis showed that a subset of alcohol-responsive microRNAs were predicted to target many alcohol-responsive mRNAs. We found microRNAs-mRNAs with overlapping patterns of expression that correlated with the amount of alcohol consumed. Cell-type specific analysis revealed a significant number of the alcohol-responsive mRNAs and microRNAs that were unique to glutamate neurons and were highly predicted to target each other. Chronic alcohol appears to perturb the coordinated microRNA regulation of mRNAs in SN, a mechanism that may explain the aberrations in synaptic plasticity affecting the alcoholic brain.

Project description:Comparison of gene expression in post-mortem hippocampus from 20 alcoholics and 19 controls. The chronic high-level alcohol consumption seen in alcoholism leads to dramatic effects on the hippocampus, including decreased white matter, loss of oligodendrocytes and other glial cells, and inhibition of neurogenesis. Examining gene expression in post mortem hippocampal tissue from 20 alcoholics and 19 controls allowed us to detect differentially expressed genes that may play a role in the risk for alcoholism or whose expression is modified by chronic consumption of alcohol. We identified 639 named genes whose expression significantly differed between alcoholics and controls at a False Discovery Rate (FDR) ? 0.20; 52% of these genes differed by at least 1.2-fold. Differentially expressed genes included the glucocorticoid receptor and the related gene FK506 binding protein 5 (FKBP5), UDP glycosyltransferase 8 (UGT8), urea transporter (SLC14A1), zinc transporter (SLC39A10), Interleukin 1 receptor type 1 (IL1R1), thioredoxin interacting protein (TXNIP), and many metallothioneins. Pathways related to inflammation, hypoxia, and stress showed activation, and pathways that play roles in neurogenesis and myelination showed decreases. The cortisol pathway dysregulation and increased inflammation identified here are seen in other stress-related conditions such as depression and post-traumatic stress disorder and most likely play a role in addiction. Many of the detrimental effects on the hippocampus appear to be mediated through NF-?B signaling. Twenty-four of the differentially regulated genes were previously identified by genome-wide association studies of alcohol use disorders; this raises the potential interest of genes not normally associated with alcoholism, such as suppression of tumorigenicity 18 (ST18), BCL2-associated athanogene 3 (BAG3), and von Willebrand factor (VWF). Comparison of gene expression from frozen human post-mortem hippocampus from 20 alcoholics and 19 controls using one array per sample. There were 6 females in each group. Sex and labeling batch were included in the analysis. The hippocampus samples came from the New South Wales Tissue Resource Centre at the University of Sydney, Australia, case ID provided for the sample. The total RNA samples were labeled in 2 balanced batches (indicated by labeling_batch). Brain sample QC provided by Tissue bank: brain pH and Post mortem interval in hours. Repoistory website: http://sydney.edu.au/medicine/pathology/trc/

Project description:Adolescent sensitivity to alcohol is predictive of later alcohol use and is influenced by genetic background. Data from our laboratory suggested that adolescent C57BL/6J and DBA/2J inbred mice differed in susceptibility to dorsal hippocampus-dependent contextual fear learning deficits after acute alcohol exposure. To investigate the biological underpinnings of this strain difference, we examined dorsal hippocampus gene expression via RNA-sequencing after alcohol and/or fear conditioning across male and female C57BL/6J and DBA/2J adolescents. Strains exhibited dramatic differences in dorsal hippocampal gene expression. Specifically, C57BL/6J and DBA/2J strains differed in 3526 transcripts in males and 2675 transcripts in females. We identified pathways likely to be involved in mediating alcohol’s effects on learning, including networks associated with Chrna7 and Fmr1. These findings provide insight into the mechanisms underlying strain differences in alcohol’s effects on learning and suggest that different biological networks are recruited for learning based on genetics, sex, and alcohol exposure.

Project description:Alcohol use disorder is marked by disrupted behavioral and emotional states which can persist into abstinence. The enduring synaptic alterations that remain despite the absence of alcohol are of interest for interventions to prevent relapse. 28 male rhesus macaques underwent over 20 months of alcohol drinking interspersed with three 30-day forced abstinence periods. After the last abstinence period, we paired ex vivo voltammetry in nucleus accumbens slices with RNA-sequencing of the ventral tegmental area. We found persistent augmentation of dopamine transporter function, kappa opioid receptor sensitivity, and dynorphin release – all inhibitory regulators which act to decrease extracellular dopamine. Surprisingly, though transcript expression was not altered, the relationship between gene expression and functional readouts of these encoded proteins was highly dynamic and altered by drinking history. Therefore, the long-lasting synaptic impact of alcohol use suggests that assessment of transcript-function relationships may provide avenues for precision therapeutics targeted to specific synaptic pathophysiologies.

Project description:Purpose: The goal of this study to examine mRNA transcriptomic changes in reward-related brain regions of subjects with alcohol use disorder. Methods: Total RNAs were extracted from postmortem hippocampus of 12 AUD and 12 control subjects. rRNA depletion RNA sequencing was performed and the sequence reads were processed using the bulk RNA-seq processing pipeline Pipeliner workflow (Federico et al. Front Genet 2019; 10, 614). AUD-associated mRNA transcriptomic changes were analyzed by the Limma-Voom method. Results: Differentially expressed mRNAs (absolute FC>2.0 & P<0.05) were identified in postmortem hippocampus of subjects with alcohol use disorder (AUD). Chronic alcohol consumption may alter mRNA transcriptome profiles in reward-related brain regions, resulting in alcohol-induced neuroadaptations.

Project description:Comparison of gene expression in post-mortem hippocampus from 20 alcoholics and 19 controls. The chronic high-level alcohol consumption seen in alcoholism leads to dramatic effects on the hippocampus, including decreased white matter, loss of oligodendrocytes and other glial cells, and inhibition of neurogenesis. Examining gene expression in post mortem hippocampal tissue from 20 alcoholics and 19 controls allowed us to detect differentially expressed genes that may play a role in the risk for alcoholism or whose expression is modified by chronic consumption of alcohol. We identified 639 named genes whose expression significantly differed between alcoholics and controls at a False Discovery Rate (FDR) ≤ 0.20; 52% of these genes differed by at least 1.2-fold. Differentially expressed genes included the glucocorticoid receptor and the related gene FK506 binding protein 5 (FKBP5), UDP glycosyltransferase 8 (UGT8), urea transporter (SLC14A1), zinc transporter (SLC39A10), Interleukin 1 receptor type 1 (IL1R1), thioredoxin interacting protein (TXNIP), and many metallothioneins. Pathways related to inflammation, hypoxia, and stress showed activation, and pathways that play roles in neurogenesis and myelination showed decreases. The cortisol pathway dysregulation and increased inflammation identified here are seen in other stress-related conditions such as depression and post-traumatic stress disorder and most likely play a role in addiction. Many of the detrimental effects on the hippocampus appear to be mediated through NF-κB signaling. Twenty-four of the differentially regulated genes were previously identified by genome-wide association studies of alcohol use disorders; this raises the potential interest of genes not normally associated with alcoholism, such as suppression of tumorigenicity 18 (ST18), BCL2-associated athanogene 3 (BAG3), and von Willebrand factor (VWF).

Project description:The objective of The Center for Alcohol Research in Epigenetics (CARE) is to identify gene regulatory pathways in hippocampus that are altered in response to chronic ethanol administration and withdrawal.