Project description:Despite the widespread use of general anaesthetics, the mechanisms mediating their effects are still not understood. Although suppressed in most parts of the brain, neuronal activity, as measured by FOS activation, is increased in the hypothalamic supraoptic nucleus (SON) by numerous general anaesthetics, and evidence points to this brain region being involved in the induction of general anaesthesia and natural sleep. Posttranslational modifications of proteins, including changes in phosphorylation, enable fast modulation of protein function which could be underlying the rapid effects of general anaesthesia. In order to identify potential phosphorylation events in the brain mediating general anaesthesia effects, we have explored the phosphoproteome responses in the rat SON, and compared these to cingulate cortex (CC) which displays no FOS activation is response to general anaesthetics. We found many changes in the phosphoproteomes of both the CC and SON in response to 15 minutes of isoflurane exposure. Pathway analysis indicated that proteins undergoing phosphorylation adaptations are involved in cytoskeleton remodelling and synaptic signalling events. Importantly, changes in protein phosphorylation appeared to be brain region-specific suggesting that differential phosphorylation adaptations might underlie the different neuronal activity responses to general anaesthesia between the CC and SON. In summary, these data suggest that rapid posttranslational modifications in proteins involved in cytoskeleton remodelling and synaptic signalling events might mediate the central mechanisms mediating general anaesthesia.

Project description:The cell bodies of hypothalamic magnocellular neurones (MCNs) are confined to the hypothalamic supraoptic nucleus (SON) whereas their axons project to the anatomically discrete posterior pituitary gland (PP). We have taken advantage of this unique anatomical structure to document proteome and phosphoproteome dynamics in neuronal cell bodies and axonal terminals in response to neuronal activation induced by water deprivation (WD). We have found that proteome and phosphoproteome responses to WD are very different between cell bodies and axonal terminals, indicating the need of each cell domain to differentially adapt in response to stimuli. Whilst changes in the proteome and phosphoproteome in the cell body are involved in protein synthesis and cytoskeleton reorganisation, respectively, in the axonal terminals they regulate synaptic vesicle cycle and secretion. Further, by comparison with transcriptome data, we have identified peptides that are not synthesised in the SON, but are present as a consequence of afferent delivery.

Project description:The magnocellullar neurons (MCNs) of the supraoptic nucleus (SON) of the hypothalamus are the principle source of the neuropeptide hormone vasopressin (VP), which has a crucial role in osmoregulation. Physiological activation of the SON by dehydration results is a massive release of VP from stores in posterior pituitary axon terminals into the general circulation. By binding to V2-type receptors located in the kidney, VP decrease the amount of water lost in urine. Osmotic activation of the SON is accompanied by a dramatic morphological and functional remodelling. We have sought to understand the mechanistic basis of this plasticity in terms of the differential expression of genes. To identify such genes, we adopted a completely unbiased and global approach based on Suppressive Subtractive Hybridisation-Polymerase Chain Reaction (SSH-PCR) Using this method, we generated a library of clones putatively differentially expressed in control vs dehydrated SON. In order to rapidly screen this library, 1152 of these clones were subjected to microarray analysis, resulting in the identification of 459 differentially expressed clones, 56 of which were sequenced. Many of these clones are expressed sequences that are new to science. Four of these were shown by in situ hybridisation (ISH) to be significantly up- or down-regulated in the SON following dehydration. These genes may represent novel effectors or mediators of SON physiological remodelling. 4 chips were hybridised with control SON and compared to 4 chips hybridised with dehydrated SON

Project description:Salt loading (SL) and water deprivation (WD) are experimental challenges that are often used to study the osmotic circuitry of the brain. Central to this circuit is the supraoptic nucleus (SON) of the hypothalamus, which is responsible for the biosynthesis of the hormones, vasopressin (AVP) and oxytocin (OXT), and their transport to terminals that reside in the posterior lobe of the pituitary. Upon osmotic challenge evoked by a change in blood volume or osmolality, the SON undergoes a function related plasticity that creates an environment that allows for an appropriate hormone response. Here, we have described the impact of SL and WD compared to euhydrated (EU) controls in terms of drinking and eating behaviour, body weight and recorded physiological data including circulating hormone data and plasma and urine osmolality. We have also used microarrays to profile the transcriptome of the SON following SL Microarrays were interrogated with RNA extracted from the supraoptic nucleus of either euhydrated (n=5) or 7-days salt loaded (2% w/v; n=5) rats. Each microarray represented an independent pool of 5 animals, and for each condition, 5 microarrays were performed.

Project description:In order to better understand physiological mechanisms and neurological symptoms involved in the development of decompression sickness we determined effects in rats on the brain proteome of fast decompression (1 bar/20 s) compared to controls (1 bar/10 min) after heliox saturation diving. The orbitrap LC-MS/MS data files presented here resulted in 1062 proteins quantified using label-free proteomics. Based on the 128 significantly regulated proteins in the orbitrap dataset and 56 in an iontrap dataset (967 quantified proteins), the networks “synaptic vesicle fusion and recycling in nerve terminals” and “translation initiation” were significantly enriched in a system biological database analysis (Metacore). Ribosomal proteins (RLA2, RS10) and the proteins hippocalcin-like protein 4 and proteasome subunit beta type-7 were significantly upregulated in both datasets. The heat shock protein 105 kDa, Rho-associated protein kinase 2 and Dynamin-1 were significantly downregulated in both datasets.

Project description:Despite considerable evidence that RNA-binding proteins (RBPs) regulate mRNA transport and local translation in dendrites, roles for axonal RBPs are poorly understood. Here we demonstrate that a nontelomeric isoform of telomere repeat-binding factor 2 (TRF2-S) is a novel RBP that regulates axonal plasticity. TRF2-S interacts directly with target mRNAs to facilitate their axonal delivery. The process is antagonized by fragile X mental retardation protein (FMRP). Distinct from the current RNA-binding model of FMRP, we show that FMRP occupies the GAR domain of TRF2-S protein to block the assembly of TRF2-S-mRNA complexes. Overexpressing TRF2-S and silencing FMRP promotes mRNA entry to axons, and enhances axonal outgrowth and neurotransmitter release from presynaptic terminals. Our findings suggest a pivotal role for TRF2-S in an axonal mRNA localization pathway that enhances axon outgrowth and neurotransmitter release.

Project description:Localized mRNA translation regulates synapse function and axon maintenance, but how compartment-specific mRNA repertoires are regulated is largely unknown. We developed an axonal transcriptome capture method that allows deep sequencing of metabolically-labeled mRNAs from retinal ganglion cell axon terminals in mouse. Comparing axonal-to-somal transcriptomes and axonal translatome-to-transcriptome enables genome-wide visualization of mRNA transport and translation and unveils potential regulators tuned to each process. FMRP and TDP-43 stand out as key regulators of transport, and experiments in Fmr1 knock-out mice validate FMRP’s role in the axonal transportation of synapse-related mRNAs. Pulse-and-chase experiments enable genome-wide assessment of mRNA stability in axons and reveal a strong coupling between mRNA translation and decay. Measuring the absolute mRNA abundance per axon terminal shows that the axonal transcriptome is stably maintained in adulthood by persistent transport. Our datasets provide a rich resource for unique insights into RNA-based mechanisms in maintaining presynaptic structure and function in vivo.

Project description:Non-alcoholic fatty liver disease (NAFLD) is the most common chronic liver disease in Western countries. There is growing evidence that dysbiosis of the intestinal microbiota and disruption of microbiota-host interactions contribute to the pathology of NAFLD. We previously demonstrated that gut microbiota derived tryptophan metabolite indole-3-acetate (I3A) was decreased in both cecum and liver of high-fat diet-fed mice and attenuated the expression of inflammatory cytokines in macrophages and TNF-a and fatty acid induced inflammatory responses in an aryl-hydrocarbon receptor (AhR) dependent manner in hepatocytes. In this study, we investigated the effect of orally administered I3A in a mouse model of diet induced NAFLD. Western diet (WD)-fed mice given sugar water (SW) with I3A showed dramatically decreased serum ALT, hepatic TG, liver steatosis, hepatocyte ballooning, lobular inflammation, and hepatic production of inflammatory cytokines, compared to WD-fed mice given only SW. Metagenomic analysis show that I3A administration did not significantly modify the intestinal microbiome, suggesting that I3A’s beneficial effects likely reflect the metabolite’s direct actions on the liver. Administration of I3A partially reversed WD induced alterations of liver metabolome and proteome, notably, decreasing expression of several enzymes in hepatic lipogenesis and β- oxidation. Mechanistically, we also show that AMP-activated protein kinase (AMPK) mediates the anti-inflammatory effects of I3A in macrophages. The potency of I3A in alleviating liver steatosis and inflammation clearly demonstrates its potential as a therapeutic modality for preventing the progression of steatosis to NASH.

Project description:Despite considerable evidence that RNA-binding proteins (RBPs) regulate mRNA transport and local translation in dendrites, roles for axonal RBPs are poorly understood. Here we demonstrate that a nontelomeric isoform of telomere repeat-binding factor 2 (TRF2-S) is a novel RBP that regulates axonal plasticity. TRF2-S interacts directly with target mRNAs to facilitate their axonal delivery. The process is antagonized by fragile X mental retardation protein (FMRP). Distinct from the current RNA-binding model of FMRP, we show that FMRP occupies the GAR domain of TRF2-S protein to block the assembly of TRF2-S-mRNA complexes. Overexpressing TRF2-S and silencing FMRP promotes mRNA entry to axons, and enhances axonal outgrowth and neurotransmitter release from presynaptic terminals. Our findings suggest a pivotal role for TRF2-S in an axonal mRNA localization pathway that enhances axon outgrowth and neurotransmitter release. RNA immunoprecipitated samples using either anti-rat TRF2-S or rabbit IgG antibodies were used to generate biotin-labeled RNA using the Illumina Total Prep RNA Amplification Kit (Ambion), which was hybridized to Illumina's rat Ref-12 Expression BeadChips (Illumina, San Diego, CA), containing 22,523 well-annotated RefSeq transcripts with ~30-fold redundancy. The arrays were scanned using an Illumina BeadStation 500X Genetic Analysis Systems scanner and the image data extracted using Illumina BeadStudio software, version 1.5, normalized by Z-score transformation and used to calculate differences in signal intensities. Significant values were calculated from two groups of independent experiments, using a two-tailed Z-test with P < 0.05, a false discovery rate <0.30, a z ratio absolute value not less than 1.5, and an average signal intensity not less than zero. The results also had to pass the filtering and one-way independent ANOVA test by sample groups less than 0.05, and detection p-value for any probe in the comparison group less than 0.02.

Project description:Wilson’s disease (WD) is a relevant human genetic disease caused by mutations in the ATP7B gene, whose product is a liver enzyme responsible for copper export into bile and blood. Interestingly, the spectrum of ATP7B mutations is vast and can influence clinical presentation (a variable spectrum of hepatic and neural manifestations), though the reason for this is not well understood. Here we describe the successful generation of iPSCs from a Chinese patient with Wilson’s disease that bears the R778L Chinese hotspot mutation in the ATP7B gene. Global gene expression profiling with DNA microarrays showed that WD iPSCs cluster together with human ESCs (H9) compared to donor fibroblasts. WD patient fibroblasts were isolated and expanded from a dermal biopsy of a middle age Chinese Han male, WD iPSCs were generated by overexpression of human Oct4/Sox2/Klf4/c-Myc in WD fibroblasts and expanded on Matrigel with mTESR1 culture medium. For DNA microarray analysis, WD fibroblasts (passage 5), 3 cell lines of WD iPSCs growing on Matrigel (passage 8) and human ES H9 growing on Matrigel (passage 40) were treated with Trizol, followed by RNA extraction and hybridization.