Project description:Background: Synaptic transmission is required for functional maturation of the CNS and to induce gene transcription involved in neuronal plasticity. Our aim is to identify genes that are transcriptionally regulated by synaptic transmission during development. cDNA microarrays will be used to compare gene expression in normal embryos and embryos with no synaptic transmission. Using the Gal4 UAS system, the tetanus toxin light fragment (TET) will be expressed throughout the nervous system. The effects of TET are well characterised: the synaptic protein n-Synaptobrevin is cleaved, blocking evokes vesicle fusion in TET expressing neurons and as a result synaptic transmission is blocked. Embryos expressing an inactive, mutant version of TET (iTET) show no detectable phenotype. Thus a comparison of gene expression in iTET expressing embryos and TET expressing embryos focuses our screen cleanly and specifically on genes that are regulated by synaptic transmission. At the end of larval life, during metamorphosis, there is a second phase of nervous system development with the same requirement for neural circuit differentiation and maturation as in the embryo. We will compare gene expression in TET expressing and iTET expressing pupae to identify genes which are regulated by synaptic transmission in this second phase of nervous system development. We will focus our analysis on genes which are similarly regulated in both systems. Plan: elav Gal4 (expressed in all the neurons) for the embryos and Heat Shock Gal4 (which allows a temporally controlled expression) for the pupae are used to drive UAS TET and UAS iTET throughout the nervous system. Crosses are set up with flies homozygous for Gal4 or UAS transgenes, so that all the progeny have the same genotype. Total RNA is extracted from 500 carefully staged embryos that have been collected at the time of hatching. Pupae are heat shocked at 24 hours after puparium formation, and heads are then collected 5 days after puparium formation. TET expressing pupae are paralysed but morphologically normal whereas iTET expressing pupae emerge as normal adults. Total RNA will be extracted from 250 heads of each genotype. Probes made from TET and iTET expressing embryos extracts will be hybridised together to the chip and so will be probes made from TET and iTET expressing pupae extracts. Genes regulated in both systems will be compared together.

Project description:Understanding the mechanisms of synaptic plasticity is crucial for elucidating how the brain adapts to internal and external stimuli. A key objective of plasticity is maintaining physiological activity states during perturbations by adjusting synaptic transmission through negative feedback mechanisms. However, identifying and characterizing novel molecular targets orchestrating synaptic plasticity remains a significant challenge. This study investigated the effects of tetrodotoxin (TTX)-induced synaptic plasticity within organotypic entorhino-hippocampal tissue cultures, offering insights into the functional, transcriptomic, and proteomic changes associated with network inhibition via voltage- gated sodium channel blockade. Our experiments demonstrate that TTX treatment induces substantial functional plasticity of excitatory synapses, evidenced by increased miniature excitatory postsynaptic current (mEPSC) amplitudes and frequencies in both dentate granule cells and CA1 pyramidal neurons. Correlating transcriptomic and proteomic data, we identified novel targets for future research into homeostatic plasticity, including cytoglobin, SLIT-ROBO Rho GTPase Activating Protein 3, Transferrin receptor, and 3-Hydroxy-3-Methylglutaryl-CoA Synthase 1. These data provide a valuable resource for future studies aiming to understand the orchestration of homeostatic plasticity by metabolic pathways in distinct cell types of the central nervous system.

Project description:Slo2 potassium channels play important roles in neuronal function, and their mutations in humans cause epilepsies and profound cognitive defects. However, little is known how Slo2 function is regulated by other proteins. In a genetic screen for suppressors of a sluggish phenotype caused by a hyperactive C. elegans Slo2 (SLO-2), mutants of adr-1, a gene important to RNA editing, were isolated. SLO-2 current in motor neurons is substantially decreased in the mutants. However, slo-2 transcripts have no detectable RNA editing events and exhibit a similar expression level in wild type and adr-1 mutants. In contrast, mRNA level of scyl-1, which encodes an orthologue of mammalian SCYL1 (a pseudokinase), is greatly reduced in adr-1 mutants due to deficient RNA editing at a single adenosine in its 3’-UTR. SCYL-1 physically interacts with SLO-2 in neurons. Single-channel open probability of SLO-2 in neurons is reduced by ~50% in scyl-1 knockout whereas that of human Slo2.2/Slack is doubled by SCYL1 in a heterologous expression system. These results suggest that SCYL-1/SCYL1 is an evolutionarily conserved regulator of Slo2 channels.

Project description:Myasthenia gravis (MG) is a chronic antibody-mediated autoimmune disease disrupting neuromuscular synaptic transmission. Antibodies (Abs) against the acetylcholine receptor (AChR) are detected in approximately 85% of patients. Here, we aimed to study the serum proteome of MG and to identify novel biomarkers reflecting disease activity.

Project description:Astrocytes participate in synaptic transmission and plasticity through tightly regulated, bidirectional communication with neurons, both pre- and post-synaptic elements, as well as microglia and oligodendrocytes. A key component of astrocyte-mediated synaptic regulation is the cytokine tumor necrosis factor (TNF). TNF signals via two cognate receptors, TNFR1 and TNFR2, both expressed in astrocytes. While TNFR1 signaling in astrocytes has been long demonstrated to be necessary for physiological synaptic function, the role of astroglial TNFR2 has never been explored. Here, we demonstrate that astroglial TNFR2 is essential for maintaining hippocampal synaptic function and plasticity in physiological conditions. Indeed, GfapcreERT2:Tnfrsf1bfl/fl mice with selective ablation of TNFR2 in astrocytes exhibited dysregulated expression of neuronal and glial proteins (e.g. SNARE complex molecules, glutamate receptor subunits, glutamate transporters) essential for hippocampal synaptic transmission and plasticity. Hippocampal astrocytes sorted from GfapcreERT2:Tnfrsf1bfl/fl mice displayed downregulation of genes and pathways implicated in synaptic plasticity, astrocyte-neuron and astrocyte-oligodendrocyte communication. These alterations were accompanied by increased glial reactivity and impaired astrocyte calcium dynamics, and ultimately translated into functional deficits, specifically impaired long-term potentiation (LTP) and cognitive functions. Notably, male GfapcreERT2:Tnfrsf1bfl/fl mice exhibited more pronounced hippocampal synaptic and cellular alterations, suggesting sex-dependent differences in astroglial TNFR2 regulation of synaptic function. Together, these findings indicate that TNFR2 signaling in astrocytes is essential for proper astrocyte-neuron communication at the basis of synaptic function, and that this is regulated in a sex-dependent manner.

Project description:GABAB receptors (GBRs), the G protein-coupled receptors for GABA, regulate synaptic transmission throughout the brain. A main synaptic GBR function is the gating of ion channels. However, where stable GBR-effector channel signaling units are formed in the biosynthetic pathway has remained unclear. Here we show that the vesicular protein synaptotagmin-11 (Syt11) binds the auxiliary GBR subunit KCTD16 and Cav2.2 channels. This enables Syt11 to recruit GBR/Cav2.2 channel complexes to post-Golgi vesicles that transport the pre-assembled signaling complexes in axons and dendrites. Bimolecular fluorescence complementation experiments reveal that GBR/Syt11 complexes are delivered to synaptic sites. Furthermore, Syt11 stabilizes GBRs and Cav2.2 channels at the neuronal plasma membrane by inhibiting constitutive internalization. Syt11-deficient neurons exhibit reduced glutamatergic synaptic transmission and impaired GBR-mediated presynaptic inhibition, thus highlighting a key role for Syt11 in the transport and stable expression of functional GBR/Cav2.2 complexes at synapses.

Project description:Scaffold Attachment Factor B (SAFB) is a conserved RNA Binding Protein (RBP) that is essential for early mammalian development. However, the RNAs that associate with SAFB in mouse embryonic stem cells have not been characterized. Here, we addressed this unknown using RNA-seq and SAFB RNA immunoprecipitation followed by RNA-seq (RIP-seq) in wild-type mouse embryonic stem cells (ESCs) and in ESCs in which SAFB and SAFB2 were knocked out. The transcript most enriched in SAFB association was the lncRNA Malat1, which contains a series of purine-rich motifs in its 5 end. Beyond Malat1, SAFB predominantly associated with introns of protein-coding genes also through purine-rich motifs. Knockout of SAFB/2 led to down- and upregulation of genes in multiple biological pathways. The nascent transcripts of many downregulated genes associated with high levels of SAFB in wild-type cells, implying that SAFB binding promotes the expression of these genes. Reintroduction of SAFB into double-knockout cells restored gene expression towards wild-type levels, an effect that was again observable at the level of nascent transcripts. Proteomic analyses indicate an enrichment of nuclear speckle-associated, SR proteins in FLAG-tagged SAFB immunoprecipitated samples. Comparison to immunoprecipitates made from FLAG-tagging of another nuclear-enriched RNA-binding protein called HNRNPU (also known as SAF-A) identified both similarities and differences. Perhaps most notably, we observed a stronger enrichment for speckle-associated proteins in SAFB immunoprecipitations and a strong enrichment for paraspeckle-associated proteins in HNRNPU immunoprecipitations. Our findings suggest that among other potential functions in mouse embryonic stem cells, SAFB directly promotes the expression of a subset of genes through its ability to bind purine regions in nascent RNA.

Project description:The circadian system produces ~24-hr oscillations in behavioral and physiological processes to ensure that they occur at optimal times of day and in the correct temporal order. At its core, the circadian system is composed of dedicated central clock neurons that keep time through a cell-autonomous molecular clock. To produce rhythmic behaviors, time-of-day information generated by clock neurons must be transmitted across output pathways to regulate the downstream neuronal populations that control the relevant behaviors. An understanding of the manner through which the circadian system enacts behavioral rhythms therefore requires the identification of the cells and molecules that make up the output pathways. To that end, we recently characterized the Drosophila pars intercerebralis (PI) as a major circadian output center that lies downstream of central clock neurons in a circuit controlling rest:activity rhythms. We have conducted single-cell RNA sequencing (scRNAseq) to identify potential circadian output genes expressed by PI cells, and used cell-specific RNA interference (RNAi) to knock down expression of ~40 of these candidate genes selectively within subsets of PI cells. We demonstrate that knockdown of the slowpoke (slo) potassium channel in PI cells reliably decreases circadian rest:activity rhythm strength. Interestingly, slo mutants have previously been shown to have aberrant rest:activity rhythms, in part due to a necessary function of slo within central clock cells. However, rescue of slo in all clock cells does not fully reestablish behavioral rhythms, indicating that expression in non-clock neurons is also necessary. Our results demonstrate that slo exerts its effects in multiple components of the circadian circuit, including PI output cells in addition to clock neurons, and we hypothesize that it does so by contributing to the generation of daily neuronal activity rhythms that allow for the propagation of circadian information throughout output circuits.

Project description:The appropriate growth of the neurons, accurate organization of their synapses, and successful neurotransmission are indispensable for sensorimotor activities. These processes are highly dynamic and tightly regulated. Extensive genetic, molecular, physiological, and behavioural studies have identified many molecular players and investigated their roles in various neuromuscular processes. In this paper we show that Beadex (Bx), the Drosophila LIM only (LMO) protein, governs the growth of larval neuromuscular junctions (NMJs) and neuronal activities. The Bx mutant, Bx7, and the RNAi-mediated neuronal-specific knockdown of Bx show drastically reduced synaptic span of the NMJs, an increased spontaneous neuronal firing with altered motor patterns in the CPGs. Microarray studies identified multiple targets of Bx that are involved in different cellular and molecular pathways, including those associated with the cytoskeleton and mitochondria, that could be responsible for the observed neuromuscular defects. With genetic interaction studies, we further show that Highwire (Hiw), a negative regulator of synaptic growth at the NMJs, negatively regulates Bx, as the latter’s deficiency was able to rescue the phenotype of the Hiw dominant negative mutant, HiwDN.

Project description:Substance P (SP) is a neuropeptide that functions in both the central and peripheral nervous systems. Although substance P-containing neurons convey nociceptive information to the spinal cord and regulate inflammatory responses in peripheral tissues, the impact of a peripheral rise in substance P on hippocampal functions such as spatial learning and memory remains unclear. Here, we show that chronic peripheral substance P significantly impaired performance in both the object place recognition (OPR) and novel object recognition (NOR) tests compared to saline controls. Electrophysiology revealed a marked reduction in CA3‑CA1 LTP without changes in basal synaptic transmission. RNA‑Seq identified 77 differentially expressed genes (DEGs), and enrichment analysis highlighted pathways related to synaptic transmission and learning/memory.