Project description:Neuronal activity-dependent gene expression plays important roles in neural plasticity. We use electroconvulsive stimulation (ECS) as an in vivo model for neuronal activation to identify genes that are regulated by neuronal activity. Dentate gyri (DG) were microdissected 4 hours after sham or ECS treatment for gene expression profiling. 4 total samples were analysed (2 for each condition). Averaged expression values between sham and ECS samples were pair-wise compared.

Project description:Human induced pluripotent stem cells (hiPSCs) have the ability to differentiate into a variety of cells and to self-renew in vitro. Because of these two characteristics, hiPSCs have been expected to provide new applications for regenerative medicine/cell therapy. Although various in vitro differentiation protocols have been developed for the efficient derivation of specific cell types, hiPSC lines vary in their ability to differentiate into specific lineages. Therefore, surrogate markers that accurately predict the differentiation propensity of hiPSC lines could be helpful for the development and manufacture of hiPSC-derived cells for therapies and in vitro assays. Here, we tried to identify the marker genes that potentially predicts the differentiation propensity of hiPSCs into neural progenitor cells (NPCs). Using ten hiPSC lines, we searched for genes significantly correlated between expression levels in the undifferentiated state and neuronal differentiation efficiency using two differentiation induction methods, and selected genes that were commonly and predominantly correlated with neuronal differentiation. Among the genes correlated with NPC differentiation, we identified ROR2 as a novel predictive marker of NPC differentiation. ROR2 expression in hiPSCs correlates negatively with NPC differentiation capacity, and ROR2 knockdown enhances NPC differentiation. These findings suggest that ROR2 serves as a useful surrogate marker for selecting hiPSC lines appropriate for NPC differentiation.

Project description:Adult neurogenesis occurs in mammals and provides a mechanism for continuous neural plasticity in the brain.However, little is known about the molecular mechanisms regulating hippocampal neural progenitor cells (NPCs) and whether their fate can be pharmacologically modulated to improve neural plasticity and regeneration. Here, we report the characterization of a unique small molecule (KHS101) that selectively induces a neuronal differentiation phenotype. Mechanism of action studies revealed a link of KHS101 to cell cycle exit and specific binding to the TACC3 protein, whose knockdown in NPCs recapitulates the KHS101-induced phenotype. Upon systemic administration, KHS101 distributed to the brainandresulted in a significant increase in neuronal differentiation in vivo. Our findings indicate that KHS101 accelerates neuronal differentiation by interaction with TACC3 and may provide a basis for pharmacological intervention.directed at endogenous NPCs. Compare expression profile of KHS101-treated hippocampal progenitor cells (2 concentrations) vs. DMSO (negative control), retinoic acid (positive control)

Project description:Fertility critically depends on the gonadotropin-releasing hormone (GnRH) pulse generator, a neural construct comprised of hypothalamic neurons coexpressing kisspeptin, neurokoinin-B and dynorphin. Here, using mathematical modeling and in vivo optogenetics we reveal for the first time how this neural construct initiates and sustains the appropriate ultradian frequency essential for reproduction. Prompted by mathematical modeling, we show experimentally using female estrous mice that robust pulsatile release of luteinizing hormone, a proxy for GnRH, emerges abruptly as we increase the basal activity of the neuronal network using continuous low-frequency optogenetic stimulation. Further increase in basal activity markedly increases pulse frequency and eventually leads to pulse termination. Additional model predictions that pulsatile dynamics emerge from nonlinear positive and negative feedback interactions mediated through neurokinin-B and dynorphin signaling respectively are confirmed neuropharmacologically. Our results shed light on the long-elusive GnRH pulse generator offering new horizons for reproductive health and wellbeing.SIGNIFICANCE STATEMENT The gonadotropin-releasing hormone (GnRH) pulse generator controls the pulsatile secretion of the gonadotropic hormones LH and FSH and is critical for fertility. The hypothalamic arcuate kisspeptin neurons are thought to represent the GnRH pulse generator, since their oscillatory activity is coincident with LH pulses in the blood; a proxy for GnRH pulses. However, the mechanisms underlying GnRH pulse generation remain elusive. We developed a mathematical model of the kisspeptin neuronal network and confirmed its predictions experimentally, showing how LH secretion is frequency-modulated as we increase the basal activity of the arcuate kisspeptin neurons in vivo using continuous optogenetic stimulation. Our model provides a quantitative framework for understanding the reproductive neuroendocrine system and opens new horizons for fertility regulation Model is encoded by Johannes and submitted to BioModels by Ahmad Zyoud.

Project description:Neuronal activity-dependent gene expression plays important roles in neural plasticity. We use electroconvulsive stimulation (ECS) as an in vivo model for neuronal activation to identify genes that are regulated by neuronal activity. Dentate gyri (DG) were microdissected 4 hours after sham or ECS treatment for gene expression profiling.

Project description:Mutations of MECP2 (Methyl-CpG Binding Protein 2) cause Rett Syndrome. As a chromatin associated multifunctional protein, how MeCP2 integrates external signals and regulates neuronal function remain unclear. While neuronal activity-induced phosphorylation of MeCP2 at serine 421 (S421) has been reported, the full spectrum of MeCP2 phosphorylation together with the in vivo function of such modifications are yet to be revealed. Here we report the identification of several novel MeCP2 phosphorylation sites in normal and epileptic brains from multiple species. We demonstrate that serine 80 (S80) phosphorylation of MeCP2 is critical as its mutation into alanine (S80A) in transgenic knock-in mice leads to locomotor deficits. S80A mutation attenuates MeCP2 chromatin association at several gene promoters in resting neurons and leads to transcription changes of a small number of genes. Calcium influx in neurons causes dephosphorylation at S80, potentially contributing to its dissociation from the chromatin. We postulate that phosphorylation of MeCP2 modulates its dynamic function in neurons transiting between resting and active states within neural circuits that underlie behaviors. E 15.5 Mecp2 -/y cortical neurons were infected with lentivirus expressing wild-type and S80A mutant MeCP2 at similar protein expression level. 2 biological independent samples and dye swap were used for this set (GSM367413) and replicate 2 set (GSM367414).

Project description:A genomic expression comparison was done among neural progenitor cells cultured on 2D substrates, 3D porous polystyrene scaffolds, and as 3D neural spheres (in vivo surrogate), with the goal of assessing the feasibility of establishing the meaning of 3D and associated physiological relevance at the molecular level Neural progenitor cells were cultured on 2D surfaces, in 3D scaffolds and as 3D neural spheres. Chemical cues are controlled by coating. Only spacial properties of the culture systems were compared.

Project description:In this study, we established mice with orthotopic colorectal cancer (CRC mice) and observed depression-like behaviors in the CRC mice. Through whole-brain c-FOS mapping, functional connectivity analysis, gut-brain inverse mapping, and correlation analysis, combined with chemogenetic manipulation, we identified the anterior cingulate cortex (ACC) as a key hub in the depression-related brain network. we performed whole transcriptome sequencing of key neural nuclei to identify molecular changes associated with CRC-depression comorbidity. Furthermore, chemogenetic modulation of neuronal excitability not only alleviated depression-like behavior but also reduced CRC progression in these mice. Importantly, our findings suggest that targeting the ACC, in addition to conventional colorectal cancer therapies, could offer therapeutic and quality-of-life benefits for patients with both CRC and depression.

Project description:Tumor stroma strongly influences behaviour of cancer cells. Here, we study influence of the tumor stroma on transcription activity of head and neck squamous cell carcinoma cells. In particular, we compare transcription activity of the cancer cells in relation to expression of a putative prognostic marker tenascin in the surrogate of the tumor stroma, margin of surgical resecate.

Project description:A genomic expression comparison was done among neural progenitor cells cultured on 2D substrates, 3D porous polystyrene scaffolds, and as 3D neural spheres (in vivo surrogate), with the goal of assessing the feasibility of establishing the meaning of 3D and associated physiological relevance at the molecular level