Project description:Connecting neurons into functional circuits requires the formation, maturation, and plasticity of synapses. While advances have been made in identifying individual genes regulating synapse development, the molecular programs orchestrating their action during circuit integration of neurons remain poorly understood. Here we have employed a bulk RNA sequencing method (RiboTag) to study the development of hippocampal GCs. GCs represent the first relay in the hippocampal tri-synaptic loop, and play an essential role in processing spatial representations and memory acquisition. This study provides a high temporal resolution analysis of the translatome of GCs during early postnatal development (P5, P7, P10, P15, P21, and P28). Together, these findings highlight the networks of key TFs and target genes orchestrating GC synapse development.

Project description:Connecting neurons into functional circuits requires the formation, maturation, and plasticity of synapses. While advances have been made in identifying individual genes regulating synapse development, the molecular programs orchestrating their action during circuit integration of neurons remain poorly understood. Here, we have employed a combination of single nuclei transcriptome and epigenome sequencing (single nuclei multiome) to study the development of the hippocampus. The hippocampus contains several excitatory and inhibitory cell types, as well as astrocytes, glia and other immune cells of the brain. The hipocampal trisynaptic circuit (DG-CA3-CA1) is essential for learning and memory. This study provides single-cell multiome data of hippocampal postnatal (P) development (P5, P10, P15, and P28), offering an in-depth analysis of gene regulatory networks during granule cell synapse formation. Together, these findings highlight the networks of key TFs and target genes orchestrating GC synapse development.

Project description:Zinc finger protein ZBTB20 plays a critical role in mouse hippocampal development by orchestrating gene expression profile of hippocampal neurons. We used microarrays to investigate the target gene of ZBTB20 in mouse hippocampal development. Mouse hippocampi were harvested at postnatal day 2 for RNA extraction and hybridization on Affymetrix microarrays. We sought to identify the target genes of transcription factor ZBTB20 in hippocampal development. To that end, we isolated the hippocampi from ZBTB20 knockout and their littermate control mice.

Project description:Zinc finger protein ZBTB20 plays a critical role in mouse hippocampal development by orchestrating gene expression profile of hippocampal neurons. We used microarrays to investigate the target gene of ZBTB20 in mouse hippocampal development.

Project description:Synapses are asymmetric junctions between presynaptic and postsynaptic neurons that mediate information transfer in the brain. The proper formation of functional synapses is crucial for synaptic transmission and brain function. However, how neurons initially recognize each other to form synapses remain to be elucidated. Here, we performed single-cell RNA sequencing of the cultured hippocampal cells on the critical time points during synapse development. . We first built comprehensive single-cell transcriptomic atlas of hippocampus undergoing synapse formation. Furthermore, we focused on neurons, and systematically analyzed temporal dynamic functional transcription factors hubs.. We identified that transcription factors, such as EGR family genes, AP-1 family genes, NeuroD family genes, NF1 family genes, may act as key regulators of synapse formation. Besides, we provided the resources of increased membrane and secretory proteins associated with synapse formation, which including previously reported synapse formation genes, Nlgn3, Nectin1, Dag1, Snap25, and the newly identified potential genes, Tmem65, Grm5, Olfm1, Timp3. Finally, we analyzed the changes of cell communication signaling pathways in neurons before and after synapse formation, and identified several important signaling pathways, including NRXN, NCAM, BMP, NEGR, and so on. Collectively, our work provided a holistic view of the molecular dynamics of the hippocampal synapse formation.

Project description:We performed deep-sequencing analysis of small RNA extracted from neuronal progenitors at different developmental stages. The RNA samples were extracted from microdissected tissues of dorsal or lateral sub-ventricular zone (SVZ) (to analyze the immature progenitor pools), of rostral migration stream (RMS) (to analyze the migrating neuroblasts) or of olfactory bulbs (OB) (to analyze both immature and mature neurons). These tissues were dissected from animals at variable ages: P1 and P6 for SVZ samples, P15 and P28 for RMS and OB samples. Expression profile of microRNA in time and space along post-natal neurogenesis

Project description:We performed deep-sequencing analysis of small RNA extracted from neuronal progenitors at different developmental stages. The RNA samples were extracted from microdissected tissues of dorsal or lateral sub-ventricular zone (SVZ) (to analyze the immature progenitor pools), of rostral migration stream (RMS) (to analyze the migrating neuroblasts) or of olfactory bulbs (OB) (to analyze both immature and mature neurons). These tissues were dissected from animals at variable ages: P1 and P6 for SVZ samples, P15 and P28 for RMS and OB samples.

Project description:The conserved MAPKKK DLK plays many roles in neuronal development, axon injury, and neuronal stress responses. The outcomes of activating or inhibiting DLK signaling depend on cell-type and cellular contexts. Emerging evidence has implicated DLK signaling in several neurodegenerative diseases. However, our understanding of the DLK-dependent cellular network in the central nervous system remains limited. Here, we investigated roles of DLK in hippocampal glutamatergic neurons, using conditional knockout and overexpression mice. We find that dorsal CA1 and dentate gyrus neurons are particularly vulnerable to elevated DLK activity. We performed RiboTRAP-seq analysis and identified the DLK dependent translatome, majority of which are involved in neuronal developmental processes, neuronal stress responses, and synapse formation and function. Increasing DLK signaling is associated with disruptions of microtubules, potentially involving Stmn4. We also show that in primary hippocampal neurons DLK regulates neurite outgrowth, axon specification, and synapse formation. This study broadens our understanding of both conserved and cell-type specific effects of DLK signaling. The identification of translational targets of DLK in glutamatergic neurons has relevance to our understanding of neurodegenerative disease.

Project description:We have recently isolated IgSF21 (IGIS) as a novel synaptic organizer that selectively promotes inhibitory presynaptic differentiation. To isolate IgSF21 receptor that mediates synapse-promoting activity of IgSF21, we performed proteomics-based screen using cultured hippocampal neurons with IgSF21-coated magnet beads.

Project description:The process of synapse turnover is regulated by specific signaling mechanisms. Various molecules that promote formation and differentiation of synapses have been identified. Some of these molecules were classified as “synapse organizers,” as they were shown to initiate differentiation of hemi-synapses when they were expressed in non-neuronal cells and co-cultured with neurons.On the other hand, little is known about the mechanisms underlying destabilization and elimination of unnecessary synapses. We used microarray profiling of dissociated hippocampal culture to identify genes in response to the down-regulation of neuronal activity in hippocampal neurons.