Project description:Synapses are highly dynamic during early brain development, enabling the rapid adaptations that occur as neural circuits remodel in response to experience. The extracellular matrix (ECM) has been proposed as a critical regulator of synaptic plasticity in the brain. However, the molecular mechanisms that regulate the ECM and their impact on structural plasticity of synapses during brain development are unknown. Here, using time lapse imaging of excitatory synapses in zebrafish hindbrain motor neurons during development we observed synapses that were both short lived (<6 hours), and longer lived (>24 hours). Loss of ECM via hyaluronidase digestion or genetic deletion of brevican preferentially destabilized short-lived synapses relative to stable synapses, leading to increased synapse density. Conversely, genetic loss of matrix metalloprotease 14 (MMP14) led to accumulation of brevican and stabilized short-lived synapses, resulting in increased synapse density. Zebrafish microglial processes contacted synapses and expressed cell surface MMP14. Microglial MMP14 was required for its effects on synapse numbers and brevican digestion both in zebrafish as well as in triculture from human induced pluripotent stem cells. These pathways also impacted motor habituation in freely swimming fish and were required for stress-induced synapse plasticity. Based on these findings, we propose a model whereby ECM accumulation during development increases the probability that a synapse will convert from dynamic to stable. These studies define a molecular mechanism whereby ECM remodeling by microglia promote synapse plasticity in the developing brain.

Project description:Memory formation is believed result from changes in synapse strength and structure. While memories may persist for the lifetime of an organism, the proteins and lipids that make up synapses undergo constant turnover with lifetimes from minutes to days. The molecular basis for memory maintenance may rely on a subset of long-lived proteins (LLPs). While it is known that LLPs exist, whether such proteins are present at synapses is unknown. We performed an unbiased screen using metabolic pulse-chase labeling in mice and cultured neurons combined with quantitative proteomics and identified synaptic LLPs with half-lives of several weeks or longer. Synaptic proteins generally exhibited longer lifetimes than cytosolic proteins. Protein turnover was sensitive to pharmacological manipulations of activity in neuronal cultures or in mice exposed to an enriched environment. We show that synapses contain LLPs and that global synapse protein turnover is modulated by neuronal activity and behavioral experience.

Project description:Mice heterozygous for the bifunctional enzyme glucosamine-2-epimerase/N-acetylmannosamine kinase (GNE+/-), which is essential for sialic acid biosynthesis, showed reduced gne transcription and sialylation in different brain regions. We found synapse loss in the hippocampus of GNE+/- mice at 6 months followed by a gradual loss of neurons in the hippocampus and substantia nigra at 12 months. Moreover, GNE+/- mice showed reduced arborization of microglia already at 6 months. A transcriptomic analysis revealed only minor inflammatory changes with slightly increased Interleukin 1β levels, indicating a homeostatic removal of synapses and neurons. Crossbreeding with complement component 3-deficient mice rescued the early onset loss of neurons and synapses in the GNE+/- mice. Thus, an intact sialic acid covered glycocalyx plays an essential role in maintaining brain homeostasis. Even a minor reduction in the sialic acid level leads to reduced microglial arborization and complement-mediated loss of neurons and synapses.

Project description:Compared to the Scramble U87 cells, MMP14 ablation induces G2M arrest SABioscience Cell cycle platform, human genes. U87 cells were infected separately with eithr lentivirus carry on Scramble or sh RNA against human MMP14 gene.Equla amount of mRNA was isolated prior RT-PCR analyses

Project description:Skeletal stem cells (SSCs) reside in a 3-dimensional extracellular matrix (ECM) compartment and differentiate into multiple cell lineages, thereby controlling tissue maintenance and regeneration. Within this environment, SSCs can proteolytically remodel the surrounding ECM in response to growth factors that direct lineage commitment. In the bone tissue, type I collagen is the most abundant ECM. The dominant type I collagenolytic proteinase found in mammals is the type I transmembrane MMP, MMP14. Therefore, SSCs from Mmp14+/+ or Mmp14-/- mice were cultured in collagen hydrogels to explore the gene expression regulated by ECM remodeling. Microarrays were used to detail the gene expression underlying ECM remodeling process in SSCs.

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:Calyx of Held giant presynaptic terminals in the medial nucleus of the trapezoid body of the auditory brainstem form axosomatic synapses that have advanced to one of the best-studied synaptic system of the mammalian brain. As the auditory system matures and adjusts to high fidelity synaptic transmission, the calyx undergoes extensive structural and functional changes: it is formed around postnatal day 3 (P3), achieves immature function until hearing onset around P10 and can be considered mature from P21 onwards. This setting provides the unique opportunity to examine the repertoire of genes driving synaptic structure and function. We performed cell type-specific gene expression profiling of globular bushy cells (GBCs), the neurons giving rise to the calyx of Held, at different maturational stages (P3, P8 and P21). We identified GBCs by stereotaxic injection of fluorescently labelled retrograde tracer Cholera toxin B into the contralateral MNTB of anesthetized rats. Animals were sacrificed 24h after injection, the brain was taken out and flash frozen. 12um thick brainstem cryosections were prepared and 200 fluorescently labelled GBCs per animal were excised from the VCN using laser microdissection. Cells were collected from 6 animals at P3 (synapse formation), 9 animals at P8 (juvenile synapse) and 5 animals at P21 (mature synapse). RNA was isolated from the collected cells and linearly amplified in order to perform cell-type specific expression profiling.

Project description:FUS is a primarily nuclear RNA-binding protein with important roles in RNA processing and transport. FUS mutations disrupting its nuclear localization characterize a subset of amyotrophic lateral sclerosis (ALS-FUS) patients, through an unidentified pathological mechanism. FUS regulates nuclear RNA, but its role at the synapse is poorly understood. Here, we used super-resolution imaging to determine the physiological localization of extranuclear, neuronal FUS and found it predominantly near the vesicle reserve pool of presynaptic sites. Using CLIP-seq on synaptoneurosome preparations, we identified synaptic RNA targets of FUS that are associated with synapse organization and plasticity. Synaptic FUS was significantly increased in a knock-in mouse model of ALS-FUS, at presymptomatic stages. Despite apparently unaltered synaptic organization, RNA-seq of synaptoneurosomes highlighted age-dependent dysregulation of glutamatergic and GABAergic synapses. Our study indicates that FUS relocalization to the synapse in early stages of ALS-FUS results in synaptic impairment, potentially representing an initial trigger of neurodegeneration.

Project description:FUS is a primarily nuclear RNA-binding protein with important roles in RNA processing and transport. FUS mutations disrupting its nuclear localization characterize a subset of amyotrophic lateral sclerosis (ALS-FUS) patients, through an unidentified pathological mechanism. FUS regulates nuclear RNA, but its role at the synapse is poorly understood. Here, we used super-resolution imaging to determine the physiological localization of extranuclear, neuronal FUS and found it predominantly near the vesicle reserve pool of presynaptic sites. Using CLIP-seq on synaptoneurosome preparations, we identified synaptic RNA targets of FUS that are associated with synapse organization and plasticity. Synaptic FUS was significantly increased in a knock-in mouse model of ALS-FUS, at presymptomatic stages. Despite apparently unaltered synaptic organization, RNA-seq of synaptoneurosomes highlighted age-dependent dysregulation of glutamatergic and GABAergic synapses. Our study indicates that FUS relocalization to the synapse in early stages of ALS-FUS results in synaptic impairment, potentially representing an initial trigger of neurodegeneration.

Project description:FUS is a primarily nuclear RNA-binding protein with important roles in RNA processing and transport. FUS mutations disrupting its nuclear localization characterize a subset of amyotrophic lateral sclerosis (ALS-FUS) patients, through an unidentified pathological mechanism. FUS regulates nuclear RNA, but its role at the synapse is poorly understood. Here, we used super-resolution imaging to determine the physiological localization of extranuclear, neuronal FUS and found it predominantly near the vesicle reserve pool of presynaptic sites. Using CLIP-seq on synaptoneurosome preparations, we identified synaptic RNA targets of FUS that are associated with synapse organization and plasticity. Synaptic FUS was significantly increased in a knock-in mouse model of ALS-FUS, at presymptomatic stages. Despite apparently unaltered synaptic organization, RNA-seq of synaptoneurosomes highlighted age-dependent dysregulation of glutamatergic and GABAergic synapses. Our study indicates that FUS relocalization to the synapse in early stages of ALS-FUS results in synaptic impairment, potentially representing an initial trigger of neurodegeneration.