SummaryParkinson's disease (PD) is a neurodegenerative disorder characterized by a progressive loss of dopaminergic neurons in the substantia nigra (SN). The present study was designed to examine the therapeutic effect of hydrogen sulfide (H 2 S, a novel biological gas) on PD. The endogenous H 2 S level was markedly reduced in the SN in a 6-hydroxydopamine (6-OHDA)-induced PD rat model. Systemic administration of NaHS (an H 2 S donor) dramatically reversed the progression of movement dysfunction, loss of tyrosine-hydroxylase positive neurons in the SN and the elevated malondialdehyde level in injured striatum in the 6-OHDA-induced PD model. H 2 S specifically inhibited 6-OHDA evoked NADPH oxidase activation and oxygen consumption. Similarly, administration of NaHS also prevented the development of PD induced by rotenone. NaHS treatment inhibited microglial activation in the SN and accumulation of pro-inflammatory factors (e.g. TNF-a and nitric oxide) in the striatum via NF-jB pathway. Moreover, significantly less neurotoxicity was found in neurons treated with the conditioned medium from microglia incubated with both NaHS and rotenone compared to that with rotenone only, suggesting that the therapeutic effect of NaHS was, at least partially, secondary to its suppression of microglial activation. In summary, we demonstrate for the first time that H 2 S may serve as a neuroprotectant to treat and prevent neurotoxin-induced neurodegeneration via multiple mechanisms including anti-oxidative stress, anti-inflammation and metabolic inhibition and therefore has potential therapeutic value for treatment of PD.
The release of amyloid precursor protein (APP) intracellular domain (AICD) may be triggered by extracellular cues through γ-secretase-dependent cleavage. AICD binds to Fe65, which may have a role in AICD-dependent signalling; however, the functional ligand has not been characterized. In this study, we have identified TAG1 as a functional ligand of APP. We found that, through an extracellular interaction with APP, TAG1 increased AICD release and triggered Fe65-dependent activity in a γ-secretasedependent manner. TAG1, APP and Fe65 colocalized in the neural stem cell niche of the fetal ventricular zone. Neural precursor cells from TAG1 -/-, APP -/-and TAG1 -/-;APP -/-mice had aberrantly enhanced neurogenesis, which was significantly reversed in TAG1 -/-mice by TAG1 or AICD but not by AICD mutated at the Fe65 binding site. Notably, TAG1 reduced normal neurogenesis in Fe65 +/+ mice. Abnormally enhanced neurogenesis also occurred in Fe65 -/-mice but could not be reversed by TAG1. These results describe a TAG1-APP signalling pathway that negatively modulates neurogenesis through Fe65.The γ-secretase proteolytic complex cleaves a wide spectrum of type-1 transmembrane protein substrates, including Notch and APP, by regulated intramembrane proteolysis (RIP) to release their intracellular domains 1 . Ligand-binding to the substrate protein is one mechanism by which this cleavage is regulated. When a ligand binds to Notch, RIP stimulates the release of the intracellular domain of Notch (NICD), which interacts with the transcription factor CSL (CBF1, Suppressor of Hairless and Lag1; ref. 1). Similar transcriptional activity or regulation has been proposed for the intracellular domains cleaved from other γ-secretase substrates, including AICD, which is cleaved from APP 1 . It is therefore important to understand the physiological mechanisms regulating cleavage of AICD.Glycophosphatidylinositol (GPI)-linked proteins are anchored to the outer leaflet of the plasma membrane and mediate the dynamic remodelling of membranes during cell-cell interactions. In the central nervous system (CNS), GPI-linked recognition molecules, such as TAG1, NB-3 and F3, have been implicated in key developmental events, including selective axonal fasciculation, neural cell adhesion and migration, and neurite outgrowth 2 . Recently, we identified F3 and its homologue NB-3 as functional ligands for the Notch receptor and we showed that their interaction with each other is involved in oligodendrocyte differentiation through activation of the transcriptional factor Deltex1 (refs 3, 4). Given that RIP processing of APP is strikingly similar to that of the Notch receptor 5 , knowledge of the interaction between F3 and the Notch receptor has led us to ask whether members of the F3 family may act as APP ligands. RESULTS TAG1 and APP bind to each otherTo investigate the potential interaction between APP and members of the F3 subfamily, cell adhesion assays were performed. When F3-transfected CHO (CHOF3) cells or non-transfected CHO cells were seeded onto c...
Neurons and glia in the vertebrate central nervous system arise in temporally distinct, albeit overlapping, phases. Neurons are generated first followed by astrocytes and oligodendrocytes from common progenitor cells. Increasing evidence indicates that axon-derived signals spatiotemporally modulate oligodendrocyte maturation and myelin formation. Our previous observations demonstrate that F3/contactin is a functional ligand of Notch during oligodendrocyte maturation, revealing the existence of another group of Notch ligands. Here, we establish that NB-3, a member of the F3/contactin family, acts as a novel Notch ligand to participate in oligodendrocyte generation. NB-3 triggers nuclear translocation of the Notch intracellular domain and promotes oligodendrogliogenesis from progenitor cells and differentiation of oligodendrocyte precursor cells via Deltex1. In primary oligodendrocytes, NB-3 increases myelin-associated glycoprotein transcripts. Thus, the NB-3/Notch signaling pathway may prove to be a molecular handle to treat demyelinating diseases. Neural progenitor cells (NPCs)1 are self-renewing multipotent cells that can give rise to all types of neural cells, namely neurons, oligodendrocytes (OLs), and astrocytes. Increasing evidence suggests that this fate commitment of NPCs requires molecular cues provided by extracellular molecules and intrinsic signaling involving various transcription factors (1, 2). Our recent study (3) has demonstrated that the F3/Notch signaling pathway via Deltex1 (DTX1) promotes oligodendrocyte precursor cell (OPC) differentiation into oligodendrocytes (OLs) and up-regulates myelin-associated glycoprotein (MAG) expression in both primary OLs and OLN-93 cells, an OL cell line.
Sorting nexin 27 (SNX27), a PDZ domain-containing endosomal protein, was recently shown to modulate glutamate receptor recycling in Down’s syndrome. However, the precise molecular role of SNX27 in GluA1 trafficking is unclear. Here we report that SNX27 is enriched in dendrites and spines, along with recycling endosomes. Significantly, the mobilization of SNX27 along with recycling endosomes into spines was observed. Mechanistically, SNX27 interacts with K-ras GTPase via the RA domain; and following chemical LTP stimuli, K-ras is recruited to SNX27-enriched endosomes through a Ca2+/CaM-dependent mechanism, which in turn drives the synaptic delivery of homomeric GluA1 receptors. Impairment of SNX27 prevents LTP and associated trafficking of AMPARs. These results demonstrate a role for SNX27 in neuronal plasticity, provide a molecular explanation for the K-ras signal during LTP and identify SNX27 as the PDZ-containing molecular linker that couples the plasticity stimuli to the delivery of postsynaptic cargo.
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