Kajimoto Taketoshi, Okada Taro, Yu Huan, Goparaju Sravan K, Jahangeer Saleem, Nakamura Shun-ichi
Division of Biochemistry, Department of Molecular and Cellular Biology, Kobe University Graduate School of Medicine, Kobe 650-0017, Japan.
Mol Cell Biol. 2007 May;27(9):3429-40. doi: 10.1128/MCB.01465-06. Epub 2007 Feb 26.
Neuronal activity greatly influences the formation and stabilization of synapses. Although receptors for sphingosine-1-phosphate (S1P), a lipid mediator regulating diverse cellular processes, are abundant in the central nervous system, neuron-specific functions of S1P remain largely undefined. Here, we report two novel actions of S1P using primary hippocampal neurons as a model system: (i) as a secretagogue where S1P triggers glutamate secretion and (ii) as an enhancer where S1P potentiates depolarization-evoked glutamate secretion. Sphingosine kinase 1 (SK1), a key enzyme for S1P production, was enriched in functional puncta of hippocampal neurons. Silencing SK1 expression by small interfering RNA as well as SK1 inhibition by dimethylsphingosine resulted in a strong inhibition of depolarization-evoked glutamate secretion. Fluorescence recovery after photobleaching analysis showed translocation of SK1 from cytosol to membranes at the puncta during depolarization, which resulted in subsequent accumulation of S1P within cells. Fluorescent resonance energy transfer analysis demonstrated that the S1P(1) receptor at the puncta was activated during depolarization and that depolarization-induced S1P(1) receptor activation was inhibited in SK1-knock-down cells. Importantly, exogenously added S1P at a nanomolar concentration by itself elicited glutamate secretion from hippocampal cells even when the Na(+)-channel was blocked by tetrodotoxin, suggesting that S1P acts on presynaptic membranes. Furthermore, exogenous S1P at a picomolar level potentiated depolarization-evoked secretion in the neurons. These findings indicate that S1P, through its autocrine action, facilitates glutamate secretion in hippocampal neurons both by secretagogue and enhancer actions and may be involved in mechanisms underlying regulation of synaptic transmission.
神经元活动对突触的形成和稳定有很大影响。尽管1-磷酸鞘氨醇(S1P)的受体在中枢神经系统中大量存在,S1P是一种调节多种细胞过程的脂质介质,但其在神经元中的特定功能仍 largely未明。在这里,我们以原代海马神经元为模型系统,报告了S1P的两种新作用:(i)作为促分泌剂,S1P触发谷氨酸分泌;(ii)作为增强剂,S1P增强去极化诱发的谷氨酸分泌。鞘氨醇激酶1(SK1)是产生S1P的关键酶,在海马神经元的功能点中富集。用小干扰RNA沉默SK1表达以及用二甲基鞘氨醇抑制SK1,导致去极化诱发的谷氨酸分泌受到强烈抑制。光漂白后荧光恢复分析表明,在去极化过程中,SK1从细胞质转移到点处的膜上,导致随后细胞内S1P的积累。荧光共振能量转移分析表明,点处的S1P(1)受体在去极化过程中被激活,并且在SK1敲低细胞中去极化诱导的S1P(1)受体激活受到抑制。重要的是,即使河豚毒素阻断了Na(+)通道,以纳摩尔浓度外源添加的S1P本身也能从海马细胞中引发谷氨酸分泌,这表明S1P作用于突触前膜。此外,皮摩尔水平的外源S1P增强了神经元中去极化诱发的分泌。这些发现表明,S1P通过其自分泌作用,通过促分泌剂和增强剂作用促进海马神经元中的谷氨酸分泌,并且可能参与突触传递调节的潜在机制。