The role of the Ca2+-dependent phospholipase C delta1 isoform in neuronal osmosensitivity

Ca2 依赖性磷脂酶 C delta1 亚型在神经元渗透敏感性中的作用

• 批准号: RGPIN-2020-06334
• 负责人: Fisher, Thomas
• 金额: $ 2.33万
• 依托单位: University of Saskatchewan
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=743476
• 关键词: role; Ca2+; dependent; phospholipase; delta1

All mammals maintain the osmolality of their body fluids to within very narrow limits through mechanisms that regulate water intake (i.e. thirst) and the loss of water in urine. Urine volume is regulated primarily by vasopressin (VP), which is released from the magnocellular neurosecretory cells of the hypothalamus (MNCs). Acute increases in osmolality excite MNCs by causing them to shrink, leading to the activation of a mechanosensitive TRPV1 channel N-terminal variant (DeltaN TRPV1), which increases electrical activity. Sustained increases in osmolality lead to a structural and functional transformation of MNCs that includes cellular hypertrophy, rapid increases in the density of many channels and receptors on the MNC surface, and an increase in the expression of many genes. We have published data showing that increases in osmolality trigger activation of phospholipase C (PLC) in MNCs and that inhibition of PLC suppresses both MNC hypertrophy and the osmotic activation of DeltaN TRPV1 channels. PLC may therefore play key roles in both phases of MNC osmosensitivity. We also demonstrated that the osmotic activation of PLC is Ca2+-dependent, which led us to hypothesize that the isoform responsible is a member of the Ca2+-dependent PLC delta family. We have unpublished data showing that transgenic mice lacking PLC delta1 show a dramatic deficiency in their ability to respond appropriately to water deprivation. We hypothesize that the failure to increase VP release enables urine production when it should be suppressed. Furthermore, we have evidence that osmotic activation of DeltaN TRPV1 currents is almost completely suppressed in MNCs from PLC delta1 KO mice and that this may be due in part to the suppression of PLC-mediated enhancement of the actin cytoskeleton. Lastly, we have evidence that sustained increases in osmolality cause the translocation of DeltaN TRPV1 channels to the MNC plasma membrane, which may be an important part of the MNC adaptation to sustained increases in osmolality. We therefore propose to test the following four hypotheses: 1)that the defective osmoregulation in PLC delta1 KO mice is mediated by a deficiency in osmotically-evoked release of VP, 2)that PLC delta1 mediates the rapid osmotically-induced Ca2+-dependent activation of PLC, 3)that osmotic regulation of DeltaN TRPV1 channels will be diminished and osmotically-evoked changes in MNC firing will be lessened in PLC delta1 KO mice, and 4)that increased osmolality triggers the translocation of DeltaN TRPV1 channels to the MNC cell membrane. We will test these hypotheses using electrophysiological, immunocytochemical, and pharmacological approaches in rats and in PLC delta1 KO and wild type mice. The proposed experiments will elucidate the role of the PLC pathway in both the acute and sustained phases of MNC osmosensitivity.  These experiments will make an vital contribution to our long-term goal of understanding of the mechanisms underlying osmoregulation.

所有哺乳动物都通过调节水分摄入（如口渴）和尿液中水分流失的机制，将体液的渗透压维持在非常狭窄的范围内。尿量主要受加压素（VP）调节，加压素由下丘脑（MNCs）的大细胞神经分泌细胞释放。渗透压的急剧增加会使MNCs收缩，从而激活机械敏感的TRPV1通道n端变体（DeltaN TRPV1），从而增加电活动。渗透压的持续增加导致跨国细胞的结构和功能转变，包括细胞肥大，跨国细胞表面许多通道和受体密度的快速增加，以及许多基因表达的增加。我们发表的数据表明，渗透压的增加会触发跨国公司中磷脂酶C （PLC）的激活，而PLC的抑制会抑制MNC肥大和DeltaN TRPV1通道的渗透激活。因此，PLC可能在跨国公司渗透敏感性的两个阶段发挥关键作用。我们还证明了PLC的渗透活化是Ca2+依赖性的，这使我们假设负责的同工异构体是Ca2+依赖性PLC δ家族的成员。我们有未发表的数据表明，缺乏PLC δ 1的转基因小鼠对缺水的反应能力明显不足。我们假设，增加VP释放的失败使尿液产生，当它应该被抑制。此外，我们有证据表明，在PLC delta1 KO小鼠的MNCs中，DeltaN TRPV1电流的渗透激活几乎完全被抑制，这可能部分是由于PLC介导的肌动蛋白细胞骨架增强被抑制。最后，我们有证据表明，持续增加的渗透压导致DeltaN TRPV1通道易位到MNC质膜，这可能是MNC适应持续增加的渗透压的重要组成部分。因此，我们建议检验以下四个假设：1) PLC delta1 KO小鼠的渗透调节缺陷是由渗透诱发VP释放不足介导的，2)PLC delta1介导了快速渗透诱导的PLC Ca2+依赖性激活，3)PLC delta1 KO小鼠的DeltaN TRPV1通道的渗透调节将减弱，渗透诱发的MNC放电变化将减轻，4)渗透压增加触发了DeltaN TRPV1通道向MNC细胞膜的易位。我们将使用电生理、免疫细胞化学和药理学方法在大鼠、PLC delta1 KO和野生型小鼠中验证这些假设。所提出的实验将阐明PLC通路在MNC渗透敏感性的急性期和持续期的作用。这些实验将为我们理解渗透调节机制的长期目标做出重要贡献。