https://fz.kiev.ua/index.php?abs=2034

O. Moroz, O. Basovska, A. Zholos
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摘要

对神经元交流机制的研究是促进健康的基本发现的基础。对不同脑区或脑区内部神经元中催产素信号的研究,旨在探索这种神经激素调节剂在调节突触传递和可塑性、神经元兴奋性(这有助于繁殖、社交行为和学习能力)、焦虑、炎症和大脑分化方面的作用。催产素由下丘脑视上核和室旁核合成,从垂体后叶分泌到血液中时,对子宫收缩和泌乳产生显著影响。同时,这种在边缘系统和大脑皮层释放的非肽类物质通过影响其膜上的离子通道来调节神经元的活动。催产素受体主要与 Gq/11 蛋白耦合,导致磷脂酶 C 激活、Ca2+ 释放和储存操作的 Ca2+ 进入。这些途径是调节不同类型 TRP 通道(尤其是典型亚家族 TRPC)活性的核心。在此,我们强调催产素信号与受体操作的 TRPC4 和多模式 TRPV4 离子通道之间的联系,催产素信号在子宫肌层的研究尤为深入,而受体操作的 TRPC4 和多模式 TRPV4 离子通道在各种条件下参与了催产素对子宫平滑肌收缩力的依赖性调节。重要的是,与催产素类似,这些通道也与神经性疼痛行为、焦虑、恐惧和抑郁有关。由于类似的信号转导途径在神经元细胞中也可能起作用,我们建议今后对催产素在中枢神经系统中的作用进行研究时,也应考虑这些Ca2+渗透通道的作用。
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https://fz.kiev.ua/index.php?abs=2034
Investigation of the mechanism of neuronal communication underlies the fundamental discoveries that promote health. The studies of oxytocin signaling in neurons from or within different brain areas are directed to explore the role of this neurohormonal modulator in the regulation of synaptic transmission and plasticity, neuronal excitability that contributes to the reproduction, social behavior and learning capacity, anxiety, inflammation and differentiation in the brain. Oxytocin is synthesized in supraoptic and paraventricular nuclei of the hypothalamus and when secreted into the bloodstream from the posterior pituitary, it produces a significant effect on uterine contraction and lactation. At the same time this nonapeptide being released within the limbic system and brain cortex modulates neuronal activity by affecting ion channels on their membranes. The oxytocin receptor is primarily coupled to Gq/11 proteins causing phospholipase C activation, Ca2+ release and store-operated Ca2+ entry. These pathways are central for the regulation of the activity of different types of TRP channels, especially of the canonical subfamily (TRPC). Here we highlight the link between oxytocin signaling, which is particularly well investigated in the myometrium, and receptor-operated TRPC4 and multimodal TRPV4 ion channels that participate in oxytocin-dependent regulation of the uterine smooth muscle contractility under various conditions. Importantly, similarly to oxytocin, these channels have been implicated in neuropathic pain behavior, anxiety, fear and depression. Since similar signal transduction pathways are likely to be functional in neuronal cells, we propose that future studies of oxytocin effects in the CNS should also consider the role of these Ca2+-permeable channels.
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