Mitochondrial H2O2 as an enable signal for triggering autophosphorylation of insulin receptor in neurons.

Q2 Biochemistry, Genetics and Molecular Biology Journal of Molecular Signaling Pub Date : 2013-10-05 DOI:10.1186/1750-2187-8-11
Nadezhda A Persiyantseva, Tatiana P Storozhevykh, Yana E Senilova, Lubov R Gorbacheva, Vsevolod G Pinelis, Igor A Pomytkin
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引用次数: 24

Abstract

Background: Insulin receptors are widely distributed in the brain, where they play roles in synaptic function, memory formation, and neuroprotection. Autophosphorylation of the receptor in response to insulin stimulation is a critical step in receptor activation. In neurons, insulin stimulation leads to a rise in mitochondrial H2O2 production, which plays a role in receptor autophosphorylation. However, the kinetic characteristics of the H2O2 signal and its functional relationships with the insulin receptor during the autophosphorylation process in neurons remain unexplored to date.

Results: Experiments were carried out in culture of rat cerebellar granule neurons. Kinetic study showed that the insulin-induced H2O2 signal precedes receptor autophosphorylation and represents a single spike with a peak at 5-10 s and duration of less than 30 s. Mitochondrial complexes II and, to a lesser extent, I are involved in generation of the H2O2 signal. The mechanism by which insulin triggers the H2O2 signal involves modulation of succinate dehydrogenase activity. Insulin dose-response for receptor autophosphorylation is well described by hyperbolic function (Hill coefficient, nH, of 1.1±0.1; R2=0.99). N-acetylcysteine (NAC), a scavenger of H2O2, dose-dependently inhibited receptor autophosphorylation. The observed dose response is highly sigmoidal (Hill coefficient, nH, of 8.0±2.3; R2=0.97), signifying that insulin receptor autophosphorylation is highly ultrasensitive to the H2O2 signal. These results suggest that autophosphorylation occurred as a gradual response to increasing insulin concentrations, only if the H2O2 signal exceeded a certain threshold. Both insulin-stimulated receptor autophosphorylation and H2O2 generation were inhibited by pertussis toxin, suggesting that a pertussis toxin-sensitive G protein may link the insulin receptor to the H2O2-generating system in neurons during the autophosphorylation process.

Conclusions: In this study, we demonstrated for the first time that the receptor autophosphorylation occurs only if mitochondrial H2O2 signal exceeds a certain threshold. This finding provides novel insights into the mechanisms underlying neuronal response to insulin. The neuronal insulin receptor is activated if two conditions are met: 1) insulin binds to the receptor, and 2) the H2O2 signal surpasses a certain threshold, thus, enabling receptor autophosphorylation in all-or-nothing manner. Although the physiological rationale for this control remains to be determined, we propose that malfunction of mitochondrial H2O2 signaling may lead to the development of cerebral insulin resistance.

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线粒体H2O2作为触发神经元胰岛素受体自磷酸化的使能信号。
背景:胰岛素受体广泛分布于大脑,在突触功能、记忆形成和神经保护中发挥作用。响应胰岛素刺激的受体自磷酸化是受体激活的关键步骤。在神经元中,胰岛素刺激导致线粒体H2O2产生增加,这在受体自磷酸化中起作用。然而,在神经元自磷酸化过程中,H2O2信号的动力学特征及其与胰岛素受体的功能关系仍未被探索。结果:在大鼠小脑颗粒神经元培养中进行了实验。动力学研究表明,胰岛素诱导的H2O2信号先于受体自磷酸化,呈单峰,峰值在5 ~ 10 s出现,持续时间小于30 s。线粒体复合体II和在较小程度上参与H2O2信号的产生。胰岛素触发H2O2信号的机制涉及琥珀酸脱氢酶活性的调节。胰岛素对受体自磷酸化的剂量反应可以用双曲函数很好地描述(Hill系数nH为1.1±0.1;R2 = 0.99)。n -乙酰半胱氨酸(NAC)是H2O2的清除剂,剂量依赖性地抑制受体的自磷酸化。观察到的剂量响应呈高度s型曲线(Hill系数nH为8.0±2.3;R2=0.97),说明胰岛素受体自磷酸化对H2O2信号高度超敏感。这些结果表明,只有当H2O2信号超过一定阈值时,自磷酸化才会随着胰岛素浓度的增加而逐渐发生。胰岛素刺激的受体自磷酸化和H2O2生成均受到百日咳毒素的抑制,提示百日咳毒素敏感的G蛋白可能在自磷酸化过程中将胰岛素受体与神经元中H2O2生成系统联系起来。结论:在本研究中,我们首次证明了只有当线粒体H2O2信号超过一定阈值时,受体才会发生自磷酸化。这一发现为神经元对胰岛素的反应机制提供了新的见解。当满足两个条件时,神经元胰岛素受体被激活:1)胰岛素与受体结合,2)H2O2信号超过一定阈值,从而使受体以全有或全无的方式进行自磷酸化。尽管这种控制的生理原理仍有待确定,但我们认为线粒体H2O2信号的故障可能导致脑胰岛素抵抗的发展。
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Journal of Molecular Signaling
Journal of Molecular Signaling Biochemistry, Genetics and Molecular Biology-Biochemistry
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期刊介绍: Journal of Molecular Signaling is an open access, peer-reviewed online journal that encompasses all aspects of molecular signaling. Molecular signaling is an exponentially growing field that encompasses different molecular aspects of cell signaling underlying normal and pathological conditions. Specifically, the research area of the journal is on the normal or aberrant molecular mechanisms involving receptors, G-proteins, kinases, phosphatases, and transcription factors in regulating cell proliferation, differentiation, apoptosis, and oncogenesis in mammalian cells. This area also covers the genetic and epigenetic changes that modulate the signaling properties of cells and the resultant physiological conditions.
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