原代培养的星形胶质细胞和神经元中瓦巴因结合动力学和FXYD7表达:细胞对细胞外K+稳态的影响?

Neuron glia biology Pub Date : 2010-05-01 Epub Date: 2010-02-26 DOI:10.1017/S1740925X10000013
Liang Peng, Rong Huang, Shiquen Zhang, Leif Hertz
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引用次数: 9

摘要

尽管Na+,K+- atp酶介导的K+摄取在神经元兴奋后重建静息细胞外K+中起主要作用,但关于星形胶质细胞Na+,K+- atp酶功能的信息很少,更不用说将K+返回神经元的机制了。Na+、K+- atp酶的催化单位是星形胶质细胞特异性α2、神经元特异性α3和普遍表达的α1。本研究采用非线性回归的方法计算了α1、α2和α3亚基在培养的脑皮质小鼠星形胶质细胞和小脑颗粒神经元中作为高亲和力(α2、α3)和低亲和力(α1) [3H]乌阿巴因结合位点的Bmax和KD值,它们在化学计量上与转运蛋白位点相等。还检测了脑和α1-β1亚型特异性FDYX7的细胞表达,调节Na+,K+- atp酶效率和K+敏感性。根据我们自己(Walz and Hertz, 1982)或其他人(Atterwill et al., 1985)公布的对钾离子敏感的吸收率,确定了Na+,K+- atp酶的周转率。α2和α3亚基Bmax为15 ~ 30 pmol/mg,最大周转率为70 ~ 80/s。α1亚基Bmax在神经元中较低,而在星形胶质细胞中较高(645 pmol/mg蛋白),其周转率较慢,反映了选择性表达FXYD7的表达,K+使其结合增强。讨论了这些特性对钾离子稳态的作用。
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Ouabain binding kinetics and FXYD7 expression in astrocytes and neurons in primary cultures: implications for cellular contributions to extracellular K+ homeostasis?

Although Na+,K+-ATPase-mediated K+ uptake into astrocytes plays a major role in re-establishing resting extracellular K+ following neuronal excitation little information is available about astrocytic Na+,K+-ATPase function, let alone mechanisms returning K+ to neurons. The catalytic units of the Na+,K+-ATPase are the astrocyte-specific α2, the neuron-specific α3 and the ubiquitously expressed α1. In the present work, Bmax and KD values for α1, α2 and α3 subunits were computed in cultured cerebro-cortical mouse astrocytes and cerebellar granule neurons by non-linear regression as high-affinity (α2, α3) and low-affinity (α1) [3H]ouabain binding sites, which stoichiometrically equal transporter sites. Cellular expression was also determined of the brain- and α1-β1 isoform-specific FDYX7, regulating Na+,K+-ATPase efficiency and K+-sensitivity. From ouabain-sensitive K+ uptake rates published by ourselves (Walz and Hertz, 1982) or others (Atterwill et al., 1985), Na+,K+-ATPase turnover was determined. Subunits α2 and α3 showed Bmax of 15-30 pmol/mg protein, with maximum turnover rates of 70-80/s. Bmax of the α1 subunit was low in neurons but very high in astrocytes (645 pmol/mg protein), where turnover rate was slow, reflecting expression of selectively expressed FXYD7, and binding was increased by K+. The role of these characteristics for K+ homeostasis are discussed.

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Neuron glia biology
Neuron glia biology 医学-神经科学
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