Maintenance of PKMζ-modulated synaptic efficacies despite protein turnover

N. Aslam
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Abstract

How can synaptic efficacies be maintained despite the fast turnover of proteins at synapses? Partially, we know that the synthesis of new proteins is essential for the induction of the late, long-lasting phase of long-term potentiation (L-LTP). Recent experiments suggest that the concentration of protein kinase Mζ (PKMζ) is increased during L-LTP and that inhibiting the PKMζ activity during the maintenance phase can effectively reverse L-LTP. Experiments have also shown that phosphorylation is necessary for the activation of PKMζ. However, it is not clear what mechanism maintains the level and activity of PKMζ despite protein turnover and phosphatase activity. Using a mathematical modeling framework, I examine the hypothesis that the activity of PKMζ is sustained through a local switching mechanism. The model for the switching mechanism is motivated by several experimental observations: 1) PKMζ has two phosphorylation sites; one is mediated by another constitutively active kinase, Phosphoinositide-dependent kinase 1 PDK1 (T410) and is essential for its activity, and another is an autophosphorylation site, T560. 2) The phosphorylation of PKMζ increases its stability and the doubly phosphorylated PKMζ has a significantly longer lifetime than the unphosphorylated and singly phosphorylated states of PKMζ. 3) The doubly phosphorylated PKMζ also regulates the new synthesis of PKMζ through a translation feedback loop. The present study implemented a mass action model consistent with these observations. The results show that such a model can be bistable and that L-LTP induction produces an increase in the total amount of PKMζ at active synapses. The increase in PKMζ concentration was maintained through the regulation of new protein synthesis by PKMζ. The results also show that blocking the activity of PKMζ in a dose-dependent manner can effectively abolish the increase in the total amount of PKMζ, which is consistent with the effect that the PKMζ inhibitor zeta inhibitory peptide (ZIP) has experimentally demonstrated. The model is consistent with available experimental results regarding the phosphorylation levels of PKMζ and the temporal aspects of blocking experiments and produces a new prediction.
尽管蛋白周转,pkm - ζ-调节的突触功能的维持
尽管突触中蛋白质的快速周转,突触的功效是如何维持的?部分地,我们知道新蛋白质的合成对于诱导长期增强(L-LTP)的后期持久阶段至关重要。最近的实验表明,蛋白激酶Mζ (PKMζ)的浓度在L-LTP期间增加,并且在维持阶段抑制PKMζ活性可以有效地逆转L-LTP。实验也表明磷酸化对于PKMζ的激活是必要的。然而,目前尚不清楚是什么机制维持PKMζ的水平和活性,尽管蛋白质周转和磷酸酶活性。使用数学建模框架,我检验了PKMζ的活性是通过局部切换机制维持的假设。转换机制的模型是由几个实验观察得出的:1)PKMζ有两个磷酸化位点;一个是由另一个组成活性激酶介导的,磷酸肌醇依赖性激酶1 PDK1 (T410),对其活性至关重要,另一个是自磷酸化位点T560。2) PKMζ的磷酸化增加了其稳定性,双磷酸化的PKMζ的寿命明显高于PKMζ的未磷酸化和单磷酸化状态。3)双磷酸化的PKMζ还通过翻译反馈回路调节PKMζ的新合成。本研究采用了与这些观察结果一致的质量作用模型。结果表明,这种模型可以是双稳态的,并且L-LTP诱导产生活跃突触中PKMζ总量的增加。通过PKMζ对新蛋白合成的调控,维持了PKMζ浓度的增加。结果还表明,以剂量依赖的方式阻断PKMζ的活性可以有效地消除PKMζ总量的增加,这与PKMζ抑制剂zeta抑制肽(ZIP)实验证明的效果一致。该模型与现有的关于PKMζ磷酸化水平和阻断实验的时间方面的实验结果一致,并产生了新的预测。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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