Derek M Sherry, Isabella R Graf, Samuel J Bryant, Thierry Emonet, Benjamin B Machta
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引用次数: 0
Abstract
The E. coli chemosensory lattice, consisting of receptors, kinases, and adaptor proteins, is an important test case for biochemical signal processing. Kinase output is characterized by precise adaptation to a wide range of background ligand levels and large gain in response to small relative changes in concentration. Existing models of this lattice achieve their gain through allosteric interactions between either receptors or core units of receptors and kinases. Here we introduce a model which operates through an entirely different mechanism in which receptors gate inherently far from equilibrium enzymatic reactions between neighboring kinases. Our lattice model achieves gain through a mechanism more closely related to zero-order ultrasensitivity than to allostery. Thus, we call it lattice ultrasensitivity (LU). Unlike other lattice critical models, the LU model can achieve arbitrarily high gain through time-scale separation, rather than through fine-tuning. The model also captures qualitative experimental results which are difficult to reconcile with existing models. We discuss possible implementations in the lattice's baseplate where long flexible linkers could potentially mediate interactions between neighboring core units.
大肠杆菌利用由受体和附属激酶组成的规则晶格来检测和放大微弱的化学信号。激酶输出的特点是精确地适应各种背景配体水平,并对配体浓度的微小相对变化做出较大的增益反应。通过平衡合作性实现增益的模型可以很好地描述这些特征。但这些模型受到了两个实验结果的挑战。首先,在受体结合试验中,既不存在适应性,也不存在大增益。其次,在缺乏适应机制的细胞中,波动有时会非常大,基本上所有激酶都会一起发生转变。在这里,我们引入了一个远离平衡的模型,在这个模型中,受体对相邻激酶之间的活性扩散进行控制。该模型通过一种我们称之为晶格超灵敏度(LU)的机制实现巨大增益。在我们的 LU 模型中,激酶和受体状态是独立的自由度,激酶动力学由远离平衡的化学速率而不是平衡异构所主导。该模型再现了过去模型的成功,同时也符合具有挑战性的实验结果。重要的是,与过去的晶格临界模型不同,我们的 LU 模型不需要根据功能对参数进行微调。
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