脂质转移和膜接触形成的定量模型。

Yongli Zhang, Jinghua Ge, Xin Bian, Avinash Kumar
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引用次数: 11

摘要

脂质转移蛋白(LTPs)在不同细胞器之间传递脂质,在脂质稳态和细胞器动力学中起关键作用。脂质转移通常发生在膜接触部位(MCS),其中两个膜保持在10-30纳米内。虽然大多数ltp作为转运脂质的穿梭机,但最近的实验揭示了一类新的真核ltp可能作为mcs中散装转运脂质的桥梁。然而,脂质转移和MCS形成的分子机制尚不清楚。在这里,我们首先回顾了最近两项使用新方法的扩展synaptotagmin (E-Syt)介导的膜结合和脂质转移的研究。然后,我们描述了基于脂质交换机制的数学模型来量化穿梭LTPs的脂质转移动力学。我们发现,在组成相似的膜之间进行简单的脂质混合和/或在组成不同的膜之间进行脂质分配,可以解释在ltp中广泛观察到的针对浓度梯度的脂质转移。我们预测,脂类的选择性运输,而不是膜蛋白,通过桥式LTPs导致渗透膜张力,类似于半透膜上的渗透压。这种张力和常规膜张力的梯度可以驱动大量脂质以与体内观察到的快速膜膨胀一致的速度通过桥式ltp。最后,我们讨论了膜张力和脂质转移在细胞器生物发生中的意义。总之,定量模型可能有助于阐明ltp介导的MCS形成和脂质转移的机制。
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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Quantitative Models of Lipid Transfer and Membrane Contact Formation.

Lipid transfer proteins (LTPs) transfer lipids between different organelles, and thus play key roles in lipid homeostasis and organelle dynamics. The lipid transfer often occurs at the membrane contact sites (MCS) where two membranes are held within 10-30 nm. While most LTPs act as a shuttle to transfer lipids, recent experiments reveal a new category of eukaryotic LTPs that may serve as a bridge to transport lipids in bulk at MCSs. However, the molecular mechanisms underlying lipid transfer and MCS formation are not well understood. Here, we first review two recent studies of extended synaptotagmin (E-Syt)-mediated membrane binding and lipid transfer using novel approaches. Then we describe mathematical models to quantify the kinetics of lipid transfer by shuttle LTPs based on a lipid exchange mechanism. We find that simple lipid mixing among membranes of similar composition and/or lipid partitioning among membranes of distinct composition can explain lipid transfer against a concentration gradient widely observed for LTPs. We predict that selective transport of lipids, but not membrane proteins, by bridge LTPs leads to osmotic membrane tension by analogy to the osmotic pressure across a semipermeable membrane. A gradient of such tension and the conventional membrane tension may drive bulk lipid flow through bridge LTPs at a speed consistent with the fast membrane expansion observed in vivo. Finally, we discuss the implications of membrane tension and lipid transfer in organelle biogenesis. Overall, the quantitative models may help clarify the mechanisms of LTP-mediated MCS formation and lipid transfer.

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