Institute of Phytopathology and Applied Zoology, Research Centre for Biosystems, Land Use, and Nutrition, Justus Liebig University, D-35392 Giessen, Germany.
Plant Physiol. 2012 Sep;160(1):349-64. doi: 10.1104/pp.112.201319. Epub 2012 Jun 29.
Tubby and Tubby-like proteins (TLPs) were first discovered in mammals, where they are involved in the development and function of neuronal cells. Due to their importance as plasma membrane (PM)-tethered transcription factors or mediators of vesicle trafficking, their lack causes obesity and other disease syndromes. Phosphatidylinositol 4,5-bisphosphate binding of the carboxyl-terminal Tubby domain attaches these proteins to the PM and vesicles and is essential for function. TLPs are conserved across eukaryotic kingdoms including plants, suggesting fundamental biological functions of TLPs. Plant TLPs possess an amino-terminal F-box domain that distinguishes them from other eukaryotic TLPs. Arabidopsis (Arabidopsis thaliana) encodes 11 AtTLPs that fall into six phylogenetic clades. We identified the significance of AtTLPs for root colonization of Arabidopsis by the mutualistic fungus Piriformospora indica. Our results further indicate conserved phosphatidylinositol 4,5-bisphosphate-binding sites in the Tubby domains that are required for PM anchoring of AtTLPs. More detailed studies revealed phospholipase C-triggered release of AtTLP3 from the PM, indicating a conserved mechanism as reported for mammalian Tubby and TLP3. We further show that hydrogen peroxide stimulates the release of AtTLP3 from the PM, presumably for activating downstream events. Different from mammalian homologs, the amino-terminal part of almost all AtTLPs has nucleocytosolic and plastidial localization patterns. Thus, it is tempting to assume that TLPs translate reactive oxygen species currents into signaling not only for transcriptional regulation in the nucleus but also affect plastid-associated functions after release from the PM.
Tubby 和 Tubby 样蛋白 (TLPs) 最初在哺乳动物中被发现,它们参与神经元细胞的发育和功能。由于它们作为质膜 (PM) 连接的转录因子或囊泡运输的介质的重要性,它们的缺乏会导致肥胖和其他疾病综合征。羧基末端 Tubby 结构域与磷脂酰肌醇 4,5-二磷酸的结合将这些蛋白附着到 PM 和囊泡上,这对于功能至关重要。TLPs 在包括植物在内的真核生物王国中是保守的,这表明 TLPs 具有基本的生物学功能。植物 TLPs 具有氨基末端 F-box 结构域,将它们与其他真核 TLPs 区分开来。拟南芥(Arabidopsis thaliana)编码 11 种 AtTLPs,分为六个系统发育分支。我们确定了 AtTLPs 在拟南芥与共生真菌 Piriformospora indica 根部定植中的重要性。我们的结果进一步表明,Tubby 结构域中的保守磷脂酰肌醇 4,5-二磷酸结合位点是 AtTLPs 在 PM 上锚定所必需的。更详细的研究揭示了 Tubby 结构域中的保守磷脂酶 C 触发的 AtTLP3 从 PM 上的释放,表明了哺乳动物 Tubby 和 TLP3 报道的保守机制。我们进一步表明,过氧化氢刺激 AtTLP3 从 PM 上释放,可能是为了激活下游事件。与哺乳动物同源物不同,几乎所有 AtTLPs 的氨基末端部分具有核质和质体的定位模式。因此,人们不禁假设,TLPs 将活性氧电流转化为信号,不仅用于核内转录调控,而且在从 PM 释放后还影响与质体相关的功能。