Delhaize E, Hebb D M, Richards K D, Lin J M, Ryan P R, Gardner R C
Plant Industry, Commonwealth Scientific Industrial and Research Organisation, GPO Box 1600, Canberra Australian Capital Territory 2601, Australia.
J Biol Chem. 1999 Mar 12;274(11):7082-8. doi: 10.1074/jbc.274.11.7082.
We describe the cloning of a wheat cDNA (TaPSS1) that encodes a phosphatidylserine synthase (PSS) and provides the first strong evidence for the existence of this enzyme in a higher eukaryotic cell. The cDNA was isolated on its ability to confer increased resistance to aluminum toxicity when expressed in yeast. The sequence of the predicted protein encoded by TaPSS1 shows homology to PSS from both yeast and bacteria but is distinct from the animal PSS enzymes that catalyze base-exchange reactions. In wheat, Southern blot analysis identified the presence of a small family of genes that cross-hybridized to TaPSS1, and Northern blots showed that aluminum induced TaPSS1 expression in root apices. Expression of TaPSS1 complemented the yeast cho1 mutant that lacks PSS activity and altered the phospholipid composition of wild type yeast, with the most marked effect being increased abundance of phosphatidylserine (PS). Arabidopsis thaliana leaves overexpressing TaPSS1 showed a marked enhancement in PSS activity, which was associated with increased biosynthesis of PS at the expense of both phosphatidylinositol and phosphatidylglycerol. Unlike mammalian cells where PS accumulation is tightly regulated even when the capacity for PS biosynthesis is increased, plant cells accumulated large amounts of PS when TaPSS1 was overexpressed. High levels of TaPSS1 expression in Arabidopsis and tobacco (Nicotiana tabacum) led to the appearance of necrotic lesions on leaves, which may have resulted from the excessive accumulation of PS. The cloning of TaPSS1 now provides evidence that the yeast pathway for PS synthesis exists in some plant tissues and provides a tool for understanding the pathways of phospholipid biosynthesis and their regulation in plants.
我们描述了一个小麦cDNA(TaPSS1)的克隆,该cDNA编码一种磷脂酰丝氨酸合酶(PSS),并首次有力证明了这种酶在高等真核细胞中的存在。该cDNA是根据其在酵母中表达时赋予增强的抗铝毒性能力而分离得到的。TaPSS1编码的预测蛋白序列与酵母和细菌中的PSS具有同源性,但与催化碱基交换反应的动物PSS酶不同。在小麦中,Southern杂交分析确定存在一个与TaPSS1交叉杂交的小基因家族,Northern杂交显示铝诱导TaPSS1在根尖表达。TaPSS1的表达补充了缺乏PSS活性的酵母cho1突变体,并改变了野生型酵母的磷脂组成,最显著的影响是磷脂酰丝氨酸(PS)丰度增加。过表达TaPSS1的拟南芥叶片显示PSS活性显著增强,这与以磷脂酰肌醇和磷脂酰甘油为代价的PS生物合成增加有关。与哺乳动物细胞不同,即使PS生物合成能力增加时PS积累也受到严格调控,植物细胞在过表达TaPSS1时积累了大量PS。拟南芥和烟草(烟草)中高水平的TaPSS1表达导致叶片上出现坏死病变,这可能是由于PS过度积累所致。TaPSS1的克隆现在提供了证据,表明酵母PS合成途径存在于一些植物组织中,并为理解植物中磷脂生物合成途径及其调控提供了一个工具。
