De Domenico Stefania, Tsesmetzis Nicolas, Di Sansebastiano Gian Pietro, Hughes Richard K, Casey Rod, Santino Angelo
Institute of Sciences of Food Production C.N.R. Section of Lecce, via Monteroni, 73100, Lecce, Italy.
BMC Plant Biol. 2007 Nov 5;7:58. doi: 10.1186/1471-2229-7-58.
Hydroperoxide lyase (HPL) is a key enzyme in plant oxylipin metabolism that catalyses the cleavage of polyunsaturated fatty acid hydroperoxides produced by the action of lipoxygenase (LOX) to volatile aldehydes and oxo acids. The synthesis of these volatile aldehydes is rapidly induced in plant tissues upon mechanical wounding and insect or pathogen attack. Together with their direct defence role towards different pathogens, these compounds are believed to play an important role in signalling within and between plants, and in the molecular cross-talk between plants and other organisms surrounding them. We have recently described the targeting of a seed 9-HPL to microsomes and putative lipid bodies and were interested to compare the localisation patterns of both a 13-HPL and a 9/13-HPL from Medicago truncatula, which were known to be expressed in leaves and roots, respectively.
To study the subcellular localisation of plant 9/13-HPLs, a set of YFP-tagged chimeric constructs were prepared using two M. truncatula HPL cDNAs and the localisation of the corresponding chimeras were verified by confocal microscopy in tobacco protoplasts and leaves. Results reported here indicated a distribution of M.truncatula 9/13-HPL (HPLF) between cytosol and lipid droplets (LD) whereas, as expected, M.truncatula 13-HPL (HPLE) was targeted to plastids. Notably, such endocellular localisation has not yet been reported previously for any 9/13-HPL. To verify a possible physiological significance of such association, purified recombinant HPLF was used in activation experiments with purified seed lipid bodies. Our results showed that lipid bodies can fully activate HPLF.
We provide evidence for the first CYP74C enzyme, to be targeted to cytosol and LD. We also showed by sedimentation and kinetic analyses that the association with LD or lipid bodies can result in the protein conformational changes required for full activation of the enzyme. This activation mechanism, which supports previous in vitro work with synthetic detergent micelle, fits well with a mechanism for regulating the rate of release of volatile aldehydes that is observed soon after wounding or tissue disruption.
氢过氧化物裂解酶(HPL)是植物氧脂代谢中的关键酶,它催化脂氧合酶(LOX)作用产生的多不饱和脂肪酸氢过氧化物裂解为挥发性醛类和氧代酸。在植物组织受到机械损伤、昆虫或病原体攻击时,这些挥发性醛类的合成会迅速被诱导。除了它们对不同病原体的直接防御作用外,这些化合物还被认为在植物内部和植物之间的信号传导以及植物与周围其他生物的分子相互作用中发挥重要作用。我们最近描述了一种种子9 - HPL定位于微粒体和假定的脂质体,并且有兴趣比较来自蒺藜苜蓿的13 - HPL和9/13 - HPL的定位模式,已知它们分别在叶片和根中表达。
为了研究植物9/13 - HPLs的亚细胞定位,使用两个蒺藜苜蓿HPL cDNA制备了一组带有黄色荧光蛋白(YFP)标签的嵌合构建体,并通过共聚焦显微镜在烟草原生质体和叶片中验证了相应嵌合体的定位。此处报道的结果表明,蒺藜苜蓿9/13 - HPL(HPLF)分布于细胞质和脂滴(LD)之间,而正如预期的那样,蒺藜苜蓿13 - HPL(HPLE)定位于质体。值得注意的是,此前尚未有关于任何9/13 - HPL这种细胞内定位的报道。为了验证这种关联可能的生理意义,将纯化的重组HPLF用于与纯化的种子脂质体的激活实验。我们的结果表明脂质体可以完全激活HPLF。
我们首次提供了CYP74C酶定位于细胞质和脂滴的证据。我们还通过沉降和动力学分析表明,与脂滴或脂质体的结合可导致酶完全激活所需的蛋白质构象变化。这种激活机制支持了先前使用合成洗涤剂胶束进行的体外研究工作,与受伤或组织破坏后不久观察到的调节挥发性醛类释放速率的机制非常吻合。
