鞘脂在植物-真菌互作中的分子调控机制研究进展

鞘脂是细胞生物膜结构的重要组分, 鞘脂及其代谢产物参与许多重要的信号转导过程。在植物-真菌互作中, 植物鞘脂的主要作用是诱导细胞发生程序性死亡; 真菌鞘脂既能引起植物死亡, 也能诱导植物产生抗病性。该文总结了植物和真菌鞘脂的结构及代谢特点, 综述了鞘脂参与调控植物-真菌互作的分子机制研究进展, 并展望了植物-真菌共生关系中鞘脂作用的研究方向。     

植物鞘脂的结构、代谢途径及其功能

众所周知, 鞘脂是生物膜结构的重要组成成分, 随着鞘脂在动物和酵母中的深入研究发现, 鞘脂及其代谢产物是一类很重要的活性分子, 它们参与调节细胞的生长、分化、衰老和细胞程序性死亡等许多重要的信号转导过程。鞘脂在植物中的研究最近几年才开始, 植物鞘脂的功能还不十分清楚。最近的研究发现, 鞘脂及其代谢产物在植物中也起着很重要的信号分子作用。该文详细总结了鞘脂在植物中的结构、代谢途径和主要生物学功能, 并结合实验室的工作对植物鞘脂的功能研究进行了展望。     

植物鞘脂的结构、代谢途径及其功能

众所周知,鞘脂是生物膜结构的重要组成成分,随着鞘脂在动物和酵母中的深入研究发现,鞘脂及其代谢产物是一类很重要的活性分子,它们参与调节细胞的生长、分化、衰老和细胞程序性死亡等许多重要的信号转导过程。鞘脂在植物中的研究最近几年才开始,植物鞘脂的功能还不十分清楚。最近的研究发现,鞘脂及其代谢产物在植物中也起着很重要的信号分子作用。该文详细总结了鞘脂在植物中的结构、代谢途径和主要生物学功能,并结合实验室的工作对植物鞘脂的功能研究进行了展望。     

鞘脂代谢及其相关疾病研究进展

近年对鞘脂代谢及其产物的研究越来越多.鞘脂及其代谢产物不仅是构成细胞膜的重要结构分子,而且参与调节细胞的生长、分化、衰老和细胞程序性死亡等许多重要的信号转导过程,使细胞产生各种不同的生物学功能.该文综述了鞘脂代谢途径的重要酶,鞘脂及其代谢产物的功能,以及它们与相关疾病的研究进展,并就其存在的问题和今后可能的研究方向做出展望.为鞘脂代谢的过程和鞘脂相关疾病的生理病理学研究提供重要的理论依据.     

植物防御素结构与功能及其抗真菌机制研究进展

植物防御素是一类分子量约为5 kD的阳离子肽,是植物内免疫系统的主要成分之一,参与了多种植物生理生化活动。植物防御素含8个保守半胱氨酸,形成4对链内二硫键来稳定其3条反向平行的β折叠片和1个α螺旋,构成所谓的Csαβ模体结构。植物防御素具有抑制真菌和细菌生长、抑制酶的活性、抑制癌细胞增殖和作为离子通道阻断剂等功能。植物防御素抗真菌机制比较复杂,但它可能首先必须和真菌细胞质膜外侧的鞘脂等复杂脂类结合,引起真菌细胞发生一系列的反应,包括细胞膜通透性增强、胞内活性氧水平增高和诱导真菌细胞凋亡等。但是植物防御素详细的抗真菌机制及其在真菌细胞内作用靶点等有待于深入研究。综述了近年来植物防御素结构、功能及其抗真菌机制等方面的最新研究进展。     

miRNA介导植物-微生物互作中的调控作用及其研究进展北大核心CSCD

微生物与植物之间存在错综复杂的双向交流和串扰,植物与病原微生物互作直接影响寄主植物的生存状况,而植物和益生微生物互作则有利于宿主的生长和健康,共生微生物也会从中受益。不管是病原微生物还是有益微生物进入植物体内,植物miRNA都会迅速做出响应,同时微生物也可以产生miRNA样RNA(miRNA-likeRNA,milRNA)影响植物健康,可见miRNA(或milRNA)是植物与微生物互作过程中迅速响应的重要媒介分子,其内在机制研究近年来取得了许多进展。文中概述了植物-病原微生物、植物-益生微生物互作中miRNA的调控作用,重点阐述了植物miRNA在植物-病原微生物互作过程中对寄主植物抗病性的调控作用和植物-益生微生物互作过程中对宿主植物生长发育及代谢的调控,以及真菌milRNA对寄主植物的跨界调控作用。     

神经酰胺与细胞凋亡

细胞凋亡 (apoptosis) 又称细胞的程序性死亡,参与机体许多生理和病理过程.近年来的研究表明细胞凋亡与鞘脂质代谢有密切的关系,鞘磷脂的水解产物神经酰胺作为脂质第二信使在诱导和抑制细胞凋亡中起着重要的作用.     

植物-内生真菌共生体对昆虫种群的影响

植物内生真菌与植食性昆虫共用寄主植物作为食物、能量来源及栖息场所,三者之间的互作关系复杂多变,在生物种群控制、生物进化和植物生产中发挥重要作用.从植物-内生真菌共生体、内生真菌对植食性昆虫与多级营养层的影响,及内生真菌抗虫代谢产物等方面概括了内生真菌-植物-昆虫相互关系的研究进展,建议将植物内生真菌纳入植物生态学、昆虫生态学和作物病虫害控制的范畴内.     

真菌鞘脂代谢及其与抗真菌药物关系研究进展

鞘脂是真核细胞中普遍存在的成分,它在真核细胞的胞吞、胞饮、信号转导、细胞的生长、凋亡、分化、衰老等过程中起着非常重要的作用.该文论述了真菌鞘脂代谢的途径及参与其合成的相关酶和基因,并比较了真菌与哺乳动物鞘脂代谢途径的不同,旨在为研究新型无公害抗真菌药物提供理论依据.     

鞘脂代谢关键酶丝氨酸棕榈酰转移酶的结构、功能及其相关疾病

鞘脂(sphingolipids)是生物细胞中最主要的膜脂之一，同时也作为信号分子介导细胞生长、增殖、迁移及死亡等重要的生理反应，异常鞘脂代谢经常与心血管疾病、糖尿病、癌症、神经变性病以及自身免疫性疾病等相关。丝氨酸棕榈酰转移酶(serine palmitoyltransferase, SPT)及其复合物是鞘脂从头合成途径的起始酶和关键酶，催化L-丝氨酸与棕榈酰辅酶A缩合形成3-酮二氢鞘氨醇，之后再经过一系列反应生成神经酰胺和其它重要的鞘脂，在鞘脂代谢和稳态调节方面发挥重要作用。本文基于国内外对SPT的研究，综述了SPT的构型、活性位点、底物结合位点等关键的结构信息，尤其近2年的研究发现，SPT是一种组成极其复杂的酶，各个亚基之间存在错综复杂的相互作用和高度调控。SPT具有重要的生物学功能，包括参与胚胎发育、调节内环境稳态、诱导细胞凋亡和参与机体免疫调节等。SPT还可以通过调节酶活性影响鞘脂代谢，进而影响血管疾病和肿瘤的发生发展，并有潜力成为肿瘤诊断和治疗的关键分子。此外，SPT突变体与神经变性病密切相关，本文着重介绍了遗传性感觉与自主神经病变1型(hereditary sensory...     

Translocation of cytoplasm and nucleus to fungal penetration sites is associated with depolymerization of microtubules and defence gene activation in infected, cultured parsley cells.

We describe a novel system of reduced complexity for analysing molecular plant-fungus interactions. The system consists of suspension-cultured parsley (Petroselinum crispum) cells infected with a phytopathogenic fungus (Phytophthora infestans) which adheres to a coated glass plate and thus immobilizes the plant cells for live microscopy. Conventional light and electron microscopy as well as time-lapse video microscopy confirmed the virtual identity of fungal infection structures and of several characteristic early plant defence reactions in the cultured cells and whole-plant tissue. Using this new system to approach previously unresolved questions, we made four major discoveries: (i) rapid translocation of plant cell cytoplasm and nucleus to the fungal penetration site was associated with local depolymerization of the microtubular network; (ii) the directed translocation was dependent on intact actin filaments; (iii) a typical plant defence-related gene was activated in the fungus-invaded cell; and (iv) simultaneous activation of this gene in adjacent, non-invaded cells did not require hypersensitive death of the directly affected cell.     

Building a mycorrhizal cell: How to reach compatibility between plants and arbuscular mycorrhizal fungi

Abstract

Arbuscular mycorrhizal fungi occur throughout the majority of ecosystems supporting host plant nutrition. Recent findings describe the accommodation of the fungus by the root cell as a crucial step for compatibility between the partners. We discuss here the novel aspects of cellular plant-fungus interactions, with a particular attention to the interface compartment, the unique apoplastic space hosting intracellular fungal structures. The main features of arbuscular mycorrhizal colonization are examined and recent information in the field of plant and fungal cell responses during the establishment of the symbiosis is discussed. Differences between the colonization of root epidermal and cortical tissues are discussed, highlighting the growing interest in the role of epidermal cells during the first and decisive steps of the symbiosis. New approaches such as root organ cultures, in vivo observations, GFP tagging and mutant plant analysis are commented on and information from these is compared with that gained from more traditional methods. In particular, the use of plant mutants is depicted as a powerful tool for dissecting and understanding the genetic and cellular aspects of plant/fungus compatibility. Finally, perspectives in this field are outlined through the application of these approaches to the currently unanswered questions.     

Sphingolipids in inflammation: roles and implications

Sphingolipids, historically described as potential reservoirs for bioactive lipids, presently define a new family of cellular mediators, joining the well-established glycerolipid-derived mediators of signal transduction such as diacylglycerol, phosphatidylinositides, and eicosanoids. Sphingolipid metabolism is clearly involved in the regulation of cell growth, differentiation, and programmed cell death. Indeed, a majority of the greater than four thousand studies conducted on sphingolipids during the past five years were investigations of the role of sphingolipids as cellular bioregulators. Studies spanning more than a decade have shown multiple interactions and intersections of the sphingolipid-mediated pathways and the eicosanoid pathway. This review will discuss the emerging mechanisms by which sphingolipids induce inflammatory responses via the eicosanoid pathway in addition to linking previous literature on sphingolipids and inflammation with newer findings of distinct roles for sphingosine-1-phosphate in regulating cyclooygenase-2 and ceramide-1-phosphate in the regulation of cytosolic phospholipase A2alpha. Finally, the relationship between bioactive sphingolipids and inflammation is discussed.     

Very long chain fatty acid and lipid signaling in the response of plants to pathogens

Recent findings indicate that lipid signaling is essential for plant resistance to pathogens. Besides oxylipins and unsaturated fatty acids known to play important signaling functions during plant-pathogen interactions, the very long chain fatty acid (VLCFA) biosynthesis pathway has been recently associated to plant defense through different aspects. VLCFAs are indeed required for the biosynthesis of the plant cuticle and the generation of sphingolipids. Elucidation of the roles of these lipids in biotic stress responses is the result of the use of genetic approaches together with the identification of the genes/proteins involved in their biosynthesis. This review focuses on recent observations which revealed the complex function of the cuticle and cuticle-derived signals, and the key role of sphingolipids as bioactive molecules involved in signal transduction and cell death regulation during plant-pathogen interactions.Key words: very long chain fatty acids (VLCFAs), plant-pathogen interactions, lipid signaling, sphingolipids, epicuticular waxes, lipid rafts, cuticle, plant defense     

Cell Death Control: The Interplay of Apoptosis and Autophagy in the Pathogenicity of Sclerotinia sclerotiorum

Programmed cell death is characterized by a cascade of tightly controlled events that culminate in the orchestrated death of the cell. In multicellular organisms autophagy and apoptosis are recognized as two principal means by which these genetically determined cell deaths occur. During plant-microbe interactions cell death programs can mediate both resistant and susceptible events. Via oxalic acid (OA), the necrotrophic phytopathogen Sclerotinia sclerotiorum hijacks host pathways and induces cell death in host plant tissue resulting in hallmark apoptotic features in a time and dose dependent manner. OA-deficient mutants are non-pathogenic and trigger a restricted cell death phenotype in the host that unexpectedly exhibits markers associated with the plant hypersensitive response including callose deposition and a pronounced oxidative burst, suggesting the plant can recognize and in this case respond, defensively. The details of this plant directed restrictive cell death associated with OA deficient mutants is the focus of this work. Using a combination of electron and fluorescence microscopy, chemical effectors and reverse genetics, we show that this restricted cell death is autophagic. Inhibition of autophagy rescued the non-pathogenic mutant phenotype. These findings indicate that autophagy is a defense response in this necrotrophic fungus/plant interaction and suggest a novel function associated with OA; namely, the suppression of autophagy. These data suggest that not all cell deaths are equivalent, and though programmed cell death occurs in both situations, the outcome is predicated on who is in control of the cell death machinery. Based on our data, we suggest that it is not cell death per se that dictates the outcome of certain plant-microbe interactions, but the manner by which cell death occurs that is crucial.     

Sphingolipid long-chain base hydroxylation is important for growth and regulation of sphingolipid content and composition in Arabidopsis

Sphingolipids are structural components of endomembranes and function through their metabolites as bioactive regulators of cellular processes such as programmed cell death. A characteristic feature of plant sphingolipids is their high content of trihydroxy long-chain bases (LCBs) that are produced by the LCB C-4 hydroxylase. To determine the functional significance of trihydroxy LCBs in plants, T-DNA double mutants and RNA interference suppression lines were generated for the two Arabidopsis thaliana LCB C-4 hydroxylase genes Sphingoid Base Hydroxylase1 (SBH1) and SBH2. These plants displayed reductions in growth that were dependent on the content of trihydroxy LCBs in sphingolipids. Double sbh1 sbh2 mutants, which completely lacked trihydroxy LCBs, were severely dwarfed, did not progress from vegetative to reproductive growth, and had enhanced expression of programmed cell death associated-genes. Furthermore, the total content of sphingolipids on a dry weight basis increased as the relative amounts of trihydroxy LCBs decreased. In trihydroxy LCB-null mutants, sphingolipid content was approximately 2.5-fold higher than that in wild-type plants. Increases in sphingolipid content resulted from the accumulation of molecular species with C16 fatty acids rather than with very-long-chain fatty acids, which are more commonly enriched in plant sphingolipids, and were accompanied by decreases in amounts of C16-containing species of chloroplast lipids. Overall, these results indicate that trihydroxy LCB synthesis plays a central role in maintaining growth and mediating the total content and fatty acid composition of sphingolipids in plants.     

Diversity and classification of mycorrhizal associations

Most mycorrhizas are 'balanced' mutualistic associations in which the fungus and plant exchange commodities required for their growth and survival. Myco-heterotrophic plants have 'exploitative' mycorrhizas where transfer processes apparently benefit only plants. Exploitative associations are symbiotic (in the broad sense), but are not mutualistic. A new definition of mycorrhizas that encompasses all types of these associations while excluding other plant-fungus interactions is provided. This definition recognises the importance of nutrient transfer at an interface resulting from synchronised plant-fungus development. The diversity of interactions between mycorrhizal fungi and plants is considered. Mycorrhizal fungi also function as endophytes, necrotrophs and antagonists of host or non-host plants, with roles that vary during the lifespan of their associations. It is recommended that mycorrhizal associations are defined and classified primarily by anatomical criteria regulated by the host plant. A revised classification scheme for types and categories of mycorrhizal associations defined by these criteria is proposed. The main categories of vesicular-arbuscular mycorrhizal associations (VAM) are 'linear' or 'coiling', and of ectomycorrhizal associations (ECM) are 'epidermal' or 'cortical'. Subcategories of coiling VAM and epidermal ECM occur in certain host plants. Fungus-controlled features result in 'morphotypes' within categories of VAM and ECM. Arbutoid and monotropoid associations should be considered subcategories of epidermal ECM and ectendomycorrhizas should be relegated to an ECM morphotype. Both arbuscules and vesicles define mycorrhizas formed by glomeromycotan fungi. A new classification scheme for categories, subcategories and morphotypes of mycorrhizal associations is provided.     

Calcium signaling in pathogenic and beneficial plant microbe interactions: What can we learn from the interaction between Piriformospora indica and Arabidopsis thaliana

Elevation of intracellular calcium levels in a plant cell is an early signaling event in many mutualistic and pathogenic plant/microbe interactions. In pathogenic plant/fungus interactions, receptor-mediated cytoplasmic calcium elevations induce defense genes via the activation of ion fluxes at the plasma membrane, an oxidative burst and MAPK activation. Mycorrhizal and beneficial endophytic plant/fungus interactions result in a better plant performance through sequencial cytoplasmic and nuclear calcium elevations. The specificity of the calcium responses depends on the calcium signature, its amplitude, duration, frequency and location, a selective activation of calcium channels in the diverse cellular membranes and the stimulation of calcium-dependent signaling components. Arabidopsis contains more than 100 genes for calcium-binding proteins and channels and the response to pathogens and beneficial fungi relies on a highly specific activation of individual members of these protein families. Genetic tools are required to understand this complex response patterns and the cross talks between the individual calcium-dependent signaling pathways. The beneficial interaction of Arabidopsis with the growth-promoting endophyte Piriformospora indica provides a nice model system to unravel signaling events leading to mutualistic or pathogenic plant/fungus interactions.Key words: Piriformospora indica, calcium, calcium signature, plant/microbe interaction