植物超长链脂肪酸及角质层蜡质生物合成相关酶基因研究现状

超长链脂肪酸(very long chain fatty acids, VLCFAs)在生物体中具有广泛的生理功能, 它们参与种子甘油酯、生物膜膜脂及鞘脂的合成, 并为角质层蜡质的生物合成提供前体物质。角质层是覆盖在植物地上部分最表层的保护层, 由角质和蜡质组成, 其中蜡质又分为角质层表皮蜡和内部蜡, 在植物生长发育、适应外界环境方面起重要作用。VLCFAs的合成由脂肪酰-CoA延长酶催化, 该酶是由b-酮脂酰-CoA合酶、b-酮脂酰-CoA还原酶、b-羟脂酰-CoA脱水酶和反式烯脂酰-CoA还原酶组成的多酶体系。合成后的VLCFAs通过脱羰基与酰基还原作用进入角质层蜡质合成途径, 形成各种蜡质组分。文章就VLCFAs及角质层蜡质合成代谢途径中相关酶基因研究进展方面做了综述, 并对植物蜡质基因研究中存在的问题提出一些看法。     

植物角质层内外蜡质的差异及其与抗逆性的关系

植物角质层是覆盖在植物地上部分的叶、花和非木质茎等器官表面的保护层,包括角质和蜡质。其中蜡质根据分布位置不同又分为表皮蜡质和内部蜡质。大量研究表明,表皮蜡质含量和结构在植物生长发育和抗逆性申发挥着重要作用。近年来有研究发现构成蜡质的成分在内外蜡质层中的分布存在差异,角质层蜡质成分影响植物抗逆性。本文针对角质层结构和内外蜡质差异性以及角质层结构和组成与植物抗逆性之间的关系进行了综述。     

植物角质层蜡质的化学组成研究综述

角质层是植物与外界的第一接触面,而角质层蜡质则是由位于角质层外的外层蜡质和深嵌在角质层中的内层蜡质两部分构成。植物角质层蜡质成分极其复杂,具有重要的生理功能。综述了有关植物角质层蜡质的化学组成信息,探讨了目前植物角质层蜡质化学成分研究中存在的一些问题,展望了角质层蜡质成分的研究前景。     

植物角质层蜡质合成与调控的分子生物学研究进展

角质层覆盖于陆生植物的地上部分。沉积于其表面的外角质层蜡质组成了植物与外部环境之间的屏障。蜡质的合成是由大量酶类协同作用的结果,又是一个积极可调控的过程。综述了近年来角质层蜡质合成与调控的分子生物学研究进展,包括突变体筛选、基因克隆和鉴定,以及功能基因组学研究等三方面,并对植物蜡质代谢基因克隆鉴定中存在的问题进行了探讨。     

水稻蜡质基因及其利用研究进展

简要介绍了水稻蜡质基因的等位基因位点及其表达特性。并从蜡质基因第1内含子核苷酸和蜡质基因剪切方式以及蜡质基因相关的顺式作用元件与反式作用因子等方面阐述了水稻蜡质基因表达调控,还概述了水稻蜡质基因的分子标记辅助选育方面的研究。从近年来的报道显示,利用反义RNA技术抑制水稻内源蜡质蛋白的表达是目前蜡质基因应用研究的主要方向。关于蜡质基因的研究,在其它作物中也都有报道。     

植物角质层基因研究进展

角质层是形成于陆生植物表皮细胞壁外表面的脂质保水层。角质层的基本功能是保水,同时也在响应逆境胁迫、自我清洁及器官发育等方面发挥作用。角质层通常由角质和蜡质组成。角质是角质层的主要结构成分,其主要组分是聚酯。蜡质成分主要为极长链饱和脂肪酸及其衍生物。这些组分在内质网上合成后被转运到细胞表面,进一步形成完整的角质层结构。近年来通过对角质层相关突变体及相应基因的研究,人们对角质层在合成、转运、形成及调控等各个阶段都有了较为深入的认识。蜡质和角质的合成途径已在角质层相关基因功能的解释下逐渐浮出水面。有关角质层前体转运方面的研究,主要的突破在于ABCG全转运蛋白的发现和功能解析。在角质层形成的机理方面,角质层基因中的酯酶和脂酶类基因的研究有助于进一步认识这个复杂的过程。在基因调控方面,新的转录因子基因和角质层与环境之间的相互关系研究,也为已知的调控网络增加了新内容。该文综述了目前关于角质层相关基因的最新研究进展。     

植物角质层对非生物逆境胁迫响应研究进展

角质层,包括角质和蜡质,是主要由脂肪酸及其衍生物构成的覆盖在植物的外表面的高度疏水层,在植物生长发育过程中起到非常重要的保护屏障作用。除了在极端温度、干旱、高盐等多种非生物逆境胁迫下起到保护作用外,还能够保护植物内部组织免受细菌、真菌病原体的侵染。现就植物角质层的组成、合成途径以及与植物抗逆性,特别是与抗旱能力的关系方面的最新研究进展进行了综述。     

植物蜡质及其与环境的关系

陆生植物的地上部分如叶、茎、花、果实等的表面覆盖着一层蜡质,它是由一系列复杂化合物组成的具有三维微结构的疏水层,在植物生长和发育过程中起着不可或缺的作用,具有很好的生物学功能。作为植物与环境的第一接触面,蜡质对外界环境因子的响应较敏感,当植物受到外界不利环境因子胁迫时,蜡质会改变自身晶体结构形态或化学组分构建防御机制以减少胁迫因子的作用,有效地协调植物与环境的关系。综述了近年来国内外关于植物蜡质的研究进展,在阐述蜡质层结构及其化学组分的基础上,着重介绍植物与环境因子的作用,包括非生物环境因子如水分、温度、光照、环境污染等以及植食性昆虫和病原菌等生物环境因子的作用。研究显示,胁迫环境下植物蜡质化学组分的变化,是由于不利环境因子的作用足以改变蜡质各产物的合成途径,从而影响蜡质产物。植物蜡质利用各种生理、化学机制对胁迫环境因子的适应以及响应,是植物适应各种生境的基础,因此通过对植物蜡质与环境关系的研究为进一步解析植物与环境关系提供证据。     

籼稻232蜡质基因转录起始位点的鉴定

Ｎｏｒｔｈｅｒｎｂｌｏｔ杂交分析和蜡质基因ｃＤＮＡ的序列分析表明水稻蜡质基因的转录本可能延伸到翻译起始密码子（ＡＴＧ）上游１２ｋｂ处。据此设计了２１Ｎｔ的寡核苷酸引物,并以籼稻２３２胚乳ＲＮＡ为模板,以引物延伸法确定籼稻２３２蜡质基因的转录起始点,籼稻蜡质基因的转录起始旁邻顺序ＣＴＣＡＣＣＡ与高等植物基因的转录起始点一致顺序ＣＴＣＡＴＣＡ仅相差１个碱基。通过顺序比较,对东乡野生稻蜡质基因中的转录起始位点的位置,以及对此两稻种中ＴＡＴＡ盒的可能顺序进行了讨论。     

花生种皮蜡质和角质层与黄曲霉侵染和产毒的关系

黄曲霉侵染花生的研究表明,种皮破损的黄曲霉毒素含量显著高于种皮完整的,种皮对黄曲霉侵染和产毒起着重要屏障作用。采用氯仿去除种皮蜡质,用KOH或角质酶去除种皮角质层后,种子黄曲霉感染率和黄曲霉毒素含量显著提高。种皮蜡质和角质层同时去除的与种皮破损的黄曲霉感染率和毒素含量差异不显著,表明种皮的抗性成份主要是蜡质和角质层。种皮蜡质含量测定和种皮表面扫描电镜观察表明,蜡质的含量和角质层的厚度与品种的抗性有关。抗性品种种皮蜡质含量显著高于感病品种。种皮蜡质提取物在体外抑菌效果不显著。说明蜡质的抗性作用主要是物理性阻止黄曲霉菌的穿透。     

Characterization of <Emphasis Type="Italic">Glossy1</Emphasis>-homologous genes in rice involved in leaf wax accumulation and drought resistance

The outermost surfaces of plants are covered with an epicuticular wax layer that provides a primary waterproof barrier and protection against different environmental stresses. Glossy 1 (GL1) is one of the reported genes controlling wax synthesis. This study analyzed GL1-homologous genes in Oryza sativa and characterized the key members of this family involved in wax synthesis and stress resistance. Sequence analysis revealed 11 homologous genes of GL1 in rice, designated OsGL1-1 to  OsGL1-11. OsGL1-1, -2 and -3 are closely related to GL1. OsGL1-4, -5, -6, and -7 are closely related to Arabidopsis CER1 that is involved in cuticular wax biosynthesis. OsGL1-8, -9, -10 and -11 are closely related to SUR2 encoding a putative sterol desaturase also involved in epicuticular wax biosynthesis. These genes showed variable expression levels in different tissues and organs of rice, and most of them were induced by abiotic stresses. Compared to the wild type, the OsGL1-2-over-expression rice exhibited more wax crystallization and a thicker epicuticular layer; while the mutant of this gene showed less wax crystallization and a thinner cuticular layer. Chlorophyll leaching experiment suggested that the cuticular permeability was decreased and increased in the over-expression lines and the mutant, respectively. Quantification analysis of wax composition by GC–MS revealed a significant reduction of total cuticular wax in the mutant and increase of total cuticular wax in the over-expression plants. Compared to the over-expression and wild type plants, the osgl1-2 mutant was more sensitive to drought stress at reproductive stage, suggesting an important role of this gene in drought resistance. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Plant surface lipid biosynthetic pathways and their utility for metabolic engineering of waxes and hydrocarbon biofuels

Due to their unique physical properties, waxes are high-value materials that are used in a variety of industrial applications. They are generated by chemical synthesis, extracted from fossil sources, or harvested from a small number of plant and animal species. As a result, the diversity of chemical structures in commercial waxes is low and so are their yields. These limitations can be overcome by engineering of wax biosynthetic pathways in the seeds of high-yielding oil crops to produce designer waxes for specific industrial end uses. In this review, we first summarize the current knowledge regarding the genes and enzymes generating the chemical diversity of cuticular waxes that accumulate at the surfaces of primary plant organs. We then consider the potential of cuticle biosynthetic genes for biotechnological wax production, focusing on selected examples of wax ester chain lengths and isomers. Finally, we discuss the genes/enzymes of cuticular alkane biosynthesis and their potential in future metabolic engineering of plants for the production of renewable hydrocarbon fuels.     

Novel<Emphasis Type="Italic"> eceriferum</Emphasis> mutants in<Emphasis Type="Italic"> Arabidopsis thaliana</Emphasis>

We conducted a novel non-visual screen for cuticular wax mutants in Arabidopsis thaliana (L.) Heynh. Using gas chromatography we screened over 1,200 ethyl methane sulfonate (EMS)-mutagenized lines for alterations in the major A. thaliana wild-type stem cuticular chemicals. Five lines showed distinct differences from the wild type and were further analyzed by gas chromatography and scanning electron microscopy. The five mutants were mapped to specific chromosome locations and tested for allelism with other wax mutant loci mapping to the same region. Toward this end, the mapping of the cuticular wax (cer) mutants cer10 to cer20 was conducted to allow more efficient allelism tests with newly identified lines. From these five lines, we have identified three mutants defining novel genes that have been designated CER22, CER23, and CER24. Detailed stem and leaf chemistry has allowed us to place these novel mutants in specific steps of the cuticular wax biosynthetic pathway and to make hypotheses about the function of their gene products.Abbreviations EMS Ethyl methane sulfonate - SEM Scanning electron microscopy - SSLP Simple sequence length polymorphism - WT Wild type     

Fine mapping of <Emphasis Type="Italic">BoGL1</Emphasis>, a gene controlling the glossy green trait in cabbage (<Emphasis Type="Italic">Brassica oleracea</Emphasis> L. Var. <Emphasis Type="Italic">capitata</Emphasis>)

The cuticular wax covering epidermal cells causes the glaucous appearance in cabbage. As a protective barrier, cuticular wax plays various roles in protection against biotic and abiotic stresses. This is the first gene mapping report of a dominant glossy green cabbage mutant. In the present paper, scanning electron microscopy (SEM) demonstrated that the wax crystals were severely reduced in the mutant, which indicates that the glossy green phenotype is caused by cuticular wax reduction. Genetic analysis revealed that the glossy trait is controlled by a single dominant gene. Through primer screening and fine mapping, the mutant gene BoGL1 (Brassica oleracea glossy 1) was delimited to the end of chromosome C08 by the flanking marker SSRC08–76 at a genetic distance of 0.2 cM. Two genes homologous to CER1 (ECERIFERUM 1), a gene related to wax biosynthesis in Arabidopsis, were located in the mapped region. Expressional analysis revealed that the Bol018504 gene was severely suppressed but that no nucleotide variation was found by sequencing. These results lay the foundation for the functional analysis of BoGL1, and they will accelerate the research on wax metabolism in cabbage.