COI1参与茉莉酸调控拟南芥吲哚族芥子油苷生物合成过程

芥子油苷是一类具有防御作用的植物次生代谢产物,外源激素茉莉酸对吲哚族芥子油苷的合成具有强烈的诱导作用,但茉莉酸调控吲哚族芥子油苷生物合成的分子机制并不清楚。以模式植物拟南芥(Arabidopsis thaliana)的野生型和coi1-22、coi1-23两种突变体为研究材料,通过茉莉酸甲酯(MeJA)处理,比较了拟南芥野生型和coi1突变体植株吲哚族芥子油苷含量、吲哚族芥子油苷合成前体色氨酸的生物合成基因(ASA1、TSA1和TSB1)、吲哚族芥子油苷生物合成基因(CYP79B2、CYP79B3和CYP83B1)及调控基因(MYB34和MYB51)的表达对MeJA的响应差异,由此确定茉莉酸信号通过COI1蛋白调控吲哚族芥子油苷生物合成,即茉莉酸信号通过信号开关COI1蛋白作用于转录因子MYB34和MYB51,进而调控吲哚族芥子油苷合成基因CYP79B2、CYP79B3、CYP83B1和前体色氨酸的合成基因ASA1、TSA1、TSB1。并且推断,COI1功能缺失后,茉莉酸信号可能通过其他未知调控因子或调控途径激活MYB34转录因子从而调控下游基因表达。     

盐胁迫对拟南芥和盐芥莲座叶芥子油苷含量的影响

芥子油苷是十字花科植物中一类含氮、含硫的次生代谢产物,与其水解产物在植物防御功能中有重要意义且与环境因子关系密切。以模式植物拟南芥（Arabidopsis thaliana）和盐生模式植物盐芥（Thellungiella halophila）为研究对象,系统地分析了盐胁迫下二者芥子油苷组成和含量的变化规律。拟南芥（生长4周）和盐芥（生长6周）叶片的芥子油苷组成在盐胁迫后没有改变。拟南芥的芥子油苷总量、脂肪族芥子油苷总量、吲哚族芥子油苷总量受盐胁迫的影响均不显著,而盐芥的则随盐胁迫增强先减少、后增加并高于对照水平。拟南芥脂肪族的3MSOP、5MSOP和吲哚族的4OHI3M、4MOI3M随盐胁迫增强而含量降低,而脂肪族的6MSOH、吲哚族的I3M以及盐芥脂肪族的3MSOP则随盐胁迫增强有含量增加的趋势。拟南芥脂肪族的8MSOO和吲哚族的1MOI3M,盐芥脂肪族的3MTP、Allyl、10MSD和吲哚族的4MOI3M,在盐胁迫下的含量变化与盐芥芥子油苷总量的变化趋势一致。     

拟南芥莲座叶芥子油苷含量对水分胁迫的响应

芥子油苷(glucosinolates)是十字花科植物中一类含氮、含硫的次生代谢产物,与其水解产物在植物防御功能中有重要意义且与环境因子关系密切.通过控制供水的方式对营养生长时期的拟南芥幼苗进行水分胁迫,观察了土壤自然干旱对营养生长时期拟南芥莲座叶芥子油苷含量及组成的影响.结果表明,土壤自然干旱处理下,拟南芥莲座叶的芥子油苷总量从处理3 d起低于对照,且随着处理天数的增加与对照组的差异逐渐增大,脂肪族芥子油苷的响应均比较明显,与芥子油苷总量的变化趋势基本一致,而吲哚族芥子油苷对水分胁迫则不敏感.脂肪族中的4-甲基亚磺酰丁基芥子油苷(4-methylsulphinylbutyl GS,4MSOB)占脂肪族芥子油苷的比例最大,它的含量变化成为影响莲座叶中芥子油苷组合模式的主导因素.     

机械损伤对拟南芥莲座叶芥子油苷含量和组成的影响

植物可以利用体内次生代谢产物的变化来抵御昆虫取食和机械损伤.芥子油苷是拟南芥的主要次生代谢产物.通过剪刀剪取叶片(40%面积)对温室培养的拟南芥幼苗莲座叶进行机械损伤处理,观察机械损伤后8个时间点拟南芥叶片中不同种类芥子油苷含量和组合模式的变化.结果表明机械损伤后3 h叶片中芥子油苷总含量开始明显上升,脂肪族和吲哚族芥子油苷含量在损伤后3 h也都显著高于损伤前.在检测到的12种芥子油苷中,4-甲基亚磺酰丁基芥子油苷(4-methylsulphinylbutyl GS,4MSOB)的含量最多,占芥子油苷总量的48.5%,并且在损伤3 h后含量增加.4MSOB含量的变化成为影响莲座叶中芥子油苷组合模式的主导因素.其它各种芥子油苷在损伤后不同时间点的变化也存在差异.     

植物激素与芥子油苷在生物合成上的相互作用

植物激素在植物的生长发育中起着关键性作用,芥子油苷是一类重要的次生代谢物质。植物激素与芥子油苷之间存在复杂的相互作用。生长素与吲哚类芥子油苷在生物合成上存在着相互作用。植物防卫信号分子与芥子油苷之间也存在相互作用,茉莉酸强烈诱导吲哚类芥子油苷生物合成相关基因CYP7982和CYP7983的表达,从而诱导吲哚-3-甲基芥子油苷和N-甲氧吲哚-3-甲基芥子油苷等吲哚类芥子油苷的生成,水杨酸和乙烯则能轻度诱导4-甲氧吲哚-3-甲基芥子油苷的生成。植物防卫信号转导途径相互作用以精细调节不同种类吲哚类芥子油苷的生成。     

植物中的吲哚族芥子油苷与生长素代谢途径的关系

文章介绍了植物中的吲哚族芥子油苷代谢与生长素合成途径相互关系的研究进展。     

外源色氨酸对油菜幼苗色氨酸下游代谢网络及生长发育的影响

色氨酸是合成蛋白质的重要氨基酸,也是植物生长激素IAA和某些次生代谢产物的前体物质,对植物生长发育及病虫害防御有重要作用。为了探究色氨酸对白菜型油菜(Brassica rapa L)生长发育及防御物质累积的影响及其可能的机制,该研究采用外源色氨酸对油菜幼苗进行叶面喷施,分析了色氨酸对油菜幼苗生长发育及生长素IAA和次生代谢产物芥子油苷合成的影响。结果表明：(1)低浓度色氨酸(100 mg/L)处理可有效地促进油菜叶片与根系的发育,但随着浓度增高,促进作用逐渐减弱。(2)荧光定量PCR分析表明,外源色氨酸处理后,油菜幼苗叶片中生长素IAA的3条合成途径都被激活,IPA途径的BrTAA1和BrYUCCA8、IAM途径的BrAMI1及IAOx途径的BrCYP71A13和BrNIT2等关键酶基因的表达均受到强烈的诱导,因而导致IAA的含量显著提高。(3)外源色氨酸处理还激活了下游的吲哚族芥子油苷的合成途径调控因子基因BrMYB34、BrMYB51和BrMYB122以及合成酶基因BrCYP79B2、BrCYP79B3、BrCYP83B1、BrSUR1的表达,同时抑制了其降解酶基因BrTGG1、BrPEN2的表达,从而引起吲哚族芥子油苷的累积。研究发现,外源色氨酸处理可通过调控生长素IAA合成途径和吲哚族芥子油苷的合成途径相关基因表达,有效地促进油菜生长调节物质和生物防御物质的累积,从而增加生物量和提高潜在抗病能力。     

拟南芥PMSR2对脂肪族芥子油苷侧链的修饰作用

芥子油苷是一类由氨基酸合成的次生代谢产物,脂肪族芥子油苷主要来源于甲硫氨酸,因侧链长度和结构的不同而拥有多样化的生物活性。根据拟南芥不同组织中芥子油苷组分和含量的特点及生物信息学分析,我们推断脂肪族芥子油苷的侧链修饰反应中可能存在由甲基亚磺酰基芥子油苷向甲硫基芥子油苷转化的还原反应,候选基因为甲硫氨酸硫还原酶2(Peptide Methionine Sulfoxide Reductase 2,PMSR2)。为了验证这一假设,我们构建了过量表达PMSR2基因的转基因拟南芥,对其芥子油苷组分及含量进行了测定,并与野生型和PMSR2基因缺失的突变体进行了对比分析,结果表明,PMSR2基因的过量表达并未使芥子油苷含量与组分发生明显变化,但PMSR2基因缺失的突变体与野生型相比,MS GSL/MT GSL的值显著提高,证明PMSR2参与了脂肪族芥子油苷侧链的修饰反应,可以将MS GSL中的硫还原生成MT GSL。该酶的鉴定进一步完善了对芥子油苷合成途径及其侧链修饰的认识,为深入研究脂肪族芥子油苷的生理功能奠定了理论基础。     

脂肪族芥子油苷侧链修饰酶基因FMO_（GS-OX4）表达模式分析

芥子油苷是一类由氨基酸衍生而来的、在植物抗生物胁迫防御性反应中起重要作用的次生代谢产物,其生物活性与侧链结构密切相关。拟南芥中有5个黄素单氧化酶FMOGS-OX1-5具有催化芥子油苷侧链上硫原子氧化的活性,使甲基硫烷芥子油苷转变为甲基亚磺酰烷芥子油苷。前期研究工作表明,在5个FMOGS-OX基因缺失突变体中,除了fmogs-ox4外均表现出芥子油苷侧链结构变化的表型。为了深入揭示FMOGS-OX4的表达特性和它对芥子油苷侧链的修饰作用,利用GFP和GUS为报告基因,系统地分析了FMOGS-OX4在不同组织中的表达情况。结果表明FMOGS-OX4主要在花梗、叶片及角果的维管组织中表达,在正常生长条件下,FMOGS-OX4表达的空间位置与芥子油苷的分布不重叠,因而,酶与底物的分离可能是fmogs-ox4没有明显表型的主要原因。     

植物芥子油苷代谢及其转移

芥子油苷是一类含氮、含硫的植物次生代谢产物,主要分布于十字花科植物。芥子油苷及其降解产物具有多种生化活性,在植物防御方面也有重要作用。简要介绍芥子油苷的分布、合成、降解和在植物体内的转移。     

Comparative quantitative trait loci mapping of aliphatic, indolic and benzylic glucosinolate production in Arabidopsis thaliana leaves and seeds

Secondary metabolites are a diverse set of plant compounds believed to have numerous functions in plant-environment interactions. Despite this importance, little is known about the regulation of secondary metabolite accumulation. We are studying the regulation of glucosinolates, a large group of secondary metabolites, in Arabidopsis to investigate how secondary metabolism is controlled. We utilized Ler and Cvi, two ecotypes of Arabidopsis that have striking differences in both the types and amounts of glucosinolates that accumulate in the seeds and leaves. QTL analysis identified six loci determining total aliphatic glucosinolate accumulation, six loci controlling total indolic glucosinolate concentration, and three loci regulating benzylic glucosinolate levels. Our results show that two of the loci controlling total aliphatic glucosinolates map to biosynthetic loci that interact epistatically to regulate aliphatic glucosinolate accumulation. In addition to the six loci regulating total indolic glucosinolate concentration, mapping of QTL for the individual indolic glucosinolates identified five additional loci that were specific to subsets of the indolic glucosinolates. These data show that there are a large number of variable loci controlling glucosinolate accumulation in Arabidopsis thaliana.     

Conservation and clade-specific diversification of pathogen-inducible tryptophan and indole glucosinolate metabolism in Arabidopsis thaliana relatives

? A hallmark of the innate immune system of plants is the biosynthesis of low-molecular-weight compounds referred to as secondary metabolites. Tryptophan-derived branch pathways contribute to the capacity for chemical defense against microbes in Arabidopsis thaliana. ? Here, we investigated phylogenetic patterns of this metabolic pathway in relatives of A. thaliana following inoculation with filamentous fungal pathogens that employ contrasting infection strategies. ? The study revealed unexpected phylogenetic conservation of the pathogen-induced indole glucosinolate (IG) metabolic pathway, including a metabolic shift of IG biosynthesis to 4-methoxyindol-3-ylmethylglucosinolate and IG metabolization. By contrast, indole-3-carboxylic acid and camalexin biosyntheses are clade-specific innovations within this metabolic framework. A Capsella rubella accession was found to be devoid of any IG metabolites and to lack orthologs of two A. thaliana genes needed for 4-methoxyindol-3-ylmethylglucosinolate biosynthesis or hydrolysis. However, C. rubella was found to retain the capacity to deposit callose after treatment with the bacterial flagellin-derived epitope flg22 and pre-invasive resistance against a nonadapted powdery mildew fungus. ? We conclude that pathogen-inducible IG metabolism in the Brassicaceae is evolutionarily ancient, while other tryptophan-derived branch pathways represent relatively recent manifestations of a plant-pathogen arms race. Moreover, at least one Brassicaceae lineage appears to have evolved IG-independent defense signaling and/or output pathway(s).     

Brassinosteroids fine-tune secondary and primary sulfur metabolism through BZR1-mediated transcriptional regulation

For adaptation to ever-changing environments,plants have evolved elaborate metabolic systems coupled to a regulatory network for optimal growth and defense. Regulation of plant secondary metabolic pathways such as glucosinolates(GSLs) by defense phytohormones in response to different stresses and nutrient deficiency has been intensively investigated, while how growth-promoting hormone balances plant secondary and primary metabolism has been largely unexplored. Here, we found that growth-promotin...     

Metabolic engineering in Nicotiana benthamiana reveals key enzyme functions in Arabidopsis indole glucosinolate modification

Indole glucosinolates, derived from the amino acid Trp, are plant secondary metabolites that mediate numerous biological interactions between cruciferous plants and their natural enemies, such as herbivorous insects, pathogens, and other pests. While the genes and enzymes involved in the Arabidopsis thaliana core biosynthetic pathway, leading to indol-3-yl-methyl glucosinolate (I3M), have been identified and characterized, the genes and gene products responsible for modification reactions of the indole ring are largely unknown. Here, we combine the analysis of Arabidopsis mutant lines with a bioengineering approach to clarify which genes are involved in the remaining biosynthetic steps in indole glucosinolate modification. We engineered the indole glucosinolate biosynthesis pathway into Nicotiana benthamiana, showing that it is possible to produce indole glucosinolates in a noncruciferous plant. Building upon this setup, we demonstrate that all members of a small gene subfamily of cytochrome P450 monooxygenases, CYP81Fs, are capable of carrying out hydroxylation reactions of the glucosinolate indole ring, leading from I3M to 4-hydroxy-indol-3-yl-methyl and/or 1-hydroxy-indol-3-yl-methyl glucosinolate intermediates, and that these hydroxy intermediates are converted to 4-methoxy-indol-3-yl-methyl and 1-methoxy-indol-3-yl-methyl glucosinolates by either of two family 2 O-methyltransferases, termed indole glucosinolate methyltransferase 1 (IGMT1) and IGMT2.     

Gene duplication in the diversification of secondary metabolism: tandem 2-oxoglutarate-dependent dioxygenases control glucosinolate biosynthesis in Arabidopsis

Secondary metabolites are a diverse set of plant compounds believed to have numerous functions in plant-environment interactions. The large chemical diversity of secondary metabolites undoubtedly arises from an equally diverse set of enzymes responsible for their biosynthesis. However, little is known about the evolution of enzymes involved in secondary metabolism. We are studying the biosynthesis of glucosinolates, a large group of secondary metabolites, in Arabidopsis to investigate the evolution of enzymes involved in secondary metabolism. Arabidopsis contains natural variations in the presence of methylsulfinylalkyl, alkenyl, and hydroxyalkyl glucosinolates. In this article, we report the identification of genes encoding two 2-oxoglutarate--dependent dioxygenases that are responsible for this variation. These genes, AOP2 and AOP3, which map to the same position on chromosome IV, result from an apparent gene duplication and control the conversion of methylsulfinylalkyl glucosinolate to either the alkenyl or the hydroxyalkyl form. By heterologous expression in Escherichia and the correlation of gene expression patterns to the glucosinolate phenotype, we show that AOP2 catalyzes the conversion of methylsulfinylalkyl glucosinolates to alkenyl glucosinolates. Conversely, AOP3 directs the formation of hydroxyalkyl glucosinolates from methylsulfinylalkyl glucosinolates. No ecotype coexpressed both genes. Furthermore, the absence of functional AOP2 and AOP3 leads to the accumulation of the precursor methylsulfinylalkyl glucosinolates. A third member of this gene family, AOP1, is present in at least two forms and found in all ecotypes examined. However, its catalytic role is still uncertain.