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。     

Variation of glucosinolates on position orders of flower buds in turnip rape (Brassica rapa)

To glucosinolate (GSL) contents on flower buds depending on their position orders in turnip rape (Brassica rapa), three Japanese ‘Nabana’ cultivars such as cv. No. 21 (Brassica rapa, early type), cv. Husanohana (B. rapa, late type) and cv. Norin No. 20 (B. napus) were investigated using HPLC analysis. Ten GSLs including glucoraphanin, sinigrin, glucoalyssin, napoleiferin, gluconapin, 4-hydroxyglucobrassicin, glucobrassicanapin, glucobrassicin, and gluconasturtiin were detected. Differences in individual and total GSL contents were found between two plant varieties, which are also depending on various developmental stages. Among the GSLs, gluconapin (mean 23.11 μmole/g dry weight (DW) and glucobrassicanapin (mean 13.41 μmole/g DW) documented the most abundant compounds and contributed average 39 and 27% of the total GSLs, but indolyl and aromatic GSLs together accounted >10% of the total GSLs. The presence of significant quantities of gluconapin in the cultivars should be studied more extensively, since the GSL is mainly responsible for the bitter taste.     

Inhibition of Glycosphingolipid Biosynthesis Does Not Impair Growth or Morphogenesis of the Postimplantation Mouse Embryo

Abstract: Whole embryo culture (WEC) of organogenesis-stage mouse embryos was adapted for glycosphingolipid (GSL) metabolic studies to evaluate the hypothesis that de novo GSL biosynthesis is a prerequisite for growth and morphogenesis of the early postimplantation embryo. WEC supports the growth and development of postimplantation mouse embryos to stages that are indistinguishable from those achieved in vivo. N -Butyldeoxygalactonojirimycin ( N B-DGJ) is an N -alkylated imino sugar that specifically inhibits biosynthesis of all glucosylceramide-based GSLs. N B-DGJ inhibited glucosylceramide and lactosylceramide biosynthesis nearly completely and inhibited ganglioside biosynthesis ∼90% in both the embryo and visceral yolk sac. N B-DGJ also significantly reduced total ganglioside content in both the embryo and visceral yolk sac as estimated by the cholera toxin immunooverlay technique. A shift in expression from the structurally simple to the structurally complex gangliosides was also observed in N B-DGJ-treated embryos and yolk sacs. Despite causing major changes in GSL biosynthesis and composition, N B-DGJ had no effect on embryo viability, growth, or morphology. The findings suggest that de novo GSL biosynthesis may not be a prerequisite for the growth and morphogenesis of the organogenesis-stage mouse embryo.     

Relationship of endogenous abscisic Acid to sucrose level and seed growth rate of soybeans

It has been proposed that abscisic acid (ABA) may stimulate sucrose transport into filling seeds of legumes, potentially regulating seed growth rate. The objective of this study was to determine whether the rate of dry matter accumulation in seeds of soybeans (Glycine max L.) is correlated with the endogenous levels of ABA and sucrose in those sinks. The levels of ABA and sucrose in seed tissues were compared in nine diverse Plant Introduction lines having seed growth rates ranging from 2.5 to 10.0 milligrams dry weight per seed per day. At 14 days after anthesis (DAA), seeds of all genotypes contained less than 2 micrograms of ABA per gram fresh weight. Levels of ABA increased rapidly, however, reaching maxima at 20 to 30 DAA, depending upon tissue type and genotype. ABA accumulated first in seed coats and then in embryos, and ABA maxima were higher in seed coats (8 to 20 micrograms per gram fresh weight) than in embryos (4 to 9 micrograms per gram fresh weight. From 30 to 50 DAA, ABA levels in both tissues decreased to less than 2 micrograms per gram fresh weight. Levels of sucrose were also low early in development, less than 10 milligrams per gram fresh weight at 14 DAA. However, by 30 DAA, sucrose levels in seed coats had increased to 20 milligrams per gram fresh weight and remained fairly constant for the remainder of the filling period. In contrast, sucrose accumulated in embryos throughout the filling period, reaching levels greater than 40 milligrams per gram fresh weight by 50 DAA. Correlation analyses indicated that the level of ABA in seed coats and embryos was not directly correlated to the level of sucrose measured in those tissues or to the rate of seed dry matter accumulation during the linear filling period. Rather, the ubiquitous pattern of ABA accumulation early in development appeared to coincide with water uptake and the rapid expansion of cotyledons occurring at that time. Whole tissue sucrose levels in embryos and seed coats, as well as sucrose levels in the embryo apoplast, were generally not correlated with the rate of dry matter accumulation. Thus, it appears that, in this set of diverse soybean genotypes, seed growth rate was not limited by endogenous concentrations of ABA or sucrose in reproductive tissues.     

Glucosinolate changes in developing pods of single and double low varieties of autumn-sown oilseed rape (B. napus)

Single and double low varieties of oilseed rape were grown in the 1987/88 and 1988/89 seasons to study changes in the concentrations of total and individual glucosinolates within pods during development. Total glucosinolate concentration in seeds of all varieties increased during development when expressed on a fresh weight basis. The levels of the major alkenyl glucosinolates present in the seed; 2–hydroxy-3–butenyl, 3–butenyl and 4–pentenyl had been reduced in the transition from single to double low varieties. The major indole glucosinolates in the seed, 4–hydroxy-3–indolylmethyl and 3–indolylmethyl were present in the same amounts in single and double low varieties but in the latter represented a greater proportion of the total seed glucosinolate content. A decline in the total glucosinolate concentration in the pod walls with time together with the analogous profile of individual glucosinolates in the seeds and pod walls suggests that the pod wall is a major site of seed glucosinolate synthesis. Other plant parts may also have an important role to play in provision of intact glucosinolates or precursors to the pod walls for glucosinolate biosynthesis.     

Novel bioresources for studies of Brassica oleracea: identification of a kale MYB transcription factor responsible for glucosinolate production

Plants belonging to the Brassicaceae family exhibit species‐specific profiles of glucosinolates (GSLs), a class of defence compounds against pathogens and insects. GSLs also exhibit various human health–promoting properties. Among them, glucoraphanin (aliphatic 4‐methylsulphinylbutyl GSL) has attracted the most attention because it hydrolyses to form a potent anticancer compound. Increased interest in developing commercial varieties of Brassicaceae crops with desirable GSL profiles has led to attempts to identify genes that are potentially valuable for controlling GSL biosynthesis. However, little attention has been focused on genes of kale (Brassica oleracea var. acephala). In this study, we established full‐length kale cDNA libraries containing 59 904 clones, which were used to generate an expressed sequence tag (EST) data set with 119 204 entries. The EST data set clarified genes related to the GSL biosynthesis pathway in kale. We specifically focused on BoMYB29, a homolog of Arabidopsis MYB29/PMG2/HAG3, not only to characterize its function but also to demonstrate its usability as a biological resource. BoMYB29 overexpression in wild‐type Arabidopsis enhanced the expression of aliphatic GSL biosynthetic genes and the accumulation of aliphatic GSLs. When expressed in the myb28myb29 mutant, which exhibited no detectable aliphatic GSLs, BoMYB29 restored the expression of biosynthetic genes and aliphatic GSL accumulation. Interestingly, the ratio of methylsulphinyl GSL content, including glucoraphanin, to that of methylthio GSLs was greatly increased, indicating the suitability of BoMYB29 as a regulator for increasing methylsulphinyl GSL content. Our results indicate that these biological resources can facilitate further identification of genes useful for modifications of GSL profiles and accumulation in kale.     

Relationships between nitrogen,dry matter accumulation and glucosinolates in <Emphasis Type="Italic">Eruca sativa</Emphasis> Mills. The applicability of the critical NO<Subscript>3</Subscript>-N levels approach

Background and Aims

Rocket salad (Eruca sativa Mills) is one of the major leafy vegetables produced worldwide and has been characterized as a rich source of chemoprotective glucosinolates (GSL). The relationship between N fertilization and the resulting plant biomass and N status with GSL quantity and quality in rocket leaves was examined.

Methods

A pot experiment was conducted, applying ten different N-rates and destructive sampling was carried out 15, 30 and 45 days after transplanting (DAT). The Mitscherlich equation was used to establish NO₃-N critical levels at each growth stage and as an indicator of N demand for relative maximum dry matter accumulation and glucosinolate content and composition was determined.

Results

Glucosinolate content was significantly influenced by N rate, growth stage and their interaction. Different GSL types showed dissimilar responses to N fertilization: aliphatic GSLs were significantly reduced under increased N rates whereas indole GSL showed the reverse. Under excess N fertilization (>1.04 g/plant), dry matter accumulation remained constant, NO₃-N was significantly increased and total GSL content was significantly reduced, factors that could lead to an anticipated product quality decline.

Conclusions

The application of the critical NO₃-N level approach used to identify optimal N fertilization rates for plant growth could serve as means to obtain optimized GSL content in the edible plant parts.

     

Effect of abscisic acid and jasmonic acid on partial desiccation of encapsulated somatic embryos of sugarcane

Embryogenic calli of sugarcane (Saccharum sp. hybrid, clone CP52-43), with somatic embryos in the late scutelar stage, were subjected to different treatments for increasing embryo tolerance to desiccation. The medium was supplemented with abscisic acid (ABA) (3.8 μM), jasmonic acid (JA) (4.7 μM) or a combination of them. A control treatment without growth regulators was also included. The embryos were encapsulated in alginate beads and dehydrated or not in sucrose (0.5 M). Thereafter, they were further dehydrated in chambers containing silicagel until the beads reached either 60% or 30% of water content (WC). Survival of encapsulated-dehydrated embryos was achieved only in the control and ABA treatment. ABA induced an increase in protein, polyamines, free proline levels and starch levels as a response to desiccation tolerance. JA treatment showed the lowest protein and polyamines levels and increased the starch content almost two-fold compared to the ABA treatment. The JA treatment induced high levels of 4-methylcatechol and the lowest levels of gallic acid. However, the ABA treatment increased gallic acid and p-coumaric acid content in the induction medium. Some differences were found in growth regulator free-medium in relation to the induction medium. JA is not effective in these desiccation processes. The mechanisms by which these two plant growth regulators act on the induction of tolerance to stress are presumably different. This revised version was published online in June 2006 with corrections to the Cover Date.     

Treatments affecting maturation and germination of American chestnut somatic embryos

The effects of amino acids, abscisic acid (ABA), polyethylene glycol (PEG), and elevated sucrose were tested on the maturation and germination of American chestnut (Castanea dentata) somatic embryos. Somatic embryos from three lines were matured over an eight week period through a two-stage process. After maturation, somatic embryos were randomly divided into three groups to measure dry weight/ fresh weight ratios, starch levels, and germination rates. Prior to transfer to germination medium, somatic embryos received a four week cold treatment. While some treatments with amino acids, elevated sucrose, PEG or ABA increased either dry weight/fresh weight ratios, starch content or both, only addition of 25mM L-asparagine significantly increased germination rate and taproot length, and this response was only obtained with one of the three lines tested. Six plants survived the transfer to potting mix, acclimatization to greenhouse conditions and field planting.     

Dissection of genetic architecture for glucosinolate accumulations in leaves and seeds of Brassica napus by genome‐wide association study

Glucosinolates (GSLs), whose degradation products have been shown to be increasingly important for human health and plant defence, compose important secondary metabolites found in the order Brassicales. It is highly desired to enhance pest and disease resistance by increasing the leaf GSL content while keeping the content low in seeds of Brassica napus, one of the most important oil crops worldwide. Little is known about the regulation of GSL accumulation in the leaves. We quantified the levels of 9 different GSLs and 15 related traits in the leaves of 366 accessions and found that the seed and leaf GSL content were highly correlated (r = 0.79). A total of 78 loci were associated with GSL traits, and five common and eleven tissue‐specific associated loci were related to total leaf and seed GSL content. Thirty‐six candidate genes were inferred to be involved in GSL biosynthesis. The candidate gene BnaA03g40190D (BnaA3.MYB28) was validated by DNA polymorphisms and gene expression analysis. This gene was responsible for high leaf/low seed GSL content and could explain 30.62% of the total leaf GSL variation in the low seed GSL panel and was not fixed during double‐low rapeseed breeding. Our results provide new insights into the genetic basis of GSL variation in leaves and seeds and may facilitate the metabolic engineering of GSLs and the breeding of high leaf/low seed GSL content in B. napus.     

Do stress-related phytohormones,abscisic acid and jasmonic acid play a role in the regulation of <Emphasis Type="Italic">Medicago sativa</Emphasis> L. somatic embryogenesis?

This study examined the role of endogenous abscisic acid (ABA) and jasmonic acid (JA) in indirect somatic embryogenesis of Medicago sativa L. A multiplex GC-MS/MS technique allowed quantitative single-run analyses of ABA, JA, 12-oxophytodienoic acid (OPDA) and indole-3-acetic acid (IAA). The preparation of initial explants led to a strong accumulation of ABA, JA and OPDA but not of IAA. Substantially higher levels of ABA, JA and OPDA were detected in developing somatic embryos than in callus or embryogenic suspension. Fluridone (FLD) decreased ABA, JA and OPDA levels. Indoprofen (INP) appeared to be a specific inhibitor of octadecanoid biosynthesis. Somatic embryo production and development were negatively affected by FLD or INP. Only INP (0.5 μM) applied during proliferation phase increased the number of cotyledonary embryos. The results strongly indicate the involvement of ABA and JA in somatic embryogenesis of M. sativa. Surprisingly, low IAA contents in comparison to stress-related compounds (ABA, JA and OPDA) were detected in explants, embryogenic tissues and somatic embryos.     

Expression of a Brassica Isopropylmalate Synthase Gene in Arabidopsis Perturbs Both Glucosinolate and Amino Acid Metabolism

Isopropylmalate synthase (IPMS) is a key enzyme in the biosynthesis of the essential amino acid leucine, and thus primary metabolism. In Arabidopsis, the functionally similar enzyme, methythiolalkylmalate synthase (MAM), is an important enzyme in the elongation of methionine prior to glucosinolate (GSL) biosynthesis, as part of secondary metabolism. We describe the cloning of an IPMS gene from Brassica, BatIMS, and its functional characterisation by heterologous expression in E. coli and Arabidopsis. Over expression of BatIMS in Arabidopsis resulted in plants with an aberrant phenotype, reminiscent of mutants in GSL biosynthesis. Metabolite analyses showed that these plants had both perturbed amino acid metabolism and enhanced levels of GSLs. Microarray profiling showed that BatIMS over expression caused up regulation of the genes for methionine-derived GSL biosynthesis, and down regulation of genes involved in leucine catabolism, in addition to perturbed expression of genes involved in auxin and ethylene metabolism. The results illustrate the cross talk that can occur between primary and secondary metabolism within transgenic plants. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Hormones in zygotic and microspore embryos of Brassica napus

A number of studies have used microspore-derived embryos (MDEs) as amodel for examining a range of processes, including hormonal regulation ofembryo development. We examined the hormonal physiology of MDEs with theprimaryobjective of testing the validity of using the MDE system as a model forhormonally-regulated development in zygotic embryos, through late stages. To dothis we identified and quantified endogenous levels of abscisic acid (ABA),indole-3-acetic acid (IAA) and a number of gibberellins (GAs), includingGA₁₉, GA₂₀, GA₁ and GA₈ in bothMDEsand zygotic embryos. The presence of GA₁₉, together with itsC₁₉ metabolites indicates that the early-13 hydroxylation pathway isoperative in both embryo systems. Gibberellins A₄ and GA₉were also identified, thereby confirming the presence of the earlynon-hydroxylation pathway in B. napus MDEs and zygoticembryos. In general, the pattern of change of hormone (ABA, IAA, GA₁and GA₂₀) content per embryo through embryogenesis was similar forMDEs and zygotic embryos. Indole-3-acetic acid and GA₁ increased toamaximum at day 30 after culture (DAC) before decreasing. Abscisicacid levels increased to a maximum at day 35, and declined in zygoticembryos but not in MDEs. GA₂₀ increased to the final harvest atmaturity, or day 40. The absolute content (g/embryo) of each hormone, howeverwas appreciably lower (5- to 15- fold) in the MDEs. This was not the result ofdilution into surrounding medium for ABA or IAA; GA₁, however, didaccumulate in the medium. Although there were absolute quantitative differencesin the levels of IAA and ABA found in the two embryo systems, the similaritiesin the pattern of hormone changes suggests that the MDE system can serve as auseful model for examining the physiological roles of hormones duringembryogenesis.     

Identification of a flavin-monooxygenase as the S-oxygenating enzyme in aliphatic glucosinolate biosynthesis in Arabidopsis

The cancer-preventive activity of cruciferous vegetables is commonly attributed to isothiocyanates resulting from the breakdown of the natural products glucosinolates (GSLs). Sulforaphane, the isothiocyanate derived from 4-methylsulfinylbutyl GSL, is thought to be the major agent conferring cancer-preventive properties, whereas the isothiocyanate of 4-methylthiobutyl GSL does not have the same activity. We report the identification of an Arabidopsis flavin-monooxygenase (FMO) enzyme, FMO(GS-OX1), which catalyzes the conversion of methylthioalkyl GSLs into methylsulfinylalkyl GSLs. This is evidenced by biochemical characterization of the recombinant protein, and analyses of the GSL content in FMO(GS-OX1) overexpression lines and an FMO(GS-OX1) knock-out mutant of Arabidopsis. The FMO(GS-OX1) overexpression lines show almost complete conversion of methylthioalkyl into methylsulfinylalkyl GSLs, with an approximately fivefold increase in 4-methylsulfinylbutyl GSL in seeds. Identification of FMO(GS-OX1) provides a molecular tool for breeding of Brassica vegetable crops with increased levels of this important GSL, which has implications for production of functional foods enriched with the cancer-preventive sulforaphane.     

Subclade of flavin-monooxygenases involved in aliphatic glucosinolate biosynthesis

Glucosinolates (GSLs) are amino acid-derived secondary metabolites with diverse biological activities dependent on chemical modifications of the side chain. We previously identified the flavin-monooxygenase FMO(GS-OX1) as an enzyme in the biosynthesis of aliphatic GSLs in Arabidopsis (Arabidopsis thaliana) that catalyzes the S-oxygenation of methylthioalkyl to methylsulfinylalkyl GSLs. Here, we report the fine mapping of a quantitative trait locus for the S-oxygenating activity in Arabidopsis. In this region, there are three FMOs that, together with FMO(GS-OX1) and a fifth FMO, form what appears to be a crucifer-specific subclade. We report the identification of these four uncharacterized FMOs, designated FMO(GS-OX2) to FMO(GS-OX5). Biochemical characterization of the recombinant protein combined with the analysis of GSL content in knockout mutants and overexpression lines show that FMO(GS-OX2), FMO(GS-OX3), and FMO(GS-OX4) have broad substrate specificity and catalyze the conversion from methylthioalkyl GSL to the corresponding methylsulfinylalkyl GSL independent of chain length. In contrast, FMO(GS-OX5) shows substrate specificity toward the long-chain 8-methylthiooctyl GSL. Identification of the FMO(GS-OX) subclade will generate better understanding of the evolution of biosynthetic activities and specificities in secondary metabolism and provides an important tool for breeding plants with improved cancer prevention characteristics as provided by the methylsulfinylalkyl GSL.     

脂肪族芥子油苷侧链修饰酶基因FMOGS-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FMO_GS-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FMO_GS-OX基因缺失突变体中,除了fmo_gs-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FMO_GS-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FMO_GS-OX4在不同组织中的表达情况。结果表明FMO_GS-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,FMO_GS-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fmo_gs-ox4没有明显表型的主要原因。     

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。