Myzus persicae (green peach aphid) feeding on Arabidopsis induces the formation of a deterrent indole glucosinolate

Cruciferous plants produce a wide variety of glucosinolates as a protection against herbivores and pathogens. However, very little is known about the importance of individual glucosinolates in plant defense and the regulation of their production in response to herbivory. When Myzus persicae (green peach aphid) feeds on Arabidopsis aliphatic glucosinolates pass through the aphid gut intact, but indole glucosinolates are mostly degraded. Although aphid feeding causes an overall decrease in Arabidopsis glucosinolate content, the production of 4-methoxyindol-3-ylmethylglucosinolate is induced. This altered glucosinolate profile is not a systemic plant response, but is limited to the area in which aphids are feeding. Aphid feeding on detached leaves causes a similar change in the glucosinolate profile, demonstrating that glucosinolate transport is not required for the observed changes. Salicylate-mediated signaling has been implicated in other plant responses to aphid feeding. However, analysis of eds5, pad4, npr1 and NahG transgenic Arabidopsis, which are compromised in this pathway, demonstrated that aphid-induced changes in the indole glucosinolate profile were unaffected. The addition of purified indol-3-ylmethylglucosinolate to the petioles of cyp79B2 cyp79B3 mutant leaves, which do not produce indole glucosinolates, showed that this glucosinolate serves as a precursor for the aphid-induced synthesis of 4-methoxyindol-3-ylmethylglucosinolate. In artificial diets, 4-methoxyindol-3-ylmethylglucosinolate is a significantly greater aphid deterrent in the absence of myrosinase than its metabolic precursor indol-3-ylmethylglucosinolate. Together, these results demonstrate that, in response to aphid feeding, Arabidopsis plants convert one indole glucosinolate to another that provides a greater defensive benefit.     

Integration of Biosynthesis and Long-Distance Transport Establish Organ-Specific Glucosinolate Profiles in Vegetative Arabidopsis

Although it is essential for plant survival to synthesize and transport defense compounds, little is known about the coordination of these processes. Here, we investigate the above- and belowground source-sink relationship of the defense compounds glucosinolates in vegetative Arabidopsis thaliana. In vivo feeding experiments demonstrate that the glucosinolate transporters1 and 2 (GTR1 and GTR2), which are essential for accumulation of glucosinolates in seeds, are likely to also be involved in bidirectional distribution of glucosinolates between the roots and rosettes, indicating phloem and xylem as their transport pathways. Grafting of wild-type, biosynthetic, and transport mutants show that both the rosette and roots are able to synthesize aliphatic and indole glucosinolates. While rosettes constitute the major source and storage site for short-chained aliphatic glucosinolates, long-chained aliphatic glucosinolates are synthesized both in roots and rosettes with roots as the major storage site. Our grafting experiments thus indicate that in vegetative Arabidopsis, GTR1 and GTR2 are involved in bidirectional long-distance transport of aliphatic but not indole glucosinolates. Our data further suggest that the distinct rosette and root glucosinolate profiles in Arabidopsis are shaped by long-distance transport and spatially separated biosynthesis, suggesting that integration of these processes is critical for plant fitness in complex natural environments.     

Genetic control of natural variation in Arabidopsis glucosinolate accumulation

Glucosinolates are biologically active secondary metabolites of the Brassicaceae and related plant families that influence plant/insect interactions. Specific glucosinolates can act as feeding deterrents or stimulants, depending upon the insect species. Hence, natural selection might favor the presence of diverse glucosinolate profiles within a given species. We determined quantitative and qualitative variation in glucosinolates in the leaves and seeds of 39 Arabidopsis ecotypes. We identified 34 different glucosinolates, of which the majority are chain-elongated compounds derived from methionine. Polymorphism at only five loci was sufficient to generate 14 qualitatitvely different leaf glucosinolate profiles. Thus, there appears to be a modular genetic system regulating glucosinolate profiles in Arabidopsis. This system allows the rapid generation of new glucosinolate combinations in response to changing herbivory or other selective pressures. In addition to the qualitative variation in glucosinolate profiles, we found a nearly 20-fold difference in the quantity of total aliphatic glucosinolates and were able to identify a single locus that controls nearly three-quarters of this variation.     

Elucidating the Role of Transport Processes in Leaf Glucosinolate Distribution

In Arabidopsis (Arabidopsis thaliana), a strategy to defend its leaves against herbivores is to accumulate glucosinolates along the midrib and at the margin. Although it is generally assumed that glucosinolates are synthesized along the vasculature in an Arabidopsis leaf, thereby suggesting that the margin accumulation is established through transport, little is known about these transport processes. Here, we show through leaf apoplastic fluid analysis and glucosinolate feeding experiments that two glucosinolate transporters, GTR1 and GTR2, essential for long-distance transport of glucosinolates in Arabidopsis, also play key roles in glucosinolate allocation within a mature leaf by effectively importing apoplastically localized glucosinolates into appropriate cells. Detection of glucosinolates in root xylem sap unambiguously shows that this transport route is involved in root-to-shoot glucosinolate allocation. Detailed leaf dissections show that in the absence of GTR1 and GTR2 transport activity, glucosinolates accumulate predominantly in leaf margins and leaf tips. Furthermore, we show that glucosinolates accumulate in the leaf abaxial epidermis in a GTR-independent manner. Based on our results, we propose a model for how glucosinolates accumulate in the leaf margin and epidermis, which includes symplasmic movement through plasmodesmata, coupled with the activity of putative vacuolar glucosinolate importers in these peripheral cell layers.Feeding behavior of herbivorous insects and distribution of defense compounds in plants have been suggested to be a result of an arms race between plants and insects that has spanned millions of years (Ehrlich and Raven, 1964). Whether insects adapted first to plants or the other way around is an ongoing debate in this research field (Schoonhoven et al., 2005; Ali and Agrawal, 2012). Leaf margin accumulation of defense compounds has been demonstrated in various plant species (Gutterman and Chauser-Volfson, 2000; Chauser-Volfson et al., 2002; Kester et al., 2002; Cooney et al., 2012). In the model plant Arabidopsis (Arabidopsis thaliana), higher concentration of glucosinolates, which constitute a major part of the chemical defense system in this plant (Kliebenstein et al., 2001a; Halkier and Gershenzon, 2006), was found at the leaf midrib and margins compared with the leaf lamina (Shroff et al., 2008; Sønderby et al., 2010). This nonuniform leaf distribution of glucosinolates appeared to explain the feeding pattern of a generalist herbivore (Helicoverpa armigera), as it avoided feeding at the leaf margin and midrib (Shroff et al., 2008). A similar feeding pattern on Arabidopsis was observed for a different generalist herbivore, Spodoptera littoralis (Schweizer et al., 2013). Interestingly, S. littoralis was shown to favor feeding from Arabidopsis leaf margins in glucosinolate-deficient mutants (Schweizer et al., 2013), which could indicate an inherent preference for margin feeding and that Arabidopsis adapted to such behavior by accumulating defense compounds here. A damaged leaf margin may be more critical for leaf stability than damage to inner leaf parts (Shroff et al., 2008), further motivating protection of this tissue. The margin-feeding preference of S. littoralis might be explained by better nutritional value of the leaf margin cells (Schweizer et al., 2013), which has been shown to consist of specialized elongated cell files (Koroleva et al., 2010; Nakata and Okada, 2013).Other distribution patterns have been reported for glucosinolates in an Arabidopsis leaf. A study investigating spatiotemporal metabolic shifts during senescence in Arabidopsis reported that fully expanded mature leaves exhibited a glucosinolate gradient from base to tip, with highest level of glucosinolates at the leaf base (Watanabe et al., 2013). In contrast to the horizontal plane, less has been reported on distribution of glucosinolates in the vertical plane of a leaf. A localization study of cyanogenic glucosides, defense molecules related to glucosinolates (Halkier and Gershenzon, 2006), determined that these compounds primarily were located in the epidermis of sorghum (Sorghum bicolor; Kojima et al., 1979). Whereas epidermis-derived trichomes in Arabidopsis were recently demonstrated to contain glucosinolates and to express glucosinolate biosynthetic genes (Frerigmann et al., 2012), no studies have investigated glucosinolates in the epidermal cell layer.Based on promoter-GUS studies, biosynthesis of glucosinolates in leaves of Arabidopsis has been associated with primarily major and minor veins in leaves and silique walls (Mikkelsen et al., 2000; Reintanz et al., 2001; Tantikanjana et al., 2001; Chen et al., 2003; Grubb et al., 2004; Schuster et al., 2006; Gigolashvili et al., 2007; Li et al., 2011; Redovniković et al., 2012). The discrepancy between vasculature-associated glucosinolate biosynthesis and margin accumulation of glucosinolates suggests that transport processes must be involved in establishing the distribution pattern of glucosinolates within a leaf.Plant transport systems include the apoplastic xylem, the symplastic phloem, and plasmodesmata. Xylem transport is mainly driven by an upward pull generated by transpiration from aerial plant organs, thereby directing transport to sites of rapid evaporation (such as leaf margins; Sattelmacher, 2001). Phloem flow is facilitated by an osmosis-regulated hydrostatic pressure difference between source and sink tissue, primarily generated by Suc bulk flow (Lucas et al., 2013). Plasmodesmata are intercellular channels that establish symplasmic pathways between neighboring cells, and most cell types in a plant are symplastically connected via plasmodesmata (Roberts and Oparka, 2003). Translocation of small molecules in these channels is driven by diffusion and is regulated developmentally as well as spatially to form symplastically connected domains (Roberts and Oparka, 2003; Christensen et al., 2009). To what extent any of these transport processes are involved in establishing specific distribution patterns of glucosinolates within leaves is not known.Recently, two plasma membrane-localized, glucosinolate-specific importers, GLUCOSINOLATE TRANSPORTER1 (GTR1) and GTR2, were identified in Arabidopsis (Nour-Eldin et al., 2012). In leaf, their expression patterns were shown to be in leaf veins (GTR1 and GTR2) and surrounding mesophyll cells (GTR1; Nour-Eldin et al., 2012). Absence of aliphatic and indole glucosinolates in seeds of the gtr1gtr2 double knockout (dKO) mutant (gtr1gtr2 dKO) demonstrated that these transporters are essential for long-distance glucosinolate transport to the seeds and indicates a role in phloem loading (Nour-Eldin et al., 2012). Another study investigating long-distance transport of glucosinolates in the 3-week-old wild type and gtr1gtr2 dKO indicated that GTR1 and GTR2 were involved in bidirectional transport of aliphatic glucosinolates between root and shoot via both phloem and xylem pathways (Andersen et al., 2013). The authors suggested a role for GTR1 and GTR2 in the retention of long-chained aliphatic glucosinolates in roots by removing the compounds from the xylem (Andersen et al., 2013).Identification of the glucosinolate transporters GTR1 and GTR2 has provided a molecular tool to investigate the role of transport processes in establishing leaf glucosinolate distribution. In this study, we have performed a detailed spatial investigation of the distribution of an exogenously fed glucosinolate (sinigrin) and endogenous glucosinolates within mature wild-type and gtr1gtr2 dKO Arabidopsis leaves, achieved by collecting and analyzing leaf parts at the horizontal (y axis: petiole, base, and tip; x axis: midrib, lamina, and margin) as well as at the vertical leaf plane (z axis: abaxial epidermis). Furthermore, we analyze wild-type and gtr1gtr2 dKO root xylem sap and leaf apoplastic fluids for glucosinolates. Based on our results, we propose a model where GTR1 and GTR2 import glucosinolates from the apoplast to the symplast and where the glucosinolate distribution pattern within an Arabidopsis leaf is established via symplasmic movement of glucosinolates through plasmodesmata, coupled with the activity of putative vacuolar glucosinolate importers in peripheral cell layers.     

Characterization of methylsulfinylalkyl glucosinolate specific polyclonal antibodies

Antibodies towards small molecules, like plant specialized metabolites, are valuable tools for developing quantitative and qualitative analytical techniques. Glucosinolates are the specialized metabolites characteristic of the Brassicales order. Here we describe the characterization of polyclonal rabbit antibodies raised against the 4-methylsulfinylbutyl glucosinolate, glucoraphanin that is one of the major glucosinolates in the model plant Arabidopsis thaliana (hereafter Arabidopsis). Analysis of the cross-reactivity of the antibodies against a number of glucosinolates demonstrated that it was highly selective for methionine-derived aliphatic glucosinolates with a methyl-sulfinyl group in the side chain. Use of crude plant extracts from Arabidopsis mutants with different glucosinolate profiles showed that the antibodies recognized aliphatic glucosinolates in a plant extract and did not cross-react with other metabolites. These methylsulfinylalkyl glucosinolate specific antibodies have prospective use in multiple applications such as ELISA, co-immunoprecipitation and immunolocalization of glucosinolates.     

Interaction of glucosinolate content of Arabidopsis thaliana mutant lines and feeding and oviposition by generalist and specialist lepidopterans

The diamondback moth, Plutella xylostella L. (Lepidoptera: Plutellidae), is an insect specialized on glucosinolate-containing Brassicaceae that uses glucosinolates in host-plant recognition. We used wild-type and mutants of Arabidopsis thaliana (L.) Heynh. (Brassicaceae) to investigate the interaction between plant glucosinolate and myrosinase content and herbivory by larvae of the generalist Helicoverpa armigera Hübner (Lepidoptera: Noctuidae) and the specialist P. xylostella. We also measured glucosinolate changes as a result of herbivory by these larvae to investigate whether herbivory and glucosinolate induction had an effect on oviposition preference by P. xylostella. Feeding by H. armigera and P. xylostella larvae was 2.1 and 2.5 times less, respectively, on apk1 apk2 plants (with almost no aliphatic glucosinolates) than on wild-type plants. However, there were no differences in feeding by H. armigera and P. xylostella larvae on wild-type, gsm1 (different concentrations of aliphatic glucosinolates compared to wild-type plants), and tgg1 tgg2 plants (lacking major myrosinases). Glucosinolate induction (up to twofold) as a result of herbivory occurred in some cases, depending on both the plant line and the herbivore. For H. armigera, induction, when observed, was noted mostly for indolic glucosinolates, while for P. xylostella, induction was observed in both aliphatic and indolic glucosinolates, but not in all plant lines. For H. armigera, glucosinolate induction, when observed, resulted in an increase of glucosinolate content, while for P. xylostella, induction resulted in both a decrease and an increase in glucosinolate content. Two-choice tests with wild-type and mutant plants were conducted with larvae and ovipositing moths. There were no significant differences in preference of larvae and ovipositing moths between wild-type and gsm1 mutants and between wild-type and tgg1 tgg2 mutants. However, both larvae and ovipositing moths preferred wild-type over apk1 apk2 mutants. Two-choice oviposition tests were also conducted with P. xylostella moths comparing undamaged plants to plants being attacked by larvae of either P. xylostella or H. armigera. Oviposition preference by P. xylostella was unaffected as a result of larval plant damage, even in the cases where herbivory resulted in glucosinolate induction.     

Piecing together the transport pathway of aliphatic glucosinolates

Glucosinolates are sulfur-rich secondary metabolites characteristic of the Brassicales order. Transport of glucosinolates was suggested more than 30 years ago through a number of studies which indicated that glucosinolates are produced in maternal tissue and subsequently transported to the seed. These observations laid the foundation for numerous studies on glucosinolate transport which have provided a wealth of information on biochemical properties of glucosinolate transport, source–sink relationships between organs and on the transport routes of glucosinolates. However, most of the conclusions and hypotheses proposed in these studies have not been discussed in context of each other to provide a complete overview of the current state of knowledge on glucosinolate transport. In this review, we are thus piecing together the glucosinolate pathway by presenting and critically analyzing all data on glucosinolate research. Furthermore, the data on glucosinolate transport is considered in the light of the newest findings on glucosinolate synthesis and distribution. The aim is to provide a comprehensive and updated set of hypotheses which may prove useful in directing future research on glucosinolate transport.     

Genotype–environment interactions affect flower and fruit herbivory and plant chemistry of Arabidopsis thaliana in a transplant experiment

Large differences exist in flower and fruit herbivory between dune and inland populations of plants of Arabidopsis thaliana (Brassicaceae). Two specialist weevils Ceutorhynchus atomus and C. contractus (Curculionidae) and their larvae are responsible for this pattern in herbivory. We test, by means of a reciprocal transplant experiment, whether these differences reflect environmental influences or genetic variation in plant defense level. All plants suffered more damage after being transplanted to the dune site than after being transplanted to the inland site. Plants of inland origin suffered more flower and fruit herbivory than plants of dune origin when grown at the dune transplant site, but differences were much smaller at the inland site. Both flower damage by adult weevils and fruit damage by their larvae were subject to significant genotype × environment interactions. The observed pattern in herbivory is a strong indication for local adaption of plant defense to the level of herbivory by Ceutorhynchus. In order to identify the mechanism of defense, a quantitative analysis of glucosinolates was performed on the seeds with HPLC. Highly significant differences were found in glucosinolate types and total concentration. These patterns were mainly determined by the origin of the plants (dune or inland) and by a genotype × environment interaction. Herbivory was not significantly correlated to the concentration of glucosinolates in seeds. We therefore analyzed the total metabolic composition of seeds, using NMR spectroscopy and multivariate data analysis. Major differences in chemical composition were found in the water–methanol fractions: more glucosinolate and sucrose in the dune and more fatty acids, lipids and sinapoylmalate in the inland populations. We discuss which of these chemical factors could explain the marked differences in damage between populations.     

Temporal consistency in herbivore responses to glucosinolate polymorphism in populations of wild cabbage (Brassica oleracea)

Natural populations of wild cabbage (Brassica oleracea) show significant qualitative diversity in heritable aliphatic glucosinolates, a class of secondary metabolites involved in defence against herbivore attack. One candidate mechanism for the maintenance of this diversity is that differential responses among herbivore species result in a net fitness balance across plant chemotypes. Such top-down differential selection would be promoted by consistent responses of herbivores to glucosinolates, temporal variation in herbivore abundance, and fitness impacts of herbivore attack on plants varying in glucosinolate profile. A 1-year survey across 12 wild cabbage populations demonstrated differential responses of herbivores to glucosinolates. We extended this survey to investigate the temporal consistency of these responses, and the extent of variation in abundance of key herbivores. Within plant populations, the aphid Brevicoryne brassicae consistently preferred plants producing the glucosinolate progoitrin. Among populations, increasing frequencies of sinigrin production correlated positively with herbivory by whitefly Aleyrodes proletella and negatively with herbivory by snails. Two Pieris butterfly species showed no consistent response to glucosinolates among years. Rates of herbivory varied significantly among years within populations, but the frequency of herbivory at the population scale varied only for B. brassicae. B. brassicae emerges as a strong candidate herbivore to impose differential selection on glucosinolates, as it satisfies the key assumptions of consistent preferences and heterogeneity in abundance. We show that variation in plant secondary metabolites structures the local herbivore community and that, for some key species, this structuring is consistent over time. We discuss the implications of these patterns for the maintenance of diversity in plant defence chemistry.     

Concentration of glucosinolates in relation to habitat and insect herbivory for the native crucifer Cardamine cordifolia

Understanding plant-insect interactions requires further data on herbivory in relation to the variation in concentration of characteristic secondary compounds. We report here analyses of the glucosinolate contents for a native perennial, montane crucifer Cardamine cordifolia in relation to: (a) plant characteristics; (b) insect herbivory; and (c) habitat. The only pattern of variation of glucosinolate content with leaf characteristics found was an inverse correlaton between leaf weight and total isothiocyanate-yielding glucosinolates (IYG) in shaded plants. There was a highly significant, negative relationship between total IYG and leaf damage by insects, particularly in typical shaded habitats. Higher insect-caused damage on denser, smaller leaves of plants from the driest soils was observed. Additionally, plants occurring in sun-exposed habitats from the beginning of the growing season, both naturally and experimentally, had similar (or lower) concentrations of total IYG, and were significantly more damaged by insects, than those in the more usual shaded habitats. The experimental removal of shade cover in mid-season resulted in significantly elevated quantities of total IYG in the first year, with a relaxation of that stress-induced response in the second year. We suggest that the insect herbivore guild on Cardamine cordifolia responds to concentration and composition of glucosinolates and exerts its greatest pressure on plants with lower concentrations. Differential herbivory, consumption mediated in part by glucosinolate concentration, appears to contribute to microhabitat occurrence of C. cordifolia.     

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.     

Elevated CO<Subscript>2</Subscript> influences herbivory-induced defense responses of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

We experimentally demonstrate that elevated CO₂ can modify herbivory-induced plant chemical responses in terms of both total and individual glucosinolate concentrations. Overall, herbivory by larvae of diamondback moths (Plutella xylostella) resulted in no change in glucosinolate levels of the annual plant Arabidopsis thaliana under ambient CO₂ conditions. However, herbivory induced a significant 28–62% increase in glucosinolate contents at elevated CO₂. These inducible chemical responses were both genotype-specific and dependent on the individual glucosinolate considered. Elevated CO₂ can also affect structural defenses such as trichomes and insect-glucosinolate interactions. Insect performance was significantly influenced by specific glucosinolates, although only under CO₂ enrichment. This study can have implications for the evolution of inducible defenses and coevolutionary adaptations between plants and their associated herbivores in future changing environments.     

Metabolic and evolutionary costs of herbivory defense: systems biology of glucosinolate synthesis

Here, we describe our updated mathematical model of Arabidopsis thaliana Columbia metabolism, which adds the glucosinolates, an important group of secondary metabolites, to the reactions of primary metabolism. In so doing, we also describe the evolutionary origins of the enzymes involved in glucosinolate synthesis. We use this model to address a long-standing question in plant evolutionary biology: whether or not apparently defensive compounds such as glucosinolates are metabolically costly to produce. We use flux balance analysis to estimate the flux through every metabolic reaction in the model both when glucosinolates are synthesized and when they are absent. As a result, we can compare the metabolic costs of cell synthesis with and without these compounds, as well as inferring which reactions have their flux altered by glucosinolate synthesis. We find that glucosinolate production can increase photosynthetic requirements by at least 15% and that this cost is specific to the suite of glucosinolates found in A.?thaliana, with other combinations of glucosinolates being even more costly. These observations suggest that glucosinolates have evolved, and indeed likely continue to evolve, for herbivory defense, since only this interpretation explains the maintenance of such costly traits.     

Localization of the glucosinolate biosynthetic enzymes reveals distinct spatial patterns for the biosynthesis of indole and aliphatic glucosinolates

Glucosinolates constitute the primary defense metabolites in Arabidopsis thaliana (Arabidopsis). Indole and aliphatic glucosinolates, biosynthesized from tryptophan and methionine, respectively, are known to serve distinct biological functions. Although all genes in the biosynthetic pathways are identified, and it is known where glucosinolates are stored, it has remained elusive where glucosinolates are produced at the cellular and tissue level. To understand how the spatial organization of the different glucosinolate biosynthetic pathways contributes to their distinct biological functions, we investigated the localization of enzymes of the pathways under constitutive conditions and, for indole glucosinolates, also under induced conditions, by analyzing the spatial distribution of several fluorophore‐tagged enzymes at the whole plant and the cellular level. We show that key steps in the biosynthesis of the different types of glucosinolates are localized in distinct cells in separate as well as overlapping vascular tissues. The presence of glucosinolate biosynthetic enzymes in parenchyma cells of the vasculature may assign new defense‐related functions to these cell types. The knowledge gained in this study is an important prerequisite for understanding the orchestration of chemical defenses from site of synthesis to site of storage and potential (re)mobilization upon attack.     

Multiple indole glucosinolates and myrosinases defend Arabidopsis against Tetranychus urticae herbivory

Arabidopsis (Arabidopsis thaliana) defenses against herbivores are regulated by the jasmonate (JA) hormonal signaling pathway, which leads to the production of a plethora of defense compounds. Arabidopsis defense compounds include tryptophan-derived metabolites, which limit Arabidopsis infestation by the generalist herbivore two-spotted spider mite, Tetranychus urticae. However, the phytochemicals responsible for Arabidopsis protection against T. urticae are unknown. Here, we used Arabidopsis mutants disrupted in the synthesis of tryptophan-derived secondary metabolites to identify phytochemicals involved in the defense against T. urticae. We show that of the three tryptophan-dependent pathways found in Arabidopsis, the indole glucosinolate (IG) pathway is necessary and sufficient to assure tryptophan-mediated defense against T. urticae. We demonstrate that all three IGs can limit T. urticae herbivory, but that they must be processed by myrosinases to hinder T. urticae oviposition. Putative IG breakdown products were detected in mite-infested leaves, suggesting in planta processing by myrosinases. Finally, we demonstrate that besides IGs, there are additional JA-regulated defenses that control T. urticae herbivory. Together, our results reveal the complexity of Arabidopsis defenses against T. urticae that rely on multiple IGs, specific myrosinases, and additional JA-dependent defenses.

Three IGs and specific myrosinases help protect Arabidopsis thaliana against herbivory by the two-spotted spider mite T. urticae.     

The Effects of Glucosinolates and Their Breakdown Products on Necrotrophic Fungi

Glucosinolates are a diverse class of S- and N-containing secondary metabolites that play a variety of roles in plant defense. In this study, we used Arabidopsis thaliana mutants that contain different amounts of glucosinolates and glucosinolate-breakdown products to study the effects of these phytochemicals on phytopathogenic fungi. We compared the fungus Botrytis cinerea, which infects a variety of hosts, with the Brassicaceae-specific fungus Alternaria brassicicola. B. cinerea isolates showed variable composition-dependent sensitivity to glucosinolates and their hydrolysis products, while A. brassicicola was more strongly affected by aliphatic glucosinolates and isothiocyanates as decomposition products. We also found that B. cinerea stimulates the accumulation of glucosinolates to a greater extent than A. brassicicola. In our work with A. brassicicola, we found that the type of glucosinolate-breakdown product is more important than the type of glucosinolate from which that product was derived, as demonstrated by the sensitivity of the Ler background and the sensitivity gained in Col-0 plants expressing epithiospecifier protein both of which accumulate simple nitrile and epithionitriles, but not isothiocyanates. Furthermore, in vivo, hydrolysis products of indole glucosinolates were found to be involved in defense against B. cinerea, but not in the host response to A. brassicicola. We suggest that the Brassicaceae-specialist A. brassicicola has adapted to the presence of indolic glucosinolates and can cope with their hydrolysis products. In contrast, some isolates of the generalist B. cinerea are more sensitive to these phytochemicals.