Signaling in the plant cytosol: cysteine or sulfide?

Cysteine (Cys) is the first organic compound containing reduced sulfur that is synthesized in the last stage of plant photosynthetic assimilation of sulfate. It is a very important metabolite not only because it is crucial for the structure, function and regulation of proteins but also because it is the precursor molecule of an enormous number of sulfur-containing metabolites essential for plant health and development. The biosynthesis of Cys is accomplished by the sequential reaction of serine acetyltransferase (SAT) and O-acetylserine(thiol)synthase (OASTL). In Arabidopsis thaliana, the analysis of specific mutants of members of the SAT and OASTL families has demonstrated that the cytosol is the compartment where the bulk of Cys synthesis takes place and that the cytosolic OASTL enzyme OAS-A1 is the responsible enzyme. Another member of the OASTL family is DES1, a novel l-cysteine desulfhydrase that catalyzes the desulfuration of Cys to produce sulfide, thus acting in a manner opposite to that of OAS-A1. Detailed studies of the oas-a1 and des1 null mutants have revealed the involvement of the DES1 and OAS-A1 proteins in coordinate regulation of Cys homeostasis and the generation of sulfide in the cytosol for signaling purposes. Thus, the levels of Cys in the cytosol strongly affect plant responses to both abiotic and biotic stress conditions, while sulfide specifically generated from the degradation of Cys negatively regulates autophagy induced in different situations. In conclusion, modulation of the levels of Cys and sulfide is likely critical for plant performance.     

Arabidopsis thaliana plants differentially modulate auxin biosynthesis and transport during defense responses to the necrotrophic pathogen Alternaria brassicicola

? Although the role of auxin in biotrophic pathogenesis has been extensively studied, relatively little is known about its role in plant resistance to necrotrophs. ? Arabidopsis thaliana mutants defective in different aspects of the auxin pathway are generally more susceptible than wild-type plants to the necrotrophic pathogen Alternaria brassicicola. We show that A.?brassicicola infection up-regulates auxin biosynthesis and down-regulates the auxin transport capacities of infected plants, these effects being partially dependent on JA signaling. We also show that these effects of A.?brassicicola infection together lead to an enhanced auxin response in host plants. ? Application of IAA and MeJA together synergistically induces the expression of defense marker genes PDF1.2 (PLANT DEFENSIN 1.2) and HEL (HEVEIN-LIKE), suggesting that enhancement of JA-dependent defense signaling may be part of the auxin-mediated defense mechanism involved in resistance to necrotrophic pathogens. ? Our results provide molecular evidence supporting the hypothesis that JA and auxin interact positively in regulating plant resistance to necrotrophic pathogens and that activation of auxin signaling by JA may contribute to plant resistance to necrotrophic pathogens.     

Ecological costs of biotrophic versus necrotrophic pathogen resistance, the hypersensitive response and signal transduction

Recent advances along numerous research avenues show that plant interactions with biotrophic and necrotrophic pathogens use similar pathways with opposing effects. The hypersensitive response is associated with increased biotroph resistance but decreased necrotroph resistance. In plant/herbivore interactions, opposing effects of defenses against specialist versus generalist herbivores are controlled by plant secondary metabolites, where a metabolite that provides resistance to generalist herbivores may stimulate specialist herbivores. This multi-trophic interaction is presented as an ecological cost of plant resistance, but similar concepts are rarely applied to plant interactions with different classes of pathogens. In this review, we begin to describe how necrotrophic pathogens may place an ecological cost upon plant resistance to biotrophic pathogens. We separate these potential ecological costs into three concepts: (1) the local cost of the hypersensitive response, (2) organismal cost of having machinery for a hypersensitive response and (3) antagonism between salicylate and jasmonate signaling. We describe the literature supporting these concepts and some predictions that they generate.     

Inhibition of Arabidopsis O-acetylserine(thiol)lyase A1 by tyrosine nitration

The last step of sulfur assimilation is catalyzed by O-acetylserine(thiol)lyase (OASTL) enzymes. OASTLs are encoded by a multigene family in the model plant Arabidopsis thaliana. Cytosolic OASA1 enzyme is the main source of OASTL activity and thus crucial for cysteine homeostasis. We found that nitrating conditions after exposure to peroxynitrite strongly inhibited OASTL activity. Among OASTLs, OASA1 was markedly sensitive to nitration as demonstrated by the comparative analysis of OASTL activity in nitrated crude protein extracts from wild type and different oastl mutants. Furthermore, nitration assays on purified recombinant OASA1 protein led to 90% reduction of the activity due to inhibition of the enzyme, as no degradation of the protein occurred under these conditions. The reduced activity was due to nitration of the protein because selective scavenging of peroxynitrite with epicatechin impaired OASA1 nitration and the concomitant inhibition of OASTL activity. Inhibition of OASA1 activity upon nitration correlated with the identification of a modified OASA1 protein containing 3-nitroTyr(302) residue. The essential role of the Tyr(302) residue for the catalytic activity was further demonstrated by the loss of OASTL activity of a Y302A-mutated version of OASA1. Inhibition caused by Tyr(302) nitration on OASA1 activity seems to be due to a drastically reduced O-acetylserine substrate binding to the nitrated protein, and also to reduced stabilization of the pyridoxal-5'-phosphate cofactor through hydrogen bonds. This is the first report identifying a Tyr nitration site of a plant protein with functional effect and the first post-translational modification identified in OASA1 enzyme.     

The 'Green Revolution' dwarfing genes play a role in disease resistance in Triticum aestivum and Hordeum vulgare

The Green Revolution dwarfing genes, Rht-B1b and Rht-D1b, encode mutant forms of DELLA proteins and are present in most modern wheat varieties. DELLA proteins have been implicated in the response to biotic stress in the model plant, Arabidopsis thaliana. Using defined wheat Rht near-isogenic lines and barley Sln1 gain of function (GoF) and loss of function (LoF) lines, the role of DELLA in response to biotic stress was investigated in pathosystems representing contrasting trophic styles (biotrophic, hemibiotrophic, and necrotrophic). GoF mutant alleles in wheat and barley confer a resistance trade-off with increased susceptibility to biotrophic pathogens and increased resistance to necrotrophic pathogens whilst the converse was conferred by a LoF mutant allele. The polyploid nature of the wheat genome buffered the effect of single Rht GoF mutations relative to barley (diploid), particularly in respect of increased susceptibility to biotrophic pathogens. A role for DELLA in controlling cell death responses is proposed. Similar to Arabidopsis, a resistance trade-off to pathogens with contrasting pathogenic lifestyles has been identified in monocotyledonous cereal species. Appreciation of the pleiotropic role of DELLA in biotic stress responses in cereals has implications for plant breeding.     

Low abundance does not mean less importance in cysteine metabolism

The cysteine molecule plays an essential role in cells because it is part of proteins and because it functions as a reduced sulfur donor molecule. In addition, the cysteine molecule may also play a role in the redox signaling of different stress processes. Even though the synthesis of cysteine by the most abundant of the isoforms of O-acetylserine(thiol) lyase in the chloroplast, the mitochondria and the cytosol is relatively well-understood, the role of the other less common isoforms homologous to O-acetylserine(thiol)lyase is unknown. Several studies on two of these isoforms, one located in the cytosol and the other one in the chloroplast, have shown that while one isoform operates with a desulfhydrase activity and is essential to regulate the homeostasis of cysteine in the cytosol, the other, located in the chloroplast, synthesizes S-sulfocysteine. This metabolite appears to be essential for the redox regulation of the chloroplast under certain lighting conditions.Key words: cysteine, S-sulfocysteine, desulfhydrase, sulfur metabolism, redox regulation, ArabidopsisCysteine occupies a central position in the plant primary and secondary metabolism due to its biochemical functions. Cysteine is the first organic compound with reduced sulfur synthesized by the plant in the photosynthetic primary sulfate assimilation. The importance of cysteine for plants derives from its role as an amino acid in proteins but also because of its functions as a precursor for a huge number of essential bio-molecules, such as many plant defense compounds formed in response to different environmental adverse conditions.^1,2 All of these bio-molecules contain sulfur moieties that act as functional groups and are derived from cysteine, and therefore, are intimately linked via their biosynthetic pathways.In addition to the final destination of the reduced sulfur atom in the primary and secondary metabolism of cells, the thiol residue of the cysteine molecule is a functional group that translates the physico-chemical signal (redox) of ROS and RNS into a functional signal, altering the properties of small molecules such as GSH or proteins whose enzymatic or functional properties depend on the redox state of its cysteine residues.³Sulfate is the major sulfur form available to plants. Sulfate is taken up to plant cells through specific sulfate transporters and is activated to adenosine 5′-phosphosulfate (APS). The reduction of the activated sulfate form, APS, is linked to plastids and the photosynthetic activity; therefore, APS is reduced to sulfite by the APS reductase using two GSH molecules as donors of the two electrons required in this step. Sulfite is further reduced to sulfide by the sulfite reductase that uses photosynthetically reduced ferredoxine (Fd) as an electron donor of the six required electrons. The biosynthesis of cysteine is further accomplished by the sequential reaction of two enzymes: First, the serine acetyltransferase (SAT) synthesizes the intermediary product, O-acetylserine (OAS), from acetyl-CoA and serine; and second, the O-acetylserine(thiol)lyase (OASTL) incorporates the sulfide to OAS producing the cysteine. Recently, much progress has been made toward understanding the action of the O-acetylserine(thiol)lyase (OASTL) enzyme, one of the enzymes responsible for the biosynthesis of cysteine, using as a model system the plant Arabidopsis thaliana. The focus of the research has been mainly placed on the most abundant enzymes based on their involvement in the primary sulfate assimilation pathway. Biochemical and molecular analysis of the major OASTL knockout mutants in Arabidopsis thaliana revealed that part of the produced sulfide is incorporated to O-acetylserine to form cysteine in the chloroplast with the assistance of the OAS-B isoform. However, most of the chloroplastic sulfide overflows and escapes into the cytosol and the mitochondria, where it is also assimilated into cysteine by the OAS-A1 and OAS-C isoforms, respectively.^4–6The three major OASTL isoforms seem to be redundant under normal growth conditions. However, our investigations on the major cytosolic isoform, the OAS-A1, revealed new insights on the function of this enzyme as a determinant of the antioxidative capacity of the cytosol.⁷ The OASTL homolog, CYS-C1, exhibits OASTL activity, but in fact, it is a β-cyanoalanine synthase enzyme that uses cysteine to detoxify cyanide within the mitochondria.⁸ Furthermore, Arabidopsis cells contain four additional O-acetylserine(thiol)lyase isoforms encoded by the CYS-D1 (At3g04940), CYS-D2 (At5g28020), CS26 (At3g03630) and CS-LIKE (At5g28030) genes with unknown function. Are these four isoforms authentic OASTL and are, therefore, redundant enzymes or do they have different activities and, therefore, different functions?Our recent research on the less-common isoforms, CS-like and CS26, shed light on this issue, and we are decoding two important aspects of the sulfur metabolism in plants.^9,10 The CS-LIKE protein was identified by sequence homology upon the completion of the sequencing of the Arabidopsis genome. Because of its cytosolic localization, it is thought to have an auxiliary function with respect to the major cytosolic isoform, the OAS-A1. The characterization of the purified recombinant protein has shown that the CS-LIKE isoform catalyzes the desulfuration of L-cysteine to sulfide plus ammonia and pyruvate; thus, CS-LIKE is a novel L-cysteine desulfhydrase (EC 4.4.1.1), and it is designated as DES1 (Fig. 1). This enzyme is important for maintaining the homeostasis of cysteine in the cell, and the loss of function of this protein in knockout mutant plants results in higher levels of cysteine and glutathione. This increased level of soluble thiols results also in a higher antioxidant capacity of the plant, which, in turn, becomes more resistant to abiotic stress phenomena such as the presence of heavy metals or hydrogen peroxide. This observation may indicate that the regulation of this enzyme may be a key component of the plant physiological processes that involve redox reactions. Cytosolic cysteine degrading enzymes with desulfhydrase activity has been found in plants, but the protein responsible for this activity remained unisolated until now that it is revealed with our investigation on DES1.¹¹ From the standpoint of biotechnology, plants with this modified enzyme may result in abiotic stress-resistant lines that deserve to be studied.Open in a separate windowFigure 1Biosynthesis of cysteine and S-sulfocysteine in the chloroplast and cytosol of Arabidopsis and subcellular localization of the responsible enzymes. The cytosolic and plastidial O-acetylserine(thiol)lyase, L-cysteine desulfhydrase and S-sulfocysteine synthase are shown in red. A single representative of a grana thylakoid is shown as a grey oval compartment.The other less common enzyme studied, called CS26 and localized in the chloroplast, has proved to be an enzyme with S-sulfocysteine synthase activity.¹⁰ This enzyme synthesizes the incorporation of thiosulfate to O-acetylserine to form S-sulfocysteine (RSSO₃⁻). This activity, discovered for the first time in plants, was previously reported in bacteria where the biosynthesis of cysteine can be accomplished by two enzymes encoded by the cysK and cysM genes.^12,13 This enzyme activity is essential for the chloroplast function under long-day growing conditions but seems to be superfluous under short-day conditions. Morphologic and biochemical phenotype comparisons of the knockout oas-b and cs26 highlight the importance of the metabolite S-sulfocysteine and not the cysteine in the redox control of the chloroplast. Under long-day growth conditions, the cs26 mutants exhibit a reduction in size and show leaf paleness, have reductions in the chlorophyll content and photosynthetic activity, and are not able to properly detoxify reactive oxygen species, which are accumulated to high levels. None of these changes are observed in the oas-b mutant.Although we do not know the function of the S-sulfocysteine molecule in the chloroplast, two aspects are important to note. On the one hand, the enzyme CS26 can be located in the chloroplast''s lumen in opposition to the enzyme OAS-B, which is located in the stroma. The second aspect is the difference in chemical reactivity of S-sulfocysteine and cysteine. The S-sulfocysteine has two sulfur atoms with different degrees of oxidation, −1 and +5; therefore, it may act as an oxidant molecule by reacting with reduced thiols forming a disulfide bridge and releasing sulfite.¹⁴ We have suggested that a putative target of S-sulfocysteine can be the STN7 kinase, which contains a transmembrane region that separates its catalytic kinase domain on the stromal side from its N-terminal end in the thylakoid lumen with two conserved cysteines that are critical for its activity. A disulfide bridge between these two cysteines is required for the kinase activity, but how the redox states of these two cysteines are regulated in the lumen remains an open question.¹⁵ In general, how the thiol oxidation of proteins located in the thylakoid lumen takes place is still unclear because no sulfhydryl oxidases have been identified in this compartment. In fact, this process is highly important because the chaperones and peptidyl-prolyl cis-trans isomerases, such as the AtFKBP13, need to be oxidized in order to be functional in the lumen and to regulate the folding of the Rieske protein.^16–18     

Constitutive activation of jasmonate signaling in an Arabidopsis mutant correlates with enhanced resistance to Erysiphe cichoracearum,Pseudomonas syringae,and Myzus persicae

In Arabidopsis spp., the jasmonate (JA) response pathway generally is required for defenses against necrotrophic pathogens and chewing insects, while the salicylic acid (SA) response pathway is generally required for specific, resistance (R) gene-mediated defenses against both biotrophic and necrotrophic pathogens. For example, SA-dependent defenses are required for resistance to the biotrophic fungal pathogen Erysiphe cichoracearum UCSC1 and the bacterial pathogen Pseudomonas syringae pv. maculicola, and also are expressed during response to the green peach aphid Myzus persicae. However, recent evidence indicates that the expression of JA-dependent defenses also may confer resistance to E. cichoracearum. To confirm and to extend this observation, we have compared the disease and pest resistance of wild-type Arabidopsis plants with that of the mutants coil, which is insensitive to JA, and cev1, which has constitutive JA signaling. Measurements of the colonization of these plants by E. cichoracearum, P. syringae pv. maculicola, and M. persicae indicated that activation of the JA signal pathway enhanced resistance, and was associated with the activation of JA-dependent defense genes and the suppression of SA-dependent defense genes. We conclude that JA and SA induce alternative defense pathways that can confer resistance to the same pathogens and pests.     

The perplexing role of autophagy in plant innate immune responses

Autophagy is a major intracellular process for the degradation of cytosolic macromolecules and organelles in the lysosomes or vacuoles for the purposes of regulating cellular homeostasis and protein and organelle quality control. In complex metazoan organisms, autophagy is highly engaged during the immune responses through interfaces either directly with intracellular pathogens or indirectly with immune signalling molecules. Studies over the last decade or so have also revealed a number of important ways in which autophagy shapes plant innate immune responses. First, autophagy promotes defence‐associated hypersensitive cell death induced by avirulent or related pathogens, but restricts unnecessary or disease‐associated spread of cell death. This elaborate regulation of plant host cell death by autophagy is critical during plant immune responses to the types of plant pathogens that induce cell death, which include avirulent biotrophic pathogens and necrotrophic pathogens. Second, autophagy modulates defence responses regulated by salicylic acid and jasmonic acid, thereby influencing plant basal resistance to both biotrophic and necrotrophic pathogens. Third, there is an emerging role of autophagy in virus‐induced RNA silencing, either as an antiviral collaborator for targeted degradation of viral RNA silencing suppressors or an accomplice of viral RNA silencing suppressors for targeted degradation of key components of plant cellular RNA silencing machinery. In this review, we summarize this important progress and discuss the potential significance of the perplexing role of autophagy in plant innate immunity.     

The BRI1-associated kinase 1, BAK1, has a brassinolide-independent role in plant cell-death control

Programmed cell death (PCD) is a common host response to microbial infection [1-3]. In plants, PCD is associated with immunity to biotrophic pathogens, but it can also promote disease upon infection by necrotrophic pathogens [4]. Therefore, plant cell-suicide programs must be strictly controlled. Here we demonstrate that the Arabidopsis thaliana Brassinosteroid Insensitive 1 (BRI1)-associated receptor Kinase 1 (BAK1), which operates as a coreceptor of BRI1 in brassinolide (BL)-dependent plant development, also regulates the containment of microbial infection-induced cell death. BAK1-deficient plants develop spreading necrosis upon infection. This is accompanied by production of reactive oxygen intermediates and results in enhanced susceptibility to necrotrophic fungal pathogens. The exogenous application of BL rescues growth defects of bak1 mutants but fails to restore immunity to fungal infection. Moreover, BL-insensitive and -deficient mutants do not exhibit spreading necrosis or enhanced susceptibility to fungal infections. Together, these findings suggest that plant steroid-hormone signaling is dispensable for the containment of infection-induced PCD. We propose a novel, BL-independent function of BAK1 in plant cell-death control that is distinct from its BL-dependent role in plant development.     

Complex genetics control natural variation in Arabidopsis thaliana resistance to Botrytis cinerea

The genetic architecture of plant defense against microbial pathogens may be influenced by pathogen lifestyle. While plant interactions with biotrophic pathogens are frequently controlled by the action of large-effect resistance genes that follow classic Mendelian inheritance, our study suggests that plant defense against the necrotrophic pathogen Botrytis cinerea is primarily quantitative and genetically complex. Few studies of quantitative resistance to necrotrophic pathogens have used large plant mapping populations to dissect the genetic structure of resistance. Using a large structured mapping population of Arabidopsis thaliana, we identified quantitative trait loci influencing plant response to B. cinerea, measured as expansion of necrotic lesions on leaves and accumulation of the antimicrobial compound camalexin. Testing multiple B. cinerea isolates, we identified 23 separate QTL in this population, ranging in isolate-specificity from being identified with a single isolate to controlling resistance against all isolates tested. We identified a set of QTL controlling accumulation of camalexin in response to pathogen infection that largely colocalized with lesion QTL. The identified resistance QTL appear to function in epistatic networks involving three or more loci. Detection of multilocus connections suggests that natural variation in specific signaling or response networks may control A. thaliana-B. cinerea interaction in this population.     

Isolation of Nicotiana plumbaginifolia cDNAs encoding isoforms of serine acetyltransferase and O-acetylserine (thiol) lyase in a yeast two-hybrid system with Escherichia coli cysE and cysK genes as baits

We applied the yeast two-hybrid system for screening of a cDNA library of Nicotiana plumbaginifolia for clones encoding plant proteins interacting with two proteins of Escherichia coli: serine acetyltransferase (SAT, the product of cysE gene) and O-acetylserine (thiol)lyase A, also termed cysteine synthase (OASTL-A, the product of cysK gene). Two plant cDNA clones were identified when using the cysE gene as a bait. These clones encode a probable cytosolic isoform of OASTL and an organellar isoform of SAT, respectively, as indicated by evolutionary trees. The second clone, encoding SAT, was identified independently also as a "prey" when using cysK as a bait. Our results reveal the possibility of applying the two-hybrid system for cloning of plant cDNAs encoding enzymes of the cysteine synthase complex in the two-hybrid system. Additionally, using genome walking sequences located upstream of the sat1 cDNA were identified. Subsequently, in silico analyses were performed aiming towards identification of the potential signal peptide and possible location of the deduced mature protein encoded by sat1.     

Impact of reduced O-acetylserine(thiol)lyase isoform contents on potato plant metabolism

Plant cysteine (Cys) synthesis can occur in three cellular compartments: the chloroplast, cytoplasm, and mitochondrion. Cys formation is catalyzed by the enzyme O-acetylserine(thiol)lyase (OASTL) using O-acetylserine (OAS) and sulfide as substrates. To unravel the function of different isoforms of OASTL in cellular metabolism, a transgenic approach was used to down-regulate specifically the plastidial and cytosolic isoforms in potato (Solanum tuberosum). This approach resulted in decreased RNA, protein, and enzymatic activity levels. Intriguingly, H(2)S-releasing capacity was also reduced in these lines. Unexpectedly, the thiol levels in the transgenic lines were, regardless of the selected OASTL isoform, significantly elevated. Furthermore, levels of metabolites such as serine, OAS, methionine, threonine, isoleucine, and lysine also increased in the investigated transgenic lines. This indicates that higher Cys levels might influence methionine synthesis and subsequently pathway-related amino acids. The increase of serine and OAS points to suboptimal Cys synthesis in transgenic plants. Taking these findings together, it can be assumed that excess OASTL activity regulates not only Cys de novo synthesis but also its homeostasis. A model for the regulation of Cys levels in plants is proposed.     

Analysis of cytosolic and plastidic serine acetyltransferase mutants and subcellular metabolite distributions suggests interplay of the cellular compartments for cysteine biosynthesis in Arabidopsis

In plants, the enzymes for cysteine synthesis serine acetyltransferase (SAT) and O-acetylserine-(thiol)-lyase (OASTL) are present in the cytosol, plastids and mitochondria. However, it is still not clearly resolved to what extent the different compartments are involved in cysteine biosynthesis and how compartmentation influences the regulation of this biosynthetic pathway. To address these questions, we analysed Arabidopsis thaliana T-DNA insertion mutants for cytosolic and plastidic SAT isoforms. In addition, the subcellular distribution of enzyme activities and metabolite concentrations implicated in cysteine and glutathione biosynthesis were revealed by non-aqueous fractionation (NAF). We demonstrate that cytosolic SERAT1.1 and plastidic SERAT2.1 do not contribute to cysteine biosynthesis to a major extent, but may function to overcome transport limitations of O-acetylserine (OAS) from mitochondria. Substantiated by predominantly cytosolic cysteine pools, considerable amounts of sulphide and presence of OAS in the cytosol, our results suggest that the cytosol is the principal site for cysteine biosynthesis. Subcellular metabolite analysis further indicated efficient transport of cysteine, γ -glutamylcysteine and glutathione between the compartments. With respect to regulation of cysteine biosynthesis, estimation of subcellular OAS and sulphide concentrations established that OAS is limiting for cysteine biosynthesis and that SAT is mainly present bound in the cysteine–synthase complex.     

Sulfur-enhanced defence: effects of sulfur metabolism, nitrogen supply, and pathogen lifestyle

Evidence from field experiments indicates differential roles of sulfur and nitrogen supply for plant resistance against pathogens. Dissection of these observations in defined pathosystems and controlled nutritional conditions indicates an activation of plant sulfur metabolism in several incompatible and compatible interactions. Contents of cysteine and glutathione as markers of primary sulfate assimilation and stress response show increases in ARABIDOPSIS THALIANA upon infection, coinciding with the synthesis of sulfur-containing defence compounds. Similar increases of thiols were observed with necrotrophic, biotrophic, and hemibiotrophic pathogens. Sulfate supply was found to be neutral or beneficial for tolerance against fungal but neutral for bacterial pathogens under IN VITRO conditions. According to various reports and own observations the effects of nitrogen supply appeared to be neutral or harmful, depending on the pathogen. The activation of sulfur metabolism was a consequence of activation of gene expression as revealed by macroarray analysis of an A. THALIANA/ALTERNARIA BRASSICICOLA pathosystem. This activation appeared to be largely independent from sufficient or optimal sulfate supply and from the established sulfate deficiency response. The data suggest that plant-pathogen interactions and sulfur metabolism are linked by jasmonic acid as signal.     

Insights into the role of jasmonic acid-mediated defenses against necrotrophic and biotrophic fungal pathogens

Jasmonic acid (JA) is a natural hormone regulator involved in development,responses against wounding and pathogen attack.Upon perception of pathogens,JA is synthesized and mediates a signaling cascade ...