NPS6, encoding a nonribosomal peptide synthetase, is a virulence determinant in the maize (Zea mays) pathogen Cochliobolus heterostrophus and is involved in tolerance to H2O2. Deletion of NPS6 orthologs in the rice (Oryza sativa) pathogen, Cochliobolus miyabeanus, the wheat (Triticum aestivum) pathogen, Fusarium graminearum, and the Arabidopsis thaliana pathogen, Alternaria brassicicola, resulted in reduced virulence and hypersensitivity to H2O2. Introduction of the NPS6 ortholog from the saprobe Neurospora crassa to the Δnps6 strain of C. heterostrophus restored wild-type virulence to maize and tolerance to H2O2, demonstrating functional conservation in filamentous ascomycete phytopathogens and saprobes. Increased sensitivity to iron depletion was identified as a conserved phenotype of Δnps6 strains. Exogenous application of iron enhanced the virulence of Δnps6 strains of C. heterostrophus, C. miyabeanus, F. graminearum, and A. brassicicola to each host. NPS6 is responsible for the biosynthesis of extracellular siderophores by C. heterostrophus, F. graminearum, and A. brassicicola. Application of the extracellular siderophore of A. brassicicola restored wild-type virulence of the ΔAbnps6 strain to Arabidopsis. It is proposed that the role of extracellular siderophores in fungal virulence to plants is to supply an essential nutrient, iron, to their producers in planta and not to act as phytotoxins, depriving their hosts of iron.
Transgenic tobacco deficient in the H 2 O 2 -removing enzyme catalase (Cat1AS) was used as an inducible and noninvasive system to study the role of H 2 O 2 as an activator of pathogenesis-related (PR) proteins in plants. Excess H 2 O 2 in Cat1AS plants was generated by simply increasing light intensities. Sustained exposure of Cat1AS plants to excess H 2 O 2 provoked tissue damage, stimulated salicylic acid and ethylene production, and induced the expression of acidic and basic PR proteins with a timing and magnitude similar to the hypersensitive response against pathogens. Salicylic acid production was biphasic, and the first peak of salicylic acid as well as the peak of ethylene occurred within the first hours of high light, which is long before the development of tissue necrosis. Under these conditions, accumulation of acidic PR proteins was also seen in upper leaves that were not exposed to high light, indicating systemic induction of expression. Short exposure of Cat1AS plants to excess H 2 O 2 did not cause damage, induced local expression of acidic and basic PR proteins, and enhanced pathogen tolerance. However, the timing and magnitude of PR protein induction was in this case more similar to that in upper uninfected leaves than to that in hypersensitiveresponse leaves of pathogen-infected plants. Together, these data demonstrate that sublethal levels of H 2 O 2 activate expression of acidic and basic PR proteins and lead to enhanced pathogen tolerance. However, rapid and strong activation of PR protein expression, as seen during the hypersensitive response, occurs only when excess H 2 O 2 is accompanied by leaf necrosis.
To investigate the resistance signaling pathways activated by pathogen infection, we previously identified the Arabidopsis thaliana mutant constitutive expresser of PR genes22 (cpr22), which displays constitutive activation of multiple defense responses. Here, we identify the cpr22 mutation as a 3-kb deletion that fuses two cyclic nucleotide-gated ion channel (ATCNGC)-encoding genes, ATCNGC11 and ATCNGC12, to generate a novel chimeric gene, ATCNGC11/12. Genetic, molecular, and complementation analyses suggest that ATCNGC11/12, as well as ATCNGC11 and ATCNGC12, form functional cAMP-activated ATCNGCs and that the phenotype conferred by cpr22 is attributable to the expression of ATCNGC11/12. However, because overexpression of ATCNGC12, but not ATCNGC11, suppressed the phenotype conferred by cpr22, the development of this phenotype appears to be regulated by the ratio between ATCNGC11/12 and ATCNGC12. Analysis of knockout lines revealed that both ATCNGC11 and ATCNGC12 are positive mediators of resistance against an avirulent biotype of Hyaloperonospora parasitica. Through epistatic analyses, cpr22-mediated enhanced resistance to pathogens was found to require NDR1-dependent and EDS1/PAD4-dependent pathways. In striking contrast, none of these pathways was required for cpr22-induced salicylic acid accumulation or PR-1 gene expression. These results demonstrate that NDR1, EDS1, and PAD4 mediate other resistance signaling function(s) in addition to salicylic acid and pathogenesis-related protein accumulation. Moreover, the requirement for both NDR1-dependent and EDS1/PAD4-dependent pathways for cpr22-mediated resistance suggests that these pathways are cross-regulated.
SummaryLocalized cell death is a common feature of ozone phytotoxicity and is generally thought to be initiated by the strong oxidant ozone itself as well as by ozone-derived reactive oxygen intermediates (ROIs). Here we report that ozone (150 nl l -1 , 5 h) elicits cellular ROI production in the ozone-sensitive tobacco cv. Bel W3, but not in the tolerant cv. Bel B. Both cultivars exhibited a transient first maximum of apoplastic ROI accumulation followed by a comparable induction of glutathione peroxidase transcript levels. During postcultivation in pollutant-free air, a second and sustained peak of apoplastic ROI accumulation was detected only in cv. Bel W3. Histochemical staining revealed a spot-like accumulation of H 2 O 2 and, to a lesser extent, of superoxide anion radicals in this cultivar. The H 2 O 2 spots ('burst initiation sites') occurred mainly in the vicinity of leaf veins and correlated in number and distribution with discrete sites of local cell death and with visible symptoms that evolved between 15 and 72 h. The results indicate that ozone effects are amplified in the sensitive tobacco cv. Bel W3 by an oxidative burst which participates in the generation of hypersensitive cell deathlike lesions.
The ozone-sensitive Arabidopsis mutant vitamin c-1 (vtc1) is deficient in l-ascorbic acid (AsA) due to a mutation in GDP-Man pyrophosphorylase (Conklin et al., 1999), an enzyme involved in the AsA biosynthetic pathway (Smirnoff et al., 2001). In this study, the physiology of this AsA deficiency was initially investigated in response to biotic (virulent pathogens) stress and subsequently with regards to the onset of senescence. Infection with either virulent Pseudomonas syringae or Peronospora parasitica resulted in largely reduced bacterial and hyphal growth in the vtc1 mutant in comparison to the wild type. When vitamin c-2 (vtc2), another AsA-deficient mutant, was challenged with P. parasitica, growth of the fungus was also reduced, indicating that the two AsA-deficient mutants are more resistant to these pathogens. Induction of pathogenesis-related proteins PR-1 and PR-5 is significantly higher in vtc1 than in the wild type when challenged with virulent P. syringae. In addition, the vtc1 mutant exhibits elevated levels of some senescence-associated gene (SAG) transcripts as well as heightened salicylic acid levels. Presumably, therefore, low AsA is causing vtc1 to enter at least some stage(s) of senescence prematurely with an accompanying increase in salicylic acid levels that results in a faster induction of defense responses.
We show that above a certain threshold concentration, ozone leads to leaf injury in tomato (Lycopersicon esculentum). Ozone-induced leaf damage was preceded by a rapid increase in 1-aminocyclopropane-1-carboxylic acid (ACC) synthase activity, ACC content, and ethylene emission. Changes in mRNA levels of specific ACC synthase, ACC oxidase, and ethylene receptor genes occurred within 1 to 5 h. Expression of the genes encoding components of ethylene biosynthesis and perception, and biochemistry of ethylene synthesis suggested that ozone-induced ethylene synthesis in tomato is under biphasic control. In transgenic plants containing anLE-ACO1 promoter-β-glucuronidase fusion construct, β-glucuronidase activity increased rapidly at the beginning of the O3 exposure and had a spatial distribution resembling the pattern of extracellular H2O2 production at 7 h, which coincided with the cell death pattern after 24 h. Ethylene synthesis and perception were required for active H2O2 production and cell death resulting in visible tissue damage. The results demonstrate a selective ozone response of ethylene biosynthetic genes and suggest a role for ethylene, in combination with the burst of H2O2production, in regulating the spread of cell death.
Arabidopsis (Arabidopsis thaliana) cyclic nucleotide-gated ion channels (CNGCs) form a large family consisting of 20 members and have been implicated in Ca 2+ signaling related to various physiological processes, such as pathogen defense, development, and thermotolerance. The null mutant of AtCNGC2, defense, no death (dnd1), exhibits autoimmune phenotypes, while it is impaired in mounting the hypersensitive response, which is a hallmark of effector-triggered (i.e. RESISTANCE-gene mediated) resistance. It has been suggested that AtCNGC2 is involved in defense responses and likely other aspects of physiology through its role as a Ca 2+ -conducting channel. However, the downstream signaling components and its relation with AtCNGC4, which is the closest paralog of AtCNGC2, remain elusive. Despite the fact that cngc4 mutants display almost identical phenotypes to those seen in cngc2 mutants, not much is known about their relationship. Here, we report the identification and characterization of the Arabidopsis mutant repressor of defense no death1 (rdd1), obtained from a suppressor screen of a transfer DNA insertion knockout mutant of AtCNGC2 in order to identify downstream components of dnd1-mediated signal transduction. rdd1 suppressed the majority of dnd1-mediated phenotypes except Ca 2+ hypersensitivity. In addition, rdd1 also suppressed the dnd1-mediated lateflowering phenotype that was discovered in this study. Our genetic analysis conducted to elucidate the relationship between AtCNGC2 and AtCNGC4 indicates that RDD1 is also involved in AtCNGC4-mediated signal transduction. Lastly, bimolecular fluorescence complementation analysis suggests that AtCNGC2 and AtCNGC4 are likely part of the same channel complex.
In animals, aconitase is a bifunctional protein. When an iron-sulfur cluster is present in its catalytic center, aconitase displays enzymatic activity; when this cluster is lost, it switches to an RNA-binding protein that regulates the translatability or stability of certain transcripts. To investigate the role of aconitase in plants, we assessed its ability to bind mRNA. Recombinant aconitase failed to bind an iron responsive element (IRE) from the human ferritin gene. However, it bound the 5' UTR of the Arabidopsis chloroplastic CuZn superoxide dismutase 2 (CSD2) mRNA, and this binding was specific. Arabidopsis aconitase knockout (KO) plants were found to have significantly less chlorosis after treatment with the superoxide-generating compound, paraquat. This phenotype correlated with delayed induction of the antioxidant gene GST1, suggesting that these KO lines are more tolerant to oxidative stress. Increased levels of CSD2 mRNAs were observed in the KO lines, although the level of CSD2 protein was not affected. Virus-induced gene silencing (VIGS) of aconitase in Nicotiana benthamiana caused a 90% reduction in aconitase activity, stunting, spontaneous necrotic lesions, and increased resistance to paraquat. The silenced plants also had less cell death after transient co-expression of the AvrPto and Pto proteins or the pro-apoptotic protein Bax. Following inoculation with Pseudomonas syringae pv. tabaci carrying avrPto, aconitase-silenced N. benthamiana plants expressing the Pto transgene displayed a delayed hypersensitive response (HR) and supported higher levels of bacterial growth. Disease-associated cell death in N. benthamiana inoculated with P. s. pv. tabaci was also reduced. Taken together, these results suggest that aconitase plays a role in mediating oxidative stress and regulating cell death.
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