SUMMARYThe complete nucleotide sequence of the genomic RNA of the potyvirus potato virus Y strain N (PVYn) was obtained from cloned cDNAs. This sequence is 9704 nucleotides long and can encode a polyprotein of 3063 amino acids. The positions of the cleavage sites at the N terminus of the capsid and cytoplasmic inclusion proteins have been determined. Other putative protein cleavage sites have been deduced by searching for consensus sequences and by analogy with the polyprotein of the tobacco vein mottling virus and of the tobacco etch virus. Comparison of the PVY polyprotein sequence with that of other potyvirus polyproteins shows similarities in genome organization and a high level of identity along most of the polyprotein, except for the putative proteins flanking the helper component. A search for specific protein motifs has revealed the existence of a potential metal-binding site at the putative N terminus of the helper component in potyviruses. The possible functions of this structure are discussed.
The deposition of lignin during plant-pathogen interactions is thought to play a role in plant defence. However, the function of lignification genes in plant disease resistance is poorly understood. In this article, we provide genetic evidence that the primary genes involved in lignin biosynthesis in Arabidopsis, CAD-C and CAD-D, act as essential components of defence to virulent and avirulent strains of the bacterial pathogen Pseudomonas syringae pv. tomato, possibly through the salicylic acid defence pathway. Thus, in contrast with cellulose synthesis, whose alteration leads to an increase in disease resistance, alteration of the cell wall lignin content leads directly or indirectly to defects in some defence components.
Hypersensitive response (HR) is a programmed cell death that is commonly associated with disease resistance in plants. Among the different HR-related early induced genes, the AtMYB30 gene is specifically, rapidly, and transiently expressed during incompatible interactions between Arabidopsis and bacterial pathogens. Its expression was also shown to be deregulated in Arabidopsis mutants affected in the control of cell death initiation. Here, we demonstrate that overexpression in Arabidopsis and tobacco of AtMYB30 (i) accelerates and intensifies the appearance of the HR in response to different avirulent bacterial pathogens, (ii) causes HR-like responses to virulent strains, and (iii) increases resistance against different bacterial pathogens, and a virulent biotrophic fungal pathogen, Cercospora nicotianae. In antisense AtMYB30 Arabidopsis lines, HR cell death is strongly decreased or suppressed in response to avirulent bacterial strains, resistance against different bacterial pathogens decreased, and the expression of HR-and defense-related genes was altered. Taken together, these results strongly suggest that AtMYB30 is a positive regulator of hypersensitive cell death.
hsr203J is a tobacco gene whose activation is rapid, highly localized, and specific for incompatible interactions between tobacco and the bacterial pathogen Ralstonia solanacearum. The effect of other hypersensitive response (HR)-inducing pathogens and elicitors has been tested with transgenic plants containing the hsr203J promoter-GUS reporter gene fusion, and confirms the generality of the preferential inducibility of the hsr203J gene promoter during incompatible interactions: bacterial and viral pathogens inducing an HR in tobacco were able to induce the promoter fusion, as were inducers of HR-like responses such as harpin, elicitins, and PopA1 proteins. A tomato hsr203 homologous cDNA was isolated (Lehsr203) and used to examine the effect of avr gene products on the expression of such genes. Lehsr203 was shown to be rapidly and transiently induced in leaves of the tomato Cf-9 line, following Avr9 product infiltration, but not in those of the Cf-0 line. Among potential effectors of HR or resistance such as H2O2, salicylic acid, methyl jasmonate, and 2,6-dichloro-isonicotinic acid (INA), none is able to induce a significant increase in promoter activation. In contrast, heavy metals that cause leaf necrosis can trigger such an activation. In addition, hsr203-GUS fusion expression is detected in transgenic tobacco lines expressing the bO gene and exhibiting spontaneous HR-like lesions. Taken together, these results demonstrate a strong correlation between hsr203 and genetically controlled cell death in tobacco and tomato. The expression of this gene should be a useful marker for programmed cell death occurring in response not only to diverse pathogens, but also to diverse death-triggering extracellular agents.
Oxylipins, derived from fatty acid hydroperoxides (FAHs), are thought to play different roles during plant pathogen interactions. During hypersensitive response (HR) some of them serve as signals necessary for defence gene activation whereas others could contribute to pathogen killing or could participate in the execution of plant programmed cell death (PCD) associated with this resistance. In order to address the role of these compounds in the latter process, we have closely observed lipid peroxidation, the first step of this metabolic pathway, under different situations which led either to accelerated or inhibited HR cell death. The oxidative process has been studied in cryptogein-elicited tobacco leaves and during Ralstonia solanacearuminduced HR. It was shown that FAH accumulation was preceded by the co-ordinated rise in 9 lipoxygenase (9 LOX) and galactolipase activities in addition to the transcription of a set of four genes encoding 9 LOX and patatinlike proteins, NtPAT1-3. The latter gene expression was at the origin of a metabolic pathway allowing the release of poly-unsaturated fatty acids from plastid galactolipids and their oxidation into free 9 FAHs. This 9 LOX-dependent lipid peroxidation was found to be sufficient to lead to HR cell death. Finally, during the bacterial-induced HR, lipid peroxidation appeared as a composite of metabolites of enzymatic and non-enzymatic origins and suggested the role of H 2 O 2 as an important source of oxidant that might, in synergy with 9 FAHs, contribute to cell death execution.
SummaryThe tobacco gene, HSR203J, which is speci®cally activated during the early steps of incompatible plant/ pathogen interactions has been shown to be a molecular marker of the hypersensitive response (HR). It constitutes an ideal model for the identi®cation of HR-responsive cis-regulatory elements. As a ®rst step in the promoter dissection, deletion mutants of the 5¢¯anking sequence of HSR203J fused to the GUS reporter gene were analyzed. Then, the construction and study of chimeric constructs containing HSR203J promoter fragments fused to a minimal promoter enabled us to identify a 28-bp regulatory element located between ±106 and ±79 upstream of the transcription initiation site. This element has been shown to be necessary and suf®cient for transcriptional activation in response to pathogen. It contains a 10-bp palindrome followed by its unperfect repeat. The mutagenesis of these two sequence elements led to the identi®cation of a 12-bp motif termed HSRE (HSR203 responsive element) responsible for the marked induction of the HSR203J gene during the HR. Since this DNA region did not show any homology with known regulatory sequences, this 12 bp motif corresponds to a novel cisregulatory element.
SummaryActivation of the tobacco gene hsr203 is rapid, highly localized, speci®c for incompatible plant±pathogen interactions, and strongly correlated with programmed cell death occurring in response to diverse pathogens. Functional characterization of hsr203 gene product has shown that HSR203 is a serine hydrolase that displays esterase activity. We show here that transgenic tobacco plants de®cient in HSR203 protein exhibit an accelerated hypersensitive response when inoculated with an avirulent strain of Ralstonia solanacearum. This response was accompanied by a maximal level of cell death and a drastic inhibition of in planta bacterial growth. Transgenic plants de®cient in HSR203 were also found to show increased resistance in a dosage-dependent manner to Pseudomonas syringae pv. pisi, another avirulent bacterial pathogen, and to virulent and avirulent races of Phytophthora parasitica, a fungal pathogen of tobacco, but not to different virulent bacteria. Surprisingly, expression of another hsr gene, hsr515, and that of the defence genes PR1-a and PR5, was strongly reduced in the transgenic lines. Our results suggest that hsr203 antisense suppression in tobacco can have pleiotropic effects on HR cell death and defence mechanisms, and induces increased resistance to different pathogens.
BackgroundLow-level, partial resistance is pre-eminent in natural populations, however, the mechanisms underlying this form of resistance are still poorly understood.Methodology/Principal FindingsIn the present study, we used the model pathosystem Pseudomonas syringae pv. tomato DC3000 (Pst) - Arabidopsis thaliana to study the genetic basis of this form of resistance. Phenotypic analysis of a set of Arabidopsis accessions, based on evaluation of in planta pathogen growth revealed extensive quantitative variation for partial resistance to Pst. It allowed choosing a recombinant inbred line (RIL) population derived from a cross between the accessions Bayreuth and Shahdara for quantitative genetic analysis. Experiments performed under two different environmental conditions led to the detection of two major and two minor quantitative trait loci (QTLs) governing partial resistance to Pst and called PRP-Ps1 to PRP-Ps4. The two major QTLs, PRP-Ps1 and PRP-Ps2, were confirmed in near isogenic lines (NILs), following the heterogeneous inbred families (HIFs) strategy. Analysis of marker gene expression using these HIFs indicated a negative correlation between the induced amount of transcripts of SA-dependent genes PR1, ICS and PR5, and the in planta bacterial growth in the HIF segregating at PRP-Ps2 locus, suggesting an implication of PRP-Ps2 in the activation of SA dependent responses.Conclusions/SignificanceThese results show that variation in partial resistance to Pst in Arabidopsis is governed by relatively few loci, and the validation of two major loci opens the way for their fine mapping and their cloning, which will improve our understanding of the molecular mechanisms underlying partial resistance.
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