Signalling in Rhizobacteria-Induced Systemic Resistance in Arabidopsis thaliana

Abstract: To protect themselves from disease, plants have evolved sophisticated defence mechanisms in which the signal molecules salicylic acid, jasmonic acid and ethylene often play crucial roles. Elucidation of signalling pathways controlling disease resistance is a major objective in research on plant-pathogen interactions. The capacity of a plant to develop a broad spectrum, systemic acquired resistance (SAR) after primary infection with a necrotizing pathogen is well-known and its signal transduction pathway extensively studied. Plants of which the roots have been colonized by specific strains of non-pathogenic fluorescent Pseudomonas spp. develop a phenotypically similar form of protection that is called rhizobacteria-mediated induced systemic resistance (ISR). In contrast to pathogen-induced SAR, which is regulated by salicylic acid, rhizobacteria-mediated ISR is controlled by a signalling pathway in which jasmonic acid and ethylene play key roles. In the past eight years, the model plant species Arabidopsis thaliana was explored to study the molecular basis of rhizobacteria-mediated ISR. Here we review current knowledge of the signal transduction steps involved in the ISR pathway that leads from recognition of the rhizobacteria in the roots to systemic expression of broad-spectrum disease resistance in aboveground foliar tissues.     

Arabidopsis thaliana GLUTATHIONE‐S‐TRANSFERASE THETA 2 interacts with RSI1/FLD to activate systemic acquired resistance

A partly infected plant develops systemic acquired resistance (SAR) and shows heightened resistance during subsequent infections. The infected parts generate certain mobile signals that travel to the distal tissues and help to activate SAR. SAR is associated with epigenetic modifications of several defence‐related genes. However, the mechanisms by which mobile signals contribute to epigenetic changes are little known. Previously, we have shown that the Arabidopsis REDUCED SYSTEMIC IMMUNITY 1 (RSI1, alias FLOWERING LOCUS D; FLD), which codes for a putative histone demethylase, is required for the activation of SAR. Here, we report the identification of GLUTATHIONE‐S‐TRANSFERASE THETA 2 (GSTT2) as an interacting factor of FLD. GSTT2 expression increases in pathogen‐inoculated as well as pathogen‐free distal tissues. The loss‐of‐function mutant of GSTT2 is compromised for SAR, but activates normal local resistance. Complementation lines of GSTT2 support its role in SAR activation. The distal tissues of gstt2 mutant plants accumulate significantly less salicylic acid (SA) and express a reduced level of the SA biosynthetic gene PAL1. In agreement with the established histone modification activity of FLD, gstt2 mutant plants accumulate an enhanced level of methylated and acetylated histones in the promoters of WRKY6 and WRKY29 genes. Together, these results demonstrate that GSTT2 is an interactor of FLD, which is required for SAR and SAR‐associated epigenetic modifications.     

Induction of Systemic Acquired Resistance by Heat Shock Treatment in Arabidopsis

A 3,6-di-O-benzylated demethylallosamizoline derivative was glycosylated at the 4-position with an N, N′-diphthaloylchitobiosyl moiety by using the thioglycoside method. After de-protections, the resulting demethylallosamidin-like pseudotrisaccharide was evaluated as an inhibitor against a couple of chitinases.     

The Elongator complex‐associated protein DRL1 plays a positive role in immune responses against necrotrophic fungal pathogens in Arabidopsis

DEFORMED ROOT AND LEAVES1 (DRL1) is an Arabidopsis homologue of the yeast TOXIN TARGET4 (TOT4)/KILLER TOXIN‐INSENSITIVE12 (KTI12) protein that is physically associated with the RNA polymerase II‐interacting protein complex named Elongator. Mutations in DRL1 and Elongator lead to similar morphological and molecular phenotypes, suggesting that DRL1 and Elongator may functionally overlap in Arabidopsis. We have shown previously that Elongator plays an important role in both salicylic acid (SA)‐ and jasmonic acid (JA)/ethylene (ET)‐mediated defence responses. Here, we tested whether DRL1 also plays a similar role as Elongator in plant immune responses. Our results show that, although DRL1 partially contributes to SA‐induced cytotoxicity, it does not play a significant role in SA‐mediated expression of PATHOGENESIS‐RELATED genes and resistance to the virulent bacterial pathogen Pseudomonas syringae pv. maculicola ES4326. In contrast, DRL1 is required for JA/ET‐ and necrotrophic fungal pathogen Botrytis cinerea‐induced defence gene expression and for resistance to B. cinerea and Alternaria brassicicola. Furthermore, unlike the TOT4/KTI12 gene which, when overexpressed in yeast, confers zymocin resistance, a phenotype of the tot4/kti12 mutant, overexpression of DRL1 does not change B. cinerea‐induced defence gene expression and resistance to this pathogen. Finally, DRL1 contains an N‐terminal P‐loop and a C‐terminal calmodulin (CaM)‐binding domain and is a CaM‐binding protein. We demonstrate that both the P‐loop and the CaM‐binding domain are essential for the function of DRL1 in B. cinerea‐induced expression of PDF1.2 and ORA59, and in resistance to B. cinerea, suggesting that the function of DRL1 in plant immunity may be regulated by ATP/GTP and CaM binding.     

Plastid omega3-fatty acid desaturase-dependent accumulation of a systemic acquired resistance inducing activity in petiole exudates of Arabidopsis thaliana is independent of jasmonic acid

Systemic acquired resistance (SAR) is an inducible defense mechanism that is activated throughout the plant, subsequent to localized inoculation with a pathogen. The establishment of SAR requires translocation of an unknown signal from the pathogen-inoculated leaf to the distal organs, where salicylic acid-dependent defenses are activated. We demonstrate here that petiole exudates (PeXs) collected from Arabidopsis leaves inoculated with an avirulent (Avr) Pseudomonas syringae strain promote resistance when applied to Arabidopsis, tomato ( Lycopersicum esculentum ) and wheat ( Triticum aestivum ). Arabidopsis FATTY ACID DESATURASE7 ( FAD7 ), SUPPRESSOR OF FATTY ACID DESATURASE DEFICIENCY1 ( SFD1 ) and SFD2 genes are required for accumulation of the SAR-inducing activity. In contrast to Avr PeX from wild-type plants, Avr PeXs from fad7 , sfd1 and sfd2 mutants were unable to activate SAR when applied to wild-type plants. However, the SAR-inducing activity was reconstituted by mixing Avr PeXs collected from fad7 and sfd1 with Avr PeX from the SAR-deficient dir1 mutant. Since FAD7 , SFD1 and SFD2 are involved in plastid glycerolipid biosynthesis and SAR is also compromised in the Arabidopsis monogalactosyldiacylglycerol synthase1 mutant we suggest that a plastid glycerolipid-dependent factor is required in Avr PeX along with the DIR1- encoded lipid transfer protein for long-distance signaling in SAR. FAD7 -synthesized lipids provide fatty acids for synthesis of jasmonic acid (JA). However, co-infiltration of JA and methylJA with Avr PeX from fad7 and sfd1 did not reconstitute the SAR-inducing activity. In addition, JA did not co-purify with the SAR-inducing activity confirming that JA is not the mobile signal in SAR.     

Constitutive and induced resistance to pathogens in Arabidopsis thaliana depends on nitrogen supply

Knowledge about the induced pathogen resistance of plants is rapidly increasing, but little information exists on its dependence on abiotic growing conditions. Arabidopsis thaliana plants that had been cultivated under different nitrogen regimes were treated with BION^®, a chemical resistance elicitor. The activities of three enzyme classes functionally involved in resistance (chitinase, chitosanase and peroxidase) were quantified over 8 d following treatment as resistance markers. Constitutive levels of three markers and the induced level of peroxidase and chitinase activity were significantly lower under limiting nitrogen supply. Under such conditions the increase of chitosanase activity after resistance induction was severely delayed, although the induced maximum activity of chitosanase was not significantly affected. Total soluble protein content decreased during the first 12 h after resistance elicitation. Thereafter, the induced plants cultivated under high N conditions reached higher protein contents than controls, whereas N‐limited induced plants continuously had reduced protein contents. A plant's investment in resistance‐related compounds can be severely constrained under limiting nitrogen supply.     

Imprimatins A and B: Novel plant activators targeting salicylic acid metabolism in Arabidopsis thaliana

Plant activators are agrochemicals that protect plants from a broad range of pathogens by activating the plant immune system. Unlike pesticides, they do not target pathogens; therefore, plant activators provide durable effects that are not overcome by pathogenic microbes. Although certain plant activators have been applied to paddy fields for more than 30 years, the molecular basis of the underlying immune induction are unclear. From the screening of 10,000 diverse chemicals by a high-throughput screening procedure to identify compounds that specifically enhance pathogen-induced cell death in Arabidopsis cultured cells, we identified 7 compounds, which we designated as immune priming chemicals (Imprimatins). These compounds increased disease resistance against pathogenic Pseudomonas bacteria in Arabidopsis plants. Pretreatments increased the accumulation of endogenous salicylic acid (SA) but reduced its metabolite, SA-O-β-D-glucoside (SAG). Imprimatins inhibited the enzymatic activities of 2 SA glucosyltransferases (SAGTs) in vitro at concentrations effective for immune priming. Single and double knockout Arabidopsis plants for both SAGTs consistently exhibited enhanced disease resistance and SA accumulation. Our results demonstrate that the control of the free SA pool through SA-inactivating enzymes can be a useful methodology to confer disease resistance in plants. SAGTs can pave the way for target-based discovery of novel crop protectants.     

拟南芥NPR1基因的克隆与表达载体的构建

NPR1基因为植物抗病基因表达和系统获得性抗性中的一个关键基因。该文以DNA PCR扩增的方法,从拟南芥基因组DNA中克隆出NPR1基因,通过序列分析,所克隆的 NPR1 基因与报道的基因序列完全一致。将其构建成植物表达载体,为今后植物抗病基因工程的开展奠定了基础。     

Isolation and characterization of the plant immune-priming compounds Imprimatin B3 and -B4, potentiators of disease resistance in Arabidopsis thaliana

Plant activators are chemical crop protectants that fortify the immune system in plants. Unlike pesticides that target pathogens, plant activators provide durable effects against a broad spectrum of diseases, which have not been overcome by pathogenic microbes. Plant activators are not only useful agrochemicals, but can also help to elucidate the details of the plant immune system. Using an established high-throughput screening procedure, we previously identified 5 compounds, designated as Imprimatins, which prime plant immune response. These compounds increased disease resistance against pathogenic Pseudomonas bacteria in Arabidopsis plants by inhibiting 2 salicylic acid (SA) glucosyltransferases (SAGTs), resulting in accumulation of the phytohormone SA. Here, we report the isolation of 2 additional Imprimatins, B3 and B4, which are structurally similar to Imprimatin B1 and B2. Because these compounds did not have strong inhibitory effects on SAGTs in vitro, they may exert their function after metabolic conversion in vivo.