Variation in DNA methylation enables plants to inherit traits independently of changes to DNA sequence. Here, we have screened an
population of epigenetic recombinant inbred lines (epiRILs) for ...resistance against
. These lines share the same genetic background, but show variation in heritable patterns of DNA methylation. We identified four epigenetic quantitative trait loci (epiQTLs) that provide quantitative resistance without reducing plant growth or resistance to other (a)biotic stresses. Phenotypic characterisation and RNA-sequencing analysis revealed that
resistant epiRILs are primed to activate defence responses at the relatively early stages of infection. Collectively, our results show that hypomethylation at selected pericentromeric regions is sufficient to provide quantitative disease resistance, which is associated with genome-wide priming of defence-related genes. Based on comparisons of global gene expression and DNA methylation between the wild-type and resistant epiRILs, we discuss mechanisms by which the pericentromeric epiQTLs could regulate the defence-related transcriptome.
Anthracnose is a destructive disease that affects a wide range of crop plants especially in tropical and subtropical regions. Colletotrichum spp. are the major pathogens causing anthracnose. In this ...study, we collected and identified the pathogen from diseased samples of Stylosanthes, a major tropical forage crop. The ability of the pathogen to naturally infect Arabidopsis thaliana was examined. Sequence analysis of ITS, ACT, CHS, and GAPDH genes showed the pathogen to be Colletotrichum gloeosporioides sensu lato (s.l.), and this was supported further by morphological characterization of representative isolates. The disease symptoms and cellular infection process of aggressive isolates (DZ‐19 and HK‐04) and a weak isolate (CJ‐04) were compared. DZ‐19 and HK‐04 caused more severe disease symptoms on both young seedlings and adult plants of Col‐0 and Ws‐2 ecotypes compared to CJ‐04. Furthermore, the more aggressive isolates showed faster and earlier germination of conidia, formation of appressoria, and growth and development of hyphae during the infection. Genetic analysis of the defence response and expression profiling of defence marker genes demonstrated the involvement of MAP kinase, Ca2+‐dependent protein kinase, salicylic acid, ethylene, and jasmonic acid pathways in the resistance against anthracnose. These results suggest that the Arabidopsis–Colletotrichum gloeosporioides pathosystem should provide a valuable tool for exploring the resistance mechanisms against this pathogen.
A pathosystem between Arabidopsis and C. gloeosporioides sensu lato from Stylosanthes has been established, which could be an effective tool for studying the resistance mechanisms of anthracnose.
Plant‐unique membrane receptor kinases with leucine‐rich repeat (LRR) extracellular domains are key regulators of development and immune responses. Here, the 1.55 Å resolution crystal structure of ...the immune receptor kinase SOBIR1 from Arabidopsis is presented. The ectodomain structure reveals the presence of five LRRs sandwiched between noncanonical capping domains. The disulfide‐bond‐stabilized N‐terminal cap harbours an unusual β‐hairpin structure. The C‐terminal cap features a highly positively charged linear motif which was found to be largely disordered in this structure. Size‐exclusion chromatography and right‐angle light‐scattering experiments suggest that SOBIR1 is a monomer in solution. The protruding β‐hairpin, a set of highly conserved basic residues at the inner surface of the SOBIR LRR domain and the presence of a genetic missense allele in LRR2 together suggest that the SOBIR1 ectodomain may mediate protein–protein interaction in plant immune signalling.
The ectodomain structure of a novel plant membrane receptor kinase with unusual capping domains is reported.
This chapter aims to review the current status of induced disease resistance signalling research. It mainly focuses on the roles of salicylic acid (SA) and jasmonic acid (JA) in the signalling ...cascades involved in the different types of induced resistance. The chapter covers two important topics in induced resistance research namely pathway crosstalk and priming. The role of JAs and ethylene (ET) in the regulation of plant growth promoting rhizobacteria (PGPR) ‐ and plant growth promoting fungi (PGPF) ‐ triggered systemic defence responses has been mainly established through the analysis of JA ‐ and ET ‐ signalling mutants. However, colonization of the roots by induced systemic resistance (ISR) ‐ inducing PGPR is often not associated with an increase in the production of these hormones. Hormonal crosstalk is thought to equip the plant with a powerful regulatory capacity to finely tune its immune response to the attacker that is encountered.
Plants deploy a sophisticated immune system to cope with different microbial pathogens and other invaders. Recent research provides an increasing body of evidence for papain-like cysteine proteases ...(PLCPs) being central hubs in plant immunity. PLCPs are required for full resistance of plants to various pathogens. At the same time, PLCPs are targeted by secreted pathogen effectors to suppress immune responses. Consequently, they are subject to a co-evolutionary host–pathogen arms race. When activated, PLCPs induce a broad spectrum of defense responses including plant cell death. While the important role of PLCPs in plant immunity has become more evident, it remains largely elusive how these enzymes are activated and which signaling pathways are triggered to orchestrate different downstream responses.
Since signaling machineries for two modes of plant‐induced immunity, pattern‐triggered immunity (PTI) and effector‐triggered immunity (ETI), extensively overlap, PTI and ETI signaling likely ...interact. In an Arabidopsis quadruple mutant, in which four major sectors of the signaling network, jasmonate, ethylene, PAD4, and salicylate, are disabled, the hypersensitive response (HR) typical of ETI is abolished when the Pseudomonas syringae effector AvrRpt2 is bacterially delivered but is intact when AvrRpt2 is directly expressed in planta. These observations led us to discovery of a network‐buffered signaling mechanism that mediates HR signaling and is strongly inhibited by PTI signaling. We named this mechanism the ETI‐Mediating and PTI‐Inhibited Sector (EMPIS). The signaling kinetics of EMPIS explain apparently different plant genetic requirements for ETI triggered by different effectors without postulating different signaling machineries. The properties of EMPIS suggest that information about efficacy of the early immune response is fed back to the immune signaling network, modulating its activity and limiting the fitness cost of unnecessary immune responses.
Synopsis
A systems‐based analysis reveals crosstalk between pattern‐ and effector‐triggered plant immunity that enables modification of immune responses based on efficacy of early immune responses.
The plant immune signaling network contains a signaling sector that mediates effector‐triggered immunity (ETI) and is inhibited by pattern‐triggered immunity (PTI).
This signaling mechanism is named ETI‐mediating and PTI‐inhibited sector, or EMPIS.
EMPIS mediates ETI in a compensatory manner with other signaling sectors.
Differences in the timing of ETI and PTI signals reaching EMPIS determine qualitative differences in EMPIS requirements for ETI response triggered by different pathogen effectors.
A systems‐based analysis reveals crosstalk between pattern‐ and effector‐triggered plant immunity that enables modification of immune responses based on efficacy of early immune responses.
Nicotinamide adenine dinucleotide (NAD
) participates in intracellular and extracellular signaling events unrelated to metabolism. In animals, purinergic receptors are required for extracellular NAD
...(eNAD
) to evoke biological responses, indicating that eNAD
may be sensed by cell-surface receptors. However, the identity of eNAD
-binding receptors still remains elusive. Here, we identify a lectin receptor kinase (LecRK), LecRK-I.8, as a potential eNAD
receptor in
. The extracellular lectin domain of LecRK-I.8 binds NAD
with a dissociation constant of 436.5 ± 104.8 nM, although much higher concentrations are needed to trigger in vivo responses. Mutations in
inhibit NAD
-induced immune responses, whereas overexpression of
enhances the
response to NAD
. Furthermore,
is required for basal resistance against bacterial pathogens, substantiating a role for eNAD
in plant immunity. Our results demonstrate that lectin receptors can potentially function as eNAD
-binding receptors and provide direct evidence for eNAD
being an endogenous signaling molecule in plants.
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