Ensnaring microbes: the components of plant disease resistance

Hammond‐Kosack, K. E.; Jones, David A.; Jones, Jonathan D. G.

doi:10.1111/j.1469-8137.1996.tb04338.x

Cited by 17 publications

(11 citation statements)

References 178 publications

(129 reference statements)

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“…Generally, pathogen infection induces a complex series of biochemical and physiological changes that mediate resistance against a range of pathogens throughout the tissues of the plant (Dixon and Lamb, 1990; Fritig et al ., 1987; Hammond‐Kosack and Jones, 1996; Lamb et al ., 1989; Ryals et al ., 1994). One of the earliest detectable signs of the HR is a rapid oxidative burst that precedes the appearance of visible necrosis by several hours and plays an important role in regulating other aspects of the defense response (Dangl et al ., 1996; Dixon et al ., 1994; Hammond‐Kosack and Jones, 1996; Low and Merida, 1996; Mehdy, 1994). Reactive oxygen intermediates (ROIs) that may be generated by the action of a membrane‐bound NADPH oxidase complex (Desikan et al ., 1996) are produced in the area of tissue where the local necrotic lesion forms and accumulate within that region to levels that may have a direct toxic effect on the cells of the plant and the invading pathogen (Peng and Kuc, 1992).…”

Section: Discussionmentioning

confidence: 99%

“…A number of hypersensitive disease resistance systems has been studied and much progress has been made recently in characterizing R (resistance) genes and their cognate pathogen‐encoded avirulence genes (Bent, 1996; Boyes et al ., 1996; Dangl, 1995; Hammond‐Kosack et al ., 1996; Jones, 1996; Staskawicz et al ., 1995). Subsequent to recognition of the pathogen by the host, a complex series of biochemical and physiological changes is induced that mediates intercellular signaling, apoptosis in the vicinity of the infection sites, attack of the microbe directly, and establishment of a persistent state of heightened sensitivity and resistance against a range of pathogens throughout the tissues of the plant (Dixon and Lamb, 1990; Fritig et al ., 1987; Hammond‐Kosack and Jones, 1996; Lamb et al ., 1989; Ryals et al ., 1994).…”

Section: Introductionmentioning

confidence: 99%

“…Subsequent to recognition of the pathogen by the host, a complex series of biochemical and physiological changes is induced that mediates intercellular signaling, apoptosis in the vicinity of the infection sites, attack of the microbe directly, and establishment of a persistent state of heightened sensitivity and resistance against a range of pathogens throughout the tissues of the plant (Dixon and Lamb, 1990; Fritig et al ., 1987; Hammond‐Kosack and Jones, 1996; Lamb et al ., 1989; Ryals et al ., 1994). Many of the biochemical and physiological changes that take place during hypersensitive resistance (HR) have been well defined, and advances have begun to elucidate the signal‐transduction events that coordinate this form of plant defense (Dangl et al ., 1996; Dangl, 1995; Hammond‐Kosack and Jones, 1996; Jones, 1996; Lamb et al ., 1989; Lamb, 1994). Despite the high degree of pathogen specificity of R gene‐mediated pathogen recognition, the consequent HR appears to be very similar for a variety of host–pathogen interactions.…”

Section: Introductionmentioning

confidence: 99%

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Collateral gene expression changes induced by distinct plant viruses during the hypersensitive resistance reaction in Chenopodium amaranticolor

Cooper¹

2001

The Plant Journal

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SummaryHypersensitive reactions to plant diseases are typically mediated by R genes. Many R genes that have been cloned only confer resistance to a particular pathogen. However, Chenopodium spp. have multivirus hypersensitive resistance, thus making the understanding of this broad-spectrum resistance mechanism attractive. Using tobacco mosaic virus (TMV) tagged with green¯uorescent protein to follow infection over time, cDNA-AFLP to ®nd genes up-regulated during virus infection in C. amaranticolor and quantitative RT±PCR to accurately measure gene expression at different time points, the ®rst dissection of this signi®cant defense response pathway is presented. The detected diseaseexpressed sequences in C. amaranticolor (DESCA) are similar to those that encode p450 monooxegenases, hypersensitivity-related genes, cellulases, ABC transporters, receptor-like kinases, serine/threonine kinases, phosphoribosylanthranilate transferases and hypothetical R genes, many of which are associated with pathogen defense in other plants. The expressions of these DESCA genes are also induced by infection with the taxonomically distinct tobacco rattle virus (TRV) in C. amaranticolor. In particular, DESCA1, one of the gene fragments from C. amaranticolor that lacks similarity to any other sequence in the GenBank database, is induced at least 200 fold 4 d after infection (dai) by both TMV and TRV. The potential role of DESCA genes in a C. amaranticolor multivirus defense response with regard to their levels and time of gene expression is discussed.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Collateral gene expression changes induced by distinct plant viruses during the hypersensitive resistance reaction in Chenopodium amaranticolor

Cooper¹

2001

The Plant Journal

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“…The HR involves rapid necrosis of infected cells and concomitant production of reactive oxygen species (Bolwell, 1999). Production of an HR is also associated with induction of pathogenesis-related (PR) genes and various anti-microbial agents, lignification of the cell wall, alkalization of the apoplast, and activation of systemic-acquired resistance (SAR) (Hammond-Kosack et al, 1996). Recognition of bacterial effector molecules occurs within the plant cell by products of specific plant-derived genes known as resistance or R proteins.…”

Section: Introductionmentioning

confidence: 99%

Overexpression of the plasma membrane‐localized NDR1 protein results in enhanced bacterial disease resistance in Arabidopsis thaliana

et al. 2004

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Previous studies have established that mutations in the NDR1 gene in Arabidopsis thaliana suppress the resistance response of three resistance proteins, RPS2, RPM1, and RPS5, to Pseudomonas syringae pv. tomato (Pst) strain DC3000 containing the cognate effector genes, avrRpt2, avrRpm1, and avrpPhB, respectively. NDR1 is a plasma membrane (PM)-localized protein, and undergoes several post-translational modifications including carboxy-terminal processing and N-linked glycosylation. Expression of NDR1 under the NDR1 native promoter complements the ndr1-1 mutation, while overexpression of NDR1 results in enhanced resistance to virulent Pst. Sequence analysis and mass spectrometry suggest that NDR1 is localized to the PM via a C-terminal glycosylphosphatidyl-inositol (GPI) anchor. GPI modification would potentially place NDR1 on the outer surface of the PM, perhaps allowing NDR1 to act as a transducer of pathogen signals and/or interact directly with the pathogen.

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“…There is considerable interest also in the other RLK because they are thought to be involved in extracellular signal perception, in particular in plant development, plant/microbe interactions, and disease resistance phenomena (reviewed in Ref. 8).…”

Section: Animal Receptor Protein Kinases (Rpk)mentioning

confidence: 99%

Novel Type of Receptor-like Protein Kinase from a Higher Plant (Catharanthus roseus)

Schulze-Muth

Irmler

Schröder

et al. 1996

Journal of Biological Chemistry

112

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We characterize CrRLK1, a novel type of receptor-like kinase (RLK), from the plant Catharanthus roseus (Madagascar periwinkle). The protein (90.2 kDa) deduced from the complete genomic and cDNA sequences is a RLK by predicting a N-terminal signal peptide, a large extracytoplasmic domain, a membrane-spanning hydrophobic region followed by a transfer-stop signal, and a C-terminal cytoplasmic protein kinase with all 11 conserved subdomains. It is a novel RLK type because the predicted extracytoplasmic region shares no similarity with other RLKs. The autophosphorylation was investigated with affinity-purified proteins expressed in Escherichia coli. The activity was higher with Mn 2؉ than with Mg 2؉ and achieved half-maximal rates at 2-2.5 M ATP. The phosphorylation was predominantly on Thr, less on Ser, and not on Tyr. In contrast to other plant RLK, the kinase used an intra-rather than an intermolecular phosphorylation mechanism. After protein cleavage with formic acid, most of the radioactivity was in a 14.1-kDa peptide located at the end of the kinase domain. Mutagenesis of the four Thr residues in this peptide identified Thr-720 in the subdomain XI as important for autophosphorylation and for phosphorylation of ␤-casein. This Thr is conserved in other related kinases, suggesting a subfamily sharing common autophosphorylation mechanisms. Animal receptor protein kinases (RPK)1 located in the membranes play an important role in the perception and transmittance of external signals. All RPK contain an extracellular domain connected by a membrane-spanning amino acid (AA) stretch to the intracellular kinase domain. The proteins can be subdivided into two groups that autophosphorylate on Ser/Thr or on Tyr residues, and oligomerization appears to play an important role in the regulation of enzyme activity (1).Several plant cDNAs and genes for RPK homologs sharing the same basic domain structure have been described. They were called receptor-like kinases (RLK), because the ligands are unknown and their function as receptors has not yet been demonstrated. Several groups are presently distinguished, and the classification is usually based on the sequences in the extracellular domain (reviewed in Ref.2): (a) the S-domain type, with similarities to the S-locus glycoproteins in Brassica; these proteins also contain ten or more cysteines in conserved positions; (b) the leucine-rich repeat type, with 9 -26 Leu-rich repeats; and (c) the epidermal growth factor (EGF)-like type that contains several EGF-like repeats. Very recent data suggest two additional types, with the extracellular region related either to plant defense proteins (3) or to lectins (4), but the investigations have not been extended much beyond the sequences. The physiological functions of plant RLKs are unknown, except for the S-domain type RLKs from Brassica that appear to be involved in the self-incompatibility phenotype (5-7).

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Ensnaring microbes: the components of plant disease resistance

Cited by 17 publications

References 178 publications

Collateral gene expression changes induced by distinct plant viruses during the hypersensitive resistance reaction in Chenopodium amaranticolor

Collateral gene expression changes induced by distinct plant viruses during the hypersensitive resistance reaction in Chenopodium amaranticolor

Overexpression of the plasma membrane‐localized NDR1 protein results in enhanced bacterial disease resistance in Arabidopsis thaliana

Novel Type of Receptor-like Protein Kinase from a Higher Plant (Catharanthus roseus)

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