Convergent loss of an EDS1/PAD4 signalling pathway in several plant lineages predicts new components of plant immunity and drought response

Baggs, EL; Thanki, AS; O’Grady, R; Schudoma, Christian; Haerty, Wilfried; Krasileva, Ksenia V.

doi:10.1101/572560

Cited by 5 publications

(4 citation statements)

References 129 publications

(105 reference statements)

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“…Conceivably, each subclade may have specialized downstream of a specific set of sensors, or alternatively, some strawberry, grapevine and/or lettuce RNLs have evolved a sensor function. Conversely, RNLs are absent in several different aquatic plant families, which correlates with absence of TNLs and the lipase-like EDS1, SAG101 and PAD4 proteins [49]. Furthermore, there is a strong indication of a co-evolved functional relationship specifically between TNLs, NRG1, and SAG101, as all three are absent from monocotyledon, and certain dicotyledon, genomes [3,17,49].…”

Section: Rnl Proteins Help Reveal How Helpers Helpmentioning

confidence: 99%

“…Conversely, RNLs are absent in several different aquatic plant families, which correlates with absence of TNLs and the lipase-like EDS1, SAG101 and PAD4 proteins [49]. Furthermore, there is a strong indication of a co-evolved functional relationship specifically between TNLs, NRG1, and SAG101, as all three are absent from monocotyledon, and certain dicotyledon, genomes [3,17,49]. This supports the hypothesis that RNLs play a role in EDS1/SAG101/PAD4 signaling downstream of TNL activation [50].…”

Section: Rnl Proteins Help Reveal How Helpers Helpmentioning

confidence: 99%

Plant NLRs get by with a little help from their friends

Feehan

Castel

Bentham

et al. 2020

Current Opinion in Plant Biology

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Many plant NLR (nucleotide binding, leucine-rich repeat) immune receptors require other NLRs for their function. In pairs of chromosomally adjacent sensor/helper NLRs, the sensor typically carries an integrated domain (ID) that mimics the authentic target of a pathogen effector. The RPW8-NLR clade supports the function of many diverse plant NLRs, particularly those with a TIR N-terminal domain, in concert with a family of EP-domain containing signaling partners. The NRC clade of NLRs is required for the function of many unlinked sensor NLRs in Solanaceous plants. We evaluate recent advances in paired NLR biology in the context of the structure and possible mechanisms of the first defined plant inflammasome containing ZAR1.

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“…Canonical TNLtype resistance genes are absent from all examined monocot genomes, as are the TIR-pathway mediators, SAG101 and NRG1 (Collier et al, 2011;Wagner et al, 2013). Remarkably, convergent loss of TNLs and downstream genes has occurred several times during plant evolution (Collier et al, 2011;Baggs et al, 2019). Monocots do, however, encode several TIR-NBS and TIR-only genes, although in low abundance relative to the high number of TNLs commonly present in dicots (Sun et al, 2014;Gao et al, 2018).…”

Section: Tir-proteins Across Plant Phylogeniesmentioning

confidence: 99%

“…While TNLs are absent from monocots (and several dicot lineages), they are present broadly across the plant phylogeny, including bryophytes and conifers (see also Figure 2C) (Baggs et al, 2019). For instance, the moss Physcomitrella patens carries TNL loci, as does the western white pine, Pinus monticola (Liu and Ekramoddoullah, 2011;Tanigaki et al, 2014).…”

Section: Tir-proteins Across Plant Phylogeniesmentioning

confidence: 99%

Enzymatic Functions for Toll/Interleukin-1 Receptor Domain Proteins in the Plant Immune System

Bayless

Nishimura

2020

Front. Genet.

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Rationally engineered improvements to crop plants will be needed to keep pace with increasing demands placed on agricultural systems by population growth and climate change. Engineering of plant immune systems provides an opportunity to increase yields by limiting losses to pathogens. Intracellular immune receptors are commonly used as agricultural disease resistance traits. Despite their importance, how intracellular immune receptors confer disease resistance is still unknown. One major class of immune receptors in dicots contains a Toll/Interleukin-1 Receptor (TIR) domain. The mechanisms of TIR-containing proteins during plant immunity have remained elusive. The TIR domain is an ancient module found in archaeal, bacterial and eukaryotic proteins. In animals, TIR domains serve a structural role by generating innate immune signaling complexes. The unusual animal TIR-protein, SARM1, was recently discovered to function instead as an enzyme that depletes cellular NAD + (nicotinamide adenine dinucleotide) to trigger axonal cell death. Two recent reports have found that plant TIR proteins also have the ability to cleave NAD +. This presents a new paradigm from which to consider how plant TIR immune receptors function. Here, we will review recent reports of the structure and function of TIR-domain containing proteins. Intriguingly, it appears that TIR proteins in all kingdoms may use similar enzymatic mechanisms in a variety of cell death and immune pathways. We will also discuss TIR structure-function hypotheses in light of the recent publication of the ZAR1 resistosome structure. Finally, we will explore the evolutionary context of plant TIR-containing proteins and their downstream signaling components across phylogenies and the functional implications of these findings.

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Convergent loss of an EDS1/PAD4 signalling pathway in several plant lineages predicts new components of plant immunity and drought response

Cited by 5 publications

References 129 publications

Plant NLRs get by with a little help from their friends

Enzymatic Functions for Toll/Interleukin-1 Receptor Domain Proteins in the Plant Immune System

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