Abstract
Plant resistance proteins (R-proteins) are key components of the plant immune system activated in response to a plethora of different pathogens. R-proteins are P-loop NTPase superfamily members, and current models describe their main function as ATPases in defense signaling pathways. Here we show that a subset of R-proteins have evolved a new function to combat pathogen infection. This subset of R-proteins possesses a nucleotide phosphatase activity in the nucleotide-binding domain. Related R-proteins that fall in the same phylogenetic clade all show the same nucleotide phosphatase activity indicating a conserved function within at least a subset of R-proteins. R-protein nucleotide phosphatases catalyze the production of nucleoside from nucleotide with the nucleotide monophosphate as the preferred substrate. Mutation of conserved catalytic residues substantially reduced activity consistent with the biochemistry of P-loop NTPases. Kinetic analysis, analytical gel filtration, and chemical cross-linking demonstrated that the nucleotide-binding domain was active as a multimer. Nuclear magnetic resonance and nucleotide analogues identified the terminal phosphate bond as the target of a reaction that utilized a metal-mediated nucleophilic attack by water on the phosphoester. In conclusion, we have identified a group of R-proteins with a unique function. This biochemical activity appears to have co-evolved with plants in signaling pathways designed to resist pathogen attack.
Highlights
Plant resistance proteins are molecular switches that respond to plant pathogens
We describe the first report of the production of key R-protein switch domains as soluble and active homogenous recombinant proteins. We use these proteins as tools to demonstrate a new, and unexpected, biochemical activity in the NBD of plant R-proteins, a nucleotide phosphatase activity that might have co-evolved with land plants to integrate into signaling pathways that protect plants from pathogen invasion
We investigated the expression of the NB-ARC domains of Pollen Signaling Protein (PSiP) and the teins and enable us to investigate whether the nucleotide phosphatase activity of R1-NB is present in other R-proteins
Summary
Plant resistance proteins are molecular switches that respond to plant pathogens. Results: A subset of resistance proteins has a nucleotide phosphatase activity. We have identified a group of R-proteins with a unique function This biochemical activity appears to have co-evolved with plants in signaling pathways designed to resist pathogen attack. We describe the first report of the production of key R-protein switch domains as soluble and active homogenous recombinant proteins We use these proteins as tools to demonstrate a new, and unexpected, biochemical activity in the NBD of plant R-proteins, a nucleotide phosphatase activity that might have co-evolved with land plants to integrate into signaling pathways that protect plants from pathogen invasion. Current research supports the role of the NBD of NB-ARC proteins as an NTPase activated through a structural switch In it quiescent state, the pro-apoptotic mammalian Apaf-1 protein binds (d)ATP but on activation by cytochrome c hydrolyzes the nucleotide to (d)ADP. This finding demonstrates that the potential signaling mechanisms available to R-proteins could be more diverse than previously suspected
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