Plant NB-LRR proteins confer robust protection against microbes and metazoan
parasites by recognizing pathogen-derived avirulence (Avr) proteins that are
delivered to the host cytoplasm. Microbial Avr proteins usually function as
virulence factors in compatible interactions; however, little is known about the
types of metazoan proteins recognized by NB-LRR proteins and their relationship
with virulence. In this report, we demonstrate that the secreted protein RBP-1
from the potato cyst nematode Globodera pallida elicits defense
responses, including cell death typical of a hypersensitive response (HR),
through the NB-LRR protein Gpa2. Gp-Rbp-1 variants from
G. pallida populations both virulent and avirulent to
Gpa2 demonstrated a high degree of polymorphism, with
positive selection detected at numerous sites. All Gp-RBP-1
protein variants from an avirulent population were recognized by Gpa2, whereas
virulent populations possessed Gp-RBP-1 protein variants both
recognized and non-recognized by Gpa2. Recognition of Gp-RBP-1
by Gpa2 correlated to a single amino acid polymorphism at position 187 in the
Gp-RBP-1 SPRY domain. Gp-RBP-1 expressed
from Potato virus X elicited Gpa2-mediated defenses that required Ran
GTPase-activating protein 2 (RanGAP2), a protein known to interact with the Gpa2
N terminus. Tethering RanGAP2 and Gp-RBP-1 variants via fusion
proteins resulted in an enhancement of Gpa2-mediated responses. However,
activation of Gpa2 was still dependent on the recognition specificity conferred
by amino acid 187 and the Gpa2 LRR domain. These results suggest a two-tiered
process wherein RanGAP2 mediates an initial interaction with pathogen-delivered
Gp-RBP-1 proteins but where the Gpa2 LRR determines which
of these interactions will be productive.
Plants have evolved a limited repertoire of NB-LRR disease resistance (R) genes to protect themselves against myriad pathogens. This limitation is thought to be counterbalanced by the rapid evolution of NB-LRR proteins, as only a few sequence changes have been shown to be sufficient to alter resistance specificities toward novel strains of a pathogen. However, little is known about the flexibility of NB-LRR R genes to switch resistance specificities between phylogenetically unrelated pathogens. To investigate this, we created domain swaps between the close homologs Gpa2 and Rx1, which confer resistance in potato (Solanum tuberosum) to the cyst nematode Globodera pallida and Potato virus X, respectively. The genetic fusion of the CC-NB-ARC of Gpa2 with the LRR of Rx1 (Gpa2 CN /Rx1 L ) results in autoactivity, but lowering the protein levels restored its specific activation response, including extreme resistance to Potato virus X in potato shoots. The reciprocal chimera (Rx1 CN /Gpa2 L ) shows a loss-of-function phenotype, but exchange of the first three LRRs of Gpa2 by the corresponding region of Rx1 was sufficient to regain a wild-type resistance response to G. pallida in the roots. These data demonstrate that exchanging the recognition moiety in the LRR is sufficient to convert extreme virus resistance in the leaves into mild nematode resistance in the roots, and vice versa. In addition, we show that the CC-NB-ARC can operate independently of the recognition specificities defined by the LRR domain, either aboveground or belowground. These data show the versatility of NB-LRR genes to generate resistance to unrelated pathogens with completely different lifestyles and routes of invasion.
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