Objective 1: Generate functional EFR variants (EFR+) recognizing both elf18-Xac and elf18-CLas. Random mutagenesis of EFR ectodomain to gain elf18-CLas responsiveness did not produce gain-of-function mutants. Using chimeric elf18 peptides of wild-type and CLas sequences, we could determine that both the N- and C-terminal regions of elf18-CLas were responsible for the lack of recognition by EFR suggesting that elf18-CLas is impaired in both binding and activation. In order to identify complex EFR mutants that respond to elf18-CLas, we are developing a FACS-based screen. We fused promoters that are expressed at a low basal level and PAMP inducible to nuclear-localized GFP and tested by Agrobacterium-mediated transient expression in N. benthamiana and in Arabidopsis protoplasts. All constructs gave significant basal expression, which is presumably due to unrestricted expression in these transient systems. Therefore, it is necessary to produce transgenic lines of these reporter construct. Modelling of the EFR/elf18/BAK1 complex has been performed, based on the available FLS2/flg22/BAK1 structure. Sites have been selected for targeted mutagenesis to improve recognition of elf18-CLas. We have also examined the interaction with BAK1 and identified two regions which may be involved in elf18 binding. Mutagenesis constructs of these regions is currently being screened for elf18-CLas response. Objective 2. Generate functional XA21-EFR chimera (XA21-EFRchim) recognizing axYS22-Xac. Reciprocal XA21 and EFR chimeric receptors have been produced and transformed into Arabidopsis for functional testing. Since it is now known that axYS22-Xac is not the ligand of XA21, we tested the response of the EFR-XA21 chimera to elf18, in order to determine the function of the XA21 cytoplasmic domain in dicots. These constructs performed in a similar manner to wild-type EFR. In addition we tested XA21, EFR, XA21-EFR and EFR-XA21 for pathogen resistance to Pseudomonas syringae pv. tomato DC3000 COR-. Interestingly, all constructs provided an elevated level of resistance, indicating that the chimera of XA21-EFR was functional and that XA21 was capable of perceiving a potential ligand Pseudomonas. A manuscript describing this work is currently being prepared for submission to PNAS. Objective 3: Generate transgenic citrus plants expressing both EFR+ and XA21-EFRchim. Constructs including EFR alone or in combination with XA21 or XA21-EFR were provided to the Moore Lab for transformation. These were transformed into E.coli DH5. cells and Agrobacterium tumefaciens strain Agl1. Confirmation of clones was done using PCR (EFR and XA21 designed primers) and restriction analysis (NcoI and SpeI restriction enzymes). Initial transformation experiments have been carried out with a total of 100 ‘Pineapple’ sweet orange segments. Germination rate for sweet orange is 5%, which is extremely low. ‘Pineapple’ sweet orange and Duncan grapefruit seedlings are on germination media and transformation experiments will be initiated in May 2014.