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This work was supported by the Biotechnology and Biological Sciences Research Council (BBSRC) and The James Hutton Institute through a PhD studentship to SE-vdA. The James Hutton Institute receives funding from the Scottish Government Rural and Environment Science and Analytical Services division. SE-vdA is supported by BBSRC grant BB/M014207/1. ; Sedentary Plant-Parasitic Nematodes (PPNs) induce and maintain an intimate relationship with their host, stimulating cells adjacent to root vascular tissue to re-differentiate into unique and metabolically active "feeding sites". The interaction between PPNs and their host is mediated by nematode effectors. We describe the discovery of a large and diverse family of effector genes, encoding C-terminally Encoded Peptide (CEP) plant hormone mimics (RrCEPs), in the syncytia-forming plant-parasite Rotylenchulus reniformis. The particular attributes of RrCEPs distinguish them from all other CEPs, regardless of origin. Together with the distant phylogenetic relationship of R. reniformis to the only other CEP-encoding nematode genus identified to date (Meloidogyne), this suggests CEPs likely evolved de novo in R. reniformis. We have characterised the first member of this large gene family (RrCEP1), demonstrating its significant upregulation during the plant-nematode interaction and expression in the effector-producing pharyngeal gland cell. All internal CEP domains of multi-domain RrCEPs are followed by di-basic residues, suggesting a mechanism for cleavage. A synthetic peptide corresponding to RrCEP1 domain 1 is biologically active and capable of upregulating plant nitrate transporter (AtNRT2.1) expression, while simultaneously reducing primary root elongation. When a non-CEP containing, syncytia-forming PPN species (Heterodera schachtii) infects Arabidopsis in a CEP-rich environment a smaller feeding site is produced. We hypothesise that CEPs of R. reniformis represent a two-fold adaptation to sustained biotrophy in this species; 1) increasing host nitrate uptake while 2) limiting the size of the syncytial feeding site produced. ; Publisher PDF ; Peer reviewed

Somnath Pokhare was supported by a fellowship provided by the Indian Council of Agricultural Research (ICAR), Government of India. This work was also supported by Royal Society International Exchanges award number IE150670 and by the Rural and Environmental Science and Analytical Services Division of the Scottish Government. SEvdA is supported by Biotechnology and Biological Sciences Research Council grants BB/R011311/1 and BB/S006397/1. This work benefited from interactions funded through COST Action FA1208. The authors thank Dr Danny Coyne (IITA) for providing the starter culture of the H. sacchari population used for this work. Bioinformatics and Computational Biology analyses were supported by the University of St Andrews Bioinformatics Unit which is funded by a Wellcome Trust ISSF award [grant 105621/Z/14/Z]. ; Interactions between plant‐parasitic nematodes and their hosts are mediated by effectors, i.e. secreted proteins that manipulate the plant to the benefit of the pathogen. To understand the role of effectors in host adaptation in nematodes, we analysed the transcriptome of Heterodera sacchari , a cyst nematode parasite of rice (Oryza sativa ) and sugarcane (Saccharum officinarum ). A multi‐gene phylogenetic analysis showed that H. sacchari and the cereal cyst nematode Heterodera avenae share a common evolutionary origin and that they evolved to parasitise monocot plants from a common dicot‐parasitic ancestor. We compared the effector repertoires of H. sacchari with those of the dicot parasites Heterodera glycines and Globodera rostochiensis to understand the consequences of this transition. While, in general, effector repertoires are similar between the species, comparing effectors and non‐effectors of H. sacchari and G. rostochiensis shows that effectors have accumulated more mutations than non‐effectors. Although most effectors show conserved spatiotemporal expression profiles and likely function, some H. sacchari effectors are adapted to monocots. This is exemplified by the plant‐peptide hormone mimics, the CLAVATA3/EMBRYO SURROUNDING REGION‐like (CLE) effectors. Peptide hormones encoded by H. sacchari CLE effectors are more similar to those from rice than those from other plants, or those from other plant‐parasitic nematodes. We experimentally validated the functional significance of these observations by demonstrating that CLE peptides encoded by H. sacchari induce a short root phenotype in rice, whereas those from a related dicot parasite do not. These data provide a functional example of effector evolution that co‐occurred with the transition from a dicot‐parasitic to a monocot‐parasitic lifestyle. ; Publisher PDF ; Peer reviewed