A novel ATPase gene, Ab-atps, plays an important role in the interaction of rice and white tip nematode, Aphelenchoides besseyi.

Plant kinases containing the LysM domain play important roles in pathogen recognition and self-defense reactions. And it could recognize microbe-associated molecules including chitin and other polypeptides. The white tip nematode Aphelenchoides besseyi is a migratory parasitic nematode that infects plant shoots. It is distributed over almost all rice-producing areas and causes up to 50% economic losses. The rice OsRLK3 gene was a defense-related LysM kinase gene of rice. This study showed that the rice LysM kinase OsRLK3 could be induced by flg22, jasmonic acid, salicylic acid, and chitin. An interaction gene, Ab-atps from A. besseyi, was identified by screening the interaction between the rice gene OsRLK3 and an A. besseyi cDNA library using yeast two-hybrid screening. Ab-atps is a novel ATP synthase gene with a full length of 1341 bp, coding for 183 amino acids. The mRNA of Ab-atps was located in the esophagus and reproductive system of A. besseyi. The expression of Ab-atps was assessed at different developmental stages of the nematode and found to be the highest in the juvenile, followed by the egg, female, and male. Reproduction was significantly decreased in nematodes treated with Ab-atps double-stranded RNA (dsRNA) (p < 0.05). Transient expression experiments showed that Ab-ATPS-GFP was distributed in the nucleus, cytoplasm, and cell membrane, and Ab-ATPS-GFP triggered plant cell death. OsRLK3 was expressed significantly higher at 0.5 day and 1 day (p < 0.05) in rice plants inoculated with nematodes treated with Ab-atps dsRNA and gfp dsRNA for 0.5-7 days, respectively. Further, OsRLK3 expression under Ab-atps dsRNA treatment was significantly lower than with gfp dsRNA treatment at 0.5 day (p < 0.05) and significantly higher than with gfp dsRNA treatment at 1 day (p < 0.05). These results suggest that rice OsRLK3 could interact with A. besseyi Ab-atps, which plays an important role in growth, reproduction, and infection of the nematode. Our findings provide a theoretical basis to further understand the parasitic strategy of A. besseyi and its interaction mechanism with host plants, suggesting new ideas and targets for controlling A. besseyi.

RNA-Seq revealed that infection with white tip nematodes could downregulate rice photosynthetic genes.

White-tip nematode, Aphelenchoides besseyi is a kind of widely distributed migratory parasitic nematode that can infect plant shoots. Transcriptome sequencing of plant parasitic nematodes and their host plants is helpful for understanding their interaction relationship. This study first reported expression patterns of defense-related genes in rice, and rice transcriptomes at different periods after infection with A. besseyi. The result showed that the defense response pathways of rice changed obviously in the early stage of A. besseyi infection, including upregulated salicylic acid and jasmonate pathways and a downregulated ethylene pathway. Transcriptome analysis results suggested that A. besseyi infection was associated with the downregulation of multiple genes related to photosynthesis with possible suppression of the photosynthetic activity. It suggested that the photosynthesis system of rice could be suppressed by infections of migratory nematodes, including A. besseyi and Hirschmanniella oryzae, but was stimulated by that of a sedentary nematode, Meloidogyne graminicola, by comparing our study with the reported transcriptome. OS09G0417800 (OsWRKY62) might play an important role in the interaction of migratory nematodes and rice. It also indicated that the infection strategy of both A. besseyi and the reported migratory nematode H. oryzae was similar to that of the fungal pathogen Magnaporthe grisea. These results provided an interesting starting point to elucidate the mechanism of the interaction between rice and A. besseyi, as well as the host and migratory plant nematodes.

Identification and Characterization of a Fatty Acid- and Retinoid-Binding Protein Gene (Ar-far-1) from the Chrysanthemum Foliar Nematode, Aphelenchoides ritzemabosi.

The chrysanthemum foliar nematode (CFN), Aphelenchoides ritzemabosi, is a migratory, plant-parasitic nematode that is widely distributed and infects the aboveground parts of many plants. The fatty acid- and retinoid-binding proteins (FAR) are nematode-specific proteins that are involved in the development, reproduction, and infection of nematodes and are secreted into the tissues to disrupt the plant defense reaction. In this study, we obtained the full-length sequence of the FAR gene (Ar-far-1) from CFN, which is 727 bp and includes a 546 bp ORF that encodes 181 amino acids. Ar-FAR-1 from CFN has the highest sequence similarity to Ab-FAR-1 from A. besseyi, and they are located within the same branch of the phylogenetic tree. Fluorescence-based ligand-binding analysis confirmed that recombinant Ar-FAR-1 was bound to fatty acids and retinol. Ar-far-1 mRNA was expressed in the muscle layer, intestine, female genital system, and egg of CFN, and more highly expressed in females than in males among the four developmental stages of CFN. We demonstrated that the reproduction number and infection capacity of CFN decreased significantly when Ar-far-1 was effectively silenced by in vitro RNAi. Ar-far-1 plays an important role in the development, reproduction, infectivity, and pathogenesis of CFN and may be used as an effective target gene for the control of CFN. The results provide meaningful data about the parasitic and pathogenic genes of CFN to study the interaction mechanism between plant-parasitic nematodes and hosts.

Molecular identification and functional characterization of the cathepsin B gene (Ab-cb-1) in the plant parasitic nematode Aphelenchoides besseyi.

The rice white tip nematode, Aphelenchoides besseyi, is widely distributed in rice planting areas worldwide and causes serious economic losses. Cathepsin genes have been demonstrated to have importance in studying the reproduction, development, pathogenicity, and control methods of plant nematodes. In this paper, a novel cathepsin B gene, Ab-cb-1, was found and cloned. The Ab-cb-1 gene was 1347 bp in length and encodes 369 amino acids. The Ab-CB-1 protein contains characteristic occluding loops but no signal peptide. A homology analysis showed that Ab-CB-1 had the highest identity value (64%) to the known amino acid sequence of cathepsin B-like cysteine protease 6 from Toxocara canis. When Ab-cb-1 was expressed in a prokaryotic system, the protein massed approximately 45 kDa and could decompose carrot callus. Ab-cb-1 mRNA was localized in the nematode intestine. The relative expression level of Ab-cb-1 in the A. besseyi Ab-S24 population, which had high reproductivity, was approximately 6.9 times that in the Ab-N10 population, which had low reproductivity, and the difference was significant (p<0.05). The Ab-cb-1 expression level was highest in females; the expression levels in males, juveniles and eggs were 30%, 12.2% and 5% of that in females, respectively, and the differences were significant among all four stages (p<0.05). Nematodes of the Ab-S24 population were treated with Ab-cb-1 dsRNA for 12 h, 24 h, 36 h and 48 h, and their reproduction decreased with increasing time. These results demonstrated that Ab-CB-1 was a digestive enzyme with hydrolytic protease properties and that Ab-cb-1 played an important role in the reproduction of A. besseyi.

Identification and function of FAR protein family genes from a transcriptome analysis of Aphelenchoides besseyi.

Motivation: The rice white tip nematode (RWTN) Aphelenchoides besseyi is a migratory plant parasitic nematode that infects the aboveground parts of plants. Fatty acid- and retinoid-binding (FAR) proteins are nematode-specific proteins that are involved in many important biological processes. Genes encoding FAR proteins have been identified in many species of nematodes, which indicated that nematodes may produce more than one type of FAR protein. The main goal of this study is to find new molecular targets including new far genes that will help control RWTN, and reduce the economic damage caused by RWTN. Results: Two RWTN populations with different levels of pathogenicity and reproduction were sequenced and analyzed with next-generation sequencing. 17 087 transcripts were annotated using six databases and 1696 differentially expressed genes (DEGs) were identified between the two RWTN populations. Seven new Ab-far genes were identified from the transcriptome data of the two RWTN populations which is the first to identify multiple far genes in plant parasitic nematodes. This study is the first to identify far genes in the nervous system of nematodes and the first to report a transcriptome sequencing analysis of different RWTN populations. The results help elucidate the genes related to parasitism and pathogenicity and also contribute to the identification of new target genes and development of new methods to control RWTN. Availability and implementation: Our data are publicly available at Sequence Read Archive (SRA) database and GenBank database. Supplementary information: Supplementary data are available at Bioinformatics online.