The genome of the migratory nematode, Radopholus similis, reveals signatures of close association to the sedentary cyst nematodes
Authors:
Reny Mathew aff001; Charles H. Opperman aff001
Authors place of work:
Department of Entomology and Plant Pathology, North Carolina State University, Raleigh, NC United States of America
aff001
Published in the journal:
PLoS ONE 14(10)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0224391
Summary
Radopholus similis, commonly known as the burrowing nematode, is an important pest of myriad crops and ornamentals including banana (Musa spp.) and Citrus spp. In order to characterize the potential role of putative effectors encoded by R. similis genes we compared predicted proteins from a draft R. similis genome with other plant-parasitic nematodes in order to define the suite of excreted/secreted proteins that enable it to function as a parasite and to ascertain the phylogenetic position of R. similis in the Tylenchida order. Identification and analysis of candidate genes encoding for key plant cell-wall degrading enzymes including GH5 cellulases, PL3 pectate lyases and GH28 polygalactouranase revealed a pattern of occurrence similar to other PPNs, although with closest phylogenetic associations to the sedentary cyst nematodes. We also observed the absence of a suite of effectors essential for feeding site formation in the cyst nematodes. Clustering of various orthologous genes shared by R. similis with other nematodes showed higher overlap with the cyst nematodes than with the root-knot or other migratory endoparasitic nematodes. The data presented here support the hypothesis that R. similis is evolutionarily closer to the cyst nematodes, however, differences in the effector repertoire delineate ancient divergence of parasitism, probably as a consequence of niche specialization. These similarities and differences further underscore distinct evolutionary relationships during the evolution of parasitism in this group of nematodes.
Keywords:
Plant pathology – Phylogenetic analysis – Nematoda – Signal peptides – Bananas – Cellulases – Chaperone proteins – Lyases
Introduction
Global crop loss caused by plant-parasitic nematodes approaches ~$100 billion annually [1]. Based upon their unique life cycles there exists two main categories of plant parasitic nematodes: ectoparasites and endoparasites. The endoparasites are further classified into two broad groups based on their feeding mechanisms, specifically, sedentary endoparasites and migratory endoparasites. The two most economically important sedentary endoparasitic nematodes are the root knot nematodes Meloidogyne spp., and the cyst nematodes belonging to the Heterodera and Globodera spp. Of these, genome and transcriptome sequences of several cyst nematodes, such as the soybean cyst nematode H. glycines [2,3] and the potato cyst nematodes, G. pallida, G. ellingtonae and G. rostochiensis. [4–6] exist in the public domain. Additionally, genomes/transcriptomes of numerous root-knot nematodes, including M. hapla [7], M. incognita, M. javanica, M. arenaria [8,9], M. graminicola [10] M. floridensis [11] and M. enterolobii [12] have been exploited to reveal important determinants of plant parasitism by sedentary endoparasitic nematodes. These nematodes form specialized feeding sites in plant roots via different mechanisms, known as giant-cells in root-knot species and syncytia in cyst nematode species [13]. Also, more recently, the draft genome of the sedentary semi-endoparasitic nematode species, R. reniformis has also been released in the public domain [14].
Unlike the sedentary endoparasitic RKN and cyst nematodes and the semi-endoparasitic, R. reniformis the burrowing nematode Radopholus similis is a migratory endoparasite. Radopholus is a member of the Pratylenchidae family, which have not been shown to form specialized feeding sites. Although the currently known host range of R. similis extends to more than 365 plant species [15], R. similis is an economically significant parasite of Musa spp. worldwide [16], and also causes significant damage to Citrus spp., coconut, palm, coffee, sugarcane, avocado, black pepper, foliage ornamentals of the family (Philodendron, Anthurium, Hibiscus) and ginger (Zingiberacieae). Additionally, bananas and plantains (Musa sp.) are consumed by ~400 million people worldwide and the export industry for these crops serves as a crucial mode of income for people living in many countries, including Colombia, Ecuador, Costa Rica and the Philippines [17].
R. similis was first identified in 1893, in the banana growing areas in Fiji islands [18] and since then has reached multiple continents, most likely on infested plant material. Characterization of R. similis populations from multiple regions worldwide indicated that R. similis radiation is a relatively recent event, occurring within the past 200–300 years [19–21]. R. similis thrives in the tropical and the sub-tropical regions around the world including east Africa, south and central America, parts of Asia, Australia and multiple regions in Europe. In the United States, R. similis is found in Florida, Texas and the islands of Hawaii & Puerto Rico [22]. R. similis is a sexually dimorphic PPN. Males and females can be classified by the unique sexual dimorphism that exists in their cephalic region, and this trait also supports the hypothesis that R. similis is closely related to the cyst nematodes, belonging to the ‘Hoplolaimidae’ family [23,24]. R. similis males are generally 500–600 μm long and possess a raised lip, a feature not shared by the females [25]. Males are more slender than females and possess a degenerate stylet, accounting for their non-feeding nature. Additionally, males possess a characteristic curved spicule near the tail end and a prominent bursa. On the contrary, females possess a distinctive stylet approximately 16–21 μm long with three knobs. R. similis females are generally 550–800 μm long ending with a unique hyalinated tail region. R. similis reproduces as a facultative hermaphrodite, although out crossing occurs preferentially when males are present [26].
The life cycle of R. similis is completed in 18–20 days at a temperature range of 25–30°C, however populations in Europe seem to undergo reproduction even at lower temperatures [23]. Eggs are laid as the females migrate through the root system and females can lay up to 4–5 eggs a day for several weeks. R. similis juveniles and females are parasitic, with the juveniles feeding outside the root system occasionally. The intercellular migration and feeding by these vermiform nematodes cause significant cell damage, which leads to the characteristic reddish-brown lesions associated with these nematodes. Additionally, damage caused by the tunneling and feeding activities, leaves the root system wounded and susceptible to opportunistic bacteria or fungi that may enter the plant through the wounded site.
The major underground symptoms of an R. similis infection seen in a banana plant is the characteristic necrotic lesions on the roots, that results in weakened root systems and reduced plant growth due to poor uptake of nutrients and water. This ultimately leads to toppling of banana plants especially during heavy rains and storm conditions and is a major concern among growers in the banana growing areas. Currently a variety of practices such as hot water and/or nematicidal treatment of the corms and suckers of banana plants, guying and propping of fallen banana plants [27] to hold them in place and even resistant cultivars have been developed to combat this parasite. Resistant cultivars of Musa spp. such as the Yangambi Km5 and Pisang Jari Buaya(AAA) have been very successful in reducing nematode populations [28] in major banana growing regions in Africa. The resistance in these cultivars has been shown to be mediated by the deposition of phenalenone-type phytoalexins at nematode infected sites [17]. However, these cultivars do not seem to be successful in managing R. similis populations infecting Musa spp. in Uganda, which has been attributed to pathogenicity variability between R. similis populations [28]. Furthermore, multiple biological agents utilized to control R. similis on bananas such as the “mutualistic endophyte Fusarium oxysporum strain 162” and the “antagonistic bacteria Bacillus firmus” have shown efficacy under controlled conditions; however, the protection they offer is generally limited to a single growing season[17,29]. Management strategies utilizing nematicides are restricted, both by cost and by regulations due to toxicity concerns for non-target organisms (including humans) as well as environmental and ground water impacts.
The genome sequence of R. similis may provide insights into the variety of mechanisms adopted by this pathogen to maintain a plant-parasitic lifestyle. In order to characterize the potential role of putative PPN effectors, including plant cell-wall degrading enzymes, encoded by R. similis genes we compared predicted proteins from our draft R. similis genome [30] with other plant-parasitic nematodes in order to define the suite of excreted/secreted proteins that enable it to function as a parasite and occupy new niches; and secondly, to ascertain the phylogenetic position of R. similis in the Tylenchida order. Small Subunit ribosomal DNA (SSU rDNA) studies have placed R. similis as a sister taxon of the endoparasitic cyst nematodes [24,31,32]. Using our predicted protein set, we performed phylogenetic analyses of orthologous clusters shared with the cyst nematodes G. rostochiensis, G. pallida, H. glycines, the root-knot nematodes M. hapla, M. incognita, the migratory endoparasite D. destructor and the free-living nematode C. elegans. We were able to corroborate the SSU rDNA phylogenetic studies that R. similis is indeed a sister-taxon to the cyst nematodes. In this article, we present key parasitism/effector features of R. similis and its phylogenetic position in comparison with several nematodes exhibiting different lifestyles.
Results and discussion
Parasitism gene repertoire and effectors
PPN effectors are secreted when the PPNs penetrate the host tissues with their spear-like stylet. Most of these effectors are produced primarily in the two subventral and one dorsal gland at different stages of parasitism and play an important role during a nematode-plant interaction. Over the years, many R. similis effectors and parasitism genes have been reported including β-1,4 endoglucanase [33], endoxylanases [34], transthyretin-like proteins [35] serine carboxypeptidase [36–38] cathepsin-B [38,39] and calreticulin [37]. We mined our predicted protein sequences in search for these known parasitism genes and found that the R. similis predicted protein set possesses all the known parasitism PPN proteins (Table B in S1 File). Additionally, R. similis protein sequences were scanned for putative signal peptides using SignalP. Based on this search, 1548 protein sequences were identified which had putative signal peptides. However, only 1405 protein sequences out of the 1548 SignalP identified candidates did not possess a transmembrane domain.
To obtain the effector repertoire encoded by R. similis, we extracted sequences coding for ~100 effectors from a diverse array of nematodes including the root-knot nematodes such as M. hapla, M. incognita and cyst nematodes like G. rostochiensis, H. avenae, G. pallida etc. (Table B in S1 File). We noted that R. similis does not possess any homologues of the CLAVATA3/ENDOSPERM SURROUNDING REGION(ESR), (CLE)—like peptides present in the cyst nematodes such as G. tabacum, G. rostochiensis and G. virginiae, which has been proven to be a required component to achieve development of a syncytium in host tissues [40]. Although we identified twelve genes predicted to encode for SPRY (SP1a and RYanodine receptor) domains, these putative SPRY-containing proteins lack a secretion signal, which is an essential requirement for the protein to be classified as a SPRYSEC ‘effector’. The presence of proteins with SPRY domains has been confirmed in the R. similis transcriptome analysis as well [41]. Within PPNs, proteins with SPRY domains and a secretion signal (SPRYSECs) have only been found in cyst nematodes and have been shown to be involved in suppressing and eliciting defense response in the host plants[42]. This absence of SPRYSEC effectors is consistent with R. similis not forming elaborate feeding sites in roots. However, effectors associated with host defense induction such as venom allergen- like effector proteins (VAPs) and suppression such as calreticulin (3) were present in R. similis [43,44] and one of these predicted calreticulins also possesses an ER-retention signals. Within PPNs, calreticulin has been extracted from the gland secretions of the root-knot nematode, M. incognita and the migratory PPN, B. xylophilus, where it has been shown to be involved in host defense suppression and reproduction respectively [43,45]. Homologues of genes involved in protection against host-derived oxidative stresses such as superoxide dismutase, peroxiredoxin, glutathione-S-transferase and glutathione-peroxidase were also found in R. similis (Table 1).Homologues of the S-phase kinase-associated protein, involved in ubiquitination pathways as well as the FAR-1/SEC-2, involved in the circumvention of host defense were also identified in R. similis [46,47]. R. similis also possesses a gene coding for a putative secreted chorismate mutase (with ~51% similarity), which is a key enzyme involved in modification of the host salicylic acid pathway [48]. A variety of proteases found in a broad spectrum of nematodes (irrespective of lifestyle) such as serine carboxypeptidase, cathepsin S, B and L were also identified in R. similis (Table B in S1 File). No homologues of the putative apoplastic effector 4D06 or the putative parasitic stage effector 30C02 or the plant peptide hormone mimic C-terminally Encoded Peptide (CEP) was found in the R. similis predicted protein set, further underscoring the lifestyle difference between a sedentary and a migratory PPN (see Table 1).
Carbohydrate-Active enzymes (CAZymes)
CAZymes comprise of enzyme families that are involved in the degradation, synthesis and/or remodeling of carbohydrates and their conjugates. CAZymes were searched in the CAZy database, dbCAN database and the peptide pattern recognition (PPR) library to look for homologues of proteins encoding putative CAZymes in the predicted protein set of R. similis. Generally, CAZymes are divided into five broad classes based on their mode of action namely glycosyl hydrolase (GH), glycosyl transferase (GT), carbohydrate esterase (CE), polysaccharide lyase (PL) and auxillary activity (AA). GHs are enzymes that accelerate the degradation of glycosidic bond between carbohydrates and/or non-carbohydrates. GHs are found across a wide gamut of organisms including bacteria, plants, fungi and nematodes [49]. Within PPNs, GHs perform a range of functions, primarily, breakdown of plant cell walls which is made up of cellulose, xylans, arabinans and pectins, which can aid in increased movement through host cells. Additionally, GHs are also involved in the breakdown of simple and complex carbohydrates such as glucose and sucrose, which can be utilized as potential sources of nutrition by a PPN. The putative GHs in R. similis belong to multiple families, notably, GH5 (cellulase), and GH28 (polygalactouranase) (Table A in S1 File). In the R. similis genome, certain GHs such as GH5(cellulase) have carbohydrate binding modules (CBM) such as CBM2 appended. Cellulases from the root-knot nematode M. incognita and the cyst nematode, G. pallida also possess an appended CBM2 domain. In the sugar beet cyst nematode, H. schachtii, a secreted protein with a CBM domain, was demonstrated to directly interact with an Arabidopsis pectin methylesterase, thereby implicating it in facilitating nematode parasitism [50].
R. similis encodes ten putative cellulase genes belonging to the GH5 family, subfamily 2 Phylogenetic analyses demonstrated that the R. similis GH5 proteins are distributed in four distinct clades, of which three are clustered and each is closely related to the cyst nematodes belonging to the Heterodera and Globodera genus (Fig 1). This result supports the previous SSU rDNA studies, which determined that R. similis is evolutionarily closer to cyst nematodes than to root knot nematodes [24]. Moreover, in one of the clades we observed that R. similis shares a sister relationship with Rotylenchulus reniformis, a semi-endoparasitic nematode that serves as a potential intermediary between the migratory parasite, R. similis and the sedentary parasite, H. glycines. Multiple effector studies and a recent phylogenetic study by Holterman et al. [32] have supported a common ancestry hypothesis between the semi-endoparasitic reniform nematode belonging to the Rotylenchulidae family and the endoparasitic cyst nematodes of the Heteroderidae family [32,51]. This particular observation also corroborates previous findings as well as the hypothesis put forth by van Megen et al. [32,52] that “members of the genus Radopholus could be relatively closely related to the common ancestor of the Hoplolaimidae and Heteroderidae”[24,32,52]. It can also be noted that three R. similis proteins shows possible sister relationships with other PPNs besides the cyst nematodes. However, the bootstrap support value is less than 50% and hence its’ not considered as a significant association. GH5 cellulases have been shown to be conserved in diverse clade 12 nematodes including the root-knot and cyst nematodes, the family Pratylenchidae and the genus Radopholus and have been hypothesized to be acquired from a common ancestral gene via HGT from bacteria [53]. Additionally, we analyzed the presence/absence of N-terminal signal peptides in these putative cellulases and found that nine out of the ten cellulases possess a signal peptide with no transmembrane domain. The putative subcellular localization patterns of these cellulases were predicted based on protein sequence information using DeepLoc [54]. DeepLoc predicted nine of these ten putative cellulase proteins to be ‘soluble’ and to be ‘extracellularly’ secreted (Table C in S1 File). Following this, we compared the predicted localization pattern of this protein with the localization of a known cellulase gene from a PPN (in this case H. glycines) and found the predicted localization likelihood patterns to be extracellular (S3 Fig). No cellulases belonging to the GH45 family were predicted in the R. similis protein set during our analysis, supporting the evidence of independent origins (bacterial and fungal) of cellulases in most PPNs [53,55].
A single gene coding for a putative polygalactouranase, belonging to the GH28 family has also been found in R. similis. Polygalactouranase is required for the breakdown of galactouronic acid, which is an essential monomer that makes up pectin. GH28 polygalactouranase has also been found in the transcriptome of R. similis by Huang et al. [41]. A BLAST analysis of this gene against the NCBI nr database indicates that the sequence is homologous to the GH28 gene of the bacterial soil-borne pathogen Ralstonia solanacearum. Intriguingly, R. solanacearum is a xylem colonising pathogen and R. similis has been reported to block xylem vessels which might imply that these functions might have been a characterisic of niche specialization. Furthermore, within plant-parasitic nematodes, GH28 genes acquired from bacteria have been found in root-knot nematode M. hapla, M. incognita and the family Pratylenchidae. Notably, polygalactouranase from RKNs as well as the false root-knot nematode, Nacobbus aberrans also demonstrates high sequence similarity with the R. solanacearum GH28 protein [9,31,56]. Significantly, the semi-endoparasitic nematode, R. reniformis also possesses GH28s, but the GH28 in R. reniformis appears to be non-functional. Because GH28 does appear to be functional in R. similis, this finding supports the hypothesis of early gain in the last common ancestor of root knot and cyst, and subsequent loss in the cyst nematodes [31].
Eight genes encoding for putative polysaccharide lyases (PL) have been predicted in R. similis. These genes belong to five families, namely PL1, PL3, PL5, PL9 and PL22. R. similis possesses four putative PL3 (pectate lyase) proteins, fewer than other PPNs in clade 12 such as M. hapla (20), M. incognita (33), H. glycines (15), G. pallida (8) and the clade 10 PPN B. xylophilus (15) (Table A in S1 File). Pectate lyase catalyze the breakdown and degradation of pectins, which is an important component of plant cell wall, in addition to hemicellulose and cellulose [57]. In addition to cellulase, pectate lyase induce softening of plant tissues, which in turn aids in movement and feeding of the nematode. Pectate lyases along with cellulases and a host of other secretory proteins are released into the plant cell during infection and feeding by the nematode. SignalP was used to search for signal peptides in these PL3 sequences in order to categorize these proteins as ‘secretory’. We found that only three of the putative PL3 proteins show presence of conserved signal peptide sequences in their N-terminal, (Table D in S1 File) and they do not possess a transmembrane domain. Pectate lyases have also been used to study phylogenetic associations in sedentary and migratory endoparasitic nematodes [58,59]. We performed phylogenetic analysis on the four PL3s and found a pattern similar to the GH5 cellulase phylogenetic tree (S1 Fig). However, the putative PL3s received a lower bootstrap support value when compared with most GH5 cellulases. The R. similis PL3s are clustered into a monophyletic clade and share a common ancestor with the cyst nematodes belonging to the Globodera and Heterodera genus Additionally, the branch length leading to the cyst nematodes from the common ancestor is relatively longer when compared with the branch length leading to the R. similis PL3s. This might indicate higher divergence and increased substitutions per site relative to the ancestor as well as R. similis.
Phylogenetic analysis of orthologous genes
Plant-parasitic nematodes occur in clade 1 (Triplonchida), clade 2 (Dorylaimida), clade 10 (Aphelencoididae) and clade 12 (Tylenchida) of the 12 clades comprising the phylum Nematoda. In a phylogenetic tree presented by Holterman et al., 2017 [32], disparate gene loss and gain events in parasitic abilities are seen among nematode lineages. We identified orthologous gene clusters shared by R. similis with other nematodes such as plant-parasitic, human-parasitic and free-living. R. similis forms a total of 8542 orthologous clusters and 5115 singletons. All the species combined, shared a total of 3690 orthologous clusters (Fig 2). We observed that R. similis shares higher number of orthologous clusters with the cyst nematode G. rostochiensis (4034), compared to the root-knot nematode M. hapla (3911), the free-living nematode C. elegans (3726), the migratory endoparasitic nematode D. destructor (3785) and the human parasitic nematode B. malayi (3723).
Additionally, alignments of 1630 orthologs for eight different species specifically R. similis, G. pallida, G. rostochiensis, H. glycines, M. incognita M. hapla, D. destructor and C. elegans was performed to gain insight into the phylogenetic relationships shared by R. similis. The resulting species tree corroborates the existing hypothesis, that, R. similis is indeed a sister taxon to the cyst nematodes (G. rostochiensis, G. pallida and H. glycines) and thereby share the latest common ancestor with the cyst nematodes than with the root-knot nematodes, M. hapla and M. incognita or the migratory endoparasite D. destructor (Fig 3). [24,60].
Conclusion
Our study confirms the close association between R. similis and the cyst nematodes specifically that R. similis and the cyst nematodes share the latest common ancestor. In multiple analysis that we have performed, including phylogenetic analysis of single-copy orthologs, analysis of secreted proteins such as cellulase, pectate lyase as well as the housekeeping gpd gene, R. similis appears as a sister taxon of the cyst nematodes (see Fig 1, Fig 2, S2 Fig and S3 Fig), reinforcing previous findings [24]. Additionally, our data conforms well with the transcriptome analysis by Huang et al. [41], specifically, the absence of putative cyst nematode genes that code for CLE-like peptides and the presence of the GH28 gene as a significant indicator. Our findings reveal a basic set of effectors for a non-feeding site forming migratory endoparasitic nematode and further support early evolutionary relationships to the Hoplolaimidae and Heteroderidae.
Transitioning from a migratory lifestyle to a sedentary one has been a giant leap in the evolution of plant-parasitic nematodes and an important milestone in achieving an intimate host-parasite interaction. Sedentary endoparasitism has been proposed to have evolved independently through five separate pathways in clade 12 of the phylum Nematoda [32]. Additionally, even within the sedentary endoparasitic nematodes, the cyst and root-knots, have few parallels in their feeding site development or their effector suite, indicating further disparate origins [61]. When this divergence occurred in the evolutionary transition is unclear. Perhaps the more intriguing question is why and what underlying evolutionary forces were in play that compelled a PPN to transition from a migratory to a sedentary lifestyle or possess distinct arsenals for establishing a sedentary lifestyle. Future work which analyzes R. similis genomes and the genomes of numerous sedentary endoparasitic nematodes from different geographical locations and ecological niches can provide further insight into these evolutionary patterns. Additionally, functional characterization studies of key effectors common between R. similis, the cyst nematodes and the semi-endoparasitic R. reniformis, could provide tell-tale signatures regarding the evolution of endoparasitism in plant-parasitic nematodes. With these data, we hope to further the understanding of the complex multipartite parasitism mechanisms that makes R. similis an economically important pathogen.
Materials and methods
Gene prediction
Gene prediction was performed using the MAKER v.2.31.8 pipeline [62] in three rounds. For the gene predictions, 7,382 R. similis ESTs were extracted from the NCBI EST database, following which the ESTs were used as evidence to make gene predictions for the genome along with an in-house built protein set constructed from the proteins of closely related nematodes downloaded from wormbase parasite and proteins from the uniprot-swissprot database. These evidence-based predictions were then integrated with ab-initio predictions performed by SNAP and AUGUSTUS to obtain a more robust and complete set of gene predictions. Finally, the gene predictions with Annotation edit distance (AED) values less than 1 were extracted using a custom perl script.
CAZyme
R. similis protein sequences were blasted against CAZy database [49] (using Diamond), dbCAN database (using HMMER) and Peptide pattern recognition (PPR) (using hotpep) to search for putative CAZymes in the R. similis proteome (34,55). The E value used was 1e-5. dbCAN2 was utilized to perform this job[63] Hits returned in at least two databases were considered as valid candidates. For annotation of the CBM moieties attached with the GHs, hits returned from DIAMOND were considered. Data for the other nematodes were from [64]. However, the genome papers of the corresponding nematodes and pertinent literature was also reviewed to ensure accuracy while reporting.
For annotating the expansins in R. similis predicted protein set, known expansin proteins sequences of plant-parasitic nematodes were downloaded from NCBI. Following this, the downloaded protein dataset was used to create a database for Blastp. Radopholus predicted protein set was used as query against this database. The E-value used was 1e-5. The data for expansins for the other nematodes were taken from [41].
Phylogenetic analysis of secreted proteins and gpd
A position specific iterative (PSI) blastp analysis of relevant genes was done against the NCBI nr database (nematoda) with an E- value of 1e-5. A blastp analysis was also performed on wormbase parasite with an e-value of 1e-5. The relevant hits were extracted, following which the sequences were aligned using MUSCLE [65] (Gap open penalty -2.90, Gap extend penalty 0.00 and hydrophobicity multiplier1.20). The cluster method selected was UPGMA. The aligned sequences were then concatenated and utilized to construct a tree using the maximum likelihood statistical method using the best-fit substitution model estimated using MEGA X [66]. Site coverage was set to be 95% with partial deletion of gaps/missing data. Resampling was performed using bootstrap analysis of 1000 replicates. For the gpd gene, C. elegans gpd genes were used as query to conduct a blastp against the R. similis protein database. Genes that returned hits with an E-value = 0.0 were used to query NCBI or wormbase.
Signal peptide and localization pattern prediction
Signal peptides and transmembrane domains in the protein sequences were predicted using SignalP4.1 [67]. The localization pattern of proteins sequences were predicted using the DeepLoc server [54] with the ‘Eukaryote’ option selected.
Phylogenetic analysis using orthologs
For constructing the venn diagram OrthoMCL [68] was utilized to identify orthologous clusters. An all against all blastp was performed with an E value of 1e-5 and the inflation value of 1.5 to balance sensitivity and selectivity of clusters. Orthovenn [69] was utilized to construct venn diagrams using orthologous clusters. Genome and protein sequences for other nematodes were downloaded from wormbase parasite [70,71].
For constructing the species tree, protein sequences of R. similis and eight other nematodes such as Globodera pallida, Globodera rostochiensis, Heterodera glycines, Meloidogyne incognita, Meloidogyne hapla, Ditylenchus destructor and Caenorhabditis elegans were analyzed by OrthoFinder [72]. Alignments was generated using MUSCLE [65] in Orthofinder. The MUSCLE generated alignments were concatenated and the species tree was constructed X[66] with the Maximum-likelihood statistical best fit method (LG+G model) estimated using MEGA X with 1000 bootstrap replications. All positions with less than 95% site coverage were eliminated. That is, fewer than 5% alignment gaps, missing data, and ambiguous bases were allowed at any position … The free-living nematode C. elegans was used as an outgroup.
NCBI accession number
The Whole genome shotgun (WGS) has been deposited in NCBI under the accession number SJFO00000000 and BioProject PRJNA522283.
Supporting information
S1 Fig [tif]
Phylogenetic analysis of . pectate lyase 3.
S2 Fig [tif]
Phylogenetic analysis of . gpd gene.
S3 Fig [a]
Localization pattern of cellulase sequences.
Zdroje
1. Coyne DL, Cortada L, Dalzell JJ, Claudius-Cole AO, Haukeland S, Luambano N, et al. Plant-Parasitic Nematodes and Food Security in Sub-Saharan Africa. Annual review of phytopathology. 2018;56: 381–403. doi: 10.1146/annurev-phyto-080417-045833 29958072
2. Gardner M, Dhroso A, Johnson N, Davis EL, Baum TJ, Korkin D, et al. Novel global effector mining from the transcriptome of early life stages of the soybean cyst nematode Heterodera glycines. Scientific reports. 2018;8: 2505. doi: 10.1038/s41598-018-20536-5 29410430
3. Masonbrink R, Maier TR, Muppirala U, Seetharam AS, Lord E, Juvale PS, et al. The genome of the soybean cyst nematode (Heterodera glycines) reveals complex patterns of duplications involved in the evolution of parasitism genes. BMC genomics. 2019;20: 119. doi: 10.1186/s12864-019-5485-8 30732586
4. Cotton JA, Lilley CJ, Jones LM, Kikuchi T, Reid AJ, Thorpe P, et al. The genome and life-stage specific transcriptomes of Globodera pallida elucidate key aspects of plant parasitism by a cyst nematode. Genome biology. 2014;15: R43. doi: 10.1186/gb-2014-15-3-r43 24580726
5. Eves-van den Akker S, Laetsch DR, Thorpe P, Lilley CJ, Danchin EG, Da Rocha M, et al. The genome of the yellow potato cyst nematode, Globodera rostochiensis, reveals insights into the basis of parasitism and virulence. Genome biology. 2016;17: 124. doi: 10.1186/s13059-016-0985-1 27286965
6. Phillips WS, Howe DK, Brown AM, Eves-Van Den Akker S, Dettwyler L, Peetz AB, et al. The draft genome of Globodera ellingtonae. Journal of nematology. 2017;49: 127. 28706309
7. Opperman CH, Bird DM, Williamson VM, Rokhsar DS, Burke M, Cohn J, et al. Sequence and genetic map of Meloidogyne hapla: A compact nematode genome for plant parasitism. Proceedings of the National Academy of Sciences. 2008;105: 14802–14807.
8. Blanc-Mathieu R, Perfus-Barbeoch L, Aury J-M, Da Rocha M, Gouzy J, Sallet E, et al. Hybridization and polyploidy enable genomic plasticity without sex in the most devastating plant-parasitic nematodes. PLoS genetics. 2017;13: e1006777. doi: 10.1371/journal.pgen.1006777 28594822
9. Abad P, Gouzy J, Aury J-M, Castagnone-Sereno P, Danchin EG, Deleury E, et al. Genome sequence of the metazoan plant-parasitic nematode Meloidogyne incognita. Nature biotechnology. 2008;26: 909. doi: 10.1038/nbt.1482 18660804
10. Somvanshi VS, Tathode M, Shukla RN, Rao U. Nematode Genome Announcement: A Draft Genome for Rice Root-Knot Nematode, Meloidogyne graminicola. Journal of nematology. 2018;50: 111–116. doi: 10.21307/jofnem-2018-018 30451432
11. Lunt DH, Kumar S, Koutsovoulos G, Blaxter ML. The complex hybrid origins of the root knot nematodes revealed through comparative genomics. PeerJ. 2014;2: e356. doi: 10.7717/peerj.356 24860695
12. Koutsovoulos GD, Poullet M, El Ashry A, Kozlowski DK, Sallet E, Da Rocha M, et al. The polyploid genome of the mitotic parthenogenetic root-knot nematode Meloidogyne enterolobii. BioRxiv. 2019; 586818.
13. Mitchum MG, Hussey RS, Baum TJ, Wang X, Elling AA, Wubben M, et al. Nematode effector proteins: an emerging paradigm of parasitism. New Phytologist. 2013;199: 879–894. doi: 10.1111/nph.12323 23691972
14. Showmaker KC, Sanders WS, den Akker Eves-van S, Martin BE, Stokes JV, Hsu CY, et al. A genomic resource for the sedentary semi-endoparasitic reniform nematode, Rotylenchulus reniformis Linford & Oliveira. Journal of nematology. 2019;51: 1–2.
15. Moens M, Perry RN. Migratory plant endoparasitic nematodes: a group rich in contrasts and divergence. Annual Review of Phytopathology. 2009;47: 313–332. doi: 10.1146/annurev-phyto-080508-081846 19400647
16. Dochez C, Dusabe J, Whyte J, Tenkouano A, Ortiz R, De Waele D. New sources of resistance to Radopholus similis in Musa germplasm from Asia. Australasian Plant Pathology. 2006;35: 481–485.
17. Hölscher D, Dhakshinamoorthy S, Alexandrov T, Becker M, Bretschneider T, Buerkert A, et al. Phenalenone-type phytoalexins mediate resistance of banana plants (Musa spp.) to the burrowing nematode Radopholus similis. Proceedings of the National Academy of Sciences. 2014;111: 105–110.
18. Cobb NA. Nematodes, mostly Australian and Fijian. F. Cunninghame & Company, printers; 1893.
19. Marin DH, Sutton TB, Barker KR. Dissemination of Bananas in Latin America and the Caribbean and Its Relationship to the Occurrence of Radophouls similis. Plant disease. 1998;82: 964–974. doi: 10.1094/PDIS.1998.82.9.964 30856847
20. Marin DH, Kaplan DT, Opperman CH. Randomly amplified polymorphic DNA differs with burrowing nematode collection site, but not with host range. Journal of nematology. 1999;31: 232. 19270894
21. Kaplan DT, Opperman CH. Reproductive strategies and karyotype of the burrowing nematode, Radopholus similis. Journal of Nematology. 2000;32: 126. 19270958
22. Ferris H. Radopholus similis. 11 Apr 2018 [cited 28 Sep 2018]. Available: http://nemaplex.ucdavis.edu/Taxadata/G111s2.aspx
23. Haegeman A, Elsen A, De Waele D, Gheysen G. Emerging molecular knowledge on Radopholus similis, an important nematode pest of banana. Molecular plant pathology. 2010;11: 315–323. doi: 10.1111/j.1364-3703.2010.00614.x 20447280
24. Holterman M, Karssen G, Van Den Elsen S, Van Megen H, Bakker J, Helder J. Small subunit rDNA-based phylogeny of the Tylenchida sheds light on relationships among some high-impact plant-parasitic nematodes and the evolution of plant feeding. Phytopathology. 2009;99: 227–235. doi: 10.1094/PHYTO-99-3-0227 19203274
25. Sekora, S. Nicholas and Crow, William. burrowing nematode- Radopholus similis. Oct 2012 [cited 28 Sep 2018]. Available: http://entnemdept.ufl.edu/creatures/NEMATODE/Radopholus_similis.htm
26. Huettel RN, Dickson DW. Parthenogenesis in the Two Races of Radopholus similis from Florida. Journal of nematology. 1981;13: 13. 19300714
27. Sarah JL, Pinochet J, Stanton J. The burrowing nematode of bananas, Radopholus similis Cobb, 1913. Musa Pest Fact Sheet (INIBAP); Parasites et Ravageurs des Musa: Fiche Technique (INIBAP); Plagas de Musa: Hoja Divulgativa (INIBAP). 1996.
28. Plowright R, Dusabe J, Coyne D, Speijer P. Analysis of the pathogenic variability and genetic diversity of the plant-parasitic nematode Radopholus similis on bananas. Nematology. 2013;15: 41–56.
29. Mendoza AR, Sikora RA. Biological control of Radopholus similis in banana by combined application of the mutualistic endophyte Fusarium oxysporum strain 162, the egg pathogen Paecilomyces lilacinus strain 251 and the antagonistic bacteria Bacillus firmus. Biocontrol. 2009;54: 263–272.
30. Mathew R, Burke M, Opperman CH. A draft genome of the burrowing nematode Radopholus similis. Journal of Nematology. 2019;51.
31. Eves-van den Akker S, Lilley CJ, Danchin EGJ, Rancurel C, Cock PJA, Urwin PE, et al. The Transcriptome of Nacobbus aberrans Reveals Insights into the Evolution of Sedentary Endoparasitism in Plant-Parasitic Nematodes. Genome Biol Evol. 2014;6: 2181–2194. doi: 10.1093/gbe/evu171 25123114
32. Holterman M, Karegar A, Mooijman P, van Megen H, van den Elsen S, Vervoort MT, et al. Disparate gain and loss of parasitic abilities among nematode lineages. PLoS One. 2017;12: e0185445. doi: 10.1371/journal.pone.0185445 28934343
33. Haegeman A, Jacob J, Vanholme B, Kyndt T, Gheysen G. A family of GHF5 endo‐1, 4‐beta‐glucanases in the migratory plant‐parasitic nematode Radopholus similis. Plant Pathology. 2008;57: 581–590.
34. Haegeman A, Vanholme B, Gheysen G. Characterization of a putative endoxylanase in the migratory plant‐parasitic nematode Radopholus similis. Molecular Plant Pathology. 2009;10: 389–401. doi: 10.1111/j.1364-3703.2009.00539.x 19400841
35. Jacob J, Vanholme B, Haegeman A, Gheysen G. Four transthyretin-like genes of the migratory plant-parasitic nematode Radopholus similis: members of an extensive nematode-specific family. Gene. 2007;402: 9–19. doi: 10.1016/j.gene.2007.07.015 17765408
36. Huang X, Xu C-L, Chen W-Z, Chen C, Xie H. Cloning and characterization of the first serine carboxypeptidase from a plant parasitic nematode, Radopholus similis. Scientific reports. 2017;7: 4815. doi: 10.1038/s41598-017-05093-7 28684768
37. Li Y, Wang K, Xie H, Wang Y-T, Wang D-W, Xu C-L, et al. A nematode calreticulin, Rs-CRT, is a key effector in reproduction and pathogenicity of Radopholus similis. PLoS One. 2015;10: e0129351. doi: 10.1371/journal.pone.0129351 26061142
38. Wang K, Li Y, Huang X, Wang D, Xu C, Xie H. The cathepsin S cysteine proteinase of the burrowing nematode Radopholus similis is essential for the reproduction and invasion. Cell & bioscience. 2016;6: 39.
39. Li Y, Wang K, Xie H, Wang D-W, Xu C-L, Huang X, et al. Cathepsin B cysteine proteinase is essential for the development and pathogenesis of the plant parasitic nematode Radopholus similis. International journal of biological sciences. 2015;11: 1073. doi: 10.7150/ijbs.12065 26221074
40. Replogle A, Wang J, Bleckmann A, Hussey RS, Baum TJ, Sawa S, et al. Nematode CLE signaling in Arabidopsis requires CLAVATA2 and CORYNE. The Plant Journal. 2011;65: 430–440. doi: 10.1111/j.1365-313X.2010.04433.x 21265896
41. Huang X, Xu C-L, Yang S-H, Li J-Y, Wang H-L, Zhang Z-X, et al. Life-stage specific transcriptomes of a migratory endoparasitic plant nematode, Radopholus similis elucidate a different parasitic and life strategy of plant parasitic nematodes. Scientific reports. 2019;9: 6277. doi: 10.1038/s41598-019-42724-7 31000750
42. Moffett P, Ali S, Magne M, Chen S, Obradovic N, Jamshaid L, et al. Analysis of Globodera rostochiensis effectors reveals conserved functions of SPRYSEC proteins in suppressing and eliciting plant immune responses. Frontiers in plant science. 2015;6: 623. doi: 10.3389/fpls.2015.00623 26322064
43. Jaouannet M, Magliano M, Arguel MJ, Gourgues M, Evangelisti E, Abad P, et al. The root-knot nematode calreticulin Mi-CRT is a key effector in plant defense suppression. Molecular Plant-Microbe Interactions. 2013;26: 97–105. doi: 10.1094/MPMI-05-12-0130-R 22857385
44. Lozano-Torres JL, Wilbers RH, Warmerdam S, Finkers-Tomczak A, Diaz-Granados A, van Schaik CC, et al. Apoplastic venom allergen-like proteins of cyst nematodes modulate the activation of basal plant innate immunity by cell surface receptors. PLoS pathogens. 2014;10: e1004569. doi: 10.1371/journal.ppat.1004569 25500833
45. Li X, Zhuo K, Luo M, Sun L, Liao J. Molecular cloning and characterization of a calreticulin cDNA from the pinewood nematode Bursaphelenchus xylophilus. Experimental parasitology. 2011;128: 121–126. doi: 10.1016/j.exppara.2011.02.017 21371475
46. Gao B, Allen R, Maier T, Davis EL, Baum TJ, Hussey RS. The parasitome of the phytonematode Heterodera glycines. Molecular Plant-Microbe Interactions. 2003;16: 720–726. doi: 10.1094/MPMI.2003.16.8.720 12906116
47. Prior A, Jones JT, BEAUCHAMP J, McDERMOTT L, COOPER A, KENNEDY MW. A surface-associated retinol-and fatty acid-binding protein (Gp-FAR-1) from the potato cyst nematode Globodera pallida: lipid binding activities, structural analysis and expression pattern. Biochemical Journal. 2001;356: 387–394. doi: 10.1042/0264-6021:3560387 11368765
48. Wang X, Xue B, Dai J, Qin X, Liu L, Chi Y, et al. A novel Meloidogyne incognita chorismate mutase effector suppresses plant immunity by manipulating the salicylic acid pathway and functions mainly during the early stages of nematode parasitism. Plant pathology. 2018;67: 1436–1448.
49. Cantarel BL, Coutinho PM, Rancurel C, Bernard T, Lombard V, Henrissat B. The Carbohydrate-Active EnZymes database (CAZy): an expert resource for glycogenomics. Nucleic acids research. 2008;37: D233–D238. doi: 10.1093/nar/gkn663 18838391
50. Hewezi T, Howe P, Maier TR, Hussey RS, Mitchum MG, Davis EL, et al. Cellulose binding protein from the parasitic nematode Heterodera schachtii interacts with Arabidopsis pectin methylesterase: cooperative cell wall modification during parasitism. The Plant Cell. 2008;20: 3080–3093. doi: 10.1105/tpc.108.063065 19001564
51. Wubben MJ, Ganji S, Callahan FE. Identification and molecular characterization of a β-1, 4-endoglucanase gene (Rr-eng-1) from Rotylenchulus reniformis. Journal of nematology. 2010;42: 342. 22736868
52. van den Elsen S, Holovachov O, Karssen G, van Megen H, Helder J, Bongers T, et al. A phylogenetic tree of nematodes based on about 1200 full-length small subunit ribosomal DNA sequences. Nematology. 2009;11: 927–950.
53. Haegeman A, Jones JT, Danchin EG. Horizontal gene transfer in nematodes: a catalyst for plant parasitism? Molecular Plant-Microbe Interactions. 2011;24: 879–887. doi: 10.1094/MPMI-03-11-0055 21539433
54. Almagro Armenteros JJ, Sønderby CK, Sønderby SK, Nielsen H, Winther O. DeepLoc: prediction of protein subcellular localization using deep learning. Bioinformatics. 2017;33: 3387–3395. doi: 10.1093/bioinformatics/btx431 29036616
55. Kikuchi T, Cock PJ, Helder J, Jones JT. Characterisation of the transcriptome of Aphelenchoides besseyi and identification of a GHF 45 cellulase. Nematology. 2014;16: 99–107.
56. Rehman S, Gupta VK, Goyal AK. Identification and functional analysis of secreted effectors from phytoparasitic nematodes. BMC microbiology. 2016;16: 48. doi: 10.1186/s12866-016-0632-8 27001199
57. Kikuchi T, Shibuya H, Aikawa T, Jones JT. Cloning and characterization of pectate lyases expressed in the esophageal gland of the pine wood nematode Bursaphelenchus xylophilus. Molecular plant-microbe interactions. 2006;19: 280–287. doi: 10.1094/MPMI-19-0280 16570658
58. Opperman CH, Bird DM, Williamson VM, Rokhsar DS, Burke M, Cohn J, et al. Sequence and genetic map of Meloidogyne hapla: A compact nematode genome for plant parasitism. Proceedings of the National Academy of Sciences. 2008.
59. Burke M, Scholl EH, Bird DM, Schaff JE, Colman SD, Crowell R, et al. The plant parasite Pratylenchus coffeaecarries a minimal nematode genome. Nematology. 2015;17: 621–637.
60. Zheng J, Peng D, Chen L, Liu H, Chen F, Xu M, et al. The Ditylenchus destructor genome provides new insights into the evolution of plant parasitic nematodes. Proc R Soc B. 2016;283: 20160942. doi: 10.1098/rspb.2016.0942 27466450
61. Lilley CJ, Maqbool A, Wu D, Yusup HB, Jones LM, Birch PR, et al. Effector gene birth in plant parasitic nematodes: Neofunctionalization of a housekeeping glutathione synthetase gene. PLoS genetics. 2018;14: e1007310. doi: 10.1371/journal.pgen.1007310 29641602
62. Cantarel BL, Korf I, Robb SM, Parra G, Ross E, Moore B, et al. MAKER: an easy-to-use annotation pipeline designed for emerging model organism genomes. Genome research. 2008;18: 188–196. doi: 10.1101/gr.6743907 18025269
63. Zhang H, Yohe T, Huang L, Entwistle S, Wu P, Yang Z, et al. dbCAN2: a meta server for automated carbohydrate-active enzyme annotation. Nucleic Acids Res. 2018;46: W95–W101. doi: 10.1093/nar/gky418 29771380
64. Li X, Yang D, Niu J, Zhao J, Jian H. De novo analysis of the transcriptome of Meloidogyne enterolobii to uncover potential target genes for biological control. International journal of molecular sciences. 2016;17: 1442.
65. Edgar RC. MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic acids research. 2004;32: 1792–1797. doi: 10.1093/nar/gkh340 15034147
66. Kumar S, Stecher G, Li M, Knyaz C, Tamura K. MEGA X: Molecular Evolutionary Genetics Analysis across Computing Platforms. Molecular biology and evolution. 2018;35: 1547–1549. doi: 10.1093/molbev/msy096 29722887
67. Nielsen H. Predicting secretory proteins with SignalP. Protein Function Prediction: Methods and Protocols. 2017; 59–73.
68. Li L, Stoeckert CJ, Roos DS. OrthoMCL: identification of ortholog groups for eukaryotic genomes. Genome research. 2003;13: 2178–2189. doi: 10.1101/gr.1224503 12952885
69. Wang Y, Coleman-Derr D, Chen G, Gu YQ. OrthoVenn: a web server for genome wide comparison and annotation of orthologous clusters across multiple species. Nucleic acids research. 2015;43: W78–W84. doi: 10.1093/nar/gkv487 25964301
70. Howe KL, Bolt BJ, Cain S, Chan J, Chen WJ, Davis P, et al. WormBase 2016: expanding to enable helminth genomic research. Nucleic acids research. 2015;44: D774–D780. doi: 10.1093/nar/gkv1217 26578572
71. Howe KL, Bolt BJ, Shafie M, Kersey P, Berriman M. WormBase ParaSite− a comprehensive resource for helminth genomics. Molecular and biochemical parasitology. 2017;215: 2–10. doi: 10.1016/j.molbiopara.2016.11.005 27899279
72. Emms DM, Kelly S. OrthoFinder: solving fundamental biases in whole genome comparisons dramatically improves orthogroup inference accuracy. Genome biology. 2015;16: 157. doi: 10.1186/s13059-015-0721-2 26243257
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