Transcriptome analysis of a nematode resistant and susceptible upland cotton line at two critical stages of Meloidogyne incognita infection and development
Authors:
Pawan Kumar aff001; Sameer Khanal aff001; Mychele Da Silva aff002; Rippy Singh aff001; Richard F. Davis aff002; Robert L. Nichols aff004; Peng W. Chee aff001
Authors place of work:
Dept. of Crop and Soil Sciences and Institute of Plant Breeding, Genetics, and Genomics, University of Georgia, Tifton, GA, United States of America
aff001; Department of Plant Pathology, University of Georgia, Tifton, GA, United States of America
aff002; USDA-ARS, Crop Protection and Management Research Unit, Tifton, GA, United States of America
aff003; Cotton Incorporated, Cary, NC, United States of America
aff004
Published in the journal:
PLoS ONE 14(9)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0221328
Summary
Host plant resistance is the most practical approach to control the Southern root-knot nematode (Meloidogyne incognita; RKN), which has emerged as one of the most serious economic pests of Upland cotton (Gossypium hirsutum L.). Previous QTL analyses have identified a resistance locus on chromosome 11 (qMi-C11) affecting galling and another locus on chromosome-14 (qMi-C14) affecting egg production. Although these two QTL regions were fine mapped and candidate genes identified, expression profiling of genes would assist in further narrowing the list of candidate genes in the QTL regions. We applied the comparative transcriptomic approach to compare expression profiles of genes between RKN susceptible and resistance genotypes at an early stage of RKN development that coincides with the establishment of a feeding site and at the late stage of RKN development that coincides with RKN egg production. Sequencing of cDNA libraries produced over 315 million reads of which 240 million reads (76%) were mapped on to the Gossypium hirsutum genome. A total of 3,789 differentially expressed genes (DEGs) were identified which were further grouped into four clusters based on their expression profiles. A large number of DEGs were found to be down regulated in the susceptible genotype at the late stage of RKN development whereas several genes were up regulated in the resistant genotype. Key enriched categories included transcription factor activity, defense response, response to phyto-hormones, cell wall organization, and protein serine/threonine kinase activity. Our results also show that the DEGs in the resistant genotype at qMi-C11 and qMi-C14 loci displayed higher expression of defense response, detoxification and callose deposition genes, than the DEGs in the susceptible genotype.
Keywords:
Biology and life sciences – Genetics – Gene expression – Genomics – Genome analysis – Biochemistry – Organisms – Eukaryota – Plants – Computational biology – proteins – DNA-binding proteins – Genetic loci – Quantitative trait loci – Gene regulation – Medicine and health sciences – Transcription factors – Regulatory proteins – Parasitic diseases – Transcriptome analysis – Flowering plants – Cotton – Nematode infections
Introduction
The genus Meloidogyne includes nearly 100 species, but four species–M. incognita, M. arenaria, M. javanica and M. hapla–account for approximately 95% of the total crop area infested by this genus. The Southern root-knot nematode (Meloidogyne incognita, RKN) is a sedentary endoparasitic nematode that penetrates plant roots as second-stage juveniles (J2s) and transforms multiple host cells into highly metabolically active ‘giant cells’ on which they feed to complete their life cycle. Formation of giant cells are initiated by the delivery of RKN ‘effectors’ into the host cells where they modulate plant signal transduction pathways resulting in multiple cycles of DNA replication followed by nuclear division without cytokinesis. Root tissues surrounding these giant cells undergo swelling resulting in gall formation, which can severely obstruct water and nutrient uptake in the infected plants leading to wilting, stunted growth, and reduced yields. Host plants respond to invading RKNs through a series of defense mechanisms by coordinating different signaling pathways. Host plants recognize pathogen-associated molecular patterns (PAMPs) derived from the pathogen by utilizing pattern recognition receptors (PRRs) that induce pattern-triggered immunity (PTI) or effector-triggered immunity (ETI) [1]. Expression of large numbers of downstream genes is triggered to regulate resistance-related pathways, including hormone signaling, transduction, and transcription factors (TFs) constituting a highly controlled regulatory network.
Cotton (Gossypium spp.) is an economically important crop providing natural fibers for the textile industry and cotton seed oil for the production of food and biodiesel fuel. Several parasitic nematode species are known to infect cotton but the Southern root-knot nematode (Meloidogyne incognita, RKN) is the most important species because it is endemic to wherever cotton is grown, has a wide host range and is capable of inflicting economic losses through direct damage to the plant root system and indirectly through increasing severity of other root diseases such as Fusarium Wilt caused by Fusarium oxysporum f. sp. vasinfectum. Yield loss due to RKN has dramatically increased in the U.S. from 1% in 1987 to 5.5% in 2006, resulting in losses of more than 136 million kilograms (4.4%) of cotton valued over $235 million (Cotton Disease Loss Estimate Committee Report 2012). Recommended management practices to control RKN include crop rotation and nematicide application. The broad host range of RKN leaves cotton growers with few profitable options to adopt crop rotation as a means of nematode management. Fields with threshold or greater levels of RKN require application of nematicides to minimize yield loss to RKN. Although nematicides are effective in controlling RKN, they do not provide season-long protection and their future availability is uncertain due to environmental concerns.
Host plant resistance, the ability of a plant to suppress nematode reproduction, is the most economical, practical, and environmentally sound method to provide a season long crop protection against RKN. A near immunity level of RKN resistance is available in the cotton germplasm ‘Auburn 623 RNR’, which originated from transgressive segregation in a cross between two moderately resistant parents, Clevewilt 6 and Wild Mexican Jack Jones [2]. The resistance was subsequently transferred to several agronomically adapted cultivars through backcrossing, resulting in the release of the M-line series including genotypes such as ‘M-120 RNR’, ‘M-315 RNR’, and ‘M-155 RNR’, with greatly improved agronomic qualities while retaining the almost-immune level of resistance of Auburn 623 RNR. By using the genotype M-315 RNR, Jenkins et al. [3] showed that resistance to RKN was due to a two-stage post-penetration interference with the first stage occurred soon (10–12 days) after infection which prevented feeding site development and the second stage occurred much later (25–30 days) after infection resulting in a significantly lowered egg production compared to a susceptible genotype. Genetic linkage mapping studies revealed that the resistance in this resistance source is largely controlled by two major QTLs, a locus on the long arm of chromosome 11 and another on the short arm of chromosome 14 [4–6]. Further studies have revealed that the locus on chromosome 11 affects root gall production while the locus on chromosome 14 largely affected RKN egg production with minimal effect on galling [5,7].
The objectives of this study were a) to explore global changes in gene expression at early (12 Days after inoculation; DAI) and late (30 DAI) stages of RKN infection in a RKN resistant and a susceptible genotype using the next generation sequencing based comparative transcriptomic approach, and b) to identify differentially expressing genes (DEGs) in the genomic regions of chromosome 11 and chromosome 14 that have previously been implicated to contain the resistant genes.
Materials and methods
Plant material
Two Upland cotton germplasm lines, M-120 RNR (M120) and Coker 201 (C201) with contrasting responses to M. incognita were used in the experiment. M120 displays a high level of resistance to both galling and RKN egg production while the susceptible genotype C201 is the recurrent parent of the resistant line [2]. Delinted cotton seeds of both genotypes were surface sterilized, germinated in vermiculite and grown for two weeks. Seedlings of similar size from both genotypes were then individually transplanted into a 10.6 cm x 10.6 cm x 12.4 cm pot filled with approximately 500 ml of steam-pasteurized soil (Tifton loamy sand). At transplant, seedlings were infected with 4,000 M. incognita J2 per plant. Inoculum was distributed into two holes about 2.5 cm deep in soil on opposite sides of the seedling and the holes were covered with soil after inoculation. Healthy seedlings of each genotype without inoculation served as treatment controls. Whole intact root system from inoculated and un-inoculated M120 and C201 plants were carefully removed from the potting-mix at 12 and 30 DAI, washed with de-ionized water, dried with sterilized paper towels and immediately frozen in liquid nitrogen. Frozen roots of individual plants were stored at -80°C until RNA extraction.
Library construction and sequencing
Frozen root samples of individual plants from M120 and C201 collected from 12 and 30 DAI along with un-inoculated control of both genotypes collected at 12 and 30 DAI were individually crushed with a mortar and pestle in liquid nitrogen, and total RNA was extracted using Spectrum™ Plant Total RNA extraction kit (Sigma-Aldrich) following the manufacturer’s protocol. Quantity and quality of the extracted RNA was assessed by NanoDrop (Thermo Scientific). Sample from the infected and control plants of both the resistant and susceptible genotypes with a 260/280 and 260/230 ratios around 2.0 were selected for library construction. Equal concentration of RNA from two individual plants from M120 and C201 at 12 and 30 DAI were utilized for cDNA library constructions. For both genotypes, the cDNA libraries constructed from plants at 12 DAI were designated as early sampling date (E), at 30 DAI designated as late sampling date (L). Similarly, for both genotypes, a cDNA library designated as control (C) was also developed from pooling equal concentration of RNA from three un-inoculated plants each sampled at 12 and 30 DAI. All libraries were constructed using the NEBNext Ultra RNA library Prep Kit for Illumina (New England BioLabs Inc.) following the manufacturer’s protocol. The NEBNext Multiplex Oligos for Illumina (Index Primers Set 2, New England BioLabs Inc.) containing adaptors and primers were used to label libraries facilitating pooling. Libraries were submitted to the Georgia Genomic Facility, University of Georgia for sequencing using 150 bp paired-end Illumina NextSeq 300 High Output flow cell platform.
Transcriptome assembly, and differential expression
The qualities of the raw reads were checked using FastQC program [8]. Low-quality bases and adapter sequences from paired reads were trimmed using the Trimmomatic v0.30 program [9]. Trimmed reads were mapped to the G. hirsutum reference genome [10] downloaded from the cotton functional genomics database (https://cottonfgd.org) using HISAT2 v2.1.0 (https://ccb.jhu.edu/software/hisat2/). Sequence alignment files were input into the software Stringtie v1.3.3 (http://ccb.jhu.edu/software/stringtie/) to assemble potential transcripts [11]. A python script was used to obtain gene-level raw counts from each library for differential gene expression analysis using the R package DESeq2 [12]. All calculated P-values were adjusted for multiple testing with Benjamini and Hochberg's approach using a false discovery rate (FDR) of 5% and genes were determined to be differentially expressing with FDR < 0.05.
cDNA libraries from RKN infected M120 and C201 plants at early and late sampling dates were compared to their respective controls to identify up and down regulated genes. In addition, the libraries of infected M120 and C201 plants at early and late sampling dates were compared to each other to identify genotype specific DEGs and estimate the log2 Fold Change (FC). Genes were considered to have a significant difference in gene expression when their relative expression levels showed at 4-FC (log2 FC >2.0 or < -2.0) difference between infected and control samples, with P-value<0.05. Clustering of the significant DEGs with similar expression patterns was performed by the Multiexperiment Viewer v4.9.0 (http://mev.tm4.org/) using K-means clustering and Pearson’s correlation coefficient.
Real-time qPCR
Primers for target genes in the QTL regions and an endogenous control gene were designed with Primer3Plus [13]—available at https://primer3plus.com/cgi-bin/dev/primer3plus.cgi - and synthesized by Eurofins Genomics US. Reverse transcription (RT) for cDNA synthesis was done using 4 μL iScript Reverse Transcription Supermix for RT-qPCR (bio-rad), ~1 μg total plant RNA, and nuclease-free water to constitute 20 μL final reaction volume. Amplification conditions were: 5 min at 25°C for priming, 20 min at 46°C for RT, and 1 min at 95°C for RT inactivation. Two biological replicates of samples corresponding to early and late infection time-points were used in 10 μl qPCR reactions containing: 5 ml of SsoAdvanced™ Universal Inhibitor-Tolerant SYBR® Green Supermix (bio-rad), 0.25 μM of each primer, 2 μl of diluted cDNA (corresponding to 20 ng of total RNA), and 2.5 μl nuclease-free water. Three technical replicates were used in qPCR reactions. StepOnePlus Real-Time PCR System (ThermoFisher Scientific) was run with the following amplification conditions: hot start of 3 min at 98°C followed by 40 cycles of 15 s at 98°C and 60 s at 58–60°C when the raw fluorescence data was recorded. After 40 cycles, melting curves were estimated from 60°C to 95°C, with a plate reading step at 0.3°C increments. Raw fluorescence data was exported to comma separated files (.csv). The fractional cycle number at threshold (CT) values and primer efficiencies were estimated using Miner [14] v4.0 (http://miner.ewindup.info/). Relative gene expression and their significance were estimated through 2,000 iterations of CT, using REST 2009 [15] v.1 (http://rest.gene-quantification.info/).
Gene enrichment analysis
Gene list enrichment analysis is done by PANTHER Overrepresentation Test (http://geneontology.org/, Released 20171205) using Fisher's Exact with FDR multiple test correction (FDR<0.05). Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis of the DEGs was performed using the Database for Annotation, Visualization and Integrated Discovery (DAVID) v6.8 (https://david.ncifcrf.gov) with Uniprot IDs associated with these genes obtained from the cotton functional genomics database (https://cottonfgd.org). GO terms with P < 0.05 were considered significantly enriched.
Results
Transcriptome sequencing
To gain insight into the transcriptomic changes in Upland cotton roots as the nematode infection progresses, cDNA libraries of resistant M120 and susceptible C201 plants were sequenced at early (12 DAI) and late (30 DAI) stages of nematode infection. After trimming adapters and low quality reads, the number of reads generated ranged from 39.3 million reads in M120-C library to 47.2 million reads in M120-E library. Of the 315 million total reads obtained (157.5 million pair ends), 240.54 million or 76.3% were mapped to the G. hirsutum reference genome from cotton functional genomics database (Fig 1).
Differential gene expression and functional analysis
Differential expression of genes in M120 and C201 (FDR <0.05) were evaluated using DESeq2 package that performs variance estimation and differential expression of the raw read count between infected and control libraries at each sampling point.
A total of 3,789 genes were found to be differentially expressed at the set threshold of P-value<0.05. Comparisons of the up and down regulated genes at early and late sampling stage are presented in a Venn diagram (Fig 2). In total there were 1,884 (49.7%) differentially expressed genes at the early stage of infection and a total of 2,172 (57.3%) at the later stage of RKN infection. The resistant genotype, M120, had greater number (1,250) of differentially expressing genes at early stage of RKN development whereas the susceptible genotype C201 had greater number (1,355) of differentially expressing genes at later stage of RKN development (Fig 2) suggesting that the host plant response to RKN infection and development is different between the two genotypes.
GO enrichment analysis of the annotated DEGs revealed several enriched biological processes, molecular functions and cellular components (Fig 3). Functional analysis of DEGs identified at the early sampling stage revealed that the key enriched biological processes include protein ubiquitination (GO:0016567), defense response (GO:0006952), response to phyto-hormones such as salicylic acid (GO:0009751), abscisic acid (GO:0009737), auxin (GO:0009733), ethylene (GO:0009873), response to chitin (GO:0010200) and cell wall organization (GO:0071555). The key molecular functions enriched included transcription factor activity (GO:0003700), protein serine/threonine kinase activity (GO:0004674), kinase activity (GO:0016301), and calmodulin binding (GO:0005516) (Fig 3). The most enriched cellular components group included plasma membrane (GO:0005886), plasmodesma (GO:0009506), and cell wall (GO:0005618). KEGG pathway analysis showed that plant-pathogen interaction (ath04626), plant hormone signal transduction (ath04075), ubiquinone and other terpenoid-quinone biosynthesis (ath00130) were also enriched.
Differential gene expression between resistance and susceptible genotypes
To estimate on the number of genes expressing differentially between M120 and C201 at early and late stages of nematode infection, we performed a comparative analysis using the DESeq2 package at the preset threshold of fold change (FC) >2.0 or < -2.0 and false discovery rate (FDR) <0.05. Comparative analysis of libraries at early stage of nematode infection (M120-E vs C201-E) identified 1,313 DEGs where a positive log2FC indicates higher relative expression of genes in M120 while negative log2FC indicates relatively higher expression of genes in C201. A total of 454 (36%) DEGs had higher expression in C201 while 859 (64%) had higher expression in M120. Similarly, a total of 1,555 DEGs were identified at the late stage of nematode infection (C201-L Vs M120-L), and of these 658 (42%) had a greater relative expression in C201 (negative log2FC) while 897 (58%) DEGs had a greater relative expression level in M120 (positive log2FC).
Cluster analysis
All the DEGs between treated and untreated libraries were grouped into four clusters based on the expression profiles using k-mean algorithm (S1 Table; Fig 4). The first cluster included 956 genes predominately up regulated at early stages of RKN infection in M120 (S1 Table). Expression levels of several of these genes were up regulated in M120-L but were down regulated in C201-E and C201-L. This cluster included over 60 genes involved in host disease response such as MYB transcription factors, genes in auxin (TIFY 9) and ethylene-activated signaling pathway (ERF13), genes activated in response to salicylic acid (syntaxin and callose synthase), and calmodulin binding genes (S1 Table). The second cluster consisted of 1,018 RKN responsive genes that were up regulated at early stages of RKN development in C201 and M120 but were down regulated in C201-L (Fig 4). This cluster included over 50 disease responsive genes, genes associated with host plant hypersensitive response such as endochitinase (EP3) flavin-containing monooxygenase (FMO1), genes involved in salicylic acid mediated signaling pathway and systemic acquired resistance (SAR) (S1 Table). The third cluster consisted of 726 RKN responsive genes up regulated at later stages of RKN infection in both C201 and M120 (S1 Table). The expression level of the majority of these genes were down regulated at early stages of RKN infection in C201. A majority of the up regulated DEGs were associated with auxin-activated signaling pathway and DNA-template transcription for controlling vegetative and floral developmental stages. The fourth cluster consisted of 1,089 RKN responsive genes that were up regulated in C201-L. This cluster included several cell wall organization genes like cellulose synthase, endoglucanase, galacturonosyltransferase, and xylose synthase along with genes involved in the lignin biosynthetic process such as laccase, caffeoylshikimate esterase. Other genes in this cluster were associated with biological processes such as response to water deprivation, response to osmotic stress, unidimensional cell growth and auxin or ethylene activated signaling pathways.
Transcription factors analysis
Transcription factors (TFs) are vital components of the host molecular response to invading pathogens as they control gene transcriptions by binding to cis-acting elements in the promoters of their target genes. TFs can positively and negatively regulate downstream defense responsive genes in response to biotic and abiotic stresses. The Plant Transcription Factor Database (planttfdb.cbi.pku.edu.cn) hosts over 5,000 G. hirsutum transcription factors that have been classified into 58 families. In this study, 571 TF’s belonging to 42 families displayed differential expression in response to RKN infection (Fig 5). The most abundantly expressing TF families were ERF (13%), MYB (13%), bHLH (9%), NAC (9%), WRKY (6%), and C2H2 (3%). These TFs are integral parts of the signaling networks that modulate many biological processes including host response to pathogens, regulation of pathogen resistance, and cell death. Enhanced activity of these TFs suggests possible role in regulating genes in multiple pathways through cis-acting sequences in response to RKN infection.
Differentially expressing genes at the QTL loci regions
The physical location of the QTL regions on chromosome 11 and 14 were identified by BLAST searching the G. hirsutum genome sequence using clone sequences from which the flanking SSR markers CIR316 and CIR069 demarcating region on chromosome 11 and markers BNL3644 and NAU5467 demarcating region on chromosome 14 were developed. We included chromosome D11, homeologs of chromosome 11 (A11) and chromosome A02, homeolog of chromosome 14 (D02) in searching for DEGs. A total of 36 DEGs were identified between C201-E and M120-E libraries while a total of 39 DEGS were identified between the C201-L and M120-L libraries (Table 1). Eighteen DEGs were common between the two stages of sampling, which included genes encoding for Glutathione S-transferase (Gh_A02G0247, Gh_A02G0260), Callose synthase (Gh_A02G0303, Gh_D02G0367), Putative disease resistance protein (Gh_A11G2835), LRR receptor-like protein kinase (Gh_A02G0272), Wall-associated receptor kinase (Gh_D02G0201), and heat shock protein (Gh_D02G0378), emphasizing the role of these QTL loci in detoxification, stress response, disease resistance, and cell wall modification in response to RKN infection and development.
qPCR of candidate genes at the QTL regions
A total of 12 DEGs primarily involved in defense-related functions, six from each of the two QTL regions on chromosomes 11 (with an exception of a homoeologous TMV resistance gene Gh_D11G3369) and 14 were selected for further qPCR analysis. Detailed information on the target genes, endogenous control, and PCR primers are provided in S2 Table. Relative gene expression (normalized against endogenous GhACT4) between nematode treated vs. control samples at early and late time-points showed that 11 out of 12 targets were significantly overexpressed in at least one treatment-genotype combination (Fig 6, S1 Fig, and S3 Table). For example, five of the six target genes on chromosome 14 such as Gh_D02G0257 and Gh_D02G0259 were significantly overexpressed in response to nematode infection, with Gh_D02G0259, a receptor kinase gene, showing significant overexpression only in the resistant M120 genotype at both stages of nematodes development (Fig 6B). Similarly, five of the six target genes chromosome 11 and a TMV resistant gene mapped to homoeologous region in chromosome 21 were significantly overexpressed in response to nematode infection. It is noteworthy that two colocalized putative disease resistance genes viz. Gh_A11G2835 and Gh_A11G2836 showed different directions of expression in response to nematode infection (Fig 6 and S1 Fig), which is collaborate with the expression results from RNA-seq (Table 1 and S1 Table). Specifically, RNA-seq showed significantly overexpression of Gh_A11G2835 in the resistant genotype at both stages of nematodes development, while qPCR showed late-stage specific overexpression in M120 with significant down expression in C201. However, Gh_A11G2836 was significantly overexpressed in the susceptible genotype C201 at the early stage in RNA-seq and at both stages in qPCR, making the colocalized pair the most likely candidate genes conditioning different disease reaction in the two genotypes.
Discussion
The Auburn 623 RNR germplasm represents the most important source of resistance to RKN in cotton. Histopathology studies have shown a two-stage mechanism in conferring RKN resistance in this germplasm source [3] and QTL analyses collaborated with this observation with the identification of two resistance loci, one on chromosome 11 which had a strong effect on root gall suppression while the second locus on chromosome 14 had a strong effect on impeding egg production but little effect on galling [4–6]. These results not only lend credence to the hypothesis that resistance in Auburn 623 is conferred by two genes with different defense response strategy against nematode attack but also suggest that the mechanism of resistance for the qMi-C11 locus occurs in the early defense reaction (~8–12 days post penetration) preventing juvenile nematodes from developing functional feeding sites to form giant cells and the qMi-C14 locus involves in the later defense mechanism (~25–30 days post penetration) whereby impeding the development of nematodes into eggs laying adult females. Therefore, analyzing the transcriptome level difference between M120 and C201 to identify unique alterations in gene expression at early and late stages of RKN development will narrow the lists of candidate genes for qMi-C11 and qMi-C14 to further facilitate in elucidating the mechanisms of resistance.
Transcriptomic changes at early stage of infection
At early stages, expression of defense response genes was up regulated in both genotypes, however the magnitude of upregulation was several-fold greater in M120. Expression levels of genes that trigger early plant defenses and hypersensitive responses such as the endochitinase EP3, disease resistance protein RPM1, and protein EDS1L were higher in M120 compared to C201. Many defense-responsive genes were specific to M120 (grouped in cluster-1) and were up regulated at both early and late stages suggesting their role in constitutive M120 specific resistance. For example, ethylene-responsive genes, ERF12, ERF13, ERF1B and transcription factors such as MYB108, and TIFY9 were expressed at higher levels in M120-E and M120-L. Genes belonging to ethylene-responsive transcription factor superfamily have played a pivotal role in adaption to biotic stresses by activating pathogenesis-related (PR) genes [16]. Together these results suggest that the durable host plant resistance in M120 may not only be due to activation of M120-specific defense response genes but also by multifold increase in expression of defense genes common between resistant and susceptible genotypes.
Plant hormones play a pivotal role in regulating plant growth and development, and coordinate host plant response to biotic stresses. Genes activated in response to plant hormones like auxins and cytokinins were up regulated in C201. Auxin responsive genes (IAA) such as IAA20, Indole-3-acetic acid-amido synthetase (GH3.6), and Dof zinc finger protein (DOF3.4) had up to 6-fold higher expression in C201 at the early stage of infection. Our findings are in genotype with previous reports that the increased activity of auxin responsive genes during the early stage of infection in susceptible plants have a role in nematode feeding site development [17]. In silico analyses of nematode-responsive genes have shown that accumulation of auxin in response to nematode infection may also result in activation of genes in other pathways critical for nematode feeding site development [17, 18]. Genes involved in cytokinin metabolic processes were also up regulated in the susceptible genotype. We detected increased activity of cytokinin dehydrogenase genes (CKX6, and CKX7) in C201, which agrees with the fact that the nematodes activate cell division by manipulating production and signaling of cytokinins [19]. Expressions of cytokinin dehydrogenase genes were found down regulated in M120, which is in contrast to findings in Arabidopsis where a transgenic line over expressing cytokinin oxidase 2 (35S:CKX2) gene produced fewer galls and eggs per plant [20]. The precise role of cytokinins and cytokinin-oxidase genes in plant-nematode interaction remains obscure.
Transcriptomic changes at later stage of infection
At the late stage of nematode development, expression levels of the genes related to plant cell wall organization and lignin modification were up regulated in C201 (cluster-4). For example, genes like cellulose synthase, xyloglucan endotransglycosylase, endoglucanase, galacturonosyltransferase, xylose synthase, laccase, and caffeoylshikimate esterase had multifold increased activity in C201. Studies have shown that nematodes enlarge their feeding site by up-regulating plant genes encoding for proteins that promote cell wall loosening like endoglucanases, pectinases, and expansins [21–23]. Further expansion of cells is achieved thru structural changes in cell wall xyloglucans which are the major components of hemicellulose and play crucial roles in cell wall flexibility [24]. The Xyloglucan endo-transglycosylase/hydrolase (XTH) genes in plants are primarily responsible for cell wall reinforcement after cell expansion is complete [25]. In the susceptible C201, xyloglucan endo-transglycosylase/hydrolase (XTH9) and expansin (EXPA5, EXPA17, EXLA1) gene expression levels were twice that in M120, suggesting rapid modification and restructuring of cell walls in susceptible genotypes. Higher expression of genes for callose deposition (CALS12) and phenylalanine ammonia-lyase (PAL), an enzyme in the lignin biosynthetic pathway were also detected in the resistant M120. Lignin and callose deposition in roots strengthen the plant resistance to invading nematodes [26, 27] by limiting the accessibility of cell wall-degrading enzymes secreted by nematodes during penetration and migration in plant roots [28].
Increased activity of detoxification genes was observed at the later stage. While the expression of glutathione S-transferase (GSTU7, GSTU8, GSTU17, GSTL3) genes involved in the conjugation of reduced glutathione to a wide number of exogenous and endogenous hydrophobic electrophiles was up regulated in both genotypes, the expression of laccase genes (LAC7, LAC14), which are involved in lignin catabolism and detoxification, had elevated expression only in the resistant genotype. Laccase genes along with peroxidase genes catalyze polymerization of monolignols to yield lignin, which plays an integral role in the defense response in several crops like cabbage [29], wheat [30], and maize [31]. In soybean a set of five laccase genes were found at rhg1 locus that provided resistance against soybean cyst nematode (SCN; Heterodera glycines) and it was suggested that LAC genes may interact with other detoxifying genes and defense related genes to provide enhanced SCN resistance [32, 33].
Transcriptomic changes at QTL loci
Genes differentially expressed at the QTL interval of qMi-C11 and qMi-C14 are of special interest in this study because of their physical position in the genome. In a previous study, we have reported the candidate genes for both QTL regions including 20 LRR genes in which SNPs were detected between a resistant and a susceptible genotype [7]. The 75 DGES found in the QTL regions primarily included genes involved in disease resistance, cell wall modification, production/metabolism of secondary metabolites and detoxification pathways.
Plant resistance gene analogs (RGAs), have conserved domains and motifs that play specific roles in host plant resistance [34]. Three resistance gene analogs (RGA1, RGA3, RGA4) at the QTL loci were overexpressed in response to RKN infection. Expression of RGA1 was confined to the late infection stage in M120 whereas RGA4 was induced in C201 at the early stage, however RGA3 was overexpressed in M120 at both early and late stages. At early stage of infection, expression levels of the gene for putative disease resistance protein (RGA3; Gh_A11G2835) was more than 6 log2FC in M120 with sustained expression till later stage of infection at relatively lower levels (log2FC = 2.0). Although quantitatively overexpressed at both stages of infection, qPCR validated significance of late stage-specific overexpression of RGA3 in M120 with concurrent down expression in C201, making the target the most probable candidate gene in chromosome 11 QTL region. Receptor like proteins (RLP) are one of the most abundant RGAs in plants that are involved in disease resistance and in plant development [33]. Two RLP12 genes (Gh_D02G0257, Gh_D02G0259) at the QTL loci on chromosome 14 were identified as candidate genes in our previous research [7] and their overexpression in response to RKN infection in M120 was evident in both RNA-seq and qPCR studies, which strongly suggest their role as plant receptors in sensing nematode parasitism and activating signaling pathways to trigger innate immune response.
A set of callose synthase genes at the QTL region on chromosome 14 and its homeolog A02 were highly up regulated in the RKN resistant M120, particularly during late infection. Similar results were reported in rice, where overexpression of three callose deposition genes along with lignin biosynthesis genes was observed in the roots of RKN resistant plants post nematode infection [28]. These results suggest that lignin and callose deposition likely interfere with some aspect of nematode development. Similarly, enhanced expression of Glutathione S-transferase genes on chromosome A02 suggest that this gene family may act as antioxidant and may be instrumental in regulating/signaling of cell death during hypersensitive response. Elevated expression of GSTs along with glutathione peroxidase (GPX) and GSH were observed in resistant tobacco when challenged with TMV [35] and in resistant sunflower infected with downy mildew [36], however, the precise role of GSTs during RKN infection in cotton needs further validation.
Finally, two genes have been reported to play a role in RKN resistance in cotton. The MIC-3 gene family that encodes cotton-specific pathogenesis-related proteins was shown to suppress RKN egg production when overexpressed in an RKN-susceptible genotype [37]. However, no MIC genes were found in the qMi-C14 region, precluding them as candidates for this QTL. Interestingly, the gene Gh_D02G0276 encoding for domesticated transposase from hAT-superfamily (RICESLEEPER 3), which we previously reported to be a candidate [7] has recently been proposed as the causal gene qMi-C14 [38]. This gene belongs to the SLEEPER gene family and while it has been known to be essential for normal growth and development [39], its role in disease resistance is largely unknown. However, the homeolog of this gene (Gh_A02G0103) was differentially up regulated in M120 at early stage of infection and suppression of its expression by virus induced gene silencing in a resistant line resulted in a phenotype that was similar to a RKN susceptible genotype. Our qPCR results did not show significant up-regulation of Gh_D02G0275 (data not shown) in response to RKN infection.
In conclusion, transcriptome analysis of M120 and C201 at early and late stages of RKN infection indicates that the host response to RKN parasitism is complex and greatly different between the resistant and susceptible genotypes. Resistant plants induced expression of early defense response genes, detoxification genes, and callose and lignin deposition genes to resist invasion and restrict movement of RKN inside the roots, whereas the susceptible plants expressed genes that facilitated establishment of feeding sites and development of female RKN. We found that the resistance in M120 might not only be due to induction of genotype-specific genes but also to greater magnitude in expression of defense response genes that are common to both genotypes. Overall, the expression data shows that the two QTL loci may have only partial contribution to RKN resistance in M120 with a greater part of resistance due to complex interactions of genes in the M120 genome. Systematic gene co-expression network analysis along with exhaustive histopathological studies are required to identify prominent pathways and/or groups of genes responsible for near immunity to RKN in the Auburn 623 RNR source.
Supporting information
S1 Fig [tif]
Quantitative real-time PCR (qRT-PCR) of candidate root-knot nematode (RKN) resistance genes at early and late infection time-points.
S1 Table [docx]
Cluster analysis of differentially expressing genes between M120 and C201 at early (E) and late (L) stages of nematode infection.
S2 Table [docx]
Target genes, endogenous control, and PCR primers used in the qPCR analysis.
S3 Table [docx]
Relative gene expression in an early and late stage in M120 and C201 genotypes in response to root-knot infection.
Zdroje
1. Jones JD, Dangl JL. The plant immune system. Nature. 2006;444(7117):323–9. doi: 10.1038/nature05286 17108957
2. Shepherd RL. Transgressive Segregation for Root-Knot Nematode Resistance in Cotton. Crop Sci. 1974;14(6):872–5.
3. Jenkins JN, Creech RG, Tang B, Lawrence GW, Mccarty JC. Cotton Resistance to Root-Knot Nematode .2. Post-Penetration Development. Crop Sci. 1995;35(2):369–73.
4. Gutierrez OA, Robinson AF, Jenkins JN, McCarty JC, Wubben MJ, Callahan FE, et al. Identification of QTL regions and SSR markers associated with resistance to reniform nematode in Gossypium barbadense L. accession GB713. Theor Appl Genet. 2011;122(2):271–80. doi: 10.1007/s00122-010-1442-2 20845024
5. He YJ, Kumar P, Shen XL, Davis RF, Van Becelaere G, May OL, et al. Re-evaluation of the inheritance for root-knot nematode resistance in the Upland cotton germplasm line M-120 RNR revealed two epistatic QTLs conferring resistance. Theor Appl Genet. 2014;127(6):1343–51. doi: 10.1007/s00122-014-2302-2 24728014
6. Shen XL, Van Becelaere G, Kumar P, Davis RF, May OL, Chee P. QTL mapping for resistance to root-knot nematodes in the M-120 RNR Upland cotton line (Gossypium hirsutum L.) of the Auburn 623 RNR source. Theor Appl Genet. 2006;113(8):1539–49. doi: 10.1007/s00122-006-0401-4 16960714
7. Kumar P, He YJ, Singh R, Davis RF, Guo H, Paterson AH, et al. Fine mapping and identification of candidate genes for a QTL affecting Meloidogyne incognita reproduction in Upland cotton. Bmc Genomics. 2016;17. doi: 10.1186/s12864-015-2333-3
8. Andrews S. FastQC: a quality control tool for high throughput sequence data. 2010.
9. Bolger AM, Lohse M, Usadel B. Trimmomatic: a flexible trimmer for Illumina sequence data. Bioinformatics. 2014;30(15):2114–20. doi: 10.1093/bioinformatics/btu170 24695404
10. Zhang T, Hu Y, Jiang W, Fang L, Guan X, Chen J, et al. Sequencing of allotetraploid cotton (Gossypium hirsutum L. acc. TM-1) provides a resource for fiber improvement. Nature biotechnology. 2015;33(5):531–7. doi: 10.1038/nbt.3207 25893781
11. Pertea M, Kim D, Pertea GM, Leek JT, Salzberg SL. Transcript-level expression analysis of RNA-seq experiments with HISAT, StringTie and Ballgown. Nature protocols. 2016;11(9):1650–67. doi: 10.1038/nprot.2016.095 27560171
12. Love MI, Huber W, Anders S. Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome biology. 2014;15(12):550. doi: 10.1186/s13059-014-0550-8 25516281
13. Untergasser A, Nijveen H, Rao X, Bisseling T, Geurts R, Leunissen JA. Primer3Plus, an enhanced web interface to Primer3. Nucleic acids research. 2007;35(Web Server issue), W71–W74. doi: 10.1093/nar/gkm306 17485472
14. Zhao S, Fernald, RD. Comprehensive algorithm for quantitative real-time polymerase chain reaction. Journal of computational biology: a journal of computational molecular cell biology. 2005;12(8), 1047–1064. doi: 10.1089/cmb.2005.12.1047 16241897
15. Pfaffl MW, Horgan GW, Dempfle L. Relative expression software tool (REST) for group-wise comparison and statistical analysis of relative expression results in real-time PCR. Nucleic acids research; 2002; 30(9), e36. doi: 10.1093/nar/30.9.e36 11972351
16. Licausi F, Ohme‐Takagi M, Perata PJNP. APETALA 2/Ethylene Responsive Factor (AP 2/ERF) transcription factors: mediators of stress responses and developmental programs. 2013;199(3):639–49.
17. Goverse A, Overmars H, Engelbertink J, Schots A, Bakker J, Helder JJMP-MI. Both induction and morphogenesis of cyst nematode feeding cells are mediated by auxin. 2000;13(10):1121–9. doi: 10.1094/MPMI.2000.13.10.1121 11043473
18. Grunewald W, Van Noorden G, Van Isterdael G, Beeckman T, Gheysen G, Mathesius UJTPC. Manipulation of auxin transport in plant roots during Rhizobium symbiosis and nematode parasitism. 2009;21(9):2553–62. doi: 10.1105/tpc.109.069617 19789282
19. Goverse A, Bird D. The role of plant hormones in nematode feeding cell formation. Genomics and Molecular Genetics of Plant-Nematode Interactions: Springer; 2011. p. 325–47.
20. Dowd CD, Chronis D, Radakovic ZS, Siddique S, Schmülling T, Werner T, et al. Divergent expression of cytokinin biosynthesis, signaling and catabolism genes underlying differences in feeding sites induced by cyst and root‐knot nematodes. The Plant Journal. 2017.
21. Kyndt T, Vieira P, Gheysen G, de Almeida-Engler J. Nematode feeding sites: unique organs in plant roots. Planta. 2013;238(5):807–18. doi: 10.1007/s00425-013-1923-z 23824525
22. Wieczorek K, Golecki B, Gerdes L, Heinen P, Szakasits D, Durachko DM, et al. Expansins are involved in the formation of nematode‐induced syncytia in roots of Arabidopsis thaliana. The Plant Journal. 2006;48(1):98–112. doi: 10.1111/j.1365-313X.2006.02856.x 16942607
23. Wieczorek K, Hofmann J, Blöchl A, Szakasits D, Bohlmann H, Grundler FM. Arabidopsis endo‐1, 4‐β‐glucanases are involved in the formation of root syncytia induced by Heterodera schachtii. The Plant Journal. 2008;53(2):336–51. doi: 10.1111/j.1365-313X.2007.03340.x 18069944
24. Scheller HV, Ulvskov P. Hemicelluloses. Annual review of plant biology. 2010;61.
25. Nishitani K, Vissenberg K. Roles of the XTH protein family in the expanding cell. The expanding cell: Springer; 2006. p. 89–116.
26. Wuyts N, Lognay G, Swennen R, De Waele DJJoeb. Nematode infection and reproduction in transgenic and mutant Arabidopsis and tobacco with an altered phenylpropanoid metabolism. 2006;57(11):2825–35.
27. Wuyts N, Lognay G, Verscheure M, Marlier M, De Waele D, Swennen RJPp. Potential physical and chemical barriers to infection by the burrowing nematode Radopholus similis in roots of susceptible and resistant banana (Musa spp.). 2007;56(5):878–90.
28. Kumari C, Dutta TK, Banakar P, Rao UJSr. Comparing the defence-related gene expression changes upon root-knot nematode attack in susceptible versus resistant cultivars of rice. 2016;6:22846.
29. Zhang SH, Yang Q, Ma RCJJoIPB. Erwinia carotovora ssp. carotovora infection induced “defense lignin” accumulation and lignin biosynthetic gene expression in Chinese cabbage (Brassica rapa L. ssp. pekinensis). 2007;49(7):993–1002.
30. Ma Q-H, Zhu H-H, Han J-QJPS. Wheat ROP proteins modulate defense response through lignin metabolism. 2017;262:32–8.
31. Wang G-F, He Y, Strauch R, Olukolu BA, Nielsen D, Li X, et al. Maize homologs of hydroxycinnamoyltransferase, a key enzyme in lignin biosynthesis, bind the nucleotide binding leucine-rich repeat Rp1 proteins to modulate the defense response. 2015;169(3):2230–43.
32. Ruben E, Jamai A, Afzal J, Njiti V, Triwitayakorn K, Iqbal M, et al. Genomic analysis of the rhg1 locus: candidate genes that underlie soybean resistance to the cyst nematode. Molecular Genetics and Genomics. 2006;276(6):503–16. doi: 10.1007/s00438-006-0150-8 17024428
33. Afzal AJ, Natarajan A, Saini N, Iqbal MJ, Geisler M, El Shemy HA, et al. The nematode resistance allele at the rhg1 locus alters the proteome and primary metabolism of soybean roots. Plant physiology. 2009;151(3):1264–80. doi: 10.1104/pp.109.138149 19429603
34. Sekhwal MK, Li P, Lam I, Wang X, Cloutier S, You FMJIJoMS. Disease resistance gene analogs (RGAs) in plants. 2015;16(8):19248–90.
35. Fodor J, Gullner G, Ádám AL, Barna B, Komives T, Király ZJPP. Local and systemic responses of antioxidants to tobacco mosaic virus infection and to salicylic acid in tobacco (role in systemic acquired resistance). 1997;114(4):1443–51.
36. Herbette S, Lenne C, De Labrouhe DT, Drevet JR, Roeckel‐Drevet PJPP. Transcripts of sunflower antioxidant scavengers of the SOD and GPX families accumulate differentially in response to downy mildew infection, phytohormones, reactive oxygen species, nitric oxide, protein kinase and phosphatase inhibitors. 2003;119(3):418–28.
37. Wubben MJ, Callahan FE, Jenkins JN, Deng DDJT, genetics a. Coupling of MIC-3 overexpression with the chromosomes 11 and 14 root-knot nematode (RKN)(Meloidogyne incognita) resistance QTLs provides insights into the regulation of the RKN resistance response in Upland cotton (Gossypium hirsutum). 2016;129(9):1759–67.
38. Wubben MJ TG, Lee P, Callahan FE, Deng DD, McCarty JC, Jenkins JN. Marker-assisted-selection coupled with recombinant inbred line genome sequencing identifies a root-knot nematode resistance gene on chromosome 14 in upland cotton. Annual meeting, society of nematologists; July 22–25; Albuquerque, New Mexico, USA2018.
39. Knip M, de Pater S, Hooykaas PJJBpb. The SLEEPER genes: a transposase-derived angiosperm-specific gene family. 2012;12(1):192.
Článok vyšiel v časopise
PLOS One
2019 Číslo 9
- Metamizol jako analgetikum první volby: kdy, pro koho, jak a proč?
- Nejasný stín na plicích – kazuistika
- Masturbační chování žen v ČR − dotazníková studie
- Těžké menstruační krvácení může značit poruchu krevní srážlivosti. Jaký management vyšetření a léčby je v takovém případě vhodný?
- Fixní kombinace paracetamol/kodein nabízí synergické analgetické účinky
Najčítanejšie v tomto čísle
- Graviola (Annona muricata) attenuates behavioural alterations and testicular oxidative stress induced by streptozotocin in diabetic rats
- CH(II), a cerebroprotein hydrolysate, exhibits potential neuro-protective effect on Alzheimer’s disease
- Comparison between Aptima Assays (Hologic) and the Allplex STI Essential Assay (Seegene) for the diagnosis of Sexually transmitted infections
- Assessment of glucose-6-phosphate dehydrogenase activity using CareStart G6PD rapid diagnostic test and associated genetic variants in Plasmodium vivax malaria endemic setting in Mauritania