Skip to main content
Download PDF
  • Research article
  • Open access
  • Published:

Involvement of jasmonic acid, ethylene and salicylic acid signaling pathways behind the systemic resistance induced by Trichoderma longibrachiatum H9 in cucumber

BMC Genomics volume 20, Article number: 144 (2019) Cite this article

Abstract

Background

Trichoderma spp. are effective biocontrol agents for many plant pathogens, thus the mechanism of Trichoderma-induced plant resistance is not fully understood. In this study, a novel Trichoderma strain was identified, which could promote plant growth and reduce the disease index of gray mold caused by Botrytis cinerea in cucumber. To assess the impact of Trichoderma inoculation on the plant response, a multi-omics approach was performed in the Trichoderma-inoculated cucumber plants through the analyses of the plant transcriptome, proteome, and phytohormone content.

Results

A novel Trichoderma strain was identified by morphological and molecular analysis, here named T. longibrachiatum H9. Inoculation of T. longibrachiatum H9 to cucumber roots promoted plant growth in terms of root length, plant height, and fresh weight. Root colonization of T. longibrachiatum H9 in the outer layer of epidermis significantly inhibited the foliar pathogen B. cinerea infection in cucumber. The plant transcriptome and proteome analyses indicated that a large number of differentially expressed genes (DEGs) and differentially expressed proteins (DEPs) were identified in cucumber plants 96 h post T. longibrachiatum H9 inoculation. Up-regulated DEGs and DEPs were mainly associated with defense/stress processes, secondary metabolism, and phytohormone synthesis and signaling, including jasmonic acid (JA), ethylene (ET) and salicylic acid (SA), in the T. longibrachiatum H9-inoculated cucumber plants in comparison to untreated plants. Moreover, the JA and SA contents significantly increased in cucumber plants with T. longibrachiatum H9 inoculation.

Conclusions

Application of T. longibrachiatum H9 to the roots of cucumber plants effectively promoted plant growth and significantly reduced the disease index of gray mold caused by B. cinerea. The analyses of the plant transcriptome, proteome and phytohormone content demonstrated that T. longibrachiatum H9 mediated plant systemic resistance to B. cinerea challenge through the activation of signaling pathways associated with the phytohormones JA/ET and SA in cucumber.

Background

Botrytis cinerea is a necrotrophic fungal pathogen that infects more than 200 commercial crops, leading to significant agricultural losses worldwide [1]. To date, chemical fungicides remain the primary method of controlling this pathogen. Due to the detrimental effects on the environment and potential risks for human health of chemical fungicides, a biocontrol method would constitute a preferable alternative approach [2]. Trichoderma spp. are plant growth-promoting fungi that have been found to have great potential for the control of gray mold caused by B. cinerea [3, 4]. The biocontrol can be achieved by a direct interaction between Trichoderma and pathogens, or indirectly by inducing plant resistance to pathogens in the same or different parts from the pathogen infection sites. Traditionally, Trichoderma spp. directly antagonize pathogens by mycoparasitism, secretion of antibiotics, and competition for space and nutrients [5,6,7]. However, subsequent discoveries have demonstrated that these biocontrol agents can also interact intimately with plant roots, even colonizing the outer epidermal layers, and act as avirulent, opportunistic plant symbionts [3, 7]. Root colonization by selected Trichoderma isolates has been reported to promote plant growth and increase resistance to a variety of pathogens, both soil-borne and foliar, in various plant species [8,9,10,11,12]. Although the mechanism of induced plant resistance is not fully understood, the plant response to Trichoderma spp. has been studied at the physiological and biochemical levels. These studies have shown that colonization by Trichoderma spp. triggers a series of plant responses that may enhance the defensive capacity of the plant. Mitogen-activated protein kinase (MAPK) cascades are activated in Arabidopsis thaliana leaves by inoculation of the roots with T. hamatum T382 [8]. The cucumber MAPK homologous to A. thaliana MPK3 is induced by incubation of the roots with T. asperellum T203 [13]. Activation of MAPK cascades will alter the phosphorylation status of many substrate proteins to regulate diverse downstream signaling pathways, such as phytohormone signaling [14]. Plant hormone signaling may modulate the defense network by translating Trichoderma-induced upstream signaling events into the activation of defense responses.

In the past, researchers found that contacting with pathogenic and non-pathogenic organisms would trigger two main defense mechanisms in plants: systemic acquired resistance (SAR) and induced systemic resistance (ISR). SAR is commonly triggered by local pathogen attack, correlating with the involvement of salicylic acid (SA) and the activation of PR genes. ISR is activated when the plant interacts with non-pathogenic rhizosphere fungi or bacteria, and requires jasmonic acid (JA)/ethylene (ET) [10, 15]. However, the traditional knowledge of ISR became controversial in recent years. Increasing research has demonstrated that Trichoderma may induce systemic resistance through multiple hormonal signaling pathways, and the specific hormones involved are dependent on both the plant species and Trichoderma strains involved. The cross-talk among different hormone signaling pathways may render plants capable of finely regulating immune responses [8, 10, 15,16,17,18,19,20,21,22,23]. It has also been demonstrated that Trichoderma spp. can positively interfere with reactive oxygen species (ROS) production, e.g., through increasing the ROS scavenging ability of the plant at future infection sites, thereby potentially reducing the damaging levels of ROS in the leaves, thus limiting B. cinerea infection [24,25,26,27]. The expression of defense-related proteins can be strongly potentiated when plants are challenged by additional pathogens, even at sites distant from the location of Trichoderma colonization [3]. Along with other defense strategies, the production of secondary metabolites, such as phytoalexins, plays important roles in the plant defense against B. cinerea [26, 28,29,30,31,32]. Collectively, it is likely that Trichoderma spp. induce multiple levels of changes in plant metabolism that can lead to increased resistance to abiotic and biotic stresses, and thus the mechanism of Trichoderma-induced systemic resistance requires further investigation [33].

Cucumber is one of the most economically important vegetables worldwide. It is susceptible to infection by the plant-pathogenic fungus B. cinerea. Finding potential biocontrol Trichoderma spp. against cucumber diseases is thus warranted [34, 35]. In this study, a novel Trichoderma strain was identified, namely T. longibrachiatum H9, which could promote plant growth and reduce the disease index of gray mold caused by B. cinerea in cucumber. Furthermore, the effect of T. longibrachiatum H9 on induction of defense response in cucumber plants was studied through the analyses of the plant transcriptome, proteome and phytohormone content. The large-scale, multi-omics datasets allowed us to monitor changes in cucumber gene and protein expressions and also provided a basis from which to illustrate the biocontrol mechanism of T. longibrachiatum H9 induced systemic resistance against B. cinerea.

Methods

Morphological and molecular identification of the novel strain

The Trichoderma H9 strain was grown on potato dextrose agar (PDA) medium at 30 °C and identified by morphological observation based on the monograph of Gams and Bisset [36]. The spores were harvested by flooding the surface of the cultures with distilled water. One milliliter of spore suspension was aliquoted and inoculated into potato-dextrose (PD) broth in a rotary shaker at 30 °C and 200 rpm for 48 h. The mycelium was collected by filtration and washed three times with distilled water. Genomic DNA was extracted using a commercial DNA extraction kit. Using the Trichoderma strain H9 genome as the template, the ITS and TEF-1α genes were amplified using specific primers, which were described in Additional file 1: Table S1 (ITS4 and ITS6 for ITS, as well as EF1-728F and TEF1-LLErev for TEF-1α). The PCR products were then sequenced by the Sangon Biotechnology Co., Ltd. Shanghai, China. The ITS and TEF-1α sequences of this strain were deposited in GenBank with the accession numbers MF111118 and MK179408 respectively, and were then aligned with the corresponding sequences of known Trichoderma strains using NCBI BLAST. The phylogenetic trees were constructed under Maximum Likelihood method using MEGA 7 software [37] based on the ITS or TEF-1α sequences. The phylogeny tests were evaluated through performing 1000 bootstrap replicates.

Plant growth, Trichoderma inoculation and pathogen challenge

Seeds of cucumber (Cucumis sativus L.) were purchased from Tianjin Kernel Cucumber Research Institute (Tianjin, China). The seeds were sterilized in 70% ethanol for 2 min, 2.0% NaOCl for 2 min, washed with sterile water three times, and then placed on a sterile gauze sheet with liquid 1/2 Murashige and Skoog (MS) medium in a Petri dish at 37 °C for 24 h. Germinated seeds (30 per box) were placed on a sterile gauze sheet on top of a sterile steel screen in a 50 × 25 × 8 (depth) cm pot system under a 12 h light/12 h dark cycle at 25 ± 2 °C with a light intensity of 120 μmol/m2s. The steel screen holds the seeds 1 cm above the liquid medium [38].

Trichoderma inoculation was performed when the plants had grown to the 3-leaf stage, at which point the spore suspension of Trichoderma H9 at a final concentration 1 × 106 cfu/mL was added to the pot. 1/2 MS medium was used instead of spore suspension in the control group.

The B. cinerea challenge was performed 24 h post H9 inoculation (24 hpTi). Ten microliters of B. cinerea spore suspension at a concentration of 1 × 108 cfu/mL was injected into the abaxial surface of the cucumber leaves. Water was injected as the control for the B. cinerea challenge. In total, four different treatment groups were established, namely non-inoculated, non-challenged plants (−T-B), non-inoculated, challenged plants (−T + B), inoculated, non-challenged plants (+T-B), and inoculated, challenged plants (+T + B) [10].

Detection of promoting effect on plant growth

The method for Trichoderma plant inoculation was described above. Thirty plants were used for each treatment. Treated plants were placed under a 12 h light/12 h dark cycle at 25 ± 2 °C. After two weeks, the plants were harvested and the root length, plant height and fresh weight were measured. Three replicates were performed.

Detection of biocontrol efficacy

The method for Trichoderma plant inoculation and B. cinerea challenge was described above in the -T + B and + T + B groups. Three different sites per leaf were selected on the second and third leaves of each plant. Twelve plants for each group were treated. Three replicates were performed. Following treatment, the cucumber plants were grown under a 12 h light/12 h dark cycle at 25 ± 2 °C. The disease severity of the gray mold was recorded daily. When B. cinerea broadly infected the cucumber leaves in the -T + B group, the disease index and inhibition rate were calculated according to the standard for gray mold disease progression. The disease progression of the infected plants was divided into five grades, where grade 0 = no visible gray mold spot, grade 1 = 1–5%, grade 3 = 6–15%, grade 5 = 16–25%, grade 7 = 26–50%, and grade 9 = ≥51% of the leaf surface covered with gray mold. The gray mold development on each plant was recorded using the above 1–5 scale, and the disease index was calculated using the following formula [39]:

$$ \mathrm{Disease}\ \mathrm{in}\mathrm{dex}=\Sigma\ \left(\mathrm{number}\ \mathrm{of}\ \mathrm{leaves}\ \mathrm{in}\ \mathrm{each}\ \mathrm{disease}\ \mathrm{grade}\times \mathrm{grade}\mathrm{s}\ \mathrm{value}\right)/\left(\mathrm{total}\ \mathrm{number}\ \mathrm{of}\ \mathrm{assessed}\ \mathrm{leaves}\times \mathrm{the}\ \mathrm{highest}\ \mathrm{grade}\ \mathrm{value}\right) $$
$$ \mathrm{Disease}\ \mathrm{inhibition}\ \mathrm{rate}\ \left(\%\right)=\left(\mathrm{disease}\ \mathrm{index}\ \mathrm{of}\ \mathrm{control}-\mathrm{disease}\ \mathrm{index}\ \mathrm{after}\ \mathrm{treatment}\right)/\mathrm{disease}\ \mathrm{index}\ \mathrm{of}\ \mathrm{control}\times 100 $$

Sample processing for transmission electron microscopic study

Cucumber root samples (4 to 10 mm) were collected from the main root at the Trichoderma penetration sites, 96 hpTi. Samples were treated and then examined in a Hitachi H-7650 transmission electron microscope as described [31, 38]. The sites of root colonization by Trichoderma were characterized by comparing the samples from Trichoderma-inoculated and non-inoculated groups. Five samples from five different roots for each group, and 10 ultrathin sections for each sample were observed.

Statistical analysis

Statistical analysis was performed using SPSS software, version 20.0 (SPSS, Inc., Chicago, IL, US). The data from plant growth promoting assays, biocontrol efficacy and plant hormones measurement assays were analyzed by one-way analysis of variance (ANOVA), and the statistical significance was determined using pair-wise comparisons (P < 0.05).

Transcriptome analysis by RNA-Seq

The second and third cucumber leaves were collected from the -T-B and + T-B groups at 96 hpTi respectively when the plants in the +T + B group showed a clear inhibition of B. cinerea infection. The samples were immediately frozen in liquid nitrogen, and then sent to Shanghai Biotechnology Co., Ltd. Shanghai, China for RNA sequencing. The reference genome for transcriptome analysis was acquired from ftp://cucurbitgenomics.org/pub/cucurbit/genome/cucumber/Chinese_long/v2/. Three biological replicates in each group were performed and raw data were deposited into the Sequence Read Archive database with the accession number SRP136435. A basic analysis was performed on the transcriptome data, including data pre-processing, genomic mapping, gene expression analysis, analysis of differentially expressed genes (DEGs), and Gene Ontology (GO)/Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analysis of DEGs. Gene expression levels were determined by FPKM (Fragments Per Kilobase of exon model per Million mapped reads) as described [40]. In order to screen DEGs, up- and down-regulation of genes was defined when the adjusted P-value was < 0.05 and the absolute fold change was ≥2.0 (log2(fold change) ≥ 1.0). Regarding the GO/KEGG enrichment analysis, P-value < 0.05 was chosen as the standard to determine enrichment.

Translatome analysis by iTRAQ mass spectrometry

The second and third cucumber leaves were collected from the -T-B and + T-B groups at 96 hpTi, and immediately frozen in liquid nitrogen, respectively, and then sent to Allwegene Technology Inc. Beijing, China for iTRAQ sequencing. Raw data related to this study have been deposited into iProX (ww.iprox.org) with ID IPX0001185000/PXD009314. Protein identification was performed using the ProteinPilot™ v4.5 search engine against a database (Uniprot Cucumis sativus L). Only peptides with an unused score ≥ 1.3 and confidence interval > 95% were counted to reduce the probability of false peptide identification. Each confident protein was identified with at least one unique peptide. Furthermore, differentially expressed proteins (DEPs) were screened by iTRAQ quantification and up- and down-regulation of proteins was defined when the P-value was < 0.05 and the absolute fold change was ≥2.0. GO/KEGG enrichment analyses of differentially expressed proteins (DEPs) for functional annotations were further performed, and P-value < 0.05 was selected as the standard to determine the enrichment.

Correlation analysis between transcriptome and proteome data

The expression trends of the genes from the transcriptome analysis and their corresponding proteins from the proteome analysis were compared as described [41]. The results were divided into three categories: correlated genes/Proteins, DEGs/DEPs with corresponding proteins/genes, and DEGs/DEPs with corresponding DEPs/DEGs. Correlated DEGs/DEPs were further divided into two categories: with the same expression trend and the opposite expression trend.

Plant hormones measurement

The same treatment groups were established (−T-B and + T-B) as in the previous experiments. The cucumber leaves were harvested from each group at 96 hpTi, and the SA and JA contents were measured using HPLC/MS/MS (high performance liquid chromatography tandem mass spectrometry), which was performed by Zoonbio Biotechnology Co., Ltd. Nanjing, China. Samples were separated by Agilent1290 Infinity liquid chromatography from Agilent (Santa Clara, CA, US) and analyzed by QTrap 6500 mass spectrometer from AB Sciex (Framingham, MA, US) as described [42]. Three replicates were performed.

Quantitative real-time (qRT-PCR) analysis marker gene expression

Leaf tissue was collected from the second and third cucumber leaf in the -T-B and + T-B groups at 96 hpTi, respectively. Total RNA was extracted from each sample using RNAiso™ Plus reagents according to the manufacturer’s instructions. The cDNA synthesis and qRT-PCR were performed according to the PrimeScript™ RT reagent kit. Specific primers used in the qRT-PCR were described in Additional file 1: Table S1. Expression values were normalized to the ACT2 gene. The experiments were repeated three times.

Results

Morphological and molecular identification of the Trichoderma H9 strain

The Trichoderma H9 strain was obtained from the soil near a cucumber plant and exhibited the typical morphological features of T. longibrachiatum based on the monograph of Gams and Bisset [36]. Molecular identification based on ITS and TEF-1α genes revealed that this H9 strain shared the highest homology in the phylogeny and clustered together with T. longibrachiatum strains, whose species identity has been confirmed by phylogenetic analysis [43,44,45,46,47]. The H9 strain was thus identified to be T. longibrachiatum, and was accordingly named T. longibrachiatum H9.

Plant growth enhancement by T. longibrachiatum H9 inoculation in cucumber plants

Furthermore, growth-promoting effects by T. longibrachiatum H9 inoculation were observed based on root length, plant height, and fresh weight measurements of the cucumber plants. The average root length, plant height, and fresh weight of the T. longibrachiatum H9-inoculated plants were 7.46 ± 0.35 cm, 3.79 ± 0.07 cm, and 48.63 ± 1.88 g, which were significantly higher than those of untreated plants with 5.02 ± 0.16 cm, 3.42 ± 0.11 cm, and 38.16 ± 1.53 g, respectively (P < 0.05). The T. longibrachiatum H9 strain significantly impacted root length (48.68%), plant height (10.82%), and fresh weight (27.44%) in cucumber (Table 1).

Table 1 Inoculation of T. longibrachiatum H9 to cucumber roots effectively promoted cucumber plant growth
Full size table

Biocontrol effects by T. longibrachiatum H9 against B. cinerea

In order to determine if T. longibrachiatum H9 could reduce the symptoms of B. cinerea infection in cucumber, 3-leaf stage cucumber plant roots were treated with T. longibrachiatum H9 and their susceptibility to B. cinerea (+T + B) leaf infection was subsequently assessed by comparison to mock-treated plants (−T + B). Treatment of cucumber with T. longibrachiatum H9 significantly reduced the disease index after 4, 8, and 12 d, and the inhibition rates increased to 56.7% on the 12th day from 49.62% on the 4th day (P < 0.05; Table 2).

Table 2 Treatment of cucumber with T. longibrachiatum H9 significantly reduced the disease index of gray mold
Full size table

Consistently, T. longibrachiatum H9 penetrated cucumber root cortical cells and was restricted in the out layer of epidermis after 96 h (96 hpTi), which allowed sufficient time for spore germination, colonization of the roots and induction of a plant response. A large number of Trichoderma hyphae developed at the root surface (RS) (Fig. 1a), penetrated into the root epidermis (EP) (Fig. 1b) and progressed towards the cortex (CO) (Fig. 1c), mainly by intercellular growth. The mycelia of T. longibrachiatum H9 grew mainly between the cells and thickened the cell wall without entering the cell, as observed by transmission electron microscopy. Taken together, the biocontrol assays indicated that root colonization by T. longibrachiatum H9 may induce systemic disease resistance against the foliar pathogen B. cinerea in cucumber.

Fig. 1
figure 1

Transmission electron micrographs indicated that T. longibrachiatum H9 had colonized the cucumber roots. Trichoderma hyphae developed at the root surface (a), penetrated into the root epidermis (b), and progressed towards the cortex (c). Arrows indicate Trichoderma hyphae. Bars: A, 10 μm; B, 500 μm; C, 500 μm

Full size image

Deciphering the plant responses associated with T. longibrachiatum H9 inoculation using transcriptome analysis and iTRAQ proteomics

To examine the underlying mechanisms of the plant response associated with T. longibrachiatum H9-induced plant resistance, both RNA-Seq and proteome analysis were performed on cucumber plant samples harvested at 96 hpTi from the -T-B and + T-B groups, respectively. Compared to untreated plants (+T-B vs. -T-B), 3765 DEGs were identified from the RNA-Seq analysis, with 2304 up-regulated genes and 1461 down-regulated genes under T. longibrachiatum H9 inoculation. A total of 922 DEPs were identified from the proteome analysis with 428 up-regulated and 494 down-regulated proteins (P < 0.05 and fold change > 2.0; Table 3). GO enrichment and KEGG enrichment analyses were further performed to classify the up-regulated and down-regulated DEGs and DEPs.

Table 3 Summary of the number of DEGs and DEPs detected in the T. longibrachiatum H9-inoculated cucumber plants, compared to untreated plants (+T-B vs. -T-B)
Full size table

Based on up-regulated DEGs or DEPs, biological processes was the most enriched category and the GO terms related to phytohormones, secondary metabolism and defense/stress processes were significantly enriched (P < 0.05). The biosynthesis and signaling of hormones, including JA/ET and SA, were observed as plant responses in the plant hormones category. “Phenylpropanoid biosynthetic process”, “flavonoid biosynthetic process”, “lignin biosynthetic process” and other secondary metabolic processes were identified in the secondary metabolites category. Many GO terms related to defense/stress processes were observed including “defense response”, “response to oxidative stress”, “response to reactive oxygen species”, and so on. Meanwhile, several signal transduction GO terms were observed, such as “MAPK cascade” and “signal transduction by protein phosphorylation” (P < 0.05; Additional file 2: Table S2, Additional file 3: Table S3). Based on down-regulated DEGs or DEPs, “photosynthesis” and “photosynthesis, light reaction” were significantly enriched terms (P < 0.05; Additional file 4: Table S4, Additional file 5: Table S5).

The KEGG enrichment analysis allowed us to identify specific pathways according to DEGs or DEPs, respectively. The pathways related to the biosynthesis of phytohormones, including “phenylalanine metabolism (SA biosynthesis)”, “alpha-linolenic acid metabolism (JA biosynthesis)”, and “cysteine and methionine metabolism (ET biosynthesis)”, were significantly enriched based on up-regulated DEGs or DEPs, respectively. Moreover, the pathways “phenylpropanoid biosynthesis”, “flavonoid biosynthesis”, “MAPK signaling pathway” and “peroxisome pathway”, which are associated with secondary metabolite biosynthesis, signal transduction, or defense/stress processes, were also activated in the T. longibrachiatum H9-inoculated cucumber plants (P < 0.05; Additional file 6: Table S6, Additional file 7: Table S7). The top 20 enriched KEGG pathways based on up-regulated DEGs or DEPs were shown, respectively (Figs. 2 and 3). The presence of T. longibrachiatum H9 reprogrammed the gene and protein expression related to phytohormones, secondary metabolism, and defense/stress processes in cucumber plants. This suggested that T. longibrachiatum H9 inoculation might enhance plant defense capacity through activating the signaling pathways associated with the phytohormones JA/ET and SA.

Fig. 2
figure 2

The top 20 enriched KEGG pathways based on up-regulated DEGs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants (+T-B vs.-T-B)

Full size image
Fig. 3
figure 3

The top 20 enriched KEGG pathways based on up-regulated DEPs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants (+T-B vs.-T-B)

Full size image

Correlation analysis of transcriptome and proteome data

To further explore the findings from both transcriptome and proteome data, the correlation analysis was performed by comparing the expression trends of the genes from the transcriptome analysis and their corresponding proteins from the proteome analysis. 3938 genes/proteins were correlated in the totally detected 4171 proteins and 20,189 genes. Among the 3765 DEGs/922 DEPs, 798 DEGs/835 DEPs showed corresponding proteins/genes, and 277 DEGs/DEPs showed corresponding DEPs/DEGs. Furthermore, 241 DEGs/DEPs showed the same expression trends with 132 DEGs/DEPs up-regulated and 109 DEGs/DEPs down-regulated (Table 4, Additional file 8: Table S8). The enriched KEGG pathways based on the 132 up-regulated DEGs/DEPs were analyzed and the top 20 pathways were shown (Fig. 4). “Phenylalanine metabolism (SA biosynthesis)”, “alpha-linolenic acid metabolism (JA biosynthesis)”, “cysteine and methionine metabolism (ET biosynthesis)”, “biosynthesis of secondary metabolites”, “phenylpropanoid biosynthesis”, and “peroxisome” pathways were remain significantly enriched. In contrast, “ribosome”, “porphyrin and chlorophyll metabolism”and “photosynthesis” were the most significantly enriched pathways based on the 109 down-regulated DEGs/DEPs (Additional file 9: Figure S1).

Table 4 Correlation of DEGs and DEPs detected in the T. longibrachiatum H9-inoculated cucumber plants, compared to untreated plants (+T-B vs. -T-B)
Full size table
Fig. 4
figure 4

The top 20 enriched KEGG pathways based on up-regulated corresponding DEGs/DEPs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants (+T-B vs.-T-B)

Full size image

Confirmation of qRT-PCR

To evaluate the transcriptome results, several genes in the hormone pathways were selected for qRT-PCR analysis in the -T-B and + T-B groups at 96 hp. Ti, such as LOX1, LOX2, and AOS1 associated with JA, PAD4 associated with SA, as well as ACO associated with ET. The expression of these genes was significantly up-regulated in the +T-B group, compared to that in the -T-B group (Fig. 5).

Fig. 5
figure 5

The expression of hormone-related genes was up-regulated in cucumber plants inoculated with T. longibrachiatum H9. Among these expressed genes, LOX1, LOX2, and AOS1 were associated with JA; PAD4 was associated with SA; and ACO was associated with ET (* and ** indicate significance at P < 0.05 and 0.01)

Full size image

JA and SA content analysis

Based on the transcriptome and proteome results, the key enzymes in JA and SA biosynthesis were up-regulated at both the RNA and protein levels. Therefore, the JA and SA contents in cucumber leaves were analyzed in the -T-B and + T-B groups at 96 hpTi. The SA content increased to 137.29 ± 1.8120 ng/g, and the JA content rose to 151.45 ± 0.0403 ng/g in the +T-B group (Table 5). The JA and SA contents significantly increased in the T. longibrachiatum H9-inoculated cucumber plants, compared to that in the untreated plants. These results implied that JA and SA played important roles in regulating the plant response and enhancing plant defense in cucumber plants with T. longibrachiatum H9 inoculation.

Table 5 The JA and SA contents in cucumber leaves significantly increased after inoculation of T. longibrachiatum H9 on the roots
Full size table

Discussion

In this study, we demonstrated that inoculation of T. longibrachiatum H9 to the cucumber roots triggered an increased resistance to the leaf pathogen B. cinerea, which is characterized by the reduction of the disease incidence. The effect of T. longibrachiatum H9 on induction of defense response was monitored through both the transcriptome and proteome analyses. More specifically, further comparison and analysis of transcriptome and proteome data provided a more reliable basis to illustrate the biocontrol mechanism of T. longibrachiatum H9 induced systemic resistance against B. cinerea. Finally, the following conclusions could be drawn by analyzing our findings and the earlier findings from other researchers.

Plants respond to Trichoderma by hormone production or signaling

It is known that phytohormones play an important role in the regulation of defense responses in plants. Generally, ISR induced by non-pathogen organisms relies on JA signaling, while pathogen-induced SAR is dependent on SA signaling. In recent years, many reported studies have demonstrated that multiple hormones may be involved in shaping ISR [8, 10, 15,16,17,18,19,20,21,22,23]. Thus, the current view on the specific hormones involved in ISR remains controversial, and the mechanism of ISR seems more complicated. Mathys et al. (2012) found that the SA pathway was a first player in the T. hamatum T382-triggered ISR-prime in A. thaliana, and SA was synthesized from chorismate rather than phenylalanine. The JA-pathway was not activated at 48 hp. Ti in the T. hamatum T382-preinoculated plants without a subsequent infection, and B. cinerea challenge caused a clear activation of the JA pathway for ISR-boost [8]. Meanwhile they defined ISR-prime phase as the process of the initial Trichoderma-plant interaction and ISR-boost phase as the effects by Trichoderma on plant responses after subsequent challenge.

However, Shoresh et al. (2010) mentioned that the presence of non-pathogenic Trichoderma may prime the systemic resistance system, which means that the entire pathway may not be turned on constantly, and the plant will react more rapidly or more strongly in a subsequent pathogen infection. Specifically, the priming is not an universal phenomenon in all the Trichoderma-plant interactions, for example, T. harzianum T22 inoculation caused a constitutive turning on of some PR proteins in maize plants even without any pathogen [15, 48]. Applying specific inhibitors and analyzing the expression of key genes in the JA/ET signaling demonstrated that JA/ET were involved in the protective effect triggered by T. asperellum T203 against P. syringae pv. Lachrymans. Remarkably, the Lox1, involved in JA production, was hardly expressed in leaves and only clearly induced in roots with T. asperellum T203 inoculation before pathogen infection. In contrast, no difference of SA content in both roots and leaves were observed in the T. asperellum T203 pre-inoculated cucumber plants, regardless of whether the plants was infected with P. syringae pv. Lachrymans or not [10]. Our results showed that both JA/ET and SA production and/or signaling activation were observed as important plant responses in the Trichoderma-inoculated cucumber plants. Specifically, some points in our results differed from earlier findings: (i) the key components of the JA/ET and SA pathways were clearly detected in cucumber leaves and significantly up-regulated 96 h post T. longibrachiatum H9 inoculation without the subsequent infections, such as LOX (lipoxygenase), AOS (allene oxide synthase) and ACX (acyl-CoA oxidase) associated with JA synthesis, and metK (S-adenosylmethionine synthetase), ACS (aminocyclopropane carboxylate synthase) and ACO (aminocyclopropane carboxylate oxidase) associated with ET synthesis, as well as PAD4 (phytoalexin deficient 4) and PAL (phenylalanine ammonia-lyase) associated with SA synthesis. (ii) The expression of PALs rather than SID2/ICS2 was up-regulated at both gene and protein levels, indicating that SA was synthesized via the phenylalanine pathway rather than from chorismate pathway for T. longibrachiatum H9-induced ISR. The discrepancy among different researches suggested that the specific hormones involved may vary and behave differently in different plant-Trichoderma interactions, under different conditions and at different time points. However, the two points remain unknown in our study and require further investigation: (i) whether the additional pathogen B. cinerea challenge induces a higher plant response in the T. longibrachiatum H9-inoculated plants (whether the priming occurs or not), (ii) whether B. cinerea induces the plant response by itself or in the Trichoderma-mediated manner.

Plants respond to Trichoderma by producing secondary metabolites

The production of secondary metabolites, especially phytoalexins, is an important plant defense strategy against pathogens. Phenylpropanoid compounds are precursors to a wide range of antimicrobial phenolics, including lignins, flavonoids, isoflavonoids and cumarins. These compounds are induced in response to microbial attack and can inhibit the growth of attacking pathogens [3, 49]. The phenylpropanoid pathway is the major source of the production of antimicrobial phenolic compounds. Several genes of the phenylpropanoid pathway have been found to be up-regulated in A. thaliana after inoculation with T. asperelloides T203, including PAL1, PAL2 and 4CL [26]. Camalexin, as an important secondary metabolite, accumulated in A. thaliana seedlings colonized with Trichoderma virens [29]. The biosynthesis of anthocyanins was increased in A. thaliana roots after inoculation of T. hamatum T382 [8]. In our results, the biosynthesis and metabolism processes of phenylpropanoid, flavonoid, lignin, coumarine, anthocyanin and some other secondary metabolites were activated, which implied that secondary metabolites play important roles for induced plant resistance in the T. longibrachiatum H9-inoculated cucumber plants.

Additionally, the antimicrobial activity of lipid transfer proteins (LTPs) in plant defense has also been reported against pathogens in numerous studies, probably due to their ability to interact with biological membranes, which may cause membrane permeabilization [50]. Proteome analysis and various transcriptome studies have also revealed altered expression of LTPs in plants inoculated with Trichoderma strains. In our study, lipid oxidation and lipid catabolic processes were also up-regulated in the T. longibrachiatum H9-inoculated cucumber plants, which indicated the possible importance of LTPs in the defense against B. cinerea in cucumber.

A hypothetical working process in cucumber plants with T. longibrachiatum H9 inoculation

MAMP (microbe-associated molecular pattern)-triggered immunity (MTI) and effector-triggered immunity (ETI) have been reported as two models of innate immunity in plants. Trichoderma can produce MAMPs as elicitors to activate plant defense responses. Plants deploy pattern recognition receptors (PRRs) to recognize the elicitors and activate a primary defense response [7, 41, 51,52,53,54]. Two MAMP/PRR pairs have been well characterized in Trichoderma spp. and plants. The first is ethylene-inducing-xylanase (Xyn2 or Eix) as the elicitor and its corresponding receptor EIX2 [55]. The second is chitin as the elicitor and its corresponding receptor CERK1 (chitin elicitor receptor-like kinase 1) [56]. Successful pathogens will deploy effectors to interfere with MTI and induce ETI which is based on the highly specific interaction of the pathogen effectors and their corresponding NB-LRR class receptors encoded by plant resistance (R) genes. Several transcriptomic and proteomic studies have reported that plant interactions with various Trichoderma spp. resulted in the up-regulation of cytoplasmic NBS/leucine rich repeat receptors (NBS/LRRs) [57, 58], suggesting that Trichoderma spp. can also induce ETI to activate plant defense.

In our results, LRRs, CDPKs, calcium-transporting ATPases and some other elicitor-responsive proteins were up-regulated, which indicated that MTI and ETI immunity systems may exist in the T. longibrachiatum H9-inoculated cucumber plants. Moreover, a wide array of plant responses including the activation of MAPK signaling cascades, phytohormone responses, defense/stress-related responses and the production of secondary metabolites, was discovered at the transcription and protein levels. Based on the results, we developed a hypothetical working model in which T. longibrachiatum H9 inoculation enhanced plant resistance in cucumber to effectively antagonize B. cinerea. Inoculation of T. longibrachiatum H9 to cucumber roots resulted in the induction of LRRs and CDPKs and other elicitor-responsive proteins, which are known as specific determinants of the plant immune response to deliver the signal of perception. Subsequently, MAPKs and WRKYs were activated as an early plant response. The induction of the MAPK signaling cascade is known to regulate diverse downstream signaling pathways and convert extracellular signals into intracellular responses [15]. Furthermore, the synthesis and signaling of phytohormones (JA/ET and SA) were activated to translate Trichoderma-induced signaling into the activation of effective defense responses. Consequently, a whole array of defense/stress-related genes and proteins, e.g., several types of detoxifying enzymes for ROS scavenging were up-regulated in the cucumber leaves post T. longibrachiatum H9 inoculation of the roots, thus rendering the cucumber plants more resistant to subsequent B. cinerea attack. Along with other defense strategies, the production of secondary metabolites was also employed as an important plant defense strategy. Finally, these responses would provide cucumber plants with induced resistance to effectively decrease gray mold caused by B. cinerea (Fig. 6).

Fig. 6
figure 6

A hypothetical working process in cucumber plants with T. longibrachiatum H9 inoculation. LRRs as well as CDPKs and other elicitor-responsive proteins were induced in the Trichoderma H9-inoculated cucumber plants to deliver the signal of perception. Subsequently, MAPK cascades were activated to regulate diverse downstream signaling pathways. Furthermore, phytohormone synthesis and signaling (JA/ET and SA) were activated to translate Trichoderma-induced signaling into the activation of effective defense responses. Consequently, a whole array of defense/stress-related genes and proteins, e.g. a variety of detoxifying enzymes for ROS scavenging, were up-regulated, thus rendering the cucumber plants more resistant to subsequent B. cinerea infection. Along with other defense strategies, the production of secondary metabolites was also employed as an important plant defense strategy

Full size image

Conclusions

Root colonization of T. longibrachiatum H9 in the outer layer of epidermis effectively promoted plant growth and reduced the disease index of gray mold caused by B. cinerea in cucumber. Furthermore, the large-scale, multi-omics datasets indicated that T. longibrachiatum H9 inoculation modulated the defense network and resulted in an enhanced defensive capacity in cucumber plants, probably through the activation of signaling pathways associated with the phytohormones JA/ET and SA.

References

  1. Dean R, Van Kan JA, Pretorius ZA, Hammond-Kosack KE, Di Pietro A, Spanu PD, Rudd JJ, Dickman M, Kahmann R, Ellis J, Foster GD. The top 10 fungal pathogens in molecular plant pathology. Mol Plant Pathol 2012; 13(4):414–430.

  2. Yun HG, Kim DJ, Gwak WS, Shin TY, Woo SD. Entomopathogenic Fungi as dual control agents against both the Pest Myzus persicae and Phytopathogen Botrytis cinerea. Mycobiology. 2017;45(3):192–8.

    Article  PubMed  PubMed Central  Google Scholar 

  3. Harman GE, Howell CR, Viterbo A, Chet I, Lorito M. Trichoderma species--opportunistic, avirulent plant symbionts. Nat Rev Microbiol. 2004;2(1):43–56.

    Article  CAS  PubMed  Google Scholar 

  4. Glare TR, Gwynn RL, Moran-Diez ME. Development of biopesticides and future opportunities. Methods Mol Biol. 2016;1477:211–21.

    Article  CAS  PubMed  Google Scholar 

  5. Druzhinina IS, Seidl-Seiboth V, Herrera-Estrella A, Horwitz BA, Kenerley CM, Monte E, Mukherjee PK, Zeilinger S, Grigoriev IV, Kubicek CP. Trichoderma: the genomics of opportunistic success. Nat Rev Microbiol. 2011;9(10):749–59.

    Article  CAS  PubMed  Google Scholar 

  6. Mukherjee PK, Horwitz BA, Kenerley CM. Secondary metabolism in Trichoderma--a genomic perspective. Microbiology 2012; 158(Pt 1):35–45.

  7. Vos CM, De Cremer K, Cammue BP, De Coninck B. The toolbox of Trichoderma spp. in the biocontrol of Botrytis cinerea disease. Mol Plant Pathol. 2015;16(4):400–12.

    Article  PubMed  Google Scholar 

  8. Mathys J, De Cremer K, Timmermans P, Van Kerckhove S, Lievens B, Vanhaecke M, Cammue BP, De Coninck B. Genome-wide characterization of ISR induced in Arabidopsis thaliana by Trichoderma hamatum T382 against Botrytis cinerea infection. Front Plant Sci. 2012;3:108.

    Article  PubMed  PubMed Central  Google Scholar 

  9. Harel YM, Mehari ZH, Rav-David D, Elad Y. Systemic resistance to gray mold induced in tomato by benzothiadiazole and Trichoderma harzianum T39. Phytopathology. 2014;104(2):150–7.

    Article  CAS  PubMed  Google Scholar 

  10. Shoresh M, Yedidia I, Chet I. Involvement of Jasmonic acid/ethylene signaling pathway in the systemic resistance induced in cucumber by Trichoderma asperellum T203. Phytopathology. 2005;95(1):76–84.

    Article  CAS  PubMed  Google Scholar 

  11. Alkooranee JT, Aledan TR, Ali AK, Lu G, Zhang X, Wu J, Fu C, Li M. Detecting the hormonal pathways in oilseed rape behind induced systemic resistance by Trichoderma harzianum TH12 to Sclerotinia sclerotiorum. PLoS One. 2017;12(1):e0168850.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  12. Brand M, Messika Y, Elad Y, David DR, Sztejnberg A. Spray treatments combined with climate modification for the management of Leveillula taurica in sweet pepper. Eur J Plant Pathol. 2009;124(2):309–29.

    Article  Google Scholar 

  13. Shoresh M, Gal-On A, Leibman D, Chet I. Characterization of a mitogen-activated protein kinase gene from cucumber required for trichoderma-conferred plant resistance. Plant Physiol. 2006;142(3):1169–79.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  14. Rodriguez MC, Petersen M, Mundy J. Mitogen-activated protein kinase signaling in plants. Annu Rev Plant Biol. 2010;61:621–49.

    Article  CAS  PubMed  Google Scholar 

  15. Shoresh M, Harman GE, Mastouri F. Induced systemic resistance and plant responses to fungal biocontrol agents. Annu Rev Phytopathol. 2010;48:21–43.

    Article  CAS  PubMed  Google Scholar 

  16. Moran-Diez E, Rubio B, Dominguez S, Hermosa R, Monte E, Nicolas C. Transcriptomic response of Arabidopsis thaliana after 24 h incubation with the biocontrol fungus Trichoderma harzianum. J Plant Physiol. 2012;169(6):614–20.

    Article  CAS  PubMed  Google Scholar 

  17. Van der Ent S, Van Wees SC, Pieterse CM. Jasmonate signaling in plant interactions with resistance-inducing beneficial microbes. Phytochemistry. 2009;70(13–14):1581–8.

    PubMed  Google Scholar 

  18. Martinez-Medina A, Fernandez I, Sanchez-Guzman MJ, Jung SC, Pascual JA, Pozo MJ. Deciphering the hormonal signalling network behind the systemic resistance induced by Trichoderma harzianum in tomato. Front Plant Sci. 2013;4:206.

    Article  PubMed  PubMed Central  Google Scholar 

  19. Martinez-Medina A, Fernandez I, Lok GB, Pozo MJ, Pieterse CM, Van Wees SC. Shifting from priming of salicylic acid- to jasmonic acid-regulated defences by Trichoderma protects tomato against the root knot nematode Meloidogyne incognita. New Phytol. 2017;213(3):1363–77.

    Article  CAS  PubMed  Google Scholar 

  20. Segarra G, Van der Ent S, Trillas I, Pieterse CM. MYB72, a node of convergence in induced systemic resistance triggered by a fungal and a bacterial beneficial microbe. Plant Biol (Stuttg). 2009;11(1):90–6.

    Article  CAS  Google Scholar 

  21. Mayo S, Gutierrez S, Malmierca MG, Lorenzana A, Campelo MP, Hermosa R, Casquero PA. Influence of Rhizoctonia solani and Trichoderma spp. in growth of bean (Phaseolus vulgaris L.) and in the induction of plant defense-related genes. Front Plant Sci. 2015;6:685.

    Article  PubMed  PubMed Central  Google Scholar 

  22. Korolev N, Rav David D, Elad Y. The role of phytohormones in basal resistance and Trichoderma-induced systemic resistance to Botrytis cinerea in Arabidopsis thaliana. BioControl. 2008;53:667–83.

    Article  CAS  Google Scholar 

  23. Leonetti P, Zonno MC, Molinari S, Altomare C. Induction of SA-signaling pathway and ethylene biosynthesis in Trichoderma harzianum-treated tomato plants after infection of the root-knot nematode Meloidogyne incognita. Plant Cell Rep. 2017;36(4):621–31.

    Article  CAS  PubMed  Google Scholar 

  24. Mur LA, Prats E, Pierre S, Hall MA, Hebelstrup KH. Integrating nitric oxide into salicylic acid and jasmonic acid/ ethylene plant defense pathways. Front Plant Sci. 2013;4:215.

    PubMed  PubMed Central  Google Scholar 

  25. Shoresh M, Harman GE. Differential expression of maize chitinases in the presence or absence of Trichoderma harzianum strain T22 and indications of a novel exo- endo-heterodimeric chitinase activity. BMC Plant Biol. 2010;10:136.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  26. Brotman Y, Landau U, Cuadros-Inostroza A, Tohge T, Fernie AR, Chet I, Viterbo A, Willmitzer L. Trichoderma-plant root colonization: escaping early plant defense responses and activation of the antioxidant machinery for saline stress tolerance. PLoS Pathog. 2013;9(3):e1003221.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  27. Temme N, Tudzynski P. Does botrytis cinerea ignore H(2)O(2)-induced oxidative stress during infection? Characterization of botrytis activator protein 1. Mol Plant-Microbe Interact. 2009;22(8):987–98.

    Article  CAS  PubMed  Google Scholar 

  28. Chassot C, Buchala A, Schoonbeek HJ, Metraux JP, Lamotte O. Wounding of Arabidopsis leaves causes a powerful but transient protection against Botrytis infection. Plant J. 2008;55(4):555–67.

    Article  CAS  PubMed  Google Scholar 

  29. Velazquez-Robledo R, Contreras-Cornejo HA, Macias-Rodriguez L, Hernandez-Morales A, Aguirre J, Casas-Flores S, Lopez-Bucio J, Herrera-Estrella A. Role of the 4-phosphopantetheinyl transferase of Trichoderma virens in secondary metabolism and induction of plant defense responses. Mol Plant-Microbe Interact. 2011;24(12):1459–71.

    Article  CAS  PubMed  Google Scholar 

  30. Contreras-Cornejo HA, Macias-Rodriguez L, Beltran-Pena E, Herrera-Estrella A, Lopez-Bucio J. Trichoderma-induced plant immunity likely involves both hormonal- and camalexin-dependent mechanisms in Arabidopsis thaliana and confers resistance against necrotrophic fungi Botrytis cinerea. Plant Signal Behav. 2011;6(10):1554–63.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  31. Yedidia I, Shoresh M, Kerem Z, Benhamou N, Kapulnik Y, Chet I. Concomitant induction of systemic resistance to Pseudomonas syringae pv. Lachrymans in cucumber by Trichoderma asperellum (T-203) and accumulation of phytoalexins. Appl Environ Microbiol. 2003;69(12):7343–53.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  32. Kim SH, Vujanovic V. Relationship between mycoparasites lifestyles and biocontrol behaviors against Fusarium spp. and mycotoxins production. Appl Microbiol Biotechnol. 2016;100(12):5257–72.

    Article  CAS  PubMed  Google Scholar 

  33. Pandey V, Ansari MW, Tula S, Yadav S, Sahoo RK, Shukla N, Bains G, Badal S, Chandra S, Gaur AK, Kumar A, Shukla A, Kumar J, Tuteja N. Dose-dependent response of Trichoderma harzianum in improving drought tolerance in rice genotypes. Planta. 2016;243(5):1251–64.

    Article  CAS  PubMed  Google Scholar 

  34. Nawrocka J, Malolepsza U, Szymczak K, Szczech M. Involvement of metabolic components, volatile compounds, PR proteins, and mechanical strengthening in multilayer protection of cucumber plants against Rhizoctonia solani activated by Trichoderma atroviride TRS25. Protoplasma. 2018;255(1):359–73.

    Article  CAS  PubMed  Google Scholar 

  35. Raza W, Ling N, Zhang R, Huang Q, Xu Y, Shen Q. Success evaluation of the biological control of Fusarium wilts of cucumber, banana, and tomato since 2000 and future research strategies. Crit Rev Biotechnol. 2017;37(2):202–12.

    Article  PubMed  Google Scholar 

  36. Gams W, Morphology BJ. Identification of Trichoderma. In: Kubicek CP, Harman GE, editiors. Trichoderma and gliocladium, basic biology, taxonomy and genetics. Taylor and Francis ltd, London; 1998. p. 3–34.

    Google Scholar 

  37. Kumar S, Stecher G, Tamura K. MEGA7: molecular evolutionary genetics analysis version 7.0 for bigger datasets. Mol Biol Evol. 2016;33(7):1870–4.

    Article  CAS  PubMed  Google Scholar 

  38. Yedidia II, Benhamou N, Chet II. Induction of defense responses in cucumber plants (Cucumis sativus L. ) by the biocontrol agent trichoderma harzianum. Appl Environ Microbiol 1999; 65(3):1061–1070.

  39. Li Y, Sun R, Yu J, Saravanakumar K, Chen J. Antagonistic and biocontrol potential of Trichoderma asperellum ZJSX5003 against the maize stalk rot pathogen Fusarium graminearum. Indian J Microbiol. 2016;56(3):318–27.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  40. Wang Z, Cui J, Song J, Gou M, Wang H, Gao K, Qiu X, Wang X, Chang Y. Integration of small RNAs and mRNAs by high-throughput sequencing reveals a complex regulatory network in Chinese sea cucumber, Russian sea cucumber and their hybrids. Comp Biochem Physiol Part D Genomics Proteomics. 2018;29:1–13.

    Article  PubMed  CAS  Google Scholar 

  41. Ye X, Wang H, Chen P, Fu B, Zhang M, Li J, Zheng X, Tan B, Feng J. Combination of iTRAQ proteomics and RNA-seq transcriptomics reveals multiple levels of regulation in phytoplasma-infected Ziziphus jujuba mill. Hortic Res. 2017;4:17080.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  42. Norskov NP, Kyro C, Olsen A, Tjonneland A, Knudsen KE. High-throughput LC-MS/MS method for direct quantification of Glucuronidated, sulfated, and free Enterolactone in human plasma. J Proteome Res. 2016;15(3):1051–8.

    Article  PubMed  CAS  Google Scholar 

  43. Druzhinina IS, Komon-Zelazowska M, Kredics L, Hatvani L, Antal Z, Belayneh T, Kubicek CP. Alternative reproductive strategies of Hypocrea orientalis and genetically close but clonal Trichoderma longibrachiatum, both capable of causing invasive mycoses of humans. Microbiology 2008; 154(Pt 11):3447–3459.

  44. Jaklitsch WM, Voglmayr H. Hypocrea britdaniae and H. Foliicola: two remarkable new European species. Mycologia. 2012;104(5):1213–21.

    Article  PubMed  PubMed Central  Google Scholar 

  45. Kredics L, Kocsube S, Nagy L, Komon-Zelazowska M, Manczinger L, Sajben E, Nagy A, Vagvolgyi C, Kubicek CP, Druzhinina IS, Hatvani L. Molecular identification of Trichoderma species associated with Pleurotus ostreatus and natural substrates of the oyster mushroom. FEMS Microbiol Lett. 2009;300(1):58–67.

    Article  CAS  PubMed  Google Scholar 

  46. Jaklitsch WM. European species of Hypocrea part I. The green-spored species. Stud Mycol. 2009;63:1–91.

    Article  PubMed  PubMed Central  Google Scholar 

  47. Jaklitsch WM. European species of Hypocrea part II: species with hyaline ascospores. Fungal Divers. 2011;48(1):1–250.

    Article  PubMed  PubMed Central  Google Scholar 

  48. Shoresh M, Harman GE. The molecular basis of shoot responses of maize seedlings to Trichoderma harzianum T22 inoculation of the root: a proteomic approach. Plant Physiol. 2008;147(4):2147–63.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  49. Huang J, Gu M, Lai Z, Fan B, Shi K, Zhou YH, Yu JQ, Chen Z. Functional analysis of the Arabidopsis PAL gene family in plant growth, development, and response to environmental stress. Plant Physiol. 2010;153(4):1526–38.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  50. Sels J, Mathys J, De Coninck BM, Cammue BP, De Bolle MF. Plant pathogenesis-related (PR) proteins: a focus on PR peptides. Plant Physiol Biochem. 2008;46(11):941–50.

    Article  CAS  PubMed  Google Scholar 

  51. Zipfel C, Kunze G, Chinchilla D, Caniard A, Jones JD, Boller T, Felix G. Perception of the bacterial PAMP EF-Tu by the receptor EFR restricts agrobacterium-mediated transformation. Cell. 2006;125(4):749–60.

    Article  CAS  PubMed  Google Scholar 

  52. Svoboda J, Boland W. Plant defense elicitors: analogues of jasmonoyl-isoleucine conjugate. Phytochemistry. 2010;71(13):1445–9.

    Article  CAS  PubMed  Google Scholar 

  53. Pare PW, Farag MA, Krishnamachari V, Zhang H, Ryu CM, Kloepper JW. Elicitors and priming agents initiate plant defense responses. Photosynth Res. 2005;85(2):149–59.

    Article  CAS  PubMed  Google Scholar 

  54. Sarrocco S, Matarese F, Baroncelli R, Vannacci G, Seidl-Seiboth V, Kubicek CP, Vergara M. The constitutive Endopolygalacturonase TvPG2 regulates the induction of plant systemic resistance by Trichoderma virens. Phytopathology. 2017;107(5):537–44.

    Article  CAS  PubMed  Google Scholar 

  55. Hanson LE, Howell CR. Elicitors of plant defense responses from biocontrol strains of Trichoderma viren. Phytopathology. 2004;94(2):171–6.

    Article  CAS  PubMed  Google Scholar 

  56. Petutschnig EK, Jones AM, Serazetdinova L, Lipka U, Lipka V. The lysin motif receptor-like kinase (LysM-RLK) CERK1 is a major chitin-binding protein in Arabidopsis thaliana and subject to chitin-induced phosphorylation. J Biol Chem. 2010;285(37):28902–11.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  57. Palmieri MC, Perazzolli M, Matafora V, Moretto M, Bachi A, Pertot I. Proteomic analysis of grapevine resistance induced by Trichoderma harzianum T39 reveals specific defence pathways activated against downy mildew. J Exp Bot. 2012;63(17):6237–51.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  58. Perazzolli M, Moretto M, Fontana P, Ferrarini A, Velasco R, Moser C, Delledonne M, Pertot I. Downy mildew resistance induced by Trichoderma harzianum T39 in susceptible grapevines partially mimics transcriptional changes of resistant genotypes. BMC Genomics. 2012;13:660.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

Download references

Acknowledgements

We thank Dr. Kyle Bender from TSL (The Sainsbury Laboratory) for the in-depth revision of the manuscript, and Dr. Jihong Xing from Hebei Agricultural University for the B. cinerea strain donation. We also would like to thank LetPub (www.letpub.com) for providing linguistic assistance.

Consent to publication

Not applicable.

Funding

This work was financially supported by the Key Fundamental Research Program of Hebei Province (15962904D), the National Water Pollution Control and Treatment Science and Technology Major Project of China (2015ZX07204–007), and National Natural Science Foundation of China (31401212). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Availability of data and materials

The data supporting the results of this study are included in the manuscript and additional supporting files. Raw data from transcriptome analysis by RNA-Seq have been deposited into the Sequence Read Archive database with the accession number SRP136435. Raw data from translatome analysis by iTRAQ mass spectrometry have been deposited into iProX (ww.iprox.org) with ID IPX0001185000/PXD009314.

Author information

Author notes

  1. Min Yuan and Yuanyuan Huang contributed equally to this work.

Authors and Affiliations

  1. College of Life Sciences, North China University of Science and Technology, Tangshan, 063210, People’s Republic of China

    Min Yuan, Weina Ge & Lan Zhang

  2. Biology Institute, Hebei Academy of Sciences, Shijiazhuang, 050081, People’s Republic of China

    Yuanyuan Huang, Zhenhua Jia, Shuishan Song & Yali Huang

Authors
  1. Min Yuan
    View author publications

    You can also search for this author in PubMed Google Scholar

  2. Yuanyuan Huang
    View author publications

    You can also search for this author in PubMed Google Scholar

  3. Weina Ge
    View author publications

    You can also search for this author in PubMed Google Scholar

  4. Zhenhua Jia
    View author publications

    You can also search for this author in PubMed Google Scholar

  5. Shuishan Song
    View author publications

    You can also search for this author in PubMed Google Scholar

  6. Lan Zhang
    View author publications

    You can also search for this author in PubMed Google Scholar

  7. Yali Huang
    View author publications

    You can also search for this author in PubMed Google Scholar

Contributions

YLH conceived and designed the project. MY and YYH performed the experiments. MY and YLH wrote the manuscript. WNG, ZHJ, SSS and LZ participated in data discussion and data analysis. All authors have read and approved the final manuscript.

Corresponding author

Correspondence to Yali Huang.

Ethics declarations

Ethics approval and consent to participate

The authors confirm that the seeds of cucumber (Cucumis sativus L.) were purchased from Tianjin Kernel Cucumber Research Institute (Tianjin, China). All experiments were conducted in accordance with the local legislation for plant material handling.

Competing interests

The authors declare that there are no conflicts of interest.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Additional files

Additional file 1:

Table S1. The primer sequences for the PCR amplification. (DOC 58 kb)

Additional file 2:

Table S2. Enriched GO terms based on up-regulated DEGs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants. (XLS 1111 kb)

Additional file 3:

Table S3. Enriched GO terms based on up-regulated DEPs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants. (XLS 960 kb)

Additional file 4:

Table S4. Enriched GO terms based on down-regulated DEGs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants. (XLS 439 kb)

Additional file 5:

Table S5. Enriched GO terms based on down-regulated DEPs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants. (XLS 459 kb)

Additional file 6:

Table S6. Enriched KEGG pathways based on up-regulated DEGs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants. (XLS 56 kb)

Additional file 7:

Table S7. Enriched KEGG pathways based on up-regulated DEPs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants. (XLS 51 kb)

Additional file 8:

Table S8. The list of DEGs/DEPs with the same expression trends. (XLS 134 kb)

Additional file 9:

Figure S1. The top 20 enriched KEGG pathways based on down-regulated DEGs/DEPs in the T. longibrachiatum H9-inoculated plants in comparison to untreated plants (+T-B vs.-T-B). (DOCX 14 kb)

Rights and permissions

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Yuan, M., Huang, Y., Ge, W. et al. Involvement of jasmonic acid, ethylene and salicylic acid signaling pathways behind the systemic resistance induced by Trichoderma longibrachiatum H9 in cucumber. BMC Genomics 20, 144 (2019). https://0-doi-org.brum.beds.ac.uk/10.1186/s12864-019-5513-8

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://0-doi-org.brum.beds.ac.uk/10.1186/s12864-019-5513-8

Keywords

BMC Genomics

ISSN: 1471-2164

Contact us