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Review

Trichoderma and the Plant Heritable Priming Responses

by
María E. Morán-Diez
*,
Ángel Emilio Martínez de Alba
,
M. Belén Rubio
,
Rosa Hermosa
and
Enrique Monte
Department of Microbiology and Genetics, Spanish-Portuguese Institute for Agricultural Research (CIALE), University of Salamanca, Villamayor, 37185 Salamanca, Spain
*
Author to whom correspondence should be addressed.
J. Fungi 2021, 7(4), 318; https://doi.org/10.3390/jof7040318
Submission received: 11 March 2021 / Revised: 15 April 2021 / Accepted: 16 April 2021 / Published: 19 April 2021
(This article belongs to the Special Issue Advances in Trichoderma-Plant Beneficial Interactions)
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Abstract

:
There is no doubt that Trichoderma is an inhabitant of the rhizosphere that plays an important role in how plants interact with the environment. Beyond the production of cell wall degrading enzymes and metabolites, Trichoderma spp. can protect plants by inducing faster and stronger immune responses, a mechanism known as priming, which involves enhanced accumulation of dormant cellular proteins that function in intracellular signal amplification. One example of these proteins is the mitogen-activated protein kinases (MAPK) that are triggered by the rise of cytosolic calcium levels and cellular redox changes following a stressful challenge. Transcription factors such as WRKYs, MYBs, and MYCs, play important roles in priming as they act as regulatory nodes in the transcriptional network of systemic defence after stress recognition. In terms of long-lasting priming, Trichoderma spp. may be involved in plants epigenetic regulation through histone modifications and replacements, DNA (hypo)methylation, and RNA-directed DNA methylation (RdDM). Inheritance of these epigenetic marks for enhanced resistance and growth promotion, without compromising the level of resistance of the plant’s offspring to abiotic or biotic stresses, seems to be an interesting path to be fully explored.

1. Introduction

Trichoderma is one of the most studied genera of ascomycetous fungi because of the importance of the practical applications and particular skills of the species that compose it [1,2]. Possibly, its main characteristic is the ability to exert positive effects on plants by means of the production of cell wall degrading enzymes (CWDE) [3] and metabolites with antimicrobial activity [4], and the release of volatile organic compounds (VOC) [5,6], which can act together as direct biocontrol agents on phytopathogenic fungi, oomycetes, nematodes, and bacteria [7]. Trichoderma spp. also compete with other plant beneficial microbes and impact the arbuscular mycorrhizal fungi (AMF) abundance in bulk soil microbiomes in agricultural systems [8]. In this sense, a single application of T. harzianum increased the rhizosphere levels and facilitated the access of AMF to the roots of the host (e.g., wheat) [8] and non-host (e.g., rapeseed, Arabidopsis) [9] plants. Trichoderma spp. can also act as indirect biocontrol agents by activating systemic immune responses in a coordinated way [10], resulting in faster and stronger induction of plant basal resistance mechanisms upon the perception of a later triggering stimulus. This phenomenon is known as priming of defence [11] and Trichoderma can provide the plant with long-lasting resistance against biotic and abiotic stresses by balancing the different phytohormone-dependent pathways—among which salicylic acid (SA), jasmonates (JA), ethylene (ET), abscisic acid (ABA), auxin (indole-3-acetic acid: IAA), and gibberellins (GA) are the most relevant—and modulating the levels of growth and defence regulatory proteins [12]. The advantage to the plant being primed for particular stress responses is in facilitating a faster and stronger reaction if the stress recurs [13]. Reinforced responses to pathogen attacks come under the category of induced defence, while responses to abiotic stresses are referred to as acclimation or hardening, even though these responses are very similar in their genesis and can also be enhanced by priming treatments [13]. An accurate definition of how Trichoderma exerts its beneficial action on plants is of particular relevance to the way in which commercial products based on the abilities of Trichoderma are registered.
Regardless of whether Trichoderma is recognized by the plant through cell-surface pattern recognition receptors (PRRs), priming involves multiple cellular localizations of targets such as: (i) inactive metabolites stored in vacuoles, which can be hydrolysed and released into the cytoplasm; (ii) reactive oxygen species (ROS) that can also interact with phytohormone-dependent pathways in the cytoplasm; and (iii) epigenetic changes that occur in the nucleus [14]. Cascades of mitogen-activated protein kinases (MAPK) and Ca2+-dependent protein kinases (CDPK, especially related to plant growth regulation and acclimation, [15]) function downstream of the ligand binding and the subsequent PRR activation and transmit extracellular priming stimuli into intracellular responses, while amplifying at the same time the transduction signals to the nucleus, resulting in transcriptional reprogramming, callose deposition, and, ultimately, synthesis of hormones and activation of defence-related genes [16].
Priming involves enhanced accumulation of dormant cellular proteins functioning in intracellular signal amplification [11,17], as is the case with: (i) signalling proteins in an inactive configuration that are activated upon exposure to stress, as occurs with MAPKs being triggered by the rise of cytosolic Ca2+ levels and cellular redox changes following a stressful challenge; (ii) transcription factors (TF) (e.g., auxin response factors (ARF), ethylene response factors (ERF), MYBs, MYCs, WRKYs) acting as regulatory nodes in the transcriptional network of systemic defence after stress recognition; and (iii) epigenetic regulation involving histone modifications and replacements, DNA (de)methylation, and RNA-directed DNA methylation (RdDM) [13,14,16,17,18,19,20].
In plant–Trichoderma systems, the actions of one trigger counteract the other. We refer to a dynamic process, which follows its own zig-zag defence model [1], in which four timing stages might be identified—Stage 1: the plant’s early perception of Trichoderma that only lasts a few hours; Stage 2: cell signalling, giving rise to systemic defence responses that can reach several days, gradually decaying in weeks; Stage 3: long-lasting priming; Stage 4: transgenerational inheritance. The latter two stages last from a few weeks to the offspring stage. Here, based on our own and other authors’ experimental evidence, we want to present how plants respond to the stimuli caused by Trichoderma, stressing that such responses are transmitted onto the progeny, in terms of different types of defence, acclimation, and growth control.

2. Plant’s Early Perception of Trichoderma

It has been observed that the root endospheric microbial community is less diverse than that of the rhizosphere, which indicates that many fungi in the rhizosphere might be trying to enter the plant, but only a few among them are allowed and prove successful [8,21]. This is the case for Trichoderma that manages to use the needed mechanisms in order to achieve its aims. Trichoderma activates PRRs by means of microbe- or damage-associated molecular patterns (MAMP or DAMP), apoplastic effectors, and a variety of VOCs [12,22,23,24]. Then, oxidative burst, callose deposition, and Ca2+ and ROS signalling are initiated rapidly following the attack because, at that point in its perception of Trichoderma, the plant does not recognize that it is a friendly attack. Secreted Trichoderma molecules are sensed by plant cells through intracellular Ca2+ changes that lead to not only intracellular ROS accumulation but to the necessary adjustments to prime defence mechanisms [25]. Figure 1 summarizes some of the main effects and responses triggered during the early interaction between the plant and Trichoderma. It is well established that G-proteins located within the cell membrane can be the linkage between host-derived signals and Trichoderma-intracellular signalling pathways, resulting in an increase in mycoparasitism-relevant processes such as the production of fungal CWDEs and antifungal metabolites, and the formation of infection structures [26]. Although the activation of G-protein signalling is different in animals and fungi than in plants, it can be thought that G-proteins may play a role in the recognition of Trichoderma by the plant. In this way, heterotrimeric G-proteins function as a convergence point of plant defence signalling by mediating responses initiated by the activation of different PRRs, as is the case of systemically transmitted stomatal closure, ROS production, or callose deposition at the cell wall [27]. There is also evidence for the role of G-protein-dependent regulation downstream of PRRs in plant growth and development [28], which indicates a molecular mechanism of G-protein recognition and signalling activation/deactivation compatible with the effects that Trichoderma has on plants. This fact constitutes a promising line of research to understand the initial dialogue between Trichoderma and the plant.
Most of the work on Trichoderma–plant interactions has been carried out in root systems. However, it should not be forgotten that many Trichoderma strains live and can be isolated from the aboveground parts of the plant [29], where they endophytically colonize leaves and stems [30]. Some strains of Trichoderma are effective in the direct control of pathogens in the phyllosphere, although their mechanism of action seems to be linked more to induced resistance and mycoparasitism than to direct competition [31]. Selected Trichoderma strains may also release VOCs related to plant growth promotion [32] but may also be involved in reducing energy losses and inducing photosynthesis and resistance to foliar pathogens, such as those producing powdery mildew [33]. Even endophytic Trichoderma strains can mitigate the negative impact of leaf-cutting ants in both agriculture and silviculture due to the potential to act as bodyguards to their plant hosts affording protection to the whole plant [34].
ROS production is one of the earliest responses, starting only a few minutes after the PRRs switch on, although, it also occurs later when the defence is already established, but at a much slower pace. ROS have been proposed to act as antimicrobials, as cross-linkers of the plant cell wall to block pathogen entry, and as local and systemic secondary messengers to trigger additional immune and developmental responses [35]. When colonizing the roots, Trichoderma spp. go beyond the oxidative burst generated as an early defence response by the plant. So, Trichoderma strains take advantage of their ability to compete in the rhizosphere, since they have the particularity of tolerating high levels of ROS [36] and even produce ROS by themselves, which in return facilitates the biocontrol activity against pathogens, most of them with a lower range of oxidative stress tolerance [37]. The establishment of Trichoderma in the root tissues may be fostered by the action of plant CWDEs such as hemicellulases and polygalacturonases. In T. harzianum, endopolygalacturonase activity was required for active root colonization and the release of oligogalacturonides, oligomers of α-1,4-linked galacturonic acid generated by the partial hydrolysis of pectin, capable of acting as DAMPs to activate the systemic defences against the necrotrophic leaf pathogenic fungus Botrytis cinerea [38]. During the colonization of the root, SA is the key phytohormone to reinforce plant cell walls, restricting Trichoderma to the apoplast and preventing the arrival to the vascular system. The important role of SA in Trichoderma root colonization was demonstrated with Arabidopsis sid2 mutants unable to synthesize SA, as plants lacking this phytohormone did not accumulate callose and allowed the dissemination of Trichoderma in the vascular ring and the upward movement to the aboveground part of the plant, which would lead to a subsequent collapse [39]. Therefore, it seems clear that Trichoderma has to cope with the oxidative burst, callose deposition, and SA-signalized immunity during the first hours of the interaction, when the early SA-dependent defence response may not reach its full potential. This struggle allows Trichoderma to colonize the root, although the down-regulation of SA would reach a balanced level where there is no indiscriminate spread of the fungus [22]. Thus, one of the first tasks Trichoderma needs to do is to accurately overcome and counteract the plant’s initial defences. In this regard, we have observed a strong down-regulation of the SA-responsive PATHOGENESIS-RELATED (PR) PROTEIN 1 (PR-1) gene after 6 h of cultivating Arabidopsis in the presence of T. harzianum [40], and it has also been reported as early as after 4 h of ArabidopsisTrichoderma interaction, as a strong down-regulation of the SA-related ENHANCED DISEASE SUSCEPTIBILITY 1 (EDS1) gene. EDS1 operates upstream of SA-dependent defences and is required early to accumulate SA, although it is also required later to generate the plant hypersensitive response (HR) to prevent the spread of infection by microbial pathogens [41]. SA production is not the only defence mechanism limited early on by the effect of Trichoderma. Syntheses of lipid barrier polymers and signalling during pathogen attack [42] are down-regulated in Arabidopsis root tissues 24 h post inoculation (hpi) with T. harzianum [40]. In this way, the rapid and local silencing of early plant defence response enables Trichoderma to establish symbiotic interactions, as it has been observed for other symbiotic systems [43]. The down-regulation of PR proteins in maize seedling roots treated with T. afroharzianum is in agreement with the local silencing of defence genes to allow fungal growth into the roots [44]. However, following the decrease of defences in Arabidopsis root colonized by Trichoderma, the expression of both PR-1 and EDS1 genes was increased as early as 48 h [40]. In addition, the accumulation of PR proteins and catalase (CAT) activity increased in both the roots and leaves of cucumber seedlings at 48 hpi with T. asperelloides T203 [45]. Corroborating this fact, it has also been described that tomato plants showed a sharped increase in the expression of the PR-1b1 gene at 72 hpi with T. longibrachiatum [46].
Based on the assumptions that each plant–Trichoderma interaction is very particular, that different activations of defence-related genes occur among Trichoderma strains against the same pathogen [47], and that it is difficult to establish a specific time point when early defence responses end, it has been proposed that 48 hpi would indicate the moment of transition when the plant reprograms its transcriptional machinery mainly towards redox and defence processes, fully accepting that Trichoderma is not an enemy [48]. There is no doubt that Trichoderma needs to minimize levels of SA-dependent defence responses—or at least prevent them from rising—but the maintenance of certain levels of SA is also very important in the establishment of an early oxidative burst. ROS generation, including superoxide anions and H2O2, is indicative of early defence response activation since they do not only act directly as toxic agents against the host plant cells but also against the pathogens by killing them or ceasing their virulent activity [49]. SA increases the accumulation of H2O2 in plants after pathogen infection. However, as observed in the first 24–48 h of tomato–T. erinaceum interaction, plants challenged with Trichoderma accumulated H2O2 at lower levels than those detected in plants infected with the pathogen Fusarium oxysporum f. sp. lycopersici (FOL) [50]. Similarly, a marked reduction in the H2O2 levels during the first 3–24 h of interaction between tomato plants and T. asperellum allowed the explanation of the protective effects exerted by Trichoderma against F. oxysporum and B. cinerea HR-like lesions [51]. These two cases may serve to illustrate that the plant accepts Trichoderma better than the pathogen.
Nevertheless, SA also plays opposite roles in preventing the damage to plants against oxidative stress by inducing the production of detoxifying enzymes such as CAT, superoxide dismutase (SOD), ascorbate peroxidase (APx), or glutathione S-transferase (GST), which reduce the accumulation of ROS as these molecules are not positive for plant cells either. We have observed that a GST gene strongly induced by SA, which participates in ROS detoxification, reinforcement of cell walls, formation of phytoalexins, and degradation of various toxic substances [52], was down-regulated in Arabidopsis plants at 24 hpi with T. harzianum [40]. In this sense, the treatment of Arabidopsis roots with T. harzianum activated, in just 4 h, the expression of the CYP71A12 gene encoding a cytochrome P450 required in the biosynthesis of phytoalexins, reached the maximum peak of expression at 24 hpi but experienced a subsequent drop after that point [53]. In the tomato–T. erinaceum study, the CAT and SOD enzymatic activities were higher in primed plants than in those unprimed with Trichoderma under FOL challenged conditions [50]. In addition, SOD rose from 24 to 48 h with a drop to 72 h, while CAT dropped to 48 h and rose sharply to 72 h. A maize–T. guizhouense study [54] found that H2O2 was accumulated in maize tissues at 24 hpi in the interaction with Trichoderma. Additionally, the expression of the auxin synthesis related gene YUC4, was down-regulated at 12 hpi and at 48 hpi, with a peak of expression at 24 hpi, which indicates a decline in SA-dependent defences and lateral root growth. The examples of the undulating behaviour of plant responses given here can be explained by SOD gene up-regulation resulting in diminished ROS activity and therefore higher accumulation of H2O2, which in turn, induces subsequent CAT activity. After the initial oxidative burst, plant performance would be justified because ROS also functions at longer times as signalling regulators of growth and mitigation of biotic and abiotic stresses. If to all this we add that Trichoderma produces its own ROS to compete with other inhabitants of the rhizosphere [37], it would seem clear that Trichoderma works by fine-tuning the levels of ROS in the plant.

3. Systemic Plant Responses to Trichoderma

Stage 2 does not have a fixed starting time but depending on the system under study, it is considered not to start after 48–72 h of Trichoderma being applied. Upon root colonization, the plant produces a phytohormone blend (as a result of a series of transcription cascades that mainly involve SA, JA, and ET but also ABA, IAA, and GA signalling pathways) that constitutes the Trichoderma signal signature [10]. The signalling pathways that are activated by the endogenous accumulation of these phytohormone signals not only regulate the plant’s dialogue with Trichoderma but also contribute to deploying different active defence responses that are effective against distinct classes of attackers [55]. The effectiveness of the contribution of Trichoderma to protecting plants will depend on how the pathogens may have evolved to manipulate plants for their own benefit, interfering with the plant’s defence-signalling network [47]. At 72 hpi, changes in SA-induced defences may contribute to hindering further Trichoderma penetration but may also be indicating induced priming against other attackers [48]. Once the colonization has begun, the Trichoderma growth inside roots is restricted to the intercellular spaces of the cortex and epidermis, because callose deposition prevents access to the vascular bundles [45]. The endophytic accumulation of Trichoderma will also act as a physical barrier to prevent the movement of the pathogen in the plant [56]. Trichoderma strains from different species can colonize the rhizosphere and grow within the root tissue not only without causing damage but while priming plants against biotic and abiotic stresses [2].
It has been observed that upon challenge exposure to stress stimuli, elevated accumulation of mRNA transcripts and inactive MAPK proteins, such as MPK3, primes Arabidopsis plants for enhanced defence and provokes immunity to future invasions, whereas their down-regulation reduces immunity [57]. In this sense, the plant defence mediated by the activation of kinases MPK3 and MPK6 rapidly alters the expression of photosynthesis-related genes and photosynthetic activity, which promotes the accumulation of ROS and accelerates HR cell death [58]. The dual functionality of the MPK3/6 cascade in promoting defence and inhibiting photosynthesis potentially allows it to orchestrate the trade-off between plant growth and defence in plant immunity. Interestingly, Agrobacterium tumefaciens hijacks the MPK3/6 pathway for delivering the T-DNA into the plant cell nucleus [59]. MPK4 is another regulatory hub that is essential for basal resistance to invasive biotrophic and hemibiotrophic attackers that has a role in ROS signalling and negatively regulates the positive effects of EDS1 on SA-mediated defence, while also displaying positive regulation of JA/ET-dependent immunity [60].
In plant–Trichoderma interactions, root colonization was accompanied by the systemic expression of an MPK3 orthologous gene in cucumber plants challenged with T. asperelloides and the overexpression of MPK3 primed them for JA- and ET-mediated defences against P. syringae pv. lachrymans without previous root colonization by the beneficial fungus [61]. It was found in Arabidopsis that plant growth regulators, such as ET and IAA, produced by the plant in response to T. atroviride, control several aspects of the root growth but, simultaneously, they can modulate MPK6 activity affecting root development [62]. MPK6 also activates ET biosynthesis through the phosphorylation of 1-AMINOCYCLOPROPANE-1-CARBOXYLATE (ACC) synthase after PRR stimulation [63]. It was observed that after T. viride inoculation onto both sides of Arabidopsis leaves, MPK6 increased the expression of a plasma membrane proton ATPase, which had a regulatory role in further leaf colonization and plant growth promotion [32]. The MPK3/6 cascade regulates phytoalexin biosynthesis and the phosphorylation of the TF ERF6, triggering the ET signalling-dependent defences [64]. The MPK3/6 cascade leads to the activation of WRKY type TFs, such as WRKY33, culminating in the expression of defence genes. In this way, early transcriptional responses mediated by WRKY33 result in the down-regulation of SA-related plant defences, but also in the up-regulation of JA-associated responses at later stages [65], as reported in bean plants colonized with T. velutinum [66]. A summary of the TFs that have been reported to be relevant to the Trichoderma–plant interaction and their regulatory effect are presented in Table 1. Studies performed on Arabidopsis showed that bacterial infection resulted in increased accumulation of the metabolite azelaic acid (AZA) that has been shown to prime plants to accumulate higher levels of SA and the activation of systemic defence against the pathogen P. syringae [67]. AZA induces the expression of the AZELAIC ACID INDUCED 1 (AZI1) gene, which encodes the secreted lipid transfer protein AZI1, involved in the production and/or translocation of a mobile immune signal [68], and has proven to be one of the targets of MPK3 and MPK6 [69]. All these cases may be indicative that signal transduction by the MPK3/6 cascade is not only necessary to induce defence responses but also constitutes a molecular node that fine-tunes the phytohormone networking that gives rise to a balance between growth and defence. The quick activation of MPK4, that negatively regulates SA accumulation and which later on regulates the inhibitory crosstalk between the SA and JA/ET signalling networks, is in agreement with the rapid (4 h) down-regulation of EDS1 in tomato plants and the subsequent up-regulation of this gene at 48 hpi with T. harzianum [40]. The already indicated undulating responses of plants undoubtedly condition the goal of building up an effective systemic defence in the medium and long term.
In addition to the role of MPKs in the activation of WRKY33 within the nucleus, there are several examples where Trichoderma spp. are described as priming activators by modulating the expression of different TFs involved in transcriptional activation or repression at the end of the MAPK signal transduction cascades, resulting in accelerated activation of the defence responses followed by their subsequent moderation, which gives rise to the timing stages that lead to the different types of systemic resistance to stresses [47,70,71,72,73,74,75]. This Trichoderma trait is corroborated by the fact that cis-elements, known to be involved in stress responses, such as WRKY, MYB, and MYC motifs, have been found in promoters of secreted Trichoderma effectors [76,77].
TFs with highly conserved WRKY domains are quite common in plants (e.g., 38 genes in the moss Physcomitrella, 83 in tomato, and 197 in soybean) and play roles in the regulation of transcriptional reprogramming associated with plant stress responses against both biotic and abiotic factors. Genes induced during defence responses often contain WRKY TF-binding sites since WRKYs can interact (in)directly with MAMPs/DAMPs or effector proteins to activate or repress plant defences. In addition to the WRKY33 seen above being associated, respectively, with lowering and raising SA- and JA-dependent defences, experimental data pointed out the existence of crosstalk between induced defence and acclimation responses mediated by WRKYs [82]. The ankyrin repeat protein NONEXPRESSOR OF PATHOGENESIS-RELATED GENES 1 (NPR1) is a transcription cofactor that acts as the master key to the plant defence signalling network and mediates crosstalk between the SA and JA/ET responses [68].
WRKY54 and WRKY70 are direct transcriptional targets of NPR1 to negatively control SA accumulation [83]. WRKY54 and WRKY70 play dual roles in systemic defence, both as negative regulators of SA biosynthesis and as positive regulators of SA signalling. In a 24-h Arabidopsis root interaction with T. harzianum [40] and T. asperelloides [72], WRKY54 was down-regulated. WRKY54 and WRKY70 were also down-regulated in Arabidopsis plants at 24 and 48 hpi with T. atroviride, with slight gene expression increases from 48 h until the relationship between Arabidopsis and Trichoderma was stably established after six days [73]. These results confirmed the important role of NPR1 as a negative regulator of SA biosynthesis in plants challenged with Trichoderma but also as an SA signal transducer at longer times. The structurally related WRKY18, WRKY40, and WRKY60 get accumulated in response to SA and JA during biotic stress as well as to ABA during abiotic stress responses. Interestingly, these TFs have leucine zipper motifs at their N termini via which they directly bind to their own respective promoters, in order to negatively regulate their expression patterns to maintain the homeostasis of WRKY proteins, which implies an additional element to understanding the crosstalk between Trichoderma and plants. WRKY18, WRKY40, and WRKY60 are also activators of T-DNA genes after their integration in the plant genome following A. tumefaciens infection [84], which also links them to the regulatory role of MPK3/6 in balancing defence and growth and opens a debate on how the use of T-DNA genes can affect the regulatory systems of plants transformed with the Ti plasmid. In Arabidopsis plants treated with T. asperelloides, the expression of WRKY18 and WRKY40 was enhanced at 9 hpi, which correlated with the negative regulation of the SA-dependent defence positive regulators FLAVIN MONOOXYGENASE 1 (FMO1) and EDS1 at the same time point. The activation of JA-signalling genes via the suppression of JASMONATE ZIM DOMAIN (JAZ) repressors was also observed [72]. The progressive decline in the expression levels of WRKY18 and WRKY40 reinforces the undulating behaviour of the defence responses in Trichoderma-colonized plants. To cite just one example of this pattern, WRKY60 kept expression levels low in the first hours of plant–Trichoderma interaction and raised them after six days [72,73]. WRKY4 gene expression is induced by SA and pathogen infection, and functions as a suppressor of SA-dependent defence genes. It was down-regulated in the first 24–48 h of inoculation of T. erinaceum in tomato [50] and T. asperelloides in Arabidopsis [72], although the levels of expression of WRKY4 tended to increase over time. WRKY activation is not exclusive to MAPK cascades as it has been proven that CDPKs phosphorylate WRKY8 for immune gene expression and ROS production [85]. WRKY8 in fact was strongly up-regulated at 24 h of Arabidopsis-T. atroviride interaction and presented a gradual decrease in its expression from then on [73]. A special point of attention is the case of WRKY70, which is a primary target for the Arabidopsis histone methylase ARABIDOPSIS TRITHORAX-LIKE FACTOR 1 (ATX1) involved in establishing the trimethylation pattern of lysine 4 (K4) in histone H3 (H3K4me3), while the SA-responsive gene PR-1 and the JA-responsive gene THI2.1 are secondary targets. The finding that the PR-1 and THI2.1 nucleosomes carry H3K4me3-marks unrelated to their transcription states has suggested that SA- and JA-inducible defence genes keep their nucleosomes in an ‘active memory’ state in preparation for quick-changes of transcription when needed by the cell [86]. As we will see later, after an initial stimulus, chromatin remodelling is stored in the defence gene promoters, which can be activated when plants are subjected to new stresses [87]. Similarly, histone methylations at the WRKY40 promoter activate the SA-dependent pathway and negatively regulate ABA-dependent adaptation of plants to unfavourable environmental conditions [88]. This behaviour would be in accordance with what has been reported for Arabidopsis-T. asperelloides [72] and with the proposed plant–Trichoderma interaction model [10].
The R2R3-MYB TFs that only exist in terrestrial plants are capable of binding to the WRKY promoters leading to their expression (e.g., MYB44 directly regulates the expression of WRKY70; and MYB51 that of WRKY33) [89,90]. MYBs are involved in multiple stress responses, including defence-induced lignification and basal immunity (MYB15), SA-and JA-mediated defence responses and enhancement of ABA signalling (MYB44), indolic glucosinolate biosynthesis upon SA and ET signalling in Arabidopsis and salt/osmotic stress regulation (MYB51), early signalling of rhizosphere-induced systemic defence (MYB72), and auxin modulation and root development through interaction with ARFs (MYB77) [89,90,91,92,93]. The root-specific TF MYB72 is required for JA/ET-dependent systemic resistance and callose accumulation induced by T. asperellum in Arabidopsis plants and also functions as an early node of convergence in the signalling pathways that are induced by different beneficial microorganisms, such as Trichoderma itself and Pseudomonas fluorescens [70]. In Arabidopsis roots colonized by T. asperelloides [72], an undulating expression pattern was observed in different MYB genes, with maximum levels for MYB15, MYB51, and MYB72 at 24 h. At this time point, the growth-regulating MYB77 gene showed its minimal expression, limiting lateral root development while increasing defences, which would be corroborating the ability of Trichoderma to balance the costs of plant growth and defence [12].
BASIC HELIX-LOOP-HELIX (bHLH) MYC TFs regulate multiple functions in plants. In particular, MYC2 is required for JA-dependent systemic defences triggered by beneficial soil microbes, JA-regulated plant development, and lateral root formation. MYC2 acts as a regulatory hub within the JA signalling pathway and functions as a negative regulator of the action of MYB51 [94], cooperating also with MYB2 in the activation of the ABA signalling pathway in response to salt stress and water deficit [95]. MYC2 contains a JAZ interaction domain and a transcriptional activation domain which recruits the mediator of RNA polymerase II (Pol II) transcription subunit 25 (MED25) of the Mediator complex [94,96]. When the levels of JA are low, MYC2 binds JAZ proteins, leading to the repression of MYC2 activity, resulting in the suppression of JA-responsive gene expression. However, when JA concentration is elevated, JAZ repressors are degraded in the 26S proteasome and MYC2 is free to form a complex with MED25 to trigger the initiation and amplification of JA-mediated transcriptional responses [97]. Arabidopsis roots inoculated with T. harzianum showed up-regulation of MYB51 and the PROLINE RICH PROTEIN BstNI SUBFAMILY 1 (PRB1) gene involved in JA- and ET-dependent defence responses in root tissues in 4 h, and down-regulation of their expression over time, while the expression of the TF ERF significantly increased from 4 to 48 hpi compared to uninoculated plants [53]. This would indicate that: (i) in the first hours of interaction with Trichoderma, JA levels are high, in an attempt to counteract the activation of SA-dependent defences, and MYB51 is not being negatively regulated by MYC2; and (ii) ERF4 acts as a transcriptional repressor of the SA-mediated suppression of JA-responsive genes, as SA levels would be being restored while maintaining a JA-dependent defence [98].
Via JA signalling, MYC2 also coordinates defence- and growth-related processes. In fact, in plant–Trichoderma interactions, MYC2 has been revealed as a master regulator of balancing the costs of plant growth and defence, since it also regulates crosstalk between the JA-dependent pathways and those of other phytohormones [12,94,99]. Of particular interest throughout these processes are, on the side of MYC2, the MED25 binding domain required for relaying JA transducing signals to the Pol II transcriptional machinery and on the MED25 side, the activator-interacting domain essential for the binding with MYC and ERF TFs [96]. The MYC2-MED25 functional complex activates JA-dependent defences but also regulates the termination of JA signalling, which means that the expression of genes dependent on the JA defence acquires an undulating shape at certain time periods [100]. MED25 has been also described as a regulator of abiotic stress responses, interacting with promoter regions of ABA-INSENSITIVE5 (ABI5) TF, leading to a negative effect on ABA-regulated gene transcription [101], in the same way as histone methylation does in WRKY40 [82]. MED25 functions as a negative regulator of primary and lateral root growth through auxin-related mechanisms [102]. MED25 cooperates with other subunits of the Mediator, as is the case with: (i) MED16, which governs the JA-ET crosstalk that also binds WRKY33 and regulates the expression of JA responsive genes and the ERF-domain TF ORA59; and (ii) MED18, which regulates JA-SA crosstalk and ROS production [96]. Although MED25 and MYC2 are evolutionarily conserved, their relatively weak interaction is species-specific and may explain why they are not interchangeable among plant species [103]. So, the different MYC2 and MED25 binding abilities could help explain a part of the enormous capacity of plants to alternate and progressively modify their defences to adapt to a changing environment.
Different studies have found that the application of Trichoderma does not produce a significant change in the expression of the MYC2 gene [41,66] or at most a slight repression after 24 h [98]. The simplest explanation is that plants tip the balance towards growth while allowing root colonization by Trichoderma. However, upon attack, plants modulate MYC2-dependent defence responses that lead to a quick up-regulation when they feel attacked, either by a caterpillar herbivore [104] or by a necrotrophic fungus [105]. Conversely, MYC2 was down-regulated in plants treated with Trichoderma but attacked by the coronatine-producer (hemi)biotrophic bacteria P. syringae pv. tomato strain DC3000 [47]. In this last case, plants challenged with T. asperellum kept similar levels of expression for the SA-dependent defence genes to the unchallenged ones, while increasing the levels of the genes involved in ET-dependent defence, providing the expected conditions for the pathogenic bacteria to be controlled.

4. Long-Lasting Priming and Plant Memory

It now seems clear that with long periods of time, defences are activated by Trichoderma [106,107], both locally, which would limit the penetration of the fungus to the first few layers of root cortical cells [45,108], and systemically [109], which would prime the plant against the attack of different pathogens.
Systemic acquired resistance (SAR) is the fact that uninfected systemic plant parts become more resistant in response to a localized infection elsewhere in the plant. Induced systemic resistance (ISR) is a term that has emerged to define the enhanced defensive capacity of the entire plant against a broad spectrum of pathogens, acquired upon local induction by beneficial microbes [20]. Interestingly, it has recently been reported that foliar applications of T. asperellum were able to suppress oak powdery mildew disease in the subsequent three years [33]. It is widely accepted that SA is essential in SAR signal transduction against biotrophic pathogens while ISR was shown to be effective against attackers that are sensitive to JA/ET-dependent defences including necrotrophic pathogens and insect herbivory [20]. It is common to find in the literature that Trichoderma induces ISR. However, in view of the responses of plants to colonization by Trichoderma and the subsequent priming of defences, the terms SAR and ISR are too stiff. It has been reported that the application of T. arundinaceum to the seeds, and T. harzianum to the substrate, primed effective defences in four-week-old tomato plants at 96 hpi with B. cinerea [110,111]. Plants challenged with T. arundinaceum displayed both SA- and JA-dependent systemic defences [110]. In the case of T. harzianum, JA-regulated responses typically directed ISR development, although the establishment of successful systemic defence required intact JA, SA, and also ABA signalling pathways [111]. When 30-day-old tomato plants from seeds inoculated with T. harzianum were treated with one of its released metabolites, harzianic acid (HA), ET/JA pathways related to ISR were activated, but HA also up-regulated the SA pathway, thus causing the co-induction of ISR and SAR responses [78].
Therefore, doubts have been raised about how to precisely define the situations of priming. According to the different examples mentioned above on the undulating behaviour of the plant’s defences triggered by Trichoderma, it seems more accurate not to use the classic definitions of ‘SA-dependent SAR’ or ‘JA-dependent ISR’ applied to plant–Trichoderma interactions. As observed with the root-knot nematode (RKN) Meloidogyne javanica and its attack on tomato roots completing their biological cycle, Trichoderma seems to reprogram the plant immunity by adapting SA- and JA-dependent defences according to the pathogen infection stage [74,112]. A time course study for 144 h carried out on tomato seedlings inoculated with T. parareesei served to prove that reprogramming of transcription due to Trichoderma favours both abiotic and biotic stress responses over normal cellular functions in an undulating pattern [113]. Interestingly, the beneficial effects (lateral root development, improved defence against B. cinerea, and growth promotion under salt stress) were more apparent depending on proximity to the Trichoderma inoculation time and whether the plants were subjected to some form of stress [113].
A model based on transcription cascades involving different hormone signalling pathways has been proposed in order to explain the dynamics in plant immunity. Particularly, the changes in redox within 24 to 48 h after the activation of some kind of defence that dictate transcription pulses of different hormone signals in systemic tissues [114]. As hormone pathways are frequently antagonistic, the transcription pulses may be mutually exclusive within single cells. Nonetheless, feedforward loops may exist in which multiple hormone signals control the next transcription pulse by transcription cascading. The result is an undulating pattern of defences as the phytohormone networking provides the plant with the regulatory potential to favour, in case of need, immune response pathways over pathways that regulate normal cellular development [115]. We have seen that in Trichoderma–plant interactions, independently regulated TFs may function in combination with modulating key immune genes through transcription cascades. It is becoming increasingly clear that the phytohormone crosstalk also provides plant cells with the ability to launch multiple hormone-driven transcription programs without cross-interference to establish immunity or growth depending on the case [12,114].
At this point, it is worth asking what happens to the stress signals when the transcription pulses disappear, or in other words when the amplitudes of the undulating curves tend to zero. It is evident that plants cannot be continuously activated under stress-free conditions, since it would be at a very high cost of energy, so signals are reverted after a prolonged decline in stress pressure [14]. The mere up-regulation of MPK3/6 or the accumulation of phytohormones and TFs crucial for the defence of plants is not sufficient to explain the reverted effects of priming. Today, we know that signals generated after stress are stored by the plants in the form of DNA hypomethylation in the promoters of defence genes and chromatin remodelling that act as a long-lasting epigenetic immune memory [116,117]. As a continuation of the work on RKN–Trichoderma interaction [74], the cytosine methylation in different contexts (CpG, CHG, and CHH) of tomato plants from seeds treated and untreated with Trichoderma was analysed. As expected, plants treated with Trichoderma showed a 2.42% lower methylation profile of their genome, validating the positive plant gene regulation described in previous plant–Trichoderma transcriptomic studies. An overview of the processes involved in the interaction of Trichoderma and the plant host from the point of view of the timing through priming, epigenetic marks, and inheritance is presented in Figure 2.
Typically, histone acetylation by acetyltransferases is associated with transcriptional activation, while histone deacetylation by deacetylases (HDA) results in transcriptional repression [118]. Acetylation of H3K4 and H3K9 in the promoters of WRKY40 and WRKY70 agrees with higher expression in biotic defence genes [119]. Deacetylase HDA19 represses transcription of WRKY38 and WRKY62 and thus negatively regulates basal defence [120]. HDA19 can be induced by JA and ET, and the overexpression of the HDA19 gene decreased the acetylation levels of H3 in Arabidopsis and did not increase the SA-regulated genes [121]. JAZ proteins physically interact with deacetylase HDA6 providing a resting state in which JA-dependent plant processes are repressed. It seems, therefore, that JAZ-mediated suppression of the JA-mediated transcription involves the establishment of a ‘closed’ or ‘suppressed’ chromatin state that excludes JA-responsive TFs, such as MYC2, from binding to their targets [94].
Methylation changes of histones can either increase or decrease transcription of genes [110]. Methylations at the WRKY40 promoter negatively regulated ABA signalling and led to the activation of the SA-dependent pathway [82], while demethylase JM17 activity did not induce but rather negatively regulated dehydration stress and ABA responses by maintaining H3K4me3 methylation levels [122]. As we have already mentioned, these processes are complex and sometimes contradictory because we have seen that H3 methylations suppress but also favours the expression of defence genes [88]. Similarly, acetylation does not always match with increased gene expression, since other regulatory mechanisms, such as peroxidase production to maintain ROS homeostasis, may also be involved [113]. In any case, the most typical modifications in defence gene promoters are H3K9ac and H3K4me3 that function as molecular footprints to gene priming, and in them seems to reside an important part of the long-lasting memory. The Arabidopsis SA-dependent systemic priming against Pseudomonas was associated with H3K9ac and H3K4me3 chromatin modifications on the promoters of WRKY6, WRKY29, and WRKY53 [87]. The mediator protein MED25 physically and functionally interacts with the acetyltransferase HAC1 which selectively regulates H3K9ac at MYC2 target promoters and thereby favours long-term JA-responsive gene expression [123]. MED25 also activates H3K9ac in the WRKY33 promoter and is usually connected with the H3K4me3 that facilitates the expression of WRKY70 to simultaneously regulating gene expression to fine-tune JA- and SA-dependent defence priming [86,124]. Together with MED25, MED18 also controls the balance between JA and SA, interacting with the acetyltransferase HOOKLESS1 to increase WRKY33 expression and thereby regulating JA-SA crosstalk and ROS production [96]. As shown above, the MYC2-MED25 complex plays a fundamental role in plant–Trichoderma interactions, and WRKY33 and WRKY70 [40,66,72,73], as well as WRKY40 or MYB77 [72], seem to be crucial in the activation and maintenance of the priming memory. The MED25-mediated H3K4me3 and H3K9ac in promoters of WRKY70 and WRKY33 respectively might justify the long-lasting induction of SA and JA/ET-dependent priming in plants challenged with Trichoderma. Similarly, the concerted methylation/demethylation activity on H3K4me3 at the WRKY40 promoter would explain the long-lasting down-regulation of this TF and as a result the modulation of SA- and ABA-dependent responses, balancing defence and growth. As observed in Arabidopsis plants, the auxin-stimulated TF MYB77 was down-regulated at 24 hpi with Trichoderma [72], thus limiting the development of lateral roots. The long-lasting up-regulation of MYC2-dependent genes after a pathogen attack would agree with the concerted deacetylations on MYB77 and ARF promoters [91,125] and as a result, the plant would shape auxin responses, tipping the balance towards defence when needed.
We have just seen that there are mechanisms in plant cells that store information on their behaviour during previous attacks in order to remember and adapt to new situations if required later. In addition, the plant’s responses to Trichoderma are effective for long-lasting priming against abiotic stresses and pathogen attacks. The energy savings provided to the plants by the priming of defences allow them to manage growth as well. In this context, the MYC2-MED25 complex, not forgetting the maintenance of ROS homeostasis, seems to play a leading role in Trichoderma-primed plants.

5. Transgenerational Inheritance

One of the focal points when addressing systemic defences maintained over time is whether priming is mediated by beneficial microbes via epigenetic mechanisms and whether they are inherited trans-generationally [20]. One could expect an affirmative answer to both questions, as there are works to show that enhanced resistance to pathogens (e.g., bacteria, fungi, or insects) in the progeny of previously attacked plants was transmitted by post-translational modifications of histones (e.g., H3K9ac, H3K27me3) at WRKY and defence gene promoters [126]; by DNA hypomethylation of SA-dependent defence regulatory genes [127]; and by mechanisms able to reduce DNA methylation [128]. However, it is well known that viral infections induce epigenetic changes that can also be transmitted to the progeny of infected plants [129]. As we will see below, these plants produce non-coding small RNAs (sRNA) in response to viral infection as well as to abiotic stresses that lead to hereditary changes in DNA methylation [130]. DNA methylation, controlled by both DNA methyltransferase and DNA demethylation enzymes, is an epigenetic mark that silences transposable elements (TE) and repeats. Some immune-response genes, containing repeats in their promoter regions, are negatively regulated by this mechanism. So, DNA demethylation is part of the plant immune response, potentially acting to prime the transcriptional activation of defence genes linked to TEs/repeats in systemic unchallenged tissues, including reproductive organs, thereby orchestrating transgenerational immune priming [131]. While chromatin modifications provide long-lasting priming, as DNA (de)methylation is transmitted by meiosis, it is not unreasonable to think that in this mechanism lies the transgenerational inheritance of priming.
Plants have evolved a variety of gene silencing pathways [132] to generate sRNAs that govern the expression of sequence homologous genes [133] at the transcriptional level (transcriptional gene silencing, TGS), either preventing or dampening transcription through DNA methylation and chromatin modifications, or at the post-transcriptional level (post-transcriptional gene silencing, PTGS), through RNA cleavage or translational repression. Moreover, sRNAs are key regulators that can reprogram the expression of stress- or development-related genes to balance resources between investment in development and responses to biotic and abiotic stresses [134], precisely the characteristics that Trichoderma confers to plants. In this regard, host cells generate sRNAs corresponding to the genome infecting pathogen. Invasive nucleic acids are transformed into double-stranded RNA and diced into primary small interfering RNAs (siRNA) through the sequential action of RNA-dependent RNA polymerases (RDR) and Dicer-like (DCL) RNase III enzymes. Then, the defence response spreads systemically throughout the plant to promote RNA silencing mediated resistance. RNA silencing is regarded as an adaptive form of antiviral immunity [135] that also has an important function in the regulation of plant endogenous processes [136]. Plants synthesize two major types of sRNAs, classified into microRNAs (miRNA) and siRNAs on the basis of their biogenesis and precursor structures. Both mature miRNAs and siRNAs associate with ARGONAUTE (AGO) proteins to guide TGS or PTGS to cognate targets based on their homology. MIR genes are transcribed into long single-stranded transcripts [137]. They adopt a fold-back stem-loop structure that is processed in most cases into a mature miRNA duplex by the enzyme DCL1 [135], although some miRNAs can be processed by DCL4 [138]. miRNA duplexes are methylated at their 3’ terminal nucleotide by the RNA methyltransferase HUA ENHANCER 1 (HEN1) [139,140,141] to protect them from degradation [140] and most are exported to the cytoplasm by the exportin-5 homologue HASTY (HST) [142]. One strand of the miRNA duplex acts as a guide strand and is selectively loaded onto an AGO protein to form the core of the RNA-induced complex (RISC), whereas the other strand, the passenger strand (miRNA*), is discarded from the complex and rapidly degraded. Most miRNAs associate with the protein AGO1; however, specific associations of miR408 or miR393* with AGO2, of miR390 with AGO7, and of miR165/166 with AGO10 have been reported [143,144,145,146]. Plant miRNAs promote the cleavage of their target RNA, to which they bind perfectly or near perfectly, by employing mostly AGO1 as the RNA slicer. Therefore, cleavage is assumed as the common approach for miRNA-mediated gene regulation in plants [147,148,149]. Thus, miRNAs act as signal molecules to carry information and they can accumulate to extremely high levels within plant tissues to regulate, by PTGS, the expression of target mRNAs involved in many aspects of plant biology, including growth, and defence and adaptation to stresses [18,150]. However, in addition to regulating RNA degradation, evidence exists to suggest that miRNAs with binding sites in gene promoters sometimes direct DNA methylation [151] to modulate gene expression through epigenetic modifications of the promoter or inhibit translation [152,153,154,155,156,157].
Some pathogens and pests deliver sRNAs into plant host cells to act as effectors through a mechanism that silences host genes in order to suppress host immunity and achieve infection. Conversely, sRNAs of the host travel into the attacker cells to inhibit their virulence. This bidirectional sRNA traffic is known as ‘cross-kingdom RNA interference (RNAi)’ [158]. The pathogenic fungus B. cinerea delivers several sRNAs into host plant cells during infection [159]. Some of these fungal sRNAs have complementarity to host immunity genes (e.g., MPK1/2) that are down-regulated during B. cinerea infection by hijacking host sRNAs machinery with its own set of sRNAs [159]. Another example of sRNAs delivered into the host cells is the case of miRNA-like RNA1 (Pst-milR1) produced by Puccinia striiformis (Pst), one of the most destructive pathogens of wheat. Pst-milR1 suppresses wheat defences during Pst infection by targeting the PR-2 gene to impair wheat resistance to Pst [160]. An example of the parasite-to-host transfer of sRNAs comes from the parasitic plant Cuscuta campestris, which produces many miRNAs, some of them specifically targeting host mRNAs involved in defence [161]. Similarly, it has been suggested that Trichoderma could be using sRNAs as effector molecules that utilize the host RNA silencing machinery to establish a symbiotic relationship with Arabidopsis by binding to AGO1 for silencing host genes involved in plant immunity [23].
It is therefore to be expected that somehow some of the Trichoderma effects could also be inherited by the plant. To confirm this assumption, it would be necessary to explore: (i) what characteristics Trichoderma confers on the plant that are non-genetically transmitted to the offspring; and (ii) whether DNA demethylation and/or methylation occurs and/or sRNA production is increased in the next generation of plants.
During the study in which we described that T. atroviride was able to colonize tomato roots by making the plant adapt its systemic SA- and JA-dependent defences according to the RKN M. javanica infection stage, we also observed that the first generation (F1) of T. atroviride-primed tomato plants inherited resistance to RKN [74]. This defence priming inheritance by the offspring varied depending on whether the F1 plants came from seeds of plants treated with T. atroviride, M. javanica, or both arranged in different pots following a split-root approach [162]. In this way, F1 plants derived from T. atroviride + M. javanica split-rooted plants exhibited a dramatic reduction in size, but in contrast they had the SA- and JA-dependent defences activated, expressing even stronger defence priming than offspring of unprimed plants. Instead, F1 plants derived from plants that were only treated with T. atroviride showed the largest sizes and highest green mass values. Thus, plant growth promotion induced by T. atroviride would also be inherited and we would expect them to be poorly defended. However, these F1 plants displayed active defence when they were infected with M. javanica, with very low levels of SA and JA but with increased auxin-induced ROS production, which was sufficient to protect the plants from a subsequent RKN attack. This means that the progeny of T. atroviride-primed plants would be displaying increased size and resistance to M. javanica without fitness costs. Seen as a whole, the results of that study indicated that the Trichoderma switching signatures involved in balancing the plant’s defence and growth would be inherited in a T. atroviride treatment conditions-dependent manner [74].
The alternative defence mechanism based on auxin-induced ROS production in plants that choose to grow, but not at the cost of being left unprotected, is compatible with the Trichoderma ability to promote more and longer secondary root hairs in cucumber plants, increasing the total absorptive surface and facilitating the uptake of nutrients, resulting in increased plant biomass [163]. A recent study [164] has proposed a molecular mechanism by which endogenous auxin activates several ARFs to up-regulate the expression of the TF RSL4 gene involved in ROS-mediated regulation of root hair elongation, by promoting the expression and activity of NADPH oxidase and peroxidase proteins. In this case, the MYC2-dependent auxin signalling pathway [94] and the interaction between MYB77 and ARFs [125] would be a gene regulation backup, acting as a major defence strategy during plant growth.
The bidirectional sRNAs study between the plants and Trichoderma is a hitherto unexplored field of research that will need further attention. As far as guide miRNAs are concerned, it would be very extensive to list their different functions as they act as integrators of multiple environmental cues. As a general rule, components of the plant immune system are constitutively repressed by specific miRNAs in non-infected tissues, but their down-regulation around an infected zone activates defence-related genes to restrict fungal growth [18]. Although it has also been noted that the activation of some miRNAs may also contribute to suppressing certain defence suppressors, providing some sort of immunity [18]. Just to mention one example, we have found that several miRNAs targeted to genes related to auxin, root growth, and defence were up-regulated in T. atroviride–tomato plants. Particularly, the transcription of MIR393 and MIR160 was induced upon Trichoderma perception by the plants. miR393 increases tolerance to ROS and targets the auxin receptors TIR1 to inhibit auxin signalling—which might be required for root growth regulation in response to stress—and alleviates its antagonism on SA signalling [165]. miR160 has a role in maintaining proper auxin homeostasis, control of root cap formation, and the regulation of ARF16 expression required to maintain the normal growth and development of aerial organs and lateral root production [166,167].
It has been proven that DNA methylation of regions flanking the miRNA coding sequence affects miRNA biogenesis [168] and the production of miRNAs targeting a promoter region along with an increase in the DNA methylation level are accompanied by the decreased expression of the corresponding gene. As a result, the ensuing silent state is inherited in the following generation. Therefore, further research is needed to clarify the basic molecular mechanisms involved in the inheritance of the epigenome triggered by the Trichoderma-induced plant priming responses.

6. Conclusions

Trichoderma is a common resident of the rhizosphere where it first evolved as a mycoparasite and then established symbiotic relationships with plants, becoming an endophyte. A fine-tuned crosstalk with the plants has allowed many strains of Trichoderma to carve out an advantageous ecological niche while providing benefits to their hosts. There are a growing number of reports that describe how Trichoderma strains try to achieve their goals and we can be faced with results that may be contradictory, depending on the timing and conditions of each Trichoderma–plant interaction study. It is now clear that time-course studies are the most appropriate to draw conclusions, that plant responses to Trichoderma signals follow undulating dynamics, that plants store the Trichoderma signature in their memory and these signatures can be passed on to their offspring. The beneficial action that Trichoderma has on plants is modulated by different molecular hubs that condition the immediate and long-lasting systemic responses, orchestrating the trade-off between plant growth and defence, as we have seen with the acceleration and moderation of MPK3/6 cascades; ROS homeostasis; WRKY4, WRKY18, WRKY33, WRKY40, WRKY70, MYB15, MYB51, MYB72, MYB77, MIR160, or MIR393 transcription dynamics; histone acetylation and methylation at the WRKY33, WRKY40, or WRKY70 promoters; the MYC2-MED25 complex activation; and the yet to be further explored DNA (hypo)methylation and ‘cross-kingdom RNAi’ between Trichoderma and plants. Moreover, the discovery that the Trichoderma switching signatures involved in balancing the plant’s defence and growth can be inherited opens up new possibilities for the biotechnological application of this fungus. A first consequence may be the registration of Trichoderma strains for commercial use in agriculture, either as plant protection products inducing systemic resistance or as biostimulants, since it seems misguided to attribute to Trichoderma a trait that depends on plant decision-making.
In terms of future prospects, the bidirectional traffic of sRNA between Trichoderma and plants has a role to play in understanding plant responses to Trichoderma priming and its heritability. It would be very interesting to explore whether and to what extent the Trichoderma signature conferred on transgenic plants is also heritable or even transmissible through grafting. This will allow us to know whether such a signature is the result of a whole or whether, on the contrary, it may be a functionally compartmentalized effect.

Author Contributions

E.M., R.H., and M.E.M.-D. conceptualized the idea of this manuscript and E.M. and M.E.M.-D. wrote the original draft; M.E.M.-D. designed figures and drafted the table; R.H. and M.E.M.-D. analysed the early transcriptomic responses of the plants; R.H. and M.B.R. contributed to the undulating profile understanding of the plants’ systemic defence responses; M.E.M.-D., Á.E.M.d.A., and E.M. analysed DNA methylation and sRNA profiles; and M.E.M.-D., Á.E.M.d.A., M.B.R., and R.H. reviewed and edited the final version of the draft. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Spanish Government, grant RTI2018-099986-B-I00 and the European Regional Development Fund (FEDER) under the Regional Government of Castile and Leon support, grants SA270P18, SA094P20 and Escalera de Excelencia CLU-2018-04.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data is contained within the article.

Acknowledgments

We would like to acknowledge that M.E.M.-D was granted a postdoctoral fellowship at the University of Salamanca (Programme II) and a postdoctoral contract of the Regional Government of Castile and Leon (Project SA094P20). Á.E.M.d.A was granted a postdoctoral contract of the Regional Government of Castile and Leon (Project SA270P18).

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

References

  1. Lorito, M.; Woo, S.L.; Harman, G.E.; Monte, E. Translational research on Trichoderma: From ’omics to the field. Annu. Rev. Phytopathol. 2010, 48, 395–417. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Druzhinina, I.S.; Seidl-Seiboth, V.; Herrera-Estrella, A.; Horwitz, B.A.; Kenerley, C.M.; Monte, E.; Mukherjee, P.K.; Zeilinger, S.; Grigoriev, I.V.; Kubicek, C.P. Trichoderma: The genomics of opportunistic success. Nat. Rev. Microbiol. 2011, 9, 749–759. [Google Scholar] [CrossRef] [PubMed]
  3. Sanz, L.; Montero, M.; Grondona, I.; Vizcaíno, J.A.; Llobell, A.; Hermosa, R.; Monte, E. Cell wall-degrading isoenzyme profiles of Trichoderma biocontrol strains show correlation with rDNA taxonomic species. Curr. Genet. 2004, 46, 277–286. [Google Scholar] [CrossRef] [PubMed]
  4. Vizcaíno, J.A.; Sanz, L.; Basilio, A.; Vicente, F.; Gutiérrez, S.; Hermosa, M.R.; Monte, E. Screening of antimicrobial activities in Trichoderma isolates representing three Trichoderma sections. Mycol. Res. 2005, 109, 1397–1406. [Google Scholar] [CrossRef]
  5. Keszler, Á.; Forgács, E.; Kótai, L.; Vizcaíno, J.A.; Monte, E.; García-Acha, I. Separation and identification of volatile components in the fermentation broth of Trichoderma atroviride by solid-phase extraction and gas chromatography-mass spectrometry. J. Chromatogr. Sci. 2000, 38, 421–424. [Google Scholar] [CrossRef]
  6. Vinale, F.; Sivasithamparam, K.; Ghisalberti, E.L.; Marra, R.; Woo, S.L.; Lorito, M. Trichoderma-plant-pathogen interactions. Soil Biol. Biochem. 2008, 40, 1–10. [Google Scholar] [CrossRef]
  7. Monte, E.; Hermosa, R. Deciphering biocontrol qualities and other plant beneficial traits in Trichoderma. In How Research Can Stimulate the Development of Commercial Biological Control Against Plant Diseases. Progress in Biological Control, 1st ed.; De Cal, A., Melgarejo, P., Magan, N., Eds.; Springer: Cham, Switzerland, 2020; Volume 21, pp. 95–108. [Google Scholar]
  8. Illescas, M.; Rubio, M.B.; Hernández-Ruiz, V.; Morán-Diez, M.E.; Martínez de Alba, A.E.; Nicolás, C.; Monte, E.; Hermosa, R. Effect of inorganic N top dressing and Trichoderma harzianum seed-inoculation on crop yield and the shaping of root microbial communities of wheat plants cultivated under high basal N fertilization. Front. Plant Sci. 2020, 11, 575861. [Google Scholar] [CrossRef]
  9. Poveda, J.; Hermosa, R.; Monte, E.; Nicolás, C. Trichoderma harzianum favours the access of arbuscular mycorrhizal fungi to non-host Brassicaceae roots and increases plant productivity. Sci. Rep. 2019, 9, 1–11. [Google Scholar] [CrossRef] [Green Version]
  10. Hermosa, R.; Viterbo, A.; Chet, I.; Monte, E. Plant-beneficial effects of Trichoderma and of its genes. Microbiology 2012, 158, 17–25. [Google Scholar] [CrossRef] [Green Version]
  11. Conrath, U.; Beckers, G.J.M.; Langenbach, C.J.G.; Jaskiewicz, M.R. Priming for enhanced defense. Annu. Rev. Phytopathol. 2015, 53, 97–119. [Google Scholar] [CrossRef]
  12. Hermosa, R.; Rubio, M.B.; Cardoza, R.E.; Nicolás, C.; Monte, E.; Gutiérrez, S. The contribution of Trichoderma to balancing the costs of plant growth and defense. Int. Microbiol. 2013, 16, 69–80. [Google Scholar] [CrossRef]
  13. Bruce, T.J.A.; Matthes, M.C.; Napier, J.A.; Pickett, J.A. Stressful “memories” of plants: Evidence and possible mechanisms. Plant Sci. 2007, 173, 603–608. [Google Scholar] [CrossRef]
  14. Pastor, V.; Luna, E.; Mauch-Mani, B.; Ton, J.; Flors, V. Primed plants do not forget. Environ. Exp. Bot. 2013, 94, 46–56. [Google Scholar] [CrossRef]
  15. Shi, S.; Li, S.; Asim, M.; Mao, J.; Xu, D.; Ullah, Z.; Liu, G.; Wang, Q.; Liu, H. The Arabidopsis calcium-dependent protein kinases (CDPKs) and their roles in plant growth regulation and abiotic stress responses. Int. J. Mol. Sci. 2018, 19, 1900. [Google Scholar] [CrossRef] [Green Version]
  16. Conrath, U. Molecular aspects of defence priming. Trends Plant Sci. 2011, 16, 524–531. [Google Scholar] [CrossRef]
  17. Conrath, U.; Beckers, G.J.M.; Flors, V.; García-Agustín, P.; Jakab, G.; Mauch, F.; Newman, M.A.; Pieterse, C.M.J.; Poinssot, B.; Pozo, M.J.; et al. Priming: Getting ready for battle. Mol. Plant-Microbe Interact. 2006, 19, 1062–1071. [Google Scholar] [CrossRef] [Green Version]
  18. Pumplin, N.; Voinnet, O. RNA silencing suppression by plant pathogens: Defence, counter-defence and counter-counter-defence. Nat. Rev. Microbiol. 2013, 11, 745–760. [Google Scholar] [CrossRef]
  19. Sahu, P.P.; Pandey, G.; Sharma, N.; Puranik, S.; Muthamilarasan, M.; Prasad, M. Epigenetic mechanisms of plant stress responses and adaptation. Plant Cell Rep. 2013, 32, 1151–1159. [Google Scholar] [CrossRef]
  20. Pieterse, C.M.J.; Zamioudis, C.; Berendsen, R.L.; Weller, D.M.; Van Wees, S.C.M.; Bakker, P.A.H.M. Induced systemic resistance by beneficial microbes. Annu. Rev. Phytopathol. 2014, 52, 347–375. [Google Scholar] [CrossRef] [Green Version]
  21. Mattoo, A.J.; Nonzom, S. Endophytic fungi: Understanding complex cross-talks. Symbiosis 2021, 1–28. [Google Scholar] [CrossRef]
  22. Mendoza-Mendoza, A.; Zaid, R.; Lawry, R.; Hermosa, R.; Monte, E.; Horwitz, B.A.; Mukherjee, P.K. Molecular dialogues between Trichoderma and roots: Role of the fungal secretome. Fungal Biol. Rev. 2018, 32, 62–85. [Google Scholar] [CrossRef]
  23. Ramírez-Valdespino, C.A.; Casas-Flores, S.; Olmedo-Monfil, V. Trichoderma as a model to study effector-like molecules. Front. Microbiol. 2019, 10, 1030. [Google Scholar] [CrossRef]
  24. Alfiky, A.; Weisskopf, L. Deciphering Trichoderma–plant–pathogen interactions for better development of biocontrol applications. J. Fungi 2021, 7, 61. [Google Scholar] [CrossRef]
  25. Navazio, L.; Baldan, B.; Moscatiello, R.; Zuppini, A.; Woo, S.L.; Mariani, P.; Lorito, M. Calcium-mediated perception and defense responses activated in plant cells by metabolite mixtures secreted by the biocontrol fungus Trichoderma atroviride. BMC Plant Biol. 2007, 7, 1–9. [Google Scholar] [CrossRef] [Green Version]
  26. Omann, M.; Zeilinger, S. How a mycoparasite employs G-protein signaling: Using the example of Trichoderma. J. Signal Transduct. 2010, 2010, 1–8. [Google Scholar] [CrossRef] [Green Version]
  27. Zhong, C.L.; Zhang, C.; Liu, J.Z. Heterotrimeric G protein signaling in plant immunity. J. Exp. Bot. 2019, 70, 1109–1118. [Google Scholar] [CrossRef]
  28. Pandey, S. Heterotrimeric G-protein signaling in plants: Conserved and novel mechanisms. Annu. Rev. Plant Biol. 2019, 70, 213–238. [Google Scholar] [CrossRef]
  29. Tseng, Y.-H.; Rouina, H.; Groten, K.; Rajani, P.; Furch, A.C.U.; Reichelt, M.; Baldwin, I.T.; Nataraja, K.N.; Uma Shaanker, R.; Oelmüller, R. An endophytic Trichoderma strain promotes growth of its hosts and defends against pathogen attack. Front. Plant Sci. 2020, 11, 573670. [Google Scholar] [CrossRef]
  30. Bailey, B.A.; Bae, H.; Strem, M.D.; Crozier, J.; Thomas, S.E.; Samuels, G.J.; Vinyard, B.T.; Holmes, K.A. Antibiosis, mycoparasitism, and colonization success for endophytic Trichoderma isolates with biological control potential in Theobroma cacao. Biol. Control 2008, 46, 24–35. [Google Scholar] [CrossRef]
  31. Galletti, S.; Burzi, P.L.; Cerato, C.; Marinello, S.; Sala, E. Trichoderma as a potential biocontrol agent for Cercospora leaf spot of sugar beet. BioControl 2008, 53, 917–930. [Google Scholar] [CrossRef]
  32. Guo, Y.; Ghirardo, A.; Weber, B.; Schnitzler, J.-P.; Benz, J.P.; Rosenkranz, M. Trichoderma species differ in their volatile profiles and in antagonism toward ectomycorrhiza Laccaria bicolor. Front. Microbiol. 2019, 10, 891. [Google Scholar] [CrossRef] [PubMed]
  33. Oszako, T.; Voitka, D.; Stocki, M.; Stocka, N.; Nowakowska, J.A.; Linkiewicz, A.; Hsiang, T.; Belbahri, L.; Berezovska, D.; Malewski, T. Trichoderma asperellum efficiently protects Quercus robur leaves against Erysiphe alphitoides. Eur. J. Plant Pathol. 2021, 159, 295–308. [Google Scholar] [CrossRef]
  34. Rocha, S.L.; Evans, H.C.; Jorge, V.L.; Cardoso, L.A.O.; Pereira, F.S.T.; Rocha, F.B.; Barreto, R.W.; Hart, A.G.; Elliot, S.L. Recognition of endophytic Trichoderma species by leaf-cutting ants and their potential in a Trojan-horse management strategy. R. Soc. Open Sci. 2017, 4, 160628. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  35. Kadota, Y.; Shirasu, K.; Zipfel, C. Regulation of the NADPH oxidase RBOHD during plant immunity. Plant Cell Physiol. 2015, 56, 1472–1480. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  36. Morán-Diez, M.E.; Cardoza, R.E.; Gutiérrez, S.; Monte, E.; Hermosa, R. TvDim1 of Trichoderma virens is involved in redox-processes and confers resistance to oxidative stresses. Curr. Genet. 2010, 56, 63–73. [Google Scholar] [CrossRef]
  37. Montero-Barrientos, M.; Hermosa, R.; Cardoza, R.E.; Gutiérrez, S.; Monte, E. Functional analysis of the Trichoderma harzianum nox1 gene, encoding an NADPH oxidase, relates production of reactive oxygen species to specific biocontrol activity against Pythium ultimum. Appl. Environ. Microbiol. 2011, 77, 3009–3016. [Google Scholar] [CrossRef] [Green Version]
  38. Morán-Diez, E.; Hermosa, R.; Ambrosino, P.; Cardoza, R.E.; Gutiérrez, S.; Lorito, M.; Monte, E. The ThPG1 endopolygalacturonase is required for the Trichoderma harzianum-plant beneficial interaction. Mol. Plant-Microbe Interact. 2009, 22, 1021–1031. [Google Scholar] [CrossRef] [Green Version]
  39. Alonso-Ramírez, A.; Poveda, J.; Martín, I.; Hermosa, R.; Monte, E.; Nicolás, C. Salicylic acid prevents Trichoderma harzianum from entering the vascular system of roots. Mol. Plant Pathol. 2014, 15, 823–831. [Google Scholar] [CrossRef]
  40. Morán-Diez, E.; Rubio, B.; Domínguez, S.; Hermosa, R.; Monte, E.; Nicolás, C. Transcriptomic response of Arabidopsis thaliana after 24h incubation with the biocontrol fungus Trichoderma harzianum. J. Plant Physiol. 2012, 169, 614–620. [Google Scholar] [CrossRef]
  41. Feys, B.J.; Moisan, L.J.; Newman, M.A.; Parker, J.E. Direct interaction between the Arabidopsis disease resistance signaling proteins, EDS1 and PAD4. EMBO J. 2001, 20, 5400–5411. [Google Scholar] [CrossRef]
  42. Salminen, A.; Kauppinen, A.; Kaarniranta, K. AMPK/Snf1 signaling regulates histone acetylation: Impact on gene expression and epigenetic functions. Cell. Signal. 2016, 28, 887–895. [Google Scholar] [CrossRef]
  43. Shoresh, M.; Spivak, M.; Bernstein, N. Involvement of calcium-mediated effects on ROS metabolism in the regulation of growth improvement under salinity. Free Radic. Biol. Med. 2011, 51, 1221–1234. [Google Scholar] [CrossRef]
  44. Chen, J.; Harman, G.E.; Comis, A.; Cheng, G.-W. Proteins related to the biocontrol of Pythium damping-off in maize with Trichoderma harzianum Rifai. J. Integr. Plant Biol. 2005, 47, 988–997. [Google Scholar] [CrossRef]
  45. Yedidia, I.; Benhamou, N.; Chet, I. Induction of defense responses in cucumber plants (Cucumis sativus L.) by the biocontrol agent Trichoderma harzianum. Appl. Environ. Microbiol. 1999, 65, 1061–1070. [Google Scholar] [CrossRef] [Green Version]
  46. De Palma, M.; D’Agostino, N.; Proietti, S.; Bertini, L.; Lorito, M.; Ruocco, M.; Caruso, C.; Chiusano, M.L.; Tucci, M. Suppression Subtractive Hybridization analysis provides new insights into the tomato (Solanum lycopersicum L.) response to the plant probiotic microorganism Trichoderma longibrachiatum MK1. J. Plant Physiol. 2016, 190, 79–94. [Google Scholar] [CrossRef]
  47. Morán-Diez, M.E.; Tranque, E.; Bettiol, W.; Monte, E.; Hermosa, R. Differential response of tomato plants to the application of three Trichoderma species when evaluating the control of Pseudomonas syringae populations. Plants 2020, 9, 626. [Google Scholar] [CrossRef]
  48. De Palma, M.; Salzano, M.; Villano, C.; Aversano, R.; Lorito, M.; Ruocco, M.; Docimo, T.; Piccinelli, A.L.; D’Agostino, N.; Tucci, M. Transcriptome reprogramming, epigenetic modifications and alternative splicing orchestrate the tomato root response to the beneficial fungus Trichoderma harzianum. Hortic. Res. 2019, 6, 1–15. [Google Scholar] [CrossRef]
  49. Zehra, A.; Meena, M.; Dubey, M.K.; Aamir, M.; Upadhyay, R.S. Synergistic effects of plant defense elicitors and Trichoderma harzianum on enhanced induction of antioxidant defense system in tomato against Fusarium wilt disease. Bot. Stud. 2017, 58, 1–14. [Google Scholar] [CrossRef]
  50. Aamir, M.; Kashyap, S.P.; Zehra, A.; Dubey, M.K.; Singh, V.K.; Ansari, W.A.; Upadhyay, R.S.; Singh, S. Trichoderma erinaceum bio-priming modulates the WRKYs defense programming in tomato against the Fusarium oxysporum f. sp. lycopersici (Fol) challenged condition. Front. Plant Sci. 2019, 10, 911. [Google Scholar] [CrossRef] [Green Version]
  51. Herrera-Téllez, V.I.; Cruz-Olmedo, A.K.; Plasencia, J.; Gavilanes-Ruiz, M.; Arce-Cervantes, O.; Hernández-León, S.; Saucedo-García, M. The protective effect of Trichoderma asperellum on tomato plants against Fusarium oxysporum and Botrytis cinerea diseases involves inhibition of reactive oxygen species production. Int. J. Mol. Sci. 2019, 20, 2007. [Google Scholar] [CrossRef] [Green Version]
  52. Gullner, G.; Komives, T.; Király, L.; Schröder, P. Glutathione S-transferase enzymes in plant-pathogen interactions. Front. Plant Sci. 2018, 9, 1836. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  53. Fernández, I.; Cosme, M.; Stringlis, I.A.; Yu, K.; Jonge, R.; van Wees, S.M.; Pozo, M.J.; Pieterse, C.M.J.; van der Heijden, M.G.A. Molecular dialogue between arbuscular mycorrhizal fungi and the nonhost plant Arabidopsis thaliana switches from initial detection to antagonism. N. Phytol. 2019, 223, 867–881. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  54. Xu, Y.; Zhang, J.; Shao, J.; Feng, H.; Zhang, R.; Shen, Q. Extracellular proteins of Trichoderma guizhouense elicit an immune response in maize (Zea mays) plants. Plant Soil 2020, 449, 133–149. [Google Scholar] [CrossRef]
  55. Koornneef, A.; Pieterse, C.M.J. Cross talk in defense signaling. Plant Physiol. 2008, 146, 839–844. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Carrero-Carrón, I.; Rubio, M.B.; Niño-Sánchez, J.; Navas-Cortés, J.A.; Jiménez-Díaz, R.M.; Monte, E.; Hermosa, R. Interactions between Trichoderma harzianum and defoliating Verticillium dahliae in resistant and susceptible wild olive clones. Plant Pathol. 2018, 67, 1758–1767. [Google Scholar] [CrossRef] [Green Version]
  57. Beckers, G.J.M.; Jaskiewicz, M.; Liu, Y.; Underwood, W.R.; He, S.Y.; Zhang, S.; Conrath, U. Mitogen-activated protein kinases 3 and 6 are required for full priming of stress responses in Arabidopsis thaliana. Plant Cell 2009, 21, 944–953. [Google Scholar] [CrossRef] [Green Version]
  58. Su, J.; Yang, L.; Zhu, Q.; Wu, H.; He, Y.; Liu, Y.; Xu, J.; Jiang, D.; Zhang, S. Active photosynthetic inhibition mediated by MPK3/MPK6 is critical to effector-triggered immunity. PLoS Biol. 2018, 16, e2004122. [Google Scholar] [CrossRef]
  59. Pitzschke, A.; Schikora, A.; Hirt, H. MAPK cascade signalling networks in plant defence. Curr. Opin. Plant Biol. 2009, 12, 421–426. [Google Scholar] [CrossRef]
  60. Wiermer, M.; Feys, B.J.; Parker, J.E. Plant immunity: The EDS1 regulatory node. Curr. Opin. Plant Biol. 2005, 8, 383–389. [Google Scholar] [CrossRef] [Green Version]
  61. 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, 1169–1179. [Google Scholar] [CrossRef] [Green Version]
  62. Contreras-Cornejo, H.A.; López-Bucio, J.S.; Méndez-Bravo, A.; Macías-Rodríguez, L.; Ramos-Vega, M.; Guevara-García, Á.A.; López-Bucio, J. Mitogen-activated protein kinase 6 and ethylene and auxin signaling pathways are involved in Arabidopsis root-system architecture alterations by Trichoderma atroviride. Mol. Plant-Microbe Interact. 2015, 28, 701–710. [Google Scholar] [CrossRef] [Green Version]
  63. Liu, Y.; Zhang, S. Phosphorylation of 1-aminocyclopropane-1-carboxylic acid synthase by MPK6, a stress-responsive mitogen-activated protein kinase, induces ethylene biosynthesis in Arabidopsis. Plant Cell 2004, 16, 3386–3399. [Google Scholar] [CrossRef] [Green Version]
  64. Meng, X.; Xu, J.; He, Y.; Yang, K.Y.; Mordorski, B.; Liu, Y.; Zhang, S. Phosphorylation of an ERF transcription factor by Arabidopsis MPK3/MPK6 regulates plant defense gene induction and fungal resistance. Plant Cell 2013, 25, 1126–1142. [Google Scholar] [CrossRef] [Green Version]
  65. Birkenbihl, R.P.; Diezel, C.; Somssich, I.E. Arabidopsis WRKY33 is a key transcriptional regulator of hormonal and metabolic responses toward Botrytis cinerea infection. Plant Physiol. 2012, 159, 266–285. [Google Scholar] [CrossRef] [Green Version]
  66. Mayo, S.; Cominelli, E.; Sparvoli, F.; González-López, O.; Rodríguez-González, A.; Gutiérrez, S.; Casquero, P.A. Development of a qPCR strategy to select bean genes involved in plant defense response and regulated by the Trichoderma velutinumRhizoctonia solani interaction. Front. Plant Sci. 2016, 7, 1109. [Google Scholar] [CrossRef]
  67. Jung, H.W.; Tschaplinski, T.J.; Wang, L.; Glazebrook, J.; Greenberg, J.T. Priming in systemic plant immunity. Science 2009, 324, 89–91. [Google Scholar] [CrossRef]
  68. Spoel, S.H.; Dong, X. How do plants achieve immunity? Defence without specialized immune cells. Nat. Rev. Immunol. 2012, 12, 89–100. [Google Scholar] [CrossRef]
  69. Pitzschke, A.; Datta, S.; Persak, H. Salt stress in Arabidopsis: Lipid transfer protein AZI1 and its control by mitogen-activated protein kinase MPK3. Mol. Plant 2014, 7, 722–738. [Google Scholar] [CrossRef] [Green Version]
  70. Segarra, G.; Van Der Ent, S.; Trillas, I.; Pieterse, C.M.J. MYB72, a node of convergence in induced systemic resistance triggered by a fungal and a bacterial beneficial microbe. Plant Biol. 2009, 11, 90–96. [Google Scholar] [CrossRef] [Green Version]
  71. Mathys, J.; De Cremer, K.; Timmermans, P.; Van Kerckhove, S.; Lievens, B.; Vanhaecke, M.; Cammue, B.P.A.; 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. [Google Scholar] [CrossRef] [Green Version]
  72. Brotman, Y.; Landau, U.; Cuadros-Inostroza, Á.; Takayuki, T.; Fernie, A.R.; 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, e1003221. [Google Scholar] [CrossRef]
  73. Sáenz-Mata, J.; Salazar-Badillo, F.B.; Jiménez-Bremont, J.F. Transcriptional regulation of Arabidopsis thaliana WRKY genes under interaction with beneficial fungus Trichoderma atroviride. Acta Physiol. Plant. 2014, 36, 1085–1093. [Google Scholar] [CrossRef]
  74. Medeiros, H.A.; De Araújo Filho, J.V.; Freitas, L.G.; Castillo, P.; Rubio, M.B.; Hermosa, R.; Monte, E. Tomato progeny inherit resistance to the nematode Meloidogyne javanica linked to plant growth induced by the biocontrol fungus Trichoderma atroviride. Sci. Rep. 2017, 7, 1–13. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  75. Rubio, M.B.; Martínez de Alba, A.E.; Nicolás, C.; Monte, E.; Hermosa, R. Early root transcriptomic changes in wheat seedlings colonized by Trichoderma harzianum under different inorganic nitrogen supplies. Front. Microbiol. 2019, 10, 2444. [Google Scholar] [CrossRef] [PubMed]
  76. Dou, K.; Wang, Z.; Zhang, R.; Wang, N.; Fan, H.; Diao, G. Cloning and characteristic analysis of a novel aspartic protease gene Asp55 from Trichoderma asperellum ACCC30536. Microbiol. Res. 2014, 169, 915–923. [Google Scholar] [CrossRef] [PubMed]
  77. Yu, W.; Mijiti, G.; Huang, Y.; Fan, H.; Wang, Y.; Liu, Z. Functional analysis of eliciting plant response protein Epl1-Tas from Trichoderma asperellum ACCC30536. Sci. Rep. 2018, 8, 1–13. [Google Scholar] [CrossRef]
  78. Manganiello, G.; Sacco, A.; Ercolano, M.R.; Vinale, F.; Lanzuise, S.; Pascale, A.; Napolitano, M.; Lombardi, N.; Lorito, M.; Woo, S.L. Modulation of tomato response to Rhizoctonia solani by Trichoderma harzianum and its secondary metabolite harzianic acid. Front. Microbiol. 2018, 9, 1966. [Google Scholar] [CrossRef]
  79. Romero-Contreras, Y.J.; Ramírez-Valdespino, C.A.; Guzmán-Guzmán, P.; Macías-Segoviano, J.I.; Villagómez-Castro, J.C.; Olmedo-Monfil, V. Tal6 from Trichoderma atroviride is a LysM effector involved in mycoparasitism and plant association. Front. Microbiol. 2019, 10, 2231. [Google Scholar] [CrossRef]
  80. Coppola, M.; Cascone, P.; Di Lelio, I.; Woo, S.L.; Lorito, M.; Rao, R.; Pennacchio, F.; Guerrieri, E.; Digilio, M.C. Trichoderma atroviride P1 colonization of tomato plants enhances both direct and indirect defense barriers against insects. Front. Physiol. 2019, 10, 813. [Google Scholar] [CrossRef] [Green Version]
  81. Kottb, M.; Gigolashvili, T.; Großkinsky, D.K.; Piechulla, B. Trichoderma volatiles effecting Arabidopsis: From inhibition to protection against phytopathogenic fungi. Front. Microbiol. 2015, 6, 995. [Google Scholar] [CrossRef] [Green Version]
  82. Banerjee, A.; Roychoudhury, A. WRKY proteins: Signaling and regulation of expression during abiotic stress responses. Sci. World J. 2015, 2015, 807560. [Google Scholar] [CrossRef] [Green Version]
  83. Wang, D.; Amornsiripanitch, N.; Dong, X. A genomic approach to identify regulatory nodes in the transcriptional network of systemic acquired resistance in plants. PLoS Pathog. 2006, 2, e123. [Google Scholar] [CrossRef] [Green Version]
  84. Zhang, Y.; Lee, C.-W.; Wehner, N.; Imdahl, F.; Svetlana, V.; Weiste, C.; Dröge-Laser, W.; Deeken, R. Regulation of oncogene expression in T-DNA-transformed plant cells. PLoS Pathog. 2015, 11, e1004620. [Google Scholar] [CrossRef]
  85. Gao, X.; Cox, K.L.; He, P. Functions of calcium-dependent protein kinases in plant innate immunity. Plants 2014, 3, 160–176. [Google Scholar] [CrossRef] [Green Version]
  86. Alvarez-Venegas, R.; Abdallat, A.A.; Guo, M.; Alfano, J.R.; Avramova, Z. Epigenetic control of a transcription factor at the cross section of two antagonistic pathways. Epigenetics 2007, 2, 106–113. [Google Scholar] [CrossRef] [Green Version]
  87. Jaskiewicz, M.; Conrath, U.; Peterhälnsel, C. Chromatin modification acts as a memory for systemic acquired resistance in the plant stress response. EMBO Rep. 2011, 12, 50–55. [Google Scholar] [CrossRef] [Green Version]
  88. Phukan, U.J.; Jeena, G.S.; Shukla, R.K. WRKY transcription factors: Molecular regulation and stress responses in plants. Front. Plant Sci. 2016, 7, 760. [Google Scholar] [CrossRef] [Green Version]
  89. Barco, B.; Clay, N.K. Hierarchical and dynamic regulation of defense-responsive specialized metabolism by WRKY and MYB transcription factors. Front. Plant Sci. 2020, 10, 1775. [Google Scholar] [CrossRef] [Green Version]
  90. Shim, J.S.; Choi, Y.D. Direct regulation of WRKY70 by AtMYB44 in plant defense responses. Plant Signal. Behav. 2013, 8, e24509. [Google Scholar] [CrossRef] [Green Version]
  91. Shin, R.; Burch, A.Y.; Huppert, K.A.; Tiwari, S.B.; Murphy, A.S.; Guilfoyle, T.J.; Schachtman, D.P. The Arabidopsis transcription factor MYB77 modulates auxin signal transduction. Plant Cell 2007, 19, 2440–2453. [Google Scholar] [CrossRef] [Green Version]
  92. Van der Ent, S.; Verhagen, B.W.M.; Van Doorn, R.; Bakker, D.; Verlaan, M.G.; Pel, M.J.C.; Joosten, R.G.; Proveniers, M.C.G.; Van Loon, L.C.; Ton, J.; et al. MYB72 is required in early signaling steps of rhizobacteria-induced systemic resistance in Arabidopsis. Plant Physiol. 2008, 146, 1293–1304. [Google Scholar] [CrossRef] [Green Version]
  93. Kranz, H.D.; Denekamp, M.; Greco, R.; Jin, H.; Leyva, A.; Meissner, R.C.; Petroni, K.; Urzainqui, A.; Bevan, M.; Martin, C.; et al. Towards functional characterisation of the members of the R2R3-MYB gene family from Arabidopsis thaliana. Plant J. 1998, 16, 263–276. [Google Scholar] [CrossRef]
  94. Kazan, K.; Manners, J.M. MYC2: The master in action. Mol. Plant 2013, 6, 686–703. [Google Scholar] [CrossRef] [Green Version]
  95. Abe, H.; Urao, T.; Ito, T.; Seki, M.; Shinozaki, K.; Yamaguchi-Shinozaki, K. Arabidopsis AtMYC2 (bHLH) and AtMYB2 (MYB) function as transcriptional activators in abscisic acid signaling. Plant Cell 2003, 15, 63–78. [Google Scholar] [CrossRef] [Green Version]
  96. Zhai, Q.; Li, C. The plant Mediator complex and its role in jasmonate signaling. J. Exp. Bot. 2019, 70, 3415–3424. [Google Scholar] [CrossRef]
  97. Çevik, V.; Kidd, B.N.; Zhang, P.; Hill, C.; Kiddle, S.; Denby, K.J.; Holub, E.B.; Cahill, D.M.; Manners, J.M.; Schenk, P.M.; et al. MEDIATOR25 acts as an integrative hub for the regulation of jasmonate-responsive gene expression in Arabidopsis. Plant Physiol. 2012, 160, 541–555. [Google Scholar] [CrossRef] [Green Version]
  98. Caarls, L.; Van Der Does, D.; Hickman, R.; Jansen, W.; Van Verk, M.C.; Proietti, S.; Lorenzo, O.; Solano, R.; Pieterse, C.M.J.; Van Wees, S.C.M. Assessing the role of ETHYLENE RESPONSE FACTOR transcriptional repressors in salicylic acid-mediated suppression of jasmonic acid-responsive genes. Plant Cell Physiol. 2017, 58, 266–278. [Google Scholar] [CrossRef]
  99. Liu, Y.; Du, M.; Deng, L.; Shen, J.; Fang, M.; Chen, Q.; Lu, Y.; Wang, Q.; Li, C.; Zhai, Q. MYC2 regulates the termination of jasmonate signaling via an autoregulatory negative feedback loop. Plant Cell 2019, 31, 106–127. [Google Scholar] [CrossRef] [Green Version]
  100. Wang, H.; Li, S.; Li, Y.; Xu, Y.; Wang, Y.; Zhang, R.; Sun, W.; Chen, Q.; Wang, X.J.; Li, C.; et al. MED25 connects enhancer–promoter looping and MYC2-dependent activation of jasmonate signalling. Nat. Plants 2019, 5, 616–625. [Google Scholar] [CrossRef]
  101. Chen, R.; Jiang, H.; Li, L.; Zhai, Q.; Qi, L.; Zhou, W.; Liu, X.; Li, H.; Zheng, W.; Sun, J.; et al. The Arabidopsis Mediator subunit MED25 differentially regulates jasmonate and abscisic acid signaling through interacting with the MYC2 and ABI5 transcription factors. Plant Cell 2012, 24, 2898–2916. [Google Scholar] [CrossRef] [Green Version]
  102. Raya-González, J.; Ortiz-Castro, R.; Ruiz-Herrera, L.F.; Kazan, K.; López-Bucio, J. Phytochrome and flowering time1/mediator25 regulates lateral root formation via auxin signaling in Arabidopsis. Plant Physiol. 2014, 165, 880–894. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  103. Peñuelas, M.; Monte, I.; Schweizer, F.; Vallat, A.; Reymond, P.; García-Casado, G.; Franco-Zorrilla, J.M.; Solano, R. Jasmonate-related MYC transcription factors are functionally conserved in Marchantia polymorpha. Plant Cell 2019, 31, 2491–2509. [Google Scholar] [CrossRef] [PubMed]
  104. Maag, D.; Kandula, D.R.W.; Müller, C.; Mendoza-Mendoza, A.; Wratten, S.D.; Stewart, A.; Rostás, M. Trichoderma atroviride LU132 promotes plant growth but not induced systemic resistance to Plutella xylostella in oilseed rape. BioControl 2014, 59, 241–252. [Google Scholar] [CrossRef]
  105. Yu, Z.; Wang, Z.; Zhang, Y.; Wang, Y.; Liu, Z. Biocontrol and growth-promoting effect of Trichoderma asperellum TaspHu1 isolate from Juglans mandshurica rhizosphere soil. Microbiol. Res. 2021, 242, 126596. [Google Scholar] [CrossRef] [PubMed]
  106. Shoresh, M.; Harman, G.E.; Mastouri, F. Induced systemic resistance and plant responses to fungal biocontrol agents. Annu. Rev. Phytopathol. 2010, 48, 21–43. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  107. Salas-Marina, M.A.; Silva-Flores, M.A.; Uresti-Rivera, E.E.; Castro-Longoria, E.; Herrera-Estrella, A.; Casas-Flores, S. Colonization of Arabidopsis roots by Trichoderma atroviride promotes growth and enhances systemic disease resistance through jasmonic acid/ethylene and salicylic acid pathways. Eur. J. Plant Pathol. 2011, 131, 15–26. [Google Scholar] [CrossRef]
  108. Chacón, M.; Rodríguez-Galán, O.; Benítez, T.; Sousa, S.; Rey, M.; Llobell, A.; Delgado-Jarana, J. Microscopic and transcriptome analyses of early colonization of tomato roots by Trichoderma harzianum. Int. Microbiol. 2007, 10, 19–27. [Google Scholar] [CrossRef]
  109. Van Wees, S.C.; Van der Ent, S.; Pieterse, C.M. Plant immune responses triggered by beneficial microbes. Curr. Opin. Plant Biol. 2008, 11, 443–448. [Google Scholar] [CrossRef] [Green Version]
  110. Malmierca, M.G.; Cardoza, R.E.; Alexander, N.J.; McCormick, S.P.; Hermosa, R.; Monte, E.; Gutiérrez, S. Involvement of Trichoderma trichothecenes in the biocontrol activity and induction of plant defense-related genes. Appl. Environ. Microbiol. 2012, 78, 4856–4868. [Google Scholar] [CrossRef] [Green Version]
  111. Martínez-Medina, A.; Fernández, I.; Sánchez-Guzmán, M.J.; Jung, S.C.; Pascual, J.A.; Pozo, M.J. Deciphering the hormonal signaling network behind the systemic resistance induced by Trichoderma harzianum in tomato. Front. Plant Sci. 2013, 4, 206. [Google Scholar] [CrossRef] [Green Version]
  112. Martínez-Medina, A.; Fernandez, I.; Lok, G.B.; Pozo, M.J.; Pieterse, C.M.J.; Van Wees, S.C.M. Shifting from priming of salicylic acid- to jasmonic acid-regulated defences by Trichoderma protects tomato against the root knot nematode Meloidogyne incognita. N. Phytol. 2017, 213, 1363–1377. [Google Scholar] [CrossRef] [Green Version]
  113. Rubio, M.B.; Quijada, N.M.; Pérez, E.; Domínguez, S.; Monte, E.; Hermosa, R. Identifying beneficial qualities of Trichoderma parareesei for plants. Appl. Environ. Microbiol. 2014, 80, 1864–1873. [Google Scholar] [CrossRef] [Green Version]
  114. Moore, J.W.; Loake, G.J.; Spoel, S.H. Transcription dynamics in plant immunity. Plant Cell 2011, 23, 2809–2820. [Google Scholar] [CrossRef] [Green Version]
  115. Pieterse, C.M.J.; Leon-Reyes, A.; Van Der Ent, S.; Van Wees, S.C.M. Networking by small-molecule hormones in plant immunity. Nat. Chem. Biol. 2009, 5, 308–316. [Google Scholar] [CrossRef] [Green Version]
  116. Alvarez, M.E.; Nota, F.; Cambiagno, D.A. Epigenetic control of plant immunity. Mol. Plant Pathol. 2010, 11, 563–576. [Google Scholar] [CrossRef]
  117. Reimer-Michalski, E.M.; Conrath, U. Innate immune memory in plants. Semin. Immunol. 2016, 28, 319–327. [Google Scholar] [CrossRef]
  118. Zhu, Q.H.; Shan, W.X.; Ayliffe, M.A.; Wang, M.B. Epigenetic mechanisms: An emerging player in plant-microbe interactions. Mol. Plant-Microbe Interact. 2016, 29, 187–196. [Google Scholar] [CrossRef] [Green Version]
  119. Sharma, C.; Kumar, S.; Saripalli, G.; Jain, N.; Raghuvanshi, S.; Sharma, J.B.; Prabhu, K.V.; Sharma, P.K.; Balyan, H.S.; Gupta, P.K. H3K4/K9 acetylation and Lr28-mediated expression of six leaf rust responsive genes in wheat (Triticum aestivum). Mol. Genet. Genom. 2019, 294, 227–241. [Google Scholar] [CrossRef]
  120. Kim, K.C.; Lai, Z.; Fan, B.; Chen, Z. Arabidopsis WRKY38 and WRKY62 transcription factors interact with histone deacetylase 19 in basal defense. Plant Cell 2008, 20, 2357–2371. [Google Scholar] [CrossRef] [Green Version]
  121. Zhou, C.; Zhang, L.; Duan, J.; Miki, B.; Wu, K. Histone Deacetylase19 is involved in jasmonic acid and ethylene signaling of pathogen response in Arabidopsis. Plant Cell 2005, 17, 1196–1204. [Google Scholar] [CrossRef] [Green Version]
  122. Huang, S.; Zhang, A.; Jin, J.B.; Zhao, B.; Wang, T.J.; Wu, Y.; Wang, S.; Liu, Y.; Wang, J.; Guo, P.; et al. Arabidopsis histone H3K4 demethylase JMJ17 functions in dehydration stress response. N. Phytol. 2019, 223, 1372–1387. [Google Scholar] [CrossRef]
  123. An, C.; Li, L.; Zhai, Q.; You, Y.; Deng, L.; Wu, F.; Chen, R.; Jiang, H.; Wang, H.; Chen, Q.; et al. Mediator subunit MED25 links the jasmonate receptor to transcriptionally active chromatin. Proc. Natl. Acad. Sci. USA 2017, 114, E8930–E8939. [Google Scholar] [CrossRef] [Green Version]
  124. Espinas, N.A.; Saze, H.; Saijo, Y. Epigenetic control of defense signaling and priming in plants. Front. Plant Sci. 2016, 7, 1201. [Google Scholar] [CrossRef]
  125. Roosjen, M.; Paque, S.; Weijers, D. Auxin response factors: Output control in auxin biology. J. Exp. Bot. 2018, 69, 179–188. [Google Scholar] [CrossRef]
  126. Luna, E.; Bruce, T.J.A.; Roberts, M.R.; Flors, V.; Ton, J. Next-generation systemic acquired resistance. Plant Physiol. 2012, 158, 844–853. [Google Scholar] [CrossRef] [Green Version]
  127. Pavet, V.; Quintero, C.; Cecchini, N.M.; Rosa, A.L.; Alvarez, M.E. Arabidopsis displays centromeric DNA hypomethylation and cytological alterations of heterochromatin upon attack by Pseudomonas syringae. Mol. Plant-Microbe Interact. 2006, 19, 577–587. [Google Scholar] [CrossRef] [Green Version]
  128. Slaughter, A.; Daniel, X.; Flors, V.; Luna, E.; Hohn, B.; Mauch-Mani, B. Descendants of primed Arabidopsis plants exhibit resistance to biotic stress. Plant Physiol. 2012, 158, 835–843. [Google Scholar] [CrossRef] [Green Version]
  129. Kathiria, P.; Sidler, C.; Golubov, A.; Kalischuk, M.; Kawchuk, L.M.; Kovalchuk, I. Tobacco mosaic virus infection results in an increase in recombination frequency and resistance to viral, bacterial, and fungal pathogens in the progeny of infected tobacco plants. Plant Physiol. 2010, 153, 1859–1870. [Google Scholar] [CrossRef] [Green Version]
  130. Boyko, A.; Blevins, T.; Yao, Y.; Golubov, A.; Bilichak, A.; Ilnytskyy, Y.; Hollander, J.; Meins, F.; Kovalchuk, I. Transgenerational adaptation of Arabidopsis to stress requires DNA methylation and the function of dicer-like proteins. PLoS ONE 2010, 5, e9514. [Google Scholar] [CrossRef]
  131. Yu, A.; Lepère, G.; Jay, F.; Wang, J.; Bapaume, L.; Wang, Y.; Abraham, A.L.; Penterman, J.; Fischer, R.L.; Voinnet, O.; et al. Dynamics and biological relevance of DNA demethylation in Arabidopsis antibacterial defense. Proc. Natl. Acad. Sci. USA 2013, 110, 2389–2394. [Google Scholar] [CrossRef] [Green Version]
  132. Martínez de Alba, A.E.; Elvira-Matelot, E.; Vaucheret, H. Gene silencing in plants: A diversity of pathways. Biochim. Biophys. Acta Gene Regul. Mech. 2013, 1829. [Google Scholar] [CrossRef] [PubMed]
  133. Parent, J.S.; Martínez de Alba, A.E.; Vaucheret, H. The origin and effect of small RNA signaling in plants. Front. Plant Sci. 2012, 3, 179. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  134. Mallory, A.C.; Vaucheret, H. Functions of microRNAs and related small RNAs in plants. Nat. Genet. 2006, 38, S31–S36. [Google Scholar] [CrossRef] [PubMed]
  135. Voinnet, O. Origin, biogenesis, and activity of plant microRNAs. Cell 2009, 136, 669–687. [Google Scholar] [CrossRef] [Green Version]
  136. Carthew, R.W.; Sontheimer, E.J. Origins and mechanisms of miRNAs and siRNAs. Cell 2009, 136, 642–655. [Google Scholar] [CrossRef] [Green Version]
  137. Jones-Rhoades, M.W.; Bartel, D.P.; Bartel, B. MicroRNAs and their regulatory roles in plants. Annu. Rev. Plant Biol. 2006, 57, 19–53. [Google Scholar] [CrossRef]
  138. Rajagopalan, R.; Vaucheret, H.; Trejo, J.; Bartel, D.P. A diverse and evolutionarily fluid set of microRNAs in Arabidopsis thaliana. Genes Dev. 2006, 20, 3407–3425. [Google Scholar] [CrossRef] [Green Version]
  139. Boutet, S.; Vazquez, F.; Liu, J.; Béclin, C.; Fagard, M.; Gratias, A.; Morel, J.B.; Crété, P.; Chen, X.; Vaucheret, H. Arabidopsis HEN1: A genetic link between endogenous miRNA controlling development and siRNA controlling transgene silencing and virus resistance. Curr. Biol. 2003, 13, 843–848. [Google Scholar] [CrossRef] [Green Version]
  140. Li, J.; Yang, Z.; Yu, B.; Liu, J.; Chen, X. Methylation protects miRNAs and siRNAs from a 3′-end uridylation activity in Arabidopsis. Curr. Biol. 2005, 15, 1501–1507. [Google Scholar] [CrossRef] [Green Version]
  141. Yu, B.; Yang, Z.; Li, J.; Minakhina, S.; Yang, M.; Padgett, R.W.; Steward, R.; Chen, X. Methylation as a crucial step in plant microRNA biogenesis. Science 2005, 307, 932–935. [Google Scholar] [CrossRef] [Green Version]
  142. Park, M.Y.; Wu, G.; Gonzalez-Sulser, A.; Vaucheret, H.; Poethig, R.S. Nuclear processing and export of microRNAs in Arabidopsis. Proc. Natl. Acad. Sci. USA 2005, 102, 3691–3696. [Google Scholar] [CrossRef] [Green Version]
  143. Mi, S.; Cai, T.; Hu, Y.; Chen, Y.; Hodges, E.; Ni, F.; Wu, L.; Li, S.; Zhou, H.; Long, C.; et al. Sorting of small RNAs into Arabidopsis argonaute complexes is directed by the 5′ terminal nucleotide. Cell 2008, 133, 116–127. [Google Scholar] [CrossRef] [Green Version]
  144. Montgomery, T.A.; Howell, M.D.; Cuperus, J.T.; Li, D.; Hansen, J.E.; Alexander, A.L.; Chapman, E.J.; Fahlgren, N.; Allen, E.; Carrington, J.C. Specificity of ARGONAUTE7-miR390 interaction and dual functionality in TAS3 trans-acting siRNA formation. Cell 2008, 133, 128–141. [Google Scholar] [CrossRef] [Green Version]
  145. Takeda, A.; Iwasaki, S.; Watanabe, T.; Utsumi, M.; Watanabe, Y. The mechanism selecting the guide strand from small RNA duplexes is different among argonaute proteins. Plant Cell Physiol. 2008, 49, 493–500. [Google Scholar] [CrossRef] [Green Version]
  146. Zhu, H.; Hu, F.; Wang, R.; Zhou, X.; Sze, S.H.; Liou, L.W.; Barefoot, A.; Dickman, M.; Zhang, X. Arabidopsis argonaute10 specifically sequesters miR166/165 to regulate shoot apical meristem development. Cell 2011, 145, 242–256. [Google Scholar] [CrossRef] [Green Version]
  147. Rhoades, M.W.; Reinhart, B.J.; Lim, L.P.; Burge, C.B.; Bartel, B.; Bartel, D.P. Prediction of plant microRNA targets. Cell 2002, 110, 513–520. [Google Scholar] [CrossRef] [Green Version]
  148. Baumberger, N.; Baulcombe, D.C. Arabidopsis ARGONAUTE1 is an RNA Slicer that selectively recruits microRNAs and short interfering RNAs. Proc. Natl. Acad. Sci. USA 2005, 102, 11928–11933. [Google Scholar] [CrossRef] [Green Version]
  149. Schwab, R.; Palatnik, J.F.; Riester, M.; Schommer, C.; Schmid, M.; Weigel, D. Specific effects of microRNAs on the plant transcriptome. Dev. Cell 2005, 8, 517–527. [Google Scholar] [CrossRef] [Green Version]
  150. Rüegger, S.; Großhans, H. MicroRNA turnover: When, how, and why. Trends Biochem. Sci. 2012, 37, 436–446. [Google Scholar] [CrossRef]
  151. Bao, N.; Lye, K.W.; Barton, M.K. MicroRNA binding sites in Arabidopsis class III HD-ZIP mRNAs are required for methylation of the template chromosome. Dev. Cell 2004, 7, 653–662. [Google Scholar] [CrossRef]
  152. Aukerman, M.J.; Sakai, H. Regulation of flowering time and floral organ identity by a microRNA and its APETALA2-like target genes. Plant Cell 2003, 15, 2730–2741. [Google Scholar] [CrossRef] [Green Version]
  153. Chen, X. A microRNA as a translational repressor of APETALA2 in Arabidopsis flower development. Science 2004, 303, 2022–2025. [Google Scholar] [CrossRef] [Green Version]
  154. Gandikota, M.; Birkenbihl, R.P.; Höhmann, S.; Cardon, G.H.; Saedler, H.; Huijser, P. The miRNA156/157 recognition element in the 3′ UTR of the Arabidopsis SBP box gene SPL3 prevents early flowering by translational inhibition in seedlings. Plant J. 2007, 49, 683–693. [Google Scholar] [CrossRef] [Green Version]
  155. Brodersen, P.; Sakvarelidze-Achard, L.; Bruun-Rasmussen, M.; Dunoyer, P.; Yamamoto, Y.Y.; Sieburth, L.; Voinnet, O. Widespread translational inhibition by plant miRNAs and siRNAs. Science 2008, 320, 1185–1190. [Google Scholar] [CrossRef]
  156. Lanet, E.; Delannoy, E.; Sormani, R.; Floris, M.; Brodersen, P.; Crété, P.; Voinnet, O.; Robaglia, C. Biochemical evidence for translational repression by Arabidopsis microRNAs. Plant Cell 2009, 21, 1762–1768. [Google Scholar] [CrossRef] [Green Version]
  157. Mallory, A.C.; Hinze, A.; Tucker, M.R.; Bouché, N.; Gasciolli, V.; Elmayan, T.; Lauressergues, D.; Jauvion, V.; Vaucheret, H.; Laux, T. Redundant and specific roles of the ARGONAUTE proteins AGO1 and ZLL in development and small RNA-directed gene silencing. PLoS Genet. 2009, 5, e1000646. [Google Scholar] [CrossRef] [Green Version]
  158. Wang, M.; Thomas, N.; Jin, H. Cross-kingdom RNA trafficking and environmental RNAi for powerful innovative pre- and post-harvest plant protection. Curr. Opin. Plant Biol. 2017, 38, 133–141. [Google Scholar] [CrossRef]
  159. Weiberg, A.; Wang, M.; Lin, F.M.; Zhao, H.; Zhang, Z.; Kaloshian, I.; Huang, H.D.; Jin, H. Fungal small RNAs suppress plant immunity by hijacking host RNA interference pathways. Science 2013, 342, 118–123. [Google Scholar] [CrossRef] [Green Version]
  160. Wang, B.; Sun, Y.; Song, N.; Zhao, M.; Liu, R.; Feng, H.; Wang, X.; Kang, Z. Puccinia striiformis f. sp. tritici microRNA-like RNA 1 (Pst-milR1), an important pathogenicity factor of Pst, impairs wheat resistance to Pst by suppressing the wheat pathogenesis-related 2 gene. N. Phytol. 2017, 215, 338–350. [Google Scholar] [CrossRef] [Green Version]
  161. Shahid, S.; Kim, G.; Johnson, N.R.; Wafula, E.; Wang, F.; Coruh, C.; Bernal-Galeano, V.; Phifer, T.; Depamphilis, C.W.; Westwood, J.H.; et al. MicroRNAs from the parasitic plant Cuscuta campestris target host messenger RNAs. Nature 2018, 553, 82–85. [Google Scholar] [CrossRef]
  162. Rubio, M.B.; Medeiros, H.A.; Morán-Diez, M.E.; Castillo, P.; Hermosa, R.; Monte, E. A split-root method to study systemic and heritable traits induced by Trichoderma in tomato plants. In Methods in Rhizosphere Biology Research. Rhizosphere Biology, 1st ed.; Reinhardt, D., Sharma, A., Eds.; Springer: Singapore, 2019; pp. 151–166. [Google Scholar]
  163. Samolski, I.; Rincón, A.M.; Pinzón, L.M.; Viterbo, A.; Monte, E. The qid74 gene from Trichoderma harzianum has a role in root architecture and plant biofertilization. Microbiology 2012, 158, 129–138. [Google Scholar] [CrossRef] [PubMed]
  164. Mangano, S.; Denita-Juarez, S.P.; Choi, H.S.; Marzol, E.; Hwang, Y.; Ranocha, P.; Velasquez, S.M.; Borassi, C.; Barberini, M.L.; Aptekmann, A.A.; et al. Molecular link between auxin and ROS-mediated polar growth. Proc. Natl. Acad. Sci. USA 2017, 114, 5289–5294. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  165. Bian, H.; Xie, Y.; Guo, F.; Han, N.; Ma, S.; Zeng, Z.; Wang, J.; Yang, Y.; Zhu, M. Distinctive expression patterns and roles of the miRNA393⁄TIR1 homolog module in regulating flag leaf inclination and primary and crown root growth in rice (Oryza sativa). N. Phytol. 2012, 196, 149–161. [Google Scholar] [CrossRef] [PubMed]
  166. Wang, J.W.; Wang, L.J.; Mao, Y.B.; Cai, W.J.; Xue, H.W.; Chen, X.Y. Control of root cap formation by microRNA-targeted auxin response factors in Arabidopsis. Plant Cell 2005, 17, 2204–2216. [Google Scholar] [CrossRef] [Green Version]
  167. Meng, Y.; Ma, X.; Chen, D.; Wu, P.; Chen, M. MicroRNA-mediated signaling involved in plant root development. Biochem. Biophys. Res. Commun. 2010, 393, 345–349. [Google Scholar] [CrossRef]
  168. Glaich, O.; Parikh, S.; Bell, R.E.; Mekahel, K.; Donyo, M.; Leader, Y.; Shayevitch, R.; Sheinboim, D.; Yannai, S.; Hollander, D.; et al. DNA methylation directs microRNA biogenesis in mammalian cells. Nat. Commun. 2019, 10, 1–11. [Google Scholar] [CrossRef] [Green Version]
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Figure 1. Schematic outline of plant’s early response to the interaction with Trichoderma. Plant´s cell surface pattern recognition receptors (PRR) are the first line of defence against Trichoderma effectors during the early response (this first stage of the colonization being considered by the plant as an attack). As a result of this first encounter between the plant and Trichoderma, a series of events will be triggered in the plant including the rapid release of reactive oxygen species (ROS), the deposition of callose, calcium influx, and accumulation of salicylic acid (SA) at the primary inoculation site as well as for systemic defence. Another one of the early events triggered by PRR stimulation is the activation of the mitogen-activated protein kinases (MAPK) cascade mediated by the G-protein complex, which will lead to several intermediate and late defence responses. Trichoderma spp. will find their way to balance this early plant response into one of mutual benefit by regulating homeostasis and reducing the synthesis of plant lipid barrier polymers, as well as by decreasing the production of SA.
Figure 1. Schematic outline of plant’s early response to the interaction with Trichoderma. Plant´s cell surface pattern recognition receptors (PRR) are the first line of defence against Trichoderma effectors during the early response (this first stage of the colonization being considered by the plant as an attack). As a result of this first encounter between the plant and Trichoderma, a series of events will be triggered in the plant including the rapid release of reactive oxygen species (ROS), the deposition of callose, calcium influx, and accumulation of salicylic acid (SA) at the primary inoculation site as well as for systemic defence. Another one of the early events triggered by PRR stimulation is the activation of the mitogen-activated protein kinases (MAPK) cascade mediated by the G-protein complex, which will lead to several intermediate and late defence responses. Trichoderma spp. will find their way to balance this early plant response into one of mutual benefit by regulating homeostasis and reducing the synthesis of plant lipid barrier polymers, as well as by decreasing the production of SA.
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Figure 2. Schematic outline of plant immune local and systemic responses to Trichoderma priming stimulus. These responses involve a transcriptional reprogramming process where the action of enhancers (Mediator complex-subunit MED25) and transcription factors (TF) have a key role in the regulation of phytohormone synthesis pathways. Regulation of these processes is mediated by small RNAs (sRNA) through a transcriptional gene silencing (TGS) mechanism—mainly through the RNA-directed DNA methylation (RdDM) pathway—or through post-transcriptional gene silencing (PTGS), which has been proven to impact whole-genome DNA methylation patterns. The inheritance of these epigenetic marks on the offspring leads to the plant immune response against abiotic or biotic stresses without the need for an external stimulus triggered by Trichoderma. Abbreviations: SA, salicylic acid; JAs, jasmonates; ET, ethylene; ABA, abscisic acid; IAA, indole-3-acetic acid; GAs, gibberellins. Created in Biorender.com.
Figure 2. Schematic outline of plant immune local and systemic responses to Trichoderma priming stimulus. These responses involve a transcriptional reprogramming process where the action of enhancers (Mediator complex-subunit MED25) and transcription factors (TF) have a key role in the regulation of phytohormone synthesis pathways. Regulation of these processes is mediated by small RNAs (sRNA) through a transcriptional gene silencing (TGS) mechanism—mainly through the RNA-directed DNA methylation (RdDM) pathway—or through post-transcriptional gene silencing (PTGS), which has been proven to impact whole-genome DNA methylation patterns. The inheritance of these epigenetic marks on the offspring leads to the plant immune response against abiotic or biotic stresses without the need for an external stimulus triggered by Trichoderma. Abbreviations: SA, salicylic acid; JAs, jasmonates; ET, ethylene; ABA, abscisic acid; IAA, indole-3-acetic acid; GAs, gibberellins. Created in Biorender.com.
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Table
Table 1. Summary of plant WRKY, MYB, and MYC transcription factors (TF) regulated by Trichoderma spp. interactions through mitogen-activated protein kinases (MAPK) or Ca2+-dependent protein kinase (CDPK) cascades and their biological effects on plant hosts.
Table 1. Summary of plant WRKY, MYB, and MYC transcription factors (TF) regulated by Trichoderma spp. interactions through mitogen-activated protein kinases (MAPK) or Ca2+-dependent protein kinase (CDPK) cascades and their biological effects on plant hosts.
TFsBiological Process 1Trichoderma StrainPlant HostRegulatory EffectReference
WRKY2Abscisic acid (ABA)-mediated
responses, establishment of cell
polarity and pollen development		T. harzianum M10Tomato
Micro-Tom		Up-regulated (Up) after T. harzianum treatment. Down-regulated (Down)
after T. harzianum +
Rhizoctonia solani application		[78] 2
WRKY4Negative regulation of jasmonic acid (JA)-, ethylene (ET)-, and salicylic acid (SA)-dependent
defence responses		T. erinaceum T7Tomato S-22Down after T. erinaceum and
T. erinaceum + Fusarium oxysporum f. sp. lycopersici (FOL) application at 24 h and 48 h (in roots) and 48 h in leaves 		[50]
WRKY8Positive regulator of fungal attack, activated by ABA, salt stress, wounding, and H2O2T. atroviride IMI206040Arabidopsis Col-0Up after T. atroviride treatment
at 24–72 h		[73]
WRKY18Negative regulator of SA-dependent defence responses, positive regulator of JA- dependent defence responses to biotic stress, and ABA-dependent defence response to abiotic stressT. asperelloides T203Arabidopsis Col-0Up after T. asperelloides treatment at
9–24 h. Enables root colonization 		[72] 2
WRKY31Positive regulation of JA-, SA-,
gibberellins (GA)-dependent defence responses and terpene biosynthesis		T. erinaceum T7Tomato S-22Up after T. erinaceum and T. erinaceum + FOL at 24 h and 48 h
(in roots and leaves) 		[50]
WRKY33Negative regulation of SA-dependent early defence responses and positive regulation of JA-dependent defence responses at later stages.
Activation and maintenance of the priming memory		T. atroviride IMI206040Arabidopsis Col-0Up after T. atroviride treatment,
at 48–72 h		[79]
T. velutinum T028Bean CanelaUp after T. velutinum treatment. Down after T. velutinum + R. solani application[66]
T. atroviride IMI206040Arabidopsis Col-0Down after T. atroviride treatment
at 24–72 h		[73]
WRKY37Defence response to fungal attackT. erinaceum T7Tomato S-22Up after T. erinaceum and T. erinaceum + FOL application at 24 h
(in roots and leaves)		[50]
WRKY38Negative regulator of SA-dependent defence responses, susceptible to
inactivation by JA-induced histone deacetylase HDA19		T. atroviride IMI206040Arabidopsis Col-0Up after T. atroviride treatment
at 96 and 144 h		[73]
WRKY40Central negative regulation of ABA signalling, positive regulation of
JA-dependent defence responses. Activation and maintenance of the priming memory		T. asperelloides T203Arabidopsis Col-0Up after T. asperelloides treatment at 9, 24, and 96 h. Enables root colonization[72] 2
WRKY54Negative regulator of SA
biosynthesis, positive regulator of SA-dependent defence responses and brassinosteroids (BR)-regulated plant growth and drought responses		T. atroviride IMI206040Arabidopsis Col-0Down after T. atroviride treatment,
at 24–48 h		[73]
T. harzianum CECT2413 (T34)Arabidopsis Col-0Down after T. harzianum treatment in the first 24 h of interaction[40]
WRKY55Positive regulator of reactive oxygen species (ROS) production and
SA-dependent defence responses		T. atroviride P1Tomato San Marzano nanoUp after T. atroviride treatment
at late stages of defence		[80] 2
WRKY60Negative regulator of SA-dependent defence responses, positive regulator of JA- dependent defence responses to biotic stress and ABA-dependent defence response to abiotic stressT. atroviride IMI206040Arabidopsis Col-0Down after T. atroviride treatment
at 24 h, and up at 144 h		[73]
WRKY70Positive regulator of SA-dependent defence responses and negative
regulator of JA-inducible genes,
acting as a node of convergence for defence signals. Activation and maintenance of the priming memory		T. atroviride IMI206040Arabidopsis Col-0Down after T. atroviride treatment
at 24 and 48 h, and up at 144 h		[73]
WRKY78Positive regulator of plant
size and development		T. harzianum M10Tomato
Micro-Tom		Down after T. harzianum + R. solani
application at late stages		[78] 2
MYB51Positive regulator of indole
glucosinolate biosynthesis and
shikimate pathway in response to
biotic and abiotic stress		T. asperelloides T203Arabidopsis Col-0Up in control and salt-stressed plants after T. asperelloides treatment
at 9, 24, and 48 h		[72] 2
T. asperellum IsmT5Arabidopsis Col-0Up after exposure to
T. asperellum volatiles		[81]
T. harzianum T78Arabidopsis Col-0Up after T. atroviride treatment in only
4 h and down over time		[53]
MYB68Positive regulator of root
development and hardening, and defence responses to abiotic stresses		T. atroviride P1Tomato San
Marzano nano		Up after T. atroviride treatment at late stages of being challenged with aphids[80] 2
MYB72Positive regulator of
JA/ET-dependent defence responses and callose accumulation		T. asperellum T34Arabidopsis Col-0Up after T. asperellum treatment[70]
T. asperelloides T203Arabidopsis Col-0Up after T. asperelloides treatment
at 24 h		[72] 2
MYB77Positive regulator of lateral root
development and
auxin-dependent responses.
Activation and maintenance of the priming memory		T. asperelloides T203Arabidopsis Col-0Up after T. asperelloides treatment
at 9, 24, and 48 h		[72] 2
MYC2Regulatory hub within the JA
signalling pathway to balance the plant’s growth and defence responses. Negative regulator of MYB51 action. Positive regulator of lateral root growth, ROS, and ABA-dependent responses. Activation and maintenance of the priming memory		T. parareesei
IMI113135 (T6),
T. asperellum IMI296237 (T25),
T. harzianum CECT2413 (T34)		Tomato MarmandeDown after Trichoderma spp. +
Pseudomonas syringae
DC3000 application		[47]
T. atroviride
IMI352941 (T11)		Tomato MarmandeDown in the offspring of plants primed with T. atroviride and T. atroviride +
nematode application 		[74]
1 Generic Gene Ontology (GO) biological process for the homologous TF annotated at the Arabidopsis Information Resource (TAIR) database (https://www.arabidopsis.org/index.jsp); 2 These research studies are based on high-throughput data analysis and describe additional TFs to those presented in this table.
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Morán-Diez, M.E.; Martínez de Alba, Á.E.; Rubio, M.B.; Hermosa, R.; Monte, E. Trichoderma and the Plant Heritable Priming Responses. J. Fungi 2021, 7, 318. https://doi.org/10.3390/jof7040318

AMA Style

Morán-Diez ME, Martínez de Alba ÁE, Rubio MB, Hermosa R, Monte E. Trichoderma and the Plant Heritable Priming Responses. Journal of Fungi. 2021; 7(4):318. https://doi.org/10.3390/jof7040318

Chicago/Turabian Style

Morán-Diez, María E., Ángel Emilio Martínez de Alba, M. Belén Rubio, Rosa Hermosa, and Enrique Monte. 2021. "Trichoderma and the Plant Heritable Priming Responses" Journal of Fungi 7, no. 4: 318. https://doi.org/10.3390/jof7040318

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