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Review

Engineering Multigenerational Host-Modulated Microbiota against Soilborne Pathogens in Response to Global Climate Change

by
Paola Durán
1,2,*,
Gonzalo Tortella
3,
Michael J. Sadowsky
4,
Sharon Viscardi
5,
Patricio Javier Barra
1,2 and
Maria de la Luz Mora
1
1
Scientific and Technological Bioresource Nucleus, Universidad de La Frontera, Temuco 4811230, Chile
2
Biocontrol Research Laboratory, Universidad de La Frontera, Temuco 4811230, Chile
3
Centro de Excelencia en Investigación Biotecnológica Aplicada al Medio Ambiente (CIBAMA-BIOREN), Facultad de Ingeniería y Ciencias, Universidad de La Frontera, Temuco 4811230, Chile
4
BioTechnology Institute, University of Minnesota, Minneapolis, MN 55108, USA
5
Núcleo de Investigación en Producción Alimentaria, Facultad de Recursos Naturales, Universidad Católica de Temuco, P.O. Box 15-D, Temuco 4813302, Chile
*
Author to whom correspondence should be addressed.
Biology 2021, 10(9), 865; https://doi.org/10.3390/biology10090865
Submission received: 23 July 2021 / Revised: 26 August 2021 / Accepted: 27 August 2021 / Published: 3 September 2021
(This article belongs to the Special Issue Diversity of Soil Fungal Communities)
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Abstract

:

Simple Summary

In order to face the challenges posed by climate change, scientific research should be directed towards global needs while also keeping into account the need for increased plant productivity. In this sense, our scientific group from the Biocontrol Research Laboratory BIOREN (Temuco, Chile) and our collaborators, have been studying the enormous potential to enhance productivity by using suppressive soils. In this review, we highlight soil-suppressive microbiota as a natural source of biocontrol agents and we propose a strategy to create microbial assemblages, where the plant selects its own inoculants (when plants “cry for help”). This approach is based on the selection of specific taxa during the transition from a conducive to a suppressive soil. We hope that this strategy leads to generation of personalized bioinoculants to counteract the effects of climate change and increase agricultural sustainability.

Abstract

Crop migration caused by climatic events has favored the emergence of new soilborne diseases, resulting in the colonization of new niches (emerging infectious diseases, EIDs). Soilborne pathogens are extremely persistent in the environment. This is in large part due to their ability to reside in the soil for a long time, even without a host plant, using survival several strategies. In this regard, disease-suppressive soils, characterized by a low disease incidence due to the presence of antagonist microorganisms, can be an excellent opportunity for the study mechanisms of soil-induced immunity, which can be applied in the development of a new generation of bioinoculants. Therefore, here we review the main effects of climate change on crops and pathogens, as well as the potential use of soil-suppressive microbiota as a natural source of biocontrol agents. Based on results of previous studies, we also propose a strategy for the optimization of microbiota assemblages, selected using a host-mediated approach. This process involves an increase in and prevalence of specific taxa during the transition from a conducive to a suppressive soil. This strategy could be used as a model to engineer microbiota assemblages for pathogen suppression, as well as for the reduction of abiotic stresses created due to global climate change.

1. Introduction

Due to global climate change, extreme weather events are becoming more frequent, resulting in increased alterations in rainfall events and changes to temperature patterns. Therefore, one main concern of modern agriculture is how plants can tolerate biotic and abiotic stresses without an effect on crop yield, and or reduction of world food security [1]. According to FAO, food security is achieved through four components: availability, access, use, and stability. In this regard, food availability and stability from crops could be at risk due to changes imparted by global climate change. A particular problem in crops is host–pathogen interactions, which influences susceptibility to disease, as well as addressing the distribution of hosts and modifying trade patterns. Moreover, the virulence of pathogens can increase, as well as their geographical expansion, leading to emerging infectious diseases (EIDs) [2]. Most EIDs are caused by pathogens that have increased in incidence, geographical distribution, and/or host range, changed their mode of pathogenesis, or recently evolved, recently discovered, or newly recognized [3,4]. For example, in the case of soilborne pathogens, major disease incidence are expected to cause higher vulnerability of crops due to decreasing resistance to pathogen attacks and migration toward previously uncolonized niches or regions [4,5,6]. An example of EIDs includes Enterobacter cloacae, which, although a human pathogen, has been reported to affect plants such as Allium cepa, Morus sp., Hylocereus spp. and Macadamia integrifolia, among others [7,8,9,10]. Xylella fastidiosa is a plant pathogen that commonly affects grapes (Vitis vinifera), but has also been found to attack mulberry leaf [11]. An increased understanding of EIDs is important due to difficulties in predicting, detecting, and diagnosing soilborne pathogens, many of which can survive for many years in the absence of host plants by forming resistant structures such as microsclerotia, sclerotia, chlamydospores, or oospores.
With respect to control, soilborne pathogens have usually been treated using broad-spectrum fungicides and/or fumigants such as methyl bromide, chloropicrin, and metam sodium, among others. However, these have gradually been prohibited because of their negative impacts on human health and the environment [12]. For example, Rivera-Becerril and colleagues evaluated the effects of a pesticide mixture composed of fenhexamid, folpel, and deltamethrin on arbuscular mycorrhizal fungi (AMF) in a vineyard and arable soils, and reported that pesticide application caused a high alteration in the composition of AMF [13]. Usually, chemical control is ineffective because it fails to diffuse efficiently downward into the roots where early protection is essential [14]. Cultural methods such as crop rotation are also applied to reduce disease incidence [15]; however, although effective in disease suppression, crop rotation has the disadvantage that it decreases the opportunity to use plants from similar taxonomic families. For example, Gaeumannomyces graminis (Ggt) is a fungus causing take-all disease in cereals, mainly in wheat (Triticum aestivum), whose spread is usually prevented by crop rotation. However, this strategy limits the use of susceptible plants belonging to the same family, such as rye (Secale cereale L.) or triticale (×Triticosecale, hybrid of wheat and rye). This enhances the probability that take-all disease incidence will increase in key foods, such as cereals, in the coming years, thereby affecting food security [16].
Despite the importance of crop rotation for the control of soilborne pathogens, several reports have shown that the continuous monoculture of a crop can induce specific soil suppressiveness, offering a unique niche harboring specialized microbial communities that can help to suppress disease [17,18,19,20]. In monocultures of soybean, an increased abundance of nematode-trapping fungi and nematode endoparasites has been observed in the rhizosphere and root endosphere of soybean plants, favoring the control of nematode Heterodera glycines [20]. In this sense, our group identified six suppressive soils against take-all disease managed by wheat monoculture for more than 10 years [17]. This suppression, also called “specific suppression”, is limited to a particular pathogen and is mediated by one or a few specific microorganisms. Moreover, it is potentially transferable to conducive or non-suppressive soil [14,15,17].
Specific antagonists can occur anywhere. However, they seem to be most dominant in the soil rhizosphere and influenced by the host plant root (known as the root-associated microbiome or rhizobiome), which is not entirely congruent with the concept of pathogen suppression [21]. In this regard, we have not found any significant differences in pathogen DNA concentration between suppressive and conducive soils, but we did demonstrate that suppressive soils have low disease incidence even though the pathogen is present at comparable densities [22]. Similarly, others have reported that higher concentrations of Ggt DNA in roots do not translate into higher disease incidence in plants [23]. In contrast, “general suppression” is based on a general antagonistic effect exerted by the total soil microbial community (biomass) and preexisting soil characteristics against a broad spectrum of soilborne pathogens [18,24]. In general suppression, antagonistic effects occur mainly in the bulk soil, being especially effective against pathogens with a saprotrophic phase (i.e., fungistasis) or influenced by bulk soil chemistry [18]. For example, the important role that soil bacterial populations play on disease suppression, arising from different strategies in organic field management, was revealed via multiple statistical approaches [25]. Therefore, and as illustrated in Figure 1, general suppression is nontransferable between soils, and this is the main characteristic that differentiates it from specific suppression [15,26]. Although it is widely accepted that suppressive functions are in a continuum of responses from general to specific, the former underlies and potentially gives rise to the latter over time, which is conditioned by cropping practices and soil amendments [18]. However, the specific microorganisms as well as their mechanism involved in both general and specific soilborne pathogens’ suppression have only recently been identified, and much remains to be understood.
To date, the human gut is the most studied and characterized microbiome, where microorganisms forming a symbiotic relation are the result of processes of selection and evolution [27]. Considering the importance of gut microorganisms, current scientific efforts are focusing on the manipulation of gut microbiota (engineering microbiome) to enhance human fitness. In fact, microbiota transplantation between humans has gained popularity as a promising therapeutic option for some pathologies [28]. In this context, several authors have considered the root system to be analogous to the human gut, which also has the ability to recruit and select microorganisms [29]. However, unlike soil microbiota, the gut microbiota has a more limited number of genera which can survive the acidic or anoxic conditions prevailing in the gastrointestinal tract. In this sense, the plant-associated microbiota is less known, and it is widely variable depending on the crop, as well as the type of soil and location. Despite the gaps in the knowledge regarding the role that the plant-associated microbiota play, their participation in the growth, root architecture, time of flowering, drought resilience, nutrient uptake, and disease suppression is known [30,31]. Moreover, the root microbiota are not static and can change in a diurnal manner [32]. The microbiota, is defined as the total complex of plant-associated microorganisms, their corresponding interactions, and their genomic machinery [33]. Plants play an active role in recruiting specific microorganisms from bulk soil and therefore modeling their rhizobiome. In fact, different plant species or their genotypes, host-specific associated microbiomes, even grow in the same soil. In addition, from a large portion of microorganisms found in the bulk soil, only a low amount is associated with the plant rhizosphere [33,34,35,36,37,38,39]. These selected microbiota would have an advantage over external microbiota [40], being a “subset” of the plant microbiosphere and acting as reservoir of microorganisms [41,42,43].
In recent years, several fascinating mechanisms involved in specific suppression have attracted scientific interest, specifically with regard to understanding the dynamics in the establishment of particular microbiota in their niche in order to decrease the incidence of a specific soilborne pathogen. Thus, the microbial transition from conducive to specific soil suppression can be understood as natural host-mediated microbiota engineering (HMME), whereby the host indirectly selects microbial communities and triggers host traits that evolve to influence the whole microbiome [44]. This new plant microbiota-manipulating strategy has recently emerged in order to improve positive interactions with plants [40,45], where specific strains consistently associated with a particular host can be used to optimize microbial functions at the individual plant and ecosystem levels [44].
In this review, we discuss the effect of global climate change on emerging infectious diseases (EIDs), the ecological roles played by microorganisms in suppressive soils for infectious diseases, the root-associated microbiome and its role in plant health, and existing methods for natural microbiota engineering, using host-mediated microbiota selection. Moreover, we discuss the use of an interdisciplinary strategy to optimize microbiota assemblages by inducing specific suppression from conducive soil. This model is based on reported antecedents and could be exploited to develop biotechnological strategies based on the use of natural microbiota to fight soilborne pathogens under the imminent climate change scenario.

2. Climate Change Effects on Plant Pathogens and Diseases

It is well known that global atmospheric CO2 concentration is increasing resulting in climate change. This has brought a series of consequences, such as deep changes in temperature and precipitation patterns [46]. As a consequence of this, the incidence and distribution of plant pathogens is being significantly altered, causing economic losses and crop damages worldwide. Moreover, weather and climate variability can directly influence plant development that lead to higher risk of plant pathogen infection [47]. Regarding airborne pathogens, several efforts have been undertaken in order to elucidate the effect of elevated CO2 concentration on plant disease. Interestingly, both beneficial and detrimental effects have been noted, which may be attributed to alterations in stoma structure, stomal conductance, and density under variations induced by climate change, landscape, and plant species [48,49]. This is largely due to the fact that stomata are the entry point for most foliar pathogens. For example, Eastburn and colleagues assessed the influence of elevated CO2 concentration (550 ppm) on the ability of three different pathogens (Septoria glycines, Peronospora manshurica and F. virguliforme) to infect soybean [49]. This study showed that disease incidence was decreased in P. manshurica and remained without significant variations in F. virguliforme. However, when these results were compared to those under a drought period, disease incidence was higher in all cases.
Regarding beneficial effects, the key role of high CO2 (1000 and 3000 ppm) in plant defense priming through processes that are linked to redox signaling and metabolism was highlighted, for example, by producing salicylic acid, SA [50]. This was shown to decrease sensitivity to infection against Botrytis cinerea and Pseudomonas syringae in Arabidopsis thaliana and Phaseolus vulgaris plants. Similar results were reported where elevated CO2 concentration (800 ppm) generally favored SA biosynthesis and signaling, but repressed the jasmonic acid (JA) pathway, which resulted in lower incidence and severity of tobacco mosaic virus (TMV) and Pseudomonas syringae in tomato plants [51]. In contrast, the severity of brown spots caused by the fungus Septoria glycines increased under elevated CO2 (550 ppm) in soybean [49]. Other reports have shown the evolution or appearance of new EIDs to exemplify detrimental effects. For example, Puccinia graminis or rust (biotrophic fungi parasitizing cereals) is a significant concern due to the evolution of new virulent races, which can result in ~100% yield loss on wheat under climate change scenarios (warmer climate with lower relative humidity) [52]. A similar tendency was reported for Puccinia striformis (yellow rust fungus), where rust fungi increased their virulence and dispersion because of wind. In fact, a foreign incursion of yellow rust fungus in North America, Australia, and Europe has been reported, and this occurred in less than three years [53,54], as seen in Table 1.
In the case of soilborne pathogens, Chitarra et al. [60] showed that elevated CO2 increased the incidence of Fusarium oxysporum. Similarly, the authors suggested that a greater frequency of extreme events could be particularly beneficial for Phytophthora cinnamomi infections, boosting their density beyond any possible response capacity of susceptible hosts [72]. In contrast, other authors found no significant effects of high CO2 (800 ppm) on disease incidence caused by the soilborne pathogens Rhizoctonia solani and Fusarium oxysporum, compared with ambient CO2 conditions (450 ppm, [73]). However, in most studies that evaluated the combined effects of multiple climate change factors on different pathogens, the effects were detrimental. For example, using data from a global field survey and a nine-year field experiment, the importance of soils derived from natural ecosystems as reservoirs for potential fungal plant pathogens was highlighted, denoting temperature as a major environmental factor involved in the global distribution of fungi [74]. Moreover, the authors noted that the proportion of potential plant pathogens will increase in most regions worldwide. Therefore, studies linking disease dynamics under different environmental factors are fundamental to predict the consequences of climate change on plant disease incidence [75]. This is especially important for key crops needed for food security (rice, potatoes, maize, cereal, and soybean). In Figure 2, we summarize the main effects of climate change (increase in CO2, temperature, and precipitation) on plant disease affecting key crops.
The impact of climate change on increases in plant pests is also of global concern because a lot of resources are required to control this problem. Zayan [76] indicated that in the US alone, farmers spent more than USD 11 billion for pest control. Additionally, they reported that global climate change could cause some plant pests to undergo from one to five additional lifecycles per season, increasing their ability to overcome plant pest resistance. In the same way, by 2050, the international trade of crops is expected to be seriously affected due to new EIDs which will appear more frequently, as reported by FAO, requiring USD 7 billion per year at that point to deal with this issue. Since the increase in the use of chemical pesticides in crops is unsustainable, it is necessary to use an ecosystem approach involving practices that can guarantee minimal pesticide usage. In this sense, chemical, biological, cultural, and physical methods must be applied together, but in a rational way. Therefore, a new green revolution is required to achieve future food security, where new concepts and approaches are needed to achieve a more sustainable development of agriculture.

3. Ecological Roles of Microorganisms from Specific Disease-Suppressive Soils

Soil disease suppression has been described for several soilborne plant pathogens, including bacteria, nematodes, and fungi (Table 2). However, general as well as specific suppression mechanisms have not been fully defined for most suppressive soils. Currently, the development of omics-based approaches has allowed us to understand that specific suppressiveness is caused by specific microorganisms that inhibit the pathogenicity of a specific soilborne pathogen. These microorganisms were recently defined as a key species or core microbiome, in turn driving the microbiome composition and its consequent functionality [77].
Specific suppression could be induced by monoculture practices through the growth of susceptible crops (host) in coexistence with infective pathogens. For example, Ggt-suppressive soil occurrence was examined in 16 locations managed by Indigenous “Mapuche” communities, using monoculture for more than 10 years [17]. Six of these soils were confirmed to be suppressive since they reduced take-all disease in wheat plants. Suppressiveness was lost upon soil sterilization and recovered by adding 1% of natural soil, hence confirming the fact that suppressiveness was closely associated with the soil microbiome community composition. An early study showed that three years of successive wheat cropping could be sufficient for the induction of specific suppression against take-all disease [96]. Later, this was confirmed where it was shown that soils with 3–4 years of wheat monoculture under relatively high pathogen inoculum concentrations were suppressive against take-all disease [23]. In this context, suppressive soils can only occur when three factors occur simultaneously: (i) a monoculture of a susceptible host, (ii) the presence of a pathogen, and (iii) an outbreak of disease [97]. Early reports showed the importance of Pseudomonas fluorescens for biological control of take-all disease [98,99]. In this sense, several antagonistic molecules produced by P. fluorescens, such as pyolotuerin, phenazine, HCN, pyrrolnitrin, and 2,4-diacetylphloroglucinol, have been reported [100,101]. However, the early interest in P. fluorescens as a tool for the biological control of plant pathogens focused on examining it as a single strain, rather than using a set of microorganisms associated with the rhizosphere of plants [101]. This biocontrol ability was attributed to the production of the antibiotic 2,4-diacetylphloroglicinol (2,4-DAPG) [102,103,104]. Other authors showed that specific members of Actinobacteria from a soil suppressive of the fungal root pathogen R. solani are able to inhibit fungal growth [105]. Additionally, it has been reported that specific members of the Burkholderiaceae family are involved in soil suppressiveness via the production of volatile sulfurous compounds [106]. Additionally, Streptomyces griseus was shown to play a fundamental role in the suppressiveness of Fusarium wilt of strawberry, caused by F. oxysporum f. sp. fragariae, via the secretion of lantipeptides which exhibit antibiotic activity [107]. These studies revealed that the rhizobiome provides a first line of defense against the development of soilborne pathogens in periods of monoculture, and in response to high disease incidence or an “outbreak”, such as induced specific suppression [19,108].

4. Rhizobiome to the Service of Plant Health, When Plants “Cry for Help”

The rhizobiome or rhizosphere microbiome comprises all microorganisms associated with plant roots [109]. Many interactions in the plant–soil–microorganisms complex occur at the rhizobiome level. Indeed, plants can repel or attract (recruit) microbes by using exudates, exerting a significant effect on the general health, or by managing agronomic practices [22,110]. An elegant study showed that Bacillus cereus (bacteria implicated in the biocontrol of a wide range of plant pathogens) is able to induce specific components in plant root exudates, which are likely involved in biocontrol processes [110]. For a specific suppression, the “cry for help” concept was suggested, where, at the stage of an outbreak, plants recruit protective microbiota mainly through the exudation of photo-synthetically fixed carbon into the rhizobiome, and favoring endosphere colonization [111,112,113]. The concept of crying for help has been linked to strigolactone (signaling hormones) production, which is involved in the promotion of arbuscular mycorrhizal fungus development and symbiosis establishment under deficient nutrient conditions [114]. Strigolactones have also been observed as a consequence of a herbivore attack, which induced plant volatiles (HIPVs) that contain crucial information for carnivorous insects’ decisions [115]. Recently, four different stages involved in “cry for help” events were proposed and included (Figure 3): (i) root immune responses to belowground and aboveground attackers; (ii) stress-induced changes in root exudation of antimicrobials and semiochemicals (signal molecules); (iii) impacts of root exudates on root-associated and soil-associated microbiota, and (iv) mechanisms by which the root-associated and soil-associated microbiomes suppress pests and diseases [112]. In relation to the first point, several studies have reported that plant roots can generate pattern-triggered immunity (PTI), which contribute to host defense against plant pathogens [116]. Plants have the capacity to recognize potential pathogens via pattern recognition receptors on the cell surface that have the capacity to detect pathogen-associated molecular patterns (PAMPs), such as flagella and lipopolysaccharides, among others, which represent the first-line defense. In this regard, it was reported that typical defense-related genes such as PR-1 and PR-10 are quickly transcribed during the early stages of root infection [117]. The second point is related to second-line defense, which includes the secretion of several molecules that can act as signals for the recruitment of beneficial microorganisms, or that can act directly as antimicrobial compounds [112]. A clear example of this was reported in 2008 [118], where the infection of Arabidopsis plants with the pathogen Pseudomonas syringae triggered the recruitment of Bacillus subtilis to the roots, which act as biocontrol against P. syringae. Moreover, the authors reported that the induction of B. subtilis by the roots was due to the secretion of malic acid, which is a chemoattractant for this strain. This last point is closely related to the third and fourth stages, since roots have the capacity to affect microbial populations in the rhizosphere either through the recruitment of beneficial bacteria or by actively repressing pathogen proliferation [119]. A good example is the pathogenic fungus Ggt, which can be suppressed in wheat crops via the production of the antibiotic 2,4-diacetylphloroglucinol by fluorescent Pseudomonas spp. in the rhizosphere [104].
Currently, specific disease suppressiveness is attributed to the role of functional core microbiota. The core microbiota concept has been defined as the “microbial community that is systematically associated with a specific host plant, where its functions as microbial genes, is essential for the entire holobiont fitness” [120]. In this regard, Trivedi and coworkers tested the potential role of core microbiota, physicochemical properties, and edaphic factors on soil suppression against F. oxysporum [121]. The authors identified bacteria belonging to the phyla Actinobacteria, Firmicutes, and Acidobacteria as the major microbial predictors for soil suppressiveness. Similarly, rRNA-based analyses showed that Oxalobacteraceae, Burkholderiaceae, Sphingobacteriaceae, and Sphingomonadaceae were significantly more abundant in the rhizosphere upon Rhizoctonia solani invasion, while stress-related bacterial genes representing antifungal activities were specifically upregulated, restricting Rhizoctonia solani growth [122]. As discussed above, plants grown in suppressive soils are able to recruit beneficial microorganisms from the bulk soil, and although the entire process of microbial recruitment is not fully elucidated, it is well known that root exudates have a primary role [17,22,84,123,124]. This is possible due to the fact that plants are surrounded by a great diversity and number of microorganisms which can provide several beneficial functions for their plant host [125]. It is thought that the plant rhizosphere contains 10 to 100 times more microbiota than bulk soil, depending on the plant species. This is typically referred to as the rhizosphere effect. Host–microbiome interactions are crucial for plant development. There is ample evidence supporting the fact that rhizosphere microorganisms have a critical role in health, nutrition, productivity, and the overall condition of the plant [22,39,126,127,128,129,130,131,132,133]. The role played by plant growth-promoting (PGP) microorganisms (PGPM) on promoting plant protection has been demonstrated via inoculation with both an individual microorganism and a synthetic mixture of microbiomes [29,79,91,113,128,129,134,135,136]. However, a fundamental challenge for the use of strategies based on microbial inoculation is that synthetic communities often do not persist in soil, and their densities decline rapidly as a result of their competition with indigenous microbiota and adaptation to new environmental conditions [137,138]. Therefore, microbial selection should consider the origin of the microorganisms, their functionality, and their preponderance within the complex microbial community, with core microorganisms being the main targets of search, isolation, and use [139] (Figure 3).

5. Core Microbiome—“Few but Good”

Plant microbiota are highly diverse, and these microorganisms are strongly connected with plants, forming complex interactions promoting the productivity and health of the plant in natural environments of the holobiont [140]. However, not all microorganisms play functionally important roles in the host’s biology [141,142]. For example, several studies have reported the presence of a “core microbiota”, a subset of microbial taxa that are consistently associated with a host taxon in a wide range of environments [44,47,123,143]. In fact, many taxa belonging to the core microbiome are likely heritable to subsequent generations and/or fruit postharvest [140,143].
The plant core microbiome is composed of key microbial taxa defined as keystone or microbial hubs, which are critical for plant health based on evolutionary processes that resulted in the selection and enrichment of microbiota carrying genes with essential functions for holobiont fitness [120,144]. Agler [145] defined the term keystone or microbial hubs as specific microorganisms strongly interconnected in the microbial network of plants. However, keystone is differentiated from hub species since the first would be a critical determinant of colonization of widely occurring microbial taxa, and the second would apply to only some specific taxa, not overall [145,146]. A complete summary of keystone taxa in different ecosystems such as grasslands, forests, agricultural lands, Arctic and Antarctic ecosystems, plant-associated microbiome, or phyllosphere, among others, was reported by Banerjee et al. [147]. In this sense, Actinobacteria phylum showed high versatility since that was reported as a keystone taxa in grassland, forest, Antarctic and Artic ecosystems, contaminated soils, aquatic environments, and human gut. For example, the phyla Actinobacteria and Proteobacteria increased positive interactions and strengthened the adaptability of microbiome to grassland degradation [148]. Coincidently, members of phyla Proteobacteria, Actinobacteria, and Bacteroidetes were dominant in both Antarctic vascular plants (Deschampsia antarctica and Colobanthus quitensis). However, co-occurrence network analyses identified 5 (Microbacteriaceae, Pseudomonaceae, Lactobacillaceae, and Corynebacteriaceae), 23 (Chitinophagaceae and Sphingomonadaceae) and 7 (Rhodospirillaceae) putative keystone taxa present in endosphere, phyllosphere, and rhizosphere, respectively. Thus, niche differentiation in Antarctic vascular plants was evidenced [149]. Another study evaluated the role of a nitrogen-fixing early-colonizer, Alnus nepalensis, evidencing that keystone taxa were different at different stages of alder growth [150]. Currently, it is well known that keystone differ to dominant species due to the fact that it might exert their influence on microbiome functioning irrespective of abundance [147], and may be attributable to specific functions such as in the case of plant residue decomposition [151], rhizo deposit stabilization in soil [150], and composted tannery sludge-treated soil [152].
With respect to suppressive soils, a total of 9 and 13 bacterial keystone taxa were identified from suppressive soils against Ralstonia solanacearum, and three species belonging to culturable strains of Pseudomonas showed high 16S rRNA gene similarity (98.4–100%) with keystone taxa [153]. However, another study showed that the keystone microbiome against Ralstonia solanacearum were comprised of the phyla Actinobacteria and Firmicutes and that these microbiota likely plan an important role in diminishing disease incidence [154]. Thus, keystone taxa are highly connected taxa that may exhibit unique and critical roles in organizing the structure of the total microbiome [152].
Microbial hubs are frequently highly connected to other microorganisms inside the network and exert a strong influence on the structure of microbial communities [155]. Thus, hub microbiomes contain more specific microorganisms designed only based on their positions inside a network topology with a specific function, whereas core microorganisms are those with high potential to organize microbiomes in ways that benefit host plants [138].
Microbial hubs and keystones are strongly affected by biotic and abiotic factors that influence the microbial community’s composition [156], and it has been reported that high levels of disturbance and dispersal can interrupt the stabilizing effects of keystone microbial taxa [146]. Therefore, host plants transmit information to the broader microbial network and likely vice versa, and microbial hubs could recruit beneficial organisms or prevent the invasion of pathogens, benefitting the whole system [118,157]. Thus, understanding the plant microbiome’s core functions and the use of synthetic communities as biological control systems provides an opportunity to build a sustainable next-generation agriculture [158]. Finally, microbiome engineering and the identification of specific microorganisms involved in pathogen suppression, such as the core microbiome or microbial hubs, could present a feasible and suitable strategy to solve multiple current agriculture-associated problems in an ecofriendly way, impacting agricultural production, and could serve as a basis for other soilborne pathogens.

6. Exploiting Host-Mediated Microbiota Engineering for Protection of Plants against Diseases

Host-mediated microbiota engineering (HMME) is a biological strategy that uses the host phenotype to indirectly select microbiota though cyclic differentiation and propagation [159,160]. HMME is a promising approach to improve host performance by engineering microbial communities for beneficial effects on plant growth and health [44,161]. This strategy enables the selection of a particular microbiome by visualizing phenotypic changes in host plants after several generations of growing in the same place [132]. Thus, modifications in host phenotypes are used to manipulate and select those microbiome functions that impact host fitness [44,162]. While HMME is a novel strategy, it has already been successfully applied to counteract the effect of abiotic stress, such as drought stress [160]. This denotes the great potential of the host as a selective marker to engineer microbiomes that mediate changes in the rhizobiome, improving plant adaptation [160,163]. In the case of biotic stress, specific disease suppression is best exemplified by naturally induced HMME, where plants recruit specific microorganisms from the rhizobiome that can provide plant disease protection [17,19]. The study of [164] assessed distinctive microbiota assembled by maize roots, through host-mediated selection, and studied the role of a simplified synthetic bacterial community composed of even strains from the most dominant phyla: Enterobacter cloacae, Stenotrophomonas maltophilia, Ochrobactrum pituitosum, Herbaspirillum frisingense, P. putida, Curtobacterium pusillum, and Chryseobacterium indologenes. These authors found that removing E. cloacae led to a complete loss of the community structure, suggesting an important role of keystone taxa in the inhibition of Fusarium verticillioides. Later, it was demonstrated in Arabidopsis thaliana that, after a disease outbreak caused by Hyaloperonospora arabidopsidis, plants were able to assemble protective microbiota in the rhizobiome, inducing systemic resistance [114]. Interestingly, the increased abundance of recruited microorganisms provided protection to the next population of plants growing in the same soil.
Collectively, these studies highlight the ability of plants to recruit specific microbiota from the rhizobiome with beneficial effects on plant growth and health. Therefore, it is evident that HMME offers a promising novel approach to attain desired host traits. While promising, this approach has only been attempted a few times; nevertheless, it is an extremely powerful technique. In this strategy, microorganisms are forced to co-evolve together with the host plant through successive generations in order to promote a desirable host trait in a manner akin to the natural engineering of plant microbiota. Moreover, the HMME approach applied to both conducive and suppressive states will be very useful to better understand the interactions between plants, microbes, and soils, as well as for the selection of microorganisms directly involved in pathogen suppression.

7. The New Generation of Personalized Bioinoculants by Inducing the Host-Mediated Microbiota Engineering—Perspectives and Future Remarks

An increase in the incidence of plant diseases in agriculture due to climate change effects is imminent. Therefore, novel strategies must be rapidly implemented to ensure food security during times of variable climates. One approach to achieve the goal of plant protection is using HMME taking into account the co-evolutive model of the transition from conducive to suppressive soil. The natural “choice” of “suitable microbiota” by the plant would ensure its success in the face of the imminent changing conditions that are predicted. Moreover, this approach is likely to have much more success than using randomly combined microbiota pools obtained from the rhizosphere of many plant species. The very large number of microorganisms in the rhizosphere coupled with the wide variation in diversity make the construction of microbial pools a daunting task with a low probability of success.
The natural selection of microbiota over multiple generations can be managed indirectly (induced) through the existence of three factors: (1) plant model used, (2) abiotic/biotic stressor or inducers, and (3) the desired microbiome. Thus, in the case of soilborne pathogen, this involves continual sowing of plant genotypes (factor 1) against an infective soilborne pathogen (factor 2) in conducive soil (factor 3) until a soil suppressive is obtained (horizontal transmission). In this manner, key specialized functional microbiota (composed of a functional core microbiome and/or microbial hubs) can be identified, and stable synthetic communities can be assembled in order to mediate plant health. Using this approach, host plants can be used to recruit and self-identify desirable microorganisms that could later be used as inoculants to transfer functional core microbiota, or whole microbiota, in order to obtain healthy plants for subsequent generations (vertical transmission [165], Figure 4). For example, Cooper et al. (2021) recently showed that HMME strategy can be used to improve wheat plant growth under drought stress [165]. A further study induced earlier or later flowering times in Arabidopsis thaliana plants using HMME selection [159].
Overall, this strategy for microbiota manipulation, which takes advantage of specialized niches (microbial hubs, keystone, and/or core microbiome) offered by disease-suppressive soils, appears to be a promising approach to improve plant health and opens new research opportunities to optimize microbiota.
On the other hand, from a practical point of view, the identification of a stable microbial hub or microbial keystone taxa that can tolerate perturbations without affecting the microbial community’s composition and favoring plant health would be extremely useful to improve crop production capacity. Moreover, future studies of its implementation should integrate other environmentally friendly strategies for soilborne disease management, such as the use of crop rotation, soil solarization, and biofumigants, among others, widely reviewed by Panth et al. [166].
Finally, although the selection of “microbial hubs” or a “microbial keystone” through a natural selection of successive plant generations is a promising alternative, the application of advanced modeling techniques to detect key bacteria in humans, which are important for a particular trait such as disease resistance or disease detection, must be taken into consideration to be applied in the plant microbiome. In this sense, a mathematical model such as random forest classification (RFC) coupled with the local interpretable model–agnostic explanation (LIME) toolbox has been effectively applied to detect specific taxa from the intestinal and oral microbiome, which served as a predictor for human diseases [167]. In this same way, for more detailed information about mechanistic mathematical models of the gut microbiota, see the review of Bucci and Xavier [168].

8. Conclusions

The understanding of the plant microbiome and rhizobiome over the last decades has allowed for the development of integrated approaches to enhance plant fitness. In this article, we propose that engineering the plant microbiome by host-mediated selection can be used to enhance plant health, taking, as a model, the co-evolutive process that occurs in conducive to suppressive soils (multigenerational generation). Using this model, plants can select their own “personalized” microbiome to counteract the negative effects of a specific soilborne pathogen. The application of this natural technology that manages the plant microbiome to control host health will likely lead to the development of the next generation of bioinoculants.

Author Contributions

Writing—first draft preparation, P.D., G.T., S.V. and P.J.B.; writing—review and editing, M.d.l.L.M., M.J.S. and P.D. funding acquisition, P.D. and M.d.l.L.M.; Figures and Tables, P.D. All authors have read and agreed to the published version of the manuscript (P.D., G.T., M.J.S., S.V., P.J.B. and M.d.l.L.M.).

Funding

This research was funded by the ANID-FONDECYT (regular project number 1201196, 1181050; Initiation 11200377), INACH (number RT06-17).

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Garrett, K.A.; Nita, M.; De Wolf, E.D.; Esker, P.D.; Gomez-Montano, L.; Sparks, A.H. Plant Pathogens as Indicators of Climate Change, 2nd ed.; Elsevier B.V.: Amsterdam, The Netherlands, 2015; ISBN 9780444635242. [Google Scholar]
  2. Fones, H.N.; Gurr, S.J. NOX ious gases and the unpredictability of emerging plant pathogens under climate change. BMC Biol. 2017, 15, 36. [Google Scholar] [CrossRef] [Green Version]
  3. Daszak, P.; Cunningham, A.; Hyatt, A. Emerging Infectious Diseases of Wildlife- Threats to Biodiversity and Human Health. Science 2000, 287, 443–449. [Google Scholar] [CrossRef]
  4. Anderson, P.K.; Cunningham, A.A.; Patel, N.G.; Morales, F.J.; Epstein, P.R.; Daszak, P. Emerging infectious diseases of plants: Pathogen pollution, climate change and agrotechnology drivers. Trends Ecol. Evol. 2004, 19, 535–544. [Google Scholar] [CrossRef]
  5. French, S.; Levy-Booth, D.; Samarajeewa, A.; Shannon, K.E.; Smith, J.; Trevors, J.T. Elevated temperatures and carbon dioxide concentrations: Effects on selected microbial activities in temperate agricultural soils. World J. Microbiol. Biotechnol. 2009, 25, 1887–1900. [Google Scholar] [CrossRef]
  6. Meisner, A.; De Boer, W. Strategies to maintain natural biocontrol of soil-borne crop diseases during severe drought and rainfall events. Front. Microbiol. 2018, 9, 2279. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  7. Bishop, A.L.; Davis, R. Internal decay of onions caused by Enterobacter cloacae. Plant Dis. 1990, 74, 692–694. [Google Scholar] [CrossRef]
  8. Wang, G.F.; Xie, G.L.; Zhu, B.; Huang, J.S.; Liu, B.; Kawicha, P.; Benyon, L.; Duan, Y.P. Identification and characterization of the Enterobacter complex causing mulberry (Morus alba) wilt disease in China. Eur. J. Plant Pathol. 2010, 126, 465–478. [Google Scholar] [CrossRef]
  9. Masyahit, M.; Sijam, K.; Awang, Y.; Satar, M.G.M. First report on bacterial soft rot disease on dragon fruit (Hylocereus spp.) caused by Enterobacter cloacae in Peninsular Malaysia. Int. J. Agric. Biol. 2009, 11, 659–666. [Google Scholar]
  10. Nishijima, K.A.; Wall, M.M.; Siderhurst, M.S. Demonstrating pathogenicity of Enterobacter cloacae on Macadamia and identifying associated volatiles of gray kernel of Macadamia in Hawaii. Plant Dis. 2007, 91, 1221–1228. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  11. Hernandez-Martinez, R.; de la Cerda, K.A.; Costa, H.S.; Cooksey, D.A.; Wong, F.P. Phylogenetic Relationships of Xylella fastidiosa Strains Isolated from Landscape Ornamentals in Southern California. Phytopathology 2007, 97, 857–864. [Google Scholar] [CrossRef] [Green Version]
  12. Weller, D.M. Take-All Decline and Beneficial Pseudomonads. In Principles of Plant-Microbe Interactions; Springer: Cham, Germany, 2015; pp. 363–370. [Google Scholar] [CrossRef]
  13. Rivera-Becerril, F.; van Tuinen, D.; Chatagnier, O.; Rouard, N.; Béguet, J.; Kuszala, C.; Soulas, G.; Gianinazzi-Pearson, V.; Martin-Laurent, F. Impact of a pesticide cocktail (fenhexamid, folpel, deltamethrin) on the abundance of Glomeromycota in two agricultural soils. Sci. Total Environ. 2017, 577, 84–93. [Google Scholar] [CrossRef]
  14. Cook, R.J. Take-all of wheat. Physiol. Mol. Plant Pathol. 2003, 62, 73–86. [Google Scholar] [CrossRef]
  15. Andrade, O.; Campillo, R.; Peyrelongue, A. Soils suppressive against Gaeumannomyces graminis var. tritici identified under wheat crop monoculture in southern Chile. Cienc. e Investig. Agrar. 2011, 38, 345–356. [Google Scholar] [CrossRef] [Green Version]
  16. Medina, A.; Akbar, A.; Baazeem, A.; Rodriguez, A.; Magan, N. Climate change, food security and mycotoxins: Do we know enough? Fungal Biol. Rev. 2017, 31, 143–154. [Google Scholar] [CrossRef] [Green Version]
  17. Durán, P.; Jorquera, M.; Viscardi, S.; Carrion, V.J. Screening and Characterization of Potentially Suppressive Soils against Gaeumannomyces graminis under Extensive Wheat Cropping by Chilean Indigenous Communities. Front. Microbiol. 2017, 8, 1552. [Google Scholar] [CrossRef] [PubMed]
  18. Schlatter, D.; Kinkel, L.; Thomashow, L.; Weller, D.; Paulitz, T. Disease Suppressive Soils: New Insights from the Soil Microbiome. Phytopathology 2017, 107, 1284–1297. [Google Scholar] [CrossRef] [Green Version]
  19. Mendes, L.W.; Raaijmakers, J.M.; De Hollander, M.; Mendes, R.; Tsai, S.M. Influence of resistance breeding in common bean on rhizosphere microbiome composition and function. ISME J. 2018, 12, 212–224. [Google Scholar] [CrossRef] [PubMed]
  20. Strom, N.; Hu, W.; Haarith, D.; Chen, S.; Bushley, K. Interactions between soil properties, fungal communities, the soybean cyst nematode, and crop yield under continuous corn and soybean monoculture. Appl. Soil Ecol. 2020, 147, 103388. [Google Scholar] [CrossRef]
  21. Termorshuizen, A.J.; Jeger, M.J. Strategies of soilborne plant pathogenic fungi in relation to disease suppression. Fungal Ecol. 2008, 1, 108–114. [Google Scholar] [CrossRef]
  22. Duran, P.; Tortella, G.; Viscardi, S.; Barra, P.J.; Carrion, V.J.; Mora, M.D.L.L.; Pozo, M.J. Microbial Community Composition in Take-All Suppressive Soils. Front. Microbiol. 2018, 9, 2198. [Google Scholar] [CrossRef]
  23. Chng, S.; Cromey, M.G.; Dodd, S.L.; Stewart, A.; Butler, R.C.; Jaspers, M.V. Take-all decline in New Zealand wheat soils and the microorganisms associated with the potential mechanisms of disease suppression. Plant Soil 2015, 397, 239–259. [Google Scholar] [CrossRef]
  24. Mazzola, M. Mechanisms of natural soil suppressiveness to soilborne diseases. Antonie Van Leeuwenhoek 2002, 81, 557–564. [Google Scholar] [CrossRef]
  25. Benítez, M.S.; Tustas, F.B.; Rotenberg, D.; Kleinhenz, M.D.; Cardina, J.; Stinner, D.; Miller, S.A.; McSpadden Gardener, B.B. Multiple statistical approaches of community fingerprint data reveal bacterial populations associated with general disease suppression arising from the application of different organic field management strategies. Soil Biol. Biochem. 2007, 39, 2289–2301. [Google Scholar] [CrossRef]
  26. Kwak, Y.S.; Weller, D.M. Take-all of wheat and natural disease suppression: A review. Plant Pathol. J. 2013, 29, 125–135. [Google Scholar] [CrossRef]
  27. Zhu, B.; Wang, X.; Li, L. Human gut microbiome: The second genome of human body. Protein Cell 2010, 1, 718–725. [Google Scholar] [CrossRef] [Green Version]
  28. Khoruts, A.; Sadowsky, M.J. Understanding the mechanisms of faecal microbiota transplantation. Nat. Rev. Gastroenterol. Hepatol. 2016, 13, 508–516. [Google Scholar] [CrossRef] [Green Version]
  29. Haney, C.H.; Samuel, B.S.; Bush, J.; Ausubel, F.M. Associations with rhizosphere bacteria can confer an adaptive advantage to plants. Nat. Plants 2015, 1, 15051. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  30. Zhao, Y.; Gao, Z.; Tian, B.; Bi, K.; Chen, T.; Liu, H.; Xie, J.; Cheng, J.; Fu, Y.; Jiang, D. Endosphere microbiome comparison between symptomatic and asymptomatic roots of Brassica napus infected with Plasmodiophora brassicae. PLoS ONE 2017, 12, e0185907. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  31. Kim, Y.; Bae, B. Optimization of Biological Phosphorus Removal from Contaminated Sediments with Phosphate-Solubilizing Microorganisms. J. Biosci. Bioeng. 2005, 99, 23–29. [Google Scholar] [CrossRef] [PubMed]
  32. Staley, C.; Ferrieri, A.P.; Tfaily, M.M.; Cui, Y.; Chu, R.K.; Wang, P.; Shaw, J.B.; Ansong, C.K.; Brewer, H.; Norbeck, A.D.; et al. Diurnal cycling of rhizosphere bacterial communities is associated with shifts in carbon metabolism. Microbiome 2017, 5, 65. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Berendsen, R.L.; Pieterse, C.M.J.; Bakker, P.A.H.M. The rhizosphere microbiome and plant health. Trends Plant Sci. 2012, 17, 478–486. [Google Scholar] [CrossRef] [PubMed]
  34. Bandyopadhyay, P.; Bhuyan, S.K.; Yadava, P.K.; Varma, A.; Tuteja, N. Emergence of plant and rhizospheric microbiota as stable interactomes. Protoplasma 2017, 254, 617–626. [Google Scholar] [CrossRef] [PubMed]
  35. Aleklett, K.; Leff, J.W.; Fierer, N.; Hart, M. Wild plant species growing closely connected in a subalpine meadow host distinct root-associated bacterial communities. PeerJ 2015, 2015, e804. [Google Scholar] [CrossRef] [Green Version]
  36. Samad, A.; Trognitz, F.; Compant, S.; Antonielli, L.; Sessitsch, A. Shared and host-specific microbiome diversity and functioning of grapevine and accompanying weed plants. Environ. Microbiol. 2017, 19, 1407–1424. [Google Scholar] [CrossRef] [PubMed]
  37. Compant, S.; Samad, A.; Faist, H.; Sessitsch, A. A review on the plant microbiome: Ecology, functions, and emerging trends in microbial application. J. Adv. Res. 2019, 19, 29–37. [Google Scholar] [CrossRef]
  38. Micallef, S.A.; Shiaris, M.P.; Colón-Carmona, A. Influence of Arabidopsis thaliana accessions on rhizobacterial communities and natural variation in root exudates. J. Exp. Bot. 2009, 60, 1729–1742. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  39. Quiza, L.; St-Arnaud, M.; Yergeau, E. Harnessing phytomicrobiome signaling for rhizosphere microbiome engineering. Front. Plant Sci. 2015, 6, 507. [Google Scholar] [CrossRef]
  40. Orozco-Mosqueda, M.D.C.; Rocha-Granados, M.D.C.; Glick, B.R.; Santoyo, G. Microbiome engineering to improve biocontrol and plant growth-promoting mechanisms. Microbiol. Res. 2018, 208, 25–31. [Google Scholar] [CrossRef] [PubMed]
  41. Germida, J.J.; Siciliano, S.D.; de Freitas, J.R.; Seib, A.M. Diversity of root-associated bacteria associated with held-grown canola (Brassica napus L.) and wheat (Triticum aestivum L.). Fems Microbiol. Ecol. 1998, 26, 43–50. [Google Scholar] [CrossRef]
  42. Marquez-Santacruz, H.A.; Hernandez-Leon, R.; Orozco-Mosqueda, M.C.; Velazquez-Sepulveda, I.; Santoyo, G. Diversity of bacterial endophytes in roots of Mexican husk tomato plants (Physalis ixocarpa) and their detection in the rhizosphere. Genet. Mol. Res. 2010, 9, 2372–2380. [Google Scholar] [CrossRef]
  43. Bai, Y.; Müller, D.B.; Srinivas, G.; Garrido-Oter, R.; Potthoff, E.; Rott, M.; Dombrowski, N.; Münch, P.C.; Spaepen, S.; Remus-Emsermann, M.; et al. Functional overlap of the Arabidopsis leaf and root microbiota. Nature 2015, 528, 364–369. [Google Scholar] [CrossRef]
  44. Mueller, U.G.; Sachs, J.L. Engineering Microbiomes to Improve Plant and Animal Health. Trends Microbiol. 2015, 23, 606–617. [Google Scholar] [CrossRef] [Green Version]
  45. Rillig, M.C.; Tsang, A.; Roy, J. Microbial Community Coalescence for Microbiome Engineering. Front. Microbiol. 2016, 7, 6–8. [Google Scholar] [CrossRef] [Green Version]
  46. Fry, W.E.; Birch, P.R.J.; Judelson, H.S.; Grünwald, N.J.; Danies, G.; Everts, K.L.; Gevens, A.J.; Gugino, B.K.; Johnson, D.A.; Johnson, S.B.; et al. Five Reasons to Consider Phytophthora infestans a Reemerging Pathogen. Phytopathology 2015, 105, 966–981. [Google Scholar] [CrossRef] [Green Version]
  47. Das, S.; Kumar, A.; Barman, M.; Pal, S.; Bandopadhyay, P. Impact of Climate Variability on Phenology of Rice. In Agronomic Crops; Springer Nature Singapore Pte Ltd.: Singapore, 2020; pp. 13–28. [Google Scholar] [CrossRef]
  48. Sevik, H.; Cetin, M.; Ozel, H.B.; Erbek, A.; Zeren Cetin, I. The effect of climate on leaf micromorphological characteristics in some broad-leaved species. Environ. Dev. Sustain. 2021, 23, 6395–6407. [Google Scholar] [CrossRef]
  49. Eastburn, D.M.; Degennaro, M.M.; Delucia, E.H.; Dermody, O.; Mcelrone, A.J. Elevated atmospheric carbon dioxide and ozone alter soybean diseases at SoyFACE. Glob. Chang. Biol. 2010, 16, 320–330. [Google Scholar] [CrossRef]
  50. Mhamdi, A.; Noctor, G. High CO2 primes plant biotic stress defences through redox-linked pathways. Plant Physiol. 2016, 172, 929–942. [Google Scholar] [CrossRef] [Green Version]
  51. Zhang, S.; Li, X.; Sun, Z.; Shao, S.; Hu, L.; Ye, M.; Zhou, Y.; Xia, X.; Yu, J.; Shi, K. Antagonism between phytohormone signalling underlies the variation in disease susceptibility of tomato plants under elevated CO2. J. Exp. Bot. 2015, 66, 1951–1963. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  52. Prank, M.; Kenaley, S.C.; Bergstrom, G.C.; Acevedo, M.; Mahowald, N.M. Climate change impacts the spread potential of wheat stem rust, a significant crop disease. Environ. Res. Lett. 2019, 14, 124053. [Google Scholar] [CrossRef] [Green Version]
  53. Hovmøller, M.S.; Yahyaoui, A.H.; Milus, E.A.; Justesen, A.F. Rapid global spread of two aggressive strains of a wheat rust fungus. Mol. Ecol. 2008, 17, 3818–3826. [Google Scholar] [CrossRef] [PubMed]
  54. Milus, E.A.; Kristensen, K.; Hovmøller, M.S. Evidence for Increased Aggressiveness in a Recent Widespread Strain of Puccinia striiformis f. sp. tritici Causing Stripe Rust of Wheat. Phytopathology 2009, 99, 89–94. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  55. Váry, Z.; Mullins, E.; Mcelwain, J.C.; Doohan, F.M. The severity of wheat diseases increases when plants and pathogens are acclimatized to elevated carbon dioxide. Glob. Chang. Biol. 2015, 21, 2661–2669. [Google Scholar] [CrossRef]
  56. Kobayashi, T.; Ishiguro, K.; Nakajima, T.; Kim, H.Y.; Okada, M.; Kobayashi, K. Effects of Elevated Atmospheric CO2 Concentration on the Infection of Rice Blast and Sheath Blight. Phytopathology 2006, 96, 425–431. [Google Scholar] [CrossRef] [Green Version]
  57. McElrone, A.J.; Reid, C.D.; Hoye, K.A.; Hart, E.; Jackson, R.B. Elevated CO2 reduces disease incidence and severity of a red maple fungal pathogen via changes in host physiology and leaf chemistry. Glob. Chang. Biol. 2005, 11, 1828–1836. [Google Scholar] [CrossRef]
  58. Hibberd, J.M.; Whitbread, R.; Farrar, J.F. Effect of 700 μmol mol−1 CO2 and infection with powdery mildew on the growth and carbon partitioning of barley. New Phytol. 1996, 134, 309–315. [Google Scholar] [CrossRef]
  59. Carter, T.R.; Saarikko, R.A. Estimating regional crop potential in Finland under a changing climate. Agric. For. Meteorol. 1996, 79, 301–313. [Google Scholar] [CrossRef]
  60. Chitarra, W.; Siciliano, I.; Ferrocino, I.; Gullino, M.L.; Garibaldi, A. Effect of elevated atmospheric CO2 and temperature on the disease severity of rocket plants caused by Fusarium wilt under phytotron conditions. PLoS ONE 2015, 10, e0140769. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  61. Skelsey, P.; Cooke, D.E.L.; Lynott, J.S.; Lees, A.K. Crop connectivity under climate change: Future environmental and geographic risks of potato late blight in Scotland. Glob. Chang. Biol. 2016, 22, 3724–3738. [Google Scholar] [CrossRef]
  62. Bonde, M.R.; Nester, S.E.; Berner, D.K. Effects of frequency of “extreme” temperature highs on development of soybean rust. Phytopathology 2013, 103, 708–716. [Google Scholar] [CrossRef] [PubMed]
  63. Robson, J.D.; Wright, M.G.; Almeida, R.P.P. Biology of Pentalonia nigronervosa (Hemiptera, Aphididae) on Banana Using Different Rearing Methods. Environ. Entomol. 2007, 36, 46–52. [Google Scholar] [CrossRef]
  64. Anhalt, M.D.; Almeida, R.P.P. Effect of temperature, vector life stage, and plant access period on transmission of banana bunchy top virus to banana. Phytopathology 2008, 98, 743–748. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  65. Huang, Y.J.; Pirie, E.J.; Evans, N.; Delourme, R.; King, G.J.; Fitt, B.D.L. Quantitative resistance to symptomless growth of Leptosphaeria maculans (phoma stem canker) in Brassica napus (oilseed rape). Plant Pathol. 2009, 58, 314–323. [Google Scholar] [CrossRef]
  66. Lukas, S.; Abbas, S.J.; Kössler, P.; Karlovsky, P.; Potthoff, M.; Joergensen, R.G. Fungal plant pathogens on inoculated maize leaves in a simulated soil warming experiment. Appl. Soil Ecol. 2018, 124, 75–82. [Google Scholar] [CrossRef]
  67. Manici, L.M.; Bregaglio, S.; Fumagalli, D.; Donatelli, M. Modelling soil borne fungal pathogens of arable crops under climate change. Int. J. Biometeorol. 2014, 58, 2071–2083. [Google Scholar] [CrossRef] [PubMed]
  68. Clarkson, J.P.; Fawcett, L.; Anthony, S.G.; Young, C. A model for sclerotinia sclerotiorum infection and disease development in lettuce, based on the effects of temperature, relative humidity and ascospore density. PLoS ONE 2014, 9, e94049. [Google Scholar] [CrossRef] [PubMed]
  69. Bidzinski, P.; Ballini, E.; Ducasse, A.; Michel, C.; Zuluaga, P.; Genga, A.; Chiozzotto, R.; Morel, J.-B. Transcriptional Basis of Drought-Induced Susceptibility to the Rice Blast Fungus Magnaporthe oryzae. Front. Plant Sci. 2016, 7, 1558. [Google Scholar] [CrossRef] [PubMed]
  70. Islam, T.M.D.; Toyota, K. Effect of Moisture Conditions and Pre-Incubation at Low Temperature on Bacterial Wilt of Tomato Caused by Ralstonia solanacearum. Microbes Environ. 2004, 19, 244–247. [Google Scholar] [CrossRef] [Green Version]
  71. Johansen, T.J.; Dees, M.W.; Hermansen, A. High soil moisture reduces common scab caused by Streptomyces turgidiscabies and Streptomyces europaeiscabiei in potato. Acta Agric. Scand. Sect. B—Soil Plant Sci. 2015, 65, 193–198. [Google Scholar] [CrossRef]
  72. Homet, P.; González, M.; Matías, L.; Godoy, O.; Pérez-Ramos, I.M.; García, L.V.; Gómez-Aparicio, L. Exploring interactive effects of climate change and exotic pathogens on Quercus suber performance: Damage caused by Phytophthora cinnamomi varies across contrasting scenarios of soil moisture. Agric. For. Meteorol. 2019, 276–277, 107605. [Google Scholar] [CrossRef]
  73. Zhou, Y.; Van Leeuwen, S.K.; Pieterse, C.M.J.; Bakker, P.A.H.M.; Van Wees, S.C.M. Effect of atmospheric CO2 on plant defense against leaf and root pathogens of Arabidopsis. Eur. J. Plant Pathol. 2019, 154, 31–42. [Google Scholar] [CrossRef] [Green Version]
  74. Delgado-Baquerizo, M.; Guerra, C.A.; Cano-Díaz, C.; Egidi, E.; Wang, J.T.; Eisenhauer, N.; Singh, B.K.; Maestre, F.T. The proportion of soil-borne pathogens increases with warming at the global scale. Nat. Clim. Chang. 2020, 10, 550–554. [Google Scholar] [CrossRef]
  75. Velásquez, A.C.; Castroverde, C.D.M.; He, S.Y. Plant–Pathogen Warfare under Changing Climate Conditions. Curr. Biol. 2018, 28, R619–R634. [Google Scholar] [CrossRef] [Green Version]
  76. Zayan, S.A. Impact of climate change on plant diseases and IPM strategies. Arab J. Plant Prot. 2018, 36, 75–79. [Google Scholar] [CrossRef] [Green Version]
  77. Dong, M.; Zhao, M.; Shen, Z.; Deng, X.; Ou, Y.; Tao, C.; Liu, H.; Li, R.; Shen, Q. Biofertilizer application triggered microbial assembly in microaggregates associated with tomato bacterial wilt suppression. Biol. Fertil. Soils 2020, 56, 551–563. [Google Scholar] [CrossRef]
  78. Kerry, B.R.; Crump, D.H.; Mullen, L.A. Natural control of the cereal cyst nematode, Heterodera avenae Woll., by soil fungi at three sites. Crop Prot. 1982, 1, 99–109. [Google Scholar] [CrossRef]
  79. El-Tarabily, K.A. Suppression of Rhizoctonia solani diseases of sugar beet by antagonistic and plant growth-promoting yeasts. J. Appl. Microbiol. 2004, 96, 69–75. [Google Scholar] [CrossRef] [PubMed]
  80. Rangarajan, S.; Saleena, L.M.; Vasudevan, P.; Nair, S. Biological suppression of rice diseases by Pseudomonas spp. under saline soil conditions. Plant Soil 2003, 251, 73–82. [Google Scholar] [CrossRef]
  81. Li, X.; de Boer, W.; Zhang, Y.; Ding, C.; Zhang, T.; Wang, X. Suppression of soil-borne Fusarium pathogens of peanut by intercropping with the medicinal herb Atractylodes lancea. Soil Biol. Biochem. 2018, 116, 120–130. [Google Scholar] [CrossRef]
  82. Siddiqui, I.A.; Shaukat, S.S. Mixtures of plant disease suppressive bacteria enhance biological control of multiple tomato pathogens. Biol. Fertil. Soils 2002, 36, 260–268. [Google Scholar] [CrossRef]
  83. Latz, E.; Eisenhauer, N.; Rall, B.C.; Scheu, S.; Jousset, A. Unravelling Linkages between Plant Community Composition and the Pathogen-Suppressive Potential of Soils. Sci. Rep. 2016, 6, 23584. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  84. Mendes, R.; Kruijt, M.; de Bruijn, I.; Dekkers, E.; Van Der Voort, M.; Schneider, J.H.M.; Piceno, Y.M.; DeSantis, T.Z.; Andersen, G.L.; Bakker, P.A.H.M.; et al. Deciphering the rhizosphere microbiome for disease-suppressive bacteria. Science 2011, 332, 1097–1100. [Google Scholar] [CrossRef]
  85. Huang, X.; Shi, D.; Sun, F.; Lu, H.; Liu, J.; Wu, W. Efficacy of sludge and manure compost amendments against Fusarium wilt of cucumber. Environ. Sci. Pollut. Res. 2012, 19, 3895–3905. [Google Scholar] [CrossRef] [PubMed]
  86. Pinto, Z.V.; Morandi, M.A.B.; Bettiol, W. Induction of suppressiveness to Fusarium wilt of chrysanthemum with composted sewage sludge. Trop. Plant Pathol. 2013, 38, 414–422. [Google Scholar] [CrossRef] [Green Version]
  87. Cotxarrera, L.; Trillas-Gay, M.I.; Steinberg, C.; Alabouvette, C. Use of sewage sludge compost and Trichoderma asperellum isolates to suppress Fusarium wilt of tomato. Soil Biol. Biochem. 2002, 34, 467–476. [Google Scholar] [CrossRef]
  88. Li, B.; Xie, G.; Soad, A.; Coosemans, J. Suppression of Meloidogyne javanica by antagonistic and plant. J. Zhejiang Univ. Sci. 2005, 6, 496–501. [Google Scholar] [CrossRef] [Green Version]
  89. Löbmann, M.T.; Vetukuri, R.R.; de Zinger, L.; Alsanius, B.W.; Grenville-Briggs, L.J.; Walter, A.J. The occurrence of pathogen suppressive soils in Sweden in relation to soil biota, soil properties, and farming practices. Appl. Soil Ecol. 2016, 107, 57–65. [Google Scholar] [CrossRef]
  90. Amir, H.; Alabouvette, C. Involvement of soil abiotic factors in the mechanisms of soil suppressiveness to fusarium wilts. Soil Biol. Biochem. 1993, 25, 157–164. [Google Scholar] [CrossRef]
  91. Cha, J.; Han, S.; Hong, H.; Cho, H.; Kim, D.; Kwon, Y.; Kwon, S.; Crüsemann, M.; Lee, Y.B.; Kim, J.F.; et al. Microbial and biochemical basis of a Fusarium wilt-suppressive soil. ISME J. 2016, 10, 119–129. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  92. Donovan, N.J.A.; Backhouse, D.B.; Burgess, L.W.C. Enhanced suppression of Gaeumannomyces graminis var. tritici by retention of residues in a cereal cropping system. Australas. Plant Pathol. 2006, 35, 43–48. [Google Scholar] [CrossRef]
  93. Shiomi, Y.; Nishiyama, M.; Onizuka, T.; Marumoto, T. Comparison of bacterial community structures in the rhizoplane of tomato plants grown in soils suppressive and conducive towards bacterial wilt. Appl. Environ. Microbiol. 1999, 65, 3996–4001. [Google Scholar] [CrossRef] [Green Version]
  94. Rosenzweig, N.; Tiedje, J.M.; Quensen, J.F.; Meng, Q.; Hao, J.J. Microbial communities associated with potato common Scab-Suppressive soil determined by pyrosequencing analyses. Plant Dis. 2012, 96, 718–725. [Google Scholar] [CrossRef] [Green Version]
  95. Ghini, R.; Morandi, M.A.B. Biotic and abiotic factors associated with soil suppressiveness to Rhizodonia solani. Sci. Agric. 2006, 63, 153–160. [Google Scholar] [CrossRef]
  96. Cook, R.J. Making greater use of introduced microorganisms for biological control of plant pathogens. Annu. Rev. Phytopathol. 1993, 31, 53–80. [Google Scholar] [CrossRef]
  97. Duran, P.; Mora, M.D.L.L. Plant–Soil–Microorganism Interaction Involved in Natural Suppression of Take-All Disease; Kaushal, M., Prasad, R., Eds.; Springer Nature: Singapore, 2021; ISBN 9781461479789. [Google Scholar]
  98. Rovira, A.D.; Campbell, R. A scanning electron microscope study of interactions between micro-organisms and Gaeumannomyces graminis (Syn. Ophiobolus graminis) on wheat roots. Microb. Ecol. 1975, 2, 177–185. [Google Scholar] [CrossRef]
  99. Cook, R.J.; Rovira, A.D. The role of bacteria in the biological control of Gaeumannomyces graminis by suppressive soils. Soil Biol. Biochem. 1976, 8, 269–273. [Google Scholar] [CrossRef]
  100. Ayyadurai, N.; Ravindra Naik, P.; Sakthivel, N. Functional characterization of antagonistic fluorescent pseudomonads associated with rhizospheric soil of rice (Oryza sativa L.). J. Microbiol. Biotechnol. 2007, 17, 919–927. [Google Scholar]
  101. Kilani-Feki, O.; Khiari, O.; Culioli, G.; Ortalo-Magné, A.; Zouari, N.; Blache, Y.; Jaoua, S. Antifungal activities of an endophytic Pseudomonas fluorescens strain Pf1TZ harbouring genes from pyoluteorin and phenazine clusters. Biotechnol. Lett. 2010, 32, 1279–1285. [Google Scholar] [CrossRef] [PubMed]
  102. Validov, S.; Mavrodi, O.; De La Fuente, L.; Boronin, A.; Weller, D.; Thomashow, L.; Mavrodi, D. Antagonistic activity among 2,4-diacetylphloroglucinol-producing fluorescent Pseudomonas spp. FEMS Microbiol. Lett. 2005, 242, 249–256. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  103. Jamali, F.; Sharifi-Tehrani, A.; Lutz, M.P.; Maurhofer, M. Influence of host plant genotype, presence of a pathogen, and coinoculation with pseudomonas fluorescens strains on the rhizosphere expression of hydrogen cyanide- and 2,4-diacetylphloroglucinol biosynthetic genes in P. fluorescens biocontrol strain CHA0. Microb. Ecol. 2009, 57, 267–275. [Google Scholar] [CrossRef] [PubMed]
  104. Kwak, Y.-S.; Bakker, P.A.H.M.; Glandorf, D.C.M.; Rice, J.T.; Paulitz, T.C.; Weller, D.M. Diversity, virulence, and 2,4-diacetylphloroglucinol sensitivity of Gaeumannomyces graminis var. tritici isolates from Washington state. Phytopathology 2009, 99, 472–479. [Google Scholar] [CrossRef] [Green Version]
  105. Cordovez, V.; Carrion, V.J.; Etalo, D.W.; Mumm, R.; Zhu, H. Diversity and functions of volatile organic compounds produced by Streptomyces from a disease-suppressive soil. Front. Microbiol. 2015, 6, 1081. [Google Scholar] [CrossRef] [Green Version]
  106. Carrión, V.J.; Cordovez, V.; Tyc, O.; Etalo, D.W.; de Bruijn, I.; de Jager, V.C.L.; Medema, M.H.; Eberl, L.; Raaijmakers, J.M. Involvement of Burkholderiaceae and sulfurous volatiles in disease-suppressive soils. ISME J. 2018, 12, 2307–2321. [Google Scholar] [CrossRef] [Green Version]
  107. Kim, D.-R.; Jeon, C.-W.; Shin, J.-H.; Weller, D.M.; Thomashow, L.; Kwak, Y.-S. Function and Distribution of a Lantipeptide in Strawberry Fusarium wilt Disease–Suppressive Soils. Mol. Plant-Microbe Interact. 2018, 32, 306–312. [Google Scholar] [CrossRef] [Green Version]
  108. Raaijmakers, J.M.; Mazzola, M. Soil immune responses. Science 2016, 352, 1392–1393. [Google Scholar] [CrossRef] [PubMed]
  109. Olanrewaju, O.S.; Ayangbenro, A.S.; Glick, B.R.; Babalola, O.O. Plant health: Feedback effect of root exudates-rhizobiome interactions. Appl. Microbiol. Biotechnol. 2019, 103, 1155–1166. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  110. Wang, N.; Wang, L.; Zhu, K.; Hou, S.; Chen, L.; Mi, D.; Gui, Y.; Qi, Y.; Jiang, C.; Guo, J.H. Plant root exudates are involved in Bacillus cereusAR156 mediated biocontrol against Ralstonia solanacearum. Front. Microbiol. 2019, 10, 98. [Google Scholar] [CrossRef] [Green Version]
  111. Pieterse, C.M.J.; Van der Does, D.; Zamioudis, C.; Leon-Reyes, A.; Van Wees, S.C.M. Hormonal Modulation of Plant Immunity. Annu. Rev. Cell Dev. Biol. 2012, 28, 489–521. [Google Scholar] [CrossRef] [Green Version]
  112. Rolfe, S.A.; Griffiths, J.; Ton, J. Crying out for help with root exudates: Adaptive mechanisms by which stressed plants assemble health-promoting soil microbiomes. Curr. Opin. Microbiol. 2019, 49, 73–82. [Google Scholar] [CrossRef] [PubMed]
  113. Berendsen, R.L.; Vismans, G.; Yu, K.; Song, Y.; De Jonge, R.; Burgman, W.P.; Burmølle, M.; Herschend, J.; Bakker, P.A.H.M.; Pieterse, C.M.J. Disease-induced assemblage of a plant-beneficial bacterial consortium. ISME J. 2018, 12, 1496–1507. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  114. López-Ráez, J.A.; Pozo, M.J.; García-garrido, J.M. Strigolactones: A cry for help in the rhizosphere. Botany 2011, 89, 513–522. [Google Scholar] [CrossRef] [Green Version]
  115. Zitzelsberger, C.; Buchbauer, G. Essential Oils as “A Cry for Help”. A Review. Nat. Prod. Commun. 2015, 10, 1127–1138. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  116. Chuberre, C.; Plancot, B.; Driouich, A.; Moore, J.P.; Bardor, M.; Gügi, B.; Vicré, M. Plant immunity is compartmentalized and specialized in roots. Front. Plant Sci. 2018, 871, 1692. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  117. Marcel, S.; Paszkowski, U.; Sawers, R.; Oakeley, E.; Angliker, H. Tissue-adapted invasion strategies of the rice blast fungus Magnaporthe oryzae. Plant Cell 2010, 22, 3177–3187. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  118. Rudrappa, T.; Czymmek, K.J.; Paré, P.W.; Bais, H.P. Root-secreted malic acid recruits beneficial soil bacteria. Plant Physiol. 2008, 148, 1547–1556. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  119. Doornbos, R.F.; van Loon, L.C.; Bakker, P.A.H.M. Impact of root exudates and plant defense signaling on bacterial communities in the rhizosphere. A review. Agron. Sustain. Dev. 2012, 32, 227–243. [Google Scholar] [CrossRef]
  120. Lemanceau, P.; Blouin, M.; Muller, D.; Moënne-Loccoz, Y. Let the Core Microbiota Be Functional. Trends Plant Sci. 2017, 22, 583–595. [Google Scholar] [CrossRef]
  121. Trivedi, P.; Delgado-Baquerizo, M.; Trivedi, C.; Hamonts, K.; Anderson, I.C.; Singh, B.K. Keystone microbial taxa regulate the invasion of a fungal pathogen in agro-ecosystems. Soil Biol. Biochem. 2017, 111, 10–14. [Google Scholar] [CrossRef]
  122. Chapelle, E.; Mendes, R.; Bakker, P.A.H.; Raaijmakers, J.M. Fungal invasion of the rhizosphere microbiome. ISME J. 2016, 10, 265–268. [Google Scholar] [CrossRef] [Green Version]
  123. van der Voort, M.; Kempenaar, M.; van Driel, M.; Raaijmakers, J.M.; Mendes, R. Impact of soil heat on reassembly of bacterial communities in the rhizosphere microbiome and plant disease suppression. Ecol. Lett. 2016, 19, 375–382. [Google Scholar] [CrossRef]
  124. Han, Y.; Xu, L.; Liu, L.; Yi, M. Illumina sequencing reveals a rhizosphere bacterial community associated with foxtail millet smut disease suppression. Plant Soil 2017, 410, 411–421. [Google Scholar] [CrossRef]
  125. Acuña, J.J.; Marileo, L.G.; Araya, M.A.; Rilling, J.I.; Larama, G.A.; Mora, M.L.; Epstein, S.; Jorquera, M.A. In Situ Cultivation Approach to Increase the Culturable Bacterial Diversity in the Rhizobiome of Plants. J. Soil Sci. Plant Nutr. 2020, 20, 1411–1426. [Google Scholar] [CrossRef]
  126. Rawat, P.; Das, S.; Shankhdhar, D.; Shankhdhar, S.C. Phosphate-Solubilizing Microorganisms: Mechanism and Their Role in Phosphate Solubilization and Uptake. J. Soil Sci. Plant Nutr. 2021, 21, 49–68. [Google Scholar] [CrossRef]
  127. Acuña, J.J.; Jorquera, M.A.; Barra, P.J.; Crowley, D.E.; de la Luz Mora, M. Selenobacteria selected from the rhizosphere as a potential tool for Se biofortification of wheat crops. Biol. Fertil. Soils 2013, 49, 175–185. [Google Scholar] [CrossRef]
  128. Barra, P.J.; Pontigo, S.; Delgado, M.; Parra–Almuna, L.; Duran, P.; Valentine, A.J.; Jorquera, M.A.; de la Luz Mora, M. Phosphobacteria inoculation enhances the benefit of P–fertilization on Lolium perenne in soils contrasting in P–availability. Soil Biol. Biochem. 2019, 136, 107516. [Google Scholar] [CrossRef]
  129. Barra, P.J.; Viscardi, S.; Jorquera, M.A.; Duran, P.A.; Valentine, A.J.; de la Luz Mora, M. Understanding the Strategies to Overcome Phosphorus–Deficiency and Aluminum–Toxicity by Ryegrass Endophytic and Rhizosphere Phosphobacteria. Front. Microbiol. 2018, 9, 1155. [Google Scholar] [CrossRef]
  130. Barra, P.J.; Inostroza, N.G.; Mora, M.L.; Crowley, D.E.; Jorquera, M.A. Bacterial consortia inoculation mitigates the water shortage and salt stress in an avocado (Persea americana Mill.) nursery. Appl. Soil Ecol. 2017, 111, 39–47. [Google Scholar] [CrossRef] [Green Version]
  131. Barra, P.J.; Inostroza, N.G.; Acuña, J.J.; Mora, M.L.; Crowley, D.E.; Jorquera, M.A. Formulation of bacterial consortia from avocado (Persea americana Mill.) and their effect on growth, biomass and superoxide dismutase activity of wheat seedlings under salt stress. Appl. Soil Ecol. 2016, 102, 80–91. [Google Scholar] [CrossRef] [Green Version]
  132. Qiu, Z.; Egidi, E.; Liu, H.; Kaur, S.; Singh, B.K. New frontiers in agriculture productivity: Optimised microbial inoculants and in situ microbiome engineering. Biotechnol. Adv. 2019, 37, 107371. [Google Scholar] [CrossRef] [PubMed]
  133. Inostroza, N.G.; Barra, P.J.; Wick, L.Y.; Mora, M.L.; Jorquera, M.A. Effect of rhizobacterial consortia from undisturbed arid- and agro-ecosystems on wheat growth under different conditions. Lett. Appl. Microbiol. 2017, 64, 158–163. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  134. Yang, W.; Gong, T.; Wang, J.; Li, G.; Liu, Y.; Zhen, J.; Ning, M.; Yue, D.; Du, Z.; Chen, G. Effects of Compound Microbial Fertilizer on Soil Characteristics and Yield of Wheat (Triticum aestivum L.). J. Soil Sci. Plant Nutr. 2020, 20, 2740–2748. [Google Scholar] [CrossRef]
  135. Moretti, L.G.; Crusciol, C.A.C.; Bossolani, J.W.; Momesso, L.; Garcia, A.; Kuramae, E.E.; Hungria, M. Bacterial Consortium and Microbial Metabolites Increase Grain Quality and Soybean Yield. J. Soil Sci. Plant Nutr. 2020, 20, 1923–1934. [Google Scholar] [CrossRef]
  136. Durán, P.; Acuña, J.J.; Jorquera, M.A.; Azcón, R.; Paredes, C.; Rengel, Z.; de la Luz Mora, M. Endophytic bacteria from selenium-supplemented wheat plants could be useful for plant-growth promotion, biofortification and Gaeumannomyces graminis biocontrol in wheat production. Biol. Fertil. Soils 2014, 50, 983–990. [Google Scholar] [CrossRef]
  137. Pineda, A.; Kaplan, I.; Bezemer, T.M. Steering Soil Microbiomes to Suppress Aboveground Insect Pests. Trends Plant Sci. 2017, 22, 770–778. [Google Scholar] [CrossRef] [Green Version]
  138. Toju, H.; Peay, K.G.; Yamamichi, M.; Narisawa, K.; Hiruma, K.; Naito, K.; Fukuda, S.; Ushio, M.; Nakaoka, S.; Onoda, Y.; et al. Core microbiomes for sustainable agroecosystems. Nat. Plants 2018, 4, 247–257. [Google Scholar] [CrossRef]
  139. Arif, I.; Batool, M.; Schenk, P.M. Plant Microbiome Engineering: Expected Benefits for Improved Crop Growth and Resilience. Trends Biotechnol. 2020, 38, 1385–1396. [Google Scholar] [CrossRef]
  140. Trivedi, P.; Leach, J.E.; Tringe, S.G.; Sa, T.; Singh, B.K. Plant–microbiome interactions: From community assembly to plant health. Nat. Rev. Microbiol. 2020, 18, 607–621. [Google Scholar] [CrossRef] [PubMed]
  141. Busby, P.E.; Soman, C.; Wagner, M.R.; Friesen, M.L.; Kremer, J.; Bennett, A.; Morsy, M.; Eisen, J.A.; Leach, J.E.; Dangl, J.L. Research priorities for harnessing plant microbiomes in sustainable agriculture. PLoS Biol. 2017, 15, e2001793. [Google Scholar] [CrossRef] [PubMed]
  142. Trivedi, P.; Mattupalli, C.; Eversole, K.; Leach, J.E. Enabling sustainable agriculture through understanding and enhancement of microbiomes. New Phytol. 2021, 230, 2129–2147. [Google Scholar] [CrossRef] [PubMed]
  143. Wisniewski, M.; Droby, S. The postharvest microbiome: The other half of sustainability. Biol. Control 2019, 137, 104025. [Google Scholar] [CrossRef]
  144. Koskella, B.; Bergelson, J. The study of host—microbiome (co) evolution across levels of selection. Philos. Trans. R. Soc. B Biol. Sci. 2020, 375, 20190604. [Google Scholar] [CrossRef]
  145. Agler, M.T.; Ruhe, J.; Kroll, S.; Morhenn, C.; Kim, S.T.; Weigel, D.; Kemen, E.M. Microbial Hub Taxa Link Host and Abiotic Factors to Plant Microbiome Variation. PLoS Biol. 2016, 14, e1002352. [Google Scholar] [CrossRef] [Green Version]
  146. Herren, C.M.; McMahon, K.D. Keystone taxa predict compositional change in microbial communities. Environ. Microbiol. 2018, 20, 2207–2217. [Google Scholar] [CrossRef] [Green Version]
  147. Banerjee, S.; Schlaeppi, K.; van der Heijden, M.G.A. Keystone taxa as drivers of microbiome structure and functioning. Nat. Rev. Microbiol. 2018, 16, 567–576. [Google Scholar] [CrossRef]
  148. Wu, X.; Yang, J.; Ruan, H.; Wang, S.; Yang, Y.; Naeem, I.; Wang, L.; Liu, L.; Wang, D. The diversity and co-occurrence network of soil bacterial and fungal communities and their implications for a new indicator of grassland degradation. Ecol. Indic. 2021, 129, 107989. [Google Scholar] [CrossRef]
  149. Zhang, Q.; Acuña, J.J.; Inostroza, N.G.; Duran, P.; Pearce, D.A. Niche Differentiation in the Composition, Predicted Function, and Co-occurrence Networks in Bacterial Communities Associated With Antarctic Vascular Plants. Front. Microbiol. 2020, 11, 1036. [Google Scholar] [CrossRef] [PubMed]
  150. Jeewani, P.H.; Gunina, A.; Tao, L.; Zhu, Z.; Kuzyakov, Y.; Van Zwieten, L.; Guggenberger, G.; Shen, C.; Yu, G.; Singh, B.P.; et al. Rusty sink of rhizodeposits and associated keystone microbiomes. Soil Biol. Biochem. 2020, 147, 107840. [Google Scholar] [CrossRef]
  151. Bao, Y.; Dolfing, J.; Guo, Z.; Chen, R.; Wu, M.; Li, Z.; Lin, X.; Feng, Y. Important ecophysiological roles of non-dominant Actinobacteria in plant residue decomposition, especially in less fertile soils. Microbiome 2021, 9, 1–17. [Google Scholar] [CrossRef]
  152. Ishimoto, C.K.; Aono, A.H.; Nagai, J.S.; Sousa, H.; Miranda, A.R.L.; Melo, V.M.M.; Mendes, L.W.; Araujo, F.F.; de Melo, W.J.; Kuroshu, R.M.; et al. Microbial co-occurrence network and its key microorganisms in soil with permanent application of composted tannery sludge. Sci. Total Environ. 2021, 789, 147945. [Google Scholar] [CrossRef]
  153. Zheng, Y.; Han, X.; Zhao, D.; Wei, K.; Yuan, Y.; Li, Y.; Liu, M.; Zhang, C.S. Exploring Biocontrol Agents From Microbial Keystone Taxa Associated to Suppressive Soil: A New Attempt for a Biocontrol Strategy. Front. Plant Sci. 2021, 12, 407. [Google Scholar] [CrossRef] [PubMed]
  154. Lee, S.M.; Kong, H.G.; Song, G.C.; Ryu, C.M. Disruption of Firmicutes and Actinobacteria abundance in tomato rhizosphere causes the incidence of bacterial wilt disease. ISME J. 2021, 15, 330–347. [Google Scholar] [CrossRef]
  155. Hassani, M.A.; Durán, P.; Hacquard, S. Microbial interactions within the plant holobiont. Microbiome 2018, 6, 58. [Google Scholar] [CrossRef] [PubMed]
  156. Dastogeer, K.M.G.; Tumpa, F.H.; Sultana, A.; Akter, M.A.; Chakraborty, A. Plant microbiome—An account of the factors that shape community composition and diversity. Curr. Plant Biol. 2020, 23, 100161. [Google Scholar] [CrossRef]
  157. van der Heijden, M.G.A.; Hartmann, M. Networking in the Plant Microbiome. PLoS Biol. 2016, 14, e1002378. [Google Scholar] [CrossRef] [PubMed]
  158. Vorholt, J.A.; Vogel, C.; Carlström, C.I.; Müller, D.B. Establishing Causality: Opportunities of Synthetic Communities for Plant Microbiome Research. Cell Host Microbe 2017, 22, 142–155. [Google Scholar] [CrossRef]
  159. Panke-Buisse, K.; Poole, A.C.; Goodrich, J.K.; Ley, R.E.; Kao-Kniffin, J. Selection on soil microbiomes reveals reproducible impacts on plant function. ISME J. 2015, 9, 980–989. [Google Scholar] [CrossRef]
  160. Jochum, M.D.; McWilliams, K.L.; Pierson, E.A.; Jo, Y.K. Host-mediated microbiome engineering (HMME) of drought tolerance in the wheat rhizosphere. PLoS ONE 2019, 14, e0225933. [Google Scholar] [CrossRef] [Green Version]
  161. Kaul, S.; Choudhary, M.; Gupta, S.; Dhar, M.K. Engineering Host Microbiome for Crop Improvement and Sustainable Agriculture. Front. Microbiol. 2021, 12, 1125. [Google Scholar] [CrossRef] [PubMed]
  162. French, E.; Kaplan, I.; Iyer-Pascuzzi, A.; Nakatsu, C.H.; Enders, L. Emerging strategies for precision microbiome management in diverse agroecosystems. Nat. Plants 2021, 7, 256–267. [Google Scholar] [CrossRef]
  163. Rodriguez, R.; Durán, P. Natural Holobiome Engineering by Using Native Extreme Microbiome to Counteract the Climate Change Effects. Front. Bioeng. Biotechnol. 2020, 8, 568. [Google Scholar] [CrossRef]
  164. Niu, B.; Paulson, J.N.; Zheng, X.; Kolter, R. Simplified and representative bacterial community of maize roots. Proc. Natl. Acad. Sci. USA 2017, 114, E2450–E2459. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  165. Cooper, R.O.; Tjards, S.; Rischling, J.; Nguyen, D.T.; Cressler, C.E. Multiple generations of antibiotic exposure and isolation influence host fitness and the microbiome in a model zooplankton species. bioRxiv 2021, 68502. [Google Scholar] [CrossRef]
  166. Panth, M.; Hassler, S.C.; Baysal-Gurel, F. Methods for Management of Soilborne Diseases in Crop Production. Agriculture 2020, 10, 16. [Google Scholar] [CrossRef] [Green Version]
  167. Ward, D.V.; Bhattarai, S.; Rojas-Correa, M.; Purkayastha, A.; Holler, D.; Da Qu, M.; Mitchell, W.G.; Yang, J.; Fountain, S.; Zeamer, A.; et al. The intestinal and oral microbiomes are robust predictors of covid-19 severity the main predictor of covid-19-related fatality. medRxiv 2021. [Google Scholar] [CrossRef]
  168. Bucci, V.; Xavier, J.B. Towards predictive models of the human gut microbiome. J. Mol. Biol. 2014, 426, 3907–3916. [Google Scholar] [CrossRef] [Green Version]
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Figure 1. Schematic representation of specific (green letters) and general suppressiveness (blue letters). Specific suppression is limited to a particular pathogen and is mediated by one or a few specific microorganisms. Moreover, it is potentially transferable to conducive or non-suppressive soil. General suppression occurs as a general antagonistic effect exerted by the total soil microbial biomass in the bulk soil against a broad spectrum of pathogens (mainly in saprotrophic phase). General suppression is not transferable between soils.
Figure 1. Schematic representation of specific (green letters) and general suppressiveness (blue letters). Specific suppression is limited to a particular pathogen and is mediated by one or a few specific microorganisms. Moreover, it is potentially transferable to conducive or non-suppressive soil. General suppression occurs as a general antagonistic effect exerted by the total soil microbial biomass in the bulk soil against a broad spectrum of pathogens (mainly in saprotrophic phase). General suppression is not transferable between soils.
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Figure 2. Effect of climate change on key crops (rice, potatoes, cereal, soybean); red: detrimental effect; yellow: neutral or unclear effect; green: desirable effect, under >CO2, >T°, <Wa (water availability).
Figure 2. Effect of climate change on key crops (rice, potatoes, cereal, soybean); red: detrimental effect; yellow: neutral or unclear effect; green: desirable effect, under >CO2, >T°, <Wa (water availability).
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Figure 3. Plants exposed to soilborne disease recruit a specific microbiome (core microbiome or microbial hubs) induced by a chemical signal to induce microbiome homeostasis.
Figure 3. Plants exposed to soilborne disease recruit a specific microbiome (core microbiome or microbial hubs) induced by a chemical signal to induce microbiome homeostasis.
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Figure 4. Engineering microbiome by host-mediated microbiome selection to plant health. The natural selection of microbiota over multiple generations can be induced by continual plant sowing in conducive inoculated soils (horizontal transmission). Using this approach, host plants can be used to recruit and self-identify desirable microorganisms that could later be used as inoculants to transfer functional core microbiota, or whole microbiota, in order to obtain healthy plants for subsequent generations (vertical transmission).
Figure 4. Engineering microbiome by host-mediated microbiome selection to plant health. The natural selection of microbiota over multiple generations can be induced by continual plant sowing in conducive inoculated soils (horizontal transmission). Using this approach, host plants can be used to recruit and self-identify desirable microorganisms that could later be used as inoculants to transfer functional core microbiota, or whole microbiota, in order to obtain healthy plants for subsequent generations (vertical transmission).
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Table
Table 1. Effect of climate change and plant disease incidence.
Table 1. Effect of climate change and plant disease incidence.
Climate VariableHostIncidencePathogenLocationReference
>CO2Wheatincrease
increase		Fusarium sp.
Septoria tritici		In vitro (Ireland)
In vitro (Ireland)		[55]
RiceincreaseMagnaporthe oryzaeJapan[56]
SoybeandecreasePeronospora manshuricaUSA[49]
SoybeanincreaseSeptoria glycinesUSA
neutralFusarium virguliformeUSA
Duke forestdecreasePhyllosticta minima
Acer rubrum		USA[57]
BarleydecreaseErysiphe graminisIn vitro (UK)[58]
>CO2 + >T°Wheat, barley, oat, potato, maizeincreaseGlobodera rostochiensis
Meloidogyne chitwoodi
Phytophthora infestans		Finland[59]
Eruca sativaincreaseFusarium oxysporumIn vitro (Italy)[60]
>T°PotatoincreasePhytophtora infestans
(first half of plant growing season)		UK[61]
decreasePhytophtora infestans
(second half of plant growing season)		UK
WheatincreasePuccinia striformisUSA, Mexico,
Denmark, Eritrea		[53]
SoybeanincreasePhakopsora pachyrhiziIn vitro (USA)[62]
Banana bunchy top virus (BBTV)increasePentalotia nigronervosaIn vitro (USA)[63,64]
Brasica napusincreaseLeptosphaeria maculansFrance[65]
MaizeneutralFusarium culmorumGermany[66]
increaseFusarium oxysporum
decreaseRhizoctonia solani
CerealsincreaseFusarium nivaleItaly[67]
Wheat, barleyincreaseBipolaris sorokiniana
Several early cropsincreasePythium ultimum
Horticultural cropsincreaseSclerotinia minor
Sunflower, sorghum, maize, cotton, soybean, etc.increaseMacrophomina phaseolina
LettuceincreaseSclerotinia sclerotiorumIn vitro (UK)[68]
<WaRiceincreaseMagnaporthe oryzaeFrance[69]
TomatoincreaseRalstonia solanaceumIn vitro (Japan)[70]
PotatodecreaseStreptomyces turgidiscabies
Streptomyces europaeiscabiei		In vitro (Norway)[71]
SoybeanincreasePeronospora manshuricaUSA[49]
increaseSeptoria glycines
increaseFusarium virguliforme
Table
Table 2. Microorganisms and abiotic factors involved in soilborne pathogen suppression.
Table 2. Microorganisms and abiotic factors involved in soilborne pathogen suppression.
PathogenCountry/Source SoilPlantSuppresserReference
Fungi
Rhizoctonia solani
Fusarium sp.		Brazil/pasture, fallow ground, forestCommon beanAbiotic (hydrolysis of fluorescein diacetate, CO2)
Biotic (total microbial activity)		[78]
Rhizoctonia solaniEgyptSugar beetPlant growth promoting (PGP yeast), Candida valida, Rhodotorula glutinis, Trichosporon asahii)[79]
Rhizoctonia solaniIndiaRicePseudomonas spp. [80]
Rhizoctonia solani
Pythium aphanidermatum, Fusarium oxysporum		BelgiumMung beanPGP rhizobacteria (Brevibacillus brevis, Bacillus subtilis)[81]
Rhizoctonia solani
Macrophomina phaseolina
Fusarium solani		PakistanTomatoesPGP rhizobacteria (Pseudomonas fluorescens,
Pseudomonas aeruginosa, Bradyrhizobium japonicum)		[82]
Rhizoctonia solaniGermanySugar beetAbiotic (pH)
Biotic (Actinomyces, Bacillus, Pseudomona)		[83]
Rhizoctonia solaniNetherlandsSugar beetProteobacteria, Firmicutes, Actinobacteria[84]
Fusarium sp.substrateCucumberSludge compost: sewage sludge (pig manure), sawdust, matured sludge compost[85]
Fusarium sp.substrateChrysanthemumComposted sewage sludge into the Pinus bark-based substrate[86]
Fusarium sp.substrateTomatoesSewage sludge and yard wastes[87]
Fusarium spp.ChinaPeanutIntercropping of peanut with Atractylodes lancea[88]
Pythium ultimumSwedenWheatPermanent soil cover and a balanced nutrient[89]
Fusarium oxysporumAlgeriaPalm grovesSoil abiotic factors (i.e., clay addition to sansy soil)[90]
Fusarium oxysporumKoreaStrawberryActinobacteria[91]
Fusarium oxysporumBrasilCommon beanPseudomonadaceae, bacillaceae, solibacteraceae and cytophagaceae[19]
Fusarium solaniPakistanTomatoesPGP rhizobacteria (Pseudomonas fluorescens, Pseudomonas aeruginosa, Bradyrhizobium japonicum)[82]
Gaeumannomyces graminisChileWheatSoil microbiome[15]
Gaeumannomyces graminisChileWheatEndophytic microbiome[17,22]
Gaeumannomyces graminisAustraliaWheatStubble retention and reduced tillage[92]
Bacteria
Ralstonia solanacearumJapanTomatoSoil bacteria[93]
Xanthomonas oryzaeIndiaRicePseudomonas spp. [80]
Streptomyces spp. USAPotatoLysobacter, acidobacteria[94]
Nematode
Heterodera avenaeUKOatVerticillium chlamydosporium,
Nematophthora gynophila		[95]
Meloidogyne javanicaBelgiumMung beanPGP rhizobacteria (Brevibacillus brevis,
Bacillus subtilis)		[81]
Meloidogyne javanicaPakistanTomatoesPGP rhizobacteria (Pseudomonas fluorescens,
Pseudomonas aeruginosa, Bradyrhizobium japonicum)		[82]
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Durán, P.; Tortella, G.; Sadowsky, M.J.; Viscardi, S.; Barra, P.J.; Mora, M.d.l.L. Engineering Multigenerational Host-Modulated Microbiota against Soilborne Pathogens in Response to Global Climate Change. Biology 2021, 10, 865. https://doi.org/10.3390/biology10090865

AMA Style

Durán P, Tortella G, Sadowsky MJ, Viscardi S, Barra PJ, Mora MdlL. Engineering Multigenerational Host-Modulated Microbiota against Soilborne Pathogens in Response to Global Climate Change. Biology. 2021; 10(9):865. https://doi.org/10.3390/biology10090865

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Durán, Paola, Gonzalo Tortella, Michael J. Sadowsky, Sharon Viscardi, Patricio Javier Barra, and Maria de la Luz Mora. 2021. "Engineering Multigenerational Host-Modulated Microbiota against Soilborne Pathogens in Response to Global Climate Change" Biology 10, no. 9: 865. https://doi.org/10.3390/biology10090865

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