Your search keyword '"plant microbiota"' showing total 223 results

1. The chemical language of plant–microbe–microbe associations: an introduction to a Virtual Issue.

Author

Hacquard, Stéphane and Martin, Francis M.

Subjects

*ANTI-infective agents, *MOLECULES, *LANGUAGE & languages

Abstract

This Editorial introduces the Virtual Issue 'Chemical language of plant–microbe–microbe associations' that includes the following papers: Basak et al. (2024), Böttner et al. (2023), Brisson et al. (2023), Feng et al. (2023), Gfeller et al. (2024), Gómez‐Pérez et al. (2023), Hong et al. (2022, 2023), Hu et al. (2024), Jiang et al. (2024), Lee et al. (2024), Nakano (2024), Ökmen et al. (2023), Revillini et al. (2023), Rovenich & Thomma (2023), Simonin et al. (2022), Snelders et al. (2023), Walsh et al. (2024), Wen et al. (2023), Xia et al. (2023), Xie et al. (2023), Zhang et al. (2023, 2024), Zheng et al. (2023), Zhou et al. (2023, 2024). Access the Virtual Issue at www.newphytologist.com/virtualissues. [ABSTRACT FROM AUTHOR]

Published

2024

2. Regulation of Bacterial Growth and Behavior by Host Plant.

Author

Nakagami, Satoru, Wang, Zhe, Han, Xiaowei, and Tsuda, Kenichi

Abstract

Plants are associated with diverse bacteria in nature. Some bacteria are pathogens that decrease plant fitness, and others are beneficial bacteria that promote plant growth and stress resistance. Emerging evidence also suggests that plant-associated commensal bacteria collectively contribute to plant health and are essential for plant survival in nature. Bacteria with different characteristics simultaneously colonize plant tissues. Thus, plants need to accommodate bacteria that provide service to the host plants, but they need to defend against pathogens at the same time. How do plants achieve this? In this review, we summarize how plants use physical barriers, control common goods such as water and nutrients, and produce antibacterial molecules to regulate bacterial growth and behavior. Furthermore, we highlight that plants use specialized metabolites that support or inhibit specific bacteria, thereby selectively recruiting plant-associated bacterial communities and regulating their function. We also raise important questions that need to be addressed to improve our understanding of plant–bacteria interactions. [ABSTRACT FROM AUTHOR]

Published

2024

3. Microbiota as a linking axis of the macroecosystem involving soil-plant-human. Potential interactions and perspectives for study

Author

Artem V. Lyamin, Lyudmila V. Orlova, Vladimir I. Platonov, Natalia M. Troz, Aleksey S. Sustretov, Elena A. Zakharova, Karim A. Kaiumov, and Dmitriy V. Alekseev

Subjects

human microbiota, plant microbiota, soil microbiota, ecological microbiology, Microbiology, QR1-502

Abstract

During analyzing morbidity data, it is obvious that the ratio of infections has decreased significantly since the beginning of the 20th century, but the proportion of metabolic and inflammatory diseases has increased. This may be related to the degradation of soils. At the same time, mobilization of nutrient elements primarily depends on the activity of soil microbiota, which is subjected to negative anthropogenic impact. Although plant nutritional value has a direct impact on human health; however, modern agricultural practices that aimed at deep cultivation are causing disturbances in the soil microbiota composition. Subsequently, this resulted in maladaptation of the human immune system, as contacts with xenobiotics occur instead of evolutionarily calibrated interactions; potentially endangering the gut microbiota. This review aims to represent recent data on the relationships among human intestinal, soil, and plant microbiota. Nowadays, it is evident that there is a broad range of influences on human health not only from intestinal microbiota but also from its connection with the environmental microbiota (i.e., soil microorganisms in particular). Today, with respect to the background of active use of modern technologies, including genetical ones, we have the opportunity to examine such volumes of data that will allow us to fully analyze microbiological diversity of the different ecological niches in terms of their common features, differences, and mutual influences. Such studies will make it possible to identify potential factors determining the composition of microbiota in different loci, assess their potential impact on human health, and adjust methods to diagnose and restore the optimal composition of human, plant, and soil microbiota.

Published

2024

4. Taste of microbes: the terroir explained by rhizospheric microbes.

Author

Nakano, Ryohei Thomas

Subjects

*PLANT metabolism, *TERROIR, *FLAVOR, *MICROORGANISMS

Abstract

This article is a Commentary on Walsh et al. (2024), 243: 1951–1965. [ABSTRACT FROM AUTHOR]

Published

2024

5. Utilization of Biodiversity for Sustainable Plant Disease Management

Author

Wong, Mui-Yun, Kwan, Yee-Min, Sathyapriya, H., and Wong, Mui-Yun, editor

Published

2024

6. Distinct microbiota assembly and functional patterns in disease-resistant and susceptible varieties of tobacco.

Author

Luhua Yang, Yuan Guo, Hui Yang, Shun Li, Yunzeng Zhang, Cheng Gao, Tian Wei, and Likai Hao

Subjects

BACTERIAL wilt diseases, DISEASE resistance of plants, TOBACCO, HYDROCYANIC acid, GENE clusters, HOST plants, PEPTIDES

Abstract

The plant microbiota is believed to be an accessory genome that extends plant functions, forming holobionts together with the host plant. Plant disease resistance, therefore, is inextricably linked with plant microbiota, which play important roles in plant growth and health. To explore the relationship between plant microbiota and disease resistance, we investigated the tobacco microbiome of two varieties with contrasting disease-resistance levels to bacterial wilt and black shank diseases. Comparative microbiome analysis indicated that the resistant variety assembled a distinct microbiota with higher network complexity and diversity. While Pseudomonas and Ensifer, which contain biocontrol and beneficial members, were enriched in the rhizosphere of the resistant variety, Ralstonia, a genus including the known causative pathogen, was enriched in the susceptible variety. Metagenome sequencing revealed that biocontrol functions, such as hydrogen cyanide synthase, pyochelin biosynthesis, and arthrofactin-type cyclic lipopeptide synthetase, were more abundant in the resistant variety. Further analysis indicated that contigs encoding the corresponding genes were mostly assigned to Pseudomonas. Among all the metagenome-assembled genomes, positive selection was suggested in the genome assigned to Pseudomonas only in the rhizosphere of the resistant variety. The search of biosynthetic gene clusters in the Pseudomonas genome revealed a non-ribosomal peptide synthetase, the compound of which was brabantamide A, with known antimicrobial activity. Collectively, our study suggests that the plant microbiota might be involved in microbe-mediated disease resistance. Particularly, our results highlight Pseudomonas in the rhizosphere of the disease-resistant variety as a promising biocontrol candidate. Our study may facilitate further screening of bacterial isolates and the targeted design of microbial communities. [ABSTRACT FROM AUTHOR]

Published

2024

7. MAPK Cascades in Plant Microbiota Structure and Functioning.

Author

Van Gerrewey, Thijs and Chung, Hoo Sun

Abstract

Mitogen-activated protein kinase (MAPK) cascades are highly conserved signaling modules that coordinate diverse biological processes such as plant innate immunity and development. Recently, MAPK cascades have emerged as pivotal regulators of the plant holobiont, influencing the assembly of normal plant microbiota, essential for maintaining optimal plant growth and health. In this review, we provide an overview of current knowledge on MAPK cascades, from upstream perception of microbial stimuli to downstream host responses. Synthesizing recent findings, we explore the intricate connections between MAPK signaling and the assembly and functioning of plant microbiota. Additionally, the role of MAPK activation in orchestrating dynamic changes in root exudation to shape microbiota composition is discussed. Finally, our review concludes by emphasizing the necessity for more sophisticated techniques to accurately decipher the role of MAPK signaling in establishing the plant holobiont relationship. [ABSTRACT FROM AUTHOR]

Published

2024

8. A sexual role in regulation of the assembly of bacterial and arbuscular mycorrhizal fungal communities.

Author

Zhu, Yuanjing, Dong, Tingting, Sun, Fangyuan, Xiao, Yuxin, and Guo, Qingxue

Subjects

*DIOECIOUS plants, *KEYSTONE species, *INDOLEACETIC acid, *RHIZOSPHERE, *SALICYLIC acid, *JASMONIC acid, *BACTERIAL communities, *FUNGAL communities

Abstract

Background and aims: Dioecious species appear to be sexually dimorphic and they present as result distinct responses to environmental settings. However, how and to what extent dioecious plants shape microbiota to their own benefit, remains unclear. Methods: Male and female Populus cathayana plants were cultivated in soils collected from different regions. The effect of a sexual role on the assembly of the bacterial community along the plant-soil continuum and the arbuscular mycorrhizal fungal community at the root endosphere and rhizosphere were studied first. The process by which phytohormones and defensive compounds of the dioecious plants influenced the endophyte community in the plant endosphere across different soil conditions was explored. Results: The male and female plants imposed strong pressure on the selection of keystone species and influenced the microbe-microbe interactions of bacterial communities in the rhizosphere, roots, phloem and leaves. Females harbored a more diverse and complicated bacterial community in their phloem than the males. Similarly, the composition of AMF communities in the rhizospheres and roots also differed between males and females, respectively. The male roots had significantly higher concentrations of jasmonic acid, salicylic acid, and indoleacetic acid than the female roots. The hormones were more significantly related to the relative abundance of AMF species in the female roots than in the male roots. Conclusion: The plant sex imposed strong regulation in plant microbiota. The different microbiota might provide external functions for dioecious plants. Therefore, more attention is required to explore the connections between plant microbiota and dioecious species. [ABSTRACT FROM AUTHOR]

Published

2024

9. Genomic and Metabolic Characterization of Plant Growth-Promoting Rhizobacteria Isolated from Nodules of Clovers Grown in Non-Farmed Soil.

Author

Wójcik, Magdalena, Koper, Piotr, Żebracki, Kamil, Marczak, Małgorzata, and Mazur, Andrzej

Subjects

*PLANT growth-promoting rhizobacteria, *AGRICULTURE, *CLOVER, *QUORUM sensing, *COMPARATIVE genomics

Abstract

The rhizosphere microbiota, which includes plant growth-promoting rhizobacteria (PGPR), is essential for nutrient acquisition, protection against pathogens, and abiotic stress tolerance in plants. However, agricultural practices affect the composition and functions of microbiota, reducing their beneficial effects on plant growth and health. Among PGPR, rhizobia form mutually beneficial symbiosis with legumes. In this study, we characterized 16 clover nodule isolates from non-farmed soil to explore their plant growth-promoting (PGP) potential, hypothesizing that these bacteria may possess unique, unaltered PGP traits, compared to those affected by common agricultural practices. Biolog profiling revealed their versatile metabolic capabilities, enabling them to utilize a wide range of carbon and energy sources. All isolates were effective phosphate solubilizers, and individual strains exhibited 1-aminocyclopropane-1-carboxylate deaminase and metal ion chelation activities. Metabolically active strains showed improved performance in symbiotic interactions with plants. Comparative genomics revealed that the genomes of five nodule isolates contained a significantly enriched fraction of unique genes associated with quorum sensing and aromatic compound degradation. As the potential of PGPR in agriculture grows, we emphasize the importance of the molecular and metabolic characterization of PGP traits as a fundamental step towards their subsequent application in the field as an alternative to chemical fertilizers and supplements. [ABSTRACT FROM AUTHOR]

Published

2023

10. The Single-Seed Microbiota Reveals Rare Taxa-Associated Community Robustness

Author

Hyun Kim, Christopher Kim, and Yong-Hwan Lee

Subjects

ecological driver, network robustness, plant microbiota, rice, seed, Plant culture, SB1-1110, Microbial ecology, QR100-130, Plant ecology, QK900-989

Abstract

Genetic and environmental cues affecting seed microbial communities have been investigated to assess the ecological characteristics of seed microbial communities. However, little is known concerning seed-to-seed microbial variations and ecological drivers at the single-seed level. We report rare taxa-associated heterogeneity and robustness of seed bacterial and fungal communities in individual seeds using 63 pooled and 70 single-seed samples from a single field-grown rice plant. Ordination analyses showed that seed-to-seed variation patterns could be clustered according to the originating panicle branch. Bacterial–fungal associations and in silico extinction experiments demonstrated that rare taxa contribute to the connectivity and robustness of the associations. Null modeling-based statistical analysis revealed that the distribution of rare taxa is mainly governed by dispersal limitation, whereas the distribution of prevalent taxa is mainly governed by homogeneous selection and ecological drift. Our findings provide an ecological framework for understanding the heterogeneity of seed microbial communities in a single plant; they will facilitate the development and application of seed microbiota or single microbe-based engineering strategies.

Published

2023

11. Endomicrobiome of in vitro and natural plants deciphering the endophytes-associated secondary metabolite biosynthesis in Picrorhiza kurrooa, a Himalayan medicinal herb

Author

Anish Tamang, Mohit Swarnkar, Pawan Kumar, Dinesh Kumar, Shiv Shanker Pandey, and Vipin Hallan

Subjects

Endomicrobiome, plant microbiota, endophytes, secondary metabolites, picrosides, next-generation DNA sequencing, Microbiology, QR1-502

Abstract

ABSTRACT Picrorhiza kurrooa an endangered high-altitude Himalayan medicinal herb, is used as a potent hepatoprotective due to the presence of various secondary metabolites, with picrosides being the most bioactive. In-vitro propagation is used as a sustainable strategy for its conservation and cultivation. The in-vitro propagation produces P. kurrooa plants (Tc) in mass, but these plants have reduced secondary metabolites (especially picrosides) compared to plants growing in their natural habitats (Wt). Therefore, considering the well-established role of microbes in secondary metabolite biosynthesis, in this study, endomicrobiome of P. kurroa plants (Tc and Wt) was explored. Using high-throughput DNA-sequencing, the endophytic communities associated with leaves, roots, and rhizomes of Wt and Tc plants were characterized. Diversity analysis revealed a loss of diversity during in-vitro propagation, and the abundant phyla were Proteobacteria, Bacteroidetes, Parcubacteria (OD1), Firmicutes, and Verrucomicrobia. Besides, the presence of distinct genera specific to different parts of Wt plants was also revealed. Quantification of secondary metabolites demonstrated the reduced accumulation of picrosides and intermediates of picroside biosynthesis in the Tc plants compared to Wt plants. Host-secondary metabolite production was positively correlated to microbial community abundance, suggesting a dynamic interplay of host-endomicrobiota interaction. Predictive functional analysis revealed the abundance of enzymes of secondary metabolite biosynthesis (especially MVA/MEP and phenylpropanoid/shikimate pathway involved in picrosides biosynthesis) in the associated-endophytic community with predominance in roots and rhizomes of Wt plants. This investigation provides novel insight into the change in the endomicrobiome of Wt and Tc plants and their correlation to the biosynthesis of secondary metabolites, and that needs to be considered for cultivation practices. IMPORTANCE Picrorhiza kurrooa is a major source of picrosides, potent hepatoprotective molecules. Due to the ever-increasing demands, overexploitation has caused an extensive decline in its population in the wild and placed it in the endangered plants' category. At present plant in-vitro systems are widely used for the sustainable generation of P. kurrooa plants, and also for the conservation of other commercially important, rare, endangered, and threatened plant species. Furthermore, the in-vitro-generated plants had reduced content of therapeutic secondary metabolites compared to their wild counterparts, and the reason behind, not well-explored. Here, we revealed the loss of plant-associated endophytic communities during in-vitro propagation of P. kurrooa plants which also correlated to in-planta secondary metabolite biosynthesis. Therefore, this study emphasized to consider the essential role of plant-associated endophytic communities in in-vitro practices which may be the possible reason for reduced secondary metabolites in in-vitro plants.

Published

2023

12. How does plant sex alter microbiota assembly in dioecious plants?

Author

Guo, Qingxue, Zhu, Yuanjing, Korpelainen, Helena, Niinemets, Ülo, and Li, Chunyang

Subjects

*DIOECIOUS plants, *PLANT exudates, *SEXUAL dimorphism, *RHIZOSPHERE, *MICROBIAL communities, *DETERMINISTIC processes, *PLANT growth, *GUT microbiome

Abstract

Males and females of dioecious plant species are different in morphology, physiology, and immunity. Male and female plants differently regulate microbial communities in the rhizosphere, phyllosphere, and endosphere along the soil–plant continuum. Sexual dimorphism in root exudates is the major force in regulating sex-specific microbial communities in the rhizosphere. Deterministic processes in sex-specific microbial assembly in the plant endosphere are caused by different physical–chemical traits like cell wall and phytohormones. Males can alleviate stress-caused damage in females by recruiting stress-tolerant microorganisms under intersexual interactions. Plant microbiota can greatly impact plant growth, defense, and health in different environments. Thus, it might be evolutionarily beneficial for plants to be able to control processes related to microbiota assembly. Dioecious plant species display sexual dimorphism in morphology, physiology, and immunity. These differences imply that male and female individuals might differently regulate their microbiota, but the role of sex in microbiota assembly has been largely neglected so far. Here, we introduce the mechanism of how sex controls microbiota in plants analogically to the sex regulation of gut microbiota in animals, in particular in humans. We argue that plant sex imposes selective pressure on filtering and constructing microbiota in the rhizosphere, phyllosphere, and endosphere along the soil–plant continuum. Since male plants are more resistant than female plants to environmental stresses, we suggest that a male host forms more stable and resistant plant microbiota that cooperate more effectively with the host to resist stresses. Male and female plants can distinguish whether a plant is of the same or different sex, and males can alleviate stress-caused damage in females. The impact of a male host on microbiota would protect female plants from unfavorable environments. [ABSTRACT FROM AUTHOR]

Published

2023

13. Transmission of synthetic seed bacterial communities to radish seedlings: impact on microbiota assembly and plant phenotype

Author

Simonin, Marie, Préveaux, Anne, Marais, Coralie, Garin, Tiffany, Arnault, Gontran, Sarniguet, Alain, and Barret, Matthieu

Subjects

Plant microbiota, Seed-borne bacteria, Core microbiota, Synthetic community, Phytobiome, Pathobiome, Archaeology, CC1-960, Science

Abstract

Seed-borne microorganisms can be pioneer taxa during germination and seedling emergence. Still, the identity and phenotypic effects of these taxa that constitute a primary inoculum of plant microbiota is mostly unknown. Here, we studied the transmission of bacteria from radish seeds to seedlings using the inoculation of individual seed-borne strains and synthetic communities (SynComs) under in vitro conditions. The SynComs were composed of highly abundant and prevalent, sub-dominant, or rare bacterial seed taxa. We monitored the transmission of each strain alone or in communities using gyrB gene amplicon sequencing and assessed their impacts on germination and seedling phenotype. All strains and SynComs successfully colonized seedlings and we were able to reconstruct a richness gradient (6, 8 and 12 strains) on both seeds and seedlings. Stenotrophomonas rhizophila became dominant on seedlings of the three SynComs but most strains had variable transmission success (i.e increasing, stable or decreasing during seed to seedling transition) that also depended on the SynCom richness. Most individual strains had no effect on seedling phenotypes, with the exception of Pseudomonas viridiflava and Paenibacillus sp. which had detrimental effects on germination and seedling development. Abnormal seedling morphologies were also observed with SynComs but their proportions decreased at the highest richness level. Interestingly, some bacterial strains previously identified as core taxa of radish seeds (Pseudomonas viridiflava, Erwinia persicina) were associated with detrimental effects on seedling phenotypes either in isolation or in SynComs. These results confirm that the plant core microbiome includes pathogenic and not only commensal or mutualistic taxa. Altogether, these results show that SynCom inoculation can effectively manipulate seed and seedling microbiota diversity and thus represents a promising tool to better understand the early stages of plant microbiota assembly. This study also highlights strong differences between native seed-borne taxa in the colonization and survival on plant habitats.

Published

2023

14. How plants manage pathogen infection

Author

Jian, Yinan, Gong, Dianming, Wang, Zhe, Liu, Lijun, He, Jingjing, Han, Xiaowei, and Tsuda, Kenichi

Published

2024

15. Mycobiota of Mexican Maize Landraces with Auxin-Producing Yeasts That Improve Plant Growth and Root Development.

Author

Ramos-Garza, Juan, Aguirre-Noyola, José Luis, Bustamante-Brito, Rafael, Zelaya-Molina, Lily X., Maldonado-Hernández, Jessica, Morales-Estrada, Aurea Itzel, Resendiz-Venado, Zoe, Palacios-Olvera, Jacqueline, Angeles-Gallegos, Thania, Terreros-Moysen, Paola, Cortés-Carvajal, Manuel, and Martínez-Romero, Esperanza

Subjects

ROOT development, ROOT growth, PLANT growth, FUNGI, YEAST, CORN

Abstract

Compared to agrochemicals, bioinoculants based on plant microbiomes are a sustainable option for increasing crop yields and soil fertility. From the Mexican maize landrace "Raza cónico" (red and blue varieties), we identified yeasts and evaluated in vitro their ability to promote plant growth. Auxin production was detected from yeast isolates and confirmed using Arabidopsis thaliana plants. Inoculation tests were performed on maize, and morphological parameters were measured. Eighty-seven yeast strains were obtained (50 from blue corn and 37 from red corn). These were associated with three families of Ascomycota (Dothideaceae, Debaryomycetaceae, and Metschnikowiaceae) and five families of Basidiomycota (Sporidiobolaceae, Filobasidiaceae, Piskurozymaceae, Tremellaceae, and Rhynchogastremataceae), and, in turn, distributed in 10 genera (Clavispora, Rhodotorula, Papiliotrema, Candida, Suhomyces, Soliccocozyma, Saitozyma Holtermaniella, Naganishia, and Aeurobasidium). We identified strains that solubilized phosphate and produced siderophores, proteases, pectinases, and cellulases but did not produce amylases. Solicoccozyma sp. RY31, C. lusitaniae Y11, R. glutinis Y23, and Naganishia sp. Y52 produced auxins from L-Trp (11.9–52 µg/mL) and root exudates (1.3–22.5 µg/mL). Furthermore, they stimulated the root development of A. thaliana. Inoculation of auxin-producing yeasts caused a 1.5-fold increase in maize plant height, fresh weight, and root length compared to uninoculated controls. Overall, maize landraces harbor plant growth-promoting yeasts and have the potential for use as agricultural biofertilizers. [ABSTRACT FROM AUTHOR]

Published

2023

16. Echinacea purpurea microbiota: bacterial–fungal interactions and the interplay with host and non‐host plant species in vitro dual culture.

Author

Maggini, V., Bettini, P. P., Fani, R., Firenzuoli, F., Bogani, P., and Bisseling, T.

Subjects

*ENDOPHYTIC bacteria, *ENDOPHYTIC fungi, *VIRAL tropism, *HOST plants, *PLANT species, *PLANT cells & tissues, *SPECIES specificity, *ECHINACEA (Plants)

Abstract

Important evidence is reported on the antimicrobial and antagonistic properties of bacterial endophytes in Echinacea purpurea and their role in the modulation of plant synthesis of bioactive compounds. Here, endophytic fungi were isolated from E. purpurea, and the dual culture approach was applied to deepen insights into the complex plant–microbiome interaction network.In vitro experiments were carried out to evaluate the species specificity of the interaction between host (E. purpurea) and non‐host (E. angustifolia and Nicotiana tabacum) plant tissues and bacterial or fungal endophytes isolated from living E. purpurea plants to test interactions between fungal and bacterial endophytes.A higher tropism towards plant tissue and growth was observed for both fungal and bacterial isolates compared to controls without plant tissue. The growth of all fungi was significantly inhibited by several bacterial strains that, in turn, were scarcely affected by the presence of fungi. Finally, E. purpurea endophytic bacteria were able to inhibit mycelial growth of the phytopathogen Botrytis cinerea.Bacteria and fungi living in symbiosis with wild Echinacea plants interact with each other and could represent a potential source of bioactive compounds and a biocontrol tool. [ABSTRACT FROM AUTHOR]

Published

2023

17. Genomic, Molecular, and Phenotypic Characterization of Arthrobacter sp. OVS8, an Endophytic Bacterium Isolated from and Contributing to the Bioactive Compound Content of the Essential Oil of the Medicinal Plant Origanum vulgare L.

Author

Semenzato, Giulia, Del Duca, Sara, Vassallo, Alberto, Bechini, Angela, Calonico, Carmela, Delfino, Vania, Berti, Fabiola, Vitali, Francesco, Mocali, Stefano, Frascella, Angela, Emiliani, Giovanni, and Fani, Renato

Subjects

*ENDOPHYTIC bacteria, *OREGANO, *ESSENTIAL oils, *ARTHROBACTER, *MEDICINAL plants, *VEGETABLE oils, *BIOACTIVE compounds

Abstract

Medicinal plants play an important role in the discovery of new bioactive compounds with antimicrobial activity, thanks to their pharmacological properties. However, members of their microbiota can also synthesize bioactive molecules. Among these, strains belonging to the genera Arthrobacter are commonly found associated with the plant's microenvironments, showing plant growth-promoting (PGP) activity and bioremediation properties. However, their role as antimicrobial secondary metabolite producers has not been fully explored. The aim of this work was to characterize the Arthrobacter sp. OVS8 endophytic strain, isolated from the medicinal plant Origanum vulgare L., from molecular and phenotypic viewpoints to evaluate its adaptation and influence on the plant internal microenvironments and its potential as a producer of antibacterial volatile molecules (VOCs). Results obtained from the phenotypic and genomic characterization highlight its ability to produce volatile antimicrobials effective against multidrug-resistant (MDR) human pathogens and its putative PGP role as a producer of siderophores and degrader of organic and inorganic pollutants. The outcomes presented in this work identify Arthrobacter sp. OVS8 as an excellent starting point toward the exploitation of bacterial endophytes as antibiotics sources. [ABSTRACT FROM AUTHOR]

Published

2023

18. Plant salt response: Perception, signaling, and tolerance.

Author

Fei Xiao and Huapeng Zhou

Subjects

HOMEOSTASIS, SALT tolerance in plants, SALT, SIGNALS & signaling, PLANT growth, PLANT development

Abstract

Salt stress is one of the significant environmental stressors that severely affects plant growth and development. Plant responses to salt stress involve a series of biological mechanisms, including osmoregulation, redox and ionic homeostasis regulation, as well as hormone or light signaling-mediated growth adjustment, which are regulated by different functional components. Unraveling these adaptive mechanisms and identifying the critical genes involved in salt response and adaption are crucial for developing salt-tolerant cultivars. This review summarizes the current research progress in the regulatory networks for plant salt tolerance, highlighting the mechanisms of salt stress perception, signaling, and tolerance response. Finally, we also discuss the possible contribution of microbiota and nanobiotechnology to plant salt tolerance. [ABSTRACT FROM AUTHOR]

Published

2023

19. Plant microbiota dysbiosis and the Anna Karenina Principle.

Author

Arnault, Gontran, Mony, Cendrine, and Vandenkoornhuyse, Philippe

Subjects

*DYSBIOSIS, *NUTRITIONAL status, *PLANT diseases, *STOCHASTIC processes, *DRINKING (Physiology)

Abstract

Microorganisms are associated with all plants, recently leading to the hologenome concept. We reviewed the assembly processes of plant microbiota and analyzed its structure during the emergence of dysbioses. In particular, we discussed the Anna Karenina Principle (AKP) based on Leo Tolstoy's assertion applied to plant microbiota: 'All healthy microbiota are alike; each disease-associated microbiota is sick in its own way.' We propose the AKP to explain how stochastic processes in plant microbiota assembly due to several external stressors could lead to plant diseases. Finally, we propose the AKP to conceptualize plant dysbioses as a transitory loss of host capacity to regulate its microbiota, implying a loss of function that leads to a reduction of the host's fitness. The involvement of plant microbiota in many plant functions, including resistance to abiotic or biotic stressors, water and nutrient intake, recently led to the holobiont concept. Shifts in microbiota composition linked to stress or disease is termed 'dysbiosis', but whether the shifts are a cause or a consequence of the stress or disease remains unknown. The Anna Karenina Principle (AKP) describes how microbiota are affected by external stressors and asserts that dysbiotic microbiota vary more among themselves than healthy microbiota. From this AKP and related new conceptualization, different dysbiosis scenarios can be identified by analyzing the β-diversity and evaluating the proportion of stochasticity in the community assembly. In response to external stress, the plant holobiont can either resist or recruit beneficial microorganisms from its environment. This latter mechanism emphasizes plant holobiont resilience. [ABSTRACT FROM AUTHOR]

Published

2023

20. Dissecting the cotranscriptome landscape of plants and their microbiota.

Author

Nobori, Tatsuya, Cao, Yu, Entila, Frederickson, Dahms, Eik, Tsuda, Yayoi, Garrido‐Oter, Ruben, and Tsuda, Kenichi

Abstract

Interactions between plants and neighboring microbial species are fundamental elements that collectively determine the structure and function of the plant microbiota. However, the molecular basis of such interactions is poorly characterized. Here, we colonize Arabidopsis leaves with nine plant‐associated bacteria from all major phyla of the plant microbiota and profile cotranscriptomes of plants and bacteria six hours after inoculation. We detect both common and distinct cotranscriptome signatures among plant–commensal pairs. In planta responses of commensals are similar to those of a disarmed pathogen characterized by the suppression of genes involved in general metabolism in contrast to a virulent pathogen. We identify genes that are enriched in the genome of plant‐associated bacteria and induced in planta, which may be instrumental for bacterial adaptation to the host environment and niche separation. This study provides insights into how plants discriminate among bacterial strains and lays the foundation for in‐depth mechanistic dissection of plant–microbiota interactions. Synopsis: The molecular basis of interactions between plants and commensal microbial species is poorly characterized. This study reveals common and distinct cotranscriptome signatures among plant–commensal bacteria pairs. The transcriptomes of commensals are distinct from that of a virulent pathogen and similar to that of a disarmed pathogen.Plant immunity appears to inhibit the metabolic activity of commensal bacteria.Commensal genes associated with plant colonization tend to be induced during interactions with plants.Transcriptome responses of plants and interacting microbiota members are incongruent. [ABSTRACT FROM AUTHOR]

Published

2022

21. Structure and properties of the exopolysaccharide isolated from Flavobacterium sp. Root935.

Author

Tiemblo-Martín, Marta, Pistorio, Valeria, Saake, Pia, Mahdi, Lisa, Campanero-Rhodes, María Asunción, Di Girolamo, Rocco, Di Carluccio, Cristina, Marchetti, Roberta, Molinaro, Antonio, Solís, Dolores, Zuccaro, Alga, and Silipo, Alba

Subjects

*CONFORMATIONAL analysis, *MOLECULAR dynamics, *HOST plants, *FLAVOBACTERIUM, *ANALYTICAL chemistry

Abstract

Flavobacterium strains exert a substantial influence on roots and leaves of plants. However, there is still limited understanding of how the specific interactions between Flavobacterium and their plant hosts are and how these bacteria thrive in this competitive environment. A crucial step in understanding Flavobacterium - plant interactions is to unravel the structure of bacterial envelope components and the molecular features that facilitate initial contact with the host environment. Here, we have revealed structure and properties of the exopolysaccharides (EPS) produced by Flavobacterium sp. Root935. Chemical analyses revealed a complex and interesting branched heptasaccharidic repeating unit, containing a variety of sugar moieties, including Rha, Fuc, GlcN, Fuc4N, Gal, Man and QuiN and an important and extended substitution pattern, including acetyl and lactyl groups. Additionally, conformational analysis using molecular dynamics simulation showed an extended hydrophobic interface and a distinctly elongated, left-handed helicoidal arrangement. Furthermore, properties of the saccharide chain, and likely the huge substitution pattern prevented interaction and recognition by host lectins and possessed a low immunogenic potential, highlighting a potential role of Flavobacterium sp. Root935 in plant-microbial crosstalk. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

22. Genomic and Metabolic Characterization of Plant Growth-Promoting Rhizobacteria Isolated from Nodules of Clovers Grown in Non-Farmed Soil

Author

Magdalena Wójcik, Piotr Koper, Kamil Żebracki, Małgorzata Marczak, and Andrzej Mazur

Subjects

plant microbiota, plant growth-promoting rhizobacteria (PGPR), Rhizobium, genomic characteristics, metabolic profiling, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

The rhizosphere microbiota, which includes plant growth-promoting rhizobacteria (PGPR), is essential for nutrient acquisition, protection against pathogens, and abiotic stress tolerance in plants. However, agricultural practices affect the composition and functions of microbiota, reducing their beneficial effects on plant growth and health. Among PGPR, rhizobia form mutually beneficial symbiosis with legumes. In this study, we characterized 16 clover nodule isolates from non-farmed soil to explore their plant growth-promoting (PGP) potential, hypothesizing that these bacteria may possess unique, unaltered PGP traits, compared to those affected by common agricultural practices. Biolog profiling revealed their versatile metabolic capabilities, enabling them to utilize a wide range of carbon and energy sources. All isolates were effective phosphate solubilizers, and individual strains exhibited 1-aminocyclopropane-1-carboxylate deaminase and metal ion chelation activities. Metabolically active strains showed improved performance in symbiotic interactions with plants. Comparative genomics revealed that the genomes of five nodule isolates contained a significantly enriched fraction of unique genes associated with quorum sensing and aromatic compound degradation. As the potential of PGPR in agriculture grows, we emphasize the importance of the molecular and metabolic characterization of PGP traits as a fundamental step towards their subsequent application in the field as an alternative to chemical fertilizers and supplements.

Published

2023

23. Impact of Climate on Soil Microbes and Plant Health

Author

Pati, Swayamsidha, Mohapatra, Swati, Vishwakarma, Kanchan, Bandekar, Divya, Mishra, Arti, Samantaray, Deviprasad, Varma, Ajit, Series Editor, Choudhary, D. K., editor, and Mishra, Arti, editor

Published

2021

24. Inter-Kingdom Networks of Canola Microbiome Reveal Bradyrhizobium as Keystone Species and Underline the Importance of Bulk Soil in Microbial Studies to Enhance Canola Production.

Author

Floc'h, Jean-Baptiste, Hamel, Chantal, Laterrière, Mario, Tidemann, Breanne, St-Arnaud, Marc, and Hijri, Mohamed

Subjects

*KEYSTONE species, *CANOLA, *CROPPING systems, *BRADYRHIZOBIUM, *PRAIRIES, *CROP diversification, *RHIZOSPHERE

Abstract

The subterranean microbiota of plants is of great importance for plant growth and health, as root-associated microbes can perform crucial ecological functions. As the microbial environment of roots is extremely diverse, identifying keystone microorganisms in plant roots, rhizosphere, and bulk soil is a necessary step towards understanding the network of influence within the microbial community associated with roots and enhancing its beneficial elements. To target these hot spots of microbial interaction, we used inter-kingdom network analysis on the canola growth phase of a long-term cropping system diversification experiment conducted at four locations in the Canadian Prairies. Our aims were to verify whether bacterial and fungal communities of canola roots, rhizosphere, and bulk soil are related and influenced by diversification of the crop rotation system; to determine whether there are common or specific core fungi and bacteria in the roots, rhizosphere, and bulk soil under canola grown in different environments and with different levels of cropping system diversification; and to identify hub taxa at the inter-kingdom level that could play an important ecological role in the microbiota of canola. Our results showed that fungi were influenced by crop diversification, which was not the case on bacteria. We found no core microbiota in canola roots but identified three core fungi in the rhizosphere, one core mycobiota in the bulk soil, and one core bacterium shared by the rhizosphere and bulk soil. We identified two bacterial and one fungal hub taxa in the inter-kingdom networks of the canola rhizosphere, and one bacterial and two fungal hub taxa in the bulk soil. Among these inter-kingdom hub taxa, Bradyrhizobium sp. and Mortierella sp. are particularly influential on the microbial community and the plant. To our knowledge, this is the first inter-kingdom network analysis utilized to identify hot spots of interaction in canola microbial communities. [ABSTRACT FROM AUTHOR]

Published

2022

25. Editorial: Insights in microbial symbioses: 2021

Author

Zhiyong Li and Robert Czajkowski

Subjects

microbial symbioses, rumen microbiota, seed endosymbionts, plant microbiota, animal microbiota, Microbiology, QR1-502

Published

2022

26. Endophytic and rhizospheric microbial communities associated with native and introduced cultivated plant species in Uruguay as sources for plant growth promotion bioinoculant development

Author

Battistoni, Federico, Scavino, Ana Fernández, Ferrando, Lucia, Montañez, Adriana, Pezanni, Fabiana, Taulé, Cecilia, and Vaz-Jauri, Patricia

Published

2023

27. Clay chips and beads capture in situ barley root microbiota and facilitate in vitro long-term preservation of microbial strains.

Author

Abdelfadil, Mohamed R, Taha, Manar H, El-Hadidi, Mohamed, Hamza, Mervat A, Youssef, Hanan H, Khalil, Mohab, Henawy, Ahmed R, Nemr, Rahma A, Elsawey, Hend, Tchuisseu Tchakounte, Gylaine Vanissa, Abbas, Mohamed, Youssef, Gehan H, Witzel, Katja, Shawky, Mohamed Essam, Fayez, Mohamed, Kolb, Steffen, Hegazi, Nabil A, and Ruppel, Silke

Subjects

*CLAY, *KLEBSIELLA oxytoca, *PLANT-microbe relationships, *GENETIC barcoding, *RHIZOSPHERE

Abstract

Capturing the diverse microbiota from healthy and/or stress resilient plants for further preservation and transfer to unproductive and pathogen overloaded soils, might be a tool to restore disturbed plant–microbe interactions. Here, we introduce Aswan Pink Clay as a low-cost technology for capturing and storing the living root microbiota. Clay chips were incorporated into the growth milieu of barley plants and developed under gnotobiotic conditions, to capture and host the rhizospheric microbiota. Afterward, it was tested by both a culture-independent (16S rRNA gene metabarcoding) and -dependent approach. Both methods revealed no significant differences between roots and adjacent clay chips in regard total abundance and structure of the present microbiota. Clay shaped as beads adequately supported the long-term preservation of viable pure isolates of typical rhizospheric microbes, i.e. Bacillus circulans , Klebsiella oxytoca , Sinorhizobium meliloti , and Saccharomyces sp. up to 11 months stored at −20°C, 4°C, and ambient temperature. The used clay chips and beads have the capacity to capture the root microbiota and to long-term preserve pure isolates. Hence, the developed approach is qualified to build on it a comprehensive strategy to transfer and store complex and living environmental microbiota of rhizosphere toward biotechnological application in sustainable plant production and environmental rehabilitation. [ABSTRACT FROM AUTHOR]

Published

2022

28. Genomic, Molecular, and Phenotypic Characterization of Arthrobacter sp. OVS8, an Endophytic Bacterium Isolated from and Contributing to the Bioactive Compound Content of the Essential Oil of the Medicinal Plant Origanum vulgare L.

Author

Giulia Semenzato, Sara Del Duca, Alberto Vassallo, Angela Bechini, Carmela Calonico, Vania Delfino, Fabiola Berti, Francesco Vitali, Stefano Mocali, Angela Frascella, Giovanni Emiliani, and Renato Fani

Subjects

plant microbiota, endophytes, volatile organic compounds, genome, essential oil, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

Medicinal plants play an important role in the discovery of new bioactive compounds with antimicrobial activity, thanks to their pharmacological properties. However, members of their microbiota can also synthesize bioactive molecules. Among these, strains belonging to the genera Arthrobacter are commonly found associated with the plant’s microenvironments, showing plant growth-promoting (PGP) activity and bioremediation properties. However, their role as antimicrobial secondary metabolite producers has not been fully explored. The aim of this work was to characterize the Arthrobacter sp. OVS8 endophytic strain, isolated from the medicinal plant Origanum vulgare L., from molecular and phenotypic viewpoints to evaluate its adaptation and influence on the plant internal microenvironments and its potential as a producer of antibacterial volatile molecules (VOCs). Results obtained from the phenotypic and genomic characterization highlight its ability to produce volatile antimicrobials effective against multidrug-resistant (MDR) human pathogens and its putative PGP role as a producer of siderophores and degrader of organic and inorganic pollutants. The outcomes presented in this work identify Arthrobacter sp. OVS8 as an excellent starting point toward the exploitation of bacterial endophytes as antibiotics sources.

Published

2023

29. Mycobiota of Mexican Maize Landraces with Auxin-Producing Yeasts That Improve Plant Growth and Root Development

Author

Juan Ramos-Garza, José Luis Aguirre-Noyola, Rafael Bustamante-Brito, Lily X. Zelaya-Molina, Jessica Maldonado-Hernández, Aurea Itzel Morales-Estrada, Zoe Resendiz-Venado, Jacqueline Palacios-Olvera, Thania Angeles-Gallegos, Paola Terreros-Moysen, Manuel Cortés-Carvajal, and Esperanza Martínez-Romero

Subjects

biofertilizers, bioinoculants, corn, plant microbiota, root exudates, sustainable agriculture, Botany, QK1-989

Abstract

Compared to agrochemicals, bioinoculants based on plant microbiomes are a sustainable option for increasing crop yields and soil fertility. From the Mexican maize landrace “Raza cónico” (red and blue varieties), we identified yeasts and evaluated in vitro their ability to promote plant growth. Auxin production was detected from yeast isolates and confirmed using Arabidopsis thaliana plants. Inoculation tests were performed on maize, and morphological parameters were measured. Eighty-seven yeast strains were obtained (50 from blue corn and 37 from red corn). These were associated with three families of Ascomycota (Dothideaceae, Debaryomycetaceae, and Metschnikowiaceae) and five families of Basidiomycota (Sporidiobolaceae, Filobasidiaceae, Piskurozymaceae, Tremellaceae, and Rhynchogastremataceae), and, in turn, distributed in 10 genera (Clavispora, Rhodotorula, Papiliotrema, Candida, Suhomyces, Soliccocozyma, Saitozyma Holtermaniella, Naganishia, and Aeurobasidium). We identified strains that solubilized phosphate and produced siderophores, proteases, pectinases, and cellulases but did not produce amylases. Solicoccozyma sp. RY31, C. lusitaniae Y11, R. glutinis Y23, and Naganishia sp. Y52 produced auxins from L-Trp (11.9–52 µg/mL) and root exudates (1.3–22.5 µg/mL). Furthermore, they stimulated the root development of A. thaliana. Inoculation of auxin-producing yeasts caused a 1.5-fold increase in maize plant height, fresh weight, and root length compared to uninoculated controls. Overall, maize landraces harbor plant growth-promoting yeasts and have the potential for use as agricultural biofertilizers.

Published

2023

30. Shared in planta population and transcriptomic features of nonpathogenic members of endophytic phyllosphere microbiota.

Author

Velásquez, André C., Huguet-Tapia, José C., and Sheng Yang He

Subjects

*TRANSCRIPTOMES, *PHYTOPATHOGENIC microorganisms, *ENDOPHYTIC bacteria, *METABOLITES, *PSEUDOMONAS syringae

Abstract

Plants and animals are in constant association with a variety of microbes. Although much is known about how pathogenic and symbiotic microbes interact with plants, less is known about the population dynamics, adaptive traits, and transcriptional features of the vast number of microbes that make up the bulk of the plant microbiota. The majority of microbiota taxa are either commensal, natural mutants of pathogens, or pathogens that encounter strong immune responses due to plant recognition of pathogen effectors. How these "nonpathogenic" microbes interact with plants is poorly understood, especially during long-term, steady-state interactions, which are more reflective of plant-microbiota interactions in nature. In this study, we embarked upon long-term population and in planta transcriptomic studies of commensal endophytic bacteria and compared them to nonpathogenic or effector-triggered immunity-inducing strains of the bacterial pathogen Pseudomonas syringae. Our results led to the discovery of multiplication-death equilibrium as a common basis for the shared long-term static population densities of these bacteria. A comprehensive in planta transcriptomic analysis using multiple time points after inoculation revealed a striking similarity between the transcriptomic features of nonpathogenic P. syringae to that of bacteria in stationary phase in vitro, a metabolically active physiological state in which the production of adaptive secondary metabolites and stress responses are induced. We propose that the long-term population and transcriptomic features of nonpathogenic bacteria captured in this study likely reflect the physiological steady state encountered by the bulk of endophytic microbiota--excluding virulent pathogens--in their life-long interactions with plants in nature. [ABSTRACT FROM AUTHOR]

Published

2022

31. Herbaria preserve plant microbiota responses to environmental changes.

Author

Bianciotto, Valeria, Selosse, Marc-André, Martos, Florent, and Marmeisse, Roland

Subjects

*HERBARIA, *PLANT adaptation, *MICROBIAL communities, *FOSSIL DNA

Abstract

Interaction between plants and their microbiota is a central theme to understand adaptation of plants to their environment. Considering herbaria as repositories of holobionts that preserved traces of ancient plant-associated microbial communities, we propose to explore these historical collections to evaluate the impact of long-lasting global changes on plant–microbiota interactions. [ABSTRACT FROM AUTHOR]

Published

2022

32. Habitat determines the relationships among bacteria, resistance genes and mobile genetic elements in the soil–plant system.

Author

Huang, Ruilin, Ding, Jixian, Guo, Yuwei, Sun, Bo, and Liang, Yuting

Subjects

*MOBILE genetic elements, *SOIL composition, *BACTERIAL genes, *BACTERIA, *MULTIDRUG resistance, *PLANT communities

Abstract

The soil antibiotic resistome is considered to be primarily determined by bacterial community composition. However, the antibiotic resistance of plant microbiota and its association with the soil microbiome in soil–plant systems remain largely unknown. Here, we studied the connections between bacteria and resistance genes (RGs) (mainly antibiotic resistance genes, ARGs) and mobile genetic elements (MGEs) in different cropping systems (rice monoculture, and ryegrass–rice and vetch–rice rotation), growth periods (early, tillering and harvesting stages) and habitats (the soil, rhizoplane and phyllosphere) through high‐throughput qPCR and 16S rRNA sequencing. The results showed that habitat was the major factor affecting the distribution of bacteria, RGs and MGEs, whereas the cropping system had less of an effect. The relative abundances of ARGs, multidrug resistance genes, metal resistance genes and integrons were highest in the soil and lowest in the phyllosphere, as was the α‐diversity of the soil and plant microbiota. Most importantly, we found that bacteria had the strongest associations with RGs and MGEs in the rhizoplane rather than in the soil and phyllosphere, which might be due to the high network interactions among rhizoplane bacteria. These results suggest that the rhizoplane could be a hotspot for exchange of ARGs in the soil–plant system. Highlights: The distributions of bacteria, RGs and MGEs were primarily controlled by habitat.The strongest associations were found between rhizoplane bacteria and RGs and MGEs.Rhizoplane bacteria had the strongest network associations. [ABSTRACT FROM AUTHOR]

Published

2022

33. Ecology and potential functions of plant-associated microbial communities in cold environments.

Author

Marian, Malek, Licciardello, Giorgio, Vicelli, Bianca, Pertot, Ilaria, and Perazzolli, Michele

Subjects

*MICROBIAL communities, *COLD adaptation, *POTENTIAL functions, *PLANT communities, *PLANT growth, COLD regions

Abstract

Complex microbial communities are associated with plants and can improve their resilience under harsh environmental conditions. In particular, plants and their associated communities have developed complex adaptation strategies against cold stress. Although changes in plant-associated microbial community structure have been analysed in different cold regions, scarce information is available on possible common taxonomic and functional features of microbial communities across cold environments. In this review, we discuss recent advances in taxonomic and functional characterization of plant-associated microbial communities in three main cold regions, such as alpine, Arctic and Antarctica environments. Culture-independent and culture-dependent approaches are analysed, in order to highlight the main factors affecting the taxonomic structure of plant-associated communities in cold environments. Moreover, biotechnological applications of plant-associated microorganisms from cold environments are proposed for agriculture, industry and medicine, according to biological functions and cold adaptation strategies of bacteria and fungi. Although further functional studies may improve our knowledge, the existing literature suggest that plants growing in cold environments harbor complex, host-specific and cold-adapted microbial communities, which may play key functional roles in plant growth and survival under cold conditions. [ABSTRACT FROM AUTHOR]

Published

2022

34. Modulation of the Wheat Seed-Borne Bacterial Community by Herbaspirillum seropedicae RAM10 and Its Potential Effects for Tryptophan Metabolism in the Root Endosphere.

Author

Carril, Pablo, Cruz, Joana, di Serio, Claudia, Pieraccini, Giuseppe, Ait Bessai, Sylia, Tenreiro, Rogério, and Cruz, Cristina

Subjects

BACTERIAL communities, MICROBIAL inoculants, TRYPTOPHAN, ENDOPHYTIC bacteria, METABOLISM, COEXISTENCE of species, GRAIN yields

Abstract

Plants and their associated microbiota share ecological and evolutionary traits that are considered to be inseparably woven. Their coexistence foresees the use of similar metabolic pathways, leading to the generation of molecules that can cross-regulate each other's metabolism and ultimately influence plant phenotype. However, the extent to which the microbiota contributes to the overall plant metabolic landscape remains largely unexplored. Due to their early presence in the seed, seed-borne endophytic bacteria can intimately colonize the plant's endosphere while conferring a series of phytobeneficial services to their host. Understanding the dynamics of these endophytic communities is a crucial step toward the formulation of microbial inoculants that can modulate the functionality of the plant-associated microbiota for improved plant fitness. In this work, wheat (Triticum aestivum) roots non-inoculated and inoculated with the bacterium Herbaspirillum seropedicae strain RAM10 were analyzed to explore the impact of inoculant–endophyte–wheat interrelationships on the regulation of tryptophan (Trp) metabolism in the endosphere environment. Root inoculation with H. seropedicae led to phylum-specific changes in the cultivable seed-borne endophytic community. This modulation shifted the metabolic potential of the community in light of its capacity to modulate the levels of key Trp-related metabolites involved in both indole-3-acetic acid (IAA) biosynthesis and in the kynurenine pathway. Our results support a mode of action of H. seropedicae relying on a shift in both the composition and functionality of the seed-borne endophytic community, which may govern important processes such as root growth. We finally provide a conceptual framework illustrating that interactions among roots, inoculants, and seed-borne endophytes are critical to fine-tuning the levels of IAA in the endosphere. Understanding the outcomes of these interactions is a crucial step toward the formulation of microbial inoculants based on their joint action with seed-borne endophytic communities to promote crop growth and health in a sustainable manner. [ABSTRACT FROM AUTHOR]

Published

2021

35. Modulation of the Wheat Seed-Borne Bacterial Community by Herbaspirillum seropedicae RAM10 and Its Potential Effects for Tryptophan Metabolism in the Root Endosphere

Author

Pablo Carril, Joana Cruz, Claudia di Serio, Giuseppe Pieraccini, Sylia Ait Bessai, Rogério Tenreiro, and Cristina Cruz

Subjects

plant microbiota, seed-borne endophytic bacteria, microbial inoculants, root endosphere, tryptophan metabolism, wheat, Microbiology, QR1-502

Abstract

Plants and their associated microbiota share ecological and evolutionary traits that are considered to be inseparably woven. Their coexistence foresees the use of similar metabolic pathways, leading to the generation of molecules that can cross-regulate each other’s metabolism and ultimately influence plant phenotype. However, the extent to which the microbiota contributes to the overall plant metabolic landscape remains largely unexplored. Due to their early presence in the seed, seed-borne endophytic bacteria can intimately colonize the plant’s endosphere while conferring a series of phytobeneficial services to their host. Understanding the dynamics of these endophytic communities is a crucial step toward the formulation of microbial inoculants that can modulate the functionality of the plant-associated microbiota for improved plant fitness. In this work, wheat (Triticum aestivum) roots non-inoculated and inoculated with the bacterium Herbaspirillum seropedicae strain RAM10 were analyzed to explore the impact of inoculant–endophyte–wheat interrelationships on the regulation of tryptophan (Trp) metabolism in the endosphere environment. Root inoculation with H. seropedicae led to phylum-specific changes in the cultivable seed-borne endophytic community. This modulation shifted the metabolic potential of the community in light of its capacity to modulate the levels of key Trp-related metabolites involved in both indole-3-acetic acid (IAA) biosynthesis and in the kynurenine pathway. Our results support a mode of action of H. seropedicae relying on a shift in both the composition and functionality of the seed-borne endophytic community, which may govern important processes such as root growth. We finally provide a conceptual framework illustrating that interactions among roots, inoculants, and seed-borne endophytes are critical to fine-tuning the levels of IAA in the endosphere. Understanding the outcomes of these interactions is a crucial step toward the formulation of microbial inoculants based on their joint action with seed-borne endophytic communities to promote crop growth and health in a sustainable manner.

Published

2021

36. Synthetic plant microbiota challenges in nonmodel species.

Author

Vaccaro, Francesca, Cangioli, Lisa, Mengoni, Alessio, and Fagorzi, Camilla

Subjects

*PLANT productivity, *PLANT species, *CHEMICAL plants, *SPECIES, *PLANT health, *SYSTEMS biology

Abstract

Plant-associated microbiota are becoming central in the development of ways to improve plant productivity and health. However, most research has focussed mainly on a few model plant species. It is essential to translate discoveries to the many nonmodel crops, allowing the design and application of effective synthetic microbiota. [ABSTRACT FROM AUTHOR]

Published

2022

37. Culture Media Based on Leaf Strips/Root Segments Create Compatible Host/Organ Setup for in vitro Cultivation of Plant Microbiota

Author

Rahma A. Nemr, Sascha Patz, Saad M. Abdelwakeel, Mohab Khalil, Ali Ben Djadid, Mohamed R. Abdelfadeel, Ahmed T. Morsi, Hanan A. Goda, Hanan H. Youssef, Mervat Hamza, Mohamed Abbas, Mohamed Fayez, Kassem F. El-Sahhar, Matthias Becker, Silke Ruppel, and Nabil A. Hegazi

Subjects

Plant microbiota, In situ similis cultivation, leaf strips/root segments culture media, plant organ compatible cultivation, MPN enrichment of plant microbiota, PCR-DGGE, Nutrition. Foods and food supply, TX341-641, Food processing and manufacture, TP368-456

Abstract

Plant microbiota have co-evolved with their associated plants in the entire holobiont, and their assemblages support diversity and productivity on our planet. Of importance is in vitro cultivation and identification of their hub taxa for possible core microbiome modification. Recently, we introduced the in situ-similis culturing strategy, based on the use of plant leaves as a platform for in vitro growth of plant microbiota. Here, the strategy is further extended by exploring plant organ compatible cultivation of plant microbiota when grown on corresponding leaf/root-based culture media. Pooling the advantages of MPN enrichment methodology together with natural plant-only-based culture media, the introduced method efficiently constructed a nutritional milieu governed by vegan nutrients of plant origin, i.e., leaf strips/root segments, immersed in plain semi-solid water agar. MPN estimates exceeded log 7.0 and 4.0 g−1 of endo-rhizosphere and endo-phyllosphere, respectively, of maize and sunflower; being proportionate to those obtained for standard culture media. With sunflower, PCR-DGGE analyses indicated divergence in community composition of cultivable endophytes primarily attributed to culture media, signaling a certain degree of plant organ affinity/compatibility. Based on 16S rRNA gene sequencing of bacterial isolates, 20 genera comprising 32 potential species were enriched; belonged to Bacteroidetes, Firmicutes, and Alpha-/Gammaproteobacteria. The described cultivation strategy furnished diversified nutritive platform in terms of homologous/heterologous plant organ-based medium and ambient/limited oxygenic cultivation procedure. Duly, cultivability extended to > 8 genera: Bosea, Brevundimonas, Chitinophaga, Pseudoxanthomonas, Sphingobacterium Caulobacter, Scandinavium, and Starkeya; the latter three genera were not yet reported for Sunflower, and possible unknown species or even one new putative genus. Thus, both potential members of the major microbiome and rare isolates of satellite microbiomes can be isolated using the presented method. It is a feasible addition to traditional cultivation methods to explore new potential resources of PGPB for future biotechnological applications.

Published

2021

38. Inter-Kingdom Networks of Canola Microbiome Reveal Bradyrhizobium as Keystone Species and Underline the Importance of Bulk Soil in Microbial Studies to Enhance Canola Production

Author

Floc’h, Jean-Baptiste, Hamel, Chantal, Laterrière, Mario, Tidemann, Breanne, St-Arnaud, Marc, and Hijri, Mohamed

Published

2022

39. Impact of Next-Generation Sequencing Technology in Plant–Microbe Interaction Study

Author

Kumari, Archana, Sumer, Samson, Jalan, Bharati, Nongbri, Pyniarlang Lyngdoh, Laskar, Mostaque Ahmed, Kalia, Vipin Chandra, editor, and Kumar, Prasun, editor

Published

2017

40. Dissection of plant microbiota and plant-microbiome interactions.

Author

Choi, Kihyuck, Khan, Raees, and Lee, Seon-Woo

Abstract

Plants rooted in soil have intimate associations with a diverse array of soil microorganisms. While the microbial diversity of soil is enormous, the predominant bacterial phyla associated with plants include Actinobacteria, Bacteroidetes, Firmicutes, Proteobacteria, and Verrucomicrobia. Plants supply nutrient niches for microbes, and microbes support plant functions such as plant growth, development, and stress tolerance. The interdependent interaction between the host plant and its microbes sculpts the plant microbiota. Plant and microbiome interactions are a good model system for understanding the traits in eukaryotic organisms from a holobiont perspective. The holobiont concept of plants, as a consequence of co-evolution of plant host and microbiota, treats plants as a discrete ecological unit assembled with their microbiota. Dissection of plant-microbiome interactions is highly complicated; however, some reductionist approaches are useful, such as the synthetic community method in a gnotobiotic system. Deciphering the interactions between plant and microbiome by this reductionist approach could lead to better elucidation of the functions of microbiota in plants. In addition, analysis of microbial communities' interactions would further enhance our understanding of coordinated plant microbiota functions. Ultimately, better understanding of plantmicrobiome interactions could be translated to improvements in plant productivity. [ABSTRACT FROM AUTHOR]

Published

2021

41. Seed-Derived Microbial Colonization of Wild Emmer and Domesticated Bread Wheat (Triticum dicoccoides and T. aestivum) Seedlings Shows Pronounced Differences in Overall Diversity and Composition

Author

Ezgi Özkurt, M. Amine Hassani, Uğur Sesiz, Sven Künzel, Tal Dagan, Hakan Özkan, and Eva H. Stukenbrock

Subjects

seed-associated microbiome, plant domestication, plant breeding, microbiota assembly, agriculture, plant microbiota, Microbiology, QR1-502

Abstract

ABSTRACT The composition of the plant microbiota may be altered by ecological and evolutionary changes in the host population. Seed-associated microbiota, expected to be largely vertically transferred, have the potential to coadapt with their host over generations. Strong directional selection and changes in the genetic composition of plants during domestication and cultivation may have impacted the assembly and transmission of seed-associated microbiota. Nonetheless, the effect of plant speciation and domestication on the composition of these microbes is poorly understood. Here, we have investigated the composition of bacteria and fungi associated with the wild emmer wheat (Triticum dicoccoides) and domesticated bread wheat (Triticum aestivum). We show that vertically transmitted bacteria, but not fungi, of domesticated bread wheat species T. aestivum are less diverse and more inconsistent among individual plants compared to those of the wild emmer wheat species T. dicoccoides. We propagated wheat seeds under sterile conditions to characterize the colonization of seedlings by seed-associated microbes. Hereby, we show markedly different community compositions and diversities of leaf and root colonizers of the domesticated bread wheat compared to the wild emmer wheat. By propagating the wild emmer wheat and domesticated bread wheat in two different soils, we furthermore reveal a small effect of plant genotype on microbiota assembly. Our results suggest that domestication and prolonged breeding have impacted the vertically transferred bacteria, but only to a lesser extent have affected the soil-derived microbiota of bread wheat. IMPORTANCE Genetic and physiological changes associated with plant domestication have been studied for many crop species. Still little is known about the impact of domestication on the plant-associated microbiota. In this study, we analyze the seed-associated and soil-derived bacterial and fungal microbiota of domesticated bread wheat and wild emmer wheat. We show a significant difference in the seed-associated, but not soil-derived, bacterial communities of the wheat species. Interestingly, we find less pronounced effects on the fungal communities. Overall, this study provides novel insight into the diversity of vertically transmitted microbiota of wheat and thereby contributes to our understanding of wheat as a “metaorganism.” Insight into the wheat microbiota is of fundamental importance for the development of improved crops.

Published

2020

42. Distinct microbiota assembly and functional patterns in disease-resistant and susceptible varieties of tobacco.

Author

Yang L, Guo Y, Yang H, Li S, Zhang Y, Gao C, Wei T, and Hao L

Abstract

The plant microbiota is believed to be an accessory genome that extends plant functions, forming holobionts together with the host plant. Plant disease resistance, therefore, is inextricably linked with plant microbiota, which play important roles in plant growth and health. To explore the relationship between plant microbiota and disease resistance, we investigated the tobacco microbiome of two varieties with contrasting disease-resistance levels to bacterial wilt and black shank diseases. Comparative microbiome analysis indicated that the resistant variety assembled a distinct microbiota with higher network complexity and diversity. While Pseudomonas and Ensifer, which contain biocontrol and beneficial members, were enriched in the rhizosphere of the resistant variety, Ralstonia , a genus including the known causative pathogen, was enriched in the susceptible variety. Metagenome sequencing revealed that biocontrol functions, such as hydrogen cyanide synthase, pyochelin biosynthesis, and arthrofactin-type cyclic lipopeptide synthetase, were more abundant in the resistant variety. Further analysis indicated that contigs encoding the corresponding genes were mostly assigned to Pseudomonas . Among all the metagenome-assembled genomes, positive selection was suggested in the genome assigned to Pseudomonas only in the rhizosphere of the resistant variety. The search of biosynthetic gene clusters in the Pseudomonas genome revealed a non-ribosomal peptide synthetase, the compound of which was brabantamide A, with known antimicrobial activity. Collectively, our study suggests that the plant microbiota might be involved in microbe-mediated disease resistance. Particularly, our results highlight Pseudomonas in the rhizosphere of the disease-resistant variety as a promising biocontrol candidate. Our study may facilitate further screening of bacterial isolates and the targeted design of microbial communities., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Yang, Guo, Yang, Li, Zhang, Gao, Wei and Hao.)

Published

2024

43. A Landscape of Opportunities for Microbial Ecology Research

Author

Cendrine Mony, Philippe Vandenkoornhuyse, Brendan J. M. Bohannan, Kabir Peay, and Mathew A Leibold

Subjects

landscape ecology, metacommunity, microbial assembly-rules, dispersal, plant microbiota, human microbiota, Microbiology, QR1-502

Abstract

Microbes encompass tremendous biodiversity, provide support to all living forms, including humans, and play an important role in many ecosystem services. The rules that govern microorganism community assembly are increasingly revealed due to key advances in molecular and analytical methods but their understanding remain a key challenge in microbial ecology. The existence of biogeographic patterns within microbial communities has been established and explained in relation to landscape-scale processes, including selection, drift, dispersal and mutation. The effect of habitat patchiness on microorganisms’ assembly rules remains though incompletely understood. Here, we review how landscape ecology principles can be adapted to explore new perspectives on the mechanisms that determine microbial community structure. To provide a general overview, we characterize microbial landscapes, the spatial and temporal scales of the mechanisms that drive microbial assembly and the feedback between microorganisms and landscape structure. We provide evidence for the effects of landscape heterogeneity, landscape fragmentation and landscape dynamics on microbial community structure, and show that predictions made for macro-organisms at least partly also apply to microorganisms. We explain why emerging metacommunity approaches in microbial ecology should include explicit characterization of landscape structure in their development and interpretation. We also explain how biotic interactions, such as competition, prey-predator or mutualist relations may influence the microbial landscape and may be involved in the above-mentioned feedback process. However, we argue that the application of landscape ecology to the microbial world cannot simply involve transposing existing theoretical frameworks. This is due to the particularity of these organisms, in terms of size, generation time, and for some of them, tight interaction with hosts. These characteristics imply dealing with unusual and dependent space and time scales of effect. Evolutionary processes have also a strong importance in microorganisms’ response to their landscapes. Lastly, microorganisms’ activity and distribution induce feedback effects on the landscape that have to be taken into account. The transposition of the landscape ecology framework to microorganisms provides many challenging research directions for microbial ecology.

Published

2020

44. Desert Microbes for Boosting Sustainable Agriculture in Extreme Environments

Author

Wiam Alsharif, Maged M. Saad, and Heribert Hirt

Subjects

PGPR, plant microbiota, desert agriculture, world hunger, desert microbes, DARWIN21, Microbiology, QR1-502

Abstract

A large portion of the earth’s surface consists of arid, semi-arid and hyper-arid lands. Life in these regions is profoundly challenged by harsh environmental conditions of water limitation, high levels of solar radiation and temperature fluctuations, along with soil salinity and nutrient deficiency, which have serious consequences on plant growth and survival. In recent years, plants that grow in such extreme environments and their naturally associated beneficial microbes have attracted increased interest. The rhizosphere, rhizosheath, endosphere, and phyllosphere of desert plants display a perfect niche for isolating novel microbes. They are well adapted to extreme environments and offer an unexploited reservoir for bio-fertilizers and bio-control agents against a wide range of abiotic and biotic stresses that endanger diverse agricultural ecosystems. Their properties can be used to improve soil fertility, increase plant tolerance to various environmental stresses and crop productivity as well as benefit human health and provide enough food for a growing human population in an environment-friendly manner. Several initiatives were launched to discover the possibility of using beneficial microbes. In this review, we will be describing the efforts to explore the bacterial diversity associated with desert plants in the arid, semi-arid, and hyper-arid regions, highlighting the latest discoveries and applications of plant growth promoting bacteria from the most studied deserts around the world.

Published

2020

45. 'In situ similis' Culturing of Plant Microbiota: A Novel Simulated Environmental Method Based on Plant Leaf Blades as Nutritional Pads

Author

Rahma A. Nemr, Mohab Khalil, Mohamed S. Sarhan, Mohamed Abbas, Hend Elsawey, Hanan H. Youssef, Mervat A. Hamza, Ahmed T. Morsi, Mahmoud El-Tahan, Mohamed Fayez, Sascha Patz, Katja Witzel, Silke Ruppel, Kassem F. El-Sahhar, and Nabil A. Hegazi

Subjects

plant microbiota, plant-based culture media, endophyllosphere, endorhizosphere, MALDI-TOF-MS, culturomics, Microbiology, QR1-502

Abstract

High-throughput cultivation methods have recently been developed to accelerate the recovery of microorganisms reluctant to cultivation. They simulate in situ environmental conditions for the isolation of environmental microbiota through the exchange of growth substrates during cultivation. Here, we introduce leaf-based culture media adopting the concept of the plant being the master architect of the composition of its microbial community. Pre-physical treatments of sunflower plant leaves, namely punching, freezing, and/or autoclavation, allowed the diffusion of electrolytes and other nutrients to configure the leaf surface as a natural pad, i.e., creating an “in situ similis” environment suitable for the growth of rarely isolated microbiota. We used surface inoculation and membrane-filtration methods to assess the culturability of endophytic bacteria from the sunflower phyllosphere and rhizosphere. Both methods supported excellent colony-forming unit (CFU) development when compared to standard R2A medium, with a special affinity to support better growth of epiphytic and endophytic populations of the phyllosphere compared with the rhizosphere. A 16S rRNA gene analysis of >122 representative isolates indicated the cultivation of a diverse set of microorganisms by application of the new methods. It indicated the predominance of 13 genera of >30 potential species, belonging to Firmicutes, Proteobacteria, and Actinobacteria, and especially genera not commonly reported for sunflower, e.g., Rhizobium, Aureimonas, Sphingomonas, Paracoccus, Stenotrophomonas, Pantoea, Kosakonia, and Erwinia. The strategy successfully extended diversity and richness in the endophyllosphere compared to the endorhizosphere, while CFUs grown on the standard R2A medium mainly pertain to Firmicutes, especially Bacillus spp. MALDI-TOF MS analysis clustered the isolates according to their niche and potential functions, where the majority of isolates of the endorhizosphere were clustered away from those of the endophyllosphere. Isolates identified as Gammaproteobacteria and Alphaproteobacteria were distinguishably sub-clustered, which was in contrast to the heterogeneous isolates of Firmicutes (Bacillus spp.). In conclusion, leaf in situ similis cultivation is an effective strategy to support the future application of culturomics of plant microbiota. This is an effort to access novel isolates that are more adapted and competitive in their natural environments, especially those subjected to abiotic stresses like those prevailing in arid/semi-arid zones, and, consequently, to support the application of agro-biotechnologies, among other technologies, to improving agriculture in such zones.

Published

2020

46. Influence of Plant Fraction, Soil, and Plant Species on Microbiota: a Multikingdom Comparison

Author

Andrzej Tkacz, Eloïne Bestion, Zhiyan Bo, Marion Hortala, and Philip S. Poole

Subjects

microbial colonization, plant microbiota, rhizosphere, roots, phyllosphere, colonization dynamics, Microbiology, QR1-502

Abstract

ABSTRACT Plant roots influence the soil microbiota via physical interaction, secretion, and plant immunity. However, it is unclear whether the root fraction or soil is more important in determining the structure of the prokaryotic or eukaryotic community and whether this varies between plant species. Furthermore, the leaf (phyllosphere) and root microbiotas have a large overlap; however, it is unclear whether this results from colonization of the phyllosphere by the root microbiota. Soil, rhizosphere, rhizoplane, and root endosphere prokaryote-, eukaryote-, and fungus-specific microbiotas of four plant species were analyzed with high-throughput sequencing. The strengths of factors controlling microbiota structure were determined using permutational multivariate analysis of variance (PERMANOVA) statistics. The origin of the phyllosphere microbiota was investigated using a soil swap experiment. Global microbial kingdom analysis conducted simultaneously on multiple plants shows that cereals, legumes, and Brassicaceae establish similar prokaryotic and similar eukaryotic communities inside and on the root surface. While the bacterial microbiota is recruited from the surrounding soil, its profile is influenced by the root itself more so than by soil or plant species. However, in contrast, the fungal microbiota is most strongly influenced by soil. This was observed in two different soils and for all plant species examined. Microbiota structure is established within 2 weeks of plant growth in soil and remains stable thereafter. A reciprocal soil swap experiment shows that the phyllosphere is colonized from the soil in which the plant is grown. IMPORTANCE Global microbial kingdom analysis conducted simultaneously on multiple plants shows that cereals, legumes, and Brassicaceae establish similar prokaryotic and similar eukaryotic communities inside and on the root surface. While the bacterial microbiota is recruited from the surrounding soil, its profile is influenced by the root fraction more so than by soil or plant species. However, in contrast, the fungal microbiota is most strongly influenced by soil. This was observed in two different soils and for all plant species examined, indicating conserved adaptation of microbial communities to plants. Microbiota structure is established within 2 weeks of plant growth in soil and remains stable thereafter. We observed a remarkable similarity in the structure of a plant’s phyllosphere and root microbiotas and show by reciprocal soil swap experiments that both fractions are colonized from the soil in which the plant is grown. Thus, the phyllosphere is continuously colonized by the soil microbiota.

Published

2020

47. Microbial interactions within the plant holobiont

Author

M. Amine Hassani, Paloma Durán, and Stéphane Hacquard

Subjects

Microbe-microbe interactions, Holobiont, Plant microbiota, Competition, Cooperation, Microbial ecology, QR100-130

Abstract

Abstract Since the colonization of land by ancestral plant lineages 450 million years ago, plants and their associated microbes have been interacting with each other, forming an assemblage of species that is often referred to as a “holobiont.” Selective pressure acting on holobiont components has likely shaped plant-associated microbial communities and selected for host-adapted microorganisms that impact plant fitness. However, the high microbial densities detected on plant tissues, together with the fast generation time of microbes and their more ancient origin compared to their host, suggest that microbe-microbe interactions are also important selective forces sculpting complex microbial assemblages in the phyllosphere, rhizosphere, and plant endosphere compartments. Reductionist approaches conducted under laboratory conditions have been critical to decipher the strategies used by specific microbes to cooperate and compete within or outside plant tissues. Nonetheless, our understanding of these microbial interactions in shaping more complex plant-associated microbial communities, along with their relevance for host health in a more natural context, remains sparse. Using examples obtained from reductionist and community-level approaches, we discuss the fundamental role of microbe-microbe interactions (prokaryotes and micro-eukaryotes) for microbial community structure and plant health. We provide a conceptual framework illustrating that interactions among microbiota members are critical for the establishment and the maintenance of host-microbial homeostasis.

Published

2018

48. A Landscape of Opportunities for Microbial Ecology Research.

Author

Mony, Cendrine, Vandenkoornhuyse, Philippe, Bohannan, Brendan J. M., Peay, Kabir, and Leibold, Mathew A

Subjects

MICROBIAL ecology, LANDSCAPE ecology, FRAGMENTED landscapes, PREDATION, MICROBIAL communities

Abstract

Microbes encompass tremendous biodiversity, provide support to all living forms, including humans, and play an important role in many ecosystem services. The rules that govern microorganism community assembly are increasingly revealed due to key advances in molecular and analytical methods but their understanding remain a key challenge in microbial ecology. The existence of biogeographic patterns within microbial communities has been established and explained in relation to landscape-scale processes, including selection, drift, dispersal and mutation. The effect of habitat patchiness on microorganisms' assembly rules remains though incompletely understood. Here, we review how landscape ecology principles can be adapted to explore new perspectives on the mechanisms that determine microbial community structure. To provide a general overview, we characterize microbial landscapes, the spatial and temporal scales of the mechanisms that drive microbial assembly and the feedback between microorganisms and landscape structure. We provide evidence for the effects of landscape heterogeneity, landscape fragmentation and landscape dynamics on microbial community structure, and show that predictions made for macro-organisms at least partly also apply to microorganisms. We explain why emerging metacommunity approaches in microbial ecology should include explicit characterization of landscape structure in their development and interpretation. We also explain how biotic interactions, such as competition, prey-predator or mutualist relations may influence the microbial landscape and may be involved in the above-mentioned feedback process. However, we argue that the application of landscape ecology to the microbial world cannot simply involve transposing existing theoretical frameworks. This is due to the particularity of these organisms, in terms of size, generation time, and for some of them, tight interaction with hosts. These characteristics imply dealing with unusual and dependent space and time scales of effect. Evolutionary processes have also a strong importance in microorganisms' response to their landscapes. Lastly, microorganisms' activity and distribution induce feedback effects on the landscape that have to be taken into account. The transposition of the landscape ecology framework to microorganisms provides many challenging research directions for microbial ecology. [ABSTRACT FROM AUTHOR]

Published

2020

49. Desert Microbes for Boosting Sustainable Agriculture in Extreme Environments.

Author

Alsharif, Wiam, Saad, Maged M., and Hirt, Heribert

Subjects

EXTREME environments, SURFACE of the earth, SUSTAINABLE agriculture, DESERT plants, POPULATION, SOIL salinity, MICROORGANISMS, ABIOTIC stress

Abstract

A large portion of the earth's surface consists of arid, semi-arid and hyper-arid lands. Life in these regions is profoundly challenged by harsh environmental conditions of water limitation, high levels of solar radiation and temperature fluctuations, along with soil salinity and nutrient deficiency, which have serious consequences on plant growth and survival. In recent years, plants that grow in such extreme environments and their naturally associated beneficial microbes have attracted increased interest. The rhizosphere, rhizosheath, endosphere, and phyllosphere of desert plants display a perfect niche for isolating novel microbes. They are well adapted to extreme environments and offer an unexploited reservoir for bio-fertilizers and bio-control agents against a wide range of abiotic and biotic stresses that endanger diverse agricultural ecosystems. Their properties can be used to improve soil fertility, increase plant tolerance to various environmental stresses and crop productivity as well as benefit human health and provide enough food for a growing human population in an environment-friendly manner. Several initiatives were launched to discover the possibility of using beneficial microbes. In this review, we will be describing the efforts to explore the bacterial diversity associated with desert plants in the arid, semi-arid, and hyper-arid regions, highlighting the latest discoveries and applications of plant growth promoting bacteria from the most studied deserts around the world. [ABSTRACT FROM AUTHOR]

Published

2020

50. Analogous wheat root rhizosphere microbial successions in field and greenhouse trials in the presence of biocontrol agents Paenibacillus peoriae SP9 and Streptomyces fulvissimus FU14.

Author

Araujo, Ricardo, Dunlap, Christopher, and Franco, Christopher M.M.

Subjects

*BIOLOGICAL pest control agents, *RHIZOSPHERE, *GREENHOUSE plants, *PAENIBACILLUS, *GREENHOUSES, *PLANT roots, *STREPTOMYCES

Abstract

Two Pythium‐infested soils were used to compare the wheat root and rhizosphere soil microbial communities from plants grown in the field or in greenhouse trials and their stability in the presence of biocontrol agents. Bacteria showed the highest diversity at early stages of wheat growth in both field and greenhouse trials, while fungal diversity increased later on, at 12 weeks of the crop cycle. The microbial communities were stable in roots and rhizosphere samples across both soil types used in this study. Such stability was also observed irrespective of the cultivation system (field or greenhouse) or addition of biocontrol coatings to wheat seeds to control Pythium disease (in this study soil infected with Pythium sp. clade F was tested). In greenhouse plant roots, Archaeorhizomyces, Debaryomyces, Delftia, and unclassified Pseudeurotiaceae were significantly reduced when compared to plant roots obtained from the field trials. Some operational taxonomic units (OTUs) represented genetic determinants clearly transmitted vertically by seed endophytes (specific OTUs were found in plant roots) and the plant microbiota was enriched over time by OTUs from the rhizosphere soil. This study provided key information regarding the microbial communities associated with wheat roots and rhizosphere soils at different stages of plant growth and the role that Paenibacillus and Streptomyces strains play as biocontrol agents in supporting plant growth in infested soils. [ABSTRACT FROM AUTHOR]

Published

2020