Your search keyword '"PLANT-microbe relationships"' showing total 1,985 results

1. The scientific landscape of phytoremediation of tailings: a bibliometric and scientometric analysis.

Author

Keith, Brian F., Lam, Elizabeth J., Montofré, Ítalo L., Zetola, Vicente, and Bech, Jaume

Subjects

*MINE waste, *ENVIRONMENTAL sciences, *QUANTITATIVE research, *BIBLIOMETRICS, *PLANT-microbe relationships

Abstract

This article seeks to evaluate the scientific landscape of the phytoremediation of mine tailings through a series of bibliometric and scientometric techniques. Phytoremediation has emerged as a sustainable approach to remediate metal-contaminated mine waste areas. A scientometric analysis of 913 publications indexed in Web of Science from 1999 to 2023 was conducted using CiteSpace. The results reveal an expanding, interdisciplinary field with environmental sciences as the core category. Keyword analysis of 561 nodes and 2,825 links shows a focus on plant-metal interactions, microbial partnerships, bioavailability, and field validation. Co-citation analysis of 1,032 nodes and 2,944 links identifies seminal works on native species, plant-microbe interactions, and amendments. Temporal mapping of 15 co-citation clusters indicates a progression from early risk assessments and native plant inquiries to integrated biological systems, economic feasibility, and sustainability considerations. Recent trends emphasize multidimensional factors influencing adoption, such as plant-soil-microbe interactions, organic amendments, and field-scale performance evaluation. The findings demonstrate an intensifying translation of phytoremediation from scientific novelty to engineering practice. This quantitative and qualitative analysis of research trends aids in understanding the development of phytoremediation for mine tailings. The results provide valuable insights for researchers and practitioners in this evolving field. [ABSTRACT FROM AUTHOR]

Published

2024

2. EcoFAB 3.0: a sterile system for studying sorghum that replicates previous field and greenhouse observations.

Author

Gupta, Kshitiz, Yang Tian, Eudes, Aymerick, Scheller, Henrik V., Singh, Anup K., Adams, Paul D., Andeer, Peter F., and Northen, Trent R.

Subjects

SUSTAINABILITY, SUSTAINABLE agriculture, SORGHUM farming, PLANT-microbe relationships, SORGHUM

Abstract

Introduction: Studying plant-microbe interactions is one of the key elements in understanding the path to sustainable agricultural practices. These interactions play a crucial role in ensuring survival of healthy plants, soil and microbial communities. Many platforms have been developed over the years to isolate these highly complex interactions however, these are designed for small model plants. This creates a need for complementary devices for larger plants, such as sorghum. Methods: This work introduces a novel platform, EcoFAB 3.0, which is designed to enable studying bioenergy plants such as sorghum for up to 4 weeks in a controlled sterile environment. Several other advantages of this platform such as dark root chambers and user-friendly assembly are also discussed in this work. Results and discussion: EcoFAB 3.0 was found to replicate previous greenhouse and field observations when comparing an engineered sorghum line overproducing 4-hydroxybenzoic acid (4-HBA) and wildtype (variety BTx430). Consistent with greenhouse and field observations, it was found that the engineered line of sorghum grown in EcoFAB 3.0 had a higher 4-HBA content and a lower dry biomass. [ABSTRACT FROM AUTHOR]

Published

2024

3. Mapping, Distribution, Function, and High-Throughput Methodological Strategies for Soil Microbial Communities in the Agroecosystem in the Last Decades.

Author

Chandrakasan, Gobinath, Gastauer, Markus, and Marcus, Gabriel

Subjects

ECOLOGICAL disturbances, SUSTAINABILITY, SOIL microbiology, AGRICULTURAL ecology, PLANT-microbe relationships

Abstract

The intricate interplay between SMCs and agroecosystems has garnered substantial attention in recent decades due to its profound implications for agricultural productivity, ecosystem sustainability, and environmental health. Understanding the distribution of SMCs is complemented by investigations into their functional roles within agroecosystems. Soil microbes play pivotal roles in nutrient cycling, organic matter decomposition, disease suppression, and plant-microbe interactions, profoundly influencing soil fertility, crop productivity, and ecosystem resilience. Elucidating the functional diversity and metabolic potential of SMCs is crucial for designing sustainable agricultural practices that harness the beneficial functions of soil microbes while minimizing detrimental impacts on ecosystem services. Various molecular techniques, such as next-generation sequencing and high-throughput sequencing, have facilitated the elucidation of microbial community structures and dynamics at different spatial scales. These efforts have revealed the influence of factors such as soil type, land management practices, climate, and land use change on microbial community composition and diversity. Advances in high-throughput methodological strategies have revolutionized our ability to characterize SMCs comprehensively and efficiently. These include amplicon sequencing, metagenomics, metatranscriptomics, and metaproteomics, which provide insights into microbial taxonomic composition, functional potential, gene expression, and protein profiles. The integration of multiomics approaches allows for a more holistic understanding of the complex interactions within SMCs and their responses to environmental perturbations. In conclusion, this review highlights the significant progress made in mapping, understanding the distribution, elucidating the functions, and employing high-throughput methodological strategies to study SMCs in agroecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

4. Profiling sorghum-microbe interactions with a specialized photoaffinity probe identifies key sorgoleone binders in Acinetobacter pittii.

Author

Van Fossen, Elise M., Kroll, Jared O., Anderson, Lindsey N., McNaughton, Andrew D., Herrera, Daisy, Yasuhiro Oda, Wilson, Andrew J., Nelson, William C., Kumar, Neeraj, Frank, Andrew R., Elmore, Joshua R., Handakumbura, Pubudu, Lin, Vivian S., and Egbert, Robert G.

Subjects

*EXUDATION (Botany), *PHOTOAFFINITY labeling, *PLANT exudates, *CHEMICAL models, *PLANT-microbe relationships

Abstract

Interactions between plants and soil microbial communities that benefit plant growth and enhance nutrient acquisition are driven by the selective release of metabolites from plant roots, or root exudation. To investigate these plant-microbe interactions, we developed a photoaffinity probe based on sorgoleone (sorgoleone diazirine alkyne for photoaffinity labeling, SoDA-PAL), a hydrophobic secondary metabolite and allelochemical produced in Sorghum bicolor root exudates. We applied SoDA-PAL to the identification of sorgoleone-binding proteins in Acinetobacter pittii SO1, a potential plant growth-promoting microbe isolated from sorghum rhizosphere soil. Competitive photoaffinity labeling of A. pittii whole cell lysates with SoDA-PAL identified 137 statistically enriched proteins, including putative transporters, transcriptional regulators, and a subset of proteins with predicted enzymatic functions. We performed computational protein modeling and docking with sorgoleone to prioritize candidates for experimental validation and then confirmed binding of sorgoleone to four of these proteins in vitro: the a/ß fold hydrolase SrgB (OH685_09420), a fumarylacetoacetase (OH685_02300), a lysophospholipase (OH685_14215), and an unannotated hypothetical protein (OH685_18625). Our application of this specialized sorgoleone-based probe coupled with structural bioinformatics streamlines the identification of microbial proteins involved in metabolite recognition, metabolism, and toxicity, widening our understanding of the range of cellular pathways that can be affected by a plant secondary metabolite. IMPORTANCE Here, we demonstrate that a photoaffinity-based chemical probe modeled after sorgoleone, an important secondary metabolite released by sorghum roots, can be used to identify microbial proteins that directly interact with sorgoleone. We applied this probe to the sorghum-associated bacterium Acinetobacter pittii and showed that probe labeling is dose-dependent and sensitive to competition with purified sorgoleone. Coupling the probe with proteomics and computational analysis facilitated the identification of putative sorgoleone binders, including a protein implicated in a conserved pathway essential for sorgoleone catabolism. We anticipate that discoveries seeded by this workflow will expand our understanding of the molecular mechanisms by which specific metabolites in root exudates shape the sorghum rhizosphere microbiome. [ABSTRACT FROM AUTHOR]

Published

2024

5. Phosphorus availability influences disease-suppressive soil microbiome through plant-microbe interactions.

Author

Cao, Yifan, Shen, Zongzhuan, Zhang, Na, Deng, Xuhui, Thomashow, Linda S., Lidbury, Ian, Liu, Hongjun, Li, Rong, Shen, Qirong, and Kowalchuk, George A.

Subjects

BACTERIAL wilt diseases, VESICULAR-arbuscular mycorrhizas, PLANT-microbe relationships, SPECIFIC gravity, RALSTONIA solanacearum

Abstract

Background: Soil nutrient status and soil-borne diseases are pivotal factors impacting modern intensive agricultural production. The interplay among plants, soil microbiome, and nutrient regimes in agroecosystems is essential for developing effective disease management. However, the influence of nutrient availability on soil-borne disease suppression and associated plant-microbe interactions remains to be fully explored. T his study aims to elucidate the mechanistic understanding of nutrient impacts on disease suppression, using phosphorous as a target nutrient. Results: A 6-year field trial involving monocropping of tomatoes with varied fertilizer manipulations demonstrated that phosphorus availability is a key factor driving the control of bacterial wilt disease caused by Ralstonia solanacearum. Subsequent greenhouse experiments were then conducted to delve into the underlying mechanisms of this phenomenon by varying phosphorus availability for tomatoes challenged with the pathogen. Results showed that the alleviation of phosphorus stress promoted the disease-suppressive capacity of the rhizosphere microbiome, but not that of the bulk soil microbiome. This appears to be an extension of the plant trade-off between investment in disease defense mechanisms versus phosphorus acquisition. Adequate phosphorus levels were associated with elevated secretion of root metabolites such as L-tryptophan, methoxyindoleacetic acid, O-phosphorylethanolamine, or mangiferin, increasing the relative density of microbial biocontrol populations such as Chryseobacterium in the rhizosphere. On the other hand, phosphorus deficiency triggered an alternate defense strategy, via root metabolites like blumenol A or quercetin to form symbiosis with arbuscular mycorrhizal fungi, which facilitated phosphorus acquisition as well. Conclusion: Overall, our study shows how phosphorus availability can influence the disease suppression capability of the soil microbiome through plant-microbial interactions. These findings highlight the importance of optimizing nutrient regimes to enhance disease suppression, facilitating targeted crop management and boosting agricultural productivity. 5_PfxzZNKyxgT3zPqUmUdg Video Abstract [ABSTRACT FROM AUTHOR]

Published

2024

6. Role of bacterial pathogens in microbial ecological networks in hydroponic plants.

Author

Wenyi Liu, Zhihua Zhang, Bin Zhang, Yi Zhu, Chongwen Zhu, Chaoyong Chen, Fangxu Zhang, Feng Liu, Jixiang Ai, Wei Wang, Wuyuan Kong, Haoming Xiang, Weifeng Wang, Daoxin Gong, Delong Meng, and Li Zhu

Subjects

PLANT-microbe relationships, NUCLEOTIDE sequencing, PLANT communities, PLANT growth, ECOLOGICAL niche

Abstract

Plant-associated microbial communities are crucial for plant growth and health. However, assembly mechanisms of microbial communities and microbial interaction patterns remain elusive across vary degrees of pathogen-induced diseases. By using 16S rRNA high-throughput sequencing technology, we investigated the impact of wildfire disease on the microbial composition and interaction network in plant three different compartments. The results showed that pathogen infection significantly affect the phyllosphere and rhizosphere microbial community. We found that the primary sources of microbial communities in healthy and mildly infected plants were from the phyllosphere and hydroponic solution community. Mutual exchanges between phyllosphere and rhizosphere communities were observed, but microbial species migration from the leaf to the root was rarely observed in severely infected plants. Moreover, wildfire disease reduced the diversity and network complexity of plant microbial communities. Interactions among pathogenic bacterial members suggested that Caulobacter and Boseamightbecrucial "pathogenantagonists" inhibiting the spreadofwildfire disease. Our study provides deep insights into plant pathoecology, which is helpful for the development of novel strategies for phyllosphere disease prediction or prevention. [ABSTRACT FROM AUTHOR]

Published

2024

7. Physiological Basis of Plant Growth Promotion in Rice by Rhizosphere and Endosphere Associated Streptomyces Isolates from India.

Author

Thenappan, Dhivya P., Pandey, Rakesh, Hada, Alkesh, Jaiswal, Dinesh Kumar, Chinnusamy, Viswanathan, Bhattacharya, Ramcharan, and Annapurna, Kannepalli

Subjects

*ACTINOBACTERIA, *RICE seeds, *HYDROCYANIC acid, *PLANT-microbe relationships, *RICE

Abstract

This study demonstrated the plant growth-promoting capabilities of native actinobacterial strains obtained from different regions of the rice plant, including the rhizosphere (FT1, FTSA2, FB2, and FH7) and endosphere (EB6). We delved into the molecular mechanisms underlying the beneficial effects of these plant-microbe interactions by conducting a transcriptional analysis of a select group of key genes involved in phytohormone pathways. Through in vitro screening for various plant growth-promoting (PGP) traits, all tested isolates exhibited positive traits for indole-3-acetic acid synthesis and siderophore production, with FT1 being the sole producer of hydrogen cyanide (HCN). All isolates were identified as members of the Streptomyces genus through 16S rRNA amplification. In pot culture experiments, rice seeds inoculated with strains FB2 and FTSA2 exhibited significant increases in shoot dry mass by 7% and 34%, respectively, and total biomass by 8% and 30%, respectively. All strains led to increased leaf nitrogen levels, with FTSA2 demonstrating the highest increase (4.3%). On the contrary, strains FB2 and FT1 increased root length, root weight ratio, root volume, and root surface area, leading to higher root nitrogen content. All isolates, except for FB2, enhanced total chlorophyll and carotenoid levels. Additionally, qRT-PCR analysis supported these findings, revealing differential gene expression in auxin (OsAUX1, OsIAA1, OsYUCCA1, OsYUCCA3), gibberellin (OsGID1, OsGA20ox-1), and cytokinin (OsIPT3, OsIPT5) pathways in response to specific actinobacterial treatments. These actinobacterial strains, which enhance both aboveground and belowground crop characteristics, warrant further evaluation in field trials, either as individual strains or in consortia. This could lead to the development of commercial bioinoculants for use in integrated nutrient management practices. [ABSTRACT FROM AUTHOR]

Published

2024

8. Effects of Trichoderma harzianum and Bacillus subtilis on the root and soil microbiomes of the soybean plant INTACTA RR2 PRO™.

Author

Rigobelo, Everlon Cid, Alves de Andrade, Luana, Barbosa Santos, Carlos Henrique, Frezarin, Edvan Teciano, Ramos Sales, Luziane, Lopes de Carvalho, Lucas Amoroso, Guariz Pinheiro, Daniel, Nicodemo, Daniel, Babalola, Olubukola Oluranti, Quecine Verdi, Maria Caroline, Mondin, Mateus, and Desoignies, Nicolas

Subjects

BOTANY, SOIL microbiology, PLANT biomass, BACILLUS subtilis, PLANT-microbe relationships

Abstract

Introduction: Soybean is a significant export product for several countries, including the United States and Brazil. There are numerous varieties of soybean. Among them, a genetically modified type known as INTACTA RR2 PRO™ has been designed to demonstrate resistance to glyphosate and to produce toxins that are lethal to several species of caterpillars. Limited information is available on the use of Trichoderma harzianum and Bacillus subtilis to promote plant growth and their impact on the plant microbiome. Methods: This study aimed to evaluate the effects of these microorganisms on this soybean cultivar by analyzing parameters, such as root and shoot dry matter, nutritional status, and root and soil microbial diversity. Results: The results indicated that treatments with B. subtilis alone or in combination with T. harzianum as seed or seed and soil applications significantly enhanced plant height and biomass compared to the other treatments and the control. No significant differences in phosphorus and nitrogen concentrations were detected across treatments, although some treatments showed close correlations with these nutrients. Microbial inoculations slightly influenced the soil and root microbiomes, with significant beta diversity differences between soil and root environments, but had a limited overall impact on community composition. Discussion: The combined application of B. subtilis and T. harzianum particularly enhanced plant growth and promoted plant-associated microbial groups, such as Rhizobiaceae, optimizing plant-microbe interactions. Furthermore, the treatments resulted in a slight reduction in fungal richness and diversity. [ABSTRACT FROM AUTHOR]

Published

2024

9. Optimized Bioprocess for the Formulation of Liquid Microbial Inoculants for Forage Cowpea and Insight of Plant-microbe Interaction by SEM.

Author

Ramya, S., Pandove, Gulab, and Kalia, Anu

Subjects

*MICROBIAL inoculants, *PLANT colonization, *POLYVINYL alcohol, *PLANT-microbe relationships, *BRADYRHIZOBIUM, *TREHALOSE

Abstract

Background: In the present investigation bioprocess for the formulation of liquid microbial inoculants with escalated shelf stability for forage cowpea has been standardized. The forage cowpea can make a relevant contribution towards livestock fodder and supply nitrogen to the soil. Methods: In the present study viability of Burkholderia seminalis, Burkholderia sp. and Bradyrhizobium sp. was evaluated for one month in a basal medium amended with different concentration of polyvinyl alcohol (PVA) (0.5%, 1%, 2% and 3%), trehalose (5 mM, 10 mM, 15 mM and 20 mM), polyethylene glycol (PEG) (0.5%, 1%, 2% and 3%) and glycerol (1%, 3%, 5% and 7%). Result: At 30th day, maximum growth and survival was observed in the basal medium amended with 5 mM trehalose for all the three test cultures. Further, Liquid microbial inoculants of Burkholderia seminalis, Burkholderia sp. and Bradyrhizobium sp. were prepared using trehalose (5 mM) in basal medium and viability retention was studied up to 180 days of storage and compared to charcoal carrier based formulations at room temperature. Furthermore, Scanning electron microscopy provided insight of root colonization of forage cowpea by liquid microbial inoculants under gnotobiotic conditions, maximum root surface colonization was observed by liquid microbial inoculants of Burkholderia seminalis followed by Burkholderia sp. and Bradyrhizobium sp. Therefore, the optimized bioprocess can be used for the formulation of liquid microbial inoculants with enhanced shelf stability and could play a pertinent role in integrated nutrient management of forage cowpea for enhanced productivity and quality. [ABSTRACT FROM AUTHOR]

Published

2024

10. Plant-microbe interactions in the rhizosphere for smarter and more sustainable crop fertilization: the case of PGPR-based biofertilizers.

Author

Zuluaga, Monica Yorlady Alzate, Fattorini, Roberto, Cesco, Stefano, and Pii, Youry

Subjects

SUSTAINABLE agriculture, SUSTAINABILITY, PLANT nutrition, PLANT-microbe relationships, MINERALS in nutrition

Abstract

Biofertilizers based on plant growth promoting rhizobacteria (PGPR) are nowadays gaining increasingly attention as a modern tool for a more sustainable agriculture due to their ability in ameliorating root nutrient acquisition. For many years, most research was focused on the screening and characterization of PGPR functioning as nitrogen (N) or phosphorus (P) biofertilizers. However, with the increasing demand for food using far fewer chemical inputs, new investigations have been carried out to explore the potential use of such bacteria also as potassium (K), sulfur (S), zinc (Zn), or iron (Fe) biofertilizers. In this review, we update the use of PGPR as biofertilizers for a smarter and more sustainable crop production and deliberate the prospects of using microbiome engineering-based methods as potential tools to shed new light on the improvement of plant mineral nutrition. The current era of omics revolution has enabled the design of synthetic microbial communities (named SynComs), which are emerging as a promising tool that can allow the formulation of biofertilizers based on PGPR strains displaying multifarious and synergistic traits, thus leading to an increasingly efficient root acquisition of more than a single essential nutrient at the same time. Additionally, host-mediated microbiome engineering (HMME) leverages advanced omics techniques to reintroduce alleles coding for beneficial compounds, reinforcing positive plantmicrobiome interactions and creating plants capable of producing their own biofertilizers. We also discusses the current use of PGPR-based biofertilizers and point out possible avenues of research for the future development of more efficient biofertilizers for a smarter and more precise crop fertilization. Furthermore, concerns have been raised about the effectiveness of PGPRbased biofertilizers in real field conditions, as their success in controlled experiments often contrasts with inconsistent field results. This discrepancy highlights the need for standardized protocols to ensure consistent application and reliable outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

11. Breaking barriers: improving time and space resolution of arbuscular mycorrhizal symbiosis with single-cell sequencing approaches.

Author

Somoza, Sofía Cristina, Bonfante, Paola, and Giovannetti, Marco

Subjects

*PLANT-microbe relationships, *RNA sequencing, *TRANSCRIPTOMES, *SYMBIOSIS, *MYCORRHIZAL plants

Abstract

The cell and molecular bases of arbuscular mycorrhizal (AM) symbiosis, a crucial plant-fungal interaction for nutrient acquisition, have been extensively investigated by coupling traditional RNA sequencing techniques of roots sampled in bulk, with methods to capture subsets of cells such as laser microdissection. These approaches have revealed central regulators of this complex relationship, yet the requisite level of detail to effectively untangle the intricacies of temporal and spatial development remains elusive. The recent adoption of single-cell RNA sequencing (scRNA-seq) techniques in plant research is revolutionizing our ability to dissect the intricate transcriptional profiles of plant-microbe interactions, offering unparalleled insights into the diversity and dynamics of individual cells during symbiosis. The isolation of plant cells is particularly challenging due to the presence of cell walls, leading plant researchers to widely adopt nuclei isolation methods. Despite the increased resolution that single-cell analyses offer, it also comes at the cost of spatial perspective, hence, it is necessary the integration of these approaches with spatial transcriptomics to obtain a comprehensive overview. To date, few single-cell studies on plant-microbe interactions have been published, most of which provide high-resolution cell atlases that will become crucial for fully deciphering symbiotic interactions and addressing future questions. In AM symbiosis research, key processes such as the mutual recognition of partners during arbuscule development within cortical cells, or arbuscule senescence and degeneration, remain poorly understood, and these advancements are expected to shed light on these processes and contribute to a deeper understanding of this plant-fungal interaction. [ABSTRACT FROM AUTHOR]

Published

2024

12. Nutrient and moisture limitations reveal keystone metabolites linking rhizosphere metabolomes and microbiomes.

Author

Baker, Nameer R., Zhalnina, Kateryna, Mengting Yuan, Herman, Don, Ceja-Navarro, Javier A., Sasse, Joelle, Jordan, Jacob S., Bowen, Benjamin P., Liyou Wu, Fossum, Christina, Chew, Aaron, Ying Fu, Saha, Malay, Jizhong Zhou, Pett-Ridge, Jennifer, Northen, Trent R., and Firestone, Mary K.

Subjects

*MICROBIAL metabolites, *PLANT-microbe relationships, *MICROBIAL communities, *ABIOTIC stress, *GLUCURONIC acid

Abstract

Plants release a wealth of metabolites into the rhizosphere that can shape the composition and activity of microbial communities in response to environmental stress. The connection between rhizodeposition and rhizosphere microbiome succession has been suggested, particularly under environmental stress conditions, yet definitive evidence is scarce. In this study, we investigated the relationship between rhizosphere chemistry, microbiome dynamics, and abiotic stress in the bioenergy crop switchgrass grown in a marginal soil under nutrient-limited, moisture-limited, and nitrogen (N)-replete, phosphorus (P)-replete, and NP-replete conditions. We combined 16S rRNA amplicon sequencing and LC-MS/MS-based metabolomics to link rhizosphere microbial communities and metabolites. We identified significant changes in rhizosphere metabolite profiles in response to abiotic stress and linked them to changes in microbial communities using network analysis. N-limitation amplified the abundance of aromatic acids, pentoses, and their derivatives in the rhizosphere, and their enhanced availability was linked to the abundance of bacterial lineages from Acidobacteria, Verrucomicrobia, Planctomycetes, and Alphaproteobacteria. Conversely, N-amended conditions increased the availability of N-rich rhizosphere compounds, which coincided with proliferation of Actinobacteria. Treatments with contrasting N availability differed greatly in the abundance of potential keystone metabolites; serotonin and ectoine were particularly abundant in N-replete soils, while chlorogenic, cinnamic, and glucuronic acids were enriched in N-limited soils. Serotonin, the keystone metabolite we identified with the largest number of links to microbial taxa, significantly affected root architecture and growth of rhizosphere microorganisms, highlighting its potential to shape microbial community and mediate rhizosphere plant-microbe interactions. [ABSTRACT FROM AUTHOR]

Published

2024

13. Epiphytic bacterial community composition on four submerged macrophytes in different regions of Taihu Lake.

Author

Hongda Fang, Zhuo Zhen, Fan Yang, Hailei Su, and Yuan Wei

Subjects

ECOLOGICAL niche, PLANT habitats, PLANT-microbe relationships, BACTERIAL communities, PLANT species

Abstract

The epiphytic bacteria in aquatic ecosystems, inhabiting a unique ecological niche with significant ecological function, have long been the subject of attention. Habitat characteristics and plant species are believed to be important in controlling the assembly of epiphytic bacteria. However, the underlying principle governing the assembly of the epiphytic bacterial community on macrophytes is far from clear. In this study, we systematically compared the diversity and community composition of epiphytic bacteria both in different habitats and on different species of macrophytes where they were attached. Results suggested that neither the plant species nor the habitat had a significant effect on the diversity and community of epiphytic bacteria independently, indicating that the epiphytic bacterial community composition was correlated to both geographical distance and individual species of macrophytes. Furthermore, almost all of the abundant taxa were shared between different lake regions or macrophyte species, and the most abundant bacteria belonged to Proteobacteria and Firmicutes. Our results demonstrated that the competitive lottery model may explain the pattern of epiphytic bacterial colonization of submerged macrophyte surfaces. This research could provide a new perspective for exploring plant-microbe interaction in aquatic systems and new evidence for the lottery model as the mechanism best explaining the assembly of epiphytic bacteria. [ABSTRACT FROM AUTHOR]

Published

2024

14. Plant species influences the composition of root system microbiome and its antibiotic resistance profile in a constructed wetland receiving primary treated wastewater.

Author

Riva, Valentina, Vergani, Lorenzo, Rashed, Ahmed Ali, El Saadi, Aiman, Sabatino, Raffaella, Di Cesare, Andrea, Crotti, Elena, Mapelli, Francesca, and Borin, Sara

Subjects

LACTIC acid bacteria, EMERGING contaminants, PHRAGMITES australis, PLANT-microbe relationships, ENDOPHYTIC bacteria, CONSTRUCTED wetlands

Abstract

Introduction: Constructed wetlands (CWs) are nature-based solutions for wastewater treatment where the root system microbiome plays a key role in terms of nutrient and pollutant removal. Nonetheless, little is known on plant-microbe interactions and bacterial population selection in CWs, which are mostly characterized in terms of engineering aspects. Methods: Here, cultivation-independent and cultivation-based analyses were applied to study the bacterial communities associated to the root systems of Phragmites australis and Typha domingensis co-occurring in the same cell of a CW receiving primary treated wastewaters. Results and discussion: Two endophytic bacteria collections (n = 156) were established aiming to find novel strains for microbial-assisted phytodepuration, however basing on their taxonomy the possible use of these strains was limited by their low degrading potential and/or for risks related to the One-Health concept. A sharp differentiation arose between the P. australis and T. domingensis collections, mainly represented by lactic acid bacteria (98%) and Enterobacteriaceae (69%), respectively. Hence, 16S rRNA amplicon sequencing was used to disentangle the microbiome composition in the root system fractions collected at increasing distance from the root surface. Both the fraction type and the plant species were recognized as drivers of the bacterial community structure. Moreover, differential abundance analysis revealed that, in all fractions, several bacteria families were significantly and differentially enriched in P. australis or in T. domingensis. CWs have been also reported as interesting options for the removal of emerging contaminants (e.g, antibiotic resistance genes, ARGs). In this study, ARGs were mostly present in the rhizosphere of both plant species, compared to the other analyzed fractions. Notably, qPCR data showed that ARGs (i.e., ermB, blaTEM, tetA) and intl1 gene (integrase gene of the class 1 integrons) were significantly higher in Phragmites than Typha rhizospheres, suggesting that macrophyte species growing in CWs can display a different ability to remove ARGs from wastewater. Overall, the results suggest the importance to consider the plant-microbiome interactions, besides engineering aspects, to select the most suitable species when designing phytodepuration systems. [ABSTRACT FROM AUTHOR]

Published

2024

15. A novel exopolysaccharide-producing bacterium, Pseudescherichia liriopis sp. nov. isolated from Liriope platyphylla, enhances the growth of Daucus carota subsp. sativus under drought and salinity stress.

Author

Inhyup Kim, Haejin Woo, Chhetri, Geeta, Sunho Park, and Taegun Seo

Subjects

PLANT growth, NITROGEN fixation, SUSTAINABLE agriculture, CROP yields, PLANT-microbe relationships, CARROTS

Abstract

Biological and abiotic stresses in plant growth are associated with reduced crop yields. Therefore, improving plant stress resistance can be a crucial strategy to improve crop production. To overcome these problems, plant growth-promoting bacteria are emphasized as one of the alternative tools for sustainable agriculture. This study found a novel strain (L3T) of a plant growth-promoting bacterium in fermented Liriope platyphylla fruit. Strain L3T showed the ability to promote plant growth. The L3T strain promoted plant growth of D. carota subsp. sativus, increasing the length (increase rate compared to the control group, 36.98%), diameter (47.06%), and weight of carrots (81.5%), ultimately increasing the edible area. In addition, we confirmed that plant growth was improved even in situations that inhibited plant growth, such as salinity and drought stress. Strain L3T performed indole production, siderophore production, phosphate solubilization, and nitrogen fixation, all characteristics of a strain that promotes plant growth. Genome analysis revealed genes involved in the growth promotion effects of strain L3T. Additionally, the properties of exopolysaccharides were identified and characterized using FTIR, TGA, and UHPLC. Our results demonstrated that L3 isolated from fermented L. platyphylla fruit can be used to simultaneously alleviate drought and NaCl stress. [ABSTRACT FROM AUTHOR]

Published

2024

16. A meta‐analysis of the effects of climate change‐related abiotic factors on aboveground and belowground plant‐associated microbes.

Author

Quiroga, Gabriela, Castagneyrol, Bastien, Abdala‐Roberts, Luis, and Moreira, Xoaquín

Subjects

*RHIZOSPHERE microbiology, *ABIOTIC environment, *PLANT-microbe relationships, *MICROORGANISMS, *CONTRAST effect, *RHIZOBACTERIA, *RHIZOSPHERE

Abstract

The abiotic environment exerts strong effects on plant‐associated microbes, shaping their interactions with plants and resulting ecosystem processes. However, these abiotic effects on plant–microbe interactions are often highly specific and contingent on the abiotic driver or microbial group, requiring synthesis work describing general patterns and from this generate hypotheses and guide mechanistic work. To address this, we conducted a meta‐analysis of the effects of climate change‐related abiotic factors, namely warming, drought, and eCO2, on plant‐associated microbes distinguishing by microbial taxonomic or biological group (bacteria, fungi or virus) and the plant part where microbes are found or associated with (phyllosphere or rhizosphere). We found abiotic driver‐specific patterns, whereby drought significantly reduced microbial abundance, whereas warming and eCO2 had no significant effects. In addition, these abiotic effects were contingent on the microbial taxonomic group, with fungi being negatively affected by drought but positively affected by warming (eCO2 enrichment had no effect), whereas bacteria and viruses were not significantly affected by any factor. Likewise, rhizospheric microbes were negatively affected by drought but positively affected by warming (eCO2 enrichment had no effect), whereas phyllospheric microbes were not significantly affected by any factor. Collectively, these findings point to important implications for global change research by highlighting contrasting effects of climate change‐related abiotic drivers on plant‐associated microbes and the contingency of such effects on microbe life histories and the nature of their interactions with plants. [ABSTRACT FROM AUTHOR]

Published

2024

17. An improved bacterial mRNA enrichment strategy in dual RNA sequencing to unveil the dynamics of plant-bacterial interactions.

Author

Shilpha, Jayabalan, Lee, Junesung, Kwon, Ji-Su, Lee, Hyun-Ah, Nam, Jae-Young, Jang, Hakgi, and Kang, Won-Hee

Subjects

*RNA sequencing, *RIBOSOMAL RNA, *TRANSCRIPTOMES, *PLANT-microbe relationships, *RHIZOBACTERIA, *RIBOSOMAL DNA, *MESSENGER RNA

Abstract

Background: Dual RNA sequencing is a powerful tool that enables a comprehensive understanding of the molecular dynamics underlying plant-microbe interactions. RNA sequencing (RNA-seq) poses technical hurdles in the transcriptional analysis of plant-bacterial interactions, especially in bacterial transcriptomics, owing to the presence of abundant ribosomal RNA (rRNA), which potentially limits the coverage of essential transcripts. Therefore, to achieve cost-effective and comprehensive sequencing of the bacterial transcriptome, it is imperative to devise efficient methods for eliminating rRNA and enhancing the proportion of bacterial mRNA. In this study, we modified a strand-specific dual RNA-seq method with the goal of enriching the proportion of bacterial mRNA in the bacteria-infected plant samples. The enriched method involved the sequential separation of plant mRNA by poly A selection and rRNA removal for bacterial mRNA enrichment followed by strand specific RNA-seq library preparation steps. We assessed the efficiency of the enriched method in comparison to the conventional method by employing various plant-bacterial interactions, including both host and non-host resistance interactions with pathogenic bacteria, as well as an interaction with a beneficial rhizosphere associated bacteria using pepper and tomato plants respectively. Results: In all cases of plant-bacterial interactions examined, an increase in mapping efficiency was observed with the enriched method although it produced a lower read count. Especially in the compatible interaction with Xanthmonas campestris pv. Vesicatoria race 3 (Xcv3), the enriched method enhanced the mapping ratio of Xcv3-infected pepper samples to its own genome (15.09%; 1.45-fold increase) and the CDS (8.92%; 1.49-fold increase). The enriched method consistently displayed a greater number of differentially expressed genes (DEGs) than the conventional RNA-seq method at all fold change threshold levels investigated, notably during the early stages of Xcv3 infection in peppers. The Gene Ontology (GO) enrichment analysis revealed that the DEGs were predominantly enriched in proteolysis, kinase, serine type endopeptidase and heme binding activities. Conclusion: The enriched method demonstrated in this study will serve as a suitable alternative to the existing RNA-seq method to enrich bacterial mRNA and provide novel insights into the intricate transcriptomic alterations within the plant-bacterial interplay. [ABSTRACT FROM AUTHOR]

Published

2024

18. Hibiscus acid and hydroxycitric acid dimethyl esters from Hibiscus flowers induce production of dithiolopyrrolone antibiotics by Streptomyces Strain MBN2-2.

Author

Sumang, Felaine Anne, Ward, Alan, Errington, Jeff, and Dashti, Yousef

Subjects

DIMETHYL sulfate, STREPTOMYCES, HIBISCUS, PLANT-microbe relationships, IRON chelates, HYDROXYCINNAMIC acids

Abstract

Plants and microbes are closely associated with each other in their ecological niches. Much has been studied about plant–microbe interactions, but little is known about the effect of phytochemicals on microbes at the molecular level. To access the products of cryptic biosynthetic gene clusters in bacteria, we incorporated an organic extract of hibiscus flowers into the culture media of different Actinobacteria isolated from plant rhizospheres. This approach led to the production of broad-spectrum dithiolopyrrolone (DTP) antibiotics, thiolutin (1) and aureothricin (2), by Streptomyces sp. MBN2-2. The compounds from the hibiscus extract responsible for triggering the production of these two DTPs were found to be hibiscus acid dimethyl ester (3) and hydroxycitric acid 1,3-dimethyl ester (4). It was subsequently found that the addition of either Fe2+ or Fe3+ to culture media induced the production of 1 and 2. The Chrome Azurol S (CAS) assay revealed that 3 and 4 can chelate iron, and therefore, the mechanism leading to the production of thiolutin and aureothricin appears to be related to changes in iron concentration levels. This work supports the idea that phytochemicals can be used to activate the production of cryptic microbial biosynthetic gene clusters and further understand plant–microbe interactions. [ABSTRACT FROM AUTHOR]

Published

2024

19. Integrated Benefits to Agriculture with Trichoderma and Other Endophytic or Root-Associated Microbes.

Author

Harman, Gary E.

Subjects

INSECT-fungus relationships, PLANT-microbe relationships, PLANT yields, CHEMICAL systems, BIOLOGICAL systems

Abstract

The use of endophytic microbes is increasing in commercial agriculture. This review will begin with a strain selection. Most strains will not function well, so only a few provide adequate performance. It will also describe the endophyte–plant relationship and the fungi and bacteria involved. Their abilities to alleviate biotic (diseases and pests) and abiotic stresses (drought, salt, and flooding) to remediate pollution and increase photosynthetic capabilities will be described. Their mechanisms of action will be elucidated. These frequently result in increased plant yields. Finally, methods and practices for formulation and commercial use will be described. [ABSTRACT FROM AUTHOR]

Published

2024

20. Temporal heterogeneity of the root microbiome in Panax ginseng soils across ecological compartments under mild soil disturbance.

Author

Zhenting Shi, Limin Yang, Meiling Yang, Kexin Li, Li Yang, and Mei Han

Subjects

GINSENG, SOIL moisture, SOILS, GROUP dynamics, SUSTAINABILITY, PLANT-microbe relationships

Abstract

Introduction: Knowledge on spatiotemporal heterogeneity of plant root microbiomes is lacking. The diversity of the root microbiome must be revealed for understanding plant–microbe interactions and the regulation of functionally crucial microbial taxa. Methods: We here investigated the dynamics of microbial group characteristics within each soil ecological compartment [rhizoplane (B), rhizosphere (J), and bulk soil (T)] across different cultivation years (year 4: F4 and year 5: F5) by using high-throughput sequencing (16S and ITS). Results: According to the species diversity, microbiome diversity and the ASV (amplified sequence variant) number in the rhizoplane ecotone increased significantly with an increase in the planting years. By contrast, the microbiome diversity of the rhizosphere soil remained relatively stable. PCoA and PERMANOVA analyses revealed that microbial taxa among different planting years and ecological compartments varied significantly. Planting years exerted the least effect on the rhizosphere microbiome, but their impact on fungi in the rhizoplane and bacteria in the bulk soil was the most significant. Discussion: Planting years influenced the microbial community composition in various ecological compartments of ginseng root soil. Potentially harmful fungi such as Cryptococcus (2.83%), Neonectria (0.89%), llyonectria (0.56%), Gibberella (0.41%), Piloderma (4.44%), and Plectosphaerella (3.88%) were enriched in F5B with an increase in planting years, whereas the abundance of potentially beneficial Mortierella increased. Correlation analysis indicated associations between bacterial taxa and soil pH/S-CAT, and between fungal taxa and soil moisture content/total potassium. Our study highlights the significance of changes in rhizoplane fungi and the stability of the rhizosphere microbial community in comprehending plant ecological sustainability [ABSTRACT FROM AUTHOR]

Published

2024

21. Mechanical resistance of the environment affects root hair growth and nucleus dynamics.

Author

Pereira, David, Alline, Thomas, Cascaro, Léa, Lin, Emilie, and Asnacios, Atef

Subjects

*HAIR growth, *ROOT growth, *ROOT hairs (Botany), *PLANT-microbe relationships, *PLANT growth, *NUTRIENT uptake

Abstract

Root hair (RH) cells are important for the growth and survival of seedlings. They favor plant–microbe interactions and nutrients uptake. When invading the soil, RH cells have to penetrate a dense medium exhibiting a variety of physical properties, such as mechanical resistance, that impact the growth and survival of plants. Here we investigate the effect of the mechanical resistance of the culture medium on RH-physical and phenotypical parameters such as length, time, and speed of growth. We also analyze the impact of the environment on nuclear dynamics. We show that the RH growth rate and the nucleus speed decrease similarly as mechanical resistance increases while the time of growth of RH cells is invariable. Moreover, during RH growth, the nucleus-to-tip distance was found to decrease when the stiffness of the environment was increased. Along this line, using Latrunculin B treatment in liquid growth media, we could internally slow down RH growth to reach speeds similar to those observed in stiff solid media while the nucleus-to-tip distance was only slightly affected, supporting thus the idea of a specific effect of mechanical resistance of the environment on nucleus dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

22. Omics approaches in understanding the benefits of plant-microbe interactions.

Author

Jain, Archana, Sarsaiya, Surendra, Singh, Ranjan, Qihai Gong, Qin Wu, and Jingshan Shi

Subjects

PLANT-microbe relationships, AGRICULTURE, SMALL molecules, SUSTAINABLE agriculture, ECOLOGICAL disturbances, PRECISION farming

Abstract

Plant-microbe interactions are pivotal for ecosystem dynamics and sustainable agriculture, and are influenced by various factors, such as host characteristics, environmental conditions, and human activities. Omics technologies, including genomics, transcriptomics, proteomics, and metabolomics, have revolutionized our understanding of these interactions. Genomics elucidates key genes, transcriptomics reveals gene expression dynamics, proteomics identifies essential proteins, and metabolomics profiles small molecules, thereby oering a holistic perspective. This review synthesizes diverse microbial-plant interactions, showcasing the application of omics in understanding mechanisms, such as nitrogen fixation, systemic resistance induction, mycorrhizal association, and pathogen-host interactions. Despite the challenges of data integration and ethical considerations, omics approaches promise advancements in precision intervention and resilient agricultural practices. Future research should address data integration challenges, enhance omics technology resolution, explore epigenomics, and understand plant-microbe dynamics under diverse conditions. In conclusion, omics technologies hold immense promise for optimizing agricultural strategies and fortifying resilient plant-microbe alliances, paving the way for sustainable agriculture and environmental stewardship. [ABSTRACT FROM AUTHOR]

Published

2024

23. Comparative Multi-Omics Analysis of Broomcorn Millet in Response to Anthracocystis destruens Infection.

Author

Enguo Wu, Xuepei Li, Qian Ma, Honglu Wang, Xiaowei Han, and Baili Feng

Subjects

*BROOMCORN millet, *PLANT-microbe relationships, *IMMUNOSUPPRESSION, *MULTIOMICS, *IMMUNE response

Abstract

Anthracocystis destruens is the causal agent of broomcorn millet (Panicum miliaceum) smut disease, which results in serious yield losses in broomcorn millet production. However, the molecular basis underlying broomcorn millet defense against A. destruens is less understood. In this study, we investigated how broomcorn millet responds to infection by A. destruens by employing a comprehensive multi-omics approach. We examined the responses of broomcorn millet across transcriptome, metabolome, and microbiome levels. Infected leaves exhibited an upregulation of genes related to photosynthesis, accompanied by a higher accumulation of photosynthesis-related compounds and alterations in hormonal levels. However, broomcorn millet genes involved in immune response were downregulated post A. destruens infection, suggesting that A. destruens may suppress broomcorn millet immunity. In addition, we show that the immune suppression and altered host metabolism induced by A. destruens have no significant effect on the microbial community structure of broomcorn millet leaf, thus providing a new perspective for understanding the tripartite interaction between plant, pathogen, and microbiota. [ABSTRACT FROM AUTHOR]

Published

2024

24. Harnessing Green Helpers: Nitrogen-Fixing Bacteria and Other Beneficial Microorganisms in Plant–Microbe Interactions for Sustainable Agriculture.

Author

Liu-Xu, Luisa, González-Hernández, Ana Isabel, Camañes, Gemma, Vicedo, Begonya, Scalschi, Loredana, and Llorens, Eugenio

Subjects

SUSTAINABLE agriculture, PLANT-microbe relationships, NUTRIENT cycles, MICROORGANISMS, CROP yields, MICROBIAL inoculants, PLANT nutrients, NITROGEN-fixing bacteria

Abstract

The health of soil is paramount for sustaining life, as it hosts diverse communities of microorganisms that interact with plants, influencing their growth, health, and resilience. Beneficial microorganisms, including fungi and bacteria, form symbiotic relationships with plants, providing essential nutrients, promoting growth, and enhancing stress tolerance. These microorganisms, such as mycorrhizal fungi and plant growth-promoting bacteria, play crucial roles in nutrient cycling, soil health, and plant productivity. Additionally, they help lessen reliance on chemical fertilizers, thereby mitigating the environmental risks associated with their use. Advances in agricultural practices harness the potential of these beneficial microorganisms to improve crop yields while minimizing the environmental impact. However, challenges such as competition with indigenous microbial strains and environmental factors limit the universal utilization of microbial inoculants. Despite these challenges, understanding and leveraging the interactions between plants and beneficial microorganisms hold promise for sustainable agriculture and enhanced food security. [ABSTRACT FROM AUTHOR]

Published

2024

25. Synergistic effects of Bacillus salmalaya strain 139SI with fertilizer on nutrient uptake and fertilizer use efficiency of oil palm seedlings.

Author

Azri, Md Hoirul, Ismail, Salmah, and Rosazlin

Subjects

BACILLUS (Bacteria), OIL palm, SEEDLINGS, NUTRIENT uptake, PLANT-microbe relationships, FERTILIZER application

Abstract

Aims: Plant-microbe interaction in the rhizosphere significantly influences nutrient uptake efficiency. Thus, this research was aimed to investigate the potential of Bacillus salmalaya strain 139SI in increasing nutrient use efficiency through its synergistic effects with fertilizer application. Methodology and results: This research analyzed the effects of B. salmalaya strain 139SI inoculant, fertilizer and a combination of both on soil nutrients, vegetative growth, chlorophyll level, photosynthetic activities, nutrient uptake and nutrient use efficiency in oil palm seedlings for four months in a nursery setting. At the end of the research, the inoculation of B. salmalaya strain 139SI resulted in a significant increase in palm growth, chlorophyll level, photosynthetic activities, nutrient uptake and nutrient use efficiency compared to the untreated group. Soil nutrient analysis demonstrated that the inoculation of B. salmalaya strain 139SI led to a notable increase in available nitrogen within the rhizosphere soil. The findings of this research also indicated a noteworthy synergistic effect between the B. salmalaya strain 139SI inoculant and fertilizer. The most promising outcomes for plant growth performance and nutrient uptake were observed when the B. salmalaya strain 139SI inoculant was added to the fertilized palm. Conclusion, significance and impact of study: This research shows that B. salmalaya strain 139SI may work synergistically with fertilizer to enhance nutrient absorption and increase fertilizer usage efficiency. Integrating B. salmalaya into the nutrient management of oil palm seedlings can potentially reduce reliance on synthetic fertilizers, offering advantages to both farmers and the ecosystem. [ABSTRACT FROM AUTHOR]

Published

2024

26. Global Diversity and Distribution of Rhizosphere and Root-Associated Fungi in Coastal Wetlands: A Systematic Review.

Author

Lumibao, Candice Y., Harris, Georgia, and Birnbaum, Christina

Subjects

COASTAL wetlands, RHIZOSPHERE, SALT marshes, VESICULAR-arbuscular mycorrhizas, FUNGAL communities, PLANT-microbe relationships

Abstract

Coastal wetlands have been long recognized for their importance to biodiversity and many biogeochemical processes including carbon sequestration; however, our understanding of plant-microbe interactions that govern many processes in these ecosystems remains elusive. Fungal communities are known to play critical roles in coastal wetlands, particularly due to their close relationships with plants, yet, systematic understanding of their distributional patterns and the factors shaping these patterns in natural coastal wetland environments has been rarely assessed. We synthesized existing published literature from fifty-one studies spanning 60 years to examine global fungal distributional patterns in coastal wetlands, draw linkages between fungi, the plant communities, and their environment, and identify gaps in fungal research and suggest future research directions. We focused on studies that reported root-associated fungi and fungi from the plant rhizosphere (i.e., soil surrounding roots) in coastal dunes, intertidal flats, salt marshes, and tidal wetlands. Our synthesis has revealed that (1) 203 fungal species were reported from salt marshes, 59 fungal species from coastal dunes, 32 from tidal wetlands, and ten from intertidal flats; (2) rhizosphere fungal communities were more species-rich and reported more often for all ecosystems except in salt marshes; and (3) nineteen different fungal guilds, which are predominantly arbuscular mycorrhizal fungi. We conclude that more research is needed to better understand root-associated fungal diversity in less studied ecosystems reviewed here. We have identified knowledge gaps in reported data and outlined suggestions to facilitate future plant-fungal research in these declining, but important, coastal ecosystems. [ABSTRACT FROM AUTHOR]

Published

2024

27. Identification of Conserved Pathways in Bacillus Strains Known for Plant Growth-Promoting Behavior Using a Multifaceted Computational Approach.

Author

Das, Vandana Apurva, Gautam, Budhayash, Yadav, Pramod Kumar, and Singh, Satendra

Subjects

BACILLUS (Bacteria), BIOTRANSFORMATION (Metabolism), BACILLUS subtilis, PLANT-microbe relationships, BACILLUS amyloliquefaciens, SUSTAINABLE agriculture

Abstract

Bacillus strains have long been recognized for their beneficial interactions with plants, enhancing growth, nutrient uptake, and stress resistance. Understanding their molecular mechanisms and plant-microbe interactions is crucial for harnessing their potential in sustainable agriculture. Here we used ten strains from the 5 Bacillus species namely Bacillus velezensis, Bacillus subtilis, Bacillus atrophaeus, Bacillus altitudinis and Bacillus amylofaciens, which are previously reported for PGPR activity. A comparative analysis of these strains was performed to determine their evolutionary relationships, which revealed that Bacillus velezensis and Bacillus amyloliquefaciens are closely related based on underlying genetic and proteomic similarities. Bacillus altitudinis strain LZP02 was the most distantly related to all the other selected strains. On the other hand, Bacillus atrophaeus strains GQJK17 and CNY01 are shown to be closely related to each other. Mauve alignment was performed to determine the genetic relationships between these strains. The LZP02 strain exhibited several unique inversions harboring important genes, such as betB, ftsW, and rodA, which are important for bacterial survival. Proteomic analysis highlighted important pathways that were conserved across these strains, including xenobiotic biodegradation and metabolism, biosynthesis of polyketides and nonribosomal pathways, and biosynthesis of secondary metabolites, all of which have been shown to be involved in plant growth promotion. [ABSTRACT FROM AUTHOR]

Published

2024

28. Mosaic of local adaptation between white clover and rhizobia along an urbanization gradient.

Author

Murray‐Stoker, David and Johnson, Marc T. J.

Subjects

*WHITE clover, *RHIZOBIUM leguminosarum, *ABIOTIC environment, *URBANIZATION, *PLANT-microbe relationships, *PHYSIOLOGICAL adaptation

Abstract

Urbanization frequently alters the biotic and abiotic environmental context. Variation in both the biotic and abiotic environment can result in selection mosaics that lead to locally adapted phenotypes. Ecological changes to urban environments can result in evolutionary responses across a diverse array of plants and animals, but the effects of urbanization on local adaptation and coevolution between species remain largely unstudied.Using a common garden experiment of 30 populations and 1080 plants, we tested for local adaptation in the mutualism between white clover (Trifolium repens) and rhizobia (Rhizobium leguminosarum symbiovar trifolii) along an urbanization gradient. We asked: (Q1) are white clover and rhizobia locally adapted? (Q2) Does nitrogen (N) addition mediate the strength of local adaptation? (Q3) Is the strength of local adaptation in host plants related to the strength of local adaptation in rhizobia, as expected if white clover and rhizobia are coadapting? And (Q4) how does the degree of local adaptation vary with urbanization?We found evidence for local adaptation for both white clover and rhizobia, with stronger signatures of local adaptation for rhizobia than white clover (Q1). While N addition positively affected plant biomass and negatively affected nodule density, N addition did not consistently mediate patterns of local adaptation (Q2). The strength of local adaptation was positively related between white clover and rhizobia under N addition, suggesting that soil N mediates coadaptation between white clover and rhizobia (Q3). We did not find a consistent relationship between measures of urbanization and local adaptation (Q4). Additionally, fitness responses for white clover and rhizobia were unrelated to Rhizobium abundance and local adaptation was unrelated to the broader bacterial microbiome in the soil inoculants or root endosphere.Synthesis. Our results show a spatial mosaic in local adaptation, with stronger local adaptation for rhizobia than white clover. While urbanization does influence the ecology of plant–microbe interactions, our study suggests urbanization does not disrupt local adaptation and coevolution among mutualists. [ABSTRACT FROM AUTHOR]

Published

2024

29. Time‐dependent interaction modification generated from plant–soil feedback.

Author

Zou, Heng‐Xing, Yan, Xinyi, and Rudolf, Volker H. W.

Subjects

*BIOTIC communities, *PLANT populations, *POPULATION dynamics, *PLANT-microbe relationships, *PHENOLOGY

Abstract

Pairwise interactions between species can be modified by other community members, leading to emergent dynamics contingent on community composition. Despite the prevalence of such higher‐order interactions, little is known about how they are linked to the timing and order of species' arrival. We generate population dynamics from a mechanistic plant–soil feedback model, then apply a general theoretical framework to show that the modification of a pairwise interaction by a third plant depends on its germination phenology. These time‐dependent interaction modifications emerge from concurrent changes in plant and microbe populations and are strengthened by higher overlap between plants' associated microbiomes. The interaction between this overlap and the specificity of microbiomes further determines plant coexistence. Our framework is widely applicable to mechanisms in other systems from which similar time‐dependent interaction modifications can emerge, highlighting the need to integrate temporal shifts of species interactions to predict the emergent dynamics of natural communities. [ABSTRACT FROM AUTHOR]

Published

2024

30. Milestones in understanding transport, sensing, and signaling of the plant nutrient phosphorus.

Author

Yang, Shu-Yi, Lin, Wei-Yi, Hsiao, Yi-Min, and Chiou, Tzyy-Jen

Subjects

*PLANT nutrients, *PLANT-microbe relationships, *SUSTAINABLE agriculture, *PHOSPHORUS, *ESSENTIAL nutrients, *PLANT translocation

Abstract

As an essential nutrient element, phosphorus (P) is primarily acquired and translocated as inorganic phosphate (Pi) by plant roots. Pi is often sequestered in the soil and becomes limited for plant growth. Plants have developed a sophisticated array of adaptive responses, termed P starvation responses, to cope with P deficiency by improving its external acquisition and internal utilization. Over the past 2 to 3 decades, remarkable progress has been made toward understanding how plants sense and respond to changing environmental P. This review provides an overview of the molecular mechanisms that regulate or coordinate P starvation responses, emphasizing P transport, sensing, and signaling. We present the major players and regulators responsible for Pi uptake and translocation. We then introduce how P is perceived at the root tip, how systemic P signaling is operated, and the mechanisms by which the intracellular P status is sensed and conveyed. Additionally, the recent exciting findings about the influence of P on plant-microbe interactions are highlighted. Finally, the challenges and prospects concerning the interplay between P and other nutrients and strategies to enhance P utilization efficiency are discussed. Insights obtained from this knowledge may guide future research endeavors in sustainable agriculture. This article reviews the molecular mechanisms of phosphorus transport, sensing and signaling; and highlights recent findings about the impact of phosphorus on plant-microbe interactions. [ABSTRACT FROM AUTHOR]

Published

2024

31. Plant-Derived, Nodule-Specific Cysteine-Rich Peptides as a Novel Source of Biopesticides for Controlling Citrus Greening Disease.

Author

Higgins, Steven A., Igwe, David O., Coradetti, Samuel, Ramsey, John S., DeBlasio, Stacy L., Pitino, Marco, Shatters Jr., Robert G., Niedz, Randall, Fleites, Laura A., and Heck, Michelle

Subjects

*CITRUS greening disease, *BIOPESTICIDES, *CANDIDATUS liberibacter asiaticus, *PEPTIDES, *PLANT-microbe relationships, *MEDICAGO truncatula, *BACTERIAL cultures

Abstract

Nodule-specific cysteine-rich (NCR) peptides, encoded in the genome of the Mediterranean legume Medicago truncatula (barrelclover), are known to regulate plant-microbe interactions. A subset of computationally derived 20-mer peptide fragments from 182 NCR peptides was synthesized to identify those with activity against the unculturable vascular pathogen associated with citrus greening disease, 'Candidatus Liberibacter asiaticus' (CLas). Grounded in a design of experiments framework, we evaluated the peptides in a screening pipeline involving three distinct assays: a bacterial culture assay with Liberibacter crescens, a CLas-infected excised citrus leaf assay, and an assay to evaluate effects on bacterial acquisition by the nymphal stage of hemipteran vector Diaphorina citri. A subset of the 20-mer NCR peptide fragments inhibits both CLas growth in citrus leaves and CLas acquisition by D. citri. Two peptides induced higher levels of D. citri mortality. These findings reveal 20-mer NCR peptides as a new class of plant-derived biopesticide molecules to control citrus greening disease. [ABSTRACT FROM AUTHOR]

Published

2024

32. Sterols, pleiotropic players in plant–microbe interactions.

Author

Der, Christophe, Courty, Pierre-Emmanuel, Recorbet, Ghislaine, Wipf, Daniel, Simon-Plas, Françoise, and Gerbeau-Pissot, Patricia

Subjects

*PLANT-microbe relationships, *STEROLS, *PHYTOSTEROLS, *CHEMICAL composition of plants, *CELL communication, *CARRIER proteins

Abstract

Sterols are crucial lipid components of the plasma membrane (PM) and are involved in its integrity and organization. Each sterol exhibits particular intrinsic properties and influences differently PM biophysical properties, such as fluidity and permeability, differently. The sterol composition of the PM varies across plant species. Transcription of genes involved in sterol biosynthesis [e.g., CYP710A , which encodes an enzyme converting β-sitosterol to stigmasterol (two major plant sterols)] is regulated in plant–microbe interactions (PMIs). The sterol composition of the plant PM is modulated during PMIs. Sterols bind specialized proteins to activate appropriate signaling cascades and/or provoke PM structural rearrangements, two mechanisms of PMI-induced responses. Understanding the establishment and functioning of PMIs requires novel technologies to track sterols at the highest spatial resolution. Plant–microbe interactions (PMIs) are regulated through a wide range of mechanisms in which sterols from plants and microbes are involved in numerous ways, including recognition, transduction, communication, and/or exchanges between partners. Phytosterol equilibrium is regulated by PMIs through expression of genes involved in phytosterol biosynthesis, together with their accumulation. As such, PMI outcomes also include plasma membrane (PM) functionalization events, in which phytosterols have a central role, and activation of sterol-interacting proteins involved in cell signaling. In spite (or perhaps because) of such multifaceted abilities, an overall mechanism of sterol contribution is difficult to determine. However, promising approaches exploring sterol diversity, their contribution to PMI outcomes, and their localization would help us to decipher their crucial role in PMIs. [ABSTRACT FROM AUTHOR]

Published

2024

33. Common mycorrhizal network: the predominant socialist and capitalist responses of possible plant-plant and plant-microbe interactions for sustainable agriculture.

Author

Ullah, Asad, Danmei Gao, and Fengzhi Wu

Subjects

SUSTAINABLE agriculture, PLANT-microbe relationships, SUSTAINABILITY, VESICULAR-arbuscular mycorrhizas, ENDOPHYTIC bacteria, SOCIALISM, PLANT growth

Abstract

Plants engage in a variety of interactions, including sharing nutrients through common mycorrhizal networks (CMNs), which are facilitated by arbuscular mycorrhizal fungi (AMF). These networks can promote the establishment, growth, and distribution of limited nutrients that are important for plant growth, which in turn benefits the entire network of plants. Interactions between plants and microbes in the rhizosphere are complex and can either be socialist or capitalist in nature, and the knowledge of these interactions is equally important for the progress of sustainable agricultural practice. In the socialist network, resources are distributed more evenly, providing benefits for all connected plants, such as symbiosis. For example, direct or indirect transfer of nutrients to plants, direct stimulation of growth through phytohormones, antagonism toward pathogenic microorganisms, and mitigation of stresses. For the capitalist network, AMF would be privately controlled for the profit of certain groups of plants, hence increasing competition between connected plants. Such plant interactions invading by microbes act as saprophytic and cause necrotrophy in the colonizing plants. In the first case, an excess of the nutritional resources may be donated to the receiver plants by direct transfer. In the second case, an unequal distribution of resources occurs, which certainly favor individual groups and increases competition between interactions. This largely depends on which of these responses is predominant ("socialist" or "capitalist") at the moment plants are connected. Therefore, some plant species might benefit from CMNs more than others, depending on the fungal species and plant species involved in the association. Nevertheless, benefits and disadvantages from the interactions between the connected plants are hard to distinguish in nature once most of the plants are colonized simultaneously by multiple fungal species, each with its own cost-benefits. Classifying plant-microbe interactions based on their habitat specificity, such as their presence on leaf surfaces (phyllospheric), within plant tissues (endophytic), on root surfaces (rhizospheric), or as surface-dwelling organisms (epiphytic), helps to highlight the dense and intricate connections between plants and microbes that occur both above and below ground. In these complex relationships, microbes often engage in mutualistic interactions where both parties derive mutual benefits, exemplifying the socialistic or capitalistic nature of these interactions. This review discusses the ubiquity, functioning, and management interventions of different types of plant-plant and plant-microbe interactions in CMNs, and how they promote plant growth and address environmental challenges for sustainable agriculture. [ABSTRACT FROM AUTHOR]

Published

2024

34. Trichoderma spp. isolates stimulate rice seedling growth of Sertani 13 variety.

Author

Akbari, Sulistya Ika, Prismantoro, Dedat, Rossiana, Nia, and Doni, Febri

Subjects

*RICE varieties, *TRICHODERMA, *FILAMENTOUS fungi, *CROP growth, *CROP yields, *PLANT-microbe relationships

Abstract

Trichoderma has become one of the most studied filamentous fungi to be used as a greener and more sustainable solution for improving the production and growth of numerous crops, due to its capability to form symbiotic associations with plants. This study aimed to evaluate the effect of Trichoderma isolates obtained from the rhizosphere of organic rice fields in Sukabumi, Indonesia, in enhancing rice germination and seedling growth. A laboratory experiment used a completely randomized design consisting of seed treatments of 21 Trichoderma isolates (T1-T21) and a control treatment without Trichoderma (C). The inoculation was employed to elucidate any potential effects of Trichoderma isolates. Results showed that five isolates, i.e., T5, T7, T9, T10, and T14 stimulated the highest seedling vigor index, root and shoot length, and fresh weight and dry weight. These findings exhibited the potential of these five isolates as plant growth-promoting fungi to improve rice seedling growth and contribute to our understanding of the role of symbiotic fungi in sustainable rice crop production. [ABSTRACT FROM AUTHOR]

Published

2024

35. Traits-based approach: leveraging genome size in plant–microbe interactions.

Author

Zhang, Haiyang, Liu, Hongwei, and Han, Xingguo

Subjects

*GENOME size, *PLANT-microbe relationships, *PLANT genomes, *PLANT size, *PLANT ecology, *CELL nuclei, *PLANT nutrients, *MICROBIAL ecology

Abstract

Trait-based approaches in microbiome research can focus on species traits over identity, improving our understanding of microbiome functions in diverse environments. Functional traits, such as morphological, physiological, and chemical characteristics can predict ecological strategies of plant-associated microbes. Genome size in plants and microbes has physiological, ecological, and evolutionary implications to their growth, stress tolerance and nutrient acquisition; it may affect the size and outcomes of plant–microbe interactions. Variation in genome size impacts plant interactions with microbial communities. It can affect plant nutrient demand, carbon allocation, and exudation-mediated responses, leading to changes in microbiomes. Further studies integrating genomic traits into microbial ecology will help us to understand plant–microbe interactions and microbial evolution. Trait-based approaches have gained growing interest in studying plant–microbe interactions. However, current traits normally considered (e.g., morphological, physiological, or chemical traits) are biased towards those showing large intraspecific variations, necessitating the identification of fewer plastic traits that differ between species. Here, we propose using genome size (the amount of DNA in the nucleus of a cell) as a suitable trait for studying plant–microbiome interactions due to its relatively stable nature, minimally affected by external environmental variations. Emerging evidence suggests that plant genome size affects the plant-associated microbial community, and tissue-specific environments select microbes based on their genome size. These findings pinpoint environmental selection in genome size as an emerging driver of plant–microbiome interactions, potentially impacting ecosystem functions and productivity. [ABSTRACT FROM AUTHOR]

Published

2024

36. Customized plant microbiome engineering for food security.

Author

Batool, Maria, Carvalhais, Lilia C., Fu, Brendan, and Schenk, Peer M.

Subjects

*MICROBIAL inoculants, *FOOD security, *CROP yields, *SOIL amendments, *PLANT-microbe relationships, *CULTIVARS

Abstract

Optimizing beneficial plant–microbe interactions can significantly enhance plant growth and resilience, which may be achievable through a targeted step-by-step process using customized microbiome engineering. 'Plant/microbe-friendly' soils can be prepared through traditional and targeted soil amendments to increase microbial diversity and soil fertility to suit specific plant cultivation needs. 'Microbe-friendly' plants and genotypes should be chosen because different crops and varieties vastly differ in their ability to benefit from microbes. 'Plant-friendly' microbiomes can be generated by applying suitable functional microbial inoculants with optimal formulations and supportive substrates. Microbiome breeding, microbiome transplanting, and the use of artificial microbial consortia to fill microbiome functional deficiencies are promising emerging areas that warrant further validation. Plant microbiomes play a vital role in promoting plant growth and resilience to cope with environmental stresses. Plant microbiome engineering holds significant promise to increase crop yields, but there is uncertainty about how this can best be achieved. We propose a step-by-step approach involving customized direct and indirect methods to condition soils and to match plants and microbiomes. Although three approaches, namely the development of (i) 'plant- and microbe-friendly' soils, (ii) 'microbe-friendly' plants, and (iii) 'plant-friendly' microbiomes, have been successfully tested in isolation, we propose that the combination of all three may lead to a step-change towards higher and more stable crop yields. This review aims to provide knowledge, future directions, and practical guidance to achieve this goal via customized plant microbiome engineering. Plant microbiomes play a vital role in promoting plant growth and resilience to cope with environmental stresses. Plant microbiome engineering holds significant promise to increase crop yields, but there is uncertainty about how this can best be achieved. We propose a step-by-step approach involving customized direct and indirect methods to condition soils and to match plants and microbiomes. Although three approaches, namely the development of (i) 'plant- and/or microbe-friendly' soils, (ii) 'microbe-friendly' plants, and (iii) 'plant-friendly' microbiomes, have been successfully tested in isolation, we propose that the combination of all three may lead to a step-change towards higher and more stable crop yields. This review aims to provide knowledge, future directions, and practical guidance to achieve this goal via customized plant microbiome engineering. [ABSTRACT FROM AUTHOR]

Published

2024

37. Bacterial endophytome sources, profile and dynamics--a conceptual framework.

Author

Lengrand, Salomé, Pesenti, Lena, Bragard, Claude, and Legrève, Anne

Subjects

PLANT-microbe relationships, PLANT yields, ABIOTIC stress, PLANT growth, GENOMICS

Abstract

Currently, it seems inconceivable to dispute the major role of microorganisms in human health or insects with endosymbionts. Although microbial endophytes were discovered long ago, little is known about the roles of plant-associated microorganisms. Some endophytes are horizontally transmitted, whereas others are seed-borne; together, they influence plant health. Beneficial endophytes can promote plant growth and yield by increasing plant resistance to biotic and abiotic stresses. Recently, the tools available to study the phytobiome have much improved, opening doors for a better understanding of the fascinating interactions taking place at the plant level. This review redefines the conceptual framework for "endophyte" and "endophytome," focusing on the intricate dynamics of bacterial endophytomes. Systematically examining the formation pathways and profiling endophytes allows for a comprehensive exploration of the intricate dynamics governing plant-microbe interactions. Additionally, the assessment of how endophytomes are influenced by both biotic and abiotic factors provides essential insights into the adaptability and resilience of plantassociated microorganisms. Our comprehensive analysis integrates genomic insights with environmental considerations, offering a nuanced perspective on the functional roles of bacterial endophytomes. Therefore, a new, inclusive definition is essential to accurately represent the complexity of interactions within the plant microbiome as well as having the whole picture of associated concepts. [ABSTRACT FROM AUTHOR]

Published

2024

38. A single laccase acts as a key component of environmental sensing in a broad host range fungal pathogen.

Author

Westrick, Nathaniel M., Dominguez, Eddie G., Bondy, Madeline, Hull, Christina M., Smith, Damon L., and Kabbage, Mehdi

Subjects

*SCLEROTINIA sclerotiorum, *LACCASE, *FUNGAL cell walls, *PHYTOPATHOGENIC microorganisms, *PLANT-microbe relationships, *GENE silencing, *TRANSMISSION electron microscopy

Abstract

Secreted laccases are important enzymes on a broad ecological scale for their role in mediating plant-microbe interactions, but within ascomycete fungi these enzymes have been primarily associated with melanin biosynthesis. In this study, a putatively secreted laccase, Sslac2, was characterized from the broad-host-range plant pathogen Sclerotinia sclerotiorum, which is largely unpigmented and is not dependent on melanogenesis for plant infection. Gene knockouts of Sslac2 demonstrate wide ranging developmental phenotypes and are functionally non-pathogenic. These mutants also displayed indiscriminate growth behaviors and enhanced biomass formation, seemingly as a result of their inability to respond to canonical environmental growth cues, a phenomenon further confirmed through chemical stress, physiological, and transcriptomic analyses. Transmission and scanning electron microscopy demonstrate apparent differences in extracellular matrix structure between WT and mutant strains that likely explain the inability of the mutants to respond to their environment. Targeting Sslac2 using host-induced gene silencing significantly improved resistance to S. sclerotiorum, suggesting that fungal laccases could be a valuable target of disease control. Collectively, we identified a laccase critical to the development and virulence of the broad-host-range pathogen S. sclerotiorum and propose a potentially novel role for fungal laccases in modulating environmental sensing. A laccase was found to act as a key component of environmental sensing in the fungal plant pathogen Sclerotinia sclerotiorum. This study demonstrates the role that this laccase plays in fungal cell wall architecture and virulence on plant tissue. [ABSTRACT FROM AUTHOR]

Published

2024

39. Volatile communication in plants relies on a KAI2-mediated signaling pathway.

Author

Stirling, Shannon A., Guercio, Angelica M., Patrick, Ryan M., Xing-Qi Huang, Bergman, Matthew E., Dwivedi, Varun, Kortbeek, Ruy W. J., Yi-Kai Liu, Fuai Sun, Tao, W. Andy, Ying Li, Boachon, Benoît, Shabek, Nitzan, and Dudareva, Natalia

Subjects

*CELLULAR signal transduction, *MORPHOGENESIS, *PLANT-microbe relationships, *VOLATILE organic compounds, *GENITALIA

Abstract

Plants are constantly exposed to volatile organic compounds (VOCs) that are released during plant-plant communication, within-plant self-signaling, and plant-microbe interactions. Therefore, understanding VOC perception and downstream signaling is vital for unraveling the mechanisms behind information exchange in plants, which remain largely unexplored. Using the hormone-like function of volatile terpenoids in reproductive organ development as a system with a visual marker for communication, we demonstrate that a petunia karrikin-insensitive receptor, PhKAI2ia, stereospecifically perceives the (−)-germacrene D signal, triggering a KAI2-mediated signaling cascade and affecting plant fitness. This study uncovers the role(s) of the intermediate clade of KAI2 receptors, illuminates the involvement of a KAI2ia-dependent signaling pathway in volatile communication, and provides new insights into plant olfaction and the long-standing question about the nature of potential endogenous KAI2 ligand(s). [ABSTRACT FROM AUTHOR]

Published

2024

40. Isolation and characterization of a newly discovered plant growth-promoting endophytic fungal strain from the genus Talaromyces.

Author

Kharkwal, Amit C., Joshi, Hemesh, Shandilya, Cheshta, Dabral, Surbhi, Kumar, Niraj, and Varma, Ajit

Subjects

*PLANT growth, *TALAROMYCES, *PLANT colonization, *INDOLEACETIC acid, *PLANT-microbe relationships, *FUNGAL colonies

Abstract

In the Kandi zone of Punjab, India, root and rhizospheric soil samples were collected from the local vegetation near the Shivalik mountain foothills. Fifteen fungal colonies exhibiting distinct cultural morphology on Potato Dextrose Agar (PDA) plates were selected for plant–microbe interaction studies. Among these, the isolate HNB9 was identified as a nonpathogenic root colonizer. Morphological and molecular analyses confirmed HNB9 as Talaromyces albobiverticillius, characterized by the secretion of a red pigment as a secondary metabolite. Plants colonized with T. albobiverticillius HNB9 exhibited enhanced growth, manifesting in increased shoot and root length compared to untreated controls. This study unveiled the first evidence that a species from the Talaromyces genus, specifically T. albobiverticillius, possesses dual capabilities of root colonization and plant growth promotion. Moreover, HNB9 demonstrated the production of plant growth-regulating compounds like Indole Acetic Acid (IAA) and proficient solubilization of crucial nutrients (Phosphorous, Zinc, and Silica) through plate culture methods. This finding represents a significant contribution to the understanding of root-colonizing fungi with plant growth-promoting attributes, challenging the existing knowledge gap within the Talaromyces genus. [ABSTRACT FROM AUTHOR]

Published

2024

41. Getting to the root of divergent outcomes in the modulation of plant–soil feedbacks by benzoxazinoids.

Author

Bass, Ethan

Subjects

*PLANT-microbe relationships, *PLANT defenses, *METABOLITES

Abstract

This article is a Commentary on Gfeller et al. (2024), 241: 2575–2588. [ABSTRACT FROM AUTHOR]

Published

2024

42. Latex – a potential plant defense against microbes.

Author

Huber, Meret

Subjects

*PLANT defenses, *LATEX, *MICROBIAL growth, *MICROORGANISMS, *PLANT-microbe relationships

Abstract

Laticifers – among the most common defensive reservoirs in plants – are hypothesized to benefit plant fitness by preventing microbes from entering wounds. I argue that while latex seals wounds, and can suppress microbial growth, direct evidence that these processes benefit plant fitness is scarce. I outline a roadmap for filling this knowledge gap. [ABSTRACT FROM AUTHOR]

Published

2024

43. Successional changes in bacterial phyllosphere communities are plant-host species dependent.

Author

Bechtold, Emily K., Wanek, Wolfgang, Nuesslein, Benedikt, DaCosta, Michelle, and Nüsslein, Klaus

Subjects

*BACTERIAL communities, *HOST plants, *AGRICULTURE, *MICROBIAL communities, *ECOLOGICAL models, *AGRICULTURAL productivity

Abstract

Phyllosphere microbial communities are increasingly experiencing intense pulse disturbance events such as drought. It is currently unknown how phyllosphere communities respond to such disturbances and if they are able to recover. We explored the stability of phyllosphere communities over time, in response to drought stress, and under recovery from drought on temperate forage grasses. Compositional or functional changes were observed during the disturbance period and whether communities returned to non-stressed levels following recovery. Here, we found that phyllosphere community composition shifts as a result of simulated drought but does not fully recover after irrigation is resumed and that the degree of community response to drought is host species dependent. However, while community composition had changed, we found a high level of functional stability (resistance) over time and in the water deficit treatment. Ecological modeling enabled us to understand community assembly processes over a growing season and to determine if they were disrupted during a disturbance event. Phyllosphere community succession was characterized by a strong level of ecological drift, but drought disturbance resulted in variable selection, or, in other words, communities were diverging due to differences in selective pressures. This successional divergence of communities with drought was unique for each host species. Understanding phyllosphere responses to environmental stresses is important as climate change-induced stresses are expected to reduce crop productivity and phyllosphere functioning. IMPORTANCE Leaf surface microbiomes have the potential to influence agricultural and ecosystem productivity. We assessed their stability by determining composition, functional resistance, and resilience. Resistance is the degree to which communities remain unchanged as a result of disturbance, and resilience is the ability of a community to recover to pre-disturbance conditions. By understanding the mechanisms of community assembly and how they relate to the resistance and resilience of microbial communities under common environmental stresses such as drought, we can better understand how communities will adapt to a changing environment and how we can promote healthy agricultural microbiomes. In this study, phyllosphere compositional stability was highly related to plant host species phylogeny and, to a lesser extent, known stress tolerances. Phyllosphere community assembly and stability are a result of complex interactions of ecological processes that are differentially imposed by host species. [ABSTRACT FROM AUTHOR]

Published

2024

44. Plant–microbe interactions through a lens: tales from the mycorrhizosphere.

Author

Williams, Alex, Sinanaj, Besiana, and Hoysted, Grace A

Subjects

*SCIENTIFIC knowledge, *PLANT-microbe relationships, *AGRICULTURE, *SOIL biodiversity, *EFFECT of human beings on climate change, *ECOSYSTEMS, *BIOFILMS, *VESICULAR-arbuscular mycorrhizas

Abstract

Background The soil microbiome plays a pivotal role in maintaining ecological balance, supporting food production, preserving water quality and safeguarding human health. Understanding the intricate dynamics within the soil microbiome necessitates unravelling complex bacterial–fungal interactions (BFIs). BFIs occur in diverse habitats, such as the phyllosphere, rhizosphere and bulk soil, where they exert substantial influence on plant–microbe associations, nutrient cycling and overall ecosystem functions. In various symbiotic associations, fungi form mycorrhizal connections with plant roots, enhancing nutrient uptake through the root and mycorrhizal pathways. Concurrently, specific soil bacteria, including mycorrhiza helper bacteria, play a pivotal role in nutrient acquisition and promoting plant growth. Chemical communication and biofilm formation further shape plant–microbial interactions, affecting plant growth, disease resistance and nutrient acquisition processes. Scope Promoting synergistic interactions between mycorrhizal fungi and soil microbes holds immense potential for advancing ecological knowledge and conservation. However, despite the significant progress, gaps remain in our understanding of the evolutionary significance, perception, functional traits and ecological relevance of BFIs. Here we review recent findings obtained with respect to complex microbial communities – particularly in the mycorrhizosphere – and include the latest advances in the field, outlining their profound impacts on our understanding of ecosystem dynamics and plant physiology and function. Conclusions Deepening our understanding of plant BFIs can help assess their capabilities with regard to ecological and agricultural safe-guarding, in particular buffering soil stresses, and ensuring sustainable land management practices. Preserving and enhancing soil biodiversity emerge as critical imperatives in sustaining life on Earth amidst pressures of anthropogenic climate change. A holistic approach integrates scientific knowledge on bacteria and fungi, which includes their potential to foster resilient soil ecosystems for present and future generations. [ABSTRACT FROM AUTHOR]

Published

2024

45. Insights into Bacterial Extracellular Vesicle Biogenesis, Functions, and Implications in Plant–Microbe Interactions.

Author

Pandey, Sarita, Blache, Anaïs, and Achouak, Wafa

Subjects

PLANT-microbe relationships, EXTRACELLULAR vesicles, CELL communication, PLANT defenses, NON-coding RNA

Abstract

Plant–microbe interactions play a crucial role in shaping plant health and survival. In recent years, the role of extracellular vesicles (EVs) in mediating intercellular communication between plants and microbes has emerged as an intriguing area of research. EVs serve as important carriers of bioactive molecules and genetic information, facilitating communication between cells and even between different organisms. Pathogenic bacteria leverage extracellular vesicles (EVs) to amplify their virulence, exploiting their cargo rich in toxins and virulence factors. Conversely, beneficial microbes initiate EV secretion to stimulate plant immune responses and nurture symbiotic relationships. The transfer of EV-packed small RNAs (sRNAs) has been demonstrated to facilitate the modulation of immune responses. Furthermore, harnessing the potential of EVs holds promise for the development of innovative diagnostic tools and sustainable crop protection strategies. This review highlights the biogenesis and functions of EVs in bacteria and their importance in plant defense, and paves the way for future research in this exciting field. [ABSTRACT FROM AUTHOR]

Published

2024

46. Exploring Cereal Metagenomics: Unravelling Microbial Communities for Improved Food Security.

Author

Masenya, Kedibone, Manganyi, Madira Coutlyne, and Dikobe, Tshegofatso Bridget

Subjects

FOOD security, MICROBIAL communities, METAGENOMICS, PLANT-microbe relationships, SUSTAINABILITY, MICROBIAL diversity

Abstract

Food security is an urgent global challenge, with cereals playing a crucial role in meeting the nutritional requirements of populations worldwide. In recent years, the field of metagenomics has emerged as a powerful tool for studying the microbial communities associated with cereal crops and their impact on plant health and growth. This chapter aims to provide a comprehensive overview of cereal metagenomics and its role in enhancing food security through the exploration of beneficial and pathogenic microbial interactions. Furthermore, we will examine how the integration of metagenomics with other tools can effectively address the adverse effects on food security. For this purpose, we discuss the integration of metagenomic data and machine learning in providing novel insights into the dynamic interactions shaping plant-microbe relationships. We also shed light on the potential applications of leveraging microbial diversity and epigenetic modifications in improving crop resilience and yield sustainability. Ultimately, cereal metagenomics has revolutionized the field of food security by harnessing the potential of beneficial interactions between cereals and their microbiota, paving the way for sustainable agricultural practices. [ABSTRACT FROM AUTHOR]

Published

2024

47. Effects of Different Heavy Metal Stressors on the Endophytic Community Composition and Diversity of Symphytum officinale.

Author

Ma, Jing, Chen, Dawei, Xu, Yifan, Liu, Yue, Liu, Lele, Huang, Jing, Gao, Ruochun, Bai, Jie, and Hou, Qinzheng

Subjects

ENDOPHYTIC bacteria, HEAVY metals, PLANT-microbe relationships, ENDOPHYTIC fungi, PLANT-fungus relationships, HOST plants, FUNGAL communities, BACTERIAL diversity

Abstract

Endophytes play an important role in helping plants resist heavy metal stress. However, little is known about the effects of different heavy metals on the diversity and composition of endophyte communities. In this study, we used 16S and ITS amplicon sequencing to reveal the structure and function of endophytes in Symphytum officinale under different heavy metal stressors. The results showed that the endophytic fungal diversity decreased compared with the control under the different heavy metals stressors, while the diversity of endophytic bacteria showed an increasing trend. The biomarker analysis indicated that Zn and Pb stress led to obvious branches. Specific OTUs analysis showed that there were 1224, 597, and 1004 OTUs specific under Zn, Pb, and Cd stress in the bacterial community and 135, 81, and 110 OTUs specific under Zn, Pb, and Cd stress in the fungal community. The co-occurrence network showed changes in microbial interactions under heavy metal contamination conditions, suggesting that endophytic bacteria play an important role in the resistance of host plants. The Spearman analysis showed that the correlation between endophytic bacteria and endophytic fungi in relation to heavy metal transport exhibited variations. Our results expand the knowledge of the relationships of plant–microbe interactions and offer pivotal information to reveal the role of endophytes under different heavy metal stress conditions. [ABSTRACT FROM AUTHOR]

Published

2024

48. Plant-Microbe Interactions under the Extreme Habitats and Their Potential Applications.

Author

Tiwari, Pragya, Bose, Subir Kumar, Park, Kyeung-Il, Dufossé, Laurent, and Fouillaud, Mireille

Subjects

PLANT-microbe relationships, BIOLOGICAL evolution, EXTREME environments, PLANT adaptation, HABITATS, PHYSIOLOGICAL adaptation

Abstract

Plant-microbe associations define a key interaction and have significant ecological and biotechnological perspectives. In recent times, plant-associated microbes from extreme environments have been extensively explored for their multifaceted benefits to plants and the environment, thereby gaining momentum in global research. Plant-associated extremophiles highlight ubiquitous occurrences, inhabiting extreme habitats and exhibiting enormous diversity. The remarkable capacity of extremophiles to exist in extreme environmental conditions is attributed to the evolution of adaptive mechanisms in these microbes at genetic and physiological levels. In addition, the plant-associated extremophiles have a major impact in promoting plant growth and development and conferring stress tolerance to the host plant, thereby contributing immensely to plant adaptation and survival in extreme conditions. Considering the major impact of plant-associated extremophiles from a socio-economic perspective, the article discusses their significance in emerging biotechnologies with a key focus on their ecological role and dynamic interaction with plants. Through this article, the authors aim to discuss and understand the favorable impact and dynamics of plant-associated extremophiles and their biotechnological utilities. [ABSTRACT FROM AUTHOR]

Published

2024

49. Heavy metals/-metalloids (As) phytoremediation with Landoltia punctata and Lemna sp. (duckweeds): coupling with biorefinery prospects for sustainable phytotechnologies.

Author

Rai, Prabhat Kumar and Nongtri, Emacaree S

Subjects

LEMNA minor, PHYTOREMEDIATION, DUCKWEEDS, HEAVY metals removal (Sewage purification), CIRCULAR economy, PLANT-microbe relationships, SEMIMETALS

Abstract

Heavy metals/-metalloids can result in serious human health hazards. Phytoremediation is green bioresource technology for the remediation of heavy metals and arsenic (As). However, there exists a knowledge gap and systematic information on duckweed-based metal phytoremediation in an eco-sustainable way. Therefore, the present review offers a critical discussion on the effective use of duckweeds (genera Landoltia and Lemna)-based phytoremediation to decontaminate metallic contaminants from wastewater. Phytoextraction and rhizofiltration were the major mechanism in 'duckweed bioreactors' that can be dependent on physico-chemical factors and plant-microbe interactions. The biotechnological advances such as gene manipulations can accelerate the duckweed-based phytoremediation process. High starch and protein contents of the metal-loaded duckweed biomass facilitate their use as feedstock in biorefinery. Biorefinery prospects such as bioenergy production, value-added products, and biofertilizers can augment the circular economy approach. Coupling duckweed-based phytoremediation with biorefinery can help achieve Sustainable Development Goals (SDGs) and human well-being. [ABSTRACT FROM AUTHOR]

Published

2024

50. Mysterious spinifex grass rings of the Australian outback May be caused by microbes

Author

Gordon, Len

Published

2021