Your search keyword '"endosphere"' showing total 221 results

201. Changes induced by heavy metals in the plant-associated microbiome of Miscanthus x giganteus.

Author

Zadel U, Nesme J, Michalke B, Vestergaard G, Płaza GA, Schröder P, Radl V, and Schloter M

Subjects

Biodegradation, Environmental, Metals, Heavy, Plant Roots, RNA, Ribosomal, 16S, Rhizosphere, Soil, Soil Pollutants, Microbiota

Abstract

Miscanthus x giganteus is a high biomass producing plant with tolerance to heavy metals. This makes Miscanthus interesting to be used for phytoremediation of heavy metal contaminated areas coupled with energy production. Since plant performance in metal polluted areas is impaired, their growth and phytoremediation effect can be improved with bacterial assistance. To identify positive and negative responders of M. x giganteus associated microbiome influenced by Cd, Pb and Zn stress compared to non-contaminated controls, we designed a greenhouse experiment. Structure of the bacterial community in three rhizocompartments, namely rhizosphere, rhizoplane and root endosphere was analysed using an isolation independent molecular approach based on 16S rRNA gene barcoding. Furthermore, quantitative PCR (qPCR) was used for bacterial biomass estimation. Our results indicated that biomass and total bacterial diversity in rhizosphere, rhizoplane and root endosphere did not significantly change despite of substantial root uptake of heavy metals. Overall, we detected 6621 OTUs, from which 171 were affected by metal addition. Whereas Streptomyces and Amycolatopsis taxa were negatively affected by the heavy metal treatment in endosphere, taxa assigned to Luteolibacter in rhizosphere and rhizoplane (log 2 fold change 1.9-4.1) and Micromonospora in endosphere (log 2 fold change 10.2) were found to be significantly enriched and highly abundant (0.1-3.7% relative abundance) under heavy metal stress. Those taxa might be of key importance for M. x giganteus performance under heavy metal pollution and might be interesting candidates for the development of new bioinocula in the future to promote plant growth and phytoremediation in heavy metal contaminated soils., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2020

202. Comparative Analysis of Root Microbiomes of Rice Cultivars with High and Low Methane Emissions Reveals Differences in Abundance of Methanogenic Archaea and Putative Upstream Fermenters.

Author

Liechty Z, Santos-Medellín C, Edwards J, Nguyen B, Mikhail D, Eason S, Phillips G, and Sundaresan V

Abstract

Rice cultivation worldwide accounts for ∼7 to 17% of global methane emissions. Methane cycling in rice paddies is a microbial process not only involving methane producers (methanogens) and methane metabolizers (methanotrophs) but also other microbial taxa that affect upstream processes related to methane metabolism. Rice cultivars vary in their rates of methane emissions, but the influence of rice genotypes on methane cycling microbiota has been poorly characterized. Here, we profiled the rhizosphere, rhizoplane, and endosphere microbiomes of a high-methane-emitting cultivar (Sabine) and a low-methane-emitting cultivar (CLXL745) throughout the growing season to identify variations in the archaeal and bacterial communities relating to methane emissions. The rhizosphere of the high-emitting cultivar was enriched in methanogens compared to that in the low emitter, whereas the relative abundances of methanotrophs between the cultivars were not significantly different. Further analysis of cultivar-sensitive taxa identified families enriched in the high emitter that are associated with methanogenesis-related processes. The high emitter had greater relative abundances of sulfate-reducing and iron-reducing taxa which peak earlier in the season than methanogens and are necessary to lower soil oxidation reduction potential before methanogenesis can occur. The high emitter also had a greater abundance of fermentative taxa which produce methanogenesis precursors (acetate, CO 2 , and H 2 ). Furthermore, the high emitter was enriched in taxa related to acetogenesis which compete with methanogens for CO 2 and H 2 These taxa were enriched in a spatio-specific manner and reveal a complex network of microbial interactions on which plant genotype-dependent factors can act to affect methanogenesis and methane emissions. IMPORTANCE Rice cultivation is a major source of anthropogenic emissions of methane, a greenhouse gas with a potentially severe impact on climate change. Emission variation between rice cultivars suggests the feasibility of breeding low-emission rice, but there is a limited understanding of how genotypes affect the microbiota involved in methane cycling. Here, we show that the root microbiome of the high-emitting cultivar is enriched both in methanogens and in taxa associated with fermentation, iron, and sulfate reduction and acetogenesis, processes that support methanogenesis. Understanding how cultivars affect microbes with methanogenesis-related functions is vital for understanding the genetic basis for methane emission in rice and can aid in the development of breeding programs that reduce the environmental impact of rice cultivation., (Copyright © 2020 Liechty et al.)

Published

2020

203. Comparison of Microbial Community of Rhizosphere and Endosphere in Kiwifruit.

Author

Kim MJ, Do H, Cho G, Jeong RD, and Kwak YS

Abstract

Understanding the microbial community and function are crucial knowledge for crop management. In this study, bacterial and fungal community structures both rhizosphere and endosphere in kiwifruit were analyzed to gain our knowledge in kiwifruit microbiome. Microbial community in rhizosphere was less variation than endosphere community. Functional prediction results demonstrated that abundance of saprotrophic fungi was similar in both rhizosphere and endosphere, but potential pathogenic fungi was more abundance in endosphere than in rhizosphere. This finding suggested that maintain healthy soil is the first priority to protect the host plant against biotic stresses., (© The Korean Society of Plant Pathology.)

Published

2019

204. Microbiomes inhabiting rice roots and rhizosphere.

Author

Ding, Long-Jun, Cui, Hui-Ling, Nie, San-An, Long, Xi-En, Duan, Gui-Lan, and Zhu, Yong-Guan

Subjects

*RICE, *BIOGEOCHEMICAL cycles, *RHIZOSPHERE, *MICROBIAL diversity, *MICROBIAL communities, *PADDY fields

Abstract

Land plants directly contact soil through their roots. An enormous diversity of microbes dwelling in root-associated zones, including endosphere (inside root), rhizoplane (root surface) and rhizosphere (soil surrounding the root surface), play essential roles in ecosystem functioning and plant health. Rice is a staple food that feeds over 50% of the global population. Its root is a unique niche, which is often characterized by an oxic region (e.g. the rhizosphere) surrounded by anoxic bulk soil. This oxic-anoxic interface has been recognized as a pronounced hotspot that supports dynamic biogeochemical cycles mediated by various functional microbial groups. Considering the significance of rice production upon global food security and the methane budget, novel insights into how the overall microbial community (i.e. the microbiome) of the rice root system influences ecosystem functioning is the key to improving crop health and sustainable productivity of paddy ecosystems, and alleviating methane emissions. This mini-review summarizes the current understanding of microbial diversity of rice root-associated compartments to some extent, especially the rhizosphere, and makes a comparison of rhizosphere microbial community structures between rice and other crops/plants. Moreover, this paper describes the interactions between root-related microbiomes and rice plants, and further discusses the key factors shaping the rice root-related microbiomes. [ABSTRACT FROM AUTHOR]

Published

2019

205. Impact of Bacterial-Fungal Interactions on the Colonization of the Endosphere

Author

Leonard S. van Overbeek and Kari Saikkonen

Subjects

0301 basic medicine, Mixed biofilms, Plant Science, Endophyte, 03 medical and health sciences, Mutualism, Bioint Diagnostics, Plant defense against herbivory, Endophytes, Colonization, Bioint Diagnostics, Food Safety & Phyt. Research, Scientific disciplines, Mutualism (biology), Rhizosphere, biology, Bacteria, Ecology, fungi, Biofilm, Fungi, Plants, PE&RC, biology.organism_classification, Bacterial-fungal interactions, Food Safety & Phyt. Research, 030104 developmental biology, Microbial Interactions, Endosphere

Abstract

Research on different endophyte taxa and the related scientific disciplines have largely developed separately, and comprehensive community-level studies on bacterial and fungal interactions and their importance are lacking. Here, we discuss the transmission modes of bacteria and fungi and the nature of their interactions in the endosphere at both the molecular and physiological level. Mixed-community biofilms in the endosphere may have a role in protecting endophytes against encountered stresses, such as from plant defense systems. However, transmission from static (in biofilms) to free-living (planktonic) forms may be crucial for the exploration of new habitable spaces in plants. Important features previously recognized as plant-microbe interactions or antagonism in endophyte genomes and metagenomes are proposed to have essential roles in the modulation of endophyte communities. No general consensus can be provided on the precise ecological boundaries of different types of endophyte or on the establishment of their interactions with plants.Traditionally, understanding of bacterial and fungal endophytes developed in separate research fields and both taxa have rarely been studied in one single integrated approach.Interactions between plants and individual populations of endophytes are key in most studies and, with the exception of antagonism against phytopathogens, no other interactions between members of the endophytic communities have been taken into account.The inner tissues of plants are hostile environments to most microorganisms due to competition with the host plant and with other microbes for nutrients and available space.

Published

2015

206. Metabolic functions of Pseudomonas fluorescens strains from Populus deltoides depend on rhizosphere or endosphere isolation compartment

Author

Steven D. Brown, Mitchel J. Doktycz, Watumesa A. Tan, Sagar M. Utturkar, David J. Weston, Se-Ran Jun, Tse-Yuan S. Lu, Alisha G. Campbell, Gerald A. Tuskan, Christopher W. Schadt, Rebecca E. Parales, Collin M. Timm, David W. Ussery, Michael S. Robeson, Sara S. Jawdy, and Dale A. Pelletier

Subjects

Microbiology (medical), Environmental Science and Management, medicine.medical_treatment, lcsh:QR1-502, microbiome, Pseudomonas fluorescens, Plant Science, Biology, Microbiology, lcsh:Microbiology, metabolic modeling, Botany, medicine, Colonization, Microbiome, Original Research, Comparative genomics, Rhizosphere, Protease, biology.organism_classification, Metabolic pathway, Populus, endosphere, Soil Sciences, rhizosphere, metabolism, Bacteria

Abstract

The bacterial microbiota of plants is diverse, with 1000s of operational taxonomic units (OTUs) associated with any individual plant. In this work, we used phenotypic analysis, comparative genomics, and metabolic models to investigate the differences between 19 sequenced Pseudomonas fluorescens strains. These isolates represent a single OTU and were collected from the rhizosphere and endosphere of Populus deltoides. While no traits were exclusive to either endosphere or rhizosphere P. fluorescens isolates, multiple pathways relevant for plant-bacterial interactions are enriched in endosphere isolate genomes. Further, growth phenotypes such as phosphate solubilization, protease activity, denitrification and root growth promotion are biased toward endosphere isolates. Endosphere isolates have significantly more metabolic pathways for plant signaling compounds and an increased metabolic range that includes utilization of energy rich nucleotides and sugars, consistent with endosphere colonization. Rhizosphere P. fluorescens have fewer pathways representative of plant-bacterial interactions but show metabolic bias toward chemical substrates often found in root exudates. This work reveals the diverse functions that may contribute to colonization of the endosphere by bacteria and are enriched among closely related isolates.

Published

2015

207. Improved plant resistance to drought is promoted by the root-associated microbiome as a water stress-dependent trait

Author

Daffonchio, Daniele Giuseppe and Vigani, Gianpiero

Subjects

pepper, endosphere, drought stress, grapevine, plant growth promoting bacteria, rhizosphere

Published

2015

208. The bacterial rhizobiome of hyperaccumulators: future perspectives based on omics analysis and advanced microscopy

Author

Giovanna Visioli, Sara D’Egidio, and Anna Maria Sanangelantoni

Subjects

Rhizosphere, Microorganism, fungi, food and beverages, metals, Context (language use), Phytoextraction process, Plant Science, phytoremediation, lcsh:Plant culture, Biology, hyperaccumulators, biology.organism_classification, omics, Phytoremediation, Mini Review Article, Microbial population biology, endosphere, Botany, microscopy, lcsh:SB1-1110, Hyperaccumulator, rhizosphere, Bacteria

Abstract

Hyperaccumulators are plants that can extract heavy metal ions from the soil and translocate those ions to the shoots, where they are sequestered and detoxified. Hyperaccumulation depends not only on the availability of mobilized metal ions in the soil, but also on the enhanced activity of metal transporters and metal chelators which may be provided by the plant or its associated microbes. The rhizobiome is captured by plant root exudates from the complex microbial community in the soil, and may colonize the root surface or infiltrate the root cortex. This community can increase the root surface area by inducing hairy root proliferation. It may also increase the solubility of metals in the rhizosphere and promote the uptake of soluble metals by the plant. The bacterial rhizobiome, a subset of specialized microorganisms that colonize the plant rhizosphere and endosphere, makes an important contribution to the hyperaccumulator phenotype. In this review, we discuss classic and more recent tools that are used to study the interactions between hyperaccumulators and the bacterial rhizobiome, and consider future perspectives based on the use of omics analysis and microscopy to study plant metabolism in the context of metal accumulation. Recent data suggest that metal-resistant bacteria isolated from the hyperaccumulator rhizosphere and endosphere could be useful in applications such as phytoextraction and phytoremediation, although more research is required to determine whether such properties can be transferred successfully to non-accumulator species.

Published

2015

209. Metabolic functions of Pseudomonas fluorescens strains from Populus deltoides depend on rhizosphere or endosphere isolation compartment.

Author

Timm, Collin M, Timm, Collin M, Campbell, Alisha G, Utturkar, Sagar M, Jun, Se-Ran, Parales, Rebecca E, Tan, Watumesa A, Robeson, Michael S, Lu, Tse-Yuan S, Jawdy, Sara, Brown, Steven D, Ussery, David W, Schadt, Christopher W, Tuskan, Gerald A, Doktycz, Mitchel J, Weston, David J, Pelletier, Dale A, Timm, Collin M, Timm, Collin M, Campbell, Alisha G, Utturkar, Sagar M, Jun, Se-Ran, Parales, Rebecca E, Tan, Watumesa A, Robeson, Michael S, Lu, Tse-Yuan S, Jawdy, Sara, Brown, Steven D, Ussery, David W, Schadt, Christopher W, Tuskan, Gerald A, Doktycz, Mitchel J, Weston, David J, and Pelletier, Dale A

Abstract

The bacterial microbiota of plants is diverse, with 1000s of operational taxonomic units (OTUs) associated with any individual plant. In this work, we used phenotypic analysis, comparative genomics, and metabolic models to investigate the differences between 19 sequenced Pseudomonas fluorescens strains. These isolates represent a single OTU and were collected from the rhizosphere and endosphere of Populus deltoides. While no traits were exclusive to either endosphere or rhizosphere P. fluorescens isolates, multiple pathways relevant for plant-bacterial interactions are enriched in endosphere isolate genomes. Further, growth phenotypes such as phosphate solubilization, protease activity, denitrification and root growth promotion are biased toward endosphere isolates. Endosphere isolates have significantly more metabolic pathways for plant signaling compounds and an increased metabolic range that includes utilization of energy rich nucleotides and sugars, consistent with endosphere colonization. Rhizosphere P. fluorescens have fewer pathways representative of plant-bacterial interactions but show metabolic bias toward chemical substrates often found in root exudates. This work reveals the diverse functions that may contribute to colonization of the endosphere by bacteria and are enriched among closely related isolates.

Published

2015

210. Diazotroph Diversity and Nitrogen Fixation in Summer Active Perennial Grasses in a Mediterranean Region Agricultural Soil.

Author

Gupta VVSR, Zhang B, Penton CR, Yu J, and Tiedje JM

Abstract

Summer-growing perennial grasses such as Panicum coloratum L. cv. Bambatsi (Bambatsi panic), Chloris gayana Kunth cv. Katambora (Rhodes grass) and Digitaria eriantha Steud. cv. Premier (Premier digit grass) growing in the poor fertility sandy soils in the Mediterranean regions of southern Australia and western Australia mainly depend upon soil N and biological N inputs through diazotrophic (free living or associative) N fixation. We investigated the community composition and diversity ( nifH -amplicon sequencing), abundance (qPCR) and functional capacity ( 15 N incubation assay) of the endophytic diazotrophic community in the below and above ground plant parts of field grown and unfertilized grasses. Results showed a diverse and abundant diazotrophic community inside plant both above and below-ground and there was a distinct diazotrophic assemblage in the different plant parts in all the three grasses. There was a limited difference in the diversity between leaves, stems and roots except that Panicum grass roots harbored greater species richness. Nitrogen fixation potentials ranged between 0.24 and 5.9 mg N kg -1 day -1 and N fixation capacity was found in both the above and below ground plant parts. Results confirmed previous reports of plant species-based variation and that Alpha-Proteobacteria were the dominant group of nifH -harboring taxa both in the belowground and aboveground parts of the three grass species. Results also showed a well-structured nifH -harboring community in all plant parts, an example for a functional endophytic community. Overall, the variation in the number and identity of module hubs and connectors among the different plant parts suggests that co-occurrence patterns within the nifH-harboring community specific to individual compartments and local environments of the niches within each plant part may dictate the overall composition of diazotrophs within a plant., (Copyright © 2019 Gupta, Zhang, Penton, Yu and Tiedje.)

Published

2019

211. Chryseobacterium populi sp. nov., isolated from Populus deltoides endosphere.

Author

Bortniak VL, Pelletier DA, and Newman JD

Subjects

Bacterial Typing Techniques, Base Composition, Chryseobacterium isolation & purification, DNA, Bacterial genetics, Fatty Acids chemistry, Nucleic Acid Hybridization, Pigmentation, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Tennessee, Vitamin K 2 chemistry, Chryseobacterium classification, Phylogeny, Populus microbiology

Abstract

As part of a study investigating the rhizosphere and endosphere of the Eastern cottonwood tree, Populus deltoides, a number of isolates were subjected to genome sequencing. The genome-derived 16S rRNA gene sequence of strain CF314 T was 97.0 % similar to those of the Chryseobacterium daecheongense and Chryseobacterium polytrichastri type strains, but was essentially equidistant from many other Chryseobacterium type strains. Overall genome similarity metrics (average nucleotide identity, digital DNA-DNA hybridization, average amino acid identity) revealed greatest similarity to the Chryseobacterium daecheongense, Chryseobacterium piperi and Chryseobacterium soldanellicola type strains, but were well below the species thresholds. Strain CF314 T had a typical fatty acid composition for Chryseobacterium species and produced flexirubin pigments, but not carotenoids. The genome encodes a number of proteins such as a C-type lectin and terpene synthases that are also found in other plant-associated Bacteroidetes. Based on phenotypic and genomic characteristics of the strain, we propose the new species Chryseobacteriumpopuli. The type strain is CF314 T =KCTC 62722 T =LMG 30786 T .

Published

2019

212. Are drought-resistance promoting bacteria cross-compatible with different plant models?

Author

Claudia Sorlini, Hadda Ouzari, Sara Borin, Daniele Daffonchio, Ramona Marasco, Eleonora Rolli, Gianpiero Vigani, and Graziano Zocchi

Subjects

Short Communication, Drought tolerance, drought tolerance, Plant Science, Root system, plant growth promoting bacteria, Plant Roots, water stress, Pepper, Carbon-Carbon Lyases, Ecosystem, 2. Zero hunger, Rhizosphere, biology, Bacteria, business.industry, fungi, food and beverages, 15. Life on land, biology.organism_classification, arid ecosystem, Droughts, Agronomy, Agriculture, endosphere, Osmoprotectant, business, plant-bacteria cross-compatibility, Reactive Oxygen Species, Plant tolerance to herbivory

Abstract

The association between plant and plant growth promoting bacteria (PGPB) contributes to the successful thriving of plants in extreme environments featured by water shortage. We have recently shown that, with respect to the non-cultivated desert soil, the rhizosphere of pepper plants cultivated under desert farming hosts PGPB communities that are endowed with a large portfolio of PGP traits. Pepper plants exposed to bacterial isolates from plants cultivated under desert farming exhibited a higher tolerance to water shortage, compared with untreated control. This promotion was mediated by a larger root system (up to 40%), stimulated by the bacteria, that enhanced plant ability to uptake water from dry soil. We provide initial evidence that the nature of the interaction can have a limited level of specificity and that PGPB isolates may determine resistance to water stress in plants others than the one of the original isolation. It is apparent that, in relation to plant resistance to water stress, a feature of primary evolutionary importance for all plants, a cross-compatibility between PGPB and different plant models exists at least on a short-term.

Published

2013

213. Is Host Filtering the Main Driver of Phylosymbiosis across the Tree of Life?

Author

Mazel F, Davis KM, Loudon A, Kwong WK, Groussin M, and Parfrey LW

Abstract

Host-associated microbiota composition can be conserved over evolutionary time scales. Indeed, closely related species often host similar microbiota; i.e., the composition of their microbiota harbors a phylogenetic signal, a pattern sometimes referred to as "phylosymbiosis." Elucidating the origins of this pattern is important to better understand microbiota ecology and evolution. However, this is hampered by our lack of theoretical expectations and a comprehensive overview of phylosymbiosis prevalence in nature. Here, we use simulations to provide a simple expectation for when we should expect this pattern to occur and then review the literature to document the prevalence and strength of phylosymbiosis across the host tree of life. We demonstrate that phylosymbiosis can readily emerge from a simple ecological filtering process, whereby a given host trait (e.g., gut pH) that varies with host phylogeny (i.e., harbors a phylogenetic signal) filters preadapted microbes. We found marked differences between methods used to detect phylosymbiosis, so we proposed a series of practical recommendations based on using multiple best-performing approaches. Importantly, we found that, while the prevalence of phylosymbiosis is mixed in nature, it appears to be stronger for microbiotas living in internal host compartments (e.g., the gut) than those living in external compartments (e.g., the rhizosphere). We show that phylosymbiosis can theoretically emerge without any intimate, long-term coevolutionary mechanisms and that most phylosymbiosis patterns observed in nature are compatible with a simple ecological process. Deviations from baseline ecological expectations might be used to further explore more complex hypotheses, such as codiversification. IMPORTANCE Phylosymbiosis is a pattern defined as the tendency of closely related species to host microbiota whose compositions resemble each other more than host species drawn at random from the same tree. Understanding the mechanisms behind phylosymbiosis is important because it can shed light on rules governing the assembly of host-associated microbiotas and, potentially, their coevolutionary dynamics with hosts. For example, is phylosymbiosis a result of coevolution, or can it be generated by simple ecological filtering processes? Beyond qualitative theoretical models, quantitative theoretical expectations can provide new insights. For example, deviations from a simple baseline of ecological filtering may be used to test more-complex hypotheses (e.g., coevolution). Here, we use simulations to provide evidence that simple host-related ecological filtering can readily generate phylosymbiosis, and we contrast these predictions with real-world data. We find that while phylosymbiosis is widespread in nature, phylosymbiosis patterns are compatible with a simple ecological model in the majority of taxa. Internal compartments of hosts, such as the animal gut, often display stronger phylosymbiosis than expected from a purely ecological filtering process, suggesting that other mechanisms are also involved.

Published

2018

214. Extraction and 16S rRNA Sequence Analysis of Microbiomes Associated with Rice Roots.

Author

Edwards J, Santos-Medellín C, and Sundaresan V

Abstract

Plant roots associate with a wide diversity of bacteria and archaea across the root-soil spectrum. The rhizosphere microbiota, the communities of microbes in the soil adjacent to the root, can contain up to 10 billion bacterial cells per gram of soil (Raynaud and Nunan, 2014) and can play important roles for the fitness of the host plant. Subsets of the rhizospheric microbiota can colonize the root surface (rhizoplane) and the root interior (endosphere), forming an intimate relationship with the host plant. Compositional analysis of these communities is important to develop tools in order to manipulate root-associated microbiota for increased crop productivity. Due to the reduced cost and increasing throughput of next-generation sequencing, major advances in deciphering these communities have recently been achieved, mainly through the use of amplicon sequencing of the 16S rRNA gene. Here we first present a protocol for dissecting the microbiota from various root compartments, developed using rice as a model. We next present a method for amplifying fragments of the 16S rRNA gene using a dual index approach. Finally, we present a simple workflow for analyzing the resulting sequencing data to make ecological inferences., (Copyright © 2018 The Authors; exclusive licensee Bio-protocol LLC.)

Published

2018

215. Grapevine rootstocks shape underground bacterial microbiome and networking but not potential functionality.

Author

Marasco R, Rolli E, Fusi M, Michoud G, and Daffonchio D

Subjects

Bacteria genetics, Bacteria isolation & purification, DNA, Bacterial genetics, DNA, Ribosomal genetics, Microbiota, Phylogeny, Plant Roots microbiology, Rhizosphere, Soil Microbiology, Bacteria classification, High-Throughput Nucleotide Sequencing methods, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA methods, Vitis microbiology

Abstract

Background: The plant compartments of Vitis vinifera, including the rhizosphere, rhizoplane, root endosphere, phyllosphere and carposphere, provide unique niches that drive specific bacterial microbiome associations. The majority of phyllosphere endophytes originate from the soil and migrate up to the aerial compartments through the root endosphere. Thus, the soil and root endosphere partially define the aerial endosphere in the leaves and berries, contributing to the terroir of the fruit. However, V. vinifera cultivars are invariably grafted onto the rootstocks of other Vitis species and hybrids. It has been hypothesized that the plant species determines the microbiome of the root endosphere and, as a consequence, the aerial endosphere. In this work, we test the first part of this hypothesis. We investigate whether different rootstocks influence the bacteria selected from the surrounding soil, affecting the bacterial diversity and potential functionality of the rhizosphere and root endosphere., Methods: Bacterial microbiomes from both the root tissues and the rhizosphere of Barbera cultivars, both ungrafted and grafted on four different rootstocks, cultivated in the same soil from the same vineyard, were characterized by 16S rRNA high-throughput sequencing. To assess the influence of the root genotype on the bacterial communities' recruitment in the root system, (i) the phylogenetic diversity coupled with the predicted functional profiles and (ii) the co-occurrence bacterial networks were determined. Cultivation-dependent approaches were used to reveal the plant-growth promoting (PGP) potential associated with the grafted and ungrafted root systems., Results: Richness, diversity and bacterial community networking in the root compartments were significantly influenced by the rootstocks. Complementary to a shared bacterial microbiome, different subsets of soil bacteria, including those endowed with PGP traits, were selected by the root system compartments of different rootstocks. The interaction between the root compartments and the rootstock exerted a unique selective pressure that enhanced niche differentiation, but rootstock-specific bacterial communities were still recruited with conserved PGP traits., Conclusion: While the rootstock significantly influences the taxonomy, structure and network properties of the bacterial community in grapevine roots, a homeostatic effect on the distribution of the predicted and potential functional PGP traits was found.

Published

2018

216. Drought Stress Results in a Compartment-Specific Restructuring of the Rice Root-Associated Microbiomes.

Author

Santos-Medellín C, Edwards J, Liechty Z, Nguyen B, and Sundaresan V

Subjects

Bacteria classification, Bacteria isolation & purification, Fungi classification, Fungi isolation & purification, Droughts, Microbiota, Oryza microbiology, Oryza physiology, Plant Roots microbiology, Plant Roots physiology, Stress, Physiological

Abstract

Plant roots support complex microbial communities that can influence plant growth, nutrition, and health. While extensive characterizations of the composition and spatial compartmentalization of these communities have been performed in different plant species, there is relatively little known about the impact of abiotic stresses on the root microbiota. Here, we have used rice as a model to explore the responses of root microbiomes to drought stress. Using four distinct genotypes, grown in soils from three different fields, we tracked the drought-induced changes in microbial composition in the rhizosphere (the soil immediately surrounding the root), the endosphere (the root interior), and unplanted soils. Drought significantly altered the overall bacterial and fungal compositions of all three communities, with the endosphere and rhizosphere compartments showing the greatest divergence from well-watered controls. The overall response of the bacterial microbiota to drought stress was taxonomically consistent across soils and cultivars and was primarily driven by an enrichment of multiple Actinobacteria and Chloroflexi , as well as a depletion of several Acidobacteria and Deltaproteobacteria While there was some overlap in the changes observed in the rhizosphere and endosphere communities, several drought-responsive taxa were compartment specific, a pattern likely arising from preexisting compositional differences, as well as plant-mediated processes affecting individual compartments. These results reveal that drought stress, in addition to its well-characterized effects on plant physiology, also results in restructuring of root microbial communities and suggest the possibility that constituents of the altered plant microbiota might contribute to plant survival under extreme environmental conditions. IMPORTANCE With the likelihood that changes in global climate will adversely affect crop yields, the potential role of microbial communities in enhancing plant performance makes it important to elucidate the responses of plant microbiomes to environmental variation. By detailed characterization of the effect of drought stress on the root-associated microbiota of the crop plant rice, we show that the rhizosphere and endosphere communities undergo major compositional changes that involve shifts in the relative abundances of a taxonomically diverse set of bacteria in response to drought. These drought-responsive microbes, in particular those enriched under water deficit conditions, could potentially benefit the plant as they could contribute to tolerance to drought and other abiotic stresses, as well as provide protection from opportunistic infection by pathogenic microbes. The identification and future isolation of microbes that promote plant tolerance to drought could potentially be used to mitigate crop losses arising from adverse shifts in climate., (Copyright © 2017 Santos-Medellín et al.)

Published

2017

217. Distribution of Rhizosphere and Endosphere Fungi on the First-Class Endangered Plant Cypripedium japonicum .

Author

Gang GH, Cho G, Kwak YS, and Park EH

Abstract

Endangered native plant habitats and populations are rapidly disappearing because of climate and environmental changes. As a representative, the abundance of the first-class endangered wild plant, Cypripedium japonicum , has been rapidly decreasing in Korea. The purpose of this study was to evaluate the distribution of rhizosphere and endophytic fungi on C. japonicum in its native habitat. A total of 440 rhizosphere and 79 endosphere fungi isolates were isolated and identified on the basis of their molecular characteristics. Sixty-five genera and 119 fungi species were identified in this study. The genus Trichoderma showed the highest abundance among both rhizosphere and endosphere fungi. Mortierella , Hypocrea , and Penicillium spp. were also relatively dominant species on C. japonicum . The community structures of rhizosphere and endosphere fungi were similar, but endosphere fungi showed greater diversity.

Published

2017

218. Structural variability and niche differentiation in the rhizosphere and endosphere bacterial microbiome of field-grown poplar trees.

Author

Beckers B, Op De Beeck M, Weyens N, Boerjan W, and Vangronsveld J

Subjects

Bacteria classification, Bacteria metabolism, Biodegradation, Environmental, High-Throughput Nucleotide Sequencing, Microbial Consortia, Plant Leaves microbiology, Plant Roots microbiology, RNA, Ribosomal, 16S, Secondary Metabolism, Bacteria isolation & purification, Microbiota genetics, Populus microbiology, Rhizosphere, Soil Microbiology

Abstract

Background: The plant microbiome represents one of the key determinants of plant health and productivity by providing a plethora of functional capacities such as access to low-abundance nutrients, suppression of phytopathogens, and resistance to biotic and/or abiotic stressors. However, a robust understanding of the structural composition of the bacterial microbiome present in different plant microenvironments and especially the relationship between below-ground and above-ground communities has remained elusive. In this work, we addressed hypotheses regarding microbiome niche differentiation and structural stability of the bacterial communities within different ecological plant niches., Methods: We sampled the rhizosphere soil, root, stem, and leaf endosphere of field-grown poplar trees (Populus tremula × Populus alba) and applied 16S rRNA amplicon pyrosequencing to unravel the bacterial communities associated with the different plant habitats., Results: We found that the structural variability of rhizosphere microbiomes in field-grown poplar trees (P. tremula × P. alba) is much lower than that of the endosphere microbiomes. Furthermore, our data not only confirm microbiome niche differentiation reports at the rhizosphere soil-root interface but also clearly show additional fine-tuning and adaptation of the endosphere microbiome in the stem and leaf compartment. Each plant compartment represents an unique ecological niche for the bacterial communities. Finally, we identified the core bacterial microbiome associated with the different ecological niches of Populus., Conclusions: Understanding the complex host-microbe interactions of Populus could provide the basis for the exploitation of the eukaryote-prokaryote associations in phytoremediation applications, sustainable crop production (bio-energy efficiency), and/or the production of secondary metabolites.

Published

2017

219. Metabolic functions of Pseudomonas fluorescens strains from Populus deltoides depend on rhizosphere or endosphere isolation compartment.

Author

Timm CM, Campbell AG, Utturkar SM, Jun SR, Parales RE, Tan WA, Robeson MS, Lu TY, Jawdy S, Brown SD, Ussery DW, Schadt CW, Tuskan GA, Doktycz MJ, Weston DJ, and Pelletier DA

Abstract

The bacterial microbiota of plants is diverse, with 1000s of operational taxonomic units (OTUs) associated with any individual plant. In this work, we used phenotypic analysis, comparative genomics, and metabolic models to investigate the differences between 19 sequenced Pseudomonas fluorescens strains. These isolates represent a single OTU and were collected from the rhizosphere and endosphere of Populus deltoides. While no traits were exclusive to either endosphere or rhizosphere P. fluorescens isolates, multiple pathways relevant for plant-bacterial interactions are enriched in endosphere isolate genomes. Further, growth phenotypes such as phosphate solubilization, protease activity, denitrification and root growth promotion are biased toward endosphere isolates. Endosphere isolates have significantly more metabolic pathways for plant signaling compounds and an increased metabolic range that includes utilization of energy rich nucleotides and sugars, consistent with endosphere colonization. Rhizosphere P. fluorescens have fewer pathways representative of plant-bacterial interactions but show metabolic bias toward chemical substrates often found in root exudates. This work reveals the diverse functions that may contribute to colonization of the endosphere by bacteria and are enriched among closely related isolates.

Published

2015

220. Are drought-resistance promoting bacteria cross-compatible with different plant models?

Author

Marasco R, Rolli E, Vigani G, Borin S, Sorlini C, Ouzari H, Zocchi G, and Daffonchio D

Subjects

Bacteria metabolism, Carbon-Carbon Lyases metabolism, Plant Roots microbiology, Reactive Oxygen Species metabolism, Rhizosphere, Droughts, Ecosystem

Abstract

The association between plant and plant growth promoting bacteria (PGPB) contributes to the successful thriving of plants in extreme environments featured by water shortage. We have recently shown that, with respect to the non-cultivated desert soil, the rhizosphere of pepper plants cultivated under desert farming hosts PGPB communities that are endowed with a large portfolio of PGP traits. Pepper plants exposed to bacterial isolates from plants cultivated under desert farming exhibited a higher tolerance to water shortage, compared with untreated control. This promotion was mediated by a larger root system (up to 40%), stimulated by the bacteria, that enhanced plant ability to uptake water from dry soil. We provide initial evidence that the nature of the interaction can have a limited level of specificity and that PGPB isolates may determine resistance to water stress in plants others than the one of the original isolation. It is apparent that, in relation to plant resistance to water stress, a feature of primary evolutionary importance for all plants, a cross-compatibility between PGPB and different plant models exists at least on a short-term.

Published

2013

221. Soil Characteristics Overwhelm Cultivar Effects on the Structure and Assembly of Root-Associated Microbiomes of Modern Maize

Author

Lin CHEN, Xiuli XIN, Jiabao ZHANG, Marc REDMILE-GORDON, Guangsen NIE, and Qingyun WANG

Subjects

0301 basic medicine, Rhizosphere, amplicon sequencing, fungi, Root microbiome, Bulk soil, Soil Science, food and beverages, Edaphic, Ultisol, Biology, Soil type, complex mixtures, root exudation, 03 medical and health sciences, 030104 developmental biology, Agronomy, endosphere, Botany, indigenous microbes, Cultivar, Microbiome, rhizosphere, edaphic properties

Abstract

Modern breeding primarily targets crop yield traits and is likely to influence root-associated microbiomes, which play significant roles in plant growth and health. The relative importance of soil and cultivar factors in shaping root-associated microbiomes of modern maize (Zea mays L.) remains uncertain. We conducted a pot experiment in a controlled environment using three soils (Mollisol, Inceptisol, and Ultisol) and four contrasting cultivars, Denghai 605, Nonghua 816, Qiaoyu 8, and Zhengdan 958, which are widely planted in China. We used 16S rRNA gene amplicon sequencing to characterize the bacterial communities in the bulk soil, rhizosphere, and endosphere. Our results showed that the four cultivars had different shoot biomass and root exudate total organic carbon and organic acid contents. The microbiomes in the bulk soil, rhizosphere, and endosphere were different. We observed apparent community divergence between soils rather than cultivars, within which edaphic factors substantially contributed to microbiome variation. Moreover, permutational multivariate analysis of variance corroborated significant contributions of soil type but not cultivar on the root-associated microbiome structure. Differential abundance analysis confirmed that each soil presented a distinct root microbiome, while network analysis indicated different co-occurrence patterns of the root microbiome among the three soils. The core root microbiome members are implicated in plant growth promotion and nutrient acquisition in the roots. In conclusion, root-associated microbiomes of modern maize are much more controlled by soil characteristics than by cultivar root exudation. Our study is anticipated to help improve breeding strategies through integrative interactions of soils, cultivars, and their associated microbiomes.