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            C Incorporation into Signature Fatty Acids as an Assay for Carbon Allocation in Arbuscular Mycorrhiza

Olsson, Pål Axel; Aarle, Ingrid M. van; Gavito, Mayra E.; Bengtson, Per; Bengtsson, Göran

doi:10.1128/aem.71.5.2592-2599.2005

Cited by 53 publications

(47 citation statements)

References 53 publications

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“…Freezedried mycelium (approximately 20 g) or ball-milled root material (approximately 100 g) was enclosed in tin capsules, and the 13 C atom% was determined with an isotope ratio mass spectrometer (20-20 stable isotope analyzer) interfaced with an ANCA-NT combustion module (PDZ Europa Scientific Instruments, Crewe, United Kingdom). Fatty acid methyl esters (prepared as described above) were analyzed with an isotope ratio mass spectrometer interfaced with a Hewlett-Packard gas chromatograph in order to determine the 13 C atom% in neutral lipid fatty acids (NLFA) and phospholipid fatty acids (25). The gas chromatograph was equipped with a 50-m HP5 capillary column (Hewlett-Packard), and He was used as the carrier gas.…”

Section: Methodsmentioning

confidence: 99%

“…Lipids were extracted from mycelia and mycorrhizal roots by vortexing (1 min) in 10 ml of a one-phase mixture containing citrate buffer, methanol, and chloroform (0.8:2:1, vol/vol/vol; pH 4.0). The lipids were fractionated into neutral lipids, glycolipids, and phospholipids on prepacked silica columns (100-mg sorbent mass; Varian Medical Systems, Palo Alto, CA) by elution with 1.5 ml chloroform, 6 ml acetone, and 1.5 ml methanol, respectively (25). The fatty acid residues in neutral lipids and phospholipids were transformed into free fatty acid methyl esters and analyzed by gas chromatography by using a 50-m HP5 capillary fused silica column (Hewlett-Packard, Wilmington, DE) with H 2 as the carrier gas (11).…”

Section: Methodsmentioning

confidence: 99%

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Effect of P Availability on Temporal Dynamics of Carbon Allocation and Glomus intraradices High-Affinity P Transporter Gene Induction in Arbuscular Mycorrhiza

Olsson

Hansson

Burleigh

2006

Appl Environ Microbiol

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Arbuscular mycorrhizal (AM) fungi depend on a C supply from the plant host and simultaneously provide phosphorus to the colonized plant. We therefore evaluated the influence of external P on C allocation in monoxenic Daucus carota-Glomus intraradices cultures in an AM symbiosis. Fungal hyphae proliferated from a solid minimal medium containing colonized roots into a C-free liquid minimal medium with high or low P availability. Roots and hyphae were harvested periodically, and the flow of C from roots to fungus was measured by isotope labeling. We also measured induction of a G. intraradices high-affinity P transporter to estimate fungal P demand. The prevailing hypothesis is that high P availability reduces mycorrhizal fungal growth, but we found that C flow to the fungus was initially highest at the high P level. Only at later harvests, after 100 days of in vitro culture, were C flow and fungal growth limited at high P availability. Thus, AM fungi can benefit initially from P-enriched environments in terms of plant C allocation. As expected, the P transporter induction was significantly greater at low P availability and greatest in very young mycelia. We found no direct link between C flow to the fungus and the P transporter transcription level, which indicates that a good C supply is not essential for induction of the high-affinity P transporter. We describe a mechanism by which P regulates symbiotic C allocation, and we discuss how this mechanism may have evolved in a competitive environment.Fungi in the phylum Glomeromycota proliferate as part of an arbuscular mycorrhizal (AM) association (5,7,32). Carbon is transferred from colonized plants to AM fungi (14), while the plants usually receive much of their P through hyphal uptake and fungal transfer to the host roots (26, 33). Colonization by AM fungi increases the size of the C sink in the roots (9) and may be a significant cost to the host plant that results in reduced growth at high P levels (1,2,15,18,19,27). The adverse effect of high soil P levels on AM formation is primarily due to high P concentrations in the roots (31), which results in reduced C allocation to the AM fungus (24). Thus, there is an important connection between external P supply and C allocation to the fungal partner in the symbiosis. Moderate levels of P fertilization seem to be optimal for AM colonization (21). While the general effect of high P availability on C flow to the fungus has been well described, the effect of high P availability on C flow to the fungus within a few days is not known.A monoxenic system with carrot root organ cultures in symbiosis with the AM fungus Glomus intraradices can be used to study fungal growth (3) and is a well-established model system for studying metabolism and transport in the AM symbiosis (5, 10). We used a system in which the level of P was varied in a compartment that was mainly available to extraradical hyphae (17), which delayed the time until the root P levels were affected by the P treatment. C allocation was measured by compound-specific...

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Effect of P Availability on Temporal Dynamics of Carbon Allocation and Glomus intraradices High-Affinity P Transporter Gene Induction in Arbuscular Mycorrhiza

Olsson

Hansson

Burleigh

2006

Appl Environ Microbiol

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“…Several monounsaturated FAMEs were observed that are common across taxa, but 18:1u9 is common to both fungi and Gram-positive bacteria (Bååth, 2003;Vestle and White, 1989). Further, enrichment of general fungal biomarkers such as 16:1u5 (Olsson et al, 1995(Olsson et al, , 2003, 18:1u7 (Olsson, 1999) and 18:2u9,12 (Frostegård and Bååth, 1996;Zelles, 1999;Zechmeister-Bolternstern et al, 2011) indicates that fungi (e.g., ectomycorrhizal and arbuscular mycorrhizal etc.) were possibly actively consuming biomass and/or exudates of the S 2 O 3 2À activated consortium (cross-feeding?).…”

Section: Isotopic Labelling Incubationsmentioning

confidence: 99%

CO2 uptake by a soil microcosm

Hart

Oppenheimer

Moran

et al. 2013

Soil Biology and Biochemistry

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CO 2 enrichment a b s t r a c t Sequestration of CO 2 via biological sinks is a matter of great scientific importance due to the potential lowering of atmospheric CO 2 . In this study, a custom built incubation chamber was used to cultivate a soil microbial community to instigate chemoautotrophy of a temperate soil. Real-time atmospheric CO 2 concentrations were monitored and estimations of total CO 2 uptake were made. After careful background flux corrections, 4.52 AE 0.05 g CO 2 kg À1 dry soil was sequestered from the chamber atmosphere over 40 h. Using isotopically labelled 13 CO 2 and GCMSeIRMS, labelled fatty acids were identified after only a short incubation, hence confirming CO 2 sequestration for soil. The results of this in vivo study provide the ground work for future studies intending to mimic the in situ environment by providing a reliable method for investigating CO 2 uptake by soil microorganisms.

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“…However, the nutrients stored in spores may reflect not only the need for formation of new fungal biomass but also that of the plants that are being colonized. The establishment of new symbiotic relations could thus depend on the accumulation of plant-limiting nutrients in spores and their transport into the host roots for recognition of a nonparasitic intruder.The nutrient accumulation and distribution in AM fungal spores have not been studied in as much detail as carbon accumulation has (32), although there are clear links between the nutrient availability and C metabolism (16,17,18). Quantitative analysis of elemental composition in AM fungal mycelia is crucial for our understanding of the distribution of nutritional resources.…”

mentioning

confidence: 99%

“…The nutrient accumulation and distribution in AM fungal spores have not been studied in as much detail as carbon accumulation has (32), although there are clear links between the nutrient availability and C metabolism (16,17,18). Quantitative analysis of elemental composition in AM fungal mycelia is crucial for our understanding of the distribution of nutritional resources.…”

mentioning

confidence: 99%

Phosphorus Availability Influences Elemental Uptake in the Mycorrhizal Fungus Glomus intraradices , as Revealed by Particle-Induced X-Ray Emission Analysis

Olsson¹,

Hammer²,

Wallander³

et al. 2008

Appl Environ Microbiol

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We investigated element accumulation in the arbuscular mycorrhizal fungus Glomus intraradices. Fungal spores and mycelia growing in monoxenic cultures were analyzed. The elemental composition was quantified using particle-induced X-ray emission (PIXE) in combination with scanning transmission ion microscopy. In the spores, Ca and Fe were associated mainly with the spore wall, while P and K showed patchy distributions and their concentrations were correlated. Excess of P in the hyphal growth medium increased the P and Si concentrations in spores and increased the K/Ca ratio in spores. Increased P availability decreased the concentration of Zn and Mn in spores. We concluded that the availability of P influences the uptake and accumulation of several elements in spores. It is demonstrated that PIXE analysis is a powerful tool for quantitative analysis of elemental accumulation in fungal mycelia.Arbuscular mycorrhizal (AM) fungal spores are asexual lipidrich survival organs (32) formed on the soil mycelium. After germination, they provide the energy carbon (C) for the fungus before carbohydrates can be taken up through symbiotic exchange with plants. In addition to lipids, the spores are potential storage organs for mineral nutrients essential for the formation of a germ tube. However, the nutrients stored in spores may reflect not only the need for formation of new fungal biomass but also that of the plants that are being colonized. The establishment of new symbiotic relations could thus depend on the accumulation of plant-limiting nutrients in spores and their transport into the host roots for recognition of a nonparasitic intruder.The nutrient accumulation and distribution in AM fungal spores have not been studied in as much detail as carbon accumulation has (32), although there are clear links between the nutrient availability and C metabolism (16,17,18). Quantitative analysis of elemental composition in AM fungal mycelia is crucial for our understanding of the distribution of nutritional resources.Electron-based methods, such as energy-dispersive X-ray spectroscopy or electron probe microanalysis (5, 30), can be used to obtain elementary maps of thin sections of fixed biological tissues. However, quantification of intact structures is not possible with these methods.Particle-induced X-ray emission (PIXE) analysis is based on the analysis of characteristic X-rays emitted from specific elements bombarded with protons from an accelerator (10). PIXE can be used to analyze elemental distributions in three-dimensional structures, and no chemical fixation is needed. Use of this technique, in combination with scanning transmission ion microscopy (STIM), enables quantification of the amounts and distribution of elements in structures as small as AM fungal spores and hyphae. PIXE is analogous to energy-dispersive X-ray spectroscopy, but its sensitivity is much higher, allowing quantification at levels of g g Ϫ1 . Limitations of the PIXE method are that it requires an extensive amount of time and the number of samples tha...

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¹³ C Incorporation into Signature Fatty Acids as an Assay for Carbon Allocation in Arbuscular Mycorrhiza

Cited by 53 publications

References 53 publications

Effect of P Availability on Temporal Dynamics of Carbon Allocation and Glomus intraradices High-Affinity P Transporter Gene Induction in Arbuscular Mycorrhiza

Effect of P Availability on Temporal Dynamics of Carbon Allocation and Glomus intraradices High-Affinity P Transporter Gene Induction in Arbuscular Mycorrhiza

CO2 uptake by a soil microcosm

Phosphorus Availability Influences Elemental Uptake in the Mycorrhizal Fungus Glomus intraradices , as Revealed by Particle-Induced X-Ray Emission Analysis

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13 C Incorporation into Signature Fatty Acids as an Assay for Carbon Allocation in Arbuscular Mycorrhiza

Cited by 53 publications

References 53 publications

Effect of P Availability on Temporal Dynamics of Carbon Allocation and Glomus intraradices High-Affinity P Transporter Gene Induction in Arbuscular Mycorrhiza

Effect of P Availability on Temporal Dynamics of Carbon Allocation and Glomus intraradices High-Affinity P Transporter Gene Induction in Arbuscular Mycorrhiza

CO2 uptake by a soil microcosm

Phosphorus Availability Influences Elemental Uptake in the Mycorrhizal Fungus Glomus intraradices , as Revealed by Particle-Induced X-Ray Emission Analysis

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Product

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¹³ C Incorporation into Signature Fatty Acids as an Assay for Carbon Allocation in Arbuscular Mycorrhiza