Your search keyword '"Hammer, Edith C."' showing total 21 results

1. Aligning spatial ecological theory with the study of clonal organisms: the case of fungal coexistence.

Author

Bielčik M, Schlägel UE, Schäfer M, Aguilar-Trigueros CA, Lakovic M, Sosa-Hernández MA, Hammer EC, Jeltsch F, and Rillig MC

Abstract

Established ecological theory has focused on unitary organisms, and thus its concepts have matured into a form that often hinders rather than facilitates the ecological study of modular organisms. Here, we use the example of filamentous fungi to develop concepts that enable integration of non-unitary (modular) organisms into the established community ecology theory, with particular focus on its spatial aspects. In doing so, we provide a link between fungal community ecology and modern coexistence theory (MCT). We first show how community processes and predictions made by MCT can be used to define meaningful scales in fungal ecology. This leads to the novel concept of the unit of community interactions (UCI), a promising conceptual tool for applying MCT to communities of modular organisms with indeterminate clonal growth and hierarchical individuality. We outline plausible coexistence mechanisms structuring fungal communities, and show at what spatial scales and in what habitats they are most likely to act. We end by describing challenges and opportunities for empirical and theoretical research in fungal competitive coexistence., (© 2024 The Author(s). Biological Reviews published by John Wiley & Sons Ltd on behalf of Cambridge Philosophical Society.)

Published

2024

2. Quantification of growth and nutrient consumption of bacterial and fungal cultures in microfluidic microhabitat models.

Author

Arellano-Caicedo C, Beech JP, Bengtsson M, Ohlsson P, and Hammer EC

Subjects

Microscopy, Fluorescence, Nutrients, Microfluidics, Image Processing, Computer-Assisted

Abstract

Understanding microbes in nature requires consideration of their microenvironment. Here, we present a protocol for quantifying biomass and nutrient degradation of bacterial and fungal cultures (Pseudomonas putida and Coprinopsis cinerea, respectively) in microfluidics. We describe steps for mask design and fabrication, master printing, polydimethylsiloxane chip fabrication, and chip inoculation and imaging using fluorescence microscopy. We include procedures for image analysis, plotting, and statistics. For complete details on the use and execution of this protocol, please refer to Arellano-Caicedo et al. (2023). 1 ., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Exposure to polystyrene nanoplastics reduces bacterial and fungal biomass in microfabricated soil models.

Author

Mafla-Endara PM, Meklesh V, Beech JP, Ohlsson P, Pucetaite M, and Hammer EC

Subjects

Biomass, Soil, Bacteria, Polystyrenes toxicity, Microplastics toxicity

Abstract

Nanoplastics have been proven to induce toxicity in diverse organisms, yet their effect on soil microbes like bacteria and fungi remains largely unexplored. In this paper, we used micro-engineered soil models to investigate the effect of polystyrene (PS) nanospheres on Pseudomonas putida and Coprinopsis cinerea. Specifically, we explored the effects of increasing concentrations of 60 nm carboxylated bovine serum albumin (BSA) coated nanospheres (0, 0.5, 2, and 10 mg/L) on these bacterial and fungal model organisms respectively, over time. We found that both microorganisms could disperse through the PS solution, but long-distance dispersal was reduced by high concentrations. Microbial biomass decreased in all treatments, in which bacteria showed a linear dose response with the strongest effect at 10 mg/L concentration, and fungi showed a non-linear response with the strongest effect at 2 mg/L concentration. At the highest nanoplastics concentration, the first colonizing fungal hyphae adsorbed most of the PS nanospheres present in their vicinity, in a process that we termed the 'vacuum cleaner effect'. As a result, the toxicity effect of the original treatment on subsequently growing fungal hyphae was reduced to a growth level indistinguishable from the control. We did not find evidence that nanoplastics are able to penetrate bacterial nor fungal cell walls. Overall, our findings provide evidence that nanoplastics can cause a direct negative effect on soil microbes and highlight the need for further studies that can explain how the microbial stress response might affect soil functions., 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 © 2023 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2023

4. Arbuscular mycorrhizal fungi trigger danger-associated peptide signaling and inhibit carbon-phosphorus exchange with nonhost plants.

Author

Wang Y, Chen H, Shao M, Zhu T, Li S, Olsson PA, and Hammer EC

Subjects

Humans, Phosphorus metabolism, Carbon, Fungi, Plant Roots metabolism, Peptides, Signal Transduction, Mycorrhizae physiology, Arabidopsis metabolism

Abstract

In soil, arbuscular mycorrhizal fungi (AMF) meet the roots of both host and presumed nonhost plants, but the interactional mechanisms of AMF with and functional relevance for nonhost plants is little known. Here we show AMF can colonize an individually grown nonhost plant, Arabidopsis thaliana, and suppress the growth of Arabidopsis and two nonhost Brassica crops. This inhibitory effect increased with increasing AMF inoculum density, and was independent of AMF species or nutrient availability. 13 C isotope labeling and physiological analyses revealed no significant carbon-phosphorus exchange between Arabidopsis and AMF, indicating a lack of nutritional function in this interaction. AMF colonization activated the danger-associated peptide Pep-PEPR signaling pathway, and caused clear defense responses in Arabidopsis. The impairment of Pep-PEPR signaling in nonhost plants greatly compromised AMF-triggered defensive responses and photosynthesis suppression, leading to higher colonization rates and reduced growth suppression upon AMF inoculation. Pretreatment with Pep peptide decreased AMF colonization, and largely substituted for AMF-induced growth suppression in nonhosts, confirming that the Pep-PEPR pathway is a key participant in resistance to AMF colonization and in mediating growth suppression of nonhost plants. This work greatly increases our knowledge about the functional relevance of AMF and their mechanisms of interactions with nonhost plants., (© 2023 John Wiley & Sons Ltd.)

Published

2023

5. Habitat complexity affects microbial growth in fractal maze.

Author

Arellano-Caicedo C, Ohlsson P, Bengtsson M, Beech JP, and Hammer EC

Subjects

Soil Microbiology, Soil, Ecosystem, Bacteria, Fractals, Carbon

Abstract

The great variety of earth's microorganisms and their functions are attributed to the heterogeneity of their habitats, but our understanding of the impact of this heterogeneity on microbes is limited at the microscale. In this study, we tested how a gradient of spatial habitat complexity in the form of fractal mazes influenced the growth, substrate degradation, and interactions of the bacterial strain Pseudomonas putida and the fungal strain Coprinopsis cinerea. These strains responded in opposite ways: complex habitats strongly reduced fungal growth but, in contrast, increased the abundance of bacteria. Fungal hyphae did not reach far into the mazes and forced bacteria to grow in deeper regions. Bacterial substrate degradation strongly increased with habitat complexity, even more than bacterial biomass, up to an optimal depth, while the most remote parts of the mazes showed both decreased biomass and substrate degradation. These results suggest an increase in enzymatic activity in confined spaces, where areas may experience enhanced microbial activity and resource use efficiency. Very remote spaces showing a slower turnover of substrates illustrate a mechanism which may contribute to the long-term storage of organic matter in soils. We demonstrate here that the sole effect of spatial microstructures affects microbial growth and substrate degradation, leading to differences in local microscale spatial availability. These differences might add up to considerable changes in nutrient cycling at the macroscale, such as contributing to soil organic carbon storage., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2023

6. Nanoscale chemical mapping of exometabolites at fungal-mineral interfaces.

Author

Pucetaite M, Hitchcock A, Obst M, Persson P, and Hammer EC

Subjects

Carbon metabolism, Minerals chemistry, Organic Chemicals, Soil chemistry, Ferric Compounds, Quartz

Abstract

Mineral-associated organic matter is an integral part of soil carbon pool. Biological processes contribute to the formation of such organo-mineral complexes when soil microbes, and in particular soil fungi, deposit a suite of extracellular metabolic compounds and their necromass on the mineral surfaces. While studied in bulk, micro- to nanoscale fungal-mineral interactions remain elusive. Of particular interest are the mutual effects at the interface between the fungal exometabolites and proximal mineral particles. In this work, we have grown saprotrophic and symbiotic fungi in contact with two soil minerals with contrasting properties: quartz and goethite, on top of X-ray transparent silicon nitride membrane windows and analyzed fungal hyphae by synchrotron-based scanning transmission X-ray microscopy in combination with near edge X-ray fine structure spectroscopy at C(K) and Fe(L) absorption edges. In the resultant chemical maps, we were able to visualize and differentiate organic compounds constituting the fungal cells, their extracellular metabolites, and the exometabolites adsorbing on the minerals. We found that the composition of the exometabolites differed between the fungal functional guilds, particularly, in their sugar to protein ratio and potassium concentration. In samples with quartz and goethite, we observed adsorption of the exometabolic compounds on the mineral surfaces with variations in their chemical composition around the particles. Although we did not observe clear alteration in the exometabolite chemistry upon mineral encounters, we show that fungal-mineral interaction result in reduction of Fe(III) in goethite. This process has been demonstrated for bulk systems, but, to our knowledge, this is the first observation on a single hypha scale offering insight into its underlying biological mechanisms. This demonstrates the link between processes initiated at the single-cell level to macroscale phenomena. Thus, spatially resolved chemical characterization of the microbial-mineral interfaces is crucial for an increased understanding of overall carbon cycling in soil., (© 2022 The Authors. Geobiology published by John Wiley & Sons Ltd.)

Published

2022

7. Habitat geometry in artificial microstructure affects bacterial and fungal growth, interactions, and substrate degradation.

Author

Arellano-Caicedo C, Ohlsson P, Bengtsson M, Beech JP, and Hammer EC

Subjects

Biomass, Hyphae cytology, Soil chemistry, Bacteria growth & development, Ecosystem, Fungi growth & development, Soil Microbiology

Abstract

Microhabitat conditions determine the magnitude and speed of microbial processes but have been challenging to investigate. In this study we used microfluidic devices to determine the effect of the spatial distortion of a pore space on fungal and bacterial growth, interactions, and substrate degradation. The devices contained channels differing in bending angles and order. Sharper angles reduced fungal and bacterial biomass, especially when angles were repeated in the same direction. Substrate degradation was only decreased by sharper angles when fungi and bacteria were grown together. Investigation at the cellular scale suggests that this was caused by fungal habitat modification, since hyphae branched in sharp and repeated turns, blocking the dispersal of bacteria and the substrate. Our results demonstrate how the geometry of microstructures can influence microbial activity. This can be transferable to soil pore spaces, where spatial occlusion and microbial feedback on microstructures is thought to explain organic matter stabilization., (© 2021. The Author(s).)

Published

2021

8. Microfluidic chips provide visual access to in situ soil ecology.

Author

Mafla-Endara PM, Arellano-Caicedo C, Aleklett K, Pucetaite M, Ohlsson P, and Hammer EC

Subjects

Hyphae physiology, Lab-On-A-Chip Devices, Soil chemistry, Bacterial Physiological Phenomena, Ecology instrumentation, Fungi physiology, Microbiota physiology, Soil Microbiology

Abstract

Microbes govern most soil functions, but investigation of these processes at the scale of their cells has been difficult to accomplish. Here we incubate microfabricated, transparent 'soil chips' with soil, or bury them directly in the field. Both soil microbes and minerals enter the chips, which enables us to investigate diverse community interdependences, such as inter-kingdom and food-web interactions, and feedbacks between microbes and the pore space microstructures. The presence of hyphae ('fungal highways') strongly and frequently increases the dispersal range and abundance of water-dwelling organisms such as bacteria and protists across air pockets. Physical forces such as water movements, but also organisms and especially fungi form new microhabitats by altering the pore space architecture and distribution of soil minerals in the chip. We show that soil chips hold a large potential for studying in-situ microbial interactions and soil functions, and to interconnect field microbial ecology with laboratory experiments., (© 2021. The Author(s).)

Published

2021

9. Fungal foraging behaviour and hyphal space exploration in micro-structured Soil Chips.

Author

Aleklett K, Ohlsson P, Bengtsson M, and Hammer EC

Subjects

Fungi, Soil, Soil Microbiology, Hyphae, Space Flight

Abstract

How do fungi navigate through the complex microscopic maze-like structures found in the soil? Fungal behaviour, especially at the hyphal scale, is largely unknown and challenging to study in natural habitats such as the opaque soil matrix. We monitored hyphal growth behaviour and strategies of seven Basidiomycete litter decomposing species in a micro-fabricated "Soil Chip" system that simulates principal aspects of the soil pore space and its micro-spatial heterogeneity. The hyphae were faced with micrometre constrictions, sharp turns and protruding obstacles, and the species examined were found to have profoundly different responses in terms of foraging range and persistence, spatial exploration and ability to pass obstacles. Hyphal behaviour was not predictable solely based on ecological assumptions, and our results obtained a level of trait information at the hyphal scale that cannot be fully explained using classical concepts of space exploration and exploitation such as the phalanx/guerrilla strategies. Instead, we propose a multivariate trait analysis, acknowledging the complex trade-offs and microscale strategies that fungal mycelia exhibit. Our results provide novel insights about hyphal behaviour, as well as an additional understanding of fungal habitat colonisation, their foraging strategies and niche partitioning in the soil environment.

Published

2021

10. Synergies between mycorrhizal fungi and soil microbial communities increase plant nitrogen acquisition.

Author

Hestrin R, Hammer EC, Mueller CW, and Lehmann J

Subjects

Ecosystem, Microbiota, Mycorrhizae metabolism, Nitrogen metabolism, Plants metabolism, Soil Microbiology

Abstract

Nitrogen availability often restricts primary productivity in terrestrial ecosystems. Arbuscular mycorrhizal fungi are ubiquitous symbionts of terrestrial plants and can improve plant nitrogen acquisition, but have a limited ability to access organic nitrogen. Although other soil biota mineralize organic nitrogen into bioavailable forms, they may simultaneously compete for nitrogen, with unknown consequences for plant nutrition. Here, we show that synergies between the mycorrhizal fungus Rhizophagus irregularis and soil microbial communities have a highly non-additive effect on nitrogen acquisition by the model grass Brachypodium distachyon . These multipartite microbial synergies result in a doubling of the nitrogen that mycorrhizal plants acquire from organic matter and a tenfold increase in nitrogen acquisition compared to non-mycorrhizal plants grown in the absence of soil microbial communities. This previously unquantified multipartite relationship may contribute to more than 70 Tg of annually assimilated plant nitrogen, thereby playing a critical role in global nutrient cycling and ecosystem function., Competing Interests: Competing interestsThe authors declare no competing interests.

Published

2019

11. Arbuscular mycorrhizal fungal and soil microbial communities in African Dark Earths.

Author

Camenzind T, Hammer EC, Lehmann J, Solomon D, Horn S, Rillig MC, and Hempel S

Subjects

Africa, Western, Agriculture methods, Biomass, Carbon analysis, Fertilizers microbiology, Microbiota, Bacteria growth & development, Fungi growth & development, Mycorrhizae growth & development, Plant Roots microbiology, Soil chemistry, Soil Microbiology

Abstract

The socio-economic values of fertile and carbon-rich Dark Earth soils are well described from the Amazon region. Very recently, Dark Earth soils were also identified in tropical West Africa, with comparable beneficial soil properties and plant growth-promoting effects. The impact of this management technique on soil microbial communities, however, is less well understood, especially with respect to the ecologically relevant group of arbuscular mycorrhizal (AM) fungi. Thus, we tested the hypotheses that (1) improved soil quality in African Dark Earth (AfDE) will increase soil microbial biomass and shift community composition and (2) concurrently increased nutrient availability will negatively affect AM fungal communities. Microbial communities were distinct in AfDE in comparison to adjacent sites, with an increased fungal:bacterial ratio of 71%, a pattern mainly related to shifts in pH. AM fungal abundance and diversity, however, did not differ despite clearly increased soil fertility in AfDE, with 3.7 and 1.7 times greater extractable P and total N content, respectively. The absence of detrimental effects on AM fungi, often seen following applications of inorganic fertilizers, and the enhanced role of saprobic fungi relevant for mineralization and C sequestration support previous assertions of this management type as a sustainable alternative agricultural practice.

Published

2018

12. Build your own soil: exploring microfluidics to create microbial habitat structures.

Author

Aleklett K, Kiers ET, Ohlsson P, Shimizu TS, Caldas VE, and Hammer EC

Subjects

Biodiversity, Computer Simulation, Dimethylpolysiloxanes chemistry, Electrochemical Techniques, Optics and Photonics, Soil, Ecosystem, Imaging, Three-Dimensional, Lab-On-A-Chip Devices, Microbiota, Microfluidics methods, Soil Microbiology

Abstract

Soil is likely the most complex ecosystem on earth. Despite the global importance and extraordinary diversity of soils, they have been notoriously challenging to study. We show how pioneering microfluidic techniques provide new ways of studying soil microbial ecology by allowing simulation and manipulation of chemical conditions and physical structures at the microscale in soil model habitats.

Published

2018

13. Phosphorus and carbon availability regulate structural composition and complexity of AM fungal mycelium.

Author

Olsson O, Olsson PA, and Hammer EC

Subjects

Glomeromycota metabolism, Mycelium metabolism, Mycorrhizae metabolism, Plant Roots metabolism, Plant Roots microbiology, Plants, Spores, Fungal growth & development, Spores, Fungal metabolism, Carbon metabolism, Daucus carota microbiology, Glomeromycota growth & development, Mycelium growth & development, Mycorrhizae growth & development, Phosphorus metabolism

Abstract

The regulation of the structural composition and complexity of the mycelium of arbuscular mycorrhizal (AM) fungi is not well understood due to their obligate biotrophic nature. The aim of this study was to investigate the structure of extraradical mycelium at high and low availability of carbon (C) to the roots and phosphorus (P) to the fungus. We used monoxenic cultures of the AM fungus Rhizophagus irregularis (formerly Glomus intraradices) with transformed carrot roots as the host in a cultivation system including a root-free compartment into which the extraradical mycelium could grow. We found that high C availability increased hyphal length and spore production and anastomosis formation within individual mycelia. High P availability increased the formation of branched absorbing structures and reduced spore production and the overall length of runner hyphae. The complexity of the mycelium, as indicated by its fractal dimensions, increased with both high C and P availability. The results indicate that low P availability induces a growth pattern that reflects foraging for both P and C. Low C availability to AM roots could still support the explorative development of the mycelium when P availability was low. These findings help us to better understand the development of AM fungi in ecosystems with high P input and/or when plants are subjected to shading, grazing or any management practice that reduces the photosynthetic ability of the plant.

Published

2014

14. The interplay between P uptake pathways in mycorrhizal peas: a combined physiological and gene-silencing approach.

Author

Grønlund M, Albrechtsen M, Johansen IE, Hammer EC, Nielsen TH, and Jakobsen I

Subjects

Amino Acid Sequence, Biological Transport physiology, Gene Silencing, Host-Pathogen Interactions, Molecular Sequence Data, Mycorrhizae physiology, Pisum sativum genetics, Pisum sativum microbiology, Phosphate Transport Proteins classification, Phosphate Transport Proteins genetics, Phosphates metabolism, Phosphorus Radioisotopes metabolism, Phylogeny, Plant Proteins genetics, Plant Roots genetics, Plant Roots microbiology, Plant Roots physiology, Sequence Homology, Amino Acid, Signal Transduction genetics, Soil chemistry, Symbiosis genetics, Symbiosis physiology, Pisum sativum physiology, Phosphate Transport Proteins physiology, Phosphorus metabolism, Plant Proteins physiology, Signal Transduction physiology

Abstract

Arbuscular mycorrhizal fungi (AMF) have a key role in plant phosphate (Pi) uptake by their efficient capture of soil phosphorus (P) that is transferred to the plant via Pi transporters in the root cortical cells. The activity of this mycorrhizal Pi uptake pathway is often associated with downregulation of Pi transporter genes in the direct Pi uptake pathway. As the total Pi taken up by the plant is determined by the combined activity of mycorrhizal and direct pathways, it is important to understand the interplay between these, in particular the actual activity of the pathways. To study this interplay we modulated the delivery of Pi via the mycorrhizal pathway in Pisum sativum by two means: (1) Partial downregulation by virus-induced gene silencing of PsPT4, a putative Pi transporter gene in the mycorrhizal pathway. This resulted in decreased fungal development in roots and soil and led to reduced plant Pi uptake. (2) Changing the percentage of AMF-colonized root length by using non-, half-mycorrhizal or full-mycorrhizal split-root systems. The combination of split roots, use of ³²P and ³³P isotopes and partial silencing of PsPT4 enabled us to show that the expression of PsPT1, a putative Pi transporter gene in the direct pathway, was negatively correlated with increasing mycorrhizal uptake capacity of the plant, both locally and systemically. However, transcript changes in PsPT1 were not translated into corresponding, systemic changes in actual direct Pi uptake. Our results suggest that AMF have a limited long-distance impact on the direct pathway., (© 2013 Scandinavian Plant Physiology Society.)

Published

2013

15. Mycorrhiza for all: an under-earth revolution.

Author

Martinez-Garcia LB, Garcia K, Hammer EC, and Vayssières A

Subjects

Agriculture, Conservation of Natural Resources, Forestry, Humans, Genome, Fungal, Mycorrhizae, Soil Microbiology, Symbiosis

Published

2013

16. Arbuscular mycorrhizal fungi--short-term liability but long-term benefits for soil carbon storage?

Author

Verbruggen E, Veresoglou SD, Anderson IC, Caruso T, Hammer EC, Kohler J, and Rillig MC

Subjects

Carbon Dioxide metabolism, Organic Chemicals metabolism, Plants metabolism, Plants microbiology, Symbiosis, Carbon metabolism, Mycorrhizae physiology, Soil chemistry, Soil Microbiology

Published

2013

17. Elemental composition in vesicles of an arbuscular mycorrhizal fungus, as revealed by PIXE analysis.

Author

Olsson PA, Hammer EC, Pallon J, van Aarle IM, and Wallander H

Subjects

Elements, Glomeromycota isolation & purification, Mycorrhizae isolation & purification, Onions microbiology, Plant Roots microbiology, Cytoplasmic Vesicles chemistry, Glomeromycota chemistry, Mycorrhizae chemistry, Spectrometry, X-Ray Emission methods

Abstract

We investigated element accumulation in vesicles of the arbuscular mycorrhizal (AM) fungus Glomus intraradices, extracted from the roots of inoculated leek plants. The elemental composition (elements heavier than Mg) was quantified using particle-induced X-ray emission (PIXE), in combination with scanning transmission ion microscopy (STIM). In vesicles, P was the most abundant of the elements analysed, followed by Ca, S, Si and K. We analysed 12 vesicles from two root systems and found that the variation between vesicles was particularly high for P and Si. The P content related positively to Si, Zn and K, while its relation to Cl fitted to a negative power function. Vesicle transects showed that P and K were present in central parts, while Ca was present mainly near the vesicle surfaces. The results showed that P is an important part (0.5% of the dry weight) of the vesicle content and that the distribution of some elements, within mycelia, may be strongly correlated., (Copyright © 2011 The British Mycological Society. Published by Elsevier Ltd. All rights reserved.)

Published

2011

18. Tit for tat? A mycorrhizal fungus accumulates phosphorus under low plant carbon availability.

Author

Hammer EC, Pallon J, Wallander H, and Olsson PA

Subjects

Culture Media chemistry, Glomeromycota metabolism, Glomeromycota physiology, Mycelium metabolism, Mycelium physiology, Mycorrhizae physiology, Phosphates metabolism, Carbon metabolism, Mycorrhizae metabolism, Phosphorus metabolism, Plant Roots microbiology, Symbiosis physiology

Abstract

The exchange of carbohydrates and mineral nutrients in the arbuscular mycorrhizal (AM) symbiosis must be controlled by both partners in order to sustain an evolutionarily stable mutualism. Plants downregulate their carbon (C) flow to the fungus when nutrient levels are sufficient, while the mechanism controlling fungal nutrient transfer is unknown. Here, we show that the fungus accumulates nutrients when connected to a host that is of less benefit to the fungus, indicating a potential of the fungus to control the transfer of nutrients. We used a monoxenic in vitro model of root organ cultures associated with Glomus intraradices, in which we manipulated the C availability to the plant. We found that G. intraradices accumulated up to seven times more nutrients in its spores, and up to nine times more in its hyphae, when the C pool available to the associated roots was halved. The strongest effect was found for phosphorus (P), considered to be the most important nutrient in the AM symbiosis. Other elements such as potassium and chorine were also accumulated, but to a lesser extent, while no accumulation of iron or manganese was found. Our results suggest a functional linkage between C and P exchange., (© 2011 Federation of European Microbiological Societies. Published by Blackwell Publishing Ltd. All rights reserved.)

Published

2011

19. Elemental composition of arbuscular mycorrhizal fungi at high salinity.

Author

Hammer EC, Nasr H, Pallon J, Olsson PA, and Wallander H

Subjects

Acacia chemistry, Acacia drug effects, Desert Climate adverse effects, Fatty Acids analysis, Glomeromycota growth & development, Hyphae chemistry, Hyphae drug effects, Hyphae growth & development, Mycorrhizae growth & development, Plant Roots chemistry, Plant Roots drug effects, Plant Roots microbiology, Potassium analysis, Salinity, Sodium analysis, Sodium Chloride pharmacology, Soil analysis, Spectrometry, X-Ray Emission methods, Spores, Fungal chemistry, Spores, Fungal drug effects, Spores, Fungal growth & development, Tunisia, Acacia microbiology, Glomeromycota chemistry, Glomeromycota drug effects, Mycorrhizae chemistry, Mycorrhizae drug effects

Abstract

We investigated the elemental composition of spores and hyphae of arbuscular mycorrhizal fungi (AMF) collected from two saline sites at the desert border in Tunisia, and of Glomus intraradices grown in vitro with or without addition of NaCl to the medium, by proton-induced X-ray emission. We compared the elemental composition of the field AMF to those of the soil and the associated plants. The spores and hyphae from the saline soils showed strongly elevated levels of Ca, Cl, Mg, Fe, Si, and K compared to their growth environment. In contrast, the spores of both the field-derived AMF and the in vitro grown G. intraradices contained lower or not elevated Na levels compared to their growth environment. This resulted in higher K:Na and Ca:Na ratios in spores than in soil, but lower than in the associated plants for the field AMF. The K:Na and Ca:Na ratios of G. intraradices grown in monoxenic cultures were also in the same range as those of the field AMF and did not change even when those ratios in the growth medium were lowered several orders of magnitude by adding NaCl. These results indicate that AMF can selectively take up elements such as K and Ca, which act as osmotic equivalents while they avoid uptake of toxic Na. This could make them important in the alleviation of salinity stress in their plant hosts.

Published

2011

20. The influence of different stresses on glomalin levels in an arbuscular mycorrhizal fungus--salinity increases glomalin content.

Author

Hammer EC and Rillig MC

Subjects

Biomass, Computer Simulation, Mycelium drug effects, Mycorrhizae drug effects, Mycorrhizae growth & development, Osmolar Concentration, Osmosis drug effects, Sodium Chloride pharmacology, Fungal Proteins metabolism, Glycoproteins metabolism, Mycorrhizae metabolism, Mycorrhizae physiology, Salinity, Stress, Physiological drug effects

Abstract

Glomalin is a glycoprotein produced by arbuscular mycorrhizal (AM) fungi, and the soil fraction containing glomalin is correlated with soil aggregation. Thus, factors potentially influencing glomalin production could be of relevance for this ecosystem process and for understanding AM fungal physiology. Previous work indicated that glomalin production in AM fungi may be a stress response, or related to suboptimal mycelium growth. We show here that environmental stress can enhance glomalin production in the mycelium of the AM fungus Glomus intraradices. We applied NaCl and glycerol in different intensities to the medium in which the fungus was grown in vitro, causing salinity stress and osmotic stress, respectively. As a third stress type, we simulated grazing on the extraradical hyphae of the fungus by mechanically injuring the mycelium by clipping. NaCl caused a strong increase, while the clipping treatment led to a marginally significant increase in glomalin production. Even though salinity stress includes osmotic stress, we found substantially different responses in glomalin production due to the NaCl and the glycerol treatment, as glycerol addition did not cause any response. Thus, our results indicate that glomalin is involved in inducible stress responses in AM fungi for salinity, and possibly grazing stress.

Published

2011

21. Phosphorus availability influences elemental uptake in the mycorrhizal fungus Glomus intraradices, as revealed by particle-induced X-ray emission analysis.

Author

Olsson PA, Hammer EC, Wallander H, and Pallon J

Subjects

Calcium metabolism, Culture Media chemistry, Daucus carota growth & development, Fungi growth & development, Iron metabolism, Mycelium growth & development, Mycorrhizae growth & development, Potassium metabolism, Spores, Fungal metabolism, Trace Elements, Daucus carota microbiology, Fungi metabolism, Mycelium metabolism, Mycorrhizae metabolism, Phosphorus metabolism, Spectrometry, X-Ray Emission methods

Abstract

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.

Published

2008