Co-ordinated Changes in the Accumulation of Metal Ions in Maize (Zea mays ssp. mays L.) in Response to Inoculation with the Arbuscular Mycorrhizal Fungus Funneliformis mosseae

Ramírez-Flores, M. Rosario; Rellán‐Álvarez, Rubén; Wozniak, Barbara; Gebreselassie, Mesfin-Nigussie; Jakobsen, Iver; Olalde‐Portugal, Víctor; Baxter, Ivan; Paszkowski, Uta; Sawers, Ruairidh J. H.

doi:10.1093/pcp/pcx100

Cited by 28 publications

(31 citation statements)

References 37 publications

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“…Moreover, an ionomics screen for 19 mineral ions in shoots and roots using the same cohort of 30 maize lines, allowed the identification of clusters of ions, which changed in response to AMF and to maize genotype in a coordinated manner (Ramírez‐Flores et al ., ). It will be interesting to understand how the coordinated uptake of or protection from certain ions occurs and whether these correlations also can be found in a field setting.…”

Section: The Plant–fungus Genotype Combination Determines the Outcomementioning

confidence: 97%

Partner communication and role of nutrients in the arbuscular mycorrhizal symbiosis

2018

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Contents Summary 1031 I. Introduction 1031 II. Interkingdom communication enabling symbiosis 1032 III. Nutritional and regulatory roles for key metabolites in the AM symbiosis 1035 IV. The plant-fungus genotype combination determines the outcome of the symbiosis 1039 V. Perspectives 1039 Acknowledgements 1041 References 1041 SUMMARY: The evolutionary and ecological success of the arbuscular mycorrhizal (AM) symbiosis relies on an efficient and multifactorial communication system for partner recognition, and on a fine-tuned and reciprocal metabolic regulation of each symbiont to reach an optimal functional integration. Besides strigolactones, N-acetylglucosamine-derivatives released by the plant were recently suggested to trigger fungal reprogramming at the pre-contact stage. Remarkably, N-acetylglucosamine-based diffusible molecules also are symbiotic signals produced by AM fungi (AMF) and clues on the mechanisms of their perception by the plant are emerging. AMF genomes and transcriptomes contain a battery of putative effector genes that may have conserved and AMF- or host plant-specific functions. Nutrient exchange is the key feature of AM symbiosis. A mechanism of phosphate transport inside fungal hyphae has been suggested, and first insights into the regulatory mechanisms of root colonization in accordance with nutrient transfer and status were obtained. The recent discovery of the dependency of AMF on fatty acid transfer from the host has offered a convincing explanation for their obligate biotrophism. Novel studies highlighted the importance of plant and fungal genotypes for the outcome of the symbiosis. These findings open new perspectives for fundamental research and application of AMF in agriculture.

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Section: The Plant–fungus Genotype Combination Determines the Outcomementioning

confidence: 97%

Partner communication and role of nutrients in the arbuscular mycorrhizal symbiosis

2018

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“…The third youngest leaf (variously, leaf 5 or 6 for different individuals) was collected for ionomic analysis using inductively coupled plasma mass spectrometry (ICP‐MS) as described previously (Ramírez‐Flores et al, ; Ziegler et al, ). Briefly, weighed tissue samples were digested in 2.5 ml of concentrated nitric acid (AR Select Grade, VWR) with an added internal standard (20 p.p.b.…”

Section: Methodsmentioning

confidence: 99%

“…The clearest benefit to the plant is enhanced P uptake (Chiu & Paszkowski, ), although AM fungi have been reported to promote uptake of other elements, including N, Fe, S, and Zn (Allen & Shachar‐Hill, ; González‐Guerrero et al, ; Govindarajulu et al, ; Liu, Hamel, Hamilton, Ma, & Smith, ; López‐Pedrosa & González‐Guerrero, ). In practice, complex interactions between nutrients influence the outcome of the symbiosis with respect to any given element (Gerlach et al, ; Liu et al, ; Ramírez‐Flores et al, ). Although AM symbioses are widespread in both natural ecosystems and cultivated fields, the plant host maintains a degree of control over establishment and the extent of colonization, rejecting the fungus under high nutrient conditions (Nouri, Breuillin‐Sessoms, Feller, & Reinhardt, ).…”

Section: Introductionmentioning

confidence: 99%

“…The impact of AM symbiosis on nutrient uptake can be quantified by comparing the concentration or content of a given element in the aerial portion of mycorrhizal (M) and non‐colonized (NC) plants (Gerlach et al, ; Ramírez‐Flores et al, ). Such a comparison, however, does not distinguish direct hyphal nutrient delivery from the secondary consequences of fungus‐induced modification of root architecture or the effects of greater root growth resulting from a general increase in plant vigor.…”

Section: Introductionmentioning

confidence: 99%

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Inoculation with the mycorrhizal fungus Rhizophagus irregularis modulates the relationship between root growth and nutrient content in maize (Zea mays ssp. mays L.)

et al. 2019

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Plant root systems play a fundamental role in nutrient and water acquisition. In resource‐limited soils, modification of root system architecture is an important strategy to optimize plant performance. Most terrestrial plants also form symbiotic associations with arbuscular mycorrhizal fungi to maximize nutrient uptake. In addition to direct delivery of nutrients, arbuscular mycorrhizal fungi benefit the plant host by promoting root growth. Here, we aimed to quantify the impact of arbuscular mycorrhizal symbiosis on root growth and nutrient uptake in maize. Inoculated plants showed an increase in both biomass and the total content of twenty quantified elements. In addition, image analysis showed mycorrhizal plants to have denser, more branched root systems. For most of the quantified elements, the increase in content in mycorrhizal plants was proportional to root and overall plant growth. However, the increase in boron, calcium, magnesium, phosphorus, sulfur, and strontium was greater than predicted by root system size alone, indicating fungal delivery to be supplementing root uptake.

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“…There is growing evidence that microbial partnerships can alter plant nutrient status beyond simply levels of nitrogen or phosphorus (e.g., [130,131]). In recent years, our capacity to characterize the microbiome of plants has increased immensely (e.g., [125,132]) with enormous potential for agriculture and plant biology.…”

Section: Ecophysiological and Nutritional Aspectsmentioning

confidence: 99%

The Impact of Genetic Changes during Crop Domestication

et al. 2018

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Abstract:Humans have domesticated hundreds of plant and animal species as sources of food, fiber, forage, and tools over the past 12,000 years, with manifold effects on both human society and the genetic structure of the domesticated species. The outcomes of crop domestication were shaped by selection driven by human preferences, cultivation practices, and agricultural environments, as well as other population genetic processes flowing from the ensuing reduction in effective population size. It is obvious that any selection imposes a reduction of diversity, favoring preferred genotypes, such as nonshattering seeds or increased palatability. Furthermore, agricultural practices greatly reduced effective population sizes of crops, allowing genetic drift to alter genotype frequencies. Current advances in molecular technologies, particularly of genome sequencing, provide evidence of human selection acting on numerous loci during and after crop domestication. Population-level molecular analyses also enable us to clarify the demographic histories of the domestication process itself, which, together with expanded archaeological studies, can illuminate the origins of crops. Domesticated plant species are found in 160 taxonomic families. Approximately 2500 species have undergone some degree of domestication, and 250 species are considered to be fully domesticated. The evolutionary trajectory from wild to crop species is a complex process. Archaeological records suggest that there was a period of predomestication cultivation while humans first began the deliberate planting of wild stands that had favorable traits. Later, crops likely diversified as they were grown in new areas, sometimes beyond the climatic niche of their wild relatives. However, the speed and level of human intentionality during domestication remains a topic of active discussion. These processes led to the so-called domestication syndrome, that is, a group of traits that can arise through human preferences for ease of harvest and growth advantages under human propagation. These traits included reduced dispersal ability of seeds and fruits, changes to plant structure, and changes to plant defensive characteristics and palatability. Domestication implies the action of selective sweeps on standing genetic variation, as well as new genetic variation introduced via mutation or introgression. Furthermore, genetic bottlenecks during domestication or during founding events as crops moved away from their centers of origin may have further altered gene pools. To date, a few hundred genes and loci have been identified by classical genetic and association mapping as targets of domestication and postdomestication divergence. However, only a few of these have been characterized, and for even fewer is the role of the wild-type allele in natural populations understood. After domestication, only favorable haplotypes are retained around selected genes, which creates a genetic valley with extremely low genetic diversity. These "selective sweeps" can allow mildly deleterious...

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Co-ordinated Changes in the Accumulation of Metal Ions in Maize (Zea mays ssp. mays L.) in Response to Inoculation with the Arbuscular Mycorrhizal Fungus Funneliformis mosseae

Cited by 28 publications

References 37 publications

Partner communication and role of nutrients in the arbuscular mycorrhizal symbiosis

Partner communication and role of nutrients in the arbuscular mycorrhizal symbiosis

Inoculation with the mycorrhizal fungus Rhizophagus irregularis modulates the relationship between root growth and nutrient content in maize (Zea mays ssp. mays L.)

The Impact of Genetic Changes during Crop Domestication

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