Your search keyword '"Darrah PR"' showing total 17 results

1. Involvement of multiple aluminium exclusion mechanisms in aluminium tolerance in wheat

Author

Pellet, DM, Papernik, LA, Jones, DL, Darrah, PR, Grunes, DL, and Kochian, LV

Subjects

food and beverages

Abstract

The goal of this study was to determine if Al-chelators other than malate are released from root apices and are involved in Al-tolerance in different wheat (Triticum aestivum L.) genotypes. Also we wanted to establish if root exudates contribute to increases in rhizosphere pH around the root tip. In seedlings of Al-tolerant Atlas, we have documented a constitutive phosphate exudation from the root apex. Because phosphate can complex Al and bind protons, it could play an important role in Al tolerance, both via complexation of Al3+ and by contributing to the alkalinization of rhizosphere pH observed at the apex of Atlas. This study suggests that in wheat, Al-tolerance can be mediated by multiple exclusion mechanisms controlled by different genes.

Published

2016

2. Interactions between root exudates, mineral nutrition and plant growth

Author

Darrah, PR

Published

2016

3. Corrigendum to 'Fourier-based spatial mapping of oscillatory phenomena in fungi' [Fungal Genet. Biol. 44 (2007) 1077-1084] (DOI:10.1016/j.fgb.2007.02.012)

Author

Fricker, MD, Tlalka, M, Bebber, D, Takagi, S, Watkinson, SC, and Darrah, PR

Published

2016

4. Re-sorption of organic compounds by roots of Zea mays L and its consequences in the rhizosphere .3. Characteristics of sugar influx and efflux

Author

Jones, DL and Darrah, PR

Published

2016

5. Modelling the rhizosphere: a review of methods for 'upscaling' to the whole-plant scale

Author

Darrah, PR, Jones, DL, Kirk, GJD, and Roose, T

Abstract

The rhizosphere is a dynamic region where multiple interacting processes in the roots and surrounding soil take place, with dimensions set by the distance to which the zone of root influence spreads into the soil. Its complexity is such that some form of mathematical modelling is essential for understanding which of the various processes operating are important, and a minimal model of the rhizosphere must provide information on (a) the spatiotemporal concentration changes of mobile solutes in the root-influenced soil, and (b) the cumulative uptake of solutes per unit length of root over time. Both are unique for a given set of parameters and initial conditions and hence the model is fully deterministic. 'Up-scaling' to uptake by whole plants by integrating individual fluxes requires a measure of the growth and senescence of the root system. Root architecture models are increasingly successful in providing this. The spatio-temporal scales of the rhizosphere and roots are sufficiently different that they can be treated separately, and this greatly simplifies modelling. The minimal model has been successfully applied to the more-mobile nutrients in soil, such as nitrate or potassium, but much less successfully to less-soluble nutrients such as phosphorus, because other, undescribed processes become important. These include transfers from unavailable forms, heterogeneity of resource distribution, root competition, water redistribution and adaptive processes. Incorporating such processes into models can disrupt independent scaling. In general, scaling from the scale of the individual root to that of the whole plant does not pose insuperable problems. Paradoxically, the major challenge in introducing more complexity is that experimental corroboration of the model is required at the individual root scale.

Published

2016

6. Fourier-based spatial mapping of oscillatory phenomena in fungi

Author

Fricker, MD, Tlalka, M, Bebber, D, Takagi, S, Tagaki, S, Watkinson, SC, and Darrah, PR

Subjects

Fourier Analysis, Oscillation, Fungi, Phase (waves), Magnitude (mathematics), Physarum polycephalum, Myosins, Biology, biology.organism_classification, Microbiology, Actins, symbols.namesake, Fourier transform, Biological Clocks, Fourier analysis, Genetics, symbols, Hilbert transform, Biological system, Spatial analysis

Abstract

Microorganisms display a range of oscillatory phenomena that operate over different temporal scales. Fourier analysis provides a compact description of such oscillations in terms of their frequency, magnitude and phase. However, in the majority of studies there is no explicit consideration of the spatial organisation of the oscillation. Here we describe procedures and a software package to map oscillatory phenomena in microorganisms in both the time and frequency domains. Key parameters of interest, such as frequency, phase or magnitude of the oscillations, are presented as pseudo-colour coded maps. This maintains the spatial information in the image and greatly facilitates understanding of potentially complex propagating waves or development of oscillatory domains with distinct behaviour. We illustrate the utility of this system with reference to spatial analysis of the pulsatile component to amino acid transport in mycelial systems of Phanerochaete velutina and Coniophora puteana , and actin–myosin based contractions in Physarum polycephalum .

Published

2007

7. Imaging complex nutrient dynamics in mycelial networks

Author

Bebber, DP, Tlalka, M, Hynes, J, Darrah, PR, Ashford, A, Watkinson, SC, Boddy, L, Fricker, MD, Dyer, P.S, Watkinson, S. C, Gadd, G., Dyer, P, Watkinson, S, Gadd, G, and Society, Royal Microscopical

Subjects

Linear mixed effect model, Histology, Foraging, Transport network, Pathology and Forensic Medicine, Nutrient, Component (UML), Botany, Image Processing, Computer-Assisted, Phanerochaete velutina, Mycelium, Network model, Microscopy, Confocal, Microscopy, Video, biology, Ecology, Scale (chemistry), Plant Sciences, Fungi, Complex network, biology.organism_classification, Network formation, Microscopy, Fluorescence, Food, Biological system, Biological network

Abstract

Summary: Transport networks are vital components of multi-cellular organisms, distributing nutrients and removing waste products. Animal cardiovascular and respiratory systems, and plant vasculature, are branching trees whose architecture is thought to determine universal scaling laws in these organisms. In contrast, the transport systems of many multi-cellular fungi do not fit into this conceptual framework, as they have evolved to explore a patchy environment in search of new resources, rather than ramify through a three-dimensional organism. These fungi grow as a foraging mycelium, formed by the branching and fusion of threadlike hyphae, that gives rise to a complex network. To function efficiently, the mycelial network must both transport nutrients between spatially separated source and sink regions and also maintain its integrity in the face of continuous attack by mycophagous insects or random damage. Here we review the development of novel imaging approaches and software tools that we have used to characterise nutrient transport and network formation in foraging mycelia over a range of spatial scales. On a millimetre scale, we have used a combination of time-lapse confocal imaging and fluorescence recovery after photobleaching to quantify the rate of diffusive transport through the unique vacuole system in individual hyphae. These data then form the basis of a simulation model to predict the impact of such diffusion-based movement on a scale of several millimetres. On a centimetre scale, we have used novel photon-counting scintillation imaging techniques to visualize radiolabel movement in small microcosms. This approach has revealed novel N-transport phenomena, including rapid, preferential N-resource allocation to C-rich sinks, induction of simultaneous bi-directional transport, abrupt switching between different pre-existing transport routes, and a strong pulsatile component to transport in some species. Analysis of the pulsatile transport component using Fourier techniques shows that as the colony forms, it self-organizes into well demarcated domains that are identifiable by differences in the phase relationship of the pulses. On the centimetre to metre scale, we have begun to use techniques borrowed from graph theory to characterize the development and dynamics of the network, and used these abstracted network models to predict the transport characteristics, resilience, and cost of the network.

Published

2007

8. Heterochrony underpins natural variation in Cardamine hirsuta leaf form.

Author

Cartolano M, Pieper B, Lempe J, Tattersall A, Huijser P, Tresch A, Darrah PR, Hay A, and Tsiantis M

Subjects

Alleles, Arabidopsis, Base Sequence, Biodiversity, Chromosome Mapping, Cloning, Molecular, Flowers, Gene Expression Regulation, Plant, Genotype, Light, Models, Genetic, Molecular Sequence Data, Phenotype, Plants, Genetically Modified, Polymorphism, Genetic, Seeds, Sequence Homology, Nucleic Acid, Cardamine genetics, Plant Leaves anatomy & histology, Quantitative Trait Loci

Abstract

A key problem in biology is whether the same processes underlie morphological variation between and within species. Here, by using plant leaves as an example, we show that the causes of diversity at these two evolutionary scales can be divergent. Some species like the model plant Arabidopsis thaliana have simple leaves, whereas others like the A. thaliana relative Cardamine hirsuta bear complex leaves comprising leaflets. Previous work has shown that these interspecific differences result mostly from variation in local tissue growth and patterning. Now, by cloning and characterizing a quantitative trait locus (QTL) for C. hirsuta leaf shape, we find that a different process, age-dependent progression of leaf form, underlies variation in this trait within species. This QTL effect is caused by cis-regulatory variation in the floral repressor ChFLC, such that genotypes with low-expressing ChFLC alleles show both early flowering and accelerated age-dependent changes in leaf form, including faster leaflet production. We provide evidence that this mechanism coordinates leaf development with reproductive timing and may help to optimize resource allocation to the next generation.

Published

2015

9. Foraging by a wood-decomposing fungus is ecologically adaptive.

Author

Darrah PR and Fricker MD

Subjects

Adaptation, Physiological, Environment, Fungi growth & development, Models, Biological, Wood metabolism, Fungi physiology, Wood microbiology

Abstract

We show that fungi that forage for wood do not conform to the paradigm of symmetric radial growth and grow asymmetrically by default. Asymmetry is further accentuated by contact with a resource that also partially polarizes growth in the direction of the resource. Despite marked changes at the perimeter, overall growth allocation on an area basis is, however, unchanged implying sophisticated regulation at the colony level. Using mathematical models, we show that this behaviour is best explained as a local response of the immediate segment contacting the resource. The model reveals that foraging behaviour is adaptive but only for resources that are clustered in space and is selectively neutral for randomly scattered resources. This clustered spatial distribution matches that found in the natural environment. Modelling also shows that the foraging strategy used by these fungi involves substantial risks as well as benefits., (© 2013 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2014

10. Simulated nitrogen deposition affects wood decomposition by cord-forming fungi.

Author

Bebber DP, Watkinson SC, Boddy L, and Darrah PR

Subjects

Basidiomycota chemistry, Carbon Cycle, England, Environment, Fagus chemistry, Fagus metabolism, Nitrogen chemistry, Soil analysis, Species Specificity, Wood analysis, Wood metabolism, Basidiomycota growth & development, Basidiomycota metabolism, Fagus microbiology, Nitrogen analysis, Wood microbiology

Abstract

Anthropogenic nitrogen (N) deposition affects many natural processes, including forest litter decomposition. Saprotrophic fungi are the only organisms capable of completely decomposing lignocellulosic (woody) litter in temperate ecosystems, and therefore the responses of fungi to N deposition are critical in understanding the effects of global change on the forest carbon cycle. Plant litter decomposition under elevated N has been intensively studied, with varying results. The complexity of forest floor biota and variability in litter quality have obscured N-elevation effects on decomposers. Field experiments often utilize standardized substrates and N-levels, but few studies have controlled the decay organisms. Decomposition of beech (Fagus sylvatica) blocks inoculated with two cord-forming basidiomycete fungi, Hypholoma fasciculare and Phanerochaete velutina, was compared experimentally under realistic levels of simulated N deposition at Wytham Wood, Oxfordshire, UK. Mass loss was greater with P. velutina than with H. fasciculare, and with N treatment than in the control. Decomposition was accompanied by growth of the fungal mycelium and increasing N concentration in the remaining wood. We attribute the N effect on wood decay to the response of cord-forming wood decay fungi to N availability. Previous studies demonstrated the capacity of these fungi to scavenge and import N to decaying wood via a translocating network of mycelium. This study shows that small increases in N availability can increase wood decomposition by these organisms. Dead wood is an important carbon store and habitat. The responses of wood decomposers to anthropogenic N deposition should be considered in models of forest carbon dynamics.

Published

2011

11. Sector analysis and predictive modelling reveal iterative shoot-like development in fern fronds.

Author

Sanders HL, Darrah PR, and Langdale JA

Subjects

Biological Evolution, Ferns anatomy & histology, Fluorescence, Microscopy, Confocal, Microscopy, Electron, Scanning, Plant Leaves anatomy & histology, Plant Shoots anatomy & histology, Ferns growth & development, Models, Biological, Plant Leaves growth & development, Plant Shoots growth & development

Abstract

Plants colonized the terrestrial environment over 450 million years ago. Since then, shoot architecture has evolved in response to changing environmental conditions. Our current understanding of the innovations that altered shoot morphology is underpinned by developmental studies in a number of plant groups. However, the least is known about mechanisms that operate in ferns--a key group for understanding the evolution of plant development. Using a novel combination of sector analysis, conditional probability modelling methods and histology, we show that shoots, fronds ('leaves') and pinnae ('leaflets') of the fern Nephrolepis exaltata all develop from single apical initial cells. Shoot initials cleave on three faces to produce a pool of cells from which individual frond apical initials are sequentially specified. Frond initials then cleave in two planes to produce a series of lateral merophyte initials that each contributes a unit of three pinnae to half of the mediolateral frond axis. Notably, this iterative pattern in both shoots and fronds is similar to the developmental process that operates in shoots of other plant groups. Pinnae initials first cleave in two planes to generate lateral marginal initials. The apical and marginal initials then divide in three planes to coordinately generate the determinate pinna. These findings impact both on our understanding of fundamental plant developmental processes and on our perspective of how shoot systems evolved.

Published

2011

12. Imaging complex nutrient dynamics in mycelial networks.

Author

Fricker MD, Lee JA, Bebber DP, Tlalka M, Hynes J, Darrah PR, Watkinson SC, and Boddy L

Subjects

Food, Fungi metabolism, Image Processing, Computer-Assisted methods, Microscopy, Confocal methods, Microscopy, Fluorescence methods, Microscopy, Video methods, Mycelium metabolism

Abstract

Transport networks are vital components of multi-cellular organisms, distributing nutrients and removing waste products. Animal cardiovascular and respiratory systems, and plant vasculature, are branching trees whose architecture is thought to determine universal scaling laws in these organisms. In contrast, the transport systems of many multi-cellular fungi do not fit into this conceptual framework, as they have evolved to explore a patchy environment in search of new resources, rather than ramify through a three-dimensional organism. These fungi grow as a foraging mycelium, formed by the branching and fusion of threadlike hyphae, that gives rise to a complex network. To function efficiently, the mycelial network must both transport nutrients between spatially separated source and sink regions and also maintain its integrity in the face of continuous attack by mycophagous insects or random damage. Here we review the development of novel imaging approaches and software tools that we have used to characterise nutrient transport and network formation in foraging mycelia over a range of spatial scales. On a millimetre scale, we have used a combination of time-lapse confocal imaging and fluorescence recovery after photobleaching to quantify the rate of diffusive transport through the unique vacuole system in individual hyphae. These data then form the basis of a simulation model to predict the impact of such diffusion-based movement on a scale of several millimetres. On a centimetre scale, we have used novel photon-counting scintillation imaging techniques to visualize radiolabel movement in small microcosms. This approach has revealed novel N-transport phenomena, including rapid, preferential N-resource allocation to C-rich sinks, induction of simultaneous bi-directional transport, abrupt switching between different pre-existing transport routes, and a strong pulsatile component to transport in some species. Analysis of the pulsatile transport component using Fourier techniques shows that as the colony forms, it self-organizes into well demarcated domains that are identifiable by differences in the phase relationship of the pulses. On the centimetre to metre scale, we have begun to use techniques borrowed from graph theory to characterize the development and dynamics of the network, and used these abstracted network models to predict the transport characteristics, resilience, and cost of the network.

Published

2008

13. Quantifying dynamic resource allocation illuminates foraging strategy in Phanerochaete velutina.

Author

Tlalka M, Bebber DP, Darrah PR, Watkinson SC, and Fricker MD

Subjects

Biological Transport, Carbon Radioisotopes metabolism, Gamma Cameras, Hyphae chemistry, Hyphae cytology, Hyphae growth & development, Hyphae physiology, Models, Biological, Phanerochaete chemistry, Phanerochaete physiology, Models, Statistical, Phanerochaete cytology, Phanerochaete growth & development

Abstract

Saprotrophic woodland fungi forage for mineral nutrients and woody resources by extension of a mycelial network across the forest floor. Different species explore at different rates and establish networks with qualitatively differing architecture. However, detailed understanding of fungal foraging behaviour has been hampered by the absence of tools to quantify resource allocation and growth accurately and non-invasively. To solve this problem, we have used photon-counting scintillation imaging (PCSI) to map and quantify nutrient allocation and localised growth simultaneously in heterogeneous resource environments. We show that colonies spontaneously shift to an asymmetric growth pattern, even in the absence of added resources, often with a distinct transition between the two growth phases. However, the extent of polarisation was much more pronounced and focussed in the presence of an additional cellulose resource. In this case, there was highly localised growth, often at the expense of growth elsewhere in the colony, and marked accumulation of (14)C-AIB in the sector of the colony with the added resource. The magnitude of the response was greatest when resource was added around the time of the endogenous developmental transition. The focussed response required a metabolisable resource, as only limited changes were seen with glass fibre discs used to mimic the osmotic and thigmotropic stimuli upon resource addition. Overall the behaviour is consistent with an adaptive foraging strategy, both to exploit new resources and also to redirect subsequent foraging effort to this region, presumably with an expectation that the probability of finding additional resources is increased.

Published

2008

14. Emergence of self-organised oscillatory domains in fungal mycelia.

Author

Tlalka M, Bebber DP, Darrah PR, Watkinson SC, and Fricker MD

Subjects

Biological Clocks physiology, Radioisotopes metabolism, Biological Transport, Fungi physiology, Mycelium growth & development

Abstract

Fungi play a central role in the nutrient cycles of boreal and temperate forests. In these biomes, the saprotrophic wood-decay fungi are the only organisms that can completely decompose woody plant litter. In particular, cord-forming basidiomycete fungi form extensive mycelial networks that scavenge scarce mineral nutrients and translocate them over long distances to exploit new food resources. Despite the importance of resource allocation, there is limited information on nutrient dynamics in these networks, particularly for nitrogen, as there is no suitable radioisotope available. We have mapped N-translocation using photon-counting scintillation imaging of the non-metabolised amino acid analogue, (14)C-aminoisobutyrate. We describe a number of novel phenomena, including rapid, preferential N-resource allocation to C-rich sinks, induction of simultaneous bi-directional N-transport, abrupt switching between different pre-existing transport routes, and emergence of locally synchronised, oscillatory phase domains. It is possible that such self-organised oscillatory behaviour is a mechanism to achieve global co-ordination in the mycelium.

Published

2007

15. Biological solutions to transport network design.

Author

Bebber DP, Hynes J, Darrah PR, Boddy L, and Fricker MD

Subjects

Adaptation, Physiological, Basidiomycota growth & development, Biological Transport physiology, Models, Biological, Mycelium growth & development, Mycelium metabolism, Basidiomycota metabolism, Mycelium physiology

Abstract

Transport networks are vital components of multicellular organisms, distributing nutrients and removing waste products. Animal and plant transport systems are branching trees whose architecture is linked to universal scaling laws in these organisms. In contrast, many fungi form reticulated mycelia via the branching and fusion of thread-like hyphae that continuously adapt to the environment. Fungal networks have evolved to explore and exploit a patchy environment, rather than ramify through a three-dimensional organism. However, there has been no explicit analysis of the network structures formed, their dynamic behaviour nor how either impact on their ecological function. Using the woodland saprotroph Phanerochaete velutina, we show that fungal networks can display both high transport capacity and robustness to damage. These properties are enhanced as the network grows, while the relative cost of building the network decreases. Thus, mycelia achieve the seemingly competing goals of efficient transport and robustness, with decreasing relative investment, by selective reinforcement and recycling of transport pathways. Fungal networks demonstrate that indeterminate, decentralized systems can yield highly adaptive networks. Understanding how these relatively simple organisms have found effective transport networks through a process of natural selection may inform the design of man-made networks.

Published

2007

16. The vacuole system is a significant intracellular pathway for longitudinal solute transport in basidiomycete fungi.

Author

Darrah PR, Tlalka M, Ashford A, Watkinson SC, and Fricker MD

Subjects

Basidiomycota ultrastructure, Cell Communication, Cell Compartmentation, Diffusion, Efficiency physiology, Fluoresceins pharmacology, Fluorescent Antibody Technique, Hyphae growth & development, Hyphae physiology, Models, Biological, Signal Transduction, Basidiomycota metabolism, Basidiomycota physiology, Biological Transport physiology, Vacuoles physiology

Abstract

Mycelial fungi have a growth form which is unique among multicellular organisms. The data presented here suggest that they have developed a unique solution to internal solute translocation involving a complex, extended vacuole. In all filamentous fungi examined, this extended vacuole forms an interconnected network, dynamically linked by tubules, which has been hypothesized to act as an internal distribution system. We have tested this hypothesis directly by quantifying solute movement within the organelle by photobleaching a fluorescent vacuolar marker. Predictive simulation models were then used to determine the transport characteristics over extended length scales. This modeling showed that the vacuolar organelle forms a functionally important, bidirectional diffusive transport pathway over distances of millimeters to centimeters. Flux through the pathway is regulated by the dynamic tubular connections involving homotypic fusion and fission. There is also a strongly predicted interaction among vacuolar organization, predicted diffusion transport distances, and the architecture of the branching colony margin.

Published

2006

17. A mathematical model of plant nutrient uptake.

Author

Roose T, Fowler AC, and Darrah PR

Subjects

Mathematical Computing, Plant Roots physiology, Soil, Models, Biological, Plant Roots metabolism, Zea mays metabolism

Abstract

The classical model of plant root nutrient uptake due to Nye. Tinker and Barber is developed and extended. We provide an explicit closed formula for the uptake by a single cylindrical root for all cases of practical interest by solving the absorption-diffusion equation for the soil nutrient concentration asymptotically in the limit of large time. We then use this single root model as a building block to construct a model which allows for root size distribution in a more realistic plant root system, and we include the effects of root branching and growth. The results are compared with previous theoretical and experimental studies.

Published

2001