Your search keyword '"Roose T"' showing total 10 results

1. Linking root structure to functionality: the impact of root system architecture on citrate-enhanced phosphate uptake.

Author

McKay Fletcher DM, Ruiz S, Dias T, Petroselli C, and Roose T

Subjects

Biological Transport, Meristem, Plant Roots, Citric Acid, Phosphates

Abstract

Root citrate exudation is thought to be important for phosphate solubilization. Previous research has concluded that cluster-like roots benefit most from this exudation in terms of increased phosphate uptake, suggesting that root structure plays an important role in citrate-enhanced uptake (additional phosphate uptake due to citrate exudation). Time-resolved computed tomography images of wheat root systems were used as the geometry for 3D citrate-phosphate solubilization models. Citrate-enhanced uptake was correlated with morphological measures of the root systems to determine which had the most benefit. A large variation of citrate-enhanced uptake over 11 root structures was observed. Root surface area dominated absolute phosphate uptake, but did not explain citrate-enhanced uptake. Number of exuding root tips correlated well with citrate-enhanced uptake. Root tips in close proximity could collectively exude high amounts of citrate, resulting in a delayed spike in citrate-enhanced uptake. Root system architecture plays an important role in citrate-enhanced uptake. Singular morphological measurements of the root systems cannot entirely explain variations in citrate-enhanced uptake. Root systems with many tips would benefit greatly from citrate exudation. Quantifying citrate-enhanced uptake experimentally is difficult as variations in root surface area would overwhelm citrate benefits., (© 2020 The Authors. New Phytologist © 2020 New Phytologist Trust.)

Published

2020

2. How changing root system architecture can help tackle a reduction in soil phosphate (P) levels for better plant P acquisition.

Author

Heppell J, Talboys P, Payvandi S, Zygalakis KC, Fliege J, Withers PJ, Jones DL, and Roose T

Subjects

Biological Transport, Models, Theoretical, Plant Roots anatomy & histology, Plant Roots metabolism, Rhizosphere, Soil chemistry, Triticum anatomy & histology, Models, Biological, Phosphates metabolism, Triticum metabolism

Abstract

The readily available global rock phosphate (P) reserves may run out within the next 50-130 years, causing soils to have a reduced P concentration which will affect plant P uptake. Using a combination of mathematical modelling and experimental data, we investigated potential plant-based options for optimizing crop P uptake in reduced soil P environments. By varying the P concentration within a well-mixed agricultural soil, for high and low P (35.5-12.5 mg L(-1) respectively using Olsen's P index), we investigated branching distributions within a wheat root system that maximize P uptake. Changing the root branching distribution from linear (evenly spaced branches) to strongly exponential (a greater number of branches at the top of the soil) improves P uptake by 142% for low-P soils when root mass is kept constant between simulations. This causes the roots to emerge earlier and mimics topsoil foraging. Manipulating root branching patterns, to maximize P uptake, is not enough on its own to overcome the drop in soil P from high to low P. Further mechanisms have to be considered to fully understand the impact of P reduction on plant development., (© 2014 John Wiley & Sons Ltd.)

Published

2015

3. High resolution synchrotron imaging of wheat root hairs growing in soil and image based modelling of phosphate uptake.

Author

Keyes SD, Daly KR, Gostling NJ, Jones DL, Talboys P, Pinzer BR, Boardman R, Sinclair I, Marchant A, and Roose T

Subjects

Computer Simulation, Models, Biological, Rhizosphere, Imaging, Three-Dimensional methods, Phosphates metabolism, Plant Roots anatomy & histology, Plant Roots growth & development, Soil, Synchrotrons, Triticum anatomy & histology

Abstract

· Root hairs are known to be highly important for uptake of sparingly soluble nutrients, particularly in nutrient deficient soils. Development of increasingly sophisticated mathematical models has allowed uptake characteristics to be quantified. However, modelling has been constrained by a lack of methods for imaging live root hairs growing in real soils. · We developed a plant growth protocol and used Synchrotron Radiation X-ray Tomographic Microscopy (SRXTM) to uncover the three-dimensional (3D) interactions of root hairs in real soil. We developed a model of phosphate uptake by root hairs based directly on the geometry of hairs and associated soil pores as revealed by imaging. · Previous modelling studies found that root hairs dominate phosphate uptake. By contrast, our study suggests that hairs and roots contribute equally. We show that uptake by hairs is more localized than by roots and strongly dependent on root hair and aggregate orientation. · The ability to image hair-soil interactions enables a step change in modelling approaches, allowing a more realistic treatment of processes at the scale of individual root hairs in soil pores., (© 2013 The Authors. New Phytologist © 2013 New Phytologist Trust.)

Published

2013

4. A dual porosity model of nutrient uptake by root hairs.

Author

Zygalakis KC, Kirk GJ, Jones DL, Wissuwa M, and Roose T

Subjects

Computer Simulation, Humidity, Plant Roots anatomy & histology, Porosity, Soil, Water metabolism, Models, Biological, Phosphates metabolism, Plant Roots metabolism

Abstract

• The importance of root hairs in the uptake of sparingly soluble nutrients is understood qualitatively, but not quantitatively, and this limits efforts to breed plants tolerant of nutrient-deficient soils. • Here, we develop a mathematical model of nutrient uptake by root hairs allowing for hair geometry and the details of nutrient transport through soil, including diffusion within and between soil particles. We give illustrative results for phosphate uptake. • Compared with conventional 'single porosity' models, this 'dual porosity' model predicts greater root uptake because more nutrient is available by slow release from within soil particles. Also the effect of soil moisture is less important with the dual porosity model because the effective volume available for diffusion in the soil is larger, and the predicted effects of hair length and density are different. • Consistent with experimental observations, with the dual porosity model, increases in hair length give greater increases in uptake than increases in hair density per unit main root length. The effect of hair density is less in dry soil because the minimum concentration in solution for net influx is reached more rapidly. The effect of hair length is much less sensitive to soil moisture., (© 2011 The Authors. New Phytologist © 2011 New Phytologist Trust.)

Published

2011

5. A dynamic model of nutrient uptake by root hairs.

Author

Leitner D, Klepsch S, Ptashnyk M, Marchant A, Kirk GJ, Schnepf A, and Roose T

Subjects

Plant Roots growth & development, Models, Biological, Phosphates metabolism, Plant Roots metabolism

Abstract

Root hairs are known to be important in the uptake of sparingly soluble nutrients by plants, but quantitative understanding of their role in this is weak. This limits, for example, the breeding of more nutrient-efficient crop genotypes. We developed a mathematical model of nutrient transport and uptake in the root hair zone of single roots growing in soil or solution culture. Accounting for root hair geometry explicitly, we derived effective equations for the cumulative effect of root hair surfaces on uptake using the method of homogenization. Analysis of the model shows that, depending on the morphological and physiological properties of the root hairs, one of three different effective models applies. They describe situations where: (1) a concentration gradient dynamically develops within the root hair zone; (2) the effect of root hair uptake is negligibly small; or (3) phosphate in the root hair zone is taken up instantaneously. Furthermore, we show that the influence of root hairs on rates of phosphate uptake is one order of magnitude greater in soil than solution culture. The model provides a basis for quantifying the importance of root hair morphological and physiological properties in overall uptake, in order to design and interpret experiments in different circumstances.

Published

2010

6. Modelling the contribution of arbuscular mycorrhizal fungi to plant phosphate uptake.

Author

Schnepf A and Roose T

Subjects

Hyphae physiology, Models, Biological, Phosphates deficiency, Soil, Mycorrhizae metabolism, Phosphates metabolism, Plants metabolism

Abstract

In this paper, we investigate the role of arbuscular mycorrhizal fungi in plant phosphorus nutrition. We develop a mathematical model which quantitatively assesses the contribution of external fungal hyphae to plant phosphate uptake. We derive an equation for solute uptake by a growing fungal mycelium which we couple with a model for root uptake. We analyse the model using nondimensionalization and numerical simulations. Simulations predict that removal of phosphate from soil is dominated by hyphal uptake as opposed to root uptake. Model analysis shows that the depletion zones around hyphae overlap within 8 h and that the transfer between fungus and root is a critical step for the behaviour of phosphorus within the mycelial phase. We also show that the volume fraction of mycelium is negligibly small in comparison to other soil phases. This is the first model to quantify the contribution of mycorrhizal fungi to plant phosphate uptake. A full data set for model parametrization and validation is not currently available. Therefore, more complete sets of experimental measurements are necessary to make this model more applicable.

Published

2006

7. A mathematical model for water and nutrient uptake by plant root systems.

Author

Roose T and Fowler AC

Subjects

Models, Biological, Plant Roots anatomy & histology, Soil, Phosphates, Plant Roots physiology, Water

Abstract

This article deals with modelling the simultaneous uptake of water and highly buffered nutrient, such as phosphate, by root branching structures from partially saturated soil. We use the simultaneous water and nutrient uptake model to investigate the effect that water movement has on nutrient uptake. With the aid of this model we are also able to show that the previous models by Barber and Tinker and Nye systematically underestimated the phosphate uptake, due to the oversimplified approach in dealing with root branching structure. In this article we show how this discrepancy can be remedied and the root branching structure included in the models of plant nutrient uptake. We will also discuss the differences in the results for continuous and spot fertilization combined with variable rainfall.

Published

2004

8. Verification and intercomparison of reactive transport codes to describe root-uptake

Author

Nowack, B., Mayer, K. U., Oswald, S. E., van Beinum, W., Appelo, C. A. J., Jacques, D., Seuntjens, P., Gérard, F., Jaillard, B., Schnepf, A., and Roose, T.

Published

2006

9. Quantifying citrate-enhanced phosphate root uptake using microdialysis.

Author

McKay Fletcher, D. M., Shaw, R., Sánchez-Rodríguez, A. R., Daly, K. R., van Veelen, A., Jones, D. L., and Roose, T.

Subjects

MICRODIALYSIS, CITRATES, PLANT roots, ORGANIC acids, RHIZOSPHERE, PHOSPHATES, NUTRIENT uptake

Abstract

Aims: Organic acid exudation by plant roots is thought to promote phosphate (P) solubilisation and bioavailability in soils with poorly available nutrients. Here we describe a new combined experimental (microdialysis) and modelling approach to quantify citrate-enhanced P desorption and its importance for root P uptake. Methods: To mimic the rhizosphere, microdialysis probes were placed in soil and perfused with citrate solutions (0.1, 1.0 and 10 mM) and the amount of P recovered from soil used to quantify rhizosphere P availability. Parameters in a mathematical model describing probe P uptake, citrate exudation, P movement and citrate-enhanced desorption were fit to the experimental data. These parameters were used in a model of a root which exuded citrate and absorbed P. The importance of soil citrate-P mobilisation for root P uptake was then quantified using this model. Results: A plant needs to exude citrate at a rate of 0.73 μmol cm−1 of root h−1 to see a significant increase in P absorption. Microdialysis probes with citrate in the perfusate were shown to absorb similar quantities of P to an exuding root. Conclusion: A single root exuding citrate at a typical rate (4.3 × 10−5 μmol m−1 of root h−1) did not contribute significantly to P uptake. Microdialysis probes show promise for measuring rhizosphere processes when calibration experiments and mathematical modelling are used to decouple microdialysis and rhizosphere mechanisms. [ABSTRACT FROM AUTHOR]

Published

2021

10. Comparison of nutrient uptake between three-dimensional simulation and an averaged root system model.

Author

Leitner, D., Schnepf, A., Klepsch, S., and Roose, T.

Subjects

PLANT roots, PLANT nutrients, COMPUTER simulation, RHIZOSPHERE, PHOSPHATES, COMPUTERS in botany

Abstract

We present a new numerical approach describing nutrient uptake in three dimensions. Dynamic boundary conditions are considered at the individual root surfaces within a root system. As an example, we compare the three-dimensional simulation results of phosphate uptake by a young maize root system to the corresponding effective solution. We show that the two solutions are similar concerning phosphate uptake and the size of the depletion zones. The presented approach makes it possible to verify simplifications that are made in the development of effective models. Furthermore, it is possible to extend existing models by including spatial heterogeneities that will increase our understanding of rhizosphere processes. [ABSTRACT FROM AUTHOR]

Published

2010