Perennial grass root system specializes for multiple resource acquisitions with differential elongation and branching patterns

Glass, Nicholas T.; Yun, Kyungdahm; Oliveira, Eduardo Augusto Dias de; Zare, Alina; Matamala, Roser; Kim, Soo-Hyung; Gonzàlez-Meler, Miquel A.

doi:10.3389/fpls.2023.1146681

Cited by 2 publications

(1 citation statement)

References 92 publications

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“…Root plasticity allows the plant to adapt to the changes in environmental conditions of the heterogenous soil matrix (Morris et al ., 2017; Lippold et al ., 2022; Glass et al ., 2023). Both plants adapted their root morphology to the local structures they encountered (Fig.…”

Section: Discussionmentioning

confidence: 99%

The soil pore structure encountered by roots affects plant‐derived carbon inputs and fate

et al. 2023

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Summary Plant roots are the main supplier of carbon (C) to the soil, the largest terrestrial C reservoir. Soil pore structure drives root growth, yet how it affects belowground C inputs remains a critical knowledge gap. By combining X‐ray computed tomography with 14C plant labelling, we identified root–soil contact as a previously unrecognised influence on belowground plant C allocations and on the fate of plant‐derived C in the soil. Greater contact with the surrounding soil, when the growing root encounters a pore structure dominated by small (< 40 μm Ø) pores, results in strong rhizodeposition but in areas of high microbial activity. The root system of Rudbeckia hirta revealed high plasticity and thus maintained high root–soil contact. This led to greater C inputs across a wide range of soil pore structures. The root–soil contact Panicum virgatum, a promising bioenergy feedstock crop, was sensitive to the encountered structure. Pore structure built by a polyculture, for example, restored prairie, can be particularly effective in promoting lateral root growth and thus root–soil contact and associated C benefits. The findings suggest that the interaction of pore structure with roots is an important, previously unrecognised, stimulus of soil C gains.

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Section: Discussionmentioning

confidence: 99%

The soil pore structure encountered by roots affects plant‐derived carbon inputs and fate

et al. 2023

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Bridging Time-series Image Phenotyping and Functional–Structural Plant Modeling to Predict Adventitious Root System Architecture

Parasurama,

Banan,

Yun

et al. 2023

Plant Phenomics

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Root system architecture (RSA) is an important measure of how plants navigate and interact with the soil environment. However, current methods in studying RSA must make tradeoffs between precision of data and proximity to natural conditions, with root growth in germination papers providing accessibility and high data resolution. Functional–structural plant models (FSPMs) can overcome this tradeoff, though parameterization and evaluation of FSPMs are traditionally based in manual measurements and visual comparison. Here, we applied a germination paper system to study the adventitious RSA and root phenology of Populus trichocarpa stem cuttings using time-series image-based phenotyping augmented by FSPM. We found a significant correlation between timing of root initiation and thermal time at cutting collection ( P value = 0.0061, R 2 = 0.875), but little correlation with RSA. We also present a use of RhizoVision [ 1 ] for automatically extracting FSPM parameters from time series images and evaluating FSPM simulations. A high accuracy of the parameterization was achieved in predicting 2D growth with a sensitivity rate of 83.5%. This accuracy was lost when predicting 3D growth with sensitivity rates of 38.5% to 48.7%, while overall accuracy varied with phenotyping methods. Despite this loss in accuracy, the new method is amenable to high throughput FSPM parameterization and bridges the gap between advances in time-series phenotyping and FSPMs.

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Perennial grass root system specializes for multiple resource acquisitions with differential elongation and branching patterns

Cited by 2 publications

References 92 publications

The soil pore structure encountered by roots affects plant‐derived carbon inputs and fate

The soil pore structure encountered by roots affects plant‐derived carbon inputs and fate

Bridging Time-series Image Phenotyping and Functional–Structural Plant Modeling to Predict Adventitious Root System Architecture

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