High-resolution quantification of root dynamics in split-nutrient rhizoslides reveals rapid and strong proliferation of maize roots in response to local high nitrogen.

Dina In 'T Zandt,Eric J W Visser,Chantal Le Marié,Norbert Kirchgessner,Andreas Hund

doi:10.1093/jxb/erv307

Dina In 'T Zandt, Eric J W Visser + Show 3 more

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https://doi.org/10.1093/jxb/erv307

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Journal: Journal of experimental botany	Publication Date: Jun 23, 2015
Citations: 21	License type: cc-by

Affiliation: Radboud University Nijmegen

Abstract

The plant's root system is highly plastic, and can respond to environmental stimuli such as high nitrogen (N) in patches. A root may respond to an N patch by selective placement of new lateral roots, and therewith increases root N uptake. This may be a desirable trait in breeding programmes, since it decreases NO3(-) leaching and N2O emission. Roots of maize (Zea mays L.) were grown without N in split-nutrient rhizoslides. One side of the slides was exposed to high N after 15 d of root development, and root elongation was measured for another 15 d, described in a time course model and parameterized. The elongation rates of crown axile roots on the N-treated side of the plant followed a logistic increase to a maximum of 5.3cm d(-1); 95% of the maximum were reached within 4 d. At the same time, on the untreated side, axile root elongation dropped linearly to 1.2cm d(-1) within 6.4 d and stayed constant thereafter. Twice as many lateral roots were formed on the crown axis on the N side compared to the untreated side. Most strikingly, the elongation rates of laterals of the N side increased linearly with most of the roots reaching an asymptote ~8 d after start of the N treatment. By contrast, laterals on the side without N did not show any detectable elongation beyond the first day after their emergence. We conclude that split-nutrient rhizoslides have great potential to improve our knowledge about nitrogen responsiveness and selection for contrasting genotypes.

Highlights

Sustainable agriculture is of utmost importance to feed the ever-increasing world population
The importance of the crown root system was suggested by a positive correlation between dry weight of the part of the root system in the high N compartment and the dry weight of the shoot, whereas no correlation was found between biomass of the β1 e −((β2
Similar dramatic increases in elongation rates were not observed in seminal roots in experiments by Drew et al (1973) on barley

Summary

Introduction

Sustainable agriculture is of utmost importance to feed the ever-increasing world population. Nitrogen fertilization causes pollution of ground, surface and coastal waters via NO3- leaching (Galloway et al 2003, 2004; ENA 2011) and increases N2O emission, which contributes to global warming (IPCC, 2013; UNEP, 2013). In this context, it is a crucial goal to decrease such N losses without reducing crop yield. An effective placement of roots would be needed to fully exploit the N patch supplied in this agrotechnique. Studying root placement in the field in detail is difficult, due to neighbouring plants and the need for an invasive excavation of the root system. We quantified the response of maize roots to a high N patch in a rhizoslide

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