A New Phenotyping Pipeline Reveals Three Types of Lateral Roots and a Random Branching Pattern in Two Cereals

Passot, Sixtine; Moreno-Ortega, Beatriz; Moukouanga, Daniel; Balsera, Crispulo; Guyomarc’h, Soazig; Lucas, Mikaël; Lobet, Guillaume; Laplaze, Laurent; Muller, Bertrand; Guédon, Yann

doi:10.1104/pp.17.01648

Cited by 32 publications

(46 citation statements)

References 47 publications

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“…Another important caveat of twodimensional (2D) growth systems is that once architectures become large and complex enough for roots to occlude one another, the ability to track the growth of individual roots is greatly diminished and usually unfeasible if grown in soil because the topology is obscured. A recent optical imaging study quantifying lateral root development in millet and maize growing in hydroponic 2D rhizotrons reported an average of 2-d-per-plant processing time using a state-of-the-art semi-automated root tracing tool (Passot et al, 2018). Hence, intense interest in X-ray and magnetic resonance-based 3D imaging for root studies has been warranted (Mooney et al, 2012;Helliwell et al, 2013;Roose et al, 2016;Morris et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Three-Dimensional Time-Lapse Analysis Reveals Multiscale Relationships in Maize Root Systems with Contrasting Architectures

Floro

Bray

et al. 2019

Plant Cell

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Understanding how an organism's phenotypic traits are conditioned by genetic and environmental variation is a central goal of biology. Root systems are one of the most important but poorly understood aspects of plants, largely due to the threedimensional (3D), dynamic, and multiscale phenotyping challenge they pose. A critical gap in our knowledge is how root systems build in complexity from a single primary root to a network of thousands of roots that collectively compete for ephemeral, heterogeneous soil resources. We used time-lapse 3D imaging and mathematical modeling to assess root system architectures (RSAs) of two maize (Zea mays) inbred genotypes and their hybrid as they grew in complexity from a few to many roots. Genetically driven differences in root branching zone size and lateral branching densities along a single root, combined with differences in peak growth rate and the relative allocation of carbon resources to new versus existing roots, manifest as sharply distinct global RSAs over time. The 3D imaging of mature field-grown root crowns showed that several genetic differences in seedling architectures could persist throughout development and across environments. This approach connects individual and system-wide scales of root growth dynamics, which could eventually be used to predict genetic variation for complex RSAs and their functions.

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Section: Introductionmentioning

confidence: 99%

Three-Dimensional Time-Lapse Analysis Reveals Multiscale Relationships in Maize Root Systems with Contrasting Architectures

Floro

Bray

et al. 2019

Plant Cell

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“…The growth of these roots was more or less horizontal in shallow soils and became more and more vertical with increased depth. Conversely, the growth orientation of fine roots, which most likely corresponded to the different types of laterals [13 and 26], was only marginally dependent on soil depth. This led us to develop a model for RLD estimation that considered soil depth as an important variable.…”

Section: Discussionmentioning

confidence: 99%

Development of a model estimating root length density from root impacts on a soil profile in pearl millet (Pennisetum glaucum(L.) R. Br). Application to measure root system response to water stress in field conditions

Faye

Sine

Chopart³

et al. 2019

Preprint

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2 profile in pearl millet (Pennisetum glaucum (L.) R. Br). Application to measure root 3 system response to water stress in field conditions Abstract 27Pearl millet, unlike other cereals, is able to withstand dry and hot conditions and plays an 28 important role for food security in arid and semi-arid areas of Africa and India. However, low 29 soil fertility and drought constrain pearl millet yield. One of the main targets to address these 30 constraints through agricultural practices or breeding is root system architecture. In this study, 31 in order to easily phenotype the root system in field conditions, we developed a model to 32 predict root length density (RLD) of pearl millet plants from root intersection densities (RID) 33 counted on a trench profile in field conditions. We identified root orientation as an important 34 parameter to improve the relationship between RID and RLD. Root orientation was notably 35 found to differ between thick roots (more anisotropic with depth) and fine roots (isotropic at 36 all depths). We used our model to study pearl millet root system response to drought and 37 showed that pearl millet reorients its root growth toward deeper soil layers that retain more 38 water in these conditions. Overall, this model opens ways for the characterization of the 39 impact of environmental factors and management practices on pearl millet root system 40 development. 41 43 Pearl millet (Pennisetum glaucum (L.) R. Br., syn. Cenchrus americanus (L.) Morrone) is a 44 cereal crop domesticated in the Western part of Sahel about 5,000 years ago [1]. It is well 45 adapted to dry tropical climate and low-fertility soils and therefore plays an important role for 46 food security in arid and semi-arid regions of sub-Saharan Africa and India. In these areas, 47 pearl millet is one of the most important sources of nutritious food [2, 3] and is the staple crop 48 for nearly 100 million people [4, 1]. Its grain is rich in protein, essential micronutrients and 49 calories. It is also gluten-free and has hypoallergenic properties [4]. In a context of climate 50 change leading to unpredictable weather patterns and rising temperatures in West Africa [5, 51 6], pearl millet could play an even more important role for food security because it can 52 withstand hot and dry conditions that would lead to the failure of other locally grown cereal 53 crops such as maize or sorghum. However, pearl millet lags far behind other cereals in terms 54 of breeding and its yield is low. The recent sequencing of a reference genome and about 1, 55 000 accessions [4] open the way for a new era of genomic-based breeding in pearl millet.56However, this will depend on the availability of phenotyping methods to characterize and 57 exploit the available genetic diversity and identify interesting target traits. 58Drought and low soil fertility are among the most important factors limiting pearl millet 59 yield. The root system is responsible for water and nutrient uptake, and root system 60 architecture is therefore a potential target ...

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“…To investigate the dynamics of the increase in individual root elongation, lengths of the 10 longest laterals were assessed throughout the 11-day experiments. In previous studies, large variability in both length and elongation rate has been observed among lateral roots in maize (Cahn et al, 1989;Moreno-Ortega et al, 2017;Passot et al, 2018) and other species (Freixes, Thibaud, Tardieu, & Muller, 2002;Muller et al, 2019;Pagès, 1995). F I G U R E 1 Average length of FR697 (a) and B73 (b) primary (black and red) and seminal (blue and orange) axial roots during 11 days after transplanting (DAT) to well-watered (WW) conditions (black and blue) or a mild water deficit (MWD) treatment at a transplant Ψ w of −0.28 MPa (red and orange).…”

Section: Dynamic Responses Of Lateral Root Length Elongation Rate mentioning

confidence: 92%

“…In the MWD treatment, in contrast, the genotypes exhibited strongly divergent responses from 4 DAT. Whereas the growth pattern of B73 roots was very similar under WW and MWD conditions throughout the experiments (Figure 3b We selected the 10 longest roots, which exhibited maximum elongation rates that were similar to those of the fastest-growing category characterized previously (Moreno-Ortega et al, 2017;Passot et al, 2018). However, the growth duration exhibited in both FR697…”

Section: Dynamic Responses Of Lateral Root Length Elongation Rate mentioning

confidence: 96%

Maize lateral root developmental plasticity induced by mild water stress. II: Genotype‐specific spatio‐temporal effects on determinate development

Dowd

Braun

Sharp

2020

Plant Cell & Environment

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Maize lateral roots exhibit determinate growth, whereby the meristem is genetically programmed to stop producing new cells. To explore whether lateral root determinacy is modified under water deficits, we studied two maize genotypes (B73 and FR697) with divergent responses of lateral root growth to mild water stress using an experimental system that provided near‐stable water potential environments throughout lateral root development. First‐order laterals of the primary root system of FR697 exhibited delayed determinacy when grown at a water potential of −0.28 MPa, resulting in longer and wider roots than in well‐watered (WW) controls. In B73, in contrast, neither the length nor width of lateral roots was affected by water deficit. In water‐stressed FR697, root elongation continued at or above the maximum rate in WW roots for 3 days longer, and was still 45% of maximum when WW roots approached their determinate length. Maintenance of root elongation was associated with sustained rates of cell production. In addition, kinematic analyses showed that reductions in tissue expansion rates with aging were delayed in the longitudinal, radial and tangential planes throughout the root growth zone. Thus, this study reveals large genotypic differences in the interaction of water stress with developmental determinacy of maize lateral roots.

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A New Phenotyping Pipeline Reveals Three Types of Lateral Roots and a Random Branching Pattern in Two Cereals

Cited by 32 publications

References 47 publications

Three-Dimensional Time-Lapse Analysis Reveals Multiscale Relationships in Maize Root Systems with Contrasting Architectures

Three-Dimensional Time-Lapse Analysis Reveals Multiscale Relationships in Maize Root Systems with Contrasting Architectures

Development of a model estimating root length density from root impacts on a soil profile in pearl millet (Pennisetum glaucum(L.) R. Br). Application to measure root system response to water stress in field conditions

Maize lateral root developmental plasticity induced by mild water stress. II: Genotype‐specific spatio‐temporal effects on determinate development

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