Beyond efficiency: The multi-scale architecture of robust water transport in plants

Magdalena Julkowska; Guillaume Lobet; Arjun Chandrasekhar

doi:10.1017/qpb.2025.10035

Beyond efficiency: The multi-scale architecture of robust water transport in plants

Published online by Cambridge University Press: 12 December 2025

Magdalena Julkowska

Guillaume Lobet and

Arjun Chandrasekhar

Show author details

Magdalena Julkowska*: Affiliation:
Boyce Thompson Institute for Plant Research , USA
Guillaume Lobet: Affiliation:
UCLouvain , Belgium
Arjun Chandrasekhar: Affiliation:
Department of Math and Computer Science, Southwestern University , USA
*: Corresponding author: Magdalena Julkowska; Email: mmj55@cornell.edu

Article contents

Abstract
Introduction
Components of robustness
Laying the foundation of hydraulic functionality at the anatomical scale
Building below-ground robustness through root system architecture
Beyond the reference: (Pan)genomic basis of robust water transport
Measuring robustness: Quantifying the invisible buffer
Conclusions and future perspectives
Open peer review
Competing interest
Data availability statement
Author contributions
Funding statement
Footnotes
References

Abstract

Agronomic research has long prioritized efficiency – optimizing resource use to maximize yield under stable conditions. However, as climate variability intensifies, efficiency alone might be insufficient to sustain agricultural production in the future. Instead, robustness – the ability to maintain function across diverse and unpredictable environments – emerges as a critical trait. Robustness is not a simple metric but an emergent property, arising from the interplay of redundancy, heterogeneity and plasticity across biological scales. We examine how the components of robustness (redundance, heterogeneity and plasticity) express themselves at the anatomical, architectural and genomic scale. A major challenge is the lack of a unified framework to measure robustness. We propose integrating empirical metrics – such as vessel grouping indices, root trait heterogeneity and gene expression plasticity – with computational models to quantify redundancy, heterogeneity and plasticity. By synthesizing insights from physiology, genomics and modelling, we outline a path towards designing crops that thrive in ideal settings and under environmental uncertainty.

Keywords

drought stress root anatomy root system architecture salt stress

Information

Type: Review
Information: Quantitative Plant Biology , Volume 7 , 2026 , e1

DOI: https://doi.org/10.1017/qpb.2025.10035 [Opens in a new window]
Creative Commons: This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright: © The Author(s), 2025. Published by Cambridge University Press in association with John Innes Centre

1. Introduction

For decades, agronomic success has been tightly linked to the pursuit of efficiency – how effectively plants convert limited resources into biomass or yield. The concept of water use efficiency was initially described over 100 years ago by Briggs and Schatz (Reference Briggs and Shantz1913) and further refined by Passioura (Reference Passioura1982), framing crop productivity as a product of three interacting components: water uptake, water transport and transpiration efficiency. Similar metrics – such as nitrogen use efficiency (Moll et al., Reference Moll, Kamprath and Jackson1982) and radiation use efficiency (Monteith & Moss, Reference Monteith and Moss1977) – have guided breeding and modelling efforts by focusing on input–output ratios. While optimizing for efficiency can lead to highly productive plants under specific conditions, it can also create ‘one-trick ponies’ – genotypes that perform well in heavily controlled environments but fail dramatically when conditions shift. This generates the yield gap, since the plants are not reaching their maximum potential in real-life scenarios.

In a fluctuating environment and changing climate, the focus on efficiency alone does not suffice to sustain plant growth (Rellán-Álvarez et al., Reference Rellán-Álvarez, Lobet and Dinneny2016). This demands a shift in focus from efficiency alone to robustness – the ability to maintain function across diverse and unpredictable environments. Unlike efficiency, robustness is not easily reduced to a single number (Liu et al., Reference Liu, Zhou, Wang and Liu2017). It is an emergent property of biological systems, arising from interactions among redundancy, heterogeneity and plasticity across biological scales.

Water transport – spanning the soil–plant–atmosphere continuum – is an ideal system through which to explore this balance. It is inherently dynamic, subject to spatial and temporal variation in soil moisture, atmospheric demand and anatomy (Martínez-Vilalta et al., Reference Martínez-Vilalta, Poyatos, Aguadé, Retana and Mencuccini2014). In this review, we examine how robustness in water transport manifests at the cellular and tissue level, through the root system architecture, to the genomic scales. We also take a stab at addressing a major gap in the field – how to measure robustness. While plant biologists have long studied robustness in various forms (Alseekh et al., Reference Alseekh, Klemmer, Yan, Guo and Fernie2025; Lachowiec et al., Reference Lachowiec, Queitsch and Kliebenstein2016; Masel & Siegal, Reference Masel and Siegal2009; Møller & Shykoff, Reference Møller and Shykoff1999), there has been no unified framework to quantify it. Here, we propose such a framework for root systems, grounded in empirical and modelling approaches, to capture the dimensions of robustness that are critical for building resilient crops (Figure 1).

2. Components of robustness

In computer science and engineering, efficiency refers to the use of minimal resources for maximal output, often resulting in streamlined designs with minimal redundancy. In contrast, robustness denotes a system’s ability to maintain functionality despite perturbations or failures, often achieved through structural and functional redundancies, heterogeneous components and dynamic plasticity in response to changing conditions (Doyle et al., Reference Doyle, Alderson, Li, Low, Roughan, Shalunov, Tanaka and Willinger2005; Kitano, Reference Kitano2004; Psaier & Dustdar, Reference Psaier and Dustdar2011), including physical component failures (Nelson, Reference Nelson1990), adversarial attacks (Muhammad & Bae, Reference Muhammad and Bae2022) and transmission errors (Berlekamp, Reference Berlekamp1980). These design principles – redundancy, heterogeneity and plasticity – are not only hallmarks of engineered fault-tolerant systems but also critical features of plant water transport systems.

Figure 1. Graphical overview of principles underlying root hydraulic robustness.Note: The aspects related to redundancy are highlighted in pink, aspects related to heterogeneity as highlighted in purple, while aspects related to plasticity are highlighted in light green. On an anatomical level, redundancy arises from multiple conduits and barriers that maintain water flow under failure; heterogeneity reflects variation in xylem structure and tissue composition that diversifies hydraulic safety; and plasticity captures dynamic modifications in suberization and xylem differentiation that adjust conductivity to stress. On root architecture scale, redundancy is expressed through overlapping root classes and compensatory branching patterns that sustain water uptake; heterogeneity emerges from spatial and temporal diversity in root types, depths and growth angles; and plasticity encompasses environmentally driven reconfiguration of root distribution through tropisms (e.g., hydro-patterning) and growth arrest–reactivation cycles. On a genomic scale, redundancy stems from gene and genome duplications providing functional backup; heterogeneity reflects allelic and structural variation shaping population-level adaptability; and plasticity manifests as stress-responsive transcriptional and epigenetic reprogramming that enables rapid adjustment of hydraulic traits. The grey arrows indicate interactions between individual scales of root hydraulic organization.

Plant hydraulic architecture must withstand a variety of stressors, including drought, salinity and mechanical damage. Understanding how redundancy, heterogeneity and plasticity act at various biological scales, from cellular traits to root system architecture and genomic organization, allows for a holistic view of robustness in plant water transport.

While we treat redundancy, heterogeneity and plasticity as distinct contributors to robustness, they are not mutually exclusive. Heterogeneity captures inherent or developmentally programmed variability among components – whether cells, tissues or genotypes – whereas plasticity describes context-dependent changes in those components triggered by environmental or physiological cues. In practice, the two can overlap – for example, stress-induced variation in vessel diameter or gene expression may appear as heterogeneity when observed across individuals, yet originates from plastic responses within each. Acknowledging this continuum clarifies that robustness arises not only from static diversity, but also from the capacity of that diversity to be reshaped through plasticity.

3. Laying the foundation of hydraulic functionality at the anatomical scale

At the anatomical level, the efficiency and robustness of plant water transport networks are governed by a finely tuned interplay between xylem architecture, vessel connectivity and apoplastic modifications. These structures form the physical basis for the ascent of water through plants and are shaped by evolutionary pressures to balance the demands of hydraulic conductivity with the need to withstand environmental perturbations (Bouda et al., Reference Bouda, Huggett, Prats, Wason, Wilson and Brodersen2022).

Redundancy at the tissue level is evident in the spatial organization and grouping of xylem vessels. Many species, especially those adapted to drought-prone environments, exhibit high vessel redundancy through the presence of multiple conduits per vascular bundle or extensive vessel interconnection (Boughalleb et al., Reference Boughalleb, Abdellaoui, Ben-Brahim and Neffati2014, Reference Boughalleb, Abdellaoui, Hadded and Neffati2015; Salih et al., Reference Salih, Ali, Lux, Luxová, Cohen, Sugimoto and Inanaga1999). This redundancy provides resilience by maintaining water flow even when individual vessels become embolized due to drought or freeze–thaw events (Carlquist, Reference Carlquist2009). The vessel grouping index, a metric used to quantify the connectivity of secondary xylem vessels within a given cross-section (and that is computed as the total number of vessels divided by the total number of vessel groups – a solitary vessel counts as one vessel group), has been proposed as a proxy for hydraulic redundancy (Lens et al., Reference Lens, Sperry, Christman, Choat, Rabaey and Jansen2011). High grouping indices correlate with increased resistance to total hydraulic failure, as embolism can be confined to isolated clusters rather than spreading systemically (Sperry et al., Reference Sperry, Meinzer and McCulloh2008).

Importantly, different anatomical-scale processes are redundant in themselves, providing multiple ways for the plant to reach the same functional features. For instance, decreasing root radial conductivity could be achieved by creating apoplastic barriers, but also by decreasing the production and activity of aquaporins, or a mix of both (Heymans et al., Reference Heymans, Couvreur, LaRue, Paez-Garcia and Lobet2020). This leaves plants with multiple strategies, each with specific costs and benefits. Understanding how this diversity of mechanisms is coordinated, and under which conditions, remains an open question.

Xylem heterogeneity enhances robustness by diversifying the mechanical and hydraulic properties within and among tissues. Vessel diameter, wall thickness, pit membrane structure and lignin composition can vary both ontogenetically (along the root or stem axis) and across species or genotypes (Burton et al., Reference Burton, Brown and Lynch2013; Heymans et al., Reference Heymans, Couvreur and Lobet2021; McLaughlin et al., Reference McLaughlin, Li, Perryman, Heymans, Schneider, Lasky and Sawers2024). Wider vessels generally confer greater efficiency but are more prone to embolism, while narrower vessels offer safety at the cost of reduced conductance – highlighting a classic safety-efficiency trade-off (Affortit et al., Reference Affortit, Faye, Jones, Benson, Sine, Burridge, Ndoye, Barry, Moukouanga, Barnard, Bhosale, Pridmore, Gantet, Vadez, Cubry, Kane, Bennett, Atkinson, Laplaze and Grondin2024; Hacke et al., Reference Hacke, Sperry, Wheeler and Castro2006). Additionally, heterogeneity can emerge within a single organ. For example, metaxylem and protoxylem differ in diameter, lignification and developmental timing, providing layered responses to environmental stress. Anatomical compartmentalization into hydraulically isolated sectors – e.g., sectors with differing vulnerability to embolism – enables partial functionality even under stress (Choat et al., Reference Choat, Sack and Holbrook2007). This intra-plant variability is increasingly recognized as a form of structural bet-hedging, especially relevant under unpredictable water availability.

Plants also exhibit a high degree of plasticity in response to environmental cues. A prime example is the modulation of apoplastic barriers, such as suberin and lignin, in the endodermis and exodermis (Cantó-Pastor et al., Reference Cantó-Pastor, Kajala, Shaar-Moshe, Manzano, Timilsena, De Bellis, Gray, Holbein, Yang, Mohammad, Nirmal, Suresh, Ursache, Mason, Gouran, West, Borowsky, Shackel, Sinha and Brady2024). These barriers regulate radial water and ion transport into the stele and are critical under drought and salinity stress. Suberization patterns can shift dynamically in response to soil water content, often increasing under drought to prevent water loss or under salt stress to restrict ion entry (Barberon et al., Reference Barberon, Vermeer, De Bellis, Wang, Naseer, Andersen, Humbel, Nawrath, Takano, Salt and Geldner2016). Plastic responses are also evident in xylem development. For instance, drought can accelerate xylem maturation and shift the balance between vessel size and number, reducing vulnerability to cavitation (Jang & Choi, Reference Jang and Choi2018; Ramachandran et al., Reference Ramachandran, Augstein, Nguyen and Carlsbecker2020). This developmental flexibility can be transient (reversible anatomical shifts) or involve longer-term acclimation via hormone-mediated signalling pathways, such as abscisic acid or auxin (Nieminen et al., Reference Nieminen, Blomster, Helariutta and Mähönen2015). Some of the observed variation in vessel size and structure likely reflects plastic developmental responses to environmental conditions, blurring the line between anatomical heterogeneity and plasticity.

4. Building below-ground robustness through root system architecture

Root system architecture defines the spatial and temporal organization of a plant’s root network, directly influencing water acquisition efficiency and its robustness under environmental stress. The dynamic and hierarchical nature of root architecture – including primary, lateral or shoot-born roots – offers a rich framework for evaluating how plants achieve resilience via redundancy, heterogeneity and plasticity at the whole-organ level. These features shape not only how roots explore soil domains but also how they buffer against localized water scarcity or mechanical obstacles.

Root system architecture redundancy refers to the presence of overlapping or compensatory root structures that serve similar hydraulic functions. In monocots such as maize, the presence of multiple shoot-born root whorls provides hydraulic redundancy across both depth and lateral spread (Hochholdinger et al., Reference Hochholdinger, Park, Sauer and Woll2004). In dicots, extensive lateral root branching, over several topological orders, ensures that if a portion of the primary root system is damaged or underperforms, other root segments can compensate by accessing adjacent or deeper water pools (Lynch, Reference Lynch2011; Schneider & Lynch, Reference Schneider and Lynch2020). This distributed design confers robustness by minimizing the risk that water uptake is catastrophically disrupted by localized root failure or patchy drought conditions. Recently, a meta-analysis of root system hydraulic properties across more than 200 plant species has shown that the root system conductivity tends to stabilize after 60 days, despite a continuous increase in root number and growth (Baca Cabrera et al., Reference Baca Cabrera, Vanderborght, Couvreur, Behrend, Gaiser, Nguyen and Lobet2024). This illustrates that, at a certain developmental point, any additional roots do not contribute to an increase in function anymore, but rather a stabilization of the existing ones.

Similar to the anatomy, the redundancy of root developmental processes (in addition to redundancy in structures) also ensures that identical functions can be reached in many different ways. Increasing the global root system conductivity can be achieved by increasing the lateral branching density, changing root diameters or increasing the primary root growth rates (Klein et al., Reference Klein, Schneider, Perkins, Brown and Lynch2020; Meunier et al., Reference Meunier, Heymans, Draye, Couvreur, Javaux and Lobet2020). Again, these different strategies are tied to different costs and benefits, creating multiple redundant development pathways that could potentially be leveraged in different environments.

Root systems also display striking heterogeneity in both structure and function. Different root classes vary in their growth angles, anatomy, final length, lifespan and hydraulic conductance. For example, steeper roots (e.g., the DEEPER ROOTING 1 trait in rice) can access groundwater reserves (Uga et al., Reference Uga, Sugimoto, Ogawa, Rane, Ishitani, Hara, Kitomi, Inukai, Ono, Kanno, Inoue, Takehisa, Motoyama, Nagamura, Wu, Matsumoto, Takai, Okuno and Yano2013). Within a single genotype, differences in suberization, xylem architecture and aquaporin expression can be observed both along and between lateral roots (Bagniewska-Zadworna et al., Reference Bagniewska-Zadworna, Byczyk, Eissenstat, Oleksyn and Zadworny2012; De Rybel et al., Reference De Rybel, Mähönen, Helariutta and Weijers2016; Wang et al., Reference Wang, Wang, Li, Li, Xu, Cohen, Aharoni and Wu2020). Developmental zonation further introduces heterogeneity, as younger root zones are more permeable and responsive to environmental cues than mature zones. This spatial variation in function allows plants to exploit a range of soil microenvironments and reduces reliance on any single root portion. Even within roots of the same topological order, random heterogeneity has been observed and quantified in several plant species (Passot et al., Reference Passot, Moreno-Ortega, Moukouanga, Balsera, Guyomarc’h, Lucas, Lobet, Laplaze, Muller and Guédon2018). It has been hypothesized that such diversity could be a functional adaptation for temporally and spatially variable and unpredictable soil environments (Muller et al., Reference Muller, Guédon, Passot, Lobet, Nacry, Pagès, Wissuwa and Draye2019).

Anyone who has ventured into the study of root architecture knows how incredibly plastic it can be. While in a research setting, this plasticity is painful to work with and requires many replications to ensure that the observed effect is indeed caused by specific treatment or genotype. In ‘the wild’, plasticity of root architecture allows the plant to tailor its response to soil water heterogeneity, enabling adaptive reallocation of growth and function (Bao et al., Reference Bao, Aggarwal, Robbins, Sturrock, Thompson, Tan, Tham, Duan, Rodriguez, Vernoux, Mooney, Bennett and Dinneny2014; Dietrich et al., Reference Dietrich, Pang, Kobayashi, Fozard, Boudolf, Bhosale, Antoni, Nguyen, Hiratsuka, Fujii, Miyazawa, Bae, Wells, Owen, Band, Dyson, Jensen, King, Tracy and Bennett2017; Orman-Ligeza et al., Reference Orman-Ligeza, Morris, Parizot, Lavigne, Babé, Ligeza, Klein, Sturrock, Xuan, Novák, Ljung, Fernandez, Rodriguez, Dodd, De Smet, Chaumont, Batoko, Périlleux, Lynch and Draye2018; Orosa-Puente et al., Reference Orosa-Puente, Leftley, von Wangenheim, Banda, Srivastava, Hill, Truskina, Bhosale, Morris, Srivastava, Kümpers, Goh, Fukaki, Vermeer, Vernoux, Dinneny, French, Bishopp, Sadanandom and Bennett2018; Scharwies et al., Reference Scharwies, Clarke, Zheng, Dinneny, Birkeland, Veltman, Sturrock, Banda, Torres-Martínez, Viana, Khare, Kieber, Pandey, Bennett, Schnable and Dinneny2024). In the field, drought can lead to reduced lateral root density near the soil surface and promote deeper root elongation in species like maize and chickpea (Kashiwagi et al., Reference Kashiwagi, Krishnamurthy, Upadhyaya, Krishna, Chandra, Vadez and Serraj2005; Zhan et al., Reference Zhan, Schneider and Lynch2015). On a smaller scale, water availability gradients guide the root tip towards available water (hydrotropism) (Dietrich et al., Reference Dietrich, Pang, Kobayashi, Fozard, Boudolf, Bhosale, Antoni, Nguyen, Hiratsuka, Fujii, Miyazawa, Bae, Wells, Owen, Band, Dyson, Jensen, King, Tracy and Bennett2017). Even outside of the plastic root tip, water gradients can modulate emergence and elongation of lateral roots, where hydropatterning promotes lateral root development in the areas with high moisture content (Bao et al., Reference Bao, Aggarwal, Robbins, Sturrock, Thompson, Tan, Tham, Duan, Rodriguez, Vernoux, Mooney, Bennett and Dinneny2014; Orosa-Puente et al., Reference Orosa-Puente, Leftley, von Wangenheim, Banda, Srivastava, Hill, Truskina, Bhosale, Morris, Srivastava, Kümpers, Goh, Fukaki, Vermeer, Vernoux, Dinneny, French, Bishopp, Sadanandom and Bennett2018; Scharwies et al., Reference Scharwies, Clarke, Zheng, Dinneny, Birkeland, Veltman, Sturrock, Banda, Torres-Martínez, Viana, Khare, Kieber, Pandey, Bennett, Schnable and Dinneny2024) while xerobranching represses lateral root formation when growing through a waterless gap (Mehra et al., Reference Mehra, Pandey, Melebari, Banda, Leftley, Couvreur, Rowe, Anfang, Gernier, Morris, Sturrock, Mooney, Swarup, Faulkner, Beeckman, Bhalerao, Shani, Jones, Dodd and Bennett2022; Orman-Ligeza et al., Reference Orman-Ligeza, Morris, Parizot, Lavigne, Babé, Ligeza, Klein, Sturrock, Xuan, Novák, Ljung, Fernandez, Rodriguez, Dodd, De Smet, Chaumont, Batoko, Périlleux, Lynch and Draye2018; Orosa-Puente et al., Reference Orosa-Puente, Leftley, von Wangenheim, Banda, Srivastava, Hill, Truskina, Bhosale, Morris, Srivastava, Kümpers, Goh, Fukaki, Vermeer, Vernoux, Dinneny, French, Bishopp, Sadanandom and Bennett2018). Plasticity is also evident in root growth arrest and reactivation cycles in response to fluctuating water potential over time. When water potential drops, newly developed lateral roots enter a temporary quiescence phase, which protects the growing tip in the long term (Geng et al., Reference Geng, Wu, Wee, Xie, Wei, Chan, Tham, Duan and Dinneny2013; Rowe et al., Reference Rowe, Topping, Liu and Lindsey2016). Mutants lacking this pause tend to cease their growth entirely at a later stage (Geng et al., Reference Geng, Wu, Wee, Xie, Wei, Chan, Tham, Duan and Dinneny2013), suggesting that early slowdown supports later recovery. While prolonged stress can cause irreversible damage, the line between reversible and irreversible changes in root systems is not well defined. Unlike above-ground traits, where water stress recovery and damage are better studied (Feller, Reference Feller2016; Gilgen & Feller, Reference Gilgen and Feller2014; Liu & Bennett, Reference Liu and Bennett2011), reversibility of root responses (the capacity to revert to pre-stress state) is less understood. Future work should focus on tracking how and when root growth can bounce back, to better link plasticity with resilience.

In the past, root ideotypes such as the ‘steep, cheap and deep’ model proposed by Lynch (Reference Lynch2013) have become a target for breeding programmes seeking drought-tolerant crops. However, these ideotypes are unlikely to perform well across various drought stress scenarios (Tardieu, Reference Tardieu2012). Determining the degree to which the plant can maintain root architecture robustness through integration of empirical root architecture studies with modelling approaches, such as Functional Structural Plant Models (OpenSimRoot (Postma et al., Reference Postma, Kuppe, Owen, Mellor, Griffiths, Bennett, Lynch and Watt2017), CRootBox (Schnepf et al., Reference Schnepf, Leitner, Landl, Lobet, Mai, Morandage, Sheng, Zörner, Vanderborght and Vereecken2018) or MECHA (Couvreur et al., Reference Couvreur, Faget, Lobet, Javaux, Chaumont and Draye2018), will provide improved insights into plant performance across various water deprivation scenarios and predict their resilience.

5. Beyond the reference: (Pan)genomic basis of robust water transport

The genomic architecture of plants underpins their capacity to construct and regulate efficient and robust water transport systems. Across evolutionary timescales, duplications, transposon activity and gene family expansions have contributed to the emergence of redundancy, heterogeneity and plasticity at the molecular level. These features are evident in the transcriptional regulation of water transport traits, the structural diversity of gene families related to hydraulics and the inter- and intra-species variation uncovered through pan-genomic studies.

Redundancy at the genetic level often arises through whole-genome and small-scale duplications, which have played a pivotal role in land plant evolution (Jiao & Paterson, Reference Jiao and Paterson2014; Kondrashov, Reference Kondrashov2012; Panchy et al., Reference Panchy, Lehti-Shiu and Shiu2016). Many key regulators of water transport, such as aquaporins, cell wall-modifying enzymes and suberin biosynthesis genes, are encoded by multigene families with partially overlapping functions (Cohen et al., Reference Cohen, Bogeat-Triboulot, Vialet-Chabrand, Merret, Courty, Moretti, Bizet, Guilliot and Hummel2013; Feng et al., Reference Feng, Wu, Gao, Kosma, Jenks and Lü2022; Sasidharan et al., Reference Sasidharan, Voesenek and Pierik2011). For example, the Arabidopsis genome contains over 30 aquaporin genes grouped into subfamilies (PIPs, TIPs, NIPs and SIPs), several of which are co-expressed and compensate for one another during abiotic stress (Maurel et al., Reference Maurel, Boursiac, Luu, Santoni, Shahzad and Verdoucq2015). This molecular redundancy allows for functional backup in case of mutation or environmental perturbation, increasing the robustness of hydraulic control. Gene duplication also facilitates sub-functionalization, where duplicate genes specialize in spatial or temporal expression – contributing further to robustness by distributing risk across tissue zones or environmental contexts. Uncovering functional gene redundancy in water transport requires approaches beyond single-gene knockouts, which often fail to reveal phenotypes due to compensation by paralogs. Tools like MULTIKNOCK or CRISPR-Combo, where guide RNAs are designed to target multiple close orthologs, enabling simultaneous inactivation of multiple related genes (Berman et al., Reference Berman, Su, Li, Landau, Chakraborty, Gerbi, Liu, Qin, Yuan, Wei, Yanai, Mayrose, Zhang and Shani2025; Hu et al., Reference Hu, Patra, Pisanty, Shafir, Belew, Binenbaum, Ben Yaakov, Shi, Charrier, Hyams, Zhang, Trabulsky, Caldararu, Weiss, Crocoll, Avni, Vernoux, Geisler, Nour-Eldin and Shani2023; Pan & Qi, Reference Pan and Qi2023), can help us identify the minimal redundancy needed for stress resilience. Cell-type-specific expression analysis and tissue-targeted gene editing can further clarify whether gene copies operate redundantly or have distinct roles in different spatial or temporal contexts. Meanwhile, the mobility of transcripts and proteins across cell layers adds another layer of buffering – allowing gene products to act beyond their site of origin. Combining multi-gene knockouts, spatial transcriptomics and tracking of mobile RNAs and proteins will allow us to better understand which redundancies are biologically necessary and how they contribute to the robustness of plant water transport networks.

Heterogeneity at the genomic level is reflected in allelic variation, which drives differential performance under water stress conditions. For instance, twofold natural variation in root water conductivity was observed among 15 Arabidopsis accessions (Sutka et al., Reference Sutka, Li, Boudet, Boursiac, Doumas and Maurel2011), where aquaporin-dependent and independent processes showed significant and independent variation. Root suberization was also observed to vary widely among Arabidopsis accessions (Feng et al., Reference Feng, Wu, Gao, Kosma, Jenks and Lü2022). Accessions collected from drier environments tend to have higher suberin content and different suberin composition. These patterns suggest that water transport components are not genetically fixed traits, but rather their allelic variation is subject to environmental adaptation.

Genetic heterogeneity extends beyond single-nucleotide variants to the structural architecture of the genome itself. Pan-genomic analyses – comparing the full gene repertoire across multiple accessions or cultivars – have revealed that up to 20% of genes in species like maize, rice and soybean may be dispensable or variably present, often including genes related to environmental adaptation (Golicz et al., Reference Golicz, Bayer, Barker, Edger, Kim, Martinez, Chan, Severn-Ellis, McCombie, Parkin, Paterson, Pires, Sharpe, Tang, Teakle, Town, Batley and Edwards2016). Here, we use accessory and dispensable genomes interchangeably to refer to the genes present in some but not all individuals of the species, in contrast to the core genome, which is shared across all accessions. Some research teams further distinguish accessory genes as conditionally adaptive and dispensable genes as non-essential; however, detailed functional validation of this functionality is yet to be experimentally validated through gene knockouts in multiple backgrounds. At this moment, it is assumed that both accessory and dispensable genome elements contribute to genomic heterogeneity and reflect the same underlying evolutionary flexibility of the plant genome. Interestingly, accessory genomes are typically enriched in genes associated with stress perception, signalling and secondary metabolism, many of which modulate water transport and root development in response to water deprivation (Gao et al., Reference Gao, Gonda, Sun, Ma, Bao, Tieman, Burzynski-Chang, Fish, Stromberg, Sacks, Thannhauser, Foolad, Diez, Blanca, Canizares, Xu, van der Knaap, Huang, Klee and Fei2019; Liang et al., Reference Liang, Muñoz-Amatriaín, Shu, Lo, Wu, Carlson, Davidson, Goodstein, Phillips, Janis, Lee, Liang, Morrell, Farmer, Xu, Close and Lonardi2023; Petereit et al., Reference Petereit, Bayer, Thomas, Tay Fernandez, Amas, Zhang, Batley and Edwards2022; Schreiber et al., Reference Schreiber, Jayakodi, Stein and Mascher2024; Wang et al., Reference Wang, Qian, Zhao, Chen and Song2023). These variably present genes, therefore, form an adaptive layer of genetic redundancy and functional diversity that can be mobilized under fluctuating environments.

Structural variants, such as copy number variants and the presence/absence of root development regulators, may mediate robustness in water-limited environments, especially in crops domesticated across a wide geographic range (Hirsch et al., Reference Hirsch, Foerster, Johnson, Sekhon, Muttoni, Vaillancourt, Peñagaricano, Lindquist, Pedraza, Barry, de Leon, Kaeppler and Buell2014). These observations point to a wide range of water transport strategies embedded within a species. Rather than being liabilities, these genomic differences represent a reservoir of adaptive potential that can be harnessed for both resilience and productivity. Modern breeding programmes already capitalize on this principle. The development of F1 hybrids often relies on combining complementary accessory genomes from elite parental lines, allowing hybrid vigour to emerge from underlying genetic heterogeneity. Leveraging pan-genomic analyses is currently utilized in designing genetic combinations with minimal deleterious genomic variants (Cheng et al., Reference Cheng, Wang, Bao, Zhou, Guarracino, Yang, Wang, Zhang, Tang, Zhang, Wu, Zhou, Zheng, Hu, Lian, Ma, Lassois, Zhang, Lucas and Huang2025; Sun et al., Reference Sun, Zhang, Liao, Guo, Zhou, Zhao, Wu, Zhao, Gong, Wang, Li, Yu, Ren, Tian, Li, Zhang, Hammar, McGregor, Jarret and Fei2025), but combining complementary accessory genomes can further maximize hybrid vigour based on genomic heterogeneity. However, the use of genomic heterogeneity for agricultural purposes is not new. For centuries, indigenous and traditional farming systems have relied on managing intraspecific diversity in small-scale, low-input agroecosystems (Altieri & Nicholls, Reference Altieri and Nicholls2017; Barnaud et al., Reference Barnaud, Deu, Garine, Chantereau, Bolteu, Koïda, McKey and Joly2009; Mutegi et al., Reference Mutegi, Sagnard, Labuschagne, Herselman, Semagn, Deu, de Villiers, Kanyenji, Mwongera, Traore and Kiambi2012; Wang et al., Reference Wang, Wang, Sun, Caiji, Yang, Cui, Cao, Ma, Han, Xue and Han2016). These systems – spanning polycultures, landraces and mixed seed banks – have been shown to stabilize yields, reduce environmental risk and sustain food security through environmental unpredictability (Altieri, Reference Altieri1999; Andreotti et al., Reference Andreotti, Neher, Speelman and Bazile2023; Beyene et al., Reference Beyene, Gibbon and Haile2006; Mulvany, Reference Mulvany2021; Vandermeer & Perfecto, Reference Vandermeer and Perfecto2007). Together, both modern and traditional strategies highlight the functional value of genetic diversity in sustaining water transport under stress. Natural diversity panels, landrace collections and pan-genomic resources offer essential tools to identify and conserve this variation. In the context of increasing climate variability, breeding for resilience will depend not only on identifying the ‘best’ water transport alleles but also on embracing the full spectrum of genetic solutions that plants have evolved across landscapes and cultures.

Beyond structural variation, plants exhibit transcriptional plasticity – the ability to reprogramme gene expression in response to changing water availability. This includes rapid upregulation of hydraulic genes like aquaporins, suberin biosynthesis genes (e.g., GPAT5 and CYP86A1) and stress-responsive transcription factors (e.g., DREB, NAC and MYB) (Barberon et al., Reference Barberon, Vermeer, De Bellis, Wang, Naseer, Andersen, Humbel, Nawrath, Takano, Salt and Geldner2016; Dinneny, Reference Dinneny2019). Plastic expression responses allow plants to adjust their water transport capacity at a moment’s notice. Epigenetic mechanisms, including DNA methylation, histone modifications and non-coding RNAs, also contribute to gene expression plasticity. Stress-induced epigenetic memory may prime future responses and enhance robustness over time or across generations (Crisp et al., Reference Crisp, Ganguly, Eichten, Borevitz and Pogson2016). It is important to keep in mind that at the transcriptional level, heterogeneity and plasticity often co-occur, as environmentally responsive expression programmes can generate population-wide variation even under uniform conditions.

Understanding the genetic underpinnings of robustness in water transport systems requires moving towards genomic diversity-aware models. Pan-genomes and expression atlases constructed across various growth conditions (Kajala et al., Reference Kajala, Gouran, Shaar-Moshe, Mason, Rodriguez-Medina, Kawa, Pauluzzi, Reynoso, Canto-Pastor, Manzano, Lau, Artur, West, Gray, Borowsky, Moore, Yao, Morimoto, Bajic and Brady2021) provide critical tools for identifying robustness-associated alleles and transcriptional responses across genotypes and environments. Combining genomic data with phenotyping and environmental modelling will be key for identifying trait-stabilizing loci and deploying them in breeding programmes focused on stress resilience.

Distinguishing the core and accessory genomes provides a useful framework for understanding how robustness operates at the genetic level. The core genome preserves essential hydraulic functions that sustain baseline performance, while the accessory genome provides a flexible repertoire of stress-adaptive genes that expand a species’ capacity to respond to environmental variability. This dual structure mirrors the broader principles of robustness, where redundancy safeguards function, heterogeneity diversifies responses and plasticity enables dynamic reconfiguration across scales.

While architecture and anatomy define the spatial and physical substrate for water transport, their regulation is ultimately rooted in the genome. The extent of anatomical and architectural plasticity that a plant can express under stress depends on its genetic circuitry and the regulatory loops controlling gene expression. Integrating environmental cues, hormonal signalling pathways, epigenetic modifications and allelic variation in structural and regulatory genes into these regulatory networks will help elucidate the feedback loops linking genomic, anatomical and architectural scales. In this integrated view, robustness emerges not from any single level but from their interaction: Genetic diversity shapes anatomical potential, which in turn constrains or enables architectural responses.

6. Measuring robustness: Quantifying the invisible buffer

While robustness is a central property of biological systems, it is not a single measurable trait but an emergent property resulting from dynamic interactions across components. In plant water transport systems, robustness reflects the capacity to maintain hydraulic function in the face of environmental, structural or genetic perturbations. Capturing this capacity requires a shift from traditional trait measurement towards integrative, multi-scalar frameworks that assess not only performance but also resilience, adaptability and failure modes. Here we propose a roadmap for quantifying the three core contributors to robustness – redundancy, heterogeneity and plasticity – across anatomical, physiological and phenotypic dimensions.

Redundancy can be measured by assessing the degree of trait overlap across tissues, organs or genotypes that contribute to similar functions. For instance:

• Xylem redundancy can be estimated using the vessel grouping index, quantifying the number of vessels per group versus isolated vessels in cross-sections (Lens et al., Reference Lens, Sperry, Christman, Choat, Rabaey and Jansen2011). High grouping values suggest greater hydraulic backup in case of embolism.
• Root redundancy may be assessed by modelling water flow through Root System Architecture using functional-structural models like OpenSimRoot (Postma et al., Reference Postma, Kuppe, Owen, Mellor, Griffiths, Bennett, Lynch and Watt2017), CRootBox (Schnepf et al., Reference Schnepf, Leitner, Landl, Lobet, Mai, Morandage, Sheng, Zörner, Vanderborght and Vereecken2018) or MECHA (Couvreur et al., Reference Couvreur, Faget, Lobet, Javaux, Chaumont and Draye2018). By taking explicitly into account the architectural and anatomical complexity of complete root structures, these models can simulate water movement in the complete soil-plant domain for contrasting combinations of traits and predict alternative water uptake pathways under perturbation.
• Genomic redundancy is measured via gene family expansions and functional overlap – for example, through transcript co-expression analysis under varying environmental conditions.
• Functionally, robustness based on the redundancy can be estimated by comparing root performance decline after perturbation (e.g., vessel blockage or root pruning), providing direct evidence of buffered function.

Heterogeneity refers to the diversity of trait values within a given plant or population. This can be measured through:

• Anatomical heterogeneity: Use of image analysis (e.g., X-ray Computer Tomography and microscopy) to quantify variation in xylem diameter, pit membrane structure or lignin distribution within organs or across genotypes. The main bottleneck for such quantification lies in the lack of throughput for anatomical quantification, except for a few specialized methods (such as the Laser Ablation Tomography (Strock et al., Reference Strock, Schneider, Galindo-Castañeda, Hall, Van Gansbeke, Mather, Roth, Chilvers, Guo, Brown and Lynch2019). To fully access and quantify anatomical heterogeneity, there is a need for more accessible methods that could be used at scale.
• Root trait heterogeneity: Calculating heterogeneity across root types or zones for traits like branching density, angle or suberization intensity (Rellán-Álvarez et al., Reference Rellán-Álvarez, Lobet, Lindner, Pradier, Sebastian, Yee, Geng, Trontin, LaRue, Schrager-Lavelle, Haney, Nieu, Maloof, Vogel and Dinneny2015) is necessary to assess the patterns and allow for the identification of emergent properties. As discussed in detail by Muller et al. (Reference Muller, Guédon, Passot, Lobet, Nacry, Pagès, Wissuwa and Draye2019), lateral roots of the same order can have strikingly different functions (absorptive vs. transportive). To fully embrace root trait heterogeneity means moving away from comparing trait averages to looking at their spread within genotypes. Such methods have long been used in the ecology field, such as the Shannon indices (Chegdali et al., Reference Chegdali, Ouabbou, Sahri and Essamadi2024; Sun et al., Reference Sun, Yuan, Liu, Lan, Tsai and Zou2019) or the coefficients of variation. As for the anatomical traits, there is also a need to move away from global metrics, such a total root length or total biomass, that, despite their interest, can hide differences in individual developmental processes and completely restrict our ability to detect heterogeneous patterns.
• Gene expression heterogeneity: Single-cell/-nuclei Ribonucleic Acid sequencing or spatial transcriptomics across different conditions and time points can help to map divergent responses in root cells during stress. Time-course transcriptomics can be used to explore gene expression plasticity, as it captures dynamic temporal reprogramming of the transcriptome in response to stress. However, when examined across individuals or cell types, such temporal changes also contribute to observed heterogeneity – illustrating how plasticity and heterogeneity can overlap depending on the scale and context of measurement. As with all experiments, providing exhaustive metadata accompanying each RNA-seq dataset will allow for more exhaustive cross-comparisons and improved insights.

Incorporating trait correlation matrices or multivariate Principal Component Analysis can further help identify uncoupled versus redundant components within the studied system, where uncorrelated traits contribute to robustness through diversification rather than overlap. One example of such traits would be the number of nodal roots (in cereals) and the number of meta-xylem vessels. Both traits effect the capacity of the root system to uptake water, but are controlled by completely different developmental processes.

Plasticity is the ability of traits to change in response to environmental stimuli, and its quantification is key to understanding system responsiveness:

• Reaction norms plot trait values (e.g., root depth, vessel density and transpiration rate) across environmental gradients, and can be fitted with linear or nonlinear models to extract slope (sensitivity) and range (flexibility) (Nicotra et al., Reference Nicotra, Atkin, Bonser, Davidson, Finnegan, Mathesius, Poot, Purugganan, Richards, Valladares and van Kleunen2010).
• Time-course phenotyping (e.g., gravimetric platforms, thermal cameras and automated imaging) captures response dynamics to stress onset and recovery, providing metrics like lag time, peak shift and return-to-baseline rate (Tardieu et al., Reference Tardieu, Cabrera-Bosquet, Pridmore and Bennett2017). Similarly, time-course transcriptomic approaches provide complementary insight into molecular plasticity, revealing transient and reversible expression changes that underlie physiological adjustments to fluctuating environments.
• Plasticity indices, such as the Relative Distance Plasticity Index or Plasticity Stability Index, quantify the extent and consistency of trait changes across multiple conditions (Valladares et al., Reference Valladares, Sanchez-gomez and Zavala2006).
• Finally, better and finer characterization of environmental variables is needed to be able to characterize the direct environment of the different plant organs and their reactions to it.

Critically, plasticity must be distinguished from mere variability – it is predictable, responsive and often adaptive. Both controlled-environment experiments and field heterogeneity trials provide necessary insights, although integration across them remains challenging.

Applying robustness metrics for plant water transport systems in real-world, large-scale field settings presents several practical challenges. Environmental heterogeneity, such as variable microclimates, soil conditions and biotic interactions, introduces noise and unpredictability, making it difficult to generalize metrics developed under controlled conditions. Data collection remains labour-intensive, destructive or spatially/temporally limited, complicating efforts to capture whole-plant or ecosystem-level responses (and this is especially true when dealing with belowground data. Logistical constraints, including frequent recalibration, human oversight and integration with existing infrastructure, further hinder operational feasibility. Additionally, cost and expertise gaps, such as the need for advanced technical training or financial resources, can disproportionately affect smaller organizations or developing regions. These challenges highlight the need for adaptive, simplified metrics, automated tools and collaborative frameworks to bridge the gap between theoretical robustness and practical, scalable application in agriculture.

7. Conclusions and future perspectives

As plants contend with increasingly erratic climates, the ability to maintain water transport under stress is critical – not just for survival, but for sustained productivity. Robustness is not a fixed trait but an emergent systems property, shaped by both evolutionary legacy and developmental responsiveness. Importantly, robustness does not necessarily oppose efficiency – many of the most resilient systems are efficient because they are fault-tolerant, adaptable and context-sensitive.

Within this framework, heterogeneity and plasticity operate along a continuum rather than as discrete phenomena. Heterogeneity provides the structural and genetic variation that buffers plants against perturbation, while plasticity enables that variation to be dynamically reconfigured in response to environmental change. Recognizing their overlap highlights that resilience emerges not simply from diversity itself, but from the capacity of biological systems to modulate and reorganize that diversity when challenged.

Understanding how plants negotiate this trade-off requires dissecting water transport not just as a physiological process but as a networked system embedded in time, space and environment. Looking forward, we envision a framework where plant hydraulic robustness is not just described but quantitatively predicted – integrating phenotypic plasticity, trait covariance and genetic diversity into models of plant performance. Such a framework could combine mechanistic and data-driven approaches, where functional–structural plant models (e.g., OpenSimRoot, MECHA or CRootBox (Postma et al. Reference Postma, Kuppe, Owen, Mellor, Griffiths, Bennett, Lynch and Watt2017; Schnepf et al. Reference Schnepf, Leitner, Landl, Lobet, Mai, Morandage, Sheng, Zörner, Vanderborght and Vereecken2018; Couvreur et al. Reference Couvreur, Faget, Lobet, Javaux, Chaumont and Draye2018) are parameterized with experimentally derived traits from high-resolution phenotyping and time-course transcriptomics. Linking these models to gene regulatory and hormonal networks would enable the prediction of how genomic variation shapes architectural and anatomical adjustments under fluctuating conditions. Incorporating trait covariance and environmental data from population studies would further allow the identification of trait combinations that stabilize water transport across stress scenarios, guiding the design of genotypes with predictable resilience. Ultimately, this integration of modelling, empirical data and biological insight would connect molecular diversity to emergent hydraulic behaviour – transforming our understanding of robustness from a conceptual framework into a predictive biological tool. The fusion of high-resolution imaging, multi-omics, AI-powered and knowledge-based modelling holds great promise for unlocking the principles of resilience embedded in plant water transport networks.

As agriculture enters a period of urgent adaptation, recognizing that robustness is as valuable as raw productivity will be essential. Through interdisciplinary approaches, we can move from observing robustness to designing for it – guiding the development of crops that thrive not just in the average field, but in the face of tomorrow’s uncertainty.

Open peer review

To view the open peer review materials for this article, please visit http://doi.org/10.1017/qpb.2025.10035.

Competing interest

The authors declare none.

Data availability statement

This review manuscript does not produce any data or code that would need to be made available.

Author contributions

MMJ, GL and AC discussed the concepts constituting the body of the review. MMJ drafted the initial version of the review, which was subsequently reviewed by GL and AC. All authors have contributed to the revision of the manuscript.

Funding statement

M.M.J. and A.C. are co-funded by the National Science Foundation (NSF IOS and Mathematical Biology #2244735). G.L. is co-funded by the European Union (ERC grant 101125638).

Footnotes

Associate Editor: Dr. Priya Ramakrishna

References

Affortit, P., Faye, A., Jones, D. H., Benson, E., Sine, B., Burridge, J., Ndoye, M. S., Barry, L., Moukouanga, D., Barnard, S., Bhosale, R., Pridmore, T., Gantet, P., Vadez, V., Cubry, P., Kane, N., Bennett, M., Atkinson, J. A., Laplaze, L., … Grondin, A. (2024). Root metaxylem area influences drought tolerance and transpiration in pearl millet in a soil texture dependent manner. Physiology. https://doi.org/10.1101/2024.11.09.622826v1.Google Scholar

Alseekh, S., Klemmer, A., Yan, J., Guo, T., & Fernie, A. R. (2025). Embracing plant plasticity or robustness as a means of ensuring food security. Nature Communications, 16(1), 461. https://doi.org/10.1038/s41467-025-55872-4.Google Scholar

Altieri, M. A. (1999). The ecological role of biodiversity in agroecosystems. Agriculture, Ecosystems & Environment, 74(1-3), 19–31. https://doi.org/10.1016/s0167-8809(99)00028-6.Google Scholar

Altieri, M. A., & Nicholls, C. I. (2017). The adaptation and mitigation potential of traditional agriculture in a changing climate. Climatic Change, 140(1), 33–45. https://doi.org/10.1007/s10584-013-0909-y.Google Scholar

Andreotti, F., Neher, C. M., Speelman, E. N., & Bazile, D. (2023). Exploring farmers’ perspectives on agrobiodiversity management: Future options for quinoa smallholder organizations in the Peruvian high Andes. Agronomy for Sustainable Development, 43(3). https://doi.org/10.1007/s13593-023-00891-y.Google Scholar

Baca Cabrera, J. C., Vanderborght, J., Couvreur, V., Behrend, D., Gaiser, T., Nguyen, T. H., & Lobet, G. (2024). Root hydraulic properties: An exploration of their variability across scales. Plant Direct, 8(4), e582. https://doi.org/10.1002/pld3.582.Google Scholar

Bagniewska-Zadworna, A., Byczyk, J., Eissenstat, D. M., Oleksyn, J., & Zadworny, M. (2012). Avoiding transport bottlenecks in an expanding root system: Xylem vessel development in fibrous and pioneer roots under field conditions. American Journal of Botany, 99(9), 1417–1426. https://doi.org/10.3732/ajb.1100552.Google Scholar

Bao, Y., Aggarwal, P., Robbins, N. E., 2nd, Sturrock, C. J., Thompson, M. C., Tan, H. Q., Tham, C., Duan, L., Rodriguez, P. L., Vernoux, T., Mooney, S. J., Bennett, M. J., & Dinneny, J. R. (2014). Plant roots use a patterning mechanism to position lateral root branches toward available water. Proceedings of the National Academy of Sciences of the United States of America, 111(25), 9319–9324. https://doi.org/10.1073/pnas.1400966111 Google Scholar

Barberon, M., Vermeer, J. E. M., De Bellis, D., Wang, P., Naseer, S., Andersen, T. G., Humbel, B. M., Nawrath, C., Takano, J., Salt, D. E., & Geldner, N. (2016). Adaptation of root function by nutrient-induced plasticity of endodermal differentiation. Cell, 164(3), 447–459. https://doi.org/10.1016/j.cell.2015.12.021.Google Scholar

Barnaud, A., Deu, M., Garine, E., Chantereau, J., Bolteu, J., Koïda, E. O., McKey, D., & Joly, H. I. (2009). A weed-crop complex in sorghum: The dynamics of genetic diversity in a traditional farming system. American Journal of Botany, 96(10), 1869–1879. https://doi.org/10.3732/ajb.0800284.Google Scholar

Berlekamp, E. R. (1980). The technology of error-correcting codes. Proceedings of the IEEE . Institute of Electrical and Electronics Engineers, 68(5), 564–593. https://doi.org/10.1109/proc.1980.11696.Google Scholar

Berman, A., Su, N., Li, Z., Landau, U., Chakraborty, J., Gerbi, N., Liu, J., Qin, Y., Yuan, B., Wei, W., Yanai, O., Mayrose, I., Zhang, Y., & Shani, E. (2025). Construction of multi-targeted CRISPR libraries in tomato to overcome functional redundancy at genome-scale level. Nature Communications, 16(1), 4111. https://doi.org/10.1038/s41467-025-59280-6.Google Scholar

Beyene, A., Gibbon, D., & Haile, M. (2006). Heterogeneity in land resources and diversity in farming practices in Tigray, Ethiopia. Agricultural Systems, 88(1), 61–74. https://doi.org/10.1016/j.agsy.2005.06.004.Google Scholar

Bouda, M., Huggett, B. A., Prats, K. A., Wason, J. W., Wilson, J. P., & Brodersen, C. R. (2022). Hydraulic failure as a primary driver of xylem network evolution in early vascular plants. Science (New York, N.Y.), 378(6620), 642–646. https://doi.org/10.1126/science.add2910 Google Scholar

Boughalleb, F., Abdellaoui, R., Ben-Brahim, N., & Neffati, M. (2014). Anatomical adaptations of Astragalus gombiformis Pomel. under drought stress. Open Life Sciences, 9(12), 1215–1225. https://doi.org/10.2478/s11535-014-0353-7.Google Scholar

Boughalleb, F., Abdellaoui, R., Hadded, Z., & Neffati, M. (2015). Anatomical adaptations of the desert species Stipa lagascae against drought stress. Biologia, 70(8). https://doi.org/10.1515/biolog-2015-0125.Google Scholar

Briggs, L. J., & Shantz, H. L. (1913). The Water Requirements of Plants. I. Investigation in the Great Plains in 1910 and 1911. US. Dep., Agr. Bur. Plant Indr. Bull. 284, 49 p.Google Scholar

Burton, A. L., Brown, K. M., & Lynch, J. P. (2013). Phenotypic diversity of root anatomical and architectural traits in Zea species. Crop Science, 53(3), 1042–1055. https://doi.org/10.2135/cropsci2012.07.0440.Google Scholar

Cantó-Pastor, A., Kajala, K., Shaar-Moshe, L., Manzano, C., Timilsena, P., De Bellis, D., Gray, S., Holbein, J., Yang, H., Mohammad, S., Nirmal, N., Suresh, K., Ursache, R., Mason, G. A., Gouran, M., West, D. A., Borowsky, A. T., Shackel, K. A., Sinha, N., … Brady, S. M. (2024). A suberized exodermis is required for tomato drought tolerance. Nature Plants, 10(1), 118–130. https://doi.org/10.1038/s41477-023-01567-x.Google Scholar

Carlquist, S. (2009). Non-random vessel distribution in woods: Patterns, modes, diversity, correlations. Aliso, 27(1), 39–58. https://doi.org/10.5642/aliso.20092701.04.Google Scholar

Chegdali, Y., Ouabbou, H., Sahri, A., & Essamadi, A. (2024). Phenotypic diversity in durum wheat landraces and cultivars from Morocco and North America. Plant Omics, 16(01), 19–27. https://doi.org/10.21475/poj.16.01.24.pne04.Google Scholar

Cheng, L., Wang, N., Bao, Z., Zhou, Q., Guarracino, A., Yang, Y., Wang, P., Zhang, Z., Tang, D., Zhang, P., Wu, Y., Zhou, Y., Zheng, Y., Hu, Y., Lian, Q., Ma, Z., Lassois, L., Zhang, C., Lucas, W. J., … Huang, S. (2025). Leveraging a phased pangenome for haplotype design of hybrid potato. Nature, 640(8058), 408–417. https://doi.org/10.1038/s41586-024-08476-9.Google Scholar

Choat, B., Sack, L., & Holbrook, N. M. (2007). Diversity of hydraulic traits in nine Cordia species growing in tropical forests with contrasting precipitation. The New Phytologist, 175(4), 686–698. https://doi.org/10.1111/j.1469-8137.2007.02137.x.Google Scholar

Cohen, D., Bogeat-Triboulot, M.-B., Vialet-Chabrand, S., Merret, R., Courty, P.-E., Moretti, S., Bizet, F., Guilliot, A., & Hummel, I. (2013). Developmental and environmental regulation of aquaporin gene expression across Populus species: Divergence or redundancy? PLoS One, 8(2), e55506. https://doi.org/10.1371/journal.pone.0055506.Google Scholar

Couvreur, V., Faget, M., Lobet, G., Javaux, M., Chaumont, F., & Draye, X. (2018). Going with the flow: Multiscale insights into the composite nature of water transport in roots. Plant Physiology, 178(4), 1689–1703. https://doi.org/10.1104/pp.18.01006.Google Scholar

Crisp, P. A., Ganguly, D., Eichten, S. R., Borevitz, J. O., & Pogson, B. J. (2016). Reconsidering plant memory: Intersections between stress recovery, RNA turnover, and epigenetics. Science Advances, 2(2), e1501340. https://doi.org/10.1126/sciadv.1501340.Google Scholar

De Rybel, B., Mähönen, A. P., Helariutta, Y., & Weijers, D. (2016). Plant vascular development: From early specification to differentiation. Nature Reviews. Molecular Cell Biology, 17(1), 30–40. https://doi.org/10.1038/nrm.2015.6.Google Scholar

Dietrich, D., Pang, L., Kobayashi, A., Fozard, J. A., Boudolf, V., Bhosale, R., Antoni, R., Nguyen, T., Hiratsuka, S., Fujii, N., Miyazawa, Y., Bae, T.-W., Wells, D. M., Owen, M. R., Band, L. R., Dyson, R. J., Jensen, O. E., King, J. R., Tracy, S. R., … Bennett, M. J. (2017). Root hydrotropism is controlled via a cortex-specific growth mechanism. Nature Plants, 3, 17057. https://doi.org/10.1038/nplants.2017.57.Google Scholar

Dinneny, J. R. (2019). Developmental responses to water and salinity in root systems. Annual Review of Cell and Developmental Biology, 35, 239–257. https://doi.org/10.1146/annurev-cellbio-100617-062949.Google Scholar

Doyle, J. C., Alderson, D. L., Li, L., Low, S., Roughan, M., Shalunov, S., Tanaka, R., & Willinger, W. (2005). The “robust yet fragile” nature of the internet. Proceedings of the National Academy of Sciences of the United States of America, 102(41), 14497–14502. https://doi.org/10.1073/pnas.0501426102.Google Scholar

Feller, U. (2016). Drought stress and carbon assimilation in a warming climate: Reversible and irreversible impacts. Journal of Plant Physiology, 203, 84–94. https://doi.org/10.1016/j.jplph.2016.04.002.Google Scholar

Feng, T., Wu, P., Gao, H., Kosma, D. K., Jenks, M. A., & Lü, S. (2022). Natural variation in root suberization is associated with local environment in Arabidopsis thaliana. The New Phytologist, 236(2), 385–398. https://doi.org/10.1111/nph.18341.Google Scholar

Gao, L., Gonda, I., Sun, H., Ma, Q., Bao, K., Tieman, D. M., Burzynski-Chang, E. A., Fish, T. L., Stromberg, K. A., Sacks, G. L., Thannhauser, T. W., Foolad, M. R., Diez, M. J., Blanca, J., Canizares, J., Xu, Y., van der Knaap, E., Huang, S., Klee, H. J., … Fei, Z. (2019). The tomato pan-genome uncovers new genes and a rare allele regulating fruit flavor. Nature Genetics, 51(6), 1044–1051. https://doi.org/10.1038/s41588-019-0410-2.Google Scholar

Geng, Y., Wu, R., Wee, C. W., Xie, F., Wei, X., Chan, P. M. Y., Tham, C., Duan, L., & Dinneny, J. R. (2013). A spatio-temporal understanding of growth regulation during the salt stress response in Arabidopsis. The Plant Cell, 25(6), 2132–2154. https://doi.org/10.1105/tpc.113.112896.Google Scholar

Gilgen, A. K., & Feller, U. (2014). Effects of drought and subsequent rewatering on Rumex obtusifolius leaves of different ages: Reversible and irreversible damages. Journal of Plant Interactions, 9(1), 75–81. https://doi.org/10.1080/17429145.2013.765043.Google Scholar

Golicz, A. A., Bayer, P. E., Barker, G. C., Edger, P. P., Kim, H., Martinez, P. A., Chan, C. K. K., Severn-Ellis, A., McCombie, W. R., Parkin, I. A. P., Paterson, A. H., Pires, J. C., Sharpe, A. G., Tang, H., Teakle, G. R., Town, C. D., Batley, J., & Edwards, D. (2016). The pangenome of an agronomically important crop plant Brassica oleracea. Nature Communications, 7(1), 13390. https://doi.org/10.1038/ncomms13390.Google Scholar

Hacke, U. G., Sperry, J. S., Wheeler, J. K., & Castro, L. (2006). Scaling of angiosperm xylem structure with safety and efficiency. Tree Physiology, 26(6), 689–701. https://doi.org/10.1093/treephys/26.6.689.Google Scholar

Heymans, A., Couvreur, V., LaRue, T., Paez-Garcia, A., & Lobet, G. (2020). GRANAR, a computational tool to better understand the functional importance of monocotyledon root anatomy. Plant Physiology, 182(2), 707–720. https://doi.org/10.1104/pp.19.00617.Google Scholar

Heymans, A., Couvreur, V., & Lobet, G. (2021). Combining cross-section images and modeling tools to create high-resolution root system hydraulic atlases in Zea mays. Plant Direct, 5(7), e334. https://doi.org/10.1002/pld3.334.Google Scholar

Hirsch, C. N., Foerster, J. M., Johnson, J. M., Sekhon, R. S., Muttoni, G., Vaillancourt, B., Peñagaricano, F., Lindquist, E., Pedraza, M. A., Barry, K., de Leon, N., Kaeppler, S. M., & Buell, C. R. (2014). Insights into the maize pan-genome and pan-transcriptome. The Plant Cell, 26(1), 121–135. https://doi.org/10.1105/tpc.113.119982.Google Scholar

Hochholdinger, F., Park, W. J., Sauer, M., & Woll, K. (2004). From weeds to crops: Genetic analysis of root development in cereals. Trends in Plant Science, 9(1), 42–48. https://doi.org/10.1016/j.tplants.2003.11.003.Google Scholar

Hu, Y., Patra, P., Pisanty, O., Shafir, A., Belew, Z. M., Binenbaum, J., Ben Yaakov, S., Shi, B., Charrier, L., Hyams, G., Zhang, Y., Trabulsky, M., Caldararu, O., Weiss, D., Crocoll, C., Avni, A., Vernoux, T., Geisler, M., Nour-Eldin, H. H., … Shani, E. (2023). Multi-Knock-a multi-targeted genome-scale CRISPR toolbox to overcome functional redundancy in plants. Nature Plants, 9(4), 572–587. https://doi.org/10.1038/s41477-023-01374-4.Google Scholar

Jang, G., & Choi, Y. D. (2018). Drought stress promotes xylem differentiation by modulating the interaction between cytokinin and jasmonic acid. Plant Signaling & Behavior, 13(3), e1451707. https://doi.org/10.1080/15592324.2018.1451707.Google Scholar

Jiao, Y., & Paterson, A. H. (2014). Polyploidy-associated genome modifications during land plant evolution. Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences, 369(1648), 20130355. https://doi.org/10.1098/rstb.2013.0355.Google Scholar

Kajala, K., Gouran, M., Shaar-Moshe, L., Mason, G. A., Rodriguez-Medina, J., Kawa, D., Pauluzzi, G., Reynoso, M., Canto-Pastor, A., Manzano, C., Lau, V., Artur, M. A. S., West, D. A., Gray, S. B., Borowsky, A. T., Moore, B. P., Yao, A. I., Morimoto, K. W., Bajic, M., … Brady, S. M. (2021). Innovation, conservation, and repurposing of gene function in root cell type development. Cell, 184(19), 5070. https://doi.org/10.1016/j.cell.2021.08.032 Google Scholar

Kashiwagi, J., Krishnamurthy, L., Upadhyaya, H. D., Krishna, H., Chandra, S., Vadez, V., & Serraj, R. (2005). Genetic variability of drought-avoidance root traits in the mini-core germplasm collection of chickpea (Cicer arietinum L.). Euphytica; Netherlands Journal of Plant Breeding, 146(3), 213–222. https://doi.org/10.1007/s10681-005-9007-1.Google Scholar

Kitano, H. (2004). Biological robustness. Nature Reviews. Genetics, 5(11), 826–837. https://doi.org/10.1038/nrg1471.Google Scholar

Klein, S. P., Schneider, H. M., Perkins, A. C., Brown, K. M., & Lynch, J. P. (2020). Multiple integrated root phenotypes are associated with improved drought tolerance. Plant Physiology, 183(3), 1011–1025. https://doi.org/10.1104/pp.20.00211.Google Scholar

Kondrashov, F. A. (2012). Gene duplication as a mechanism of genomic adaptation to a changing environment. Proceedings. Biological sciences, 279(1749), 5048–5057. https://doi.org/10.1098/rspb.2012.1108.Google Scholar

Lachowiec, J., Queitsch, C., & Kliebenstein, D. J. (2016). Molecular mechanisms governing differential robustness of development and environmental responses in plants. Annals of Botany, 117(5), 795–809. https://doi.org/10.1093/aob/mcv151.Google Scholar

Lens, F., Sperry, J. S., Christman, M. A., Choat, B., Rabaey, D., & Jansen, S. (2011). Testing hypotheses that link wood anatomy to cavitation resistance and hydraulic conductivity in the genus acer. The New Phytologist, 190(3), 709–723. https://doi.org/10.1111/j.1469-8137.2010.03518.x.Google Scholar

Liang, Q., Muñoz-Amatriaín, M., Shu, S., Lo, S., Wu, X., Carlson, J. W., Davidson, P., Goodstein, D. M., Phillips, J., Janis, N. M., Lee, E. J., Liang, C., Morrell, P. L., Farmer, A. D., Xu, P., Close, T. J., & Lonardi, S. (2023). A view of the pan-genome of domesticated Cowpea (Vigna unguiculata [L.] Walp.). The Plant Genome, e20319. https://doi.org/10.1002/tpg2.20319 Google Scholar

Liu, J., Zhou, M., Wang, S., & Liu, P. (2017). A comparative study of network robustness measures. Frontiers of Computer Science, 11(4), 568–584. https://doi.org/10.1007/s11704-016-6108-z.Google Scholar

Liu, J.-X., & Bennett, J. (2011). Reversible and irreversible drought-induced changes in the anther proteome of rice (Oryza sativa L.) genotypes IR64 and Moroberekan. Molecular Plant, 4(1), 59–69. https://doi.org/10.1093/mp/ssq039.Google Scholar

Lynch, J. P. (2011). Root phenes for enhanced soil exploration and phosphorus acquisition: Tools for future crops. Plant Physiology, 156(3), 1041–1049. https://doi.org/10.1104/pp.111.175414.Google Scholar

Lynch, J. P. (2013). Steep, cheap and deep: An ideotype to optimize water and N acquisition by maize root systems. Annals of Botany, 112(2), 347–357. https://doi.org/10.1093/aob/mcs293.Google Scholar

Martínez-Vilalta, J., Poyatos, R., Aguadé, D., Retana, J., & Mencuccini, M. (2014). A new look at water transport regulation in plants. The New Phytologist, 204(1), 105–115. https://doi.org/10.1111/nph.12912.Google Scholar

Masel, J., & Siegal, M. L. (2009). Robustness: Mechanisms and consequences. Trends in Genetics: TIG, 25(9), 395–403. https://doi.org/10.1016/j.tig.2009.07.005.Google Scholar

Maurel, C., Boursiac, Y., Luu, D.-T., Santoni, V., Shahzad, Z., & Verdoucq, L. (2015). Aquaporins in plants. Physiological Reviews, 95(4), 1321–1358. https://doi.org/10.1152/physrev.00008.2015.Google Scholar

McLaughlin, C. M., Li, M., Perryman, M., Heymans, A., Schneider, H., Lasky, J. R., & Sawers, R. J. H. (2024). Evidence that variation in root anatomy contributes to local adaptation in Mexican native maize. Evolutionary Applications, 17(3), e13673. https://doi.org/10.1111/eva.13673.Google Scholar

Mehra, P., Pandey, B. K., Melebari, D., Banda, J., Leftley, N., Couvreur, V., Rowe, J., Anfang, M., Gernier, H. D., Morris, E., Sturrock, C. J., Mooney, S. J., Swarup, R., Faulkner, C., Beeckman, T., Bhalerao, R. P., Shani, E., Jones, A. M., Dodd, I. C., … Bennett, M. J. (2022). Hydraulic flux–responsive hormone redistribution determines root branching. Science, 378(6621), 762–768. https://doi.org/10.1126/science.add3771.Google Scholar

Meunier, F., Heymans, A., Draye, X., Couvreur, V., Javaux, M., & Lobet, G. (2020). MARSHAL, a novel tool for virtual phenotyping of maize root system hydraulic architectures. Silico Plants, 2(1). https://doi.org/10.1093/insilicoplants/diz012.Google Scholar

Moll, R. H., Kamprath, E. J., & Jackson, W. A. (1982). Analysis and interpretation of factors which contribute to efficiency of nitrogen utilization¹ . Agronomy Journal, 74(3), 562–564. https://doi.org/10.2134/agronj1982.00021962007400030037x.Google Scholar

Møller, A. P., & Shykoff, J. A. (1999). Morphological developmental stability in plants: Patterns and causes. International Journal of Plant Sciences, 160(S6), S135–S146. https://doi.org/10.1086/314219.Google Scholar

Monteith, J. L., & Moss, C. J. (1977). Climate and the efficiency of crop production in Britain. Philosophical Transactions of the Royal Society of London, 281(980), 277–294. https://doi.org/10.1098/rstb.1977.0140.Google Scholar

Muhammad, A., & Bae, S.-H. (2022). A survey on efficient methods for adversarial robustness. IEEE Access: Practical Innovations, Open Solutions, 10, 118815–118830. https://doi.org/10.1109/access.2022.3216291.Google Scholar

Muller, B., Guédon, Y., Passot, S., Lobet, G., Nacry, P., Pagès, L., Wissuwa, M., & Draye, X. (2019). Lateral roots: Random diversity in adversity. Trends in Plant Science, 24(9), 810–825. https://doi.org/10.1016/j.tplants.2019.05.011.Google Scholar

Mulvany, P. (2021). Sustaining agricultural biodiversity and heterogeneous seeds. In Rethinking food and agriculture (pp. 285–321). Elsevier. https://doi.org/10.1016/b978-0-12-816410-5.00014-1 Google Scholar

Mutegi, E., Sagnard, F., Labuschagne, M., Herselman, L., Semagn, K., Deu, M., de Villiers, S., Kanyenji, B. M., Mwongera, C. N., Traore, P. C. S., & Kiambi, D. (2012). Local scale patterns of gene flow and genetic diversity in a crop–wild–weedy complex of sorghum (Sorghum bicolor (L.) Moench) under traditional agricultural field conditions in Kenya. Conservation Genetics, 13(4), 1059–1071. https://doi.org/10.1007/s10592-012-0353-y.Google Scholar

Nelson, V. P. (1990). Fault-tolerant computing: Fundamental concepts. Computer, 23(7), 19–25. https://doi.org/10.1109/2.56849.Google Scholar

Nicotra, A. B., Atkin, O. K., Bonser, S. P., Davidson, A. M., Finnegan, E. J., Mathesius, U., Poot, P., Purugganan, M. D., Richards, C. L., Valladares, F., & van Kleunen, M. (2010). Plant phenotypic plasticity in a changing climate. Trends in Plant Science, 15(12), 684–692. https://doi.org/10.1016/j.tplants.2010.09.008.Google Scholar

Nieminen, K., Blomster, T., Helariutta, Y., & Mähönen, A. P. (2015). Vascular cambium development. The Arabidopsis Book / American Society of Plant Biologists, 13, e0177. https://doi.org/10.1199/tab.0177.Google Scholar

Orman-Ligeza, B., Morris, E. C., Parizot, B., Lavigne, T., Babé, A., Ligeza, A., Klein, S., Sturrock, C., Xuan, W., Novák, O., Ljung, K., Fernandez, M. A., Rodriguez, P. L., Dodd, I. C., De Smet, I., Chaumont, F., Batoko, H., Périlleux, C., Lynch, J. P., … Draye, X. (2018). The Xerobranching response represses lateral root formation when roots are not in contact with water. Current Biology: CB, 28(19), 3165–3173.e5. https://doi.org/10.1016/j.cub.2018.07.074 Google Scholar

Orosa-Puente, B., Leftley, N., von Wangenheim, D., Banda, J., Srivastava, A. K., Hill, K., Truskina, J., Bhosale, R., Morris, E., Srivastava, M., Kümpers, B., Goh, T., Fukaki, H., Vermeer, J. E. M., Vernoux, T., Dinneny, J. R., French, A. P., Bishopp, A., Sadanandom, A., & Bennett, M. J. (2018). Root branching toward water involves posttranslational modification of transcription factor ARF7. Science, 362(6421), 1407–1410. https://doi.org/10.1126/science.aau3956.Google Scholar

Pan, C., & Qi, Y. (2023). CRISPR-combo-mediated orthogonal genome editing and transcriptional activation for plant breeding. Nature Protocols, 18(6), 1760–1794. https://doi.org/10.1038/s41596-023-00823-w.Google Scholar

Panchy, N., Lehti-Shiu, M., & Shiu, S.-H. (2016). Evolution of gene duplication in plants. Plant Physiology, 171(4), 2294–2316. https://doi.org/10.1104/pp.16.00523.Google Scholar

Passioura, J. B. (1982). Water in the soil-plant-atmosphere continuum. In Physiological plant ecology II (pp. 5–33). Springer. https://doi.org/10.1007/978-3-642-68150-9_2 Google Scholar

Passot, S., Moreno-Ortega, B., Moukouanga, D., Balsera, C., Guyomarc’h, S., Lucas, M., Lobet, G., Laplaze, L., Muller, B., & Guédon, Y. (2018). A new phenotyping pipeline reveals three types of lateral roots and a random branching pattern in two cereals. Plant Physiology, 177(3), 896–910. https://doi.org/10.1104/pp.17.01648.Google Scholar

Petereit, J., Bayer, P. E., Thomas, W. J. W., Tay Fernandez, C. G., Amas, J., Zhang, Y., Batley, J., & Edwards, D. (2022). Pangenomics and crop genome adaptation in a changing climate. Plants, 11(15), 1949. https://doi.org/10.3390/plants11151949.Google Scholar

Postma, J. A., Kuppe, C., Owen, M. R., Mellor, N., Griffiths, M., Bennett, M. J., Lynch, J. P., & Watt, M. (2017). OpenSimRoot: Widening the scope and application of root architectural models. The New Phytologist, 215(3), 1274–1286. https://doi.org/10.1111/nph.14641.Google Scholar

Psaier, H., & Dustdar, S. (2011). A survey on self-healing systems: Approaches and systems. Computing, 91(1), 43–73. https://doi.org/10.1007/s00607-010-0107-y.Google Scholar

Ramachandran, P., Augstein, F., Nguyen, V., & Carlsbecker, A. (2020). Coping with water limitation: Hormones that modify plant root xylem development. Frontiers in Plant Science, 11, 570. https://doi.org/10.3389/fpls.2020.00570.Google Scholar

Rellán-Álvarez, R., Lobet, G., & Dinneny, J. R. (2016). Environmental control of root system biology. Annual Review of Plant Biology, 67, 619–642. https://doi.org/10.1146/annurev-arplant-043015-111848.Google Scholar

Rellán-Álvarez, R., Lobet, G., Lindner, H., Pradier, P.-L., Sebastian, J., Yee, M.-C., Geng, Y., Trontin, C., LaRue, T., Schrager-Lavelle, A., Haney, C. H., Nieu, R., Maloof, J., Vogel, J. P., & Dinneny, J. R. (2015). GLO-Roots: An imaging platform enabling multidimensional characterization of soil-grown root systems. eLife, 4. https://doi.org/10.7554/elife.07597.Google Scholar

Rowe, J. H., Topping, J. F., Liu, J., & Lindsey, K. (2016). Abscisic acid regulates root growth under osmotic stress conditions via an interacting hormonal network with cytokinin, ethylene and auxin. The New Phytologist, 211(1), 225–239. https://doi.org/10.1111/nph.13882.Google Scholar

Salih, A. A., Ali, I. A., Lux, A., Luxová, M., Cohen, Y., Sugimoto, Y., & Inanaga, S. (1999). Rooting, water uptake, and xylem structure adaptation to drought of two sorghum cultivars. Crop Science, 39(1), 168–173. https://doi.org/10.2135/cropsci1999.0011183X003900010027x.Google Scholar

Sasidharan, R., Voesenek, L. A., & Pierik, R. (2011). Cell wall modifying proteins mediate plant acclimatization to biotic and abiotic stresses. Critical Reviews in Plant Sciences, 30(6), 548–562. https://doi.org/10.1080/07352689.2011.615706.Google Scholar

Scharwies, J. D., Clarke, T., Zheng, Z., Dinneny, A., Birkeland, S., Veltman, M. A., Sturrock, C. J., Banda, J., Torres-Martínez, H. H., Viana, W. G., Khare, R., Kieber, J., Pandey, B. K., Bennett, M., Schnable, P. S., & Dinneny, J. R. (2024). Maize genetic diversity identifies moisture-dependent root-branch signaling pathways. Plant Biology. https://doi.org/10.1101/2024.08.26.609741v1.full Google Scholar

Schneider, H. M., & Lynch, J. P. (2020). Should root plasticity be a crop breeding target? Frontiers in Plant Science, 11, 546. https://doi.org/10.3389/fpls.2020.00546.Google Scholar

Schnepf, A., Leitner, D., Landl, M., Lobet, G., Mai, T. H., Morandage, S., Sheng, C., Zörner, M., Vanderborght, J., & Vereecken, H. (2018). CRootBox: A structural-functional modelling framework for root systems. Annals of Botany, 121(5), 1033–1053. https://doi.org/10.1093/aob/mcx221.Google Scholar

Schreiber, M., Jayakodi, M., Stein, N., & Mascher, M. (2024). Plant pangenomes for crop improvement, biodiversity and evolution. Nature Reviews. Genetics, 25(8), 563–577. https://doi.org/10.1038/s41576-024-00691-4.Google Scholar

Shantz, H. L., & Briggs, L. J., (1913). Water requirement of plants - 2. A review of the literature. U.S. G.P.O. https://doi.org/10.5962/bhl.title.119193 Google Scholar

Sperry, J. S., Meinzer, F. C., & McCulloh, K. A. (2008). Safety and efficiency conflicts in hydraulic architecture: Scaling from tissues to trees. Plant, Cell & Environment, 31(5), 632–645. https://doi.org/10.1111/j.1365-3040.2007.01765.x.Google Scholar

Strock, C. F., Schneider, H. M., Galindo-Castañeda, T., Hall, B. T., Van Gansbeke, B., Mather, D. E., Roth, M. G., Chilvers, M. I., Guo, X., Brown, K., & Lynch, J. P. (2019). Laser ablation tomography for visualization of root colonization by edaphic organisms. Journal of Experimental Botany. https://doi.org/10.1093/jxb/erz271.Google Scholar

Sun, H., Zhang, J., Liao, S., Guo, S., Zhou, Z., Zhao, X., Wu, S., Zhao, J., Gong, G., Wang, J., Li, M., Yu, Y., Ren, Y., Tian, S., Li, S., Zhang, H., Hammar, S. A., McGregor, C., Jarret, R., … Fei, Z. (2025). Population-level super-pangenome reveals genome evolution and empowers precision breeding in watermelon. Plant Biology. https://doi.org/10.1101/2025.07.25.666869v1.abstract Google Scholar

Sun, W., Yuan, X., Liu, Z.-J., Lan, S., Tsai, W.-C., & Zou, S.-Q. (2019). Multivariate analysis reveals phenotypic diversity of Euscaphis japonica population. PLoS One, 14(7), e0219046. https://doi.org/10.1371/journal.pone.0219046.Google Scholar

Sutka, M., Li, G., Boudet, J., Boursiac, Y., Doumas, P., & Maurel, C. (2011). Natural variation of root hydraulics in Arabidopsis grown in normal and salt-stressed conditions. Plant Physiology, 155(3), 1264–1276. https://doi.org/10.1104/pp.110.163113.Google Scholar

Tardieu, F. (2012). Any trait or trait-related allele can confer drought tolerance: Just design the right drought scenario. Journal of Experimental Botany, 63(1), 25–31. https://doi.org/10.1093/jxb/err269.Google Scholar

Tardieu, F., Cabrera-Bosquet, L., Pridmore, T., & Bennett, M. (2017). Plant Phenomics, from sensors to knowledge. Current Biology: CB, 27(15), R770–R783. https://doi.org/10.1016/j.cub.2017.05.055.Google Scholar

Uga, Y., Sugimoto, K., Ogawa, S., Rane, J., Ishitani, M., Hara, N., Kitomi, Y., Inukai, Y., Ono, K., Kanno, N., Inoue, H., Takehisa, H., Motoyama, R., Nagamura, Y., Wu, J., Matsumoto, T., Takai, T., Okuno, K., & Yano, M. (2013). Control of root system architecture by DEEPER ROOTING 1 increases rice yield under drought conditions. Nature Genetics, 45(9), 1097–1102. https://doi.org/10.1038/ng.2725.Google Scholar

Valladares, F., Sanchez-gomez, D., & Zavala, M. A. (2006). Quantitative estimation of phenotypic plasticity: Bridging the gap between the evolutionary concept and its ecological applications. The Journal of Ecology, 94(6), 1103–1116. https://doi.org/10.1111/j.1365-2745.2006.01176.x.Google Scholar

Vandermeer, J., & Perfecto, I. (2007). The agricultural matrix and a future paradigm for conservation. Conservation Biology: The Journal of the Society for Conservation Biology, 21(1), 274–277. https://doi.org/10.1111/j.1523-1739.2006.00582.x.Google Scholar

Wang, C., Wang, H., Li, P., Li, H., Xu, C., Cohen, H., Aharoni, A., & Wu, S. (2020). Developmental programs interact with abscisic acid to coordinate root suberization in Arabidopsis. The Plant Journal: For Cell and Molecular Biology, 104(1), 241–251. https://doi.org/10.1111/tpj.14920.Google Scholar

Wang, S., Qian, Y.-Q., Zhao, R.-P., Chen, L.-L., & Song, J.-M. (2023). Graph-based pan-genomes: Increased opportunities in plant genomics. Journal of Experimental Botany, 74(1), 24–39. https://doi.org/10.1093/jxb/erac412.Google Scholar

Wang, Y., Wang, Y., Sun, X., Caiji, Z., Yang, J., Cui, D., Cao, G., Ma, X., Han, B., Xue, D., & Han, L. (2016). Influence of ethnic traditional cultures on genetic diversity of rice landraces under on-farm conservation in Southwest China. Journal of Ethnobiology and Ethnomedicine, 12(1), 51. https://doi.org/10.1186/s13002-016-0120-0.Google Scholar

Zhan, A., Schneider, H., & Lynch, J. P. (2015). Reduced lateral root branching density improves drought tolerance in maize. Plant Physiology, 168(4), 1603–1615. https://doi.org/10.1104/pp.15.00187.Google Scholar

Author comment: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR1

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr1

Magdalena Julkowska

Boyce Thompson Institute for Plant Research, United States

Revision round: 0

Role: author

Comments

No accompanying comment.

Review: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR2

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr2

Reviewer_1

Date of review: 17 September 2025

Revision round: 0

Role: reviewer

Recommendation/decision: minor-revision

Conflict of interest statement

Reviewer declares none.

Comments

This is a very intersting manuscript on an important topic.

Just a few minor points:

In the section ‘Building belowground robustness through root system architecture’ section there are a few points where terminology can be clarified. For example in paragraph 1 and 2 of that section root types are listed e.g. ‘primary, lateral, adventitious, nodal, and crown’. E.g. crown roots, brace roots, and multiple nodal root whorls. Nodal and crown are types of adventitious roots. It would be useful to refine this list to not be redundant. In addition, ‘multiple nodal root whorls’ could be changed to ‘crown and brace roots emerging from several stem nodes’ or something similar.

Page 7 ‘within a single genotype, lateral roots and their segments’ Unclear what ‘and their segments’ means. In the same paragraph, what is ‘root sector’

Page 7 (same paragraph as comment above) is ‘random heterogeneity’ really random in this case?

Page 8, the term ‘reversibility’ should be clarified. Reversible plasticity has been used to define several different phenomenons, e.g. changes in the root phenotype at the growing root tip when stress is released or changes in the same tissue (reverting back to the original phenotype in the same tissue)

While the review proposes several metrics for measuring robustness, it might be helpful to include a more in-depth discussion on the practical challenges and limitations of applying these methods at scale, especially in a field setting. Expanding on these practical difficulties would provide a more realistic roadmap for future research.

The review discusses how different root developmental processes can achieve similar functions (redundancy) and how some root traits, such as root depth, are plastic in response to drought. It could further elaborate on the interplay between these three components. For example, how does genetic influence the degree of anatomical plasticity in response to stress?

The authors could also consider modifying the figure in the manuscript to show that architecture, anatomy, and genetics also interact!

Review: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR3

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr3

Alexandre Grondin

UMR DIADE, Institut de Recherche pour le Développement Centre de Montpellier, France

Date of review: 21 September 2025

Revision round: 0

Role: reviewer

Recommendation/decision: minor-revision

Conflict of interest statement

Reviewer declares none.

Comments

In this review article, Julkowska et al. discuss the concept of robustness in plant water transport, arguing that robustness—defined as the ability to maintain function under adverse conditions—rather than efficiency stricto sensu may be a more relevant target to sustain agricultural production in the future. The concept of robustness is broken down into three subcomponents: redundancy, heterogeneity, and plasticity. The authors describe how each of these components may be expressed at anatomical, architectural, and genomic scales. Overall, this is an original and nice review that is enjoyable to read.

The authors may wish to consider the following suggestions to further improve the manuscript:

-The distinction between heterogeneity and plasticity is not always entirely clear. This is evident on Page 5 under “Xylem heterogeneity” and on Page 14 under “Gene expression heterogeneity.” It might be more straightforward to explicitly acknowledge that these concepts can overlap in certain contexts.

-Page 5: The method for calculating the vessel grouping index should be explained more clearly.

-Page 10: The distinction between the dispensable and accessory genome should be clarified. The terminology could be made more consistent to avoid confusion.

-Page 14: Should time-course transcriptomics also be considered under plasticity? This is briefly mentioned in the section on gene expression heterogeneity and highlights the difficulties to distinguish between the two processes at times.

-Page 14: The statement “where uncorrelated traits contribute to robustness through diversification rather than overlap” is interesting. The authors could expand on this idea to explain more concretely how uncorrelated traits could be interpreted.

-Page 15: The statement “we envision a framework where plant hydraulic robustness is quantitatively predicted—integrating phenotypic plasticity, trait covariance, and genetic diversity into models of plant performance” is interesting but vague. Space might be limited, but providing additional insight into how such a framework could be constructed would be valuable for readers.

Recommendation: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR4

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr4

Priya Ramakrishna

Laboratory of Biogeochemistry, Ecole Polytechnique Federale de Lausanne, Switzerland

Date of review: 23 September 2025

Revision round: 0

Role: Associate Editor

Recommendation/decision: minor-revision

Comments

Dear Prof. Julkowska,

Both reviewers have welcomed the review and recognised its importance to the community. They have raised a few minor comments, which I believe will improve the manuscript and make it ready for publication. We would be happy to consider a revised version that addresses these points.

All the best,

Priya Ramakrishna

Decision: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR5

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr5

Olivier Hamant

RDP, ENS de Lyon, France

Revision round: 0

Role: Editor in Chief

Recommendation/decision: minor-revision

Comments

No accompanying comment.

Author comment: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR6

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr6

Magdalena Julkowska

Boyce Thompson Institute for Plant Research, United States

Revision round: 1

Role: author

Comments

No accompanying comment.

Review: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR7

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr7

Alexandre Grondin

UMR DIADE, Institut de Recherche pour le Développement Centre de Montpellier, France

Date of review: 21 November 2025

Revision round: 1

Role: reviewer

Recommendation/decision: accept

Conflict of interest statement

Reviewer declares none.

Comments

I thank the authors for considering my previous comments. In particular, the authors have clarified their views on how heterogeneity and plasticity can overlap and have clarified some previously unclear statements. As a minor comment, genomic heterogeneity does not translate into a straightforward visualisation in the Figure 1. Appart from that, I consider that the paper has improved and is now in an acceptable form for publication.

Review: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR8

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr8

Reviewer_1

Date of review: 27 November 2025

Revision round: 1

Role: reviewer

Recommendation/decision: accept

Conflict of interest statement

Reviewer declares none.

Comments

The authors have addressed all of my concerns!

Recommendation: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR9

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr9

Priya Ramakrishna

Laboratory of Biogeochemistry, Ecole Polytechnique Federale de Lausanne, Switzerland

Date of review: 30 November 2025

Revision round: 1

Role: Associate Editor

Recommendation/decision: accept

Comments

Dear Dr. Julkowska,

Thank you for the careful revision of your manuscript. All pending issues have been resolved. Thank you and the co-authors again for your valuable contribution.

Best regards,

Priya

Decision: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR10

Published online by Cambridge University Press: 12 December 2025

DOI: https://doi.org/10.1017/qpb.2025.10035.pr10

Olivier Hamant

RDP, ENS de Lyon, France

Revision round: 1

Role: Editor in Chief

Recommendation/decision: accept

Comments

No accompanying comment.

Article contents

Beyond efficiency: The multi-scale architecture of robust water transport in plants

Abstract

Keywords

Information

1. Introduction

2. Components of robustness

3. Laying the foundation of hydraulic functionality at the anatomical scale

4. Building below-ground robustness through root system architecture

5. Beyond the reference: (Pan)genomic basis of robust water transport

6. Measuring robustness: Quantifying the invisible buffer

7. Conclusions and future perspectives

Open peer review

Competing interest

Data availability statement

Author contributions

Funding statement

Footnotes

References

Author comment: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR1

Comments

Review: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR2

Conflict of interest statement

Comments

Review: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR3

Conflict of interest statement

Comments

Recommendation: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR4

Comments

Decision: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R0/PR5

Comments

Author comment: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR6

Comments

Review: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR7

Conflict of interest statement

Comments

Review: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR8

Conflict of interest statement

Comments

Recommendation: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR9

Comments

Decision: Beyond efficiency: The multi-scale architecture of robust water transport in plants — R1/PR10

Comments

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests