Root System Architecture and Abiotic Stress Tolerance: Current Knowledge in Root and Tuber Crops

Khan, Muhammad Awais; Gemenet, Dorcus C.; Villordon, Arthur

doi:10.3389/fpls.2016.01584

Cited by 164 publications

(124 citation statements)

References 130 publications

(120 reference statements)

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“…We conducted signed gene co‐expression network analysis using the WGCNA (Khan et al., ) based on FPKM data. Genes with FPKM < 1 for all samples and a coefficient of variation cut‐off of 0.25 was removed prior to WGCNA analysis.…”

Section: Methodsmentioning

confidence: 99%

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Multivariate analyses of root phenotype and dynamic transcriptome underscore valuable root traits and water‐deficit responsive gene networks in maize

Zhang

Pang

et al. 2019

Plant Direct

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Root system architecture (RSA) plays a vital role in plant adaptation and productivity under water‐deficit environments. In this study, we use two maize inbreeds to investigate root phenotypic and early transcriptional responses to water‐deficit stress. As evidenced by improved survival rate and photosynthetic efficiency at early seedling and late vegetative stage, CIMBL55 was characterized as a tolerant genotype versus sensitive SHEN5003. Image‐based root phenotyping revealed that drought tolerant cultivar had notably different RSA features from drought sensitive cultivar including larger root size, longer root length, and more number of lateral roots and seminal roots. Dynamic transcriptome investigations on primary and seminal root integrating differential gene expression, temporal gene co‐expression, and weighted gene co‐expression network analysis (WGCNA) revealed a high degree of genotype‐ and root type‐specificity in response to PEG‐induced water deficit. The higher drought tolerability of CIMBL55 versus SHEN5003 can be attributed to the enhanced expression of genes associated with antioxidant defense and a higher proportion of water‐deficit responsive genes. Upon water deficit, seminal roots exhibited more dramatic transcriptional changes than the primary root, and a more exclusive functional association with stress response. Genome‐wide WGCNA identified system‐level functionality of genes associated with specific root traits. Multiple root‐specific and root‐predominant hub genes were identified with functions involved in transcriptional regulation, root development, and drought response. Conclusively, integrated root phenotypic and transcriptomic analyses identified important root system architectures and water‐deficit responsive gene networks in maize. Findings will serve a valuable resource that merits in‐depth functional analyses toward a better understanding of RSA‐associated drought tolerance in maize.

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Section: Methodsmentioning

confidence: 99%

“…Khan et al, 2016) based on FPKM data. Genes with FPKM < 1 for all samples and a coefficient of variation cut-off of 0.25 was removed prior to WGCNA analysis.…”

mentioning

confidence: 99%

Multivariate analyses of root phenotype and dynamic transcriptome underscore valuable root traits and water‐deficit responsive gene networks in maize

Zhang

Pang

et al. 2019

Plant Direct

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“…A better physiological understanding of root growth dynamics and architecture is crucial to optimize crop performance through the modification of below‐ground root traits adapted to environmental and climatic extremes (Khan, Gemenet, & Villordon, ; Postma, Schurr, & Fiorani, ; Uga et al., ). Nonetheless, root systems are not easily accessible for phenotyping specific traits in soil, either in the greenhouse or in natural field settings.…”

Section: Introductionmentioning

confidence: 99%

“…A better physiological understanding of root growth dynamics and architecture is crucial to optimize crop performance through the modification of below-ground root traits adapted to environmental and climatic extremes (Khan, Gemenet, & Villordon, 2016;Postma, Schurr, & Fiorani, 2014;Uga et al, Chochois, 2013a). Minirhizotrons are nondestructive in situ root phenotyping systems suitable for both greenhouse pots and field landscapes that enable the acquisition of highquality data on root growth, demography, and dynamics in a spatiotemporal context (Crocker et al, 2003;Polomski & Kuhn, 2002).…”

Section: Introductionmentioning

confidence: 99%

Characterization of root traits for improvement of spring wheat in the Pacific Northwest

et al. 2020

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Understanding the genetic basis of root traits provides essential information on a largely untapped resource for crop improvement, as roots are instrumental for the uptake of water and nutrients. However, breeding for improved root traits is challenging due to laborious and time‐consuming root phenotyping in soil. Our studies sought to uncover spatiotemporal root‐growth dynamics of mature plant root systems in five spring wheat (Triticum aestivum L.) cultivars, Louise, Alpowa, Hollis, Drysdale, and Dharwar Dry, and a facultative spring landrace, AUS28451 using the in situ minirhizotron technique. The 2‐yr greenhouse study revealed that the root system grows rapidly after early node elongation to gain maximum size during anthesis, after which root growth slows and transitions to senescence. We were able to detect quantifiable differences among wheat cultivars in root traits in both 5‐d old seedlings and root systems at anthesis. Furthermore, the positive correlation of the observed root traits with grain yield and the consistency in root traits observed using minirhizotrons and through extraction of young and mature root systems has reinforced the experimental results. A negative correlation was found between root number, area, and length and root diameter. We found that the spring wheat cultivars, AUS28451, Dharwar Dry, and Alpowa, had increased root number, area, and length, but also increased time to heading. The results from this study can be further leveraged to screen breeding lines for root traits of interest, as well as assess the heritability of root traits for dryland farming in the inland Pacific Northwest.

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“…Roots serve as boundaries between plants and complex soil mediums. Aside from anchoring the plant to soil medium (Khan et al , 2016), another major function of the root is to provide plant access to nutrient and water uptake. Roots are also essential for forming symbioses with beneficial microbes in the rhizosphere and used as storage organs (Smith and De Smet, 2012; Khan et al , 2016).…”

Section: Introductionmentioning

confidence: 99%

Assessing Root System Architecture of Wheat Seedlings Using A High-Throughput Root Phenotyping System

Adeleke

Millas

McNeal

et al. 2019

Preprint

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Root System Architecture and Abiotic Stress Tolerance: Current Knowledge in Root and Tuber Crops

Cited by 164 publications

References 130 publications

Multivariate analyses of root phenotype and dynamic transcriptome underscore valuable root traits and water‐deficit responsive gene networks in maize

Multivariate analyses of root phenotype and dynamic transcriptome underscore valuable root traits and water‐deficit responsive gene networks in maize

Characterization of root traits for improvement of spring wheat in the Pacific Northwest

Assessing Root System Architecture of Wheat Seedlings Using A High-Throughput Root Phenotyping System

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