Genetic screening for mutants with altered seminal root numbers in hexaploid wheat using a high-throughput root phenotyping platform

Shorinola, Oluwaseyi; Kaye, R. C.; Golan, Guy; Peleg, Zvi; Kepinski, Stefan; Uauy, Cristóbal

doi:10.1101/364018

Cited by 3 publications

(3 citation statements)

References 47 publications

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“…This ‘hidden half’ of plants is a conduit for resource uptake from the soil, and logically a high‐value target for manipulation to improve crop productivity on nutrient‐deficient soils (Meister et al., 2014). Besides anchorage, storage functions, synthesis and accumulation of secondary metabolites, root systems serve as an interface for symbiotic microbial relationships (Khan et al., 2016; Shorinola et al., 2019). Roots are becoming a key target for a second green revolution, and are deemed essential for production of high‐yielding food grains such as wheat and rice (Gewin, 2010).…”

Section: Introductionmentioning

confidence: 99%

Root system architecture in cereals: progress, challenges and perspective

et al. 2022

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Roots are essential multifunctional plant organs involved in water and nutrient uptake, metabolite storage, anchorage, mechanical support, and interaction with the soil environment. Understanding of this 'hidden half' provides potential for manipulation of root system architecture (RSA) traits to optimize resource use efficiency and grain yield in cereal crops. Unfortunately, root traits are highly neglected in breeding due to the challenges of phenotyping, but could have large rewards if the variability in RSA traits can be fully exploited. Until now, a plethora of genes have been characterized in detail for their potential role in improving RSA. The use of forward genetics approaches to find sequence variations in genes underpinning desirable RSA would be highly beneficial. Advances in computer vision applications have allowed image-based approaches for high-throughput phenotyping of RSA traits that can be used by any laboratory worldwide to make progress in understanding root function and dissection of the genetics. At the same time, the frontiers of root measurement include non-invasive methods like X-ray computer tomography and magnetic resonance imaging that facilitate new types of temporal studies. Root physiology and ecology are further supported by spatiotemporal root simulation modeling. The discovery of component traits providing improved resilience and yield advantage in target environments is a key necessity for mainstreaming root-based cereal breeding. The integrated use of pan-genome resources, now available in most cereals, coupled with new in-field phenotyping platforms has the potential for precise selection of superior genotypes with improved RSA.

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Section: Introductionmentioning

confidence: 99%

Root system architecture in cereals: progress, challenges and perspective

et al. 2022

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“…As the root develops, some of the peripheral elements can increase in size becoming similar to the initial CMX. In recent years, several studies on root system architecture uncovered the genetic basis of these traits, however, most studies focused on the geometric traits, such as root number, length, diameter and, angle (Christopher et al, 2013; Golan et al, 2018; Hamada et al, 2012; Shorinola et al, 2019; Soriano & Alvaro, 2019; Voss‐Fels, Snowdon, & Hickey, 2018). On the other hand, root anatomical traits were less studied and remain largely unexplored.…”

Section: Introductionmentioning

confidence: 99%

Deciphering the genetic basis of wheat seminal root anatomy uncovers ancestral axial conductance alleles

Hendel

Bacher

Oksenberg

et al. 2021

Plant Cell & Environment

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Root axial conductance, which describes the ability of water to move through the xylem, contributes to the rate of water uptake from the soil throughout the whole plant lifecycle. Under the rainfed wheat agro-system, grain-filling is typically occurring during declining water availability (i.e., terminal drought). Therefore, preserving soil water moisture during grain filling could serve as a key adaptive trait. We hypothesized that lower wheat root axial conductance can promote higher yields under terminal drought. A segregating population derived from a cross between durum wheat and its direct progenitor wild emmer wheat was used to underpin the genetic basis of seminal root architectural and functional traits. We detected 75 QTL associated with seminal roots morphological, anatomical and physiological traits, with several hotspots harbouring co-localized QTL. We further validated the axial conductance and central metaxylem QTL using wild introgression lines. Field-based characterization of genotypes with contrasting axial conductance suggested the contribution of low axial conductance as a mechanism for water conservation during grain filling and consequent increase in grain size and yield. Our findings underscore the potential of harnessing wild alleles to reshape the wheat root system architecture and associated hydraulic properties for greater adaptability under changing climate.

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“…The importance of the "hidden half" in polyploid wheats The "hidden half" of wheat, referring to the root system, plays fundamental roles in ensuring nutrient and water uptake efficiency, and thus the adaptability of wheat to diverse growth environments. High-throughput screening of mutant populations, genetic mapping studies, and gene transcriptome profiling have found multiple mutants with altered root architecture, QTLs for wheat root traits, and candidate genes and signaling pathways relating to root development (An et al, 2006;He et al, 2014;Shorinola et al, 2019;Zhuang et al, 2021). These QTLs/genes tend to be related to plant hormone (BR, AUX, and cytokinin) signaling and ROS homeostasis (He et al, 2014;Zhuang et al, 2021).…”

Section: Adaptation To Environmental Constraintsmentioning

confidence: 99%

Shaping polyploid wheat for success: Origins, domestication, and the genetic improvement of agronomic traits

Liu

Yao

Xin

et al. 2022

JIPB

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Bread wheat (Triticum aestivum L., AABBDD, 2n = 6x = 42), which accounts for most of the cultivated wheat crop worldwide, is a typical allohexaploid with a genome derived from three diploid wild ancestors. Bread wheat arose and evolved via two sequential allopolyploidization events and was further polished through multiple steps of domestication. Today, cultivated allohexaploid bread wheat has numerous advantageous traits, including adaptive plasticity, favorable yield traits, and extended end-use quality, which have enabled its cultivation well beyond the ranges of its tetraploid and diploid progenitors to become a global staple food crop. In the past decade, rapid advances in wheat genomic research have considerably accelerated our understanding of the bases for the shaping of complex agronomic traits in this polyploid crop. Here, we summarize recent advances in characterizing major genetic factors underlying the origin, evolution, and improvement of polyploid wheats. We end with a brief discussion of the future prospects for the design of gene cloning strategies and modern wheat breeding.

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Genetic screening for mutants with altered seminal root numbers in hexaploid wheat using a high-throughput root phenotyping platform

Cited by 3 publications

References 47 publications

Root system architecture in cereals: progress, challenges and perspective

Root system architecture in cereals: progress, challenges and perspective

Deciphering the genetic basis of wheat seminal root anatomy uncovers ancestral axial conductance alleles

Shaping polyploid wheat for success: Origins, domestication, and the genetic improvement of agronomic traits

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