A major root architecture QTL responding to water limitation in durum wheat

The optimal root system architecture (RSA) of a crop is context dependent and critical for efficient resource capture in the soil. Narrow root growth angle promoting deeper root growth is often associated with improved access to water and nutrients in deep soils during terminal drought. RSA, therefore is a drought-adaptive trait that could minimize yield losses in regions with limited rainfall. Here, GWAS for seminal root angle (SRA) identified seven marker-trait associations clustered on chromosome 6A, representing a major quantitative trait locus (qSRA-6A) which also displayed high levels of pairwise LD (r2 = 0.67). Subsequent haplotype analysis revealed significant differences between major groups. Candidate gene analysis revealed loci related to gravitropism, polar growth and hormonal signaling. No differences were observed for root biomass between lines carrying hap1 and hap2 for qSRA-6A, highlighting the opportunity to perform marker-assisted selection for the qSRA-6A locus and directly select for wide or narrow RSA, without influencing root biomass. Our study revealed that the genetic predisposition for deep rooting was best expressed under water-limitation, yet the root system displayed plasticity producing root growth in response to water availability in upper soil layers. We discuss the potential to deploy root architectural traits in cultivars to enhance yield stability in environments that experience limited rainfall

Genetic bases of the heterotrophic growth of hypocotyl in optimal conditions and under abiotic stresses in Medicago truncatula : contribution of the number and length of the cells

La croissance hétérotrophe de l’hypocotyle est une étape clé pour la réussite de la levée. La présente étude est focalisée sur le déterminisme génétique de l’allongement de cet organe à l’obscurité chez Medicago truncatula en analysant le nombre et la longueur des cellules de l’épiderme, tissu gouvernant l’allongement des organes. Une grande variabilité génétique du nombre de cellules a été révélée dans les graines de 15 génotypes représentatifs de la diversité génétique de l’espèce. La stabilité de ce caractère dans des graines provenant de différentes productions suggère qu’il est sous contrôle génétique fort. Il a été montré que ce nombre de cellules, préétabli dans les graines, est le principal déterminant de la variation génotypique de la longueur de hypocotyle en conditions optimales de croissance. Par contre, l'élongation cellulaire devient le déterminant majeur des différences génotypiques observées sous stress abiotiques (basse température, déficit hydrique).Des loci contrôlant le nombre de cellules de l’épiderme et leur longueur maximale à basse température ont ensuite été identifiés dans une population de lignées recombinantes. Ceux ayant un impact sur l’élongation de l’hypocotyle à basse température ont été mis en évidence. Enfin, deux génotypes présentant un nombre de cellules similaire mais des capacités d’allongement cellulaire contrastées ont été plus finement comparés. Des protéines ayant un rôle dans la formation et l’organisation du cytosquelette et dans la modification des parois cellulaires ont été révélées en lien avec les différences d’allongemeThe heterotrophic growth of hypocotyl is a crucial process for successful seedling emergence. The present study is focused on the genetic determinism of its elongation in darkness in Medicago truncatula by analyzing the number and the length of cells of epidermis, the tissue controlling organ elongation.A large genetic variability of the epidermal cell number of the hypocotyl in seeds of 15 genotypes representative of the genetic diversity of the species was revealed. The stability of this trait in the seeds collected from different productions suggests it is under strong genetic control. This cell number was shown to be the main contributor of genotypic variation of hypocotyl length in optimal conditions. On the other hand, cell elongation becomes the major determinant of the genotypic differences observed under abiotic stresses (low temperature, water deficit).Quantitative Trait Loci (QTLs) controlling the number of epidermal cells and their maximal length at low temperature were then identified using a recombinant inbred lines population, and those impacting hypocotyl elongation at low temperature were highlighted.Finally, two genotypes sharing a similar cell number but contrasted capacities of cell elongation were compared more in detail. Proteins playing a role in the formation and organization of cytoskeleton and in the modification of the cell wall were revealed in connection with the differences in cellular elongation between genotypes. Moreover, differences in the cell wall sugar composition, in the degree of methylation of pectins and in a potential inhibit

Bases génétiques de la croissance hétérotrophe de l'hypocotyle en conditions optimales et sous stress abiotiques chez Medicago truncatula : contribution du nombre et de la longueur des cellules

The heterotrophic growth of hypocotyl is a crucial process for successful seedling emergence. The present study is focused on the genetic determinism of its elongation in darkness in Medicago truncatula by analyzing the number and the length of cells of epidermis, the tissue controlling organ elongation.A large genetic variability of the epidermal cell number of the hypocotyl in seeds of 15 genotypes representative of the genetic diversity of the species was revealed. The stability of this trait in the seeds collected from different productions suggests it is under strong genetic control. This cell number was shown to be the main contributor of genotypic variation of hypocotyl length in optimal conditions. On the other hand, cell elongation becomes the major determinant of the genotypic differences observed under abiotic stresses (low temperature, water deficit).Quantitative Trait Loci (QTLs) controlling the number of epidermal cells and their maximal length at low temperature were then identified using a recombinant inbred lines population, and those impacting hypocotyl elongation at low temperature were highlighted.Finally, two genotypes sharing a similar cell number but contrasted capacities of cell elongation were compared more in detail. Proteins playing a role in the formation and organization of cytoskeleton and in the modification of the cell wall were revealed in connection with the differences in cellular elongation between genotypes. Moreover, differences in the cell wall sugar composition, in the degree of methylation of pectins and in a potential inhibitoLa croissance hétérotrophe de l’hypocotyle est une étape clé pour la réussite de la levée. La présente étude est focalisée sur le déterminisme génétique de l’allongement de cet organe à l’obscurité chez Medicago truncatula en analysant le nombre et la longueur des cellules de l’épiderme, tissu gouvernant l’allongement des organes. Une grande variabilité génétique du nombre de cellules a été révélée dans les graines de 15 génotypes représentatifs de la diversité génétique de l’espèce. La stabilité de ce caractère dans des graines provenant de différentes productions suggère qu’il est sous contrôle génétique fort. Il a été montré que ce nombre de cellules, préétabli dans les graines, est le principal déterminant de la variation génotypique de la longueur de hypocotyle en conditions optimales de croissance. Par contre, l'élongation cellulaire devient le déterminant majeur des différences génotypiques observées sous stress abiotiques (basse température, déficit hydrique).Des loci contrôlant le nombre de cellules de l’épiderme et leur longueur maximale à basse température ont ensuite été identifiés dans une population de lignées recombinantes. Ceux ayant un impact sur l’élongation de l’hypocotyle à basse température ont été mis en évidence. Enfin, deux génotypes présentant un nombre de cellules similaire mais des capacités d’allongement cellulaire contrastées ont été plus finement comparés. Des protéines ayant un rôle dans la formation et l’organisation du cytosquelette et dans la modification des parois cellulaires ont été révélées en lien avec les différences d’allongem

Quantitative dissection of variations in root growth rate : a matter of cell proliferation or of cell expansion?

Plant organ growth results from cell production and cell expansion. Deciphering the contribution of each of these processes to growth rate is an important issue in developmental biology. Here, we investigated the cellular processes governing root elongation rate, considering two sources of variation: genotype and disturbance by chemicals (NaCl, polyethylene glycol, H2O2, abscisic acid). Exploiting the adventitious rooting capacity of the Populus genus, and using time-lapse imaging under infrared-light, particle image velocimetry, histological analysis, and kinematics, we quantified the cellular processes involved in root growth variation, and analysed the covariation patterns between growth parameters. The rate of cell production by the root apical meristem and the number of dividing cells were estimated in vivo without destructive measurement. We found that the rate of cell division contributed more to the variation in cell production rate than the number of dividing cells. Regardless of the source of variation, the length of the elongation zone was the best proxy for growth rate, summarizing rates of cell production and cell elongation into a single parameter. Our results demonstrate that cell production rate is the main driver of growth rate, whereas elemental elongation rate is a key driver of short-term growth adjustments.publishe

Cell length instead of cell number becomes the predominant factor contributing to hypocotyl length genotypic differences under abiotic stress in Medicago truncatula

Hypocotyl elongation in the dark is a crucial process to ensure seedling emergence. It relies both on the cell number and cell length. The contribution of these two factors to the maximal hypocotyl length and the impact of environmental conditions on this contribution are not known. This is surprising considering the agronomic and economical importance of seedling emergence in crop establishment. Using 14 genotypes from a nested core collection representing Medicago truncatula (barrel medic) natural variation, we investigated how epidermal cell number and cell length contribute to hypocotyl length under optimal, low temperature (8°C) and water deficit (−0.50 MPa) conditions. Both cell number and length vary according to genotypes and contribute to maximal hypocotyl length differences between genotypes. This contribution, however, depends on growth conditions. Cell number is the major contributor under optimal conditions (60%) whereas cell length becomes the major determinant under stress. Maximal hypocotyl length is correlated with hypocotyl elongation rate under both stresses but not under optimal condition, revealing contrasted genotypes for cell elongation capacity under stress. To identify the genetic regulators determining cell number and cell length, quantitative trait loci (QTLs) were detected using a recombinant inbred lines population exhibiting segregation in maximal hypocotyl length. Two QTLs controlling cell number and three QTLs controlling cell length at low temperature were detected. One QTL for cell number and two for cell length were found to be associated with hypocotyl length under low temperature. This study provides new information to improve seedling emergence under abiotic stress

A major root architecture QTL responding to water limitation in Durum Wheat

The optimal root system architecture (RSA) of a crop is context dependent and critical for efficient resource capture in the soil. Narrow root growth angle promoting deeper root growth is often associated with improved access to water and nutrients in deep soils during terminal drought. RSA, therefore is a drought-adaptive trait that could minimize yield losses in regions with limited rainfall. Here, GWAS for seminal root angle (SRA) identified seven marker-trait associations clustered on chromosome 6A, representing a major quantitative trait locus (qSRA-6A) which also displayed high levels of pairwise LD (r(2) = 0.67). Subsequent haplotype analysis revealed significant differences between major groups. Candidate gene analysis revealed loci related to gravitropism, polar growth and hormonal signaling. No differences were observed for root biomass between lines carrying hapl and hap2 for qSRA-6A, highlighting the opportunity to perform marker-assisted selection for the qSRA-6A locus and directly select for wide or narrow RSA, without influencing root biomass. Our study revealed that the genetic predisposition for deep rooting was best expressed under water-limitation, yet the root system displayed plasticity producing root growth in response to water availability in upper soil layers. We discuss the potential to deploy root architectural traits in cultivars to enhance yield stability in environments that experience limited rainfall