2019
DOI: 10.1111/jac.12332
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Selection of wheat genotypes for biomass allocation to improve drought tolerance and carbon sequestration into soils

Abstract: The biomass allocation pattern of plants to shoots and roots is a key in the cycle of elements such as carbon, water and nutrients with, for instance, the greatest allocations to roots fostering the transfer of atmospheric carbon to soils through photosynthesis. Several studies have investigated the root to shoot ratio (R:S) biomass of existing crops but variation within a crop species constitutes an important information gap for selecting genotypes aiming for increasing soil carbon stocks for climate change m… Show more

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Cited by 35 publications
(30 citation statements)
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“…On the contrary, plants under drought tended to invest more in root biomass for most genotypes, as revealed by the reduced S/R ratios in this condition (Table 2). Intra-specific variation for assimilate partitioning between roots and shoots has been found in wheat [55][56][57], generally with relatively larger roots in landraces [55,56]. In our case, we did not observe overall differences in S/R ratio between landraces and cultivars, but we did find genetic variability among the landraces for assimilate partitioning.…”
Section: Shoot Vs Root Growthsupporting
confidence: 45%
“…On the contrary, plants under drought tended to invest more in root biomass for most genotypes, as revealed by the reduced S/R ratios in this condition (Table 2). Intra-specific variation for assimilate partitioning between roots and shoots has been found in wheat [55][56][57], generally with relatively larger roots in landraces [55,56]. In our case, we did not observe overall differences in S/R ratio between landraces and cultivars, but we did find genetic variability among the landraces for assimilate partitioning.…”
Section: Shoot Vs Root Growthsupporting
confidence: 45%
“…Traits with high loading on the first and second PCs are important for selection as they are able to discriminate the genotypes more effectively compared to traits with less contributions (Shlens, 2014;Zhang & Castelló, 2017;Zuśka et al, 2019). The differences in trait contributions to the total variation observed among the genotypes under different water regimes were in line with findings from Mwadzingeni et al (2016) and Mathew et al (2019). Similarly, families plotted in the positive quadrants of the first principal component axis (Figures 1 and 2) can be selected as genetic resources for improving above-ground traits.…”
Section: Trait Contribution To Total Variation Within the Mutant Population Under Different Water Regimessupporting
confidence: 67%
“…Similarly, the strategy could be extended to select genotypes with favourable biomass allocation using root-shoot ratio and shoot biomass, which are more easily measurable compared with root biomass. Mathew et al (2019) used selection for root-to-shoot ratios and shoot biomass to indirectly improve biomass allocation for drought tolerance and carbon sequestration in wheat. Under water-stressed condition, the high positive loadings of productive tiller number, shoot biomass, total biomass, root biomass, root-shoot ratio and grain yield on the first two PC axes indicate the importance of selecting families based on these traits for drought tolerance and increased biomass (Table 5).…”
Section: Trait Contribution To Total Variation Within the Mutant Population Under Different Water Regimesmentioning
confidence: 99%
“…However, the re-tillering ability of barley (Jamieson et al, 1995) lead to an even slightly higher (although not significant) tiller number at the end of recovery phase compared to control treatment. Although the absolute number of tillers can be increased after drought (Blum et al, 1990), drought stress during the booting stage leads to a reduction in the number of productive tillers and a concomitant decrease in grain number and seed set (Lawlor et al, 1981; Rajala et al, 2010; Mathew et al, 2019).…”
Section: Discussionmentioning
confidence: 99%