Utility of anthesis–silking interval information to predict grain yield under water and nitrogen limited conditions

Lima, Dayane Cristina; León, Natalia de; Kaeppler, Shawn M.

doi:10.1002/csc2.20854

Cited by 3 publications

(9 citation statements)

References 68 publications

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“…The grain yield loss obtained in the present study ranged from 35 to 89% with an average of 61% under managed drought conditions. These yield losses fall within the range reported by other authors [16,[40][41][42][43]. The magnitude of grain yield reduction as a result of drought is known to depend on the duration and intensity of the drought stress [44][45][46][47].…”

Section: Discussionsupporting

confidence: 87%

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Performance and Stability Analysis of Extra-Early Maturing Orange Maize Hybrids under Drought Stress and Well-Watered Conditions

Bonkoungou,

Badu-Apraku,

Adetimirin

et al. 2024

Agronomy

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The consistently low yield turnout of maize on farmers’ fields owing to drought and the nutritional challenges attributable to the consumption of white endosperm maize pose a major threat to food and nutritional security in Sub-Saharan Africa (SSA). The objectives of this study were to assess the performance of newly developed extra-early maturing orange hybrids under managed drought and well-watered conditions, compare the outcomes of multiple-trait base index and multi-trait genotype–ideotype distance index selection procedures, and identify drought-tolerant hybrids with stable performance across contrasting environments for commercialization in SSA. One hundred and ninety orange hybrids and six checks were evaluated under managed drought and well-watered conditions at Ikenne for two seasons between 2021 and 2023. A 14 × 14-lattice design was used for the field evaluations under both research conditions. Drought stress was achieved by the complete withdrawal of irrigation water 25 days after planting. Results revealed significant differences among the hybrids under drought and well-watered conditions. Grain yield, ears per plant, and plant aspect under managed drought were correlated to the same traits under well-watered conditions, suggesting that the expression of these traits is governed by common genetic factors. Twenty-nine hybrids were identified as top-performing drought-tolerant hybrids by the multiple-trait base index and the multi-trait genotype–ideotype distance index. Of the selected outstanding 29 hybrids, 34% were derived from crosses involving the tester TZEEIOR 197, demonstrating the outstanding genetic potential of this inbred line. Further analysis of the 29 selected hybrids revealed TZEEIOR 509 × TZEEIOR 197 as the hybrid that combined the most drought-tolerant adaptive traits. However, the hybrids TZEEIOR 526 × TZEEIOR 97, TZEEIOR 384 × TZEEIOR 30, TZEEIOR 515 × TZEEIOR 249, TZEEIOR 510 × TZEEIOR 197, TZEEIOR 479 × TZEEIOR 197, and TZEEIOR 458 × TZEEIOR 197 were identified as the most stable hybrids across drought and well-watered conditions. These hybrids should be extensively tested in multi-location trials for deployment and commercialization in SSA.

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Section: Discussionsupporting

confidence: 87%

“…The imposed drought stress covered the flowering and grain filling periods. Increased anthesis-silking interval is known to increase the incidence of barrenness [39,40]. The grain yield loss obtained in the present study ranged from 35 to 89% with an average of 61% under managed drought conditions.…”

Section: Discussionmentioning

confidence: 51%

Performance and Stability Analysis of Extra-Early Maturing Orange Maize Hybrids under Drought Stress and Well-Watered Conditions

Bonkoungou,

Badu-Apraku,

Adetimirin

et al. 2024

Agronomy

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“…Separation due to water treatment was not as universally significant, which may partially be due to the water stress treatment in Hancock relying on differential irrigation within natural rainfall. Water treatments were supplied based on reference potential evapotranspiration, with the well‐watered treatment receiving the recommended amount and the water‐stressed plants receiving 60% of the amount (Lima et al., 2023). Though the timing of irrigation was controlled, we did not have control over natural rainfall events, thus we did not have precise control of the timing of the rainfall events.…”

Section: Resultsmentioning

confidence: 99%

LEADER (Leaf Element Accumulation from DEep Roots): A nondestructive phenotyping platform to estimate rooting depth in the field

Hanlon,

Brown,

Lynch

2023

Crop Science

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Deeper rooted crops are an avenue to increase plant water and nitrogen uptake under limiting conditions and increase long‐term soil carbon storage. Measuring rooting depth, however, is challenging due to the destructive, laborious, or imprecise methods that are currently available. Here, we present LEADER (Leaf Element Accumulation from DEep Roots) as a method to estimate in‐field root depth of maize plants. We use both X‐ray fluorescence (XRF) spectroscopy and ICP‐OES (inductively coupled plasma optical emission spectroscopy) to measure leaf elemental content and relate this to metrics of root depth. Principal components of leaf elemental content correlate with measures of root length in four genotypes (R2 = 0.8 for total root length), and we use linear discriminant analysis to classify plants as having different metrics related to root depth across four field sites in the United States. We can correctly classify the plots with the longest root length at depth (deeper than 30 or 40 cm) with high accuracy (accuracy >0.6) at two of our field sites (Hancock, WI and Rock Spring, PA). We also use strontium (Sr) as a tracer element in both greenhouse and field studies, showing that elemental accumulation of Sr in leaf tissue can be measured with XRF and can estimate root depth. We propose the adoption of LEADER as a tool for measuring root depth in different plant species and soils. LEADER is faster and easier than any other methods that currently exist and could allow for extensive study and understanding of deep rooting.

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“…With the increase in the maize area cultivated in the off-season (Companhia Nacional de Abastecimento [CONAB], 2023), it is expected that the crop will be even more exposed to abiotic stress conditions, such as water deficit, low incidence of solar radiation and variations in air temperature, especially during the final stage of development. In addition to variations in meteorological conditions, maize cultivation covers several regions of Brazil, being subjected to nutrient deficiencies, such as phosphorus and nitrogen, aluminum toxicity, salinity and soil waterlogging (Lima, Leon, & Kaeppler, 2022;Zaidi, Shahid, Seetharam, & Vinayan, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…However, due to the lower genetic contribution in the expression of this character, selection based on secondary characters has become efficient (Carvalho et al, 2022). Mainly for adaptation to environments with stress caused by meteorological variables, the interval between male and female flowering has been the main secondary character used (Lima et al, 2022;Zaidi et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Maize genetic breeding for tolerance to abiotic stress with focus on sustainable use of environmental resources

Loro,

Carvalho,

Pradebon

et al. 2023

Agron. Sci. Biotechnol.

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This bibliographic review explored maize genetic breeding to increase tolerance to abiotic stress. The main stresses faced by the crop, such as water stress and nitrogen deficiency, and their negative impacts on grain yield were discussed. Strategies to minimize these effects were examined, focusing on the selection of tolerant genotypes and the strategic positioning of these genotypes in different growing environments. The germplasm bank and genetic diversity were highlighted as crucial resources to identify desirable traits and genes associated with resistance to abiotic stress. The selection of secondary characters, considering their heritability and correlation with characters of interest, allows maximizing the efficiency in the selection of promising genotypes in genetic breeding programs. Test environments simulating stresses, such as water stress and low nitrogen, are essential to evaluate the performance of genotypes and identify the most tolerant ones. The genetic breeding of maize for tolerance to abiotic stress promotes promising solutions to face environmental challenges and ensure the sustainability of agricultural production.

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Utility of anthesis–silking interval information to predict grain yield under water and nitrogen limited conditions

Cited by 3 publications

References 68 publications

Performance and Stability Analysis of Extra-Early Maturing Orange Maize Hybrids under Drought Stress and Well-Watered Conditions

Performance and Stability Analysis of Extra-Early Maturing Orange Maize Hybrids under Drought Stress and Well-Watered Conditions

LEADER (Leaf Element Accumulation from DEep Roots): A nondestructive phenotyping platform to estimate rooting depth in the field

Maize genetic breeding for tolerance to abiotic stress with focus on sustainable use of environmental resources

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