Challenges of Maize Breeding Under Tropical Conditions of Brazil

Pinho, Renzo Garcia Von; Silva, Eric Vinicius Vieira; Oliveira, Thiago Lucas de

doi:10.18512/rbms2022vol21e1258

Cited by 2 publications

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“…Drought, low N, and high nighttime temperature conditions are the major abiotic factors limiting the yield of maize in tropical environments (Boomsma et al., 2009; Durães, 2014; Edmeades et al., 2017; Nurmberg et al., 2022; Von Pinho et al., 2022). Low N is considered the second most limiting factor to maize yield, and the effects of low N stress on maize yield appear to be more intense under drought stress than under optimum moisture since N is transported in the soil mainly by mass flow and therefore is highly soil water dependent (Bänziger, 2000; Barber & Cushman, 1981; DeBruin & Butzen, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…In relation to heat stress, high temperature negatively affects maize growth, development, and yield mainly in lowland tropical environments (0–600 m above sea level, asl), which are characterized by lower solar radiation and high night temperature, that is, lower diurnal temperature amplitude, especially during the maize grain filling stage (Durães, 2014; Fancelli, 2017; Prasanna et al., 2021; Von Pinho et al., 2022). High night temperature associated with lower diurnal temperature amplitude during maize flowering and post‐flowering resulted in increases in night respiration and reductions in photosynthesis, crop growth rate, kernel number, and grain yield (Alam et al., 2017; Hussain et al., 2019; Kettler et al., 2022; Wang et al., 2020).…”

Section: Introductionmentioning

confidence: 99%

“…During the 2020/21 season, Brazilian maize production was significantly affected by drought occurrence during the reproductive phase of maize, and the amount of harvested maize was reduced by approximately 15.00 million metric tons, which represented a decline of 16% compared with 2019/20 maize production (CONAB, 2022). Drought, low N, and high nighttime temperature conditions are the major abiotic factors limiting the yield of maize in tropical environments (Boomsma et al, 2009;Durães, 2014;Edmeades et al, 2017;Nurmberg et al, 2022;Von Pinho et al, 2022). Low N is considered the second most limiting factor to maize yield, and the effects of low N stress on maize yield appear to be more intense under drought stress than under optimum moisture since N is transported in the soil mainly by mass flow and therefore is highly soil water dependent (Bänziger, 2000;Barber & Cushman, 1981;DeBruin & Butzen, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…In the presence of genotype by environment interaction (GEI), different cultivars respond differently to diverse environments, and consequently, the rank of cultivars may vary in different environments, complicating the identification of maize cultivars across multiple environments (De Leon et al., 2016; El‐Soda et al., 2014; Haldane, 1946; Yan, 2016). In tropical environments, the GEI tends to be stronger than in non‐tropical environments due to the more pronounced and frequent occurrence of abiotic stress, such as drought, heat, and low N (Edmeades et al., 2017; Nurmberg et al., 2022; Von Pinho et al., 2022). Consequently, maize cultivars must be evaluated across multiple tropical environments before their recommendation and release for farmers.…”

Section: Introductionmentioning

confidence: 99%

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Assessment of yield performance and stability of hybrids and populations of tropical maize across multiple environments in Southeastern Brazil

et al. 2023

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The identification of stable genotypes with high yield in diverse multiple‐stress environments is important to increase maize (Zea mays L.) grain yield under tropical environments. Our objective was to assess the yield performance and stability of experimental hybrids and broad‐based populations of tropical maize across diverse environments in Southeastern Brazil. We evaluated two sets of maize genotypes for grain yield: 190 experimental hybrids along with 6 commercial hybrids and 45 population hybrids along with their 10 parental populations across 8 environments in Southeastern Brazil. Multiple statistical methods were used and compared in the analyses. Combined analysis of variance indicated that genotypic main effect (G), environmental main effect (E), and genotype by environment interaction were highly significant (p < 0.0001) for grain yield. The E accounted for 42% of the total variation for both hybrids and populations, and they were more similar within the growing season than between seasons, mainly for populations. Low nitrogen (N) stress was a key factor in hybrid evaluation and recommendation, particularly under drought stress conditions. Among the environment classification methods, genotype main effect plus genotype × environment interaction (GGE) biplot provided more accurate information about environments grouping and selection of the genotypes than the Eberhart and Russell method. Harmonic mean of the relative performance of the predicted genetic values (HMRPGV) based on mixed models ranked the hybrids and populations according to mean grain yield and stability, penalizing hybrids, and populations with lower stability. Therefore, we recommend the GGE biplot and HMRPGV for genotype evaluation based on multi‐environment trials data. These methods identified 92V2144 and 92V2033 as the most promising hybrids for favorable and 92V2141, 92V2153, and 92V2137 as the most promising for unfavorable environments. 92VX033 and 92VX043 were identified as broadly adapted and stable populations across multiple environments in Southeastern Brazil.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Assessment of yield performance and stability of hybrids and populations of tropical maize across multiple environments in Southeastern Brazil

et al. 2023

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Proposal of a super trait for increased grain yield, popping expansion, and ear rot resistance in popcorn

de Almeida,

Vivas,

de Souza

et al. 2024

Crop Science

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Fusarium ear rot (FER) is a disease that causes a decrease in grain quality in several popcorn fields in tropical regions. To contribute to the development of popcorn cultivars resistant to FER and superior in the main agronomic traits, the study aimed to compare gains in popping expansion (PE), grain yield (GY), and FER resistance through direct and indirect selection strategies by proposing a new super trait. The study was conducted in Campos dos Goytacazes, RJ. The traits were evaluated in 41 inbred lines from four environments using a randomized block design with four replicates. Six selection strategies and four selection intensities were tested. Direct selection on GY resulted in losses in PE and small gains in FER in the majority of the environments. Positive selection on PE resulted in FER reduction in scenarios of lower selection intensity. Selection by popping volume showed a satisfactory increase in GY and PE but was not effective in FER reduction. Selection by multi‐trait genotype–ideotype distance index resulted in GY increase only in some environments, PE increase in all environments, and FER reduction in all environments under higher selection intensities. The newly developed super trait popping volume without Fusarium (PVwF) showed the possibility of increasing GY (32.90% at 88.8%) and PE (5.10% at 10.20%) while simultaneously reducing FER in all environments and selection intensities (−6.30% at −6.70%). PVwF is an easily executable methodology to help popcorn breeders optimize gains in their programs. The lines L214, L217, L292, and L328 are more suitable for use in mating blocks aimed to develop superior popcorn hybrids.

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Challenges of Maize Breeding Under Tropical Conditions of Brazil

Cited by 2 publications

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Assessment of yield performance and stability of hybrids and populations of tropical maize across multiple environments in Southeastern Brazil

Assessment of yield performance and stability of hybrids and populations of tropical maize across multiple environments in Southeastern Brazil

Proposal of a super trait for increased grain yield, popping expansion, and ear rot resistance in popcorn

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