Parâmetros genéticos de caracteres relacionados à tolerância à deficiência hídrica em milho tropical Genetic parameters of drought tolerance related traits in tropical maize

A seleção de caracteres relacionados à tolerância à deficiência hídrica em milho tem sido objeto de interesse em programas de melhoramento, principalmente em virtude da ineficiência da seleção para produzir grãos nessas condições. O objetivo deste trabalho foi estimar parâmetros genéticos em duas populações de milho tropical. Foram avaliadas duas populações (denominadas D e U) com 256 progênies F2:3, no delineamento em látice 16 x 16 em sete ou nove ambientes e densidade populacional de 62.500 plantas ha-1. Diferenças significativas foram constatadas entre progênies (P), ambientes (A) e para a interação P x A em ambas as populações. Os coeficientes de herdabilidade em nível de médias de progênies variaram entre 73,52% para prolificidade na população D e 95,88% para florescimento feminino (FF) na população U. No caráter produção de grãos (PG) houve correlação genética significativa nas populações U e D, respectivamente, com prolificidade (0,79 e 0,88) e florescimento feminino (-0,76 e -0,44); na população U com florescimento masculino (-0,74) e; na população D com stay-green (-0,50). Não foi constatada correlação genética significativa entre PG e intervalo entre florescimentos (IF). Os parâmetros genéticos estimados sugerem que a utilização de índices de seleção que incluam, além de PG, caracteres como prolificidade, FF e SG na seleção de progênies sob condições normais de umidade, poderia propiciar o desenvolvimento de material com alta produtividade e boa tolerância a estresses hídricos.<br>The selection of drought tolerance related traits in maize has been object of interest in improvement programs, mainly in function of the selection inefficiency for grain yield on these conditions. The objective of this work was to estimate genetic parameters in two populations of tropical maize. Two populations (called D and U) with 256 F2:3 progenies had been evaluated in a 16x16 simple lattice, in seven and nine environments with population density of 62,500 plants ha-1. Significant differences were observed among line (P), environments (A) and for the P x A interaction in both populations. The heritability coefficients at progenies level average had varied between 73.52% for prolificacy in population D and 95.88% for female flowering (FF) in population U. Grain yield (PG) presented significant genetic correlation in populations U and D, respectively, with prolificacy (0,79 and 0.88) and female flowering (-0,76 and -0,44); in population U with male flowering (-0.74) and; in population D with stay-green (-0.50). No genetic correlation was observed between PG and anthesis-silking interval (IF). Estimated of genetic parameters suggest that the use of selection indices that include, besides PG, characters as prolificacy, FF and SG in the selection process under conditions of normal water supply, could lead to the development of cultivars with high grain yield and good drought tolerance

Genetic variation and environmental stability of grain mineral nutrient concentrations in Triticum dicoccoides under five environments

Nineteen wild emmer wheat [Triticum turgidum ssp. dicoccoides (Körn.) Thell.] genotypes were evaluated for the grain concentrations of phosphorous (P), potassium (K), sulfur (S), magnesium (Mg), calcium (Ca), zinc (Zn), manganese (Mn), iron (Fe) and cooper (Cu) under five different environments in Turkey and Israel. Each mineral nutrient has been investigated for the (1) genotype by environment (G × E) interactions, (2) genotype stability, (3) correlation among minerals and (4) mineral stability. Among the macronutrients analyzed, grain concentrations of Ca (range 338–2,034 mg kg−1) and S (range 0.18–0.43%) showed the largest variation. In the case of micronutrients, the largest variation was observed in the grain Mn concentration (range 13–87 mg kg−1). Grain concentrations of Fe and Zn also showed important variation (range 27–86 and 39–115 mg kg−1, respectively). Accessions with higher nutrient concentrations (especially Zn and Fe) had also greater grain weight, suggesting that higher grain Zn and Fe concentrations are not necessarily related to small grain size or weight. Analysis of variance showed that environment was the most important source of variation for K, S, Ca, Fe, Mn and Zn, explaining between 44 and 78% of the total variation and G × E explained between 20 and 40% of the total variation in all the minerals, except for S and Zn where its effect accounted for less than 16%. Genotype was the most important source of variation for Cu (explaining 38% of the total variation). However, genotype effect was also important for Mg, Mn, Zn and S. Sulfur and Zn showed the largest heritability values (77 and 72%, respectively). Iron exhibited low heritability and high ratio value between the G × E and genotype variance components , suggesting that specific adaptation for this mineral could be positively exploited. The wild emmer germplasm tested in the current study revealed some outstanding accessions (such as MM 5/4 and 24-39) in terms of grain Zn and Fe concentrations and environmental stability that can be used as potential donors to enhance grain micronutrient concentrations in wheats. Keywords Genotype × environment interaction - Grain quality - Micronutrients - Plant breeding - Mineral stability - Triticum turgidum ssp. dicoccoide