Abstract
The mechanisms controlling the partitioning of seed composition constituents along the main stem in soybean are still controversial. Therefore, the objective of this study was to investigate seed protein, oil, and fatty acids partitioning in soybean cultivars along the main stem. The cultivars were DT97-4290, maturity group (MG) IV; Stressland, MG IV; Hutcheson, MG V; TracyM, MG VI. Seeds were harvested based on position on the plant (top nodes, middle nodes, and bottom nodes). At R8 (physiological maturity stage), DT97-4290, Hutcheson, and Stressland had higher percentage of protein and oleic acid and lower percentage of oil and linolenic acid in top node seed compared with bottom node seed. The increase of protein in top node compared with the bottom node across the two experiments ranged from 15.5 to 19.5%, 7.0 to 10.5%, 14.2 to 15.8%, 11.2 to 16.5%, respectively for DT97-4290, Hutcheson, Stressland, and TracyM. Except for TracyM, the increase of oleic acid in the top node ranged from 45.4 to 93%, depending on the cultivar. Conversely, the decrease in the top node seed ranged from 14.4 to 26.8% for oil and from 5.7 to 34.4% for linolenic acid, depending on the cultivar. The partitioning trend of seed composition constituents at R6 (seed - fill stage) was inconsistent. Except for Stressland, seed oleic acid was higher at R6 than at R8. The higher protein and oleic acid concentrations in the top node seed was accom- panied by higher activity of nitrate reductase activity, higher chlorophyll concentration, higher nitrogen (N) and sulfur (S) percentages in the fully expanded leaves at R5-R6 growth stage, and higher seed nitrogen (N) and sulfur (S) percentages in DT 97-4290 and Stressland. The current research suggests that the partitioning of seed protein, oil, and fatty acids in nodes along the plant depended on the position of node on the main stem, cultivar differences, seed N and S status, and tissue N and S partitioning. The higher nitrate reductase activity at the top nodes, accompanied higher protein and oleic acid, and the changes of oleic acid at R6 and R8 along the stem, were not previously reported, and need further investigation. The current knowledge is useful for soybean germplasm selection for desirable traits such protein and oleic acid, and for accurate measurements of seed composition constituents in breeding lines.
Highlights
Soybean seed is a source of protein and oil for human nutrition and a source of soybean meal for livestock feed
Since each experiment was conducted in a different greenhouse bay and in different years, it was expected that interactions between experiment (Exp) and other variables will be significantly (P ≤ 0.5) different for seed composition constituents
Our research showed that two cultivars (DT97-4290, indeterminate, and Hutcheson, determinate) had consistent trend in that protein and oleic acid percentage were higher and oil and linolenic acid percentage were lower in upper nodes (Top and middle third (Middle)) compared with those of lower nodes (Bottom)
Summary
Soybean seed is a source of protein and oil for human nutrition and a source of soybean meal for livestock feed. Soybean protein meal and soybean oil accounted for 69% and 30%, respectively in 2006 and 2007, of the world's supply of protein meal and edible oil [1]. Many international and domestic soybean processors prefer soybean with at least 340 g kg-1 protein and 190 g kg-1 oil, assuming 130 g kg-1 seed moisture [2]. Soybean seed quality is determined by the quantity and quality of protein and oil content (seed composition). Previous studies showed that soybean seed protein and oil qualities and quantities significantly vary as function of node position [3,4]. The source of this variability is not yet understood, and the literature about seed protein and oil partitioning along the main
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