Abstract
Increasing pea (Pisum sativum) seed nutritional value and particularly seed protein content, while maintaining yield, is an important challenge for further development of this crop. Seed protein content and yield are complex and unstable traits, integrating all the processes occurring during the plant life cycle. During filling, seeds are the main sink to which assimilates are preferentially allocated at the expense of vegetative organs. Nitrogen seed demand is satisfied partly by nitrogen acquired by the roots, but also by nitrogen remobilized from vegetative organs. In this study, we evaluated the respective roles of nitrogen source capacity and sink strength in the genetic variability of seed protein content and yield. We showed in eight genotypes of diverse origins that both the maximal rate of nitrogen accumulation in the seeds and nitrogen source capacity varied among genotypes. Then, to identify the genetic factors responsible for seed protein content and yield variation, we searched for quantitative trait loci (QTL) for seed traits and for indicators of sink strength and source nitrogen capacity. We detected 261 QTL across five environments for all traits measured. Most QTL for seed and plant traits mapped in clusters, raising the possibility of common underlying processes and candidate genes. In most environments, the genes Le and Afila, which control internode length and the switch between leaflets and tendrils, respectively, determined plant nitrogen status. Depending on the environment, these genes were linked to QTL of seed protein content and yield, suggesting that source-sink adjustments depend on growing conditions.
Highlights
Increasing pea (Pisum sativum) seed nutritional value and seed protein content, while maintaining yield, is an important challenge for further development of this crop
By maximizing the flux of assimilate to seeds at the beginning of seed filling (BSF) through depodding experiments in which only the pods on the secondflowering node were left to develop on the plant, we determined the potential seed size and protein content of eight genotypes (‘Ballet’, ‘Cameor’, ‘Terese’, ‘Sommette’, ‘Athos’, VavD265, K586, and China)
In the mapping population RECOMBINANT INBRED LINE1 (RIL1) (Fig. 4), this relationship differentiated lines according to le and af, indicating that Le/af lines may encounter suboptimal nitrogen status as compared to their le/Af counterparts. Both Le and af were associated with reduced NNI and Kof et al (2006) observed a reduction of root weight in af near-isogenic lines (NILs). These results suggest that genes such as af or le, which affect the development of aerial vegetative organs, may induce root modifications
Summary
Increasing pea (Pisum sativum) seed nutritional value and seed protein content, while maintaining yield, is an important challenge for further development of this crop. To identify the genetic factors responsible for seed protein content and yield variation, we searched for quantitative trait loci (QTL) for seed traits and for indicators of sink strength and source nitrogen capacity. These genes were linked to QTL of seed protein content and yield, suggesting that source-sink adjustments depend on growing conditions. Nitrogen acquisition relies both on symbiotic fixation of atmospheric nitrogen in root nodules and on soil nitrate assimilation by roots The contribution of these two pathways to the global nitrogen nutrition of the plant varies according to the genotype and the environment. Seed protein content depends, on one hand, on nitrogen availability during seed filling and, on the other hand, on the embryo’s intrinsic capacity to accumulate storage compounds, as exemplified by wrinkled seed peas. The shape of the seed is wrinkled, starch accumulation is reduced, and seed protein content is elevated
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