Frontiers in Plant Science (Sep 2016)

Genotypic variation in grain P loading across diverse rice growing environments and implications for field P balances

  • Elke Vandamme,
  • Matthias Wissuwa,
  • Terry Rose,
  • Terry Rose,
  • Ibnou Dieng,
  • Khady Nani Drame,
  • Mamadou Fofana,
  • Kalimuthu Senthilkumar,
  • Ramaiah Venuprasad,
  • Demba Jallow,
  • Zacharie Segda,
  • Lalith Suriyagoda,
  • Dinarathna Sirisena,
  • Yoichiro Kato,
  • Kazuki Saito

DOI
https://doi.org/10.3389/fpls.2016.01435
Journal volume & issue
Vol. 7

Abstract

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More than 60% of phosphorus (P) taken up by rice (Oryza spp) is accumulated in the grains at harvest and hence exported from fields, leading to a continuous removal of P. If P removed from fields is not replaced by P inputs then soil P stocks decline, with consequences for subsequent crops. Breeding rice genotypes with a low concentration of P in the grains could be a strategy to reduce maintenance fertilizer needs and slow soil P depletion in low input systems. This study aimed to assess variation in grain P concentrations among rice genotypes across diverse environments and evaluate the implications for field P balances at various grain yield levels. Multi-location screening experiments were conducted at different sites across Africa and Asia and yield components and grain P concentrations were determined at harvest. Genotypic variation in grain P concentration was evaluated while considering differences in P supply and grain yield using cluster analysis to group environments and boundary line analysis to determine minimum grain P concentrations at various yield levels. Average grain P concentrations across genotypes varied almost 3-fold among environments, from 1.4 to 3.9 mg g-1. Minimum grain P concentrations associated with grain yields of 150, 300 and 500 g m-2 varied between 1.2 and 1.7, 1.3 and 1.8 and 1.7 and 2.2 mg g-1 among genotypes respectively. Two genotypes, Santhi Sufaid and DJ123, were identified as potential donors for low grain P concentration. Improvements in P balances that could be achieved by exploiting this genotypic variation are in the range of less than 0.10 g P m-2 (1 kg P ha-1) in low yielding systems, and 0.15 to 0.50 g P m-2 (1.5-5.0 kg P ha-1) in higher yielding systems. Improved crop management and alternative breeding approaches may be required to achieve larger reductions in grain P concentrations in rice.

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