Abstract
Since genetic improvement greatly promoted an increased yield japonica inbred rice in east China after the 1990s, better root characteristics were certainly expected. In 2018 and 2019, nine japonica inbred rice released in the 1990s, 2000s, and 2010s were investigated to evaluate the changes in root morpho-physiology and identify root traits that contributed to the positive yield trends during the genetic process. The 2010’s rice had 8.0 and 4.3% higher grain yield than the 1990’s and the 2000’s rice, respectively (p < 0.05). Genetic yield gain was mainly attributed to the increased spikelets per panicle. Compared with the 1990’s and the 2000’s rice, the 2010’s rice had higher shoot biomass at heading and maturity (p < 0.05), as well as root biomass (p < 0.05), especially for root biomass of 15–30 cm soil depth. Leaf area index (LAI), soil-plant analysis development (SPAD) values, and leaf photosynthetic rate at middle grain-filling period (MGP) and late grain-filling period (LGP) were all increased. The 2010’s rice had consistently higher root length and volume, root oxidation activity, and root bleeding rate at MGP and LGP than the 1990’s and the 2000’s rice (p < 0.05). Positive correlations were detected between root length and volume, root oxidation activity, and root bleeding rate at MGP, LGP, and SPAD values, leaf photosynthetic rate at MGP and LGP, and higher shoot biomass accumulation after heading and grain yield (p < 0.05 or p < 0.01). The present study implied that genetic improvement optimized post-heading root morphology and physiology, which maintained shoot stay-green and facilitated biomass accumulation and yield increase in japonica inbred rice during the genetic process since the 1990s.
Highlights
Rice is a staple grain crop worldwide, increasing rice production is a major strategy for ensuring food security [1]
Genetic improvement is recognized as a key driver in improving rice yield [2]
The increasing grain yield during genetic improvement was associated with enlarged sink potential through spikelets per panicle [6], increased total biomass, and/or harvest index [4,7], better leaf stay-green and more erect plant canopy [8,9], and optimized source-sink balance [10]
Summary
Rice is a staple grain crop worldwide, increasing rice production is a major strategy for ensuring food security [1]. The increasing grain yield during genetic improvement was associated with enlarged sink potential through spikelets per panicle [6], increased total biomass, and/or harvest index [4,7], better leaf stay-green and more erect plant canopy [8,9], and optimized source-sink balance [10]. Such above studies focused mainly on the shoot traits that contributed directly to progressive yield gain during the genetic improvement
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