分子生物学
IVD分子诊断
细胞培养与分析
蛋白研究
细胞因子
重组蛋白
抗体
高通量测序建库
病原检测UCF系列
生物医药
工具酶
抑制剂激活剂与常用试剂
仪器
耗材

Post-Heading High Nighttime Temperature Impairs Grain Protein-Starch Balance and Rice Quality Through Altering Nitrogen Metabolism

Zhechuan Liu, Shengming Xia, Yixiao Li, Hubo Li, Menghao Zhu, Huanran Yin, Zhenmei Wang, Jianguo Man, Dongliang Xiong, Kehui Cui, Jianliang Huang, Shaobing Peng, Shen Yuan, Fei Wang

Journal:PLANT CELL AND ENVIRONMENT

IF:6.9

DOI:10.1111/pce.70437

PMID:

Published:2026-02-15

research field:植物生理学籽粒品质研究分子生物学农业气候学作物科学

Abstract

High nighttime temperatures (HNT) tend to diminish rice quality by disrupting assimilate translocation and grain filling process in rice ( Oryza sativa L.). However, there is controversy remains regarding whether source or sink limitation are the primary driver under HNT during grain filling period. Additionally, the physiological mechanisms underlying the genotypic variation in the response of grain protein content to HNT and its effect on rice quality have been less explored. To address whether nitrogen remobilization from leaves to grains during grain filling determines genotypic differences in grain quality under high night temperature, two cultivars – HHZ (Huanghuazhan, an indica inbred line) and YY4949 (Yongyou4949, an indica - japonica hybrid) – were treated with 30/22°C (day/night, CK) and 30/27°C (HNT) over two consecutive years. Significant genotypic variation in the response of grain storage substances to HNT was observed between the two cultivars. Under HNT, YY4949 exhibited a significant increase in grain protein content and glutelin/prolamin ratio, and this shift negatively impacted rice eating and cooking quality. Notably, the protein/amylose ratio exhibited a stronger correlation with chalkiness degree and pasting characteristics of rice flour. Under HNT, accelerated nitrogen remobilization from leaves to grains in YY4949 – driven by enhanced chloroplast degradation and upregulated expression of nitrogen metabolism-related enzymes and transporters exacerbated source limitation to rice quality and disrupted the balance between starch and protein in grains. Collectively, these findings suggest that genetic modulation of nitrogen remobilization could facilitate the breeding of climate-resilient rice cultivars with superior grain quality.

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