植物生态学报 ›› 2011, Vol. 35 ›› Issue (4): 431-440.DOI: 10.3724/SP.J.1258.2011.00431
收稿日期:
2010-08-27
接受日期:
2010-12-17
出版日期:
2011-08-27
发布日期:
2011-04-13
通讯作者:
朱艳
作者简介:
*E-mail: yanzhu@njau.edu.cn
CHEN Jie, TANG Liang, LIU Xiao-Jun, CAO Wei-Xing, ZHU Yan*()
Received:
2010-08-27
Accepted:
2010-12-17
Online:
2011-08-27
Published:
2011-04-13
Contact:
ZHU Yan
摘要:
通过解析水稻(Oryza sativa)植株碳素积累和转运的动态规律及其与环境因子和基因型之间的定量关系, 构建基于植株碳流动态的水稻籽粒淀粉积累模拟模型。水稻籽粒中的淀粉积累速率取决于库限制下的淀粉积累速率和源限制下的可获取碳源。库限制下的淀粉积累速率是潜在淀粉积累速率及温度、水分、氮素、淀粉合成能力等因子综合影响的结果; 源限制下的可获取碳源取决于花后光合器官生产的即时光合产物和营养器官向籽粒转运的储存光合产物。花后植株即时光合产物随花后生长度日呈对数递减。花后营养器官向籽粒转运的储存光合产物又分为叶片和茎中积累碳素的转运。利用不同栽培条件下的独立田间试验资料对籽粒淀粉积累的动态模型进行了检验, 结果显示籽粒淀粉积累量和含量的模拟值和观测值之间的根均方差均值分别为3.61%和4.51%, 决定系数分别为0.994和0.959, 表明该模型对不同栽培条件下的水稻单籽粒淀粉积累量和含量具有较好的预测性, 为水稻生产中籽粒淀粉指标的动态预测和管理调控提供了量化工具。
陈洁, 汤亮, 刘小军, 曹卫星, 朱艳. 基于植株碳流的水稻籽粒淀粉积累模拟模型. 植物生态学报, 2011, 35(4): 431-440. DOI: 10.3724/SP.J.1258.2011.00431
CHEN Jie, TANG Liang, LIU Xiao-Jun, CAO Wei-Xing, ZHU Yan. Modeling rice grain starch accumulation based on plant carbon flow. Chinese Journal of Plant Ecology, 2011, 35(4): 431-440. DOI: 10.3724/SP.J.1258.2011.00431
图2 叶片(A)和茎中(B)贮存的可溶性总糖向籽粒的转运量随花后生长度日的变化动态。
Fig. 2 Changes of remobilization of water soluble carbohydrate from leaves (A) and stems (B) to grain with growing degree days (GDD) after anthesis.
图3 花后叶片(A)和茎中(B)可溶性总糖相对含量随播种后累积生长度日的变化动态。
Fig. 3 Changes of relative water soluble carbohydrate content in leaves (A) and stems (B) with growing degree days (GDD) after sowing.
图4 籽粒可获取碳源(A)、可溶性总糖消耗量(B)和可溶性总糖积累量(C)随花后生长度日的变化动态。
Fig. 4 Changes of amount of carbon availability (A), consumption (B) and accumulation (C) of water soluble carbohydrate with growing degree days (GDD) after anthesis in grain.
图5 两个水稻品种(A)及不同生态点(B)与不同施氮水平(C)下单籽粒淀粉积累动态观测值和模拟值的比较。
Fig. 5 Comparison of simulated with measured single grain starch accumulation for two cultivars (A) under different eco-sites (B) and nitrogen rates (C).
图6 两个水稻品种(A)、不同生态区(B)与不同施氮水平(C)下单籽粒淀粉含量观测值和模拟值的比较。
Fig. 6 Comparison of simulated with measured single grain starch content for two cultivars (A) and under different eco-sites (B) and nitrogen rates (C).
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