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林业科学 ›› 2019, Vol. 55 ›› Issue (5): 55-64.doi: 10.11707/j.1001-7488.20190507

• 论文与研究报告 • 上一篇    下一篇

楸树种间和种内杂种生长与光合系统氮素利用及分配的差异分析

肖遥1, 易飞1, 韩东花1, 卢楠1, 杨桂娟1, 赵鲲2, 王军辉1, 麻文俊1   

  1. 1. 中国林业科学研究院林业研究所 林木遗传育种国家重点实验室 国家林业和草原局林木培育重点实验室 国家林木种质资源平台 北京 100091;
    2. 河南省洛阳市农林科学院 洛阳 471002
  • 收稿日期:2018-10-11 修回日期:2019-01-02 出版日期:2019-05-25 发布日期:2019-05-20
  • 基金资助:
    "十三五"国家重点研发计划课题"楸树良种选育与高效培育技术研究"(2017YFD0600604)。

Difference Analysis of Growth and Nitrogen Utilization and Distribution in Photosynthetic System of Catalpa bungei Intraspecific and Interspecific Hybrids

Xiao Yao1, Yi Fei1, Han Donghua1, Lu Nan1, Yang Guijuan1, Zhao Kun2, Wang Junhui1, Ma Wenjun1   

  1. 1. State Key Laboratory of Tree Genetics and Breeding Key Laboratory of Tree Breeding and Cultivation of National Forestry and Grassland Administration National Forest Genetic Resource Platform Research Institute of Forestry, Chinese Academy of Forestry Beijing 100091;
    2. Luoyang Academy of Agriculture and Forestry Sciences, Henan Province Luoyang 471002
  • Received:2018-10-11 Revised:2019-01-02 Online:2019-05-25 Published:2019-05-20

摘要: [目的]采用课题组早期创制的楸树种内杂种和种间杂种为试验材料,比较杂种间多年的生长性状及光合生理生化特性。旨在明晰楸树种间和种内杂种的生长及光合能力差异及其原因,探究杂种叶片氮素利用及分配与光合效率的潜在关系,为楸树栽培及遗传改良提供参考。[方法]试验采用完全随机区组设计,测定种内杂种(楸树×楸树,Cbb)和种间杂种(楸树×滇楸,Cbf)1~5年树高和1~6年胸径及6年生时的叶片氮素含量、叶绿素含量、光响应曲线和CO2响应曲线。采用非直角双曲线模型拟合光响应曲线,FvCB生化模型(Farquhar、von Caemmerer和Berry提出的生物化学光合模型)拟合CO2响应曲线,分别计算了表观光合量子效率(AQY)、光补偿点(LCP)等气体交换参数及最大羧化效率(Vc max)、最大电子传递速率(Jmax)等光合生理生化参数。并计算出光合系统(捕光系统,羧化系统和生物力能学组分)氮素分配比例。[结果]方差分析显示2年生以上的种内杂种Cbb树高和胸径均显著大于种间杂种Cbf。种间与种内杂种间叶绿素总量没有显著差异,但Cbf叶绿素b显著高出Cbb 15.08%,Cbb的叶绿素a/b和类胡萝卜素/叶绿素总量比值均显著大于Cbf。Cbb具有更高的最大净光合速率、气孔导度、最大羧化效率和暗呼吸速率,表明了Cbb具有更强的光合能力。种间与种内杂种间叶片氮素含量没有显著差异,但Cbb光系统氮素分配比例相对较高,同时具有更高的光合氮素利用效率,这可能是其高光合效率的主要因素之一。相关分析表明楸树杂种光合氮素利用效率与氮素在羧化系统及生物力能学组分中的分配比例呈显著正相关;种内杂种Cbb光合氮素利用效率与其胸径具有较好的(R2=0.531)正向线性关系。[结论]1)楸树种内杂种(楸树×楸树)对本地环境(中原地区)具有更强的适应性,致使其生长势显著优于种间杂种(楸树×滇楸);2)相对于云贵高原,中原地区更长的日照时间和更高的7月均温可能促使了楸树×楸树形成适应高光合辐射环境的响应机制(高水平Chl a/b和Car/Chl a+b);3)楸树×楸树光合系统更高的N分配比例及高效的N素利用效率提高了其光合能力;4)楸树种间杂种中滇楸所传递给子代的遗传物质不具有适应中原地区环境的调控机制,这是楸树×滇楸在生长和光合生理方面均劣于楸树×楸树的主要原因。

关键词: 楸树, 滇楸, 杂种, 氮素分配, 光合作用

Abstract: [Objective] This study aims to clarify the differences in growth and photosynthetic capacity of intraspecific and interspecific hybrids of Catalpa, and to explore the potential relationship between growth and photosynthetic capacity which is regulated by nitrogen use and distribution in leaves, and to provide favorable basis for Catalpa cultivation and genetic improvement.[Method] The experiment was designed with complete random block design, the height of 1-5 years old trees and DBH of 1-6 years old trees of the Catalpa bungei×C. bungei and C. bungei×C. fargesii f. duclouxii hybrids, and leaf nitrogen content, chlorophyll content, light response curve and CO2 response curve of the Catalpa hybrids in 6 years old were measured. The non-orthogonal hyperbolic model was used to fit the light response curve to calculate the gas exchange parameters, such as the apparent quantum yield (AQY) and the light compensation point (LCP). The FvCB biochemical model (The biochemical photosynthetic model proposed by Farquhar, von Caemmerer and Berry) was used to fit to the CO2 response curve, and the maximum carboxylation efficiency (Vc max), maximum electron transfer rate (Jmax) and other photosynthetic biochemical parameters were estimated via the model. Nitrogen allocation ratio in photosynthetic system, include light-harvesting system, carboxylation system and bio-energy component, were calculated.[Result] Analysis of variance showed that tree height and DBH of intraspecific hybrids (C. bungei×C. bungei) were significantly greater than interspecific hybrids (C. bungei×C. fargesii f. duclouxii) after 2 years. There was no significant difference between the two hybrids in the total amount of chlorophyll. But the content of chlorophyll b of interspecific hybrids was significantly higher (15.08%) than intraspecific hybrids. On the other hand, the chlorophyll a/b and carotenoid/chlorophyll a+b of intraspecific hybrids was significantly higher than interspecific hybrids. The photosynthetic parameters showed that the intraspecific hybrid had a greater maximum net photosynthetic rate, stomatal conductance, maximum carboxylation efficiency and dark respiration rate. It showed that they had stronger photosynthetic capacity. There was no significant difference in leaf nitrogen content between the two hybrid types. However, more nitrogen was invested to photosystem for intraspecific hybrid leading to higher photosynthetic nitrogen utilization efficiency (PNUE). And it may be one of the reasons of high photosynthetic efficiency for intraspecific hybrid. Correlation analysis showed that the PNUE of Catalpa hybrids was significantly positively correlated with the nitrogen allocation in the carboxylation system and bioenergetics. In addition, the PNUE of intraspecific hybrid had a greater (R2=0.531) positive linear relationship with the diameter at breast height (DBH).[Conclusion] 1) Intraspecific hybrids have a stronger adaptability to the local environment (The central plains), it was the reason that growth of Catalpa bungei×C. bungei was significantly better than interspecific hybrid (C. bungei×C. fargesii f. duclouxii). 2) Compared with Yunnan-Guizhou plateau, the longer sunshine duration and higher mean temperature in July in the central plains may be the reason for the formation of a response mechanism (high level Chl a/b and Car/Chl a+b) for intraspecific hybrid to adapt to the high photosynthetic radiation environment. 3) Higher N distribution ratio and N use efficiency in photosynthetic system of C. bungei×C. bungei improved its photosynthetic ability. 4) The genetic material transmitted to the offspring by C. fargesii f. duclouxii did not have the regulatory mechanism to adapt to the environment in the central plains, this is the main reason why the growth and photosynthetic physiology of interspecific hybrids are inferior to that of intraspecific hybrids in the central plains.

Key words: Catalpa bungei, Catalpa fargesii f. duclouxii, hybrids, nitrogen allocation, photosynthesis

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