山鸡椒水分及氮素利用效率性别特异性动态

doi:10.11707/j.1001-7488.20190407

摘要/Abstract

摘要： [目的]以雌雄异株山鸡椒为研究材料，分析雌雄植株在生殖生长过程中水分及氮素利用策略的性别特异性动态变化规律，以期为雌雄异株植物资源分配动态变化机制提供理论依据。[方法]测定雌雄植株在开花后105~165天共5个时期叶片养分含量（碳含量、氮含量、碳氮比）、稳定碳同位素组成（δ¹³C）、稳定氮同位素组成（δ¹⁵N），并分析其动态变化规律。[结果]1）雌雄株叶片δ¹³C平均值分别为-29.38‰和-28.08‰。性别和发育时期对雌雄株叶片δ¹³C值影响均显著，5个时期雌株δ¹³C值均显著低于雄株；且随发育进程雌雄植株δ¹³C值均不断下降。2）雌雄株叶片δ¹⁵N平均值分别为1.90‰和2.95‰。性别和发育时期对雌雄株叶片δ¹⁵N值均有极显著影响，开花后105~150天（即雌株果实中精油及柠檬醛含量快速积累期）雌株δ¹⁵N值显著低于雄株；随着发育进程，雌雄株叶片δ¹⁵N值均表现出双峰变化趋势，双峰出现在开花后105天和135天，雌株叶片δ¹⁵N在开花后120天达到最低值，雄株叶片在开花后165天时达到最低值。3）雌雄株叶片碳含量平均值分别为49.44%和49.28%。开花后105天和120天，雌株叶片C含量高于雄株叶片C含量，开花后135~165天（果实精油快速积累期到稳定期），雌株叶片C含量低于雄株。雄株叶片C含量随发育进程显著升高，而雌株叶片C含量在不同时期无显著差异。4）雌雄株叶片N含量平均值分别为1.71%和1.51%。性别对N含量影响显著，雄株叶片N含量均低于雌株（除开花后135天）。5）雌雄株叶片C/N平均值分别为29.15和33.72。性别对叶片碳氮比影响显著，雌株C/N值在不同发育时期均小于雄株，但发育时期对其无显著影响；随着发育时期推进，雄株C/N值下降程度高于雌株。6）雌雄植株叶片δ¹³C与N含量以及δ¹³C与δ¹⁵N之间均无显著相关性。[结论]山鸡椒雌雄植株在养分含量、水分及氮素利用策略存在差异，且在开花后105~165天表现出动态变化规律。雌株水分利用效率低于雄株，从果实精油及柠檬醛含量快速积累期到稳定期，雌株水分利用效率不断下降；雌株氮利用低于雄株，且随着植株发育，雌雄株叶片氮素利用效率均表现出双峰变化趋势；雄株叶片氮含量低于雌株，分配更多的氮素至花芽以保证花粉形成；果实精油快速积累期到稳定期，雌株叶片碳含量低于雄株，为果实及种子的形成提供更多的碳元素。

关键词: 雌雄异株, 山鸡椒, 水分利用效率, 氮素利用效率

Abstract: [Objective] In this study, dynamic patterns of sex-specific water and nitrogen use efficiencies in male and female plants of dioecious Litsea cubeba were analyzed. The result provides a theoretical basis for understanding of the dynamic changes of resource allocation of dioecious plants.[Method] The nutrient content (carbon and nitrogen content, the ratio of carbon and nitrogen (C/N)), water use efficiency, as inferred from leaf carbon isotope composition (δ¹³C), and nitrogen use, estimated by leaf nitrogen isotope composition (δ¹⁵N) were measured in male and female plants during 105 and 165 days after flowering (DAF).[Result] 1) The mean leaf δ¹³C values of female and male plants were -29.38‰ and -28.08‰. Leaf δ¹³C values of both male and female plants were significantly affected by sex and development period. Leaf δ¹³C values of the female plants were all lower than the male plants for the five periods. Leaf δ¹³C values of both male and female plants were constantly decreased during the development period. 2) The mean leaf δ¹⁵N values of the female and male plants were 1.90‰ and 2.95‰. Sex and development period also had significant effect on leaf δ¹⁵N values of male and female plants. Leaf δ¹⁵N values of the female plants were lower than the male plants from 105 to 150 DAF (rapid accumulation stage of oil and citral contents). δ¹⁵N values showed double peaks during 105 and 165 DAF, and the largest values were appeared at 105 and 135 DAF. Meanwhile, δ¹⁵N value of the female plant was lowest at 120 DAF, while the lowest value was appeared in the male plant at 165 DAF. 3) The mean leaf carbon contents of the female and male plants were 49.44% and 49.28% respectively. Leaf carbon contents were higher in the female plant than in the male plant at 105 and 120 DAF, while lower in the female plant than in the male plant from 135 DAF to 165 DAF (from accumulation stage to stable stage of oil content). The leaf carbon contents significantly increased with time in the male plant, but not significantly in the female in different periods. 4) The mean leaf nitrogen contents of the female and male plants were 1.71% and 1.51%. Sex had a significant effect on the leaf nitrogen content, and the leaf nitrogen contents of the male plants were lower than the female plants from 105 to 165 DAF (except for 135 DAF). 5) The mean leaf C/N of the female and male plants was 29.15 and 33.72. Sex had a significant effect on C/N, and the female plants had a lower C/N than the male plants, regardless of time. The decreased value of C/N was higher in the male plants than in the male plants from 135 to 165 DAF. 6) There were no correlations between δ¹³C and the nitrogen content and between δ¹³C and δ¹⁵N.[Conclusion] The sexes of the L. cubeba differ in terms of temporal patterns of water use efficiency and nitrogen use. The water use efficiency of female plant was lower than that of male plant, and constantly declined from rapid accumulation stage to stable stage of oil and citral contents. The nitrogen use efficiency of female plant was also lower than that of male plant, and the nitrogen use efficiency of female and male plants showed double peaks. The nitrogen content of male plant was lower than that of female plant, allocating more nitrogen to flower buds for pollen formation. The carbon content of female plant was lower than that of male plant from the rapid accumulation stage to stable stage of oil and citral contents, supplying more carbon for fruit and seed formation.

Key words: dioecy, Litsea cubeba, water use efficiency, nitrogen use efficiency

中图分类号:

S718.43

高暝, 陈益存, 吴立文, 汪阳东. 山鸡椒水分及氮素利用效率性别特异性动态[J]. 林业科学, 2019, 55(4): 62-68.

Gao Ming, Chen Yicun, Wu Liwen, Wang Yangdong. Dynamic Patterns of Sex-Specific Difference of Water and Nitrogen Use Efficiency in Litsea cubeba[J]. Scientia Silvae Sinicae, 2019, 55(4): 62-68.

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