‘凤丹’牡丹不同器官C、N、P和可溶性糖的季节性变化特征

doi:10.11707/j.1001-7488.20191206

林业科学 ›› 2019, Vol. 55 ›› Issue (12): 50-60.doi: 10.11707/j.1001-7488.20191206

‘凤丹’牡丹不同器官C、N、P和可溶性糖的季节性变化特征

汪成忠^1,^2,³,倪雪艳¹,朱玮¹,马菡泽²,钱剑林¹,杨继²,胡永红³,宋志平^2,*

1. 苏州农业职业技术学院苏州 215008
2. 复旦大学生物多样性研究所上海 200438
3. 上海辰山植物园中国科学院上海辰山植物科学研究中心上海市资源植物功能基因组学重点实验室上海 201602

收稿日期:2018-12-14 出版日期:2019-12-25 发布日期:2020-01-02
通讯作者: 宋志平
基金资助:
江苏现代农业产业技术体系建设专项资金(JATS[2018]232);江苏现代农业产业技术体系建设专项资金(JATS[2018]235);上海市资源植物功能基因组学重点实验室开放课题(PFGR201803);江苏省高等学校自然科学研究项目(18KJB220011);苏州市科技局项目(SNG2018052);上海市绿化与市容管理局重点攻关项目(G182407);上海市科学技术委员会创新行动计划(14JC1403902);江苏省高等学校大学生创新创业训练计划项目(201812808011Y)

Seasonal Changes of Carbon, Nitrogen, Phosphorus and Soluble Sugar Concentrations in Plant of 'Fengdan' (Paeonia ostii) Chronosequence

Chengzhong Wang^1,^2,³,Xueyan Ni¹,Wei Zhu¹,Hanze Ma²,Jianlin Qian¹,Ji Yang²,Yonghong Hu³,Zhiping Song^2,*

1. Suzhou Polytechnic Institute of Agriculture Suzhou 215008
2. Institute of Biodiversity Sciences, Fudan University Shanghai 200438
3. Shanghai Chenshan Botanical Garden Shanghai Chenshan Plant Science Research Center, CAS Shanghai Key Laboratory of Plant Functional Genomics and Resources Shanghai 201602

Received:2018-12-14 Online:2019-12-25 Published:2020-01-02
Contact: Zhiping Song
Supported by:
江苏现代农业产业技术体系建设专项资金(JATS[2018]232);江苏现代农业产业技术体系建设专项资金(JATS[2018]235);上海市资源植物功能基因组学重点实验室开放课题(PFGR201803);江苏省高等学校自然科学研究项目(18KJB220011);苏州市科技局项目(SNG2018052);上海市绿化与市容管理局重点攻关项目(G182407);上海市科学技术委员会创新行动计划(14JC1403902);江苏省高等学校大学生创新创业训练计划项目(201812808011Y)

摘要/Abstract

摘要：

目的: 明确‘凤丹’牡丹不同发育阶段的化学计量特征和分配规律，探讨源-库关系，可为解析其产量构成机制奠定基础，也为油用牡丹的栽培管理提供指导。方法: 采取破坏性取样策略，研究‘凤丹’牡丹年周期中，4、6、8龄（4年生、6年生、8年生）植株的根、茎、叶、花、果等器官中C、N、P元素和可溶性糖含量的变化动态。结果: 1）各器官中C含量的季节性变化趋势相似，且C含量随株龄增大而增高；根和茎中N含量随季节变化的趋势相似，都随株龄增大而上升，不同株龄植株的叶片的N含量变化趋势一致，均在花期最高；P元素含量及其变化在各器官及不同株龄之间存在差异。2）年周期中各器官的C:N均表现为先升后降，株龄效应明显；C:P在各器官中变化趋势不一，根和茎的C:P表现为6年生> 8年生> 4年生，不同株龄叶片的C:P仅在花期不同（4年生< 6年生< 8年生），繁殖器官的C:P表现为4年生< 6年生< 8年生；年周期中，‘凤丹’N:P逐渐下降，各器官的N:P均表现为6年生> 4年生> 8年生，N:P变化范围为2.71~7.62。3）在休眠期和落叶期，各元素基本上都平均分配到根和茎中，在花期和果熟期，C元素均匀分配到各器官，而N、P元素则较多分配到叶和繁殖器官，株龄对各元素分配动态的影响不一致。4）各器官可溶性糖含量差异明显。以可溶性糖含量表征的源、库强度及源/库比的分析结果显示，初始（休眠期）源结构为根和茎，之后（花果期）的源结构是叶片，库结构则包括花或果实、以及根和茎；6年生植株的源强度最大，8年生植株则库强度最大，花期源/库比最高的是6年生植株，果熟期则是4年生植株。结论: ‘凤丹’牡丹的化学计量特征和源-库结构关系随生长发育阶段而动态变化，且明显受株龄的影响；N元素是‘凤丹’牡丹生长的限制因子，适当增施N肥可提高产量。

关键词: ‘凤丹’牡丹, 化学计量特征, 株龄效应, 源-库关系

Abstract:

Objectve: 'Fengdan'(Paeonia ostii) is a new woody oil crop. It is not clear about the carbon, nitrogen, and phosphorus stoichiometry and source-sink structure in this plant species. This study compared the seasonal variations of C, N, P, and soluble sugar concentrations and allocations, as well as the ratios of C:N, C:P and N:P in different organs of 'Fengdan' in an annual cycle at different stages of development, in order to lay a foundation for the analysis of its yield composition and provide a guidance for the cultivation and management of oil peony. Method: A destructive strategy was applied to sample roots, stems, leaves, flowers and fruits of 4-, 6-, and 8-year-old plants from Tongling peony garden in Anhui Province at the stage of bud dormancy, flowering, fruit mature, and defoliation. The dynamic changes of C, N, P and soluble sugar concentrations in those samples were measured, and then the allocation and stoichiometry dynamics were analyzed. Result: The results showed that:1) all organs had a similar seasonal dynamics of C content, and it increased with tree age. N content in roots and stems had a similar seasonal variation, and it also increased with tree age. Whereas N contents in leaves of different plant ages had a similar changing trend, and it reached the highest values at flowering stage. There were differences in P concentrations in both different organs and different plant ages. 2) The C:N ratio in all Fengdan organs increased first and then decreased in the annual cycle, which was significantly influenced by tree age. The change trend of C:P ratio over seasons in all organs was different. The C:P ratio in roots and stems was 6 a > 8 a > 4 a. The C:P ratio in leaves presented difference only at flowering stage, with 4 a < 6 a < 8 a. The C:P ratio of reproductive organs was 6 a > 8 a > 4 a. In the annual cycle, the N:P ratio of 'Fengdan' decreased gradually. The N:P ratio in all organs ranged from 2.71 to 7.62, and was 6 a > 4 a > 8 a. 3) At dormancy and defoliation stages, C, N, and P were all equally allocated to root and stem. At flowering and fruit mature stages, C was evenly portioned to each organ, whereas N and P were relatively more distributed in leaves and reproductive organs. The effects of plant age on the element allocations were different among C, N and P. 4) There was significantly difference in soluble sugar concentration among different organs. Soluble sugar concentration in source or sink structure was used to indirectly express the source or sink strength, and then to estimate the ratio of source:sink. At the beginning of annual cycle (at dormancy stage), the source structure was root and stem, and it was leaf at flowering and fruiting stages when reproductive organs (flower or fruits) were the main sink structure. At the same time the sink structure included root and stem, as well as flower and fruit. Six-year-old plants had the biggest source strength and eight-year-old plants had the biggest sink strength. Six-year-old plants had the highest source:sink ratio at flowering stage, whereas 4-year-old plants had the highest source:sink ratio at fruiting stage. Conclusion: Stoichiometry and source-sink structure of 'Fengdan' varied with plant development and growth stages, and were influenced by tree age. N was a limiting factor for plant growth in 'Fengdan', and appropriate addition of N was able to increase seed yield of oil peony.

Key words: Paeonia ostii, stoichiometric characteristics, plant age effect, source-sink

中图分类号:

S718.43

汪成忠,倪雪艳,朱玮,马菡泽,钱剑林,杨继,胡永红,宋志平. ‘凤丹’牡丹不同器官C、N、P和可溶性糖的季节性变化特征[J]. 林业科学, 2019, 55(12): 50-60.

Chengzhong Wang,Xueyan Ni,Wei Zhu,Hanze Ma,Jianlin Qian,Ji Yang,Yonghong Hu,Zhiping Song. Seasonal Changes of Carbon, Nitrogen, Phosphorus and Soluble Sugar Concentrations in Plant of 'Fengdan' (Paeonia ostii) Chronosequence[J]. Scientia Silvae Sinicae, 2019, 55(12): 50-60.

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植物器官 Plant part	化学计量 Stoichiometry	株龄 Tree age		发育时期 Developmental stage		株龄×发育时期 Tree age × Developmental stage
植物器官 Plant part	化学计量 Stoichiometry	df	F	df	F	df	F
	N	2	578.530^**	3	687.867^**	6	64.477^**
	P	2	276.500^**	3	65.333^**	6	58.500^**
	C	2	102.606^**	3	737.705^**	6	395.384^**
根Root	C:N	2	935.237^**	3	1 278.905^**	6	160.236^**
	C:P	2	886.563^**	3	819.973^**	6	299.768^**
	N:P	2	343.935^**	3	205.603^**	6	104.091^**
	可溶性糖Soluble sugar	2	9.354^**	3	321.732^**	6	49.557^**
	N	2	389.019^**	3	215.458^**	6	55.852^**
	P	2	714.143^**	3	260.714^**	6	89.000^**
	C	2	184.768^**	3	1 800.528^**	6	551.178^**
茎Stem	C:N	2	558.103^**	3	362.253^**	6	64.639^**
	C:P	2	1 216.23^**	3	887.780^**	6	338.036^**
	N:P	2	137.992^**	3	38.179^**	6	35.453^**
	可溶性糖Soluble sugar	2	187.619^**	3	63.094^**	6	62.862^**
	N	2	10.084^**	3	3 786.282^**	6	51.097^**
	P	2	151.400^**	3	4 417.400^**	6	77.000^**
	C	2	1 350.301^**	3	6 741.789^**	6	1 696.343^**
叶Leaf	C:N	2	9.475^**	3	509.981^**	6	60.015^**
	C:P	2	71.905^**	3	2 064.264^**	6	243.142^**
	N:P	2	37.024^**	3	22.774^**	6	25.112^**
	可溶性糖Soluble sugar	2	30.243^**	3	141.152^**	6	41.425^**

发育时期 Developmental stage	指标 Index	株龄Tree age
发育时期 Developmental stage	指标 Index	df	F	P
	源强度Source strength	2	1 075.779	0.000
花期Flowering	库强度Sink strength	2	129.208	0.000
	源库比Source-sink ratio	2	179.152	0.000
	源强度Source strength	2	992.354	0.000
果熟期Fruit mature	库强度Sink strength	2	56.641	0.000
	源库比Source-sink ratio	2	97.380	0.000

株龄 Tree age	源强度 Source strength		库强度 Sink strength		源库比 Source-sink ratio
株龄 Tree age	花期Flowering	果熟期Fruit mature	花期Flowering	果熟期Fruit mature	花期Flowering	果熟期Fruit mature
4 a	2.06±0.03c	30.35±0.66b	0.30±0.01b	0.61±0.04c	6.89±0.19b	51.64±2.88a
6 a	4.22±0.05a	43.43±0.33a	0.21±0.01c	1.21±0.07b	20.21±1.01a	37.06±2.14b
8 a	3.28±0.02b	16.20±0.10c	0.62±0.03a	1.54±0.08a	5.42±0.24b	10.79±0.57c

‘凤丹’牡丹不同器官C、N、P和可溶性糖的季节性变化特征

Seasonal Changes of Carbon, Nitrogen, Phosphorus and Soluble Sugar Concentrations in Plant of 'Fengdan' (Paeonia ostii) Chronosequence

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