自然高温干旱下7个香椿无性系的叶片解剖结构及叶绿素荧光特性比较

doi:10.11924/j.issn.1000-6850.casb2023-0229

中国农学通报 ›› 2024, Vol. 40 ›› Issue (10): 17-28.doi: 10.11924/j.issn.1000-6850.casb2023-0229

所属专题：园艺

自然高温干旱下7个香椿无性系的叶片解剖结构及叶绿素荧光特性比较

闫彩霞¹(), 苗婷婷¹, 刘俊龙¹(), 吴中能¹, 麻文俊², 曹志华¹, 孙慧¹

¹ 安徽省林业科学研究院，合肥 230088
² 中国林业科学研究院林业研究所，北京 100091

收稿日期:2023-03-21 修回日期:2024-01-15 出版日期:2024-04-05 发布日期:2024-04-01
通讯作者:
刘俊龙，男，1981年出生，安徽阜阳人，副研究员，硕士，主要从事用材林及竹类研究。通信地址：230088 安徽省合肥市蜀山区黄山路618-1号安徽省林业科学研究院，Tel：0551-62631176，E-mail：58161450@qq.com。
作者简介:
闫彩霞，女，1989年出生，河南濮阳人，研实员，硕士，研究方向：森林培育。通信地址：230088 安徽省合肥市蜀山区黄山路618-1号安徽省林业科学研究院，Tel：0551-62631176，E-mail：954916397@qq.com。
基金资助:
“十四五”国家重点研发计划子课题“香椿新品种选育”(2021YFD2200305-3); 2024年安徽省主要经济树种高效培育技术研究

Comparison of Leaf Anatomical Structure and Chlorophyll Fluorescence Characteristics of 7 Toona sinensis Clones Under Natural High Temperature and Drought

YAN Caixia¹(), MIAO Tingting¹, LIU Junlong¹(), WU Zhongneng¹, MA Wenjun², CAO Zhihua¹, SUN Hui¹

¹ Anhui Academy of Forestry, Hefei 230088
² Forestry Research Institute, Chinese Academy of Forestry, Beijing 100091

Received:2023-03-21 Revised:2024-01-15 Published:2024-04-05 Online:2024-04-01

摘要/Abstract

摘要：

揭示不同香椿无性系在自然高温干旱胁迫下的叶片解剖特征和光合生理响应机制，为香椿栽培和种质资源利用提供参考。以‘XC34-2’、‘XC12-10’、‘XC9-9’、‘XC18-4’、‘XC6-6’等5个香椿无性系2年生截干苗为研究对象，以‘黑油椿’、‘红油椿’2个乡土品种为对照，测定自然高温干旱胁迫下香椿叶片解剖结构、叶绿素含量、叶绿素荧光参数特征，采用单因素方差分析比较所有指标在无性系间的差异。结果表明，5个无性系的中脉比‘黑油椿’、‘红油椿’薄，除海绵组织外，其他各项解剖结构均比‘黑油椿’、‘红油椿’厚，其中‘XC18-4’的叶片最厚，栅栏组织和海绵组织最发达，角质层最厚的‘XC34-2’(2.01 μm)是角质层最薄的‘红油椿’的1.63倍。7个无性系在相同的干热环境中受到的光抑制程度存在极显著差异，Fv/Fm为0.67~0.79。高温干旱胁迫影响香椿无性系PS Ⅱ吸收的激发能的能量分配，‘XC34-2’的Y(Ⅱ)更高，Y(NO)、Y(NPQ)均较低，‘红油椿’大致与之相反。此外，不同的无性系在高温干旱环境中采取了不同的光保护策略，‘XC9-9’和‘XC18-4’的过剩激发能主要由关闭态的PS Ⅱ反应中心贡献，同时过剩的激发能量转向调节性能量耗散以Y(NPQ)为主，而‘红油椿’和‘XC6-6’的非调节性能量耗散Y(NO)在未做功的能量中起到同等重要的作用。根据主成分分析筛选出角质层厚度、叶绿素a与叶绿素b的比、最大光化学量子产量和栅栏组织厚度4个典型指标。平均隶属函数结果显示，5个无性系的耐高温干旱能力均强于2个乡土品种，其中，‘XC18-4’具有较强的抵御干热灼伤、水分调节以及光能吸收、转化和利用能力，隶属函数平均分最高(0.929)，根据5级评分法划分为高抗无性系；‘XC34-2’(0.742)次之，属于抗高温干旱无性系，‘红油椿’(0.219)最差，为干热较敏感型无性系。

关键词: 香椿, 自然高温干旱, 解剖结构, 叶绿素, 叶绿素荧光

Abstract:

The research was conducted to reveal the leaf anatomical structure characteristics and photosynthetic physiological response mechanism of different Toona sinensis clones under natural high temperature and drought stress, and provide reference for T. sinensis cultivation and germplasm resource utilization. Using 5 2-year-old T. sinensis clones seedling as the research objects, including ‘XC34-2’、‘XC12-10’、‘XC9-9’、‘XC18-4’、‘XC6-6’, and 2 native varieties as reference, including ‘Black oil toona’ and ‘Red oil toona’. Leaf anatomical structure, chlorophyll contents and chlorophyll fluorescence parameters characteristics under high temperature and drought stress were measured, the single factor analysis of variance were used to compare the differences between all indexes among the clones. The results showed that the middle vein of the five clones were thinner than those of ‘Black oil toona’ and ‘Red oil toona’, and other anatomical structures were thicker than those of ‘Black oil toona’ and ‘Red oil toona’, except for the spongy tissue, among which ‘XC18-4’ had the thickest leaves and the most developed palisade tissue and spongy tissue. The thickest cuticle (2.01 μm) of ‘XC34-2’ was 1.63 times that of the thinnest cuticle of ‘Red oil toona’. Seven clones subjected to the extremely different degree of photoinhibition in the same dry and hot environment, with Fv/Fm varying from 0.67 to 0.79. High temperature and drought stress affected the distribution of excitation energy absorbed by PS Ⅱ in T. sinensis clones. ‘XC34-2’ had higher Y(Ⅱ) and lower Y(NO) and Y(NPQ), and ‘Red oil toona’ was roughly the opposite. In addition, different clones took different photoprotection strategies under high temperature and drought. The excess excitation energy in ‘XC9-9’ and ‘XC18-4’ was mainly contributed by the closed PSⅡ reaction center, and the excess excitation energy shifted to regulatory energy dissipation [Y(NPQ)], while the non-regulatory energy dissipation [Y(NO)] in ‘Red oil toona’ and ‘XC6-6’ played an equally important role in the unworked energy. Four typical indicators were screened by principal component analysis, including cuticle thickness, chlorophyll a/b ratio, maximum photochemical quantum yield and palisade tissue thickness. According to the results of the average subordination function scores, the high temperature and drought tolerance of 5 T. sinensis clones was stronger than that of the two native varieties. With strong capable of dry-hot burn resistance, water regulation and absorption, transformation and utilization of light energy, ‘XC18-4’ got the highest average score of subordination function (0.929), and was classified as high resistance clone according to the 5-level scoring method, followed by ‘XC34-2’ (0.747), belonging to a resistance clone under hot and drought stress. ‘Red oil toona’ (0.219) was more sensitive to high temperature and drought stress.

Key words: Toona sinensis, natural high temperature and drought, anatomical structure, chlorophyll, fluorescence of chlorophyll

闫彩霞, 苗婷婷, 刘俊龙, 吴中能, 麻文俊, 曹志华, 孙慧. 自然高温干旱下7个香椿无性系的叶片解剖结构及叶绿素荧光特性比较[J]. 中国农学通报, 2024, 40(10): 17-28.

YAN Caixia, MIAO Tingting, LIU Junlong, WU Zhongneng, MA Wenjun, CAO Zhihua, SUN Hui. Comparison of Leaf Anatomical Structure and Chlorophyll Fluorescence Characteristics of 7 Toona sinensis Clones Under Natural High Temperature and Drought[J]. Chinese Agricultural Science Bulletin, 2024, 40(10): 17-28.

图/表 16

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无性系	叶片厚度/μm	角质层厚度/μm	上表皮厚度/μm	下表皮厚度/μm	栅栏组织厚度/μm	海绵组织厚度/μm
XC34-2	198.693±5.205b	2.007±0.120a	15.460±0.815b	11.983±0.597a	95.963±1.671bc	73.280±2.364ab
XC12-10	199.008±9.197b	1.817±0.087ab	19.874±0.262a	11.023±1.181a	102.583±6.122b	63.710±2.826c
XC9-9	184.700±8.832b	1.790±0.125ab	14.060±1.809b	12.217±0.858a	90.750±4.460bc	65.883±2.499bc
XC18-4	224.313±8.828a	1.800±0.148ab	16.550±0.232b	11.987±0.900a	117.450±5.153a	76.527±2.904a
黑油椿	187.123±4.557b	1.273±0.173c	15.483±0.172b	11.880±0.850a	89.910±2.401bc	68.577±2.326abc
红油椿	183.803±10.544b	1.230±0.076c	14.440±0.507b	11.197±0.423a	84.230±7.037c	72.707±3.491ab
XC6-6	197.987±2.892b	1.457±0.136bc	16.470±0.536b	11.970±0.684a	104.227±2.149ab	63.863±1.403c
无性系	栅海比	CTR/%	SR/%	中脉厚度/mm	中脉/叶片厚度
XC34-2	1.310±0.021b	48.320±0.427c	36.870±0.388b	1.166±0.011b	5.873±0.157cd
XC12-10	1.607±0.029a	51.493±0.881ab	32.020±0.058d	1.208±0.021ab	6.093±0.247c
XC9-9	1.380±0.051b	49.130±0.459bc	35.733±1.036bc	1.151±0.053bc	6.240±0.193bc
XC18-4	1.533±0.020a	52.343±0.448a	34.123±0.183c	1.209±0.009ab	5.403±0.187d
黑油椿	1.313±0.039b	48.057±0.867cd	36.637±0.459b	1.288±0.021a	6.887±0.097a
红油椿	1.157±0.052c	45.700±1.233d	39.603±0.725a	1.237±0.030ab	6.753±0.211ab
XC6-6	1.633±0.052a	52.647±0.871a	32.257±0.534d	1.071±0.030c	5.407±0.073d

无性系	叶片厚度/μm	角质层厚度/μm	上表皮厚度/μm	下表皮厚度/μm	栅栏组织厚度/μm	海绵组织厚度/μm
XC34-2	198.693±5.205b	2.007±0.120a	15.460±0.815b	11.983±0.597a	95.963±1.671bc	73.280±2.364ab
XC12-10	199.008±9.197b	1.817±0.087ab	19.874±0.262a	11.023±1.181a	102.583±6.122b	63.710±2.826c
XC9-9	184.700±8.832b	1.790±0.125ab	14.060±1.809b	12.217±0.858a	90.750±4.460bc	65.883±2.499bc
XC18-4	224.313±8.828a	1.800±0.148ab	16.550±0.232b	11.987±0.900a	117.450±5.153a	76.527±2.904a
黑油椿	187.123±4.557b	1.273±0.173c	15.483±0.172b	11.880±0.850a	89.910±2.401bc	68.577±2.326abc
红油椿	183.803±10.544b	1.230±0.076c	14.440±0.507b	11.197±0.423a	84.230±7.037c	72.707±3.491ab
XC6-6	197.987±2.892b	1.457±0.136bc	16.470±0.536b	11.970±0.684a	104.227±2.149ab	63.863±1.403c
无性系	栅海比	CTR/%	SR/%	中脉厚度/mm	中脉/叶片厚度
XC34-2	1.310±0.021b	48.320±0.427c	36.870±0.388b	1.166±0.011b	5.873±0.157cd
XC12-10	1.607±0.029a	51.493±0.881ab	32.020±0.058d	1.208±0.021ab	6.093±0.247c
XC9-9	1.380±0.051b	49.130±0.459bc	35.733±1.036bc	1.151±0.053bc	6.240±0.193bc
XC18-4	1.533±0.020a	52.343±0.448a	34.123±0.183c	1.209±0.009ab	5.403±0.187d
黑油椿	1.313±0.039b	48.057±0.867cd	36.637±0.459b	1.288±0.021a	6.887±0.097a
红油椿	1.157±0.052c	45.700±1.233d	39.603±0.725a	1.237±0.030ab	6.753±0.211ab
XC6-6	1.633±0.052a	52.647±0.871a	32.257±0.534d	1.071±0.030c	5.407±0.073d

无性系	Car/(mg/g)	Chl a/(mg/g)	Chl b/(mg/g)	Chl a/b	Chl/(mg/g)
XC34-2	0.18±0.02c	1.56±0.08d	0.50±0.01d	3.14±0.12a	2.05±0.08b
XC12-10	0±0d	2.03±0.10bc	1.55±0.12a	1.31±0.08c	3.58±0.20a
XC9-9	0±0d	2.06±0.02bc	1.43±0.03a	1.45±0.01c	3.49±0.04a
XC18-4	0.26±0.01b	1.80±0.09cd	0.57±0.03cd	3.15±0.02a	2.37±0.12b
黑油椿	0.33±0.01a	2.64±0.06a	0.93±0.03b	2.84±0.02b	3.57±0.09a
红油椿	0.31±0.02a	2.27±0.13ab	0.78±0.06bc	2.92±0.08b	3.05±0.19a
XC6-6	0.22±0.01b	1.85±0.18cd	0.58±0.05cd	3.19±0.06a	2.43±0.23b

无性系	Car/(mg/g)	Chl a/(mg/g)	Chl b/(mg/g)	Chl a/b	Chl/(mg/g)
XC34-2	0.18±0.02c	1.56±0.08d	0.50±0.01d	3.14±0.12a	2.05±0.08b
XC12-10	0±0d	2.03±0.10bc	1.55±0.12a	1.31±0.08c	3.58±0.20a
XC9-9	0±0d	2.06±0.02bc	1.43±0.03a	1.45±0.01c	3.49±0.04a
XC18-4	0.26±0.01b	1.80±0.09cd	0.57±0.03cd	3.15±0.02a	2.37±0.12b
黑油椿	0.33±0.01a	2.64±0.06a	0.93±0.03b	2.84±0.02b	3.57±0.09a
红油椿	0.31±0.02a	2.27±0.13ab	0.78±0.06bc	2.92±0.08b	3.05±0.19a
XC6-6	0.22±0.01b	1.85±0.18cd	0.58±0.05cd	3.19±0.06a	2.43±0.23b

	Y(II)	ETR	qP	qN	Y(NO)	Y(NPQ)	Fv/Fm	Car	Chla	Chlb	Chla/b
Y(II)	1
ETR	1.000^**	1
qP	0.117	0.122	1
qN	-0.578^**	-0.574^**	0.542^**	1
Y(NO)	0.068	0.064	-0.628^**	-0.834^**	1
Y(NPQ)	-0.760^**	-0.756^**	0.326^*	0.957^**	-0.701^**	1
Fv/Fm	0.270	0.266	-0.860^**	-0.545^**	0.351^*	-0.422^**	1
Car	-0.489	-0.493	-0.317	0.063	0.242	0.200	-0.002	1
Chla	-0.339	-0.340	0.059	0.232	-0.059	0.273	-0.220	0.909^**	1
Chlb	0.045	0.058	0.201	0.025	-0.008	-0.027	-0.247	0.917^**	0.357	1
Chla/b	-0.118	-0.129	-0.149	0.030	-0.006	0.087	0.164	-0.758^**	-0.119	-0.961^**	1
Chl	-0.167	-0.159	0.162	0.149	-0.039	0.140	-0.284	0.914^**	0.804^**	0.843^**	-0.680^**
L	0.215	0.214	-0.215	-0.213	0.069	-0.179	0.358	-0.148	-0.331	-0.193	0.117
C	0.628^**	0.634^**	-0.326	-0.626^**	0.402	-0.628^**	0.552^**	-0.699^*	-0.828^**	-0.140	-0.080
UE	0.272	0.274	0.080	-0.020	-0.168	-0.096	0.098	-0.040	-0.134	0.632^*	-0.690^**
LE	0.238	0.239	0.001	-0.139	0.056	-0.188	0.073	-0.130	-0.082	0.153	-0.199
P	0.229	0.227	-0.214	-0.216	0.075	-0.192	0.386	-0.226	-0.378	-0.180	0.105
S	-0.043	-0.042	-0.182	-0.091	0.067	-0.006	0.141	0.202	0.015	-0.392	0.386
M	-0.338	-0.342	-0.233	0.126	-0.014	0.234	0.013	0.623	0.417	0.427	-0.370
P/S	0.246	0.245	-0.040	-0.116	-0.014	-0.158	0.246	-0.341	-0.355	0.096	-0.159
CTR	0.196	0.194	-0.128	-0.146	0.035	-0.149	0.313	-0.324	-0.371	-0.094	0.033
SR	-0.298	-0.297	0.017	0.128	0.022	0.189	-0.236	0.383	0.361	-0.219	0.294
M/L	-0.410	-0.413	0.009	0.247	-0.034	0.293	-0.288	0.532	0.539	0.406	-0.306
	Chl	L	C	UE	LE	P	S	M	P/S	CTR	SR
Y(II)
ETR
qP
qN
Y(NO)
Y(NPQ)
Fv/Fm
Car
Chla
Chlb
Chla/b
Chl	1
L	-0.326	1
C	-0.601^*	0.322	1
UE	0.313	0.516^*	0.193	1
LE	0.046	0.287	0.027	0.088	1
P	-0.347	0.943^**	0.339	0.557^**	0.135	1
S	-0.237	0.639^**	0.086	-0.066	0.296	0.374	1
M	0.526	0.145	-0.328	0.154	0.174	-0.068	0.477^*	1
P/S	-0.160	0.488^*	0.270	0.631^**	-0.092	0.736^**	-0.348	-0.420	1
CTR	-0.289	0.590^**	0.292	0.489^*	-0.143	0.824^**	-0.180	-0.409	0.962^**	1
SR	0.086	-0.425	-0.286	-0.690^**	0.002	-0.666^**	0.422	0.385	-0.982^**	-0.904^**	1
M/L	0.589^*	-0.756^**	-0.496^*	-0.363	-0.137	-0.849^**	-0.217	0.532^*	-0.707^**	-0.781^**	0.635^**

自然高温干旱下7个香椿无性系的叶片解剖结构及叶绿素荧光特性比较

Comparison of Leaf Anatomical Structure and Chlorophyll Fluorescence Characteristics of 7 Toona sinensis Clones Under Natural High Temperature and Drought

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成分	特征值	贡献率/%	累积贡献率/%
1	9.189	39.953	39.953
2	4.925	21.412	61.365
3	4.279	18.603	79.968
4	2.107	9.162	89.130
5	1.702	7.398	96.528
6	0.799	3.472	100.000

指标	成分1	成分2	成分3	成分4
Y(II)	0.779	0.023	-0.072	-0.433
ETR	0.774	0.019	-0.074	-0.441
qP	-0.327	0.199	-0.868	-0.280
qN	-0.757	0.354	-0.548	-0.011
Y(NO)	0.380	-0.477	0.627	0.318
Y(NPQ)	-0.864	0.300	-0.363	0.132
Fv/Fm	0.665	-0.033	0.728	0.079
Car	-0.539	0.720	0.102	0.349
Chl a	-0.750	-0.406	0.027	0.385
Chl b	0.031	-0.996	-0.070	0.010
Chl a/ b	-0.179	0.969	0.038	0.101
Chl	-0.387	-0.881	-0.032	0.216
L	0.755	0.409	0.110	0.460
C	0.861	-0.108	0.239	-0.396
UE	0.506	-0.267	-0.560	0.296
LE	0.300	0.319	0.366	-0.200
P	0.825	0.284	-0.109	0.476
S	-0.005	0.587	0.715	0.151
P/S	0.737	-0.088	-0.565	0.321
CTR	0.798	0.050	-0.419	0.371
SR	-0.725	0.178	0.587	-0.262
M	-0.455	-0.231	0.457	0.369
M/L	0.779	0.023	-0.072	-0.433

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无性系	隶属函数值					排名	耐热抗旱等级
无性系	C	Chl a/b	Fv/Fm	P	平均值	排名	耐热抗旱等级
XC34-2	1	0.976	0.638	0.353	0.742	2	R
XC12-10	0.755	0	0.354	0.552	0.415	4	MR
XC9-9	0.721	0.071	0.685	0.196	0.418	5	MR
XC18-4	0.734	0.983	1	1	0.929	1	HR
黑油椿	0.055	0.814	0.346	0.171	0.347	6	S
红油椿	0	0.858	0.016	0	0.219	7	S
XC6-6	0.292	1	0	0.602	0.474	3	MR

无性系	隶属函数值					排名	耐热抗旱等级
无性系	C	Chl a/b	Fv/Fm	P	平均值	排名	耐热抗旱等级
XC34-2	1	0.976	0.638	0.353	0.742	2	R
XC12-10	0.755	0	0.354	0.552	0.415	4	MR
XC9-9	0.721	0.071	0.685	0.196	0.418	5	MR
XC18-4	0.734	0.983	1	1	0.929	1	HR
黑油椿	0.055	0.814	0.346	0.171	0.347	6	S
红油椿	0	0.858	0.016	0	0.219	7	S
XC6-6	0.292	1	0	0.602	0.474	3	MR