元宝枫色素含量、分布及超微结构与叶色的关系

doi:10.11707/j.1001-7488.LYKX20230157

摘要/Abstract

摘要：

目的: 探究元宝枫叶片颜色属性与不同叶色叶片各组织中色素含量和分布，以及与细胞超微结构的关系，为明确元宝枫叶片呈色的内部机制提供细胞学依据，为揭示红叶植物变色机制提供参考。方法: 分析元宝枫叶片颜色属性，测定各颜色叶片叶绿素、类胡萝卜素和花色素苷含量，观察叶片各组织中色素分布情况，使用透视电镜观察叶肉细胞的叶绿体和其他细胞器的超微结构。结果: 元宝枫不同叶色叶片色素含量、分布和超微结构均存在差异。1）红叶花色素苷含量极显著（P<0.05）高于黄叶和绿叶，叶绿素含量较低。黄叶叶绿素含量最低，类胡萝卜素含量显著（P<0.05）高于红叶，类胡萝卜素与叶绿素含量比值显著高于绿叶和红叶（P<0.05）。绿叶叶绿素和类胡萝卜素含量显著（P<0.05）高于黄叶和红叶，花色素苷含量显著（P<0.05）低于红叶，与黄叶之间无显著差异。相关分析表明，元宝枫叶片色素含量比值均与叶绿素含量呈负相关关系。2）元宝枫叶片上下表皮细胞均无色素分布，花色素苷主要分布于栅栏组织。红叶花色素苷分布明显，绿叶和黄叶花色素苷分布较少。黄叶类胡萝卜素分布明显，在海绵组织也有花色素苷分布。3）嫩绿色叶片叶绿体尚在发育中；绿叶细胞发育成熟，有淀粉粒。叶片变红后，叶绿体中核糖体减少，全红叶片中出现叶绿体解体的残留物；黄叶中叶绿体受损，细胞中有嗜锇颗粒；尖端变褐的叶片细胞中有大量嗜锇颗粒，有些细胞基本为空腔。结论: 元宝枫彩叶未发生结构变异，其颜色变化是因为在叶片变红过程中，叶绿素和类胡萝卜素含量降低尤其叶绿素含量下降迅速，而花色素苷含量上升，其内部花色素苷与叶绿素和类胡萝卜素的比值上升造成的，属于色素型彩叶。叶片花色素苷主要分布于栅栏组织，在变红前就已产生，随其含量上升，最终在叶色上呈现出来。在叶色变化过程中，叶绿体逐渐解体，出现衰老症状，为衰老期型彩叶。黄叶生长势差，叶色从绿转黄，不能呈现红色，衰老速度较红叶更快。

关键词: 元宝枫, 色素含量, 色素分布, 超微结构

Abstract:

Objective: This study aims to explore the relationship between different leaf colors of Acer truncatum and the content and distribution of internal pigments, as well as the ultrastructure of mesophyll cells, to provide cytological basis for clarifying the internal mechanism of leaf coloration of A. truncatum, and provide a reference for revealing the color changing mechanism of red leaf plants. Method: A. truncatum leaves were divided into three categories of green, red and yellow leaves according to the leaf color. The contents of chlorophyll, carotenoid and anthocyanin in the leaves with different colors were determined, and the distribution of pigments in various tissues of the leaves was observed. According to the process of leaf color change, it was able to be divided into six categories: light green, green, yellow, reddish tip, full red and brown tip. The chloroplasts and other organelles of mesophyll cells were observed by using a transmission electron microscopy. Result: There were significant differences in pigment content and distribution, and ultrastructure among leaves with different colors. 1) The anthocyanin content of red leaves was significantly higher than that of yellow and green leaves (P<0.05), while the chlorophyll content was lower. The chlorophyll content of yellow leaves was the lowest, the carotenoid content was significantly (P<0.05) higher than that of red leaves, and the ratio of carotenoid to chlorophyll was significantly higher than that of green leaves and red leaves (P<0.05). The chlorophyll and carotenoid contents of green leaves were significantly higher than those of yellow and red leaves (P<0.05), and the anthocyanin content was significantly lower than that of red leaves (P<0.05), but there was no significant difference in anthocyanin content between green and yellow leaves. Correlation analysis showed that the ratio of pigment content in A. truncatum leaves was negatively correlated with chlorophyll content. 2） There were no pigments in the upper and lower epidermic cells. Anthocyanin was mainly distributed in the palisade tissue. The anthocyanin distribution was prominent in red leaves and less in green leaves and yellow leaves. The distribution of carotenoids was prominent in the yellow leaves. Anthocyanin in yellow leaves was also distributed in spongy tissue. 3） Chloroplasts in young green leaves were still developing, and those in green leaves were mature and had starch grains. After the leaves turned red, the ribosomes in the chloroplasts reduced, and residues of the chloroplast disassembly appeared in fully red leaves. Chloroplasts were damaged in the yellow leaves, and there were osmiophilic granules in the cells. There were lots of osmiophilic granules in tip-brown leaves, and some cells were hollow. Conclusion: There is no structural variation in the coloration of A. truncatum leaves. The color change is caused by the decrease of chlorophyll and carotenoid content during the reddening process of leaves, especially a rapid decrease in chlorophyll content. At the same time, the anthocyanin content increases, and the ratio of anthocyanin to chlorophyll and carotenoid increases. Anthocyanins in the leaves are mainly distributed in the palisade tissue, and synthetized before leaf coloration. With the increase of the anthocyanin content, leaves eventually exhibit color. In the process of leaf coloration, the chloroplasts gradually disintegrate, and some senescence features occur. The colored leaves in A. trumcatum are senescent colored leaves. Yellow leaves are in poor nutritional condition, and their color changes from green to yellow, and cannot turn red. Yellow leaves age faster than red leaves.

Key words: Acer trumcatum, content of pigments, pigments distribution, ultrastructure

中图分类号:

S722.5

王娟,蔺银鼎,李洁,田旭平. 元宝枫色素含量、分布及超微结构与叶色的关系[J]. 林业科学, 2024, 60(3): 111-120.

Juan Wang,Yinding Lin,Jie Li,Xuping Tian. Relationships between the Pigment Content and Distribution, Mesophyll Ultrastructure with Leaf Color of Acer truncatum[J]. Scientia Silvae Sinicae, 2024, 60(3): 111-120.

图/表 6

表1

图1

图2

图3

图4

图5

参考文献 0

	艾　叶, 陈　娟, 郑清冬, 等. 建兰水晶艺叶片的超微结构和转录组学分析. 西北植物学报, 2020, 40 (3): 382- 393.
	Ai Y, Chen J, Zheng Q D, et al. Ultrastructure and transcriptomic analysis of crastal leaf mutant of Cymbidium ensifolium. Acta Botanica Boreali-Occidentalia Sinica, 2020, 40 (3): 382- 393.
	白　雪. 2020. 四季秋海棠叶片在低温和高光胁迫下次生花色素苷生物合成相关基因以及物质的研究. 郑州: 河南农业大学.
	Bai X. 2020. Study on genes and substances related to anthocyanin biosynthesis by low temperature and high light stress in the leaves of Begonia semperflorens. Zhengzhou: Henan Agricultural University. ［in Chinese］
	陈建芳. 2014. 温湿度及外源蔗糖对元宝枫秋叶变色的影响研究. 北京: 北京林业大学.
	Chen J F. 2014. Study on the impact of temperature, humidity and sucrose on the leaf color variations of Acer truncatum during autumn. Beijing: Beijing Forestry University. ［in Chinese］
	陈柯伊, 李朝娜, 成敏敏, 等. 不同叶色矢竹叶绿体结构和光系统特性差异. 植物学报, 2018, 53 (4): 509- 518. doi: 10.11983/CBB17115
	Chen K Y, Li Z N, Cheng M M, et al. Chloroplast ultrastructure and chlorophyll fluorescence characteristics of three cultivars of Pseudosasa japonica. Chinese Bulletin of Botany, 2018, 53 (4): 509- 518. doi: 10.11983/CBB17115
	陈凌艳, 何丽婷, 赖金莉, 等. 银丝竹不同叶色叶绿素合成及叶结构差异. 森林与环境学报, 2017, 37 (4): 385- 391.
	Chen L Y, He L T, Lai J L, et al. The variation of chlorophyll biosynthesis and the structure in different color leaves of Bambusa multiplex ‘Silverstripe’. Journal of Forest and Environment, 2017, 37 (4): 385- 391.
	崔珂婉, 林　梅, 朴　楠, 等. 元宝枫秋季转色期叶色变化与生理特性的关系. 中国园艺文摘, 2015, 30 (3): 5- 7. doi: 10.3969/j.issn.1672-0873.2015.03.002
	Cui K W, Lin H, Pu N, et al. The relationship between leaf color expression and physiological characteristics in autumn foliage during color change of Acer truncatum. Chinese Horticulture Abstracts, 2015, 30 (3): 5- 7. doi: 10.3969/j.issn.1672-0873.2015.03.002
	范燕萍, 李慧玲, 李浩健. 几种花叶线艺兰叶片色斑色素组成和叶绿体超微结构研究. 华南农业大学学报, 2006, 27 (4): 8- 11.
	Fan Y P, Li H L, Li H J. Pigment composition and ultrastructural difference of chloroplast in three kinds of variegation leaf of Cymbidium sinense. Journal of South China Agricultural University, 2006, 27 (4): 8- 11.
	黄金亮, 张　帆, 万雪琴, 等. 芽变突变体彩叶杨光合特性及叶绿体超微结构的研究. 核农学报, 2019, 33 (5): 855- 862.
	Huang J L, Zhang F, Wan X Q, et al. Study on photosynthetic characteristics and chloroplast ultrastructure of bud mutant of color-leaved poplar. Journal of Nuclear Agricultural Sciences, 2019, 33 (5): 855- 862.
	黄利斌, 陈庆生, 张　敏, 等. 2013. 乌桕秋叶显色的生理生化与数字图像分析. 林业科学, 49(11): 32−41.
	Huang L B, Chen Q S, Zhang M, et al. 2013. Analysis of autumn leaf colorization of Sapium sebiferum by using physiological and digital imaging methods. Scientia Silvae Sinicae, 49(11): 32−41. ［in English］
	李亚蒙, 王庆菊, 沈　向. 四种李属彩叶树种枝叶花色苷分布的解剖研究. 山东农业大学学报(自然科学版), 2006, 37 (4): 489- 494.
	Li Y M, Wang Q J, Shen X. Pigment distribution in fresh shoot tissues of four colored-leaf Prunus taxa. Journal of Shandong Agricultural University (Natural Science Edition), 2006, 37 (4): 489- 494.
	梁　峰, 蔺银鼎. 光照强度对彩叶植物元宝枫叶色表达的影响. 山西农业大学学报(自然科学版), 2009, 29 (1): 41- 45.
	Liang F, Lin Y D. Effect of light intensity on leaf-color expression of Acer truncatum Bunge. Journal of Shanxi Agricultural University (Natrual Science Edition), 2009, 29 (1): 41- 45.
	蔺银鼎, 梁　峰. 主要气候因子对元宝枫秋叶着色的影响. 中国农学通报, 2010, 26 (2): 166- 170.
	Lin Y D, Liang F. On eco-mechanism of the autumn lives color emerging of Acer truncatum Bunge. Chinese Agricultural Science Bulletin, 2010, 26 (2): 166- 170.
	刘　平, 宋　岩, 陆秀君, 等. 美国红枫和元宝枫幼叶春季转色期生理物性研究. 生态环境学报, 2018, 27 (3): 452- 458.
	Liu P, Song Y, Lu X J, et al. Research of physiological characteristics in juvenile leaves of Acer × freemanii ‘Autumn Blaze’ and Acer truncatum during leaf color transformation in spring. Ecology and Environmental Sciences, 2018, 27 (3): 452- 458.
	罗　兰. 2007. 彩叶草叶片呈色的生理特性及其花色素苷性质研究. 重庆: 西南大学.
	Luo L, 2007. Study on physiological characteristics of leaf color expression and anthocyanins in Solenostemon scutellarioides. Chongqing: Southwest University. ［in Chinese］
	马宗琪, 崔　静, 王　秀, 等. 2016. 树木叶片叶绿素含量三种测定方法的比较. 林业科技, 41(5): 42−45.
	Ma Z Q, Cui J, Wang X, et al. Comparison of three methods for measuring chlorophyll content in tree leaves. Forestry Science & Technology, 41(5): 42−45. ［in Chinese］
	齐新玲. 2016. 元宝枫无性系DNA指纹图谱的构建. 泰安: 山东农业大学.
	Qi X L. 2016. Establishment of DNA fingerprints for clones of Acer truncatum Bunge. Tai’an: Shandong Agricultural University. ［in Chinese］
	钱见平, 丰　震, 王长宪, 等. 元宝枫无性系秋季叶片主要成分含量动态变化. 中国农学通报, 2013, 29 (7): 26- 30. doi: 10.3969/j.issn.1000-6850.2013.07.007
	Qian J P, Feng Z, Wang C X, et al. The dynamic changes of main component in leaves of Acer truncatum Bunge clones in autumn. Chinese Agricultural Science Bulletin, 2013, 29 (7): 26- 30. doi: 10.3969/j.issn.1000-6850.2013.07.007
	苏佳露, 史无双, 杨雅运, 等. 6个竹种叶色与光合色素含量及叶片结构比较. 林业科学, 2020, 56 (7): 194- 203.
	Su J L, Shi W S, Yang Y L, et al. Comparison of leaf color and pigment content and observation of leaf structure of different growth stages from six bamboo species. Scientia Silvae Sinicae, 2020, 56 (7): 194- 203.
	孙旺旺, 孟宪敏, 徐秀源, 等. 金叶连翘叶片色素含量和解剖结构研究. 植物研究, 2020, 40 (3): 321- 329.
	Sun W W, Meng X M, Xu X Y, et al. Contents of pigments and anatomical structure in the leaves of Forsythia koreana ‘Sun Gold’. Bulletin of Botanical Research, 2020, 40 (3): 321- 329.
	田丽媛. 2012. 温湿度对北京5种秋季色叶树种秋叶变色的影响. 北京: 北京林业大学.
	Tian L Y. 2012. The impact of temperature of temperature and humidity on five kinds of fall-color tree’s color changing in autumn of Beijing. Beijing: Beijing Forestry University. ［in Chinese］
	唐前瑞. 红继木和继木叶绿体超微结构的比较. 湖南农业大学学报(自然科学版), 2003, 29 (1): 41- 42.
	Tang Q R. Study on the chloroplast ultrastructure of Loropetalum chinensis var. rubrumyien and L. chinensis. Journal of Hunan Agricultural University (Natural Science Edition), 2003, 29 (1): 41- 42.
	唐生森, 陈　虎, 覃永康, 等. 枫香秋季变色期叶色变化及其生理基础. 广西植物, 2020, 41 (12): 2061- 2068.
	Tang S S, Chen H, Qin Y K, et al. Physiological characteristics of Liquidambar formosana leaves during leaf color transformation in autumn. Guihala, 2020, 41 (12): 2061- 2068.
	王啸晨, 岳祥华, 吴　杰, 等. 2种观赏彩叶竹形态结构的观察与分析. 中国农学通报, 2012, 28 (16): 233- 238.
	Wang X C, Yue X H, Wu J, et al. Appearance and structure analysis of chimeric leaves from two ornamental bamboos. Chinese Agricultural Science Bulletin, 2012, 28 (16): 233- 238.
	王永格, 丛日晨. 北京城区秋季红色叶元宝枫优良品种的筛选. 北方园艺, 2010, 33 (1): 144- 147.
	Wang Y G, Cong R C. Selection on splendid ‘Acer truncatum’ varieties of fall-scenery-leaf. Northern Horticulture, 2010, 33 (1): 144- 147.
	王振兴, 曹建冉, 秦红艳, 等. 狗枣猕猴桃彩叶色素含量和结构共同影响叶色. 植物生理学报, 2016a, 52 (12): 1921- 1926.
	Wang Z X, Cao J R, Qin H Y, et al. Common effect of pigment content and leaf structure on leaf color in Actinidia kolomikta. Plant Physiology Journal, 2016a, 52 (12): 1921- 1926.
	王振兴, 于云飞, 陈　丽, 等. 彩叶植物叶片色素组成、结构以及光合特性的研究进展. 植物生理学报, 2016b, 52 (1): 1- 7.
	Wang J X, Lu Y F, Chen L, et al. Advances in leaf pigment composition, structure and photosynthetic characteristics of colored-leaf plants. Plant Physiology Journal, 2016b, 52 (1): 1- 7.
	王志红, 蔺银鼎. K元素对元宝枫秋叶变色的影响研究. 山西农业大学学报(自然科学版), 2009, 29 (2): 139- 142.
	Wang Z H, Lin Y D. The influence of potassium on color expression of Acer truncatum Bunge leaves. Journal of Shanxi Agricultural University (Natural Science Edition), 2009, 29 (2): 139- 142.
	解植彩, 张文晋, 张新慧. 不同程度盐胁迫对乌拉尔甘草叶片亚显微结构的影响. 时珍国医国药, 2017, 28 (5): 1200- 1204.
	Xie Z C, Zhang W J, Zhang X H. Effects of different level of salt stress on ultrastructure in leaves of Glycyrrhiza uralensis. Lishizen Medicine and Materia Medica, 2017, 28 (5): 1200- 1204.
	闫　菲, 杨树华, 卫晶晶, 等. ‘金叶’弯刺蔷薇叶绿体结构、叶绿体合成物质含量及相关基因表达分析. 园艺学报, 2019, 46 (11): 2188- 2200.
	Yan F, Yang S H, Wei J J, et al. Chloroplast ultrastructure, metabolite contents and gene expression involved in the pathway of chlorophyll biosynthesis of Rosa beggeriana ‘Aurea’. Acta Horticulturae Sinica, 2019, 46 (11): 2188- 2200.
	杨科家. 2010. 元宝枫叶色、叶形与翅果的变异研究. 泰安: 山东农业大学.
	Yang K J. 2010. The researches on variation of leaf color, leaf and samara shape in Acer truncatum Bunge. Tai’an: Shandong Agricultural University. ［in Chinese］
	俞正超, 刘晓涛, 黄烜栋, 等. 夏季南亚热带森林演替中后期优势种幼叶花色素苷的光保护作用. 热带亚热带植物学报, 2018, 26 (4): 363- 374.
	Yu Z C, Liu X T, Huang X D, et al. Photoprotective effects of anthocyanin in young leaves of dominant species in the middle and late successional stages of south subtropical forest in summer. Journal of Tropical and Subtropical Botany, 2018, 26 (4): 363- 374.
	张莉莎, 米胜南, 王　玲, 等. 水稻短根白化突变体sral生理生化分析及基因定位. 作物学报, 2019, 45 (4): 556- 567. doi: 10.3724/SP.J.1006.2019.82041
	Zhang L S, Mi S N, Wang L, et al. Physiological and biochemical analysis and gene mapping of a novel short radicle and albino mutant sra1 in rice. Acta Agronomica Sinica, 2019, 45 (4): 556- 567. doi: 10.3724/SP.J.1006.2019.82041
	张　敏, 钱　猛, 倪竞德, 等. 2012. 乌桕秋叶转色前后生理特性及超微结构的变化. 东北林业大学学报, 40(1): 20−24.
	Zhang M, Qian M, Ni J D, et al. 2012. Changes in physiological index and chloroplast ultrastructure in fall foliage of Sapium sebiferum before and after leaf color change. Journal of Northeast Forestry University, 40(1): 20−24. ［in Chinese］
	张　敏, 黄利斌, 周　鹏, 等. 榉树秋季转色期叶色变化的生理生化. 林业科学, 2015, 51 (8): 44- 51.
	Zhang M, Huang L B, Zhou P, et al. Physiological and biochemical changes in Zelkova serrata leaves during leaf color transformation in autumn. Scientia Silvae Sinicae, 2015, 51 (8): 44- 51.
	张小燕, Wee K S A, Kajita T, 等. 种源地两种红树叶片结构和功能的影响: 对温度的适应性遗传. 植物生态学报, 2021, 45 (11): 1241- 1250. doi: 10.17521/cjpe.2021.0221
	Zhang X Y, Wee K S A, Kajita T, et al. Effect of provenance on leaf structure and function of two mangrove species: the genetic adaptation to temperature. Chinese Journal of Plant Ecology, 2021, 45 (11): 1241- 1250. doi: 10.17521/cjpe.2021.0221
	张振宇, 王　鹏, 王淑安, 等. “金薇”叶片呈色的结构和生理基础研究. 北方园艺, 2014, 38 (4): 68- 72.
	Zhang Z Y, Wang P, Wang S A, et al. Study on structure and physiological basis of leaf colouring in Lagerstroemia indica L. ‘Jinwei’. Northern Horticulture, 2014, 38 (4): 68- 72.
	Feild T S, Lee D W, Holbrook N M. Why leaves plant turn red in autumn. the role of anthocyanins in senescing leaves of red-osier dogwood. Plant Physiology, 2001, 127 (2): 566- 574. doi: 10.1104/pp.010063
	Hanke G, Mulo P. 2013. Plant type ferredoxins and ferredoxin-dependent metabolism. Plant, Cell & Environment, 36(6): 1071-1084.
	Hara N. Study of the variegated leaves with special reference to those caused by air spaces. Japanese Journal of Botany, 1957, 16, 86- 101.
	Hughes N M, Connors M K, Grace M H, et al. The same anthocyanins served four different ways: insights into anthocyanin structure-function relationships from the wintergreen orchid, Tipularia discolor. Plant Science: an International Journal of Experimental Plant Biology, 2021, (303): 110793.
	Konstantina Z, Yinanis M, Yiola P. Transient winter leaf reddening in Cistus creticus characterizes weak (stress-sensitive) individuals, yet anthocyanins cannot alleviate the adverse effects on photosynthesis. Journal of Experimental Botany, 2009, 60 (11): 3031- 3042. doi: 10.1093/jxb/erp131
	Sheue C R, Pao S H, Chien L F, et al. Natural foliar variegation without costs? the case of Begonia. Annals of Botany, 2012, 109 (6): 1065- 1074. doi: 10.1093/aob/mcs025
	Wang Z X, Fan S T, Chen L, et al. Actinidia kolomikta leaf colour and optical characteristics. Biologia Plantarum, 2015, 59 (4): 767- 772. doi: 10.1007/s10535-015-0544-8

颜色属性 Color attribute	绿色嫩叶 Green young leaf	绿色成熟叶 Green mature leaf	黄叶 Yellow leaf	尖端变红叶片 Tip red leaf	全红叶 Fully red leaf	尖端变褐叶片 Tip browned leaf
L	46.94±0.41	69.00±0.19	84.62±0.62	78.71±0.52	62.92±0.61	59.93±0.31
a	?13.04±0.21	?32.91±0.18	4.94±0.19	18.75±0.57	37.24±0.42	23.00±0.27
b	27.58±0.32	56.97±0.15	49.89±0.17	21.67±0.80	7.10±0.37	11.04±0.40

[1]	徐薪璐,蔡鸥,赵婉琪,吕卓,姚文静,李龙,林树燕. 靓竹彩叶形成的细胞学以及光合色素[J]. 林业科学, 2023, 59(8): 40-51.
[2]	刘怡彤,郭慧,裴顺祥,吴莎,吴迪,辛学兵. 基于MaxEnt模型的天然元宝枫在我国的适生区区划及合理性分析[J]. 林业科学, 2023, 59(12): 13-24.
[3]	文世涛,代琳心,刘杏娥,马建锋. 单叶省藤材胞间层超微结构及多糖组成[J]. 林业科学, 2021, 57(11): 152-157.
[4]	吴焦焦,田秋玲,谭星,乐佳兴,张文,高岚,李林珂,王一诺,刘芸. 氮磷钾肥配施对黄栌生长和叶片呈色的影响[J]. 林业科学, 2021, 57(11): 179-189.
[5]	苏佳露,史无双,杨雅运,王星,丁雨龙,林树燕. 6个竹种叶色与光合色素含量及叶片结构比较[J]. 林业科学, 2020, 56(7): 194-203.
[6]	杨佳骏,吴永波,张燕红. 高温与干旱胁迫对‘南林895杨’扦插苗生长和超微结构的影响[J]. 林业科学, 2020, 56(5): 176-183.
[7]	徐有明,周彩霞,林汉,陶吉云,张菊花. 湿地松树木形成层恢复活动期、活动期和休眠期原始细胞超微结构变化[J]. 林业科学, 2020, 56(10): 145-153.
[8]	徐伟, 毕嘉瑞, 刘梅, 张吉辉, 张益恺, 臧连生. 杨背麦蛾(鳞翅目:麦蛾科)触角感器的超微结构[J]. 林业科学, 2019, 55(5): 95-103.
[9]	黄亚丽,张军,樊英利,刘易超,杨敏生. 遮荫对中华金叶榆和鑫叶栾叶片呈色及相关生理指标的影响[J]. 林业科学, 2019, 55(10): 171-180.
[10]	张江涛, 杨淑红, 朱镝, 朱延林, 刘友全. 美洲黑杨2025及其2个芽变品种苗对持续干旱的生理响应及抗旱性评价[J]. 林业科学, 2018, 54(6): 33-43.
[11]	成敏敏, 陈柯伊, 朱雪玉, 王凯利, 周明兵, 杨海芸. 花叶矢竹复绿期光合特性及叶绿体结构[J]. 林业科学, 2018, 54(4): 1-10.
[12]	周艳威, 陈金慧, 鲁路, 成铁龙, 杨立明, 施季森. 杂交鹅掌楸体胚再生植株淹水胁迫下叶片超微结构及光合特性变化[J]. 林业科学, 2018, 54(3): 19-28.
[13]	史敏晶, 吴继林, 郝秉中, 谭海燕, 田维敏. 橡胶树橡胶粒子起源的超微结构分析[J]. 林业科学, 2016, 52(2): 114-119.
[14]	钱莲文, 吴文杰, 孙境蔚, 冯莹. 铝胁迫对常绿杨生长及叶肉细胞超微结构的影响[J]. 林业科学, 2016, 52(11): 39-46.
[15]	宋秀华, 李传荣, 许景伟, 胡丁猛, 王超. 元宝枫、雪松挥发物释放的昼夜节律[J]. 林业科学, 2015, 51(4): 141-147.