干旱胁迫对转JERF36银中杨苗木叶片解剖结构及光合特性的影响

doi:10.11707/j.1001-7488.20170502

摘要/Abstract

摘要： [目的] 以转JERF36银中杨（ABJ01）和非转基因银中杨（9#）为试验材料，开展干旱胁迫对2个株系苗高生长、叶片形态解剖结构、光合特性的影响研究，以期为转基因杨树的抗旱性评价提供参考，并为转基因杨树的推广应用提供科学依据。[方法] 于2015年6月底，苗高约45 cm时，选取生长一致的苗木进行土壤干旱胁迫试验。胁迫程度分为3个梯度：正常供水、中度胁迫、重度胁迫，土壤含水量分别控制在田间持水量的60%~80%，40%~60%，20%~40%，胁迫时间为30天。[结果] 干旱胁迫下，2个株系的苗高生长均受到抑制，随着胁迫程度的加剧，受抑制程度增大，但ABJ01受抑制程度较低，重度胁迫下其苗高显著高于9#。叶片形态数据显示，与正常供水相比，干旱胁迫处理后，2个株系的单叶面积显著降低，说明干旱胁迫抑制杨树叶片生长；中度、重度胁迫下9#的单叶面积均显著低于ABJ01，表明ABJ01叶片生长受抑制程度低。叶片解剖结构数据显示，ABJ01和9#的叶表皮细胞生长和叶肉细胞生长均受干旱胁迫的抑制，但ABJ01受抑制程度较低。中度胁迫下，ABJ01的叶片上、下表皮厚度分别比9#显著高出5.55%和4.70%，栅栏组织厚度比9#显著高出6.17%，海绵组织厚度和叶片组织疏松度（SR）则分别比9#显著降低12.35%和12.38%；重度胁迫下ABJ01的叶片上、下表皮厚度分别比9#显著高出16.27%和10.58%，海绵组织厚度和SR则分别比9#显著降低11.71%和11.58%。ABJ01具有更发达的栅栏组织和相对少的海绵组织，这有助于CO₂向光合场所的传导，维持叶片较高的净光合速率（P_n），以适应干旱胁迫条件。光合生理数据显示，干旱胁迫下，ABJ01的P_n显著高于非转基因株系9#（10.50%~18.97%），说明干旱胁迫下ABJ01具有更强的光合能力。正常供水下，2个株系的气孔导度（G₃）、最大光化学效率（F_v/F_m）差异不显著，干旱胁迫下转基因株系ABJ01的G_s、F_v/F_m下降幅度比非转基因株系9#小，说明ABJ01受干旱胁迫影响程度较低；ABJ01的蒸腾速率（Tr）小于9#，表明ABJ01在干旱胁迫下具有更强的保水能力。ABJ01的叶片叶绿素a、叶绿素b和总叶绿素含量较9#高，F_v/F_m值较9#高，说明转基因株系维持叶绿素含量稳定的能力较强且光系统受损伤程度小。[结论] 外源基因JERF36可能通过影响叶片结构发育提高转基因银中杨在干旱胁迫下的气体交换能力和保水能力，从而增强转基因银中杨的抗旱能力。

关键词: 干旱胁迫, 转基因杨树, 叶片解剖结构, 光合特性

Abstract: [Objective] In this study, transgenic Populus alba×P. berolinensis line (ABJ01) and non-transgenic line (9#) were used to test effects of drought stress. To provide a new reference for drought assessment and scientific basis for promotion and application of transgenic poplars, seedling height, morphological and anatomical structure of leaves, and photosynthetic characteristics of transgenic poplar and non-transgenic poplar under drought stress were measured. [Method] At the end of June 2015, a soil drought stress experiment was conducted with seedlings of transgenic poplar and non-transgenic poplar at the average height around 45 cm. The seedlings were subjected to three regimes of water (control, moderate stress, and severe stress), and the soil moisture was controlled at 60%-80%, 40%-60%, 20%-40% of the field water capacity, respectively for 30 days. [Result] Seedling height growth of the two lines was inhibited to a certain degree by drought stress, and the inhibition was increasing severe with the stress level increased. The seedling height of transgenic line ABJ01 was 9.38% higher than non-transgenic line 9# under severe drought stress. Single leaf area of the two lines was significantly reduced under drought stress, indicating that drought stress suppressed growth of poplar leaves. Single leaf area of 9# was significantly lower than ABJ01, accounting for 10.82% and 13.79% of the control, respectively, indicating limitation of leaf growth in ABJ01 was lower under drought stress. Anatomical structure of leaves showed that growth of leaf epidermal cells and mesophyll cells in ABJ01 and 9# were inhibited by drought stress, however the inhibited degree of ABJ01 was lower. Under moderate drought stress, leaf upper epidermal thickness and lower epidermal thickness of ABJ01 were 5.55% and 4.70% significantly greater than that of 9#, respectively. Thickness of palisade tissue of ABJ01 was 6.17% significant greater than 9#. In contrast, sponge tissue thickness and SR were 12.35% and 12.38% significantly lower than those of 9#, respectively. Under severe drought stress condition, leaf upper epidermal thickness and lower epidermal thickness of ABJ01 were 16.27% and 10.05% significantly higher than 9#, respectively, but sponge tissue thickness and SR were 11.71% and 11.58% significant lower than those of 9#, respectively. The more developed palisade tissue and relatively reduced spongy tissue may facilitate the conduction of CO₂, and maintain the higher P_n in leaf of ABJ01, which would contribute to adaptation to drought stress. Photosynthetic physiological data suggested that P_n of 9# was 2.8 times lower than that of ABJ01, and ABJ01 P_n was significantly higher than non-transgenic lines 9# (10.50%-18.97%), indicating ABJ01 had a greater photosynthetic capacity. Under control treatment, there were no significant differences in G_s, F_v/F_m between the two lines. However under drought stress, the decreased trend in transgenic line was relatively smaller compared with non-transgenic line under drought stress, indicating that ABJ01 indexes was less affected by drought stress. In addition, ABJ01 Tr was less than 9#, suggesting that ABJ01 had stronger capacity in water holding under drought conditions. The chlorophyll a, chlorophyll b and total chlorophyll content in ABJ01 were higher than those of 9#. ABJ01 F_v/F_m was higher than 9#, indicating that the ability of maintaining the stability of chlorophyll content was stronger and the damage of PSⅡ was less in transgenic line. [Conclusion] The study suggests that exogenous gene JERF36 may improve the gas exchange capacity and water-holding capacity of transgenic Populus alba×P. berolinensis under drought stress by impacting the leaf structural of transgenic poplar, finally enhance drought tolerance of transgenic Populus alba×P. berolinensis.

Key words: drought stress, transgenic poplar, leaf anatomical structure, photosynthetic characteristics

中图分类号:

S718.5

黄绢, 陈存, 张伟溪, 丁昌俊, 苏晓华, 黄秦军. 干旱胁迫对转JERF36银中杨苗木叶片解剖结构及光合特性的影响[J]. 林业科学, 2017, 53(5): 8-15.

Huang Juan, Chen Cun, Zhang Weixi, Ding Changjun, Su Xiaohua, Huang Qinjun. Effects of Drought Stress on Anatomical Structure and Photosynthetic Characteristics of Transgenic JERF36 Populus alba×P. berolinensis Seedling Leaves[J]. Scientia Silvae Sinicae, 2017, 53(5): 8-15.

参考文献

陈昕, 徐宜凤, 张振英. 2012. 干旱胁迫下石灰花楸幼苗叶片的解剖结构和光合生理响应. 西北植物学报, 32(1):111-116.
(Chen X, Xu Y F, Zhang Z Y. 2012. Leaf anatomical, structure and photosynthetic physiology responses of Sorbus folgneri seedlings under drought stress. Acta Bot Boreal-Occidentalia Sinica, 32(1):111-116.[in Chinese])
高俊凤. 2006.植物生理学实验指导. 北京:高等教育出版社.
(Gao J F. 2006. Guide of plant ohysiology experiment. Beijing:Higher Education Press. [in Chinese])
井大炜, 邢尚军, 马海林, 等. 2014. I-107 欧美杨对不同强度干旱胁迫的形态与生理响应. 东北林业大学学报, 42 (1):10-13.
(Jing D W, Xing S J, Ma H L, et al. 2014. Morphological and physiological responses of Populus×euramericana cv. 'Neva 'to water stress. Journal of Northeast Forestry University, 42 (1):10-13.[in Chinese])
井大炜, 邢尚军, 杜振宇, 等. 2013. 干旱胁迫对杨树幼苗生长、光合特性及活性氧代谢的影响. 应用生态学报, 24(7):1809-1816.
(Jing D W, Xing S J, Du Z Y, et al. 2013. Effects of drought stress on the growth, photosynthetic characteristics,and active oxygen metabolism of poplar seedlings.Chinese Journal of Applied Ecology, 24(7):1809-1816. [in Chinese])
李芳兰, 包维楷. 2005. 植物叶片形态解剖结构对环境变化的响应与适应. 植物学通报, 22(增刊):118-127.
(Li F L, Bao W K. 2005. Responses of the morphological and anatomical structure of the plant leaf to environmental change. Chinese Bulletin of Botany, 22(S1):118-127.[in Chinese])
李欢, 樊军锋, 高建社, 等. 2013. 黑杨叶片旱生结构的比较. 西北林学院学报, 28(3):113-118.
(Li H, Fan J F, Gao J S, et al. 2013. Comparison on drought resistance on anatomical structures of black poplar leaf. Journal of Northwest Forestry University, 28(3):113-118. [in Chinese])
李义良. 2008.转基因杨树的分子检测及抗逆性评价. 北京:北京林业大学博士学位论文.
(Li Y L. 2008. Molecular detection and evaluation of stress tolerance in transgenic poplars. Beijing:PhD thesis of Beijing Forestry University. [in Chinese])
李文正, 张海文, 王俊英, 等. 2006. ERF转录因子及其在烟草抗逆性改良中的应用. 生物技术通报, (4):30-34.
(Li W Z, Zhang H W, Wang J Y, et al. 2006. Ethylene responsive factors and their application in improving tobacco tolerance to biotic and abiotic stresses. Biotechnology Bulletin, (4):30-34. [in Chinese])
马兰青, 王丽雪, 王有年,等. 1996. 干旱对苹果叶片形态解剖结构的影响. 北京农学院学报, 11(2):27-31.
(Ma L Q, Wang L X, Wang Y N, et al. 1996. Affection of aridity to anatomical structure on apple leaves. Journal of Beijing Agricultural College, 11(2):27-31. [in Chinese])
马耀光,张保军,罗志成,等. 2003. 旱地农业节水技术. 北京:化学工业出版社, 11.
(Ma Y G, Zhang B J, Luo Z C, et al. 2003. Dryland agriculture water-saving technology. Beijing:Chemical Industry Press, 11.
潘存娥, 田丽萍, 李贞贞, 等. 2011. 5种杨树无性系叶片解剖结构的抗旱性研究. 中国农学通报, 27(2):21-25.
(Pan C E, Tian L P, Li Z Z, et al. 2011. Studies on drought resistance on anatomical structure of leaves of 5 poplar clones. Chinese Agricultural Science Bulletin, 27(2):21-25. [in Chinese])
苏晓华, 张冰玉, 黄秦军. 2009.杨树基因工程育种. 北京:科学出版社.
(Su X H, Zhang B Y, Huang Q J. 2009.Poplar genetic engineering breeding. Beijing:Science Press. [in Chinese])
王林龙, 李清河, 徐军, 等. 2015. 不同种源油蒿形态与生理特征对干旱胁迫的响应. 林业科学, 51(2):37-43.
(Wang L L, Li Q H, Xu J, et al. 2015. Morphology and physiology characteristic responses of different provenances of Artemisia ordosica to drought stress. Scientia Silvae Sinicae, 51(2):37-43. [in Chinese])
燕玲, 李红, 刘艳. 2002. 13种锦鸡儿属植物叶的解剖生态学研究. 干旱区资源与环境, 16(1):100-106.
(Yan L, Li H, Liu Y. 2002. The anatomical ecology studies on the leaf of 13 species in Caragana genus. Journal of Arid Land Resources and Environment, 16(1):100-106. [in Chinese])
叶龙华, 黄香兰, 薛立. 2014. 干旱胁迫对树木叶片性状及抗旱生理的影响. 世界林业研究, 27(1):29-34.
(Ye L H, Huang X L, Xue L. 2014. Effects of drought on leaf traits and drought-resistant physiology of trees. World Forestry Research, 27(1):29-34. [in Chinese])
张计育, 王庆菊, 郭忠仁. 2012. 植物AP2/ERF类转录因子研究进展. 遗传, 34(7):835-847.
(Zhang J Y, Wang Q J, Guo Z R. 2012. Progresses on plant AP2/ERF transcription factors. Hereditas, 34(7):835-847. [in Chinese])
Anjum S A, Xie X,Wang L C, et al. 2011. Morphological, physiological and biochemical responses of plants to drought stress. African Journal of Agricultural Research, 6(9):2026-2032.
Araus J L, Slafer G A, Reynolds M P, et al. 2002. Plant breeding and drought in C3 cereals:What should we breed for? Ann Bot, 89(7):925-940.
Bacelar E A, Correia C M, Moutinho-Pereira J M, et al. 2004. Sclerophylly and leaf anatomical traits of five field-grown olive cultivars growing under drought conditions. Tree Physiol, 24(2):233-239.
Boughalleb F, Hajlaoui H. 2011. Physiological and anatomical changes induced by drought in two olive cultivars (cv Zalmati and Chemlali). Acta Physiol Plant, 33(1):53-65.
Chartzoulakis K, Patskas A, Kofidis G, et al. 2002. Water stress affects leaf anatomy, gas exchange, water relations and growth of two avocado cultivars. Scientia Horticulturae, 95(1):39-50.
Ennajeh M, Vadel A M, Cochard H, et al. 2010. Comparative impacts of water stress on the leaf anatomy of a drought-resistant and a drought-sensitive olive cultivar. J of Hortic Sci & Biotech, 85(4):289-294.
Evans J R, Loreto F. 2000. Acquisition and diffusion of CO₂ in higher plant leaves//Leegood R C, Sharkey T D, von Caemmerers.Photosynthesis:phystology and metabolism.Netherlands:Kluver Academic Publishers, 321-351.
Li Y L, Su X H, Zhang B Y, et al. 2009. Expression of jasmonic ethylene responsive factor gene in transgenic poplar tree leads to increased salt tolerance. Tree Physiology, 29(2):273-279.
Reddy A R, Chiatanya K V, Vivekanandan M. 2004. Drought induced responses of photosynthesis and antioxidant metabolism in higher plants. J Plant Physiol, 161(11):1189-1202.
Rubio De Casas R R, Vargas P, Pérez-Corona E, et al. 2007. Field patterns of leaf plasticity in adults of the long-lived evergreen Quercus coccifera. Annals of Botany, 100(2):325-334.
Wang W, Vincour B, Altman A. 2003. Plant responses to drought, salinity and extreme temperatures:towards genetic engineering for stress tolerance. Planta, 218(1):1-14
Wu L J, Zhang Z J, Zhang H W, et al. 2008. Transcriptional modulation of ethylene response factor protein JERF3 in the oxidative stress response enhances tolerance of tobacco seedlings to salt, drought, and freezing. Plant Physiology, 148(4):1953-1963.
Zhang H W, Liu W, Wan L Y, et al. 2010. Functional analyses of ethylene response factor JERF3 with the aim of improving tolerance to drought and osmotic stress in transgenic rice. Transgenic Res, 19(5):809-818.
Zhao C X, Huang Z S. 1981. A preliminary study of xeromorphism of some important xerophytes growing in Tungeli desert. Journal of Integrative Plant Biology, 23(4):278-283.

[1]	夏国威, 孙晓梅, 陈东升, 张守攻. 日本落叶松冠层光合特性的空间变化[J]. 林业科学, 2019, 55(6): 13-21.
[2]	王怡霖, 王卫锋, 张芸香, 常淑君, 郭晋平. 碧玉杨叶形态结构与生理特性对干旱的响应[J]. 林业科学, 2019, 55(4): 42-50.
[3]	江成, 周厚君, 赵岩秋, 何辉, 楚立威, 宋学勤, 卢孟柱. 干旱和高盐胁迫下钙离子依赖核酸酶基因CDD对银腺杨84K生长发育的影响[J]. 林业科学, 2019, 55(2): 33-40.
[4]	种培芳, 詹瑾, 贾向阳, 李毅. 模拟CO₂浓度升高及降雨变化对荒漠灌木红砂光合及生长的影响[J]. 林业科学, 2018, 54(9): 27-37.
[5]	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.
[6]	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.
[7]	史文辉, 李国雷, 苏淑钗, 刘勇, 贾黎明, 尚治国. 子叶切除与苗圃施肥对栓皮栎容器苗造林效果的影响[J]. 林业科学, 2018, 54(1): 64-73.
[8]	杜明凤, 丁贵杰, 赵熙州. 不同家系马尾松对持续干旱的响应及抗旱性[J]. 林业科学, 2017, 53(6): 21-29.
[9]	全文选, 丁贵杰. 干旱胁迫下马尾松幼苗针叶挥发性物质与内源激素的变化[J]. 林业科学, 2017, 53(4): 49-55.
[10]	罗青红, 宁虎森, 何苗, 吉小敏, 雷春英. 5种沙地灌木对干旱胁迫的生理生态响应[J]. 林业科学, 2017, 53(11): 29-42.
[11]	储文渊, 王玉娇, 朱东悦, 陈竹, 严涵薇, 项艳. 盐和干旱胁迫下杨树新内参基因的筛选[J]. 林业科学, 2017, 53(10): 70-79.
[12]	黄绢, 李丹, 王宁宁, 苏晓华, 黄秦军. 不同配置方式杨树超短轮伐人工林光合特性及生长差异[J]. 林业科学, 2016, 52(8): 131-137.
[13]	陈盼飞, 任亚超, 张军, 王进茂, 杨敏生. 8年生嫁接转基因杨树Bt毒蛋白的表达与运输[J]. 林业科学, 2016, 52(7): 46-52.
[14]	宋洋, 廖亮, 刘涛, 蒋燕锋, 喻卫武, 胡渊渊, 吴家胜. 不同遮荫水平下香榧苗期光合作用及氮分配的响应机制[J]. 林业科学, 2016, 52(5): 55-63.
[15]	薛雪, 李娟娟, 郑云峰, 张金池, 庄家尧, 王鹰翔. 5个常绿园林树种的夏季光合蒸腾特性[J]. 林业科学, 2015, 51(9): 150-156.