天津滨海盐碱地盐胁迫对6种树木幼苗生长的影响

doi:10.16843/j.sswc.2021.03.006

Abstract
Figure/Table
References
Related Citation (8)

Download: PDF (988 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract [Background] Tianjin Binhai New district is the first national comprehensive reform and innovation zone in China, but its land is severely salinized. This problem restricts its saline-alkali land reclamation and ecological restoration, resulting in serious soil erosion problems, which is not conducive to its sustainable economic,social and ecological development. Therefore, based on the soil and plant conditions in the coastal saline-alkali area of Tianjin, this study selected 6 representative greening trees in North China to explore their physiological salt tolerance mechanisms and to conduct a comprehensive salt tolerance evaluation. This study aims to add alternative greening trees to the saline-alkali area of Tianjin Binhai New district, and to improve the level of green landscape in the process of ecological restoration in this area.[Methods] Six greening tree seedlings (Albizia julibrissin, Hibiscus syriacus,Amorpha fruticosa, Lycium barbarum,Lonicera maackii, and Parthenocissus tricuspidata) commonly used in North China were selected as test materials, and a gradient design of 4 NaCl solution concentrations of 0.2%-0.5% was simulated to calculate the growth and physiological indexes of different tree seedlings under salt stress, and the membership function method was adpated for the comprehensive evaluation of the salt tolerance of 6 tree seedlings.[Results] 1) A. fruticosa, H. syriacus and A. julibrissin were all alive after 15 d of salt stress at each concentration. L. barbarum, L. maackii and P. tricuspidata were alive with the increase of concentration and the number of cultivation days, their survival rates decreased, and P. tricuspidata cultivated at 0.5% concentration all died after 15 d. 2) With the increase of salt concentration, the biomass of A. fruticosa increased firstly and then decreased, and the biomass of other trees decreased. Under the 0.2% and 0.3% concentration, the aboveground biomass of A. fruticosa increased, and the belowground biomass of H. syriacus increased. 3) Under salt stress, the relative conductivity, MDA and soluble sugar content of the 6 tree seedling leaves increased. The soluble sugar content of L. maackii changed the most. The soluble sugar content of P. tricuspidata vulgaris reached the peak at 0.3% and then decreased.[Conclusions] The growth of L. barbarum is the most sensitive to salt stress, and the growth of A. fruticosa is promoted under 0.2% and 0.3% salt stress. The aboveground part of H. syriacus is more sensitive to salt stress, and the underground part of A. fruticosa is more sensitive to salt stress. A. fruticosa and A. julibrissin showed a more stable cell membrane structure and function under salt stress. P. tricuspidata had a disordered osmotic regulation function of soluble sugar from 0.3% salt stress, and the cell membrane structure was severely damaged.The comprehensive salt tolerance of 6 greening tree seedlings was A. fruticosan > H. syriacus > A. julibrissi > L. barbarum > L. maacki > P. tricuspidata.

Key words： salt stress greening trees physiological and ecological response salt tolerance evaluation coastal saline-alkali land

Received: 18 November 2020

PACS:

S727.5

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	WEI Yangchen
	LI Shiyu
	YANG Jianying
	ZHAO Tingning
	WANG Ying
	WANG Anyi

Cite this article:

WEI Yangchen,LI Shiyu,YANG Jianying, et al. Effects of salt stress on the growth and physiological characters of 6 typical greening tree seedlings in Tianjin coastal saline-alkali land[J]. SSWC, 2021, 19(3): 47-55.

URL:

http://journal12.magtechjournal.com/Jweb_stbc/EN/10.16843/j.sswc.2021.03.006 OR http://journal12.magtechjournal.com/Jweb_stbc/EN/Y2021/V19/I3/47

[1]	全国土壤普查办公室.中国土壤[M].北京:中国农业出版社,1998:666 National Soil Survey Office. Soils of China[M]. Beijing:China Agriculture Press, 1998:666.
[2]	ZHANG Jinlin, FLOWERS T J, WANG S M. Mechanisms of sodium uptake by roots of higher plants[J]. Plant and Soil, 2010, 326(S1/S2):45.
[3]	杨劲松.中国盐渍土研究的发展历程与展望[J].土壤学报,2008,45(5):837. YANG Jinsong. Development and prospect of the research on salt-affected soils in China[J]. Acta Pedologica Sinica,2008,45(5):837.
[4]	王佳丽,黄贤金,钟太洋,等.盐碱地可持续利用研究综述[J].地理学报,2011,66(5):673. WANG Jiali, HUANG Xianjin, ZHONG Taiyang, et al. Review on sustainable utilization of salt-affected land[J].Acta Geographica Sinica,2011,66(5):673.
[5]	李金彪,陈金林,刘广明,等.滨海盐碱地绿化理论技术研究进展[J].土壤通报,2014,45(1):246. LI Jinbiao, CHEN Jinlin, LIU Guangming, et al. Progress of greening theory and technology for coastal saline land[J]. Chinese Journal of Soil Science,2014,45(1):246.
[6]	张兴.天津滨海盐碱地地区土壤现状调查及绿化对策:以万科东丽湖度假区为例[J].天津农业科学,2017,23(4):108. ZHANG Xing. Investigation and greening countermeasures of soil status in coastal saline-alkali in Tianjin:A case of the Vanke Dongli Lake[J].Tianjin Agricultural Sciences, 2017, 23(4):108.
[7]	李少朋,陈昢圳,刘惠芬,等.丛枝菌根提高滨海盐碱地植物耐盐性的作用机制及其生态效应[J].生态环境学报,2019,28(2):411. LI Shaopeng, CHEN Pozhen, LIU Huifen, et al. Mechanism and ecological effects of arbuscular mycorrhizal fungi on improving salt tolerance of plants in coastal saline-alkaline land[J]. Ecology and Environmental Sciences,2019,28(2):411.
[8]	LI Jianguo, PU Lijie, HAN Mingfang, et al. Soil salinization research in China:Advances and prospects[J]. Journal of Geographical Sciences, 2014,24(5):943.
[9]	吕乐福,池风龙,刘庆岭,等.中新天津生态城土壤盐分调查及改良对策[J].延边大学农学学报,2018,40(3):62. LIU Lefu, CHI Fenglong, LIU Qingling, et al. Investigation and improvement of soil salinity contents in Sino-Singapore Tianjin Eco-city[J].Agricultural Science Journal of Yanbian University,2018,40(3):62.
[10]	吕乐福,池风龙,卢立波,等.天津生态城滨海盐碱区海绵城市建设模式分析[J].给水排水,2019,55(S1):92. LIU Lefu, CHI Fenglong, LU Libo, et al. Analysis on the construction model of sponge city in the coastal saline-alkali area of Tianjin Eco-city[J].Water & Wastewater Engineering,2019,55(S1):92.
[11]	李勇.中新天津生态城植物多样性分析[J].城市环境与城市生态,2010,23(4):26. LI Yong. Plant diversity in Sino-Sigapore Tianjin Eco-city[J].Urban Environment & Urban Ecology,2010,23(4):26.
[12]	尹德洁,荆瑞,关海燕,屈琦琦,张丽丽,王若鹏,董丽.天津滨海新区湿地耐盐植物分布与土壤化学因子的相关关系[J].北京林业大学学报,2018,40(8):103. Yin Dejie, JING Rui, GUAN Haiyan, et al. Correlations between the distribution of salt-tolerant plants and soil chemical factors in wetland of Tianjin Coastal New Area, northern China[J]. Journal of Beijing Forestry University,2018,40(8):103.
[13]	刘爱荣,张远兵,钟泽华,等.盐胁迫对彩叶草生长和渗透调节物质积累的影响[J].草业学报,2013,22(2):211. LIU Ailong, ZHANG Yuanbing, ZHONG Zehua, et al. Effects of salt stress on the growth and osmotica accumulation of Coleus blumei[J].Acta Prataculturae Sinica,2013,22(2):211.
[14]	袁小环,孙男,滕文军,等.9种观赏草苗期耐盐性评价及NaCl胁迫对芨芨草生长的影响[J].植物资源与环境学报,2011,20(3):69. YUAN Xiaohuan, SUN Nan, TENG Wenjun, et al. Assessment of salt tolerance of nine species of ornamental grass at seedling stage and effect of NaCl stress on growth of Achnatherum splendens[J].Journal of Plant Resources and Environment,2011,20(3):69.
[15]	李燕青,孙文彦,许建新,等.华北盐碱地耐盐经济作物筛选[J].华北农学报,2013,28(S1):227. LI Yanqing, SUN Wenyan, XU Jianxin, et al. Selection of salt-tolerant cash crops in saline-alkali land in North China[J].Acta Agriculturae Boreali-Sinica,2013,28(S1):227.
[16]	林艳芝,杨立柱,李海,等.滨海盐碱地原土绿化盐生植物引进与筛选[J].现代农业科技,2020,7(5):116. LIN Yanzhi,YANG Lizhu, LI Hai, et al. Introduction and selection of halophytes for greening the original soil in coastal saline-alkali land[J].Modern Agricultural Science and Technology,2020,7(5):116.
[17]	李合生.植物生理生化实验原理和技术[M].北京:高等教育出版社, 2000:260. LI Hesheng. Principles and techniques of plant physiology and biochemistry experiments[M]. Beijing:Higher Education Press, 2000:260.
[18]	熊雪,桂维阳,刘沫含,等.不同紫花苜蓿品种在均匀与不均匀盐胁迫下的耐盐性评价[J].草业学报,2018,27(9):67. XIONG Xue, GUI Weiyang, LIU Mohan, et al. Evaluation of salt tolerance in different alfalfa varieties under uniform and non-uniform salt stress[J].Acta Prataculturae Sinica,2018,27(9):67.
[19]	谢楠,赵海明,李源,等.饲用黑麦、小黑麦品种苗期耐盐性评价及盐胁迫下的生理响应[J].草地学报,2016,24(1):84. XIE Nan, ZHAO Haiming, LI Yuan, et al. Salt tolerance evaluation and physiological responses of forage rye and triticale at seedling growth stages[J]. Acta Agrestia Sinica,2016,24(1):84.
[20]	列志旸,薛立.盐胁迫对树木生长影响研究综述[J].世界林业研究,2017,30(3):30. LIE Zhiyang, XUE Li. Effects of salt stress on tree growth:A review[J].World Forestry Research,2017,30(3):30.
[21]	FALSTER D S, WESTOBY M. Plant height and evolutionary games[J]. Trends in Ecology & Evolution, 2003, 18(7):337.
[22]	王佺珍,刘倩,高娅妮,等.植物对盐碱胁迫的响应机制研究进展[J].生态学报,2017,37(16):5565. WANG Quanzhen, LIU Qian, GAO Yani, et al. Review on the mechanisms of the response to salinity-alkalinity stress in plants[J].Acta Ecologica Sinica,2017,37(16):5565.
[23]	华建峰,杜丽娟,王莦丰,等.混合盐胁迫对江苏省沿海常用绿化树种生长的影响及耐盐性评价[J].植物资源与环境学报,2015,24(3):41. HUA Jianfeng, DU Lijuan, WANG Xiaofeng, et al. Effect of mixed salt stress on growth of common greening species in coastal area of Jiangsu Province and evaluation of their salt tolerance[J].Journal of Plant Resources and Environment,2015,24(3):41.
[24]	张华新,刘正祥,刘秋芳.盐胁迫下树种幼苗生长及其耐盐性[J].生态学报,2009,29(5):2263. ZHANG Huaxin, LIU Zhengxiang, LIU Qiufang. Seedling growth and salt tolerance of tree species under NaCl stress[J].Acta Ecologica Sinica,2009,29(5):2263.
[25]	ANDRÉ M, FRANOIS M. Salt tolerance in Phragmites australis populations from coastal Mediterranean marshes[J]. Aquatic Botany, 2001, 70(1):39.
[26]	SALTER J, MORRIS K, BAILEY P C E, et al. Interactive effects of salinity and water depth on the growth of Melaleuca ericifolia Sm. (Swamp paperbark) seedlings[J]. Aquatic Botany, 2007, 86(3):213.
[27]	王树凤,胡韵雪,孙海菁,等.盐胁迫对2种栎树苗期生长和根系生长发育的影响[J].生态学报,2014,34(4):1021. WANG Shufeng, HU Yunxue, SUN Haiqing, et al. Effects of salt stress on growth and root development of two oak seedlings[J].Acta Ecologica Sinica,2014,34(4):1021.
[28]	张金林,李惠茹,郭姝媛,等.高等植物适应盐逆境研究进展[J].草业学报,2015,24(12):220. ZHANG Jinlin, LI Huiru, GUO Shuyuan, et al. Research advances in higher plant adaptation to salt stress[J]. Acta Prataculturae Sinica,2015,24(12):220.
[29]	何凌仙子,贾志清,刘涛,等.植物适应逆境胁迫研究进展[J].世界林业研究,2018,31(2):13. HE Lingxianzi, JIA Zhiqing, LIU Tao, et al. Research progress in plants adaptability towards adversity stress[J].World Forestry Research,2018,31(2):13.
[30]	杨升,张华新,张丽.植物耐盐生理生化指标及耐盐植物筛选综述[J].西北林学院学报,2010,25(3):59. YANG Sheng, ZHANG Xinhua, ZHANG Li. Physiological and biochemical indices of salt tolerance and scanning of salt-tolerance plants:A review[J].Journal of Northwest Forestry University,2010,25(3):59.
[31]	刘晶,才华,刘莹,等.两种紫花苜蓿苗期耐盐生理特性的初步研究及其耐盐性比较[J].草业学报,2013,22(2):250. LIU Jing, CAI Hua, LIU Ying, et al. A study on physiological characteristics and comparison of salt tolerance of two Medicago sativa at the seedling stage[J].Acta Prataculturae Sinica,2013,22(2):250.
[32]	李珍,云岚,石子英,等.盐胁迫对新麦草种子萌发及幼苗期生理特性的影响[J].草业学报,2019,28(8):119. LI Zhen, YUN Lan, SHI Ziying, et al. Physiological characteristics of Psathyrostachys juncea at seed germination and seedling growth stages under salt stress[J].Acta Prataculturae Sinica,2019,28(8):119.