柽柳属(Tamarix)植物生境适应机制与资源价值研究进展

doi:10.7522/j.issn.1000-694X.2014.00213

摘要/Abstract

摘要： 柽柳属(Tamarix)植物起源于第三纪古地中海地区,具有耐盐碱、抗干旱和抗沙埋等特点,适应性强,是沙荒地和盐碱地的建群种。从植物生理生态和分子机理上阐述了柽柳属植物适应广泛生境的机制,包括种群特征、个体形态结构、种子繁殖特性、群体遗传结构以及植株在干旱和盐碱胁迫下生理生化和分子响应等,综述了其在生态和药用方面的价值,并提出可深入研究的问题和方向。

关键词: 柽柳属(Tamarix), 生理生态适应, 分子机制, 资源价值

Abstract: The plant of the genus Tamarix was an Old World genus occurred in Mediterranean region since Tertiary. As constructive species on the sandy and salty soil, they played important roles in sandy fixation and fragile ecosystem restoration. From the views of eco-physiological and molecular levels, this paper reviewed the mechanism of the adaptation of diverse habitats, including the aspects of community character, morphology, seed propagation, genetic variation. By summarizing their physiological, biochemical and molecular response under drought and saline-alkali stress, the paper re-evaluated its roles in ecological restoration, medicine and health. The aim of this review was to propose the issues and directions in the further studies and to provide theoretical references for research and utilization of Tamarix plant.

Key words: Tamarix, eco-physiological adaptability, molecular mechanism, resource value

中图分类号:

孙丽坤, 刘万秋, 陈拓, 刘光琇. 柽柳属(Tamarix)植物生境适应机制与资源价值研究进展[J]. 中国沙漠, 2016, 36(2): 349-356.

Sun Likun, Liu Wanqiu, Chen Tuo, Liu Guangxiu. Review on Mechanism of Habitat Adaptability and Resource Value of Tamarix Species[J]. JOURNAL OF DESERT RESEARCH, 2016, 36(2): 349-356.

参考文献

[1] 张道远,潘伯荣,尹林克.柽柳科柽柳属的植物地理研究[J].云南植物研究,2003,25(4):415-427.
[2] Gaskin J F,Schaal B A.Molecular phylogenetic investigation of US invasive Tamarix[J].Systematic Botany,2003,28(1):86-95.
[3] Bunge A G.Tentamen Generis Tamaricum Species Accuratius Definiendi[M].Dorpati,Germany,1852.
[4] Niedenzu F.Tamaricaceae[M]//Engler A,Prantl K.Die natürl.Pflanzenfam.1925.
[5] Baum B B.The genus Tamarix[M].Jerusale,Isreal:Academic Press,1978.
[6] Qaiser M.The genus Tamarix (Tamaricaceae) in Pakistan[J].Iranian Journal of Botany,1983,2(1):21-68.
[7] 赵景奎.黄河三角洲柽柳群体遗传多样性的研究[D].南京:南京林业大学,2006.
[8] 吴征镒.中国植物志[M].北京:科学出版社,1999.
[9] 张鹏云,张耀甲,刘名庭.柽柳属植物的分类特征[J].干旱区研究,1989,6(3):1-9.
[10] 张道远,陈之端,孙海英,等.用核糖体DNA的ITS序列探讨中国柽柳科植物系统分类中的几个问题[J].西北植物学报,2000,20(3):421-431.
[11] 华丽,张道远,潘伯荣.中国柽柳属和水柏枝属的分子系统学研究[J].云南植物研究,2004,26(3):283-289.
[12] 张瑾,陈文业,张继强.甘肃敦煌西湖荒漠-湿地生态系统优势植物种群分布格局及种间关联性[J].中国沙漠,2013,33(2):349-357.
[13] 霍红,冯起,苏永红,等.额济纳绿洲植物群落种间关系和生态位研究[J].中国沙漠,2013,33(4):1027-1033.
[14] 武志博,田永祯,赵菊英,等.额济纳绿洲重盐地多枝柽柳分布格局研究[J].中国沙漠,2013,33(1):106-109.
[15] 杨尧军,袁宏波,刘淑娟,等.库姆塔格沙漠沙生柽柳种群与环境因子分析[J].干旱区研究,2013,30(5):827-831.
[16] 侯佳文,海米提·依米提,叶茂.博斯腾湖滨柽柳(Tamarix ramosissima)生长对湖水位的敏感性[J].中国沙漠,2015,35(3):667-673.
[17] 赵振勇,王让会,张慧芝,等.天山南麓山前平原柽柳灌丛地上生物量[J].应用生态学报,2006,17(9):1557-1562.
[18] 贺强,崔保山,赵欣胜,等.水盐梯度下黄河三角洲湿地植物种的生态位[J].应用生态学报,2008,19(5):969-975.
[19] 荣戗戗,刘京涛,夏江宝,等.莱州湾湿地柽柳叶片N、P生态化学计量学特征[J].生态学杂志,2012,31(12):3032-3037.
[20] 蒋礼学,李彦.三种荒漠灌木根系的构形特征与叶性因子对干旱生境的适应性比较[J].中国沙漠,2008,28(6):1118-1124.
[21] 曾凡江,张希明,李小明.柽柳的水分生理特性研究进展[J].应用生态学报,2002,13(5):611-614.
[22] Chen Y N,Zhou H H,Chen Y P.Adaptation strategies of desert riparian forest vegetation in response to drought stress[J].Ecohydrology,2013,6(6):956-973.
[23] 张道远,谭敦炎,张娟,等.国产柽柳属16种植物当年生小枝比较解剖及其生态意义[J].云南植物研究,2003,25(6):653-662.
[24] 李尝君,郭京衡,曾凡江,等.多枝柽柳(Tamarix ramosissima)根、冠构型的年龄差异及其适应意义[J].中国沙漠,2015,35(2):365-372.
[25] Abbruzzese G,Kuzminsky E,Abou Jaoude R,et al.Leaf epidermis morphological differentiation between Tamarix africana Poir. and Tamarix gallica L.(Tamaricaceae) with ecological remarks[J].Plant Biosystems,2013,147(3):573-582.
[26] 张道远,尹林克,潘伯荣.柽柳泌盐腺结构、功能及分泌机制研究进展[J].西北植物学报,2003,23(1):190-194.
[27] Wilgus F,Hamilton K.Germination of salt cedar seed[J].Weeds,1962,10(4):332-333.
[28] 王仲礼.黄河三角洲柽柳(Tamarix chinensis)有性生殖过程及其适应性的研究[D].南京:南京林业大学,2005.
[29] 陈敏,刘林德,张莉,等.黑河中游和烟台海滨中国柽柳的传粉生态学研究[J].植物生态学报,2012,47(3):264-270.
[30] 严成,魏岩,王磊.密花柽柳的两季开花结实及其生态意义[J].干旱区研究,2011,28(2):335-340.
[31] 王建刚,李霞,石瑞花,等.不同水分条件刚毛柽柳开花结实观测[J].生态学杂志,2008,27(3):328-332.
[32] 张道远,尹林克,潘伯荣.柽柳属植物抗旱性能研究及其应用潜力评价[J].中国沙漠,2003,23(3):252-256.
[33] Zhou H H,Chen Y N,Li W H,et al.Xylem hydraulic conductivity and embolism in riparian plants and their responses to drought stress in desert of Northwest China[J].Ecohydrology,2013,6(6):984-993.
[34] 付爱红,陈亚宁,陈亚鹏.塔里木河下游干旱胁迫下多枝柽柳茎水势的变化[J].生态学杂志,2008,27(4):532-538.
[35] 袁国富,张佩,薛沙沙,等.沙丘多枝柽柳灌丛根层土壤含水量变化特征与根系水力提升证据[J].植物生态学报,2012,36(10):1033-1042.
[36] 刘冰,赵文智.荒漠绿洲过渡带柽柳和泡泡刺光合作用及水分代谢的生态适应性[J].中国沙漠,2009,29(1):101-107.
[37] 朱成刚,李卫红,马建新,等.塔里木河下游地下水位对柽柳叶绿素荧光特性的影响[J].应用生态学报,2010,21(7):1689-1696.
[38] 陈阳,王贺,张福锁,等.新疆荒漠盐碱生境柽柳盐分分泌特点及其影响因子[J].生态学报,2010,30(2):511-518.
[39] 朱军涛,李向义,张希明,等.4种荒漠植物的抗氧化系统和渗透调节的季节变化[J].中国沙漠,2011,31(6):1467-1471.
[40] 王霞,尹林克.土壤缓慢水分胁迫下柽柳植物内源激素的变化[J].新疆农业大学学报,2000,23(4):41-43.
[41] 张娟,尹林克,张道远.刚毛柽柳天然居群遗传多样性初探[J].云南植物研究,2003,25(5):557-562.
[42] 李锐.柽柳SSR标记开发及群体遗传结构分析[D].南京:南京林业大学,2007.
[43] 张如华.柽柳群体遗传变异研究[D].南京:南京林业大学,2011.
[44] Gaskin J F,Schaal B A.Hybrid Tamarix widespread in U.S.invasion and undetected in native Asian range[J].PNAS,2002,99(17):11256-11259.
[45] Gaskin J F,Kazmer D J.Introgression between invasive saltcedars (Tamarix chinensis and T.ramosissima) in the USA[J].Biological Invasions,2009,11(5):1121-1130.
[46] Williams W I,Friedman J M,Gaskin J F,et al.Hybridization of an invasive shrub affects tolerance and resistance to defoliation by a biological control agent[J].Evolutionary Applications,2014,7(3):381-393.
[47] 杨允菲,祝廷成.植物生态学[M].北京:高等教育出版社,2011:312-314.
[48] 王玉成.柽柳抗逆分子机理研究与相关基因的克隆[D].哈尔滨:东北林业大学,2005.
[49] Li H Y,Wang Y C,Jiang J,et al.Identification of genes responsive to salt stress on Tamarix hispida roots[J].Gene,2009,433(1):65-71.
[50] Gao C Q,Wang Y C,Liu G F,et al.Cloning of ten peroxidase (POD) genes from Tamarix hispida and characterization of their responses to abiotic stress[J].Plant Molecular Biology Reporter,2010,28(1):77-89.
[51] Wang C,Gao C Q,Wang L Q,et al.Comprehensive transcriptional profiling of NaHCO₃-stressed Tamarix hispida roots reveals networks of responsive genes[J].Plant Molecular Biology,2013,84(1/2):145-157.
[52] Zheng L,Liu G F,Meng X N,et al.A WRKY gene from Tamarix hispida,ThWRKY4,mediates abiotic stress responses by modulating reactive oxygen species and expression of stress-responsive genes[J].Plant Molecular Biology,2013,82(4/5):303-320.
[53] Wang L Q,Wang C,Wang D,et al.Molecular characterization and transcript profiling of NAC genes in response to abiotic stress in Tamarix hispida[J].Tree Genetics and Genomes,2014,10(1):157-171.
[54] Yang G Y,Wang Y C,Xia D,et al.Overexpression of a GST gene (ThGSTZ1) from Tamarix hispida improves drought and salinity tolerance by enhancing the ability to scavenge reactive oxygen species[J].Plant Cell Tissue and Organ Culture,2014,117(1):99-112.
[55] Yang G Y,Wang Y C,Zhang K M,et al.Expression analysis of nine small heat shock protein genes from Tamarix hispida in response to different abiotic stresses and abscisic acid treatment[J].Molecular Biology Reports,2014,41(3):1279-1289.
[56] Liu W J,Wang Y C,Gao C Q.The ethylene response factor (ERF) genes from Tamarix hispida respond to salt,drought and ABA treatment[J].Trees-Structure and Function,2014,28(2):317-327.
[57] 杨丽文,何秉宇,黄培佑,等.和田河流域天然柽柳灌木林生态价值评估[J].中国沙漠,2005,25(2):268-274.
[58] 樊自立,徐海量,傅荩仪,等.塔里木河下游生态保护目标和措施[J].中国沙漠,2013,33(4):1191-1197.
[59] 潘文利和于雷.辽河三角洲盐碱地防护林体系建设技术研究[J].应用生态学杂志.1998,9(3):231-236.
[60] Ebrahimabadi A,Alavi I.Plant type seletion for reclamation of Sarcheshmeh copper mine using fuzzy-topsis approach[J].Archives of Mining Sciences,2013,58(3):953-968.
[61] Masciandaro G,Di Biase A,Macci C,et al.Phytoremediation of dredged marine sediment:Monitoring of chemical and biochemical processes contributing to sediment reclamation[J].Journal of Environmental Management,2014,134:166-174.
[62] Manousaki E,Kadukova J,Papadantonakis N,et al.Phytoextraction and phytoexcretion of Cd by the leaves of Tamarix smyrnensis growing on contaminated non-saline and saline soils[J].Environmental Research,2008,106(3):326-332.
[63] Manners R B,Schmidt J C,Scott M L.Mechanisms of vegetation-induced channel narrowing of an unregulated canyon river:Results from a natural field-scale experiment[J].Geomorphology,2014,211:100-115.
[64] 黄时伟,梁敬钰.柽柳属植物研究进展[J].海峡药学,2007,19(3):5-8.
[65] Mouri C,Mozaffarian V,Zhang X,et al.Characterization of flavonols in plants used for textile dyeing and the significance of flavonol conjugates[J].Dyes and Pigments,2014,100:135-141.
[66] 张媛,屠鹏飞.柽柳属药用植物研究进展[J].中草药.2008,39(6):947-951.
[67] 廖菁,邢亚超,李宁,等.柽柳属植物的化学成分和药理活性研究进展[J].现代药物与临床,2012,27(4):404-408.
[68] Assiri A M A.Protective effect of Tamarix amplexicaulis seeds against hepatotoxicity induced by carbon tetrachloride,paracetamol,or D-galactosamine[J].Journal of Saudi Chemistry Society,2006,10(3):437-446.
[69] Sehrawat A,Sultana S.Tamarix gallica ameliorates thioacetamide-induced hepatic oxidative stressand hyperproliferative response in Wistar rat[J].Journal of Enzyme Inhibition Medical Chemistry,2006,21(2):215-223.
[70] Ksouri R,Falleh H,Megdiche W,et al.Antioxidant and antimicrobial activities of the edible medicinal halophyte Tamarix gallica L.and related polyphenolic constituents [J].Food Chem Toxicol,2009,47(8):2083-2091.
[71] Boulaaba M,Tsolmon S,Ksouri R,et al.Anticancer effect of Tamarix gallica extracts on human colon cancer cells involves Erk1/2 and p38 action on G(2)/M cell cycle arrest[J].Cytotechnology,2013,65(6):927-936.
[72] Ionescu D,Aldea I M,Bleotu C,et al.Evalution of cytotoxic activities of Tamarix gallica and Silybum marianum extracts[J].Farmacia,2014,62(2):329-340.
[73] Farzaei M H,Abbasabadi Z,Shams-Ardekani M R.A comprehensive review of plant and their active constitutes with wound healing activity in traditional medicine[J].Wounds-a Compendium of Clinical Research and Practice,2014,26(7):197-206.