构树对环境胁迫的响应机制研究进展

doi:10.14088/j.cnki.issn0439-8114.2019.21.001

摘要/Abstract

摘要： 构树具有较强的环境适应能力,能在多种逆境中维持正常的生长发育,是一种多功能综合性树种。构树对逆境的广适性是构树广泛分布的基础,也是作为生态环境修复树种的有力保障。综述了构树对非生物胁迫（干旱、盐碱、重金属、养分缺乏等）和生物胁迫（病虫害）抗性的研究进展,探讨了构树对不同逆境胁迫的生理生化响应机制,为构树资源的深入开发利用提供理论参考。

关键词: 构树, 生物胁迫, 非生物胁迫, 生态适应性

Abstract: Broussonetia papyrifera as a kind of multi-functional and comprehensive tree species, has a strong environmental adaptability and keeps the normal production and development in harsh habitats. The adaptability of Broussonetia papyrifera to adversity is the basis of its wide distribution, and also is a strong guarantee as a tree species for ecological environment restoration. The research status of resistance of Broussonetia papyrifera to both abiotic stresses （drought, salinity, heavy metal and nutrient deficiency etc.） and biotic stress （diseases and pests） were mainly reviewed,and the mechanisms of physiological and biochemical responses to different stresses were discussed, aiming to provide theoretical reference for the further development and utilization of Broussonetia papyrifera resources.

Key words: Broussonetia papyrifera, biotic stress, abiotic stress, ecological adaptability

中图分类号:

黄咏明, 卢素芳, 徐爱春, 戴永红, 郎鹏, 秦仲麒, 田瑞. 构树对环境胁迫的响应机制研究进展[J]. 湖北农业科学, 2019, 58(21): 5-9.

HUANG Yong-ming, LU Su-fang, XU Ai-chun, DAI Yong-hong, LANG Peng, QIN Zhong-qi, TIAN Rui. Research progress on response mechanisms of Broussonetia papyrifera to environmental stresses[J]. HUBEI AGRICULTURAL SCIENCES, 2019, 58(21): 5-9.

参考文献

[1] 何跃军,钟章成,刘锦春,等.石灰岩土壤基质上构树幼苗接种丛枝菌根(AM)真菌的光合特征[J].植物研究,2008,28(4):452-457.
[2] 张秋玉,李远发,梁芳.构树资源研究利用现状及其展望[J].广西农业科学,2009,40(2):217-220.
[3] 邳植,沈世华.构树作为新兴的蛋白饲料原料的研究[J].饲料工业,2018,39(11):23-28.
[4] 谢钊俊,夏玉芳,张克丽,等.不同树龄和起源构树纤维形态分析[J].西部林业科学,2015,44(6):110-114.
[5] 张婉,赵运林,唐永成.构树对干旱、盐碱和重金属胁迫的适应机制研究进展[J].植物学研究,2017,6(5):325-332.
[6] 叶波,吴永波,邵维,等.高温干旱复合胁迫及复水对构树(Broussonetia papyrifera)幼苗光合特性和叶绿素荧光参数的影响[J].生态学杂志,2014,33(9):2343-2349.
[7] 杨帆,丁菲,杜天真.盐胁迫下构树幼苗各器官中K+、Ca²+、Na+和Cl-含量分布及吸收特征[J].应用生态学报,2009,20(4):767-772.
[8] 蒋泽平,肖小君,何开跃.NaCl胁迫对构树、光叶楮生理及细胞结构的影响[J].南京林业大学学报(自然科学版),2010,34(3): 77-82.
[9] NAGPAL U M K,BANKAR A V,PAWAR N J,et al. Equilibrium and kinetic studies on biosorption of heavy metals by leaf powder of paper mulberry(Broussonetia papyrifera)[J].Water air and soil pollution,2011,215:177-188.
[10] XING D K,WU Y Y,YU R,et al.Photosynthetic capability and Fe,Mn,Cu,and Zn contents in two Moraceae species under different phosphorus levels[J].Acta Geochim,2016,35(3):309-315.
[11] 慕军鹏,陈红利.构树叶性状分化的生态功能初步研究[J].广西植物,2018,38(8):1088-1095.
[12] 李娜,郭学民,黎明,等.构树雌雄株叶片解剖结构特征的比较研究[J].植物科学学报,2017,35(2):164-170.
[13] 任媛媛,翟晓巧,刘艳萍.6个构树无性系叶片解剖结构与抗旱性的关系[J].陕西农业科学,2015,61(12):17-21.
[14] 丁菲,杨帆,李德龙,等.构树解剖结构特征与抗旱性研究[J].安徽农业科学,2010,38(36):20949-20952.
[15] 杨平,朱学慧,姬慧娟,等.温度和水分胁迫对构树种子萌发的影响[J].四川林业科技,2015,36(6):90-92.
[16] 丁菲,杨帆,杜天真.干旱胁迫对构树幼苗抗氧化酶活性变化的影响[J].江西农业大学学报,2008,30(4):680-683.
[17] 吴永波,叶波.高温干旱复合胁迫对构树幼苗抗氧化酶活性和活性氧代谢的影响[J].生态学报,2016,36(2):403-410.
[18] 黄华明. 水分胁迫对构树生理及形态的影响[J].安徽农学通报,2010,16(19):52-53.
[19] 魏媛,喻理飞.一年生构树幼苗对水分胁迫的生理响应[J].西北林学院学报,2010,25(4):40-44.
[20] LI M R,LI Y,LI H Q,et al.Overexpression of AtNHX5 improves tolerance to both salt and drought stress in Broussonetia papyrifera(L.) Vent[J].Tree physiology,2011,31(3):349-357.
[21] YAMAGUCHI-SHINOZAKAI K,SHINOZAKi K.Transcriptional regulatory networks in cellular response and the tolerance to dehydration and cold stresses[J].Annual review of plant biology,2006,57:781-803.
[22] SUN J W,PENG X J,FAN W H,et al.Functional analysis of BpDREB2 gene involved in salt and drought response from a woody plant Broussonetia papyrifera[J].Gene,2014,535:140-149
[23] JIA T J,AA J,LIU Z,et al.Salt stress induced soybean GmIFS1 expression and isoflavone accumulation and salt tolerance in transgenic soybean cotyledon hairy roots and tobacco[J].Plant cell tissue and organ culture,2017,128(2):469-477.
[24] ZHENG J,MA X H,ZHANG X L,et al.Salicylic acid promotes plant growth and salt-related gene expression in Dianthus superbus L.(Caryophyllaceae) grown under different salt stress conditions[J].Physiology and molecular biology of plants,2018, 24(2):231-238.
[25] ZHANG X K,ZHOU Q H,CAO J H,et al.Differential Cl-/salt tolerance and NaCl-induced alternations of tissue and cellular ion fluxes in Glycine max,Glycine soja and their hybrid seedlings[J].Journal of agronomy and crop science,2011,197:329-339.
[26] HASEGAWA P M.Sodium (Na+) homeostasis and salt tolerance of plants[J].Environmental and experimental botany,2013,92:19-31.
[27] MUCHATE N S,NIKALJE G C,RAJURKAR N S,et al.Plant salt stress:Adaptive responses,tolerance mechanism and bioengineering for salt tolerance[J].Botanical review,2016,82:371-406.
[28] 王爱霞,方炎明.NaCl胁迫对不同种源构树种子萌发及幼苗生长的影响[J].江苏农业科学,2016,44(8):257-261.
[29] 杨帆,丁菲,杜天真.盐胁迫对构树种子萌发及幼苗生理特性的影响[J].种子,2008,27(8):68-71.
[30] 吴纲,肖小君,何开跃,等.NaCl胁迫对构树种子发芽及幼苗生理生化指标的影响[J].江苏林业科技,2009,36(4):8-12.
[31] 肖小君. 构树和光叶楮对NaCl胁迫的响应[D].南京:南京林业大学,2009.
[32] 丁菲,杨帆,张国武,等.NaCl胁迫对构树幼苗叶片水势、光合作用及Na+、K+吸收和分配的影响[J].林业科学研究,2009, 22(3):428-433.
[33] 王素平,郭世荣,周国贤,等.NaCl胁迫下黄瓜幼苗体内K+、Na+和Cl-分布及吸收特性的研究[J].西北植物学报,2006,26(11):2281-2288.
[34] 张敏,黄利斌,王磊.NaCl胁迫下构树离子相对含量及分布的能谱分析[J].西南林业大学学报,2011,31(1):17-21.
[35] 闻志刚. 构树幼苗对盐胁迫的生理响应[D].北京:中国林业科学研究院,2018.
[36] 孙静文. 构树DREB转录因子及木质素合成代谢相关基因的克隆及功能分析[D].北京:中国科学院植物研究所,2006.
[37] 李岩. 异源表达两种抗逆相关基因改良光叶楮抗逆性的研究[D].乌鲁木齐:新疆大学,2007.
[38] ZHANG M,FANG Y M,LIANG Z H,et al.Enhanced expression of vacuolar H+-ATPase subunit E in the roots is associated with the adaptation of Broussonetia papyrifera to salt stress[J].PLoS One,2012,7(10):e48143.
[39] 张运红,和爱玲,杨占平,等.土壤改良剂对镉污染土壤小麦抗性、光合特性及产量的影响[J].河南农业科学,2018,47(12):57-63.
[40] 张帆,蒋宁俊.土壤重金属污染工程危害及修复方法[J].环境监测管理与技术,2010,22(4):58-60.
[41] 李敏,滕泽栋,朱静,等.解磷微生物修复土壤重金属污染研究进展[J].生态学报,2018,38(10):3393-3402.
[42] ZHAO K,WU Y Y.Rhizosphere calcareous soil P-extraction at the expense of organic carbon from root-exuded organic acids induced by phosphorus deficiency in several plant species[J].Soil science and plant nutrition,2014,60:640-650.
[43] 童方平,龙应忠,杨勿享,等.锑矿区构树富集重金属的特性研究[J].中国农学通报,2010,26(14):328-331.
[44] 栾以玲,姜志林,吴永刚.栖霞山矿区植物对重金属元素富集能力的探讨[J].南京林业大学学报(自然科学版),2008,32(6):69-72.
[45] 李贵,童方平,刘振华,等.植物原位阻截铅锌矿区土壤重金属效果和配置模式研究[J].中国农学通报,2012,28(31):61-64.
[46] 林晓燕,唐彪,熊云武,等.铅锌矿区土壤重金属含量及木本植物吸收特征[J].湖北农业科学,2016,55(18):4656-4659.
[47] 李欣,孙文,金政,等.燃煤火电厂周边土壤重金属污染状况及绿化树种对重金属的积累特性[J].上海交通大学学报(农业科学版),2016,34(4):21-29.
[48] 沈晓蔚,彭志,李欣,等.上海市月浦工业区道路绿化土壤重金属污染状况及木本绿化植物中重金属的积累[J].上海交通大学学报(农业科学版),2018,36(2):62-69.
[49] 麻占威,吴永贵,付天岭,等.不同植物凋落物对土法冶炼铅锌废渣的改良效果[J].贵州农业科学,2014,42(6):188-192.
[50] 王成,蒋泽平,李文青,等.FTIR-NIR研究镉胁迫对构树试管幼苗生长的影响与机理[J].农业环境科学学报,2014,33(4):673-679.
[51] 董晓辉. 构树叶部累积重金属的季节特征及保护酶的适应机制研究[D].长沙:中南林业科技大学,2010.
[52] XU Z G,DONG M,PENG X Y,et al.New insight into the molecular basis of cadmium stress responses of wild paper mulberry plant by transcriptome analysis[J].Ecotoxicology and environmental safety,2019,171:301-312.
[53] ZHAO K,WU Y Y.Effects of Zn deficiency and bicarbonate on the growth and photosynthetic characteristics of four plant species[J].PLoS One,2017,12(1):e0169812.
[54] SHAHBAZ A M,OKI Y,ADACHI T,et al.Phosphorus starvation induced root-mediated pH changes in solubilization and acquisition of sparingly soluble P sources and organic acids exudation by Brassica cultivars[J].Soil science and plant nutrition,2006,52:623-633.
[55] ZHAO X,LIU J F,XIA X L,et al.The evaluation of heavy metal accumulation and application of a comprehensive bio-concentration index for woody species on contaminated sites in Hunan,China[J].Environmental science and pollution research,2014,21:5076-5085.
[56] ZHAO K,WU Y Y.Effect of Zn deficiency and excessive bicarbonate on the allocation and exudation of organic acids in two Moraceae plants[J].Acta Geochim,2018,37(1):125-133.
[57] 赵宽,吴沿友.4种植物幼苗根茎叶及根系分泌物中低分子量有机酸的特征[J].西北植物学报,2014,34(5):1002-1007.
[58] MORGAN J A,BENDING G D,WHITE P J.Biological costs and benefits to plant-microbe interactions in the rhizosphere[J].Journal of experimental botany,2005,56(417):1729-1739.
[59] RICHARDSON A E,BAREA J M,MCNRILL A M,et al.Acquisition of phosphorus and nitrogen in the rhizosphere and plant growth promotion by microorganisms[J].Plant soil,2009,321:305-339.
[60] 罗燕,樊卫国.不同施磷水平下4种柑橘砧木的根际土壤有机酸、微生物及酶活性[J].中国农业科学,2014,47(5):955-967.
[61] 吴沿友,邢德科,刘莹.植物利用碳酸氢根离子的特征分析[J].地球与环境,2011,39(2):273-277.
[62] 李强,何媛媛,曹建华,等.植物碳酸酐酶对岩溶作用的影响及其生态效应[J].生态环境学报,2011,20(12):1867-1871.
[63] WU Y Y,XING D K.Effect of bicarbonate treatment on photosynthetic assimilation of inorganic carbon in two plant species of Moraceae[J].Photosynthetica,2012,50(4):587-594.
[64] 梁静. 构树和桑树对聚乙二醇诱导的干旱以及低磷的生理响应[D].江苏镇江:江苏大学,2010.
[65] 吴沿友,梁铮,邢德科.模拟干旱胁迫下构树和桑树的生理特征比较[J].广西植物,2011,31(1):92-96.
[66] LIU Q Z,WU T Q,DAVIS R E,et al.First report of witches′-broom disease of Broussonetia papyrifera and its association with a phytoplasma of elm yellows group(16SrV)[J].Plant disease,2004,88(7):770-770.
[67] MEI C J,WANG Q C,GUI J C,et al.Molecular identification of ‘Candidatus phytoplasma asteris’ related strain (16SrΙ-B) associated with Broussonetia papyrifera in Nanjing,China[J].European journal of plant pathology,2016,145(1):203-207.
[68] 廖为财,魏洪义,王广利.桑天牛对不同补充营养材料及环境条件的行为响应[J].生物灾害科学,2012,35(1):78-84.
[69] 杨爽,李婧,李海鹏,等.构树小线角木蠹蛾的发生及防治方法[J].国际沙棘研究与开发,2014,2(2):35-38.
[70] 王哲宇,童丽丽,汤庚国.淹水胁迫对构树幼苗形态及生理特性的影响[J].甘肃农业大学学报,2013,48(6):99-103.
[71] PENG X J,TENG L H,YAN X Q,et al.The cold responsive mechanism of the paper mulberry:Decreased photosynthesis capacity and increased starch accumulation[J].BMC Genomics,2015,16:898.
[72] PENG X J,WU Q Q,TENG L H,et al.Transcriptional regulation of the paper mulberry under cold stress as revealed by a comprehensive analysis of transcription factors[J].BMC Plant Biology,2015,15:108.
[73] 王宏远,韩志敏,刘子琦.中国喀斯特地区石漠化成因及其危害研究概述[J].安徽农业科学,2011,39(11):6680-6684.