外生菌根真菌提高马尾松幼苗的抗旱性研究进展
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摘要
该文对外生菌根增强苗木抗性机理及提高马尾松幼苗的抗旱性研究进行了综述,旨在为菌根化马尾松幼苗抗旱性育种提供参考。
This paper reviews the research on the ectomycorrhizal enhanced seedling resistance and drought resistance of Pinus massoniana seedlings,in order to provide reference for drought resistance breeding of mycorrhizal Pinus massoniana seedlings.
This paper reviews the research on the ectomycorrhizal enhanced seedling resistance and drought resistance of Pinus massoniana seedlings,in order to provide reference for drought resistance breeding of mycorrhizal Pinus massoniana seedlings.
引文
[1]Pohjanen J,Koskim?ki J J,Pirttil?A M.Interactions of Meristem-Associated Endophytic Bacteria[M].Advances in Endophytic Research,2014.
[2]Averill C,Turner B,Finzi A.Mycorrhiza-mediated competition between plants and decomposers drives soil carbon storage[J].Nature,2014,505(7484):543-545.
[3]Pena R,Lang C,Lohaus G,et al.Phylogenetic and functional traits of ectomycorrhizal assemblages in top soil from different biogeographic regions and forest types.[J].Mycorrhiza,2016,27(3):1-13.
[4]Martin F,Duplessis S,Ditengou F,et al.Developmental cross talking in the ectomycorrhizal symbiosis:signals and communication genes.[J].New Phytologist,2010,151(1):145-154.
[5]Ostonen I,Helmisaari H S,Borken W,et al.Fine root foraging strategies in Norway spruce forests across a European climate gradient[J].Global Change Biology,2011,17(12):3620-3632.
[6]佟丽华,张红光,姚鑫.外生菌根真菌的作用与应用开发前景展望[J].安徽农学通报,2008,14(14):86-89.
[7]邓勋,宋小双,尹大川,等.深色有隔内生真菌与褐环乳牛肝菌双接种对樟子松生长及抗立枯病的影响[J].中国森林病虫,2017,36(1):21-25.
[8]于浩,陈展,尚鹤,等.野外模拟酸雨胁迫下接种外生菌根真菌对马尾松幼苗的缓解作用[J].生态学报,2017,37(16):5418-5427.
[9]温祝桂,王杰,汤阳泽,等.外生菌根真菌彩色豆马勃(Pisolithu stinctorius)辅助植物修复重金属Cu污染土壤的应用潜力[J].生物技术通报,2017,33(4):149-156.
[10]温祝桂,朱小梅,刘冲,等.两株外生菌根真菌对盐渍土壤中黑松幼苗生长的影响[J].中南林业科技大学学报,2019(04):22-27.
[11]王艺,丁贵杰.干旱胁迫对马尾松菌根化苗木生长的影响[J].森林与环境学报,2016,36(2):173-179.
[12]叶锦培,黄振格,梁彩霞,等.外生菌根真菌接种与铝胁迫对土贡松幼苗生长的影响[J].山西农业科学,2018,46(11):1867-1870,1892.
[13]Pent M,P?ldmaa K,Bahram M.Bacterial Communities in Boreal Forest Mushrooms Are Shaped Both by Soil Parameters and Host Identity[J].Frontiers in Microbiology,2017,8:836.
[14]辜夕容,倪亚兰,江亚男,等.接种双色蜡蘑对马尾松根际土壤无机磷和活性铝含量的影响[J].土壤学报,2018,55(05):1179-1189.
[15]孙帅,张小晶,刘金平,等.遮阴和干旱对荩草生理代谢及抗性系统影响的协同作用[J].生态学报,2018,38(5):1770-1779.
[16]李冀南,李朴芳,孔海燕,等.干旱胁迫下根源化学信号研究进展[J].生态学报,2011,31(9):2610-2620.
[17]Park S Y,Peterson F C,Mosquna A,et al.Agrochemical control of plant water use using engineered abscisic acid receptors[J].Nature,2015,520(7548):545-548.
[18]张文泉.樟子松外生菌根真菌多样性及菌根生物技术研究[D].呼和浩特:内蒙古农业大学,2013.
[19]Warren J M,Brooks J R,Meinzer F C,et al.Hydraulic redistribution of water from Pinus ponderosa trees to seedlings:evidence for an ectomycorrhizal pathway[J].New Phytologist,2008,178(2):382-394.
[20]Querejeta J,Egerton-Warburton L,Allen M F.Hydraulic lift may buffer rhizosphere hyphae against the negative effects of severe soil drying in a California Oak savanna[J].Soil Biology and Biochemistry,2007,39(2):409-417.
[21]王琚钢,峥嵘,白淑兰,等.外生菌根对干旱胁迫的响应[J].生态学杂志,2012,31(6):1571-1576.
[22]王如岩,于水强,张金池,等.干旱胁迫下接种菌根真菌对滇柏和楸树幼苗根系的影响[J].南京林业大学学报,2012,36(6):23-27.
[23]Stonor R,Smith S,Manjarrez M,Facelli E,Smith F.Mycorrhizal responses in wheat:shading decreases growth but does not lower the contribution of the fungal phosphate uptake pathway[J].Mycorrhiza,2014,1-8.
[24]Facelli E,Duan T,Smith S.Opening the black box:outcomes of interactions between arbuscular mycorrhizal(AM)and nonhost genotypes of Medicago depend on fungal identity,interplay between P uptake pathways and external P supply[J].Plant Cell&Environment,2014,37(6):1382-1392.
[25]Chen A,Gu M,Sun S.Identification of two conserved cis-acting elements,MYCS and PIBS,involved in the regulation of mycorrhiza-activate phosphate transporters in eudicot species[J].New Phytologist,2011,189(4):1157-1169.
[26]El-Mesbahi M,Azcon R,Ruiz-Lozano J.Plant potassium content modifies the effects of arbuscualar mycrrhizal symbiosis on root hydraulic properties in maize plants[J].Mycorrhiza,2012,22(7):555-564.
[27]张中峰,张金池,黄玉清,等.接种菌根真菌对青冈栎幼苗耐旱性的影响[J].生态学报,2016,36(11):3402-3410.
[28]张珍明,贺红早,张家春,等.接种外生菌根菌对无籽刺梨生长和碳、氮、磷分布的影响[J].北方园艺,2016(04):151-154.
[29]马琼,黄建国,蒋剑波.接种外生菌根真菌对马尾松幼苗生长的影响[J].福建林业科技,2005,32(2):85-88.
[30]徐超,吴小芹.菌根化马尾松对干旱胁迫的响应及其内源多胺的变化[J].西北植物学报,2009,29(2):0296-0301.
[31]张婷,丁贵杰,文晓鹏.菌根化马尾松磷转运蛋白家族基因的生物信息学和表达分析[J].西南大学学报(自然科学版),2017,39(5):90-98.
[32]张中峰.菌根真菌对青冈栎幼苗耐旱性和土壤特性的影响及机理研究[D].南京:南京林业大学,2015.
[33]张亮,王明霞,张薇,等.外生菌根真菌对土壤钾的活化作用[J].微生物学报,2014,54(7):786-792.
[34]庞丽杰,王文革,宋富强.3株外生菌根真菌对红松苗木的接种效应[J].防护林科技,2015(11):41-43.
[35]Miransari M,Abrishamchi A,Khoshbakht K.Plant hormones as singals in arbuscular mycorrhizal symbiosis[J].Critical reviews in biotechnology,2013,1-12.
[36]宋瑞清,吴克.红皮云杉外生菌根菌对苗木生长的影响[J].微生物学报,2005,45(6):910-914.
[37]周政贤.中国马尾松[M].北京:中国林业出版社,2001.
[38]王艺,丁贵杰.干旱胁迫下外生菌根真菌对马尾松幼苗生长和微量元素吸收的影响[J].浙江农林大学学报,2012,29(6):822-828.
[39]王艺,丁贵杰.水分胁迫下外生菌根对马尾松幼苗养分吸收的影响[J].林业科学研究,2013(02):227-233.
[40]翟帅帅,丁贵杰,王艺,等.褐环乳牛肝菌对马尾松幼苗根系构型的影响[J].森林与环境学报,2015(3):243-248.
[41]王艺,丁贵杰.外生菌根对马尾松幼苗生长、生理特征和养分的影响[J].南京林业大学学报(自然科学版),2013,37(2):97-102.
[42]陈文霞.马尾松遗传连锁图谱构建[D].南京:南京林业大学,2010.
[43]梅利娜,范付华,崔博文.基于马尾松转录组的SSR分子标记开发及种质鉴定[J].农业生物技术学报,2017,06(25):991-1002.
[44]崔博文,范付华,丁贵杰.基于马尾松反转录转座子序列的IRAP分子标记开发及应用[J].林业科学研究,2016,29(03):348-353.
[45]阮维程,潘婷,季孔庶.马尾松纤维素合成酶基因PmCesA1的克隆及其分析[J].分子植物育种,2015,04(13):861-870.
[46]陈虎,贾婕,罗群风.马尾松谷胱甘肽过氧化物酶PmGPX基因的克隆及表达分析[J].浙江农林大学学报,2017,05(34):856-863.
[47]蔡琼,丁贵杰,文晓鹏.马尾松水通道蛋白PmPIP1基因克隆及在干旱胁迫下的表达分析[J].浙江农林大学学报,2016(02):191-200.
[2]Averill C,Turner B,Finzi A.Mycorrhiza-mediated competition between plants and decomposers drives soil carbon storage[J].Nature,2014,505(7484):543-545.
[3]Pena R,Lang C,Lohaus G,et al.Phylogenetic and functional traits of ectomycorrhizal assemblages in top soil from different biogeographic regions and forest types.[J].Mycorrhiza,2016,27(3):1-13.
[4]Martin F,Duplessis S,Ditengou F,et al.Developmental cross talking in the ectomycorrhizal symbiosis:signals and communication genes.[J].New Phytologist,2010,151(1):145-154.
[5]Ostonen I,Helmisaari H S,Borken W,et al.Fine root foraging strategies in Norway spruce forests across a European climate gradient[J].Global Change Biology,2011,17(12):3620-3632.
[6]佟丽华,张红光,姚鑫.外生菌根真菌的作用与应用开发前景展望[J].安徽农学通报,2008,14(14):86-89.
[7]邓勋,宋小双,尹大川,等.深色有隔内生真菌与褐环乳牛肝菌双接种对樟子松生长及抗立枯病的影响[J].中国森林病虫,2017,36(1):21-25.
[8]于浩,陈展,尚鹤,等.野外模拟酸雨胁迫下接种外生菌根真菌对马尾松幼苗的缓解作用[J].生态学报,2017,37(16):5418-5427.
[9]温祝桂,王杰,汤阳泽,等.外生菌根真菌彩色豆马勃(Pisolithu stinctorius)辅助植物修复重金属Cu污染土壤的应用潜力[J].生物技术通报,2017,33(4):149-156.
[10]温祝桂,朱小梅,刘冲,等.两株外生菌根真菌对盐渍土壤中黑松幼苗生长的影响[J].中南林业科技大学学报,2019(04):22-27.
[11]王艺,丁贵杰.干旱胁迫对马尾松菌根化苗木生长的影响[J].森林与环境学报,2016,36(2):173-179.
[12]叶锦培,黄振格,梁彩霞,等.外生菌根真菌接种与铝胁迫对土贡松幼苗生长的影响[J].山西农业科学,2018,46(11):1867-1870,1892.
[13]Pent M,P?ldmaa K,Bahram M.Bacterial Communities in Boreal Forest Mushrooms Are Shaped Both by Soil Parameters and Host Identity[J].Frontiers in Microbiology,2017,8:836.
[14]辜夕容,倪亚兰,江亚男,等.接种双色蜡蘑对马尾松根际土壤无机磷和活性铝含量的影响[J].土壤学报,2018,55(05):1179-1189.
[15]孙帅,张小晶,刘金平,等.遮阴和干旱对荩草生理代谢及抗性系统影响的协同作用[J].生态学报,2018,38(5):1770-1779.
[16]李冀南,李朴芳,孔海燕,等.干旱胁迫下根源化学信号研究进展[J].生态学报,2011,31(9):2610-2620.
[17]Park S Y,Peterson F C,Mosquna A,et al.Agrochemical control of plant water use using engineered abscisic acid receptors[J].Nature,2015,520(7548):545-548.
[18]张文泉.樟子松外生菌根真菌多样性及菌根生物技术研究[D].呼和浩特:内蒙古农业大学,2013.
[19]Warren J M,Brooks J R,Meinzer F C,et al.Hydraulic redistribution of water from Pinus ponderosa trees to seedlings:evidence for an ectomycorrhizal pathway[J].New Phytologist,2008,178(2):382-394.
[20]Querejeta J,Egerton-Warburton L,Allen M F.Hydraulic lift may buffer rhizosphere hyphae against the negative effects of severe soil drying in a California Oak savanna[J].Soil Biology and Biochemistry,2007,39(2):409-417.
[21]王琚钢,峥嵘,白淑兰,等.外生菌根对干旱胁迫的响应[J].生态学杂志,2012,31(6):1571-1576.
[22]王如岩,于水强,张金池,等.干旱胁迫下接种菌根真菌对滇柏和楸树幼苗根系的影响[J].南京林业大学学报,2012,36(6):23-27.
[23]Stonor R,Smith S,Manjarrez M,Facelli E,Smith F.Mycorrhizal responses in wheat:shading decreases growth but does not lower the contribution of the fungal phosphate uptake pathway[J].Mycorrhiza,2014,1-8.
[24]Facelli E,Duan T,Smith S.Opening the black box:outcomes of interactions between arbuscular mycorrhizal(AM)and nonhost genotypes of Medicago depend on fungal identity,interplay between P uptake pathways and external P supply[J].Plant Cell&Environment,2014,37(6):1382-1392.
[25]Chen A,Gu M,Sun S.Identification of two conserved cis-acting elements,MYCS and PIBS,involved in the regulation of mycorrhiza-activate phosphate transporters in eudicot species[J].New Phytologist,2011,189(4):1157-1169.
[26]El-Mesbahi M,Azcon R,Ruiz-Lozano J.Plant potassium content modifies the effects of arbuscualar mycrrhizal symbiosis on root hydraulic properties in maize plants[J].Mycorrhiza,2012,22(7):555-564.
[27]张中峰,张金池,黄玉清,等.接种菌根真菌对青冈栎幼苗耐旱性的影响[J].生态学报,2016,36(11):3402-3410.
[28]张珍明,贺红早,张家春,等.接种外生菌根菌对无籽刺梨生长和碳、氮、磷分布的影响[J].北方园艺,2016(04):151-154.
[29]马琼,黄建国,蒋剑波.接种外生菌根真菌对马尾松幼苗生长的影响[J].福建林业科技,2005,32(2):85-88.
[30]徐超,吴小芹.菌根化马尾松对干旱胁迫的响应及其内源多胺的变化[J].西北植物学报,2009,29(2):0296-0301.
[31]张婷,丁贵杰,文晓鹏.菌根化马尾松磷转运蛋白家族基因的生物信息学和表达分析[J].西南大学学报(自然科学版),2017,39(5):90-98.
[32]张中峰.菌根真菌对青冈栎幼苗耐旱性和土壤特性的影响及机理研究[D].南京:南京林业大学,2015.
[33]张亮,王明霞,张薇,等.外生菌根真菌对土壤钾的活化作用[J].微生物学报,2014,54(7):786-792.
[34]庞丽杰,王文革,宋富强.3株外生菌根真菌对红松苗木的接种效应[J].防护林科技,2015(11):41-43.
[35]Miransari M,Abrishamchi A,Khoshbakht K.Plant hormones as singals in arbuscular mycorrhizal symbiosis[J].Critical reviews in biotechnology,2013,1-12.
[36]宋瑞清,吴克.红皮云杉外生菌根菌对苗木生长的影响[J].微生物学报,2005,45(6):910-914.
[37]周政贤.中国马尾松[M].北京:中国林业出版社,2001.
[38]王艺,丁贵杰.干旱胁迫下外生菌根真菌对马尾松幼苗生长和微量元素吸收的影响[J].浙江农林大学学报,2012,29(6):822-828.
[39]王艺,丁贵杰.水分胁迫下外生菌根对马尾松幼苗养分吸收的影响[J].林业科学研究,2013(02):227-233.
[40]翟帅帅,丁贵杰,王艺,等.褐环乳牛肝菌对马尾松幼苗根系构型的影响[J].森林与环境学报,2015(3):243-248.
[41]王艺,丁贵杰.外生菌根对马尾松幼苗生长、生理特征和养分的影响[J].南京林业大学学报(自然科学版),2013,37(2):97-102.
[42]陈文霞.马尾松遗传连锁图谱构建[D].南京:南京林业大学,2010.
[43]梅利娜,范付华,崔博文.基于马尾松转录组的SSR分子标记开发及种质鉴定[J].农业生物技术学报,2017,06(25):991-1002.
[44]崔博文,范付华,丁贵杰.基于马尾松反转录转座子序列的IRAP分子标记开发及应用[J].林业科学研究,2016,29(03):348-353.
[45]阮维程,潘婷,季孔庶.马尾松纤维素合成酶基因PmCesA1的克隆及其分析[J].分子植物育种,2015,04(13):861-870.
[46]陈虎,贾婕,罗群风.马尾松谷胱甘肽过氧化物酶PmGPX基因的克隆及表达分析[J].浙江农林大学学报,2017,05(34):856-863.
[47]蔡琼,丁贵杰,文晓鹏.马尾松水通道蛋白PmPIP1基因克隆及在干旱胁迫下的表达分析[J].浙江农林大学学报,2016(02):191-200.