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2025年5月16日 周五
首页 > 过刊浏览>2024年第51卷第11期 >4451-4463. DOI:10.13344/j.microbiol.china.240169
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齿瓣石斛不同月龄幼苗根内共生真菌多样性动态变化分析
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国家自然科学基金(32171655);中国科学院西部之光青年学者项目(E1XB011B01);中国科学院西双版纳热带植物园"十四五"规划项目(E3ZKFF8B)


Dynamics of symbiotic fungal diversity in roots of Dendrobium devonianum seedlings at different developmental stages
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    摘要:

    【背景】兰科植物整个生命周期都与真菌形成密切的共生关系,种子萌发、幼苗形成等关键发育阶段都需要共生真菌为其提供营养。【目的】探究齿瓣石斛(Dendrobium devonianum)不同月龄幼苗共生真菌多样性及其变化规律。【方法】基于种子-真菌野外直播技术获得齿瓣石斛不同月龄幼苗并采集根样品,采用扩增子测序技术研究共生真菌群落组成、相对丰度及多样性。【结果】齿瓣石斛2‒6月龄幼苗中共有944个扩增子序列变体(amplicon sequence variant, ASV),隶属5门24纲71目144科218属。2‒4月龄幼苗的优势真菌为无孢蜡壳属(Serendipita)、篮状菌属(Talaromyces)和弯孢属(Curvularia),6月龄幼苗的优势真菌为篮状菌属和蜡壳耳属(Sebacina)。优势共生真菌类群在幼苗期发生了2次转变,即2月龄前由胶膜菌属(Tulasnella)转变成无孢蜡壳属;6月龄期由无孢蜡壳属转变成蜡壳耳属。【结论】齿瓣石斛幼苗发育过程中对于共生真菌的选择是一个动态过程,可能是主动选择环境中的最适真菌,亦或是被动选择了环境中相对丰度较高的真菌。这一结果为了解齿瓣石斛不同发育阶段共生真菌群落的多样性和动态变化提供了新的证据,并为分离获得促进幼苗生长、提高幼苗成活率的关键真菌类群提供了科学依据。

    Abstract:

    [Background] Orchids form a close symbiotic relationship with mycorrhizal fungi throughout their life cycle. The symbiotic fungi provide essential nutrients during seed germination and seedling establishment of orchids. [Objective] To reveal the diversity and dynamics of the endophytic (symbiotic) fungi of Dendrobium devonianum seedlings at different developmental stages. [Methods] The seedlings of D. devonianum were developed from in situ symbiotic seed germination, and the root samples were collected from the seedlings two, three, four, and six months after germination, respectively. Amplicon sequencing was employed to analyze the fungal community composition, abundance, and diversity. [Results] A total of 944 amplicon sequence variants (ASVs) were obtained from roots of seedling at all the four stages, belonging to 218 genera, 144 families, 71 orders, 24 classes of 5 phyla. The dominant fungal genera in D. devonianum seedlings of two to four months were Serendipita, Talaromyces, and Curvularia, respectively, while Talaromyces and Sebacina were dominant in the roots of six-month-old seedlings. The dominate symbiotic fungi underwent two shifts during seedling development. The first switch was from Tulasnella to Serendipita in the seedlings less than two months old and the second was from Serendipita to Sebacina in the seedlings of four to six months old. [Conclusion] The fungi in D. devonianum seedlings experience dynamic changes. The seedlings may actively choose the most compatible fungal partners or may be passively associated with the mycorrhizal fungi with high relative abundance in the environment. These new insights into the dynamics of symbiotic fungi during orchid seedling development offer a scientific basis to isolate fungal strains that might be employed to promote the growth and improve the survival of D. devonianum seedlings.

    参考文献
    [1] PÉREZ-ESCOBAR OA, BOGARÍN D, PRZELOMSKA NAS, ACKERMAN JD, BALBUENA JA, BELLOT S, BÜHLMANN RP, CABRERA B, AGUILAR CANO J, CHARITONIDOU M, CHOMICKI G, CLEMENTS MA, CRIBB P, FERNÁNDEZ M, FLANAGAN NS, GRAVENDEEL B, HÁGSATER E, HALLEY JM, HU AQ, JARAMILLO C, et al. The origin and speciation of orchids[J]. New Phytologist, 2024, 242(2): 700-716.
    [2] SHAO SC, JACQUEMYN H, SELOSSE MA. Improved use of mycorrhizal fungi for upscaling of orchid cultivation and population restoration of endangered orchids in China[J]. Symbiosis, 2024, 92(2): 149-158.
    [3] DEARNALEY JDW, MARTOS F, SELOSSE MA. 12 orchid mycorrhizas: molecular ecology, physiology, evolution and conservation aspects[M]//Fungal Associations. Berlin, Heidelberg: Springer, 2012: 207-230.
    [4] DEARNALEY JDW. Further advances in orchid mycorrhizal research[J]. Mycorrhiza, 2007, 17(6): 475-486.
    [5] RASMUSSEN HN, RASMUSSEN FN. Seedling mycorrhiza: a discussion of origin and evolution in Orchidaceae[J]. Botanical Journal of the Linnean Society, 2014, 175(3): 313-327.
    [6] RASMUSSEN HN, DIXON KW, JERSÁKOVÁ J, TĚŠITELOVÁ T. Germination and seedling establishment in orchids: a complex of requirements[J]. Annals of Botany, 2015, 116(3): 391-402.
    [7] WEIß M, WALLER F, ZUCCARO A, SELOSSE MA. Sebacinales-one thousand and one interactions with land plants[J]. New Phytologist, 2016, 211(1): 20-40.
    [8] OKAYAMA M, YAMATO M, YAGAME T, IWASE K. Mycorrhizal diversity and specificity in Lecanorchis (Orchidaceae)[J]. Mycorrhiza, 2012, 22(7): 545-553.
    [9] LIU HC, JACQUEMYN H, YU S, CHEN W, HE XY, HUANG YQ. Mycorrhizal diversity and community composition in co-occurring Cypripedium species[J]. Mycorrhiza, 2023, 33(1): 107-118.
    [10] DURÁN-LÓPEZ ME, CAROCA-CÁCERES R, JAHREIS K, NARVÁEZ-VERA M, ANSALONI R, CAZAR ME. The micorryzal fungi Ceratobasidium sp. and Sebacina vermifera promote seed germination and seedling development of the terrestrial orchid Epidendrum secundum Jacq[J]. South African Journal of Botany, 2019, 125: 54-61.
    [11] JIANG JW, ZHANG K, CHENG S, NIE QW, ZHOU SX, CHEN QQ, ZHOU JL, ZHEN X, LI XT, ZHEN TW, XU MY, HSIANG T, SUN ZX, ZHOU Y. Fusarium oxysporum KB-3 from Bletilla striata: an orchid mycorrhizal fungus[J]. Mycorrhiza, 2019, 29(5): 531-540.
    [12] 王美娜, 胡玥, 李鹤娟, 李健, 陈建兵, 兰思仁. 兰科植物菌根真菌研究新见解[J]. 广西植物, 2021, 41(4): 487-502. WANG MN, HU Y, LI HJ, LI J, CHEN JB, LAN SR. New insights into orchid mycorrhizal fungi research[J]. Guihaia, 2021, 41(4): 487-502(in Chinese).
    [13] WATERMAN RJ, BIDARTONDO MI, STOFBERG J, COMBS JK, GEBAUER G, SAVOLAINEN V, BARRACLOUGH TG, PAUW A. The effects of above- and belowground mutualisms on orchid speciation and coexistence[J]. The American Naturalist, 2011, 177(2): E54-E68.
    [14] ZENG XH, DIAO HX, NI ZY, SHAO L, JIANG K, HU C, HUANG QJ, HUANG WC. Temporal variation in community composition of root associated endophytic fungi and carbon and nitrogen stable isotope abundance in two Bletilla species (Orchidaceae)[J]. Plants, 2020, 10(1): 18.
    [15] 侯天文, 金辉, 刘红霞, 安德军, 罗毅波. 四川黄龙沟优势兰科植物菌根真菌多样性及其季节变化[J]. 生态学报, 2010, 30(13): 3424-3432. HOU TW, JIN H, LIU HX, AN DJ, LUO YB. The variations of mycorrhizal fungi diversity among different growing periods of the dominant orchids from two habitats in the Huanglong Valley, Sichuan[J]. Acta Ecologica Sinica, 2010, 30(13): 3424-3432(in Chinese).
    [16] 刁海欣, 黄卫昌, 曾歆花, 黄清俊. 黄花白及Bletilla ochracea不同生长发育期的菌根真菌多样性变化[J]. 南昌大学学报(理科版), 2020, 44(4): 346-353. DIAO HX, HUANG WC, ZENG XH, HUANG QJ. Study on the mycorrhizal fungi diversity of Bletilla ochracea across different growth and development stages[J]. Journal of Nanchang University (Natural Science), 2020, 44(4): 346-353(in Chinese).
    [17] ERCOLE E, ADAMO M, RODDA M, GEBAUER G, GIRLANDA M, PEROTTO S. Temporal variation in mycorrhizal diversity and carbon and nitrogen stable isotope abundance in the wintergreen meadow orchid Anacamptis morio[J]. New Phytologist, 2015, 205(3): 1308-1319.
    [18] 李佳瑶. 菌根真菌群落组成对兰科植物空间分布的响应[D]. 北京: 北京协和医学院硕士学位论文, 2021. LI JY. Response of mycorrhizal fungal community composition to spatial distribution of Orchidaceae plants[D]. Beijing: Master’s Thesis of Peking Union Medical College, 2021(in Chinese).
    [19] XING XK, GAI XG, LIU Q, HART MM, GUO SX. Mycorrhizal fungal diversity and community composition in a lithophytic and epiphytic orchid[J]. Mycorrhiza, 2015, 25(4): 289-296.
    [20] 毛益婷. 兰科石斛属根部内生真菌及其对种子萌发和苗木生长的效应[D]. 北京: 北京林业大学硕士学位论文, 2011. MAO YT. Endophytic fungus from the Dendrobium plants and effects on seed germination and seeding growth[D]. Beijing: Master’s Thesis of Beijing Forestry University, 2011(in Chinese).
    [21] WANG DY, JACQUEMYN H, GOMES SIF, VOS RA, MERCKX VSFT. Symbiont switching and trophic mode shifts in Orchidaceae[J]. New Phytologist, 2021, 231(2): 791-800.
    [22] 徐锦堂, 郭顺星. 供给天麻种子萌发营养的真菌: 紫萁小菇[J]. 真菌学报, 1989, 8(3): 221-226, 245. XU JT, GUO SX. Fungus associated with nutrition of seed germination of Gastrodia elata: Mycena osmundicola Lange[J]. Mycosystema, 1989, 8(3): 221-226, 245(in Chinese).
    [23] YAGAME T, OGURA-TSUJITA Y, KINOSHITA A, IWASE K, YUKAWA T. Fungal partner shifts during the evolution of mycoheterotrophy in Neottia[J]. American Journal of Botany, 2016, 103(9): 1630-1641.
    [24] BIDARTONDO MI, READ DJ. Fungal specificity bottlenecks during orchid germination and development[J]. Molecular Ecology, 2008, 17(16): 3707-3716.
    [25] ZHANG LY, RAMMITSU K, KINOSHITA A, TOKUHARA K, YUKAWA T, OGURA-TSUJITA Y. Symbiotic culture of three closely related Dendrobium species reveals a growth bottleneck and differences in mycorrhizal specificity at early developmental stages[J]. Diversity, 2022, 14(12): 1119.
    [26] MENG YY, FAN XL, ZHOU LR, SHAO SC, LIU Q, SELOSSE MA, GAO JY. Symbiotic fungi undergo a taxonomic and functional bottleneck during orchid seeds germination: a case study on Dendrobium moniliforme[J]. Symbiosis, 2019, 79(3): 205-212.
    [27] ZHU GH, JI ZH, JEFFREY JW, HOWARD PW. Dendrobium[M]//Flora of China: Vol. 25. Beijing: Science Press & St. Louis: Missouri Botanical Garden Press, 2009: 367-397.
    [28] SCHUITEMAN A. Typification of infrageneric taxa in Dendrobium (Orchidaceae)[J]. Muelleria, 2012, 30(1): 3-7.
    [29] 李孟凯, 余应鹏, 王伟, 邢震, 陈学达. 中国石斛属(兰科)植物新资料[J]. 广西植物, 2024, 44(5): 1003-1006. LI MK, YU YP, WANG W, XING Z, CHEN XD. New records of Dendrobium (Orchidaceae) from China[J]. Guihaia, 2024, 44(5): 1003-1006(in Chinese).
    [30] SHAO SC, MOHANDASS D, GAO JY. In situ symbiotic seed germination in Dendrobium spp. (Orchidaceae): implications for orchid restoration[J]. Proceedings of the 18th EOCCE, 2019: 36-46.
    [31] 倪凯, 何鹏飞, 梁志庆, 王胤骁, 沈宇明, 段兴恩. 齿瓣石斛研究进展[J]. 云南中医中药杂志, 2023, 44(1): 86-90. NI K, HE PF, LIANG ZQ, WANG YX, SHEN YM, DUAN XE. Research progress of Dendrobium devonianum[J]. Yunnan Journal of Traditional Chinese Medicine and Materia Medica, 2023, 44(1): 86-90(in Chinese).
    [32] SHAO SC, BURGESS KS, CRUSE-SANDERS JM, LIU Q, FAN XL, HUANG H, GAO JY. Using in situ symbiotic seed germination to restore over-collected medicinal orchids in southwest China[J]. Frontiers in Plant Science, 2017, 8: 888.
    [33] 邵士成, 高江云, 黄晖, 刘强. 一种齿瓣石斛种子和共生真菌混合播种的育苗方法: CN105815002B[P]. 2018-03-27. SHAO SC, GAO JY, HUANG H, LIU Q. Seedling growing method adopting Dendrobium devonianum seed and symbiotic fungus mixed sowing: CN105815002B[P]. 2018-03-27(in Chinese).
    [34] WAUD M, BUSSCHAERT P, RUYTERS S, JACQUEMYN H, LIEVENS B. Impact of primer choice on characterization of orchid mycorrhizal communities using 454 pyrosequencing[J]. Molecular Ecology Resources, 2014, 14(4): 679-699.
    [35] SELOSSE MA, PETROLLI R, MUJICA MI, LAURENT L, PEREZ-LAMARQUE B, FIGURA T, BOURCERET A, JACQUEMYN H, LI TQ, GAO JY, MINASIEWICZ J, MARTOS F. The waiting room hypothesis revisited by orchids: were orchid mycorrhizal fungi recruited among root endophytes?[J]. Annals of Botany, 2022, 129(3): 259-270.
    [36] SARMIENTO DJC. Tulasnella spp. as saprotrophic and mycorrhizal fungi of tropical orchids: morphology, molecular taxonomy, and ecology[D]. Frankfurt: PhD thesis of Johann Wolfgang Goethe-University, 2016.
    [37] FOCHI V, CHITARRA W, KOHLER A, VOYRON S, SINGAN VR, LINDQUIST EA, BARRY KW, GIRLANDA M, GRIGORIEV IV, MARTIN F, BALESTRINI R, PEROTTO S. Fungal and plant gene expression in the Tulasnella calospora-Serapias vomeracea symbiosis provides clues about nitrogen pathways in orchid mycorrhizas[J]. New Phytologist, 2017, 213(1): 365-379.
    [38] SUETSUGU K, HARAGUCHI TF, OKADA H, TAYASU I. Stigmatodactylus sikokianus (Orchidaceae) mainly acquires carbon from decaying litter through association with a specific clade of Serendipitaceae[J]. New Phytologist, 2021, 231(5): 1670-1675.
    [39] CEVALLOS S, DECLERCK S, SUÁREZ JP. In situ orchid seedling-trap experiment shows few keystone and many randomly associated mycorrhizal fungal species during early plant colonization[J]. Frontiers in Plant Science, 2018, 9: 1664.
    [40] 冯晓晓, 陈家杰, 刘峰, 胡卫珍, 林福呈, 章初龙. 西双版纳5种附生兰非菌根内生真菌多样性研究[J]. 菌物学报, 2019, 38(11): 1876-1885. FENG XX, CHEN JJ, LIU F, HU WZ, LIN FC, ZHANG CL. Diversity of non-mycorrhizal endophytic fungi from five epiphytic orchids from Xishuangbanna, China[J]. Mycosystema, 2019, 38(11): 1876-1885(in Chinese).
    [41] 朱彦明, 金锦游, 崔永一. 内生真菌对铁皮石斛种苗生长的影响[J]. 浙江农业科学, 2019, 60(9): 1601-1605. ZHU YM, JIN JY, CUI YY. Effect of endophytic fungi on growth of Dendrobium officinale seedlings[J]. Journal of Zhejiang Agricultural Sciences, 2019, 60(9): 1601-1605(in Chinese).
    [42] KÖMPE YÖ, MUTLU VA, ÖZKOÇ İ, DEMIRAY S, SERHAT B. Fungal diversity and ex vitro symbiotic germination of Serapias vomeracea (Orchidaceae)[J]. Acta Botanica Croatica, 2022, 81(1): 108-116.
    [43] 柴晓蕾, 宋希强, 朱婕. 华石斛内生真菌组织分布特点及其抑菌活性[J]. 热带作物学报, 2018, 39(1): 137-144. CHAI XL, SONG XQ, ZHU J. Diversity of endophytic fungi isolated from Dendrobium sinense with different culture media and their antimicrobial activities[J]. Chinese Journal of Tropical Crops, 2018, 39(1): 137-144(in Chinese).
    [44] BELL J, YOKOYA K, KENDON JP, SARASAN V. Diversity of root-associated culturable fungi of Cephalanthera rubra (Orchidaceae) in relation to soil characteristics[J]. PeerJ, 2020, 8: e8695.
    [45] ARIFIN AR, PHILLIPS RD, WEINSTEIN AM, LINDE CC. Cryptostylis species (Orchidaceae) from a broad geographic and habitat range associate with a phylogenetically narrow lineage of Tulasnellaceae fungi[J]. Fungal Biology, 2022, 126(8): 534-546.
    [46] 胡瑶, 雷星宇, 张跃龙, 李宏告, 李丽辉. 野生国兰根系共生真菌群落结构及生物学功能[J/OL]. 分子植物育种, 2023. http://kns.cnki.net/kcms/detail/46.1068. S.20231207.1125.008.html. HU Y, LEI XY, ZHANG YL, LI HG, LI LH. Analysis on community structure and biological function of symbiotic fungi in wild orchid root system[J/OL]. Molecular Plant Breeding, 2023. http://kns.cnki.net/kcms/ detail/46.1068.S.20231207.1125.008.html (in Chinese).
    [47] WANG SQ, LU ZX, LANG B, WANG XH, LI YQ, CHEN J. Curvularia lunata and Curvularia leaf spot of maize in China[J]. ACS Omega, 2022, 7(51): 47462-47470.
    [48] STŘEDA T, KRÉDL Z, POKORNÝ R, SANGCHOTE S. Effect of wetting period on infection of orchid flowers by Alternaria alternata and Curvularia eragrostidis[J]. New Zealand Journal of Crop and Horticultural Science, 2013, 41(1): 1-8.
    [49] MIRGHASEMPOUR SA, MICHAILIDES T, CHEN WL, MAO BZ. Fusarium spp. associated with Dendrobium officinale dieback disease in China[J]. Journal of Fungi, 2022, 8(9): 919.
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梁玉琼,王梦雪,高世南,张文杰,席会鹏,邵士成. 齿瓣石斛不同月龄幼苗根内共生真菌多样性动态变化分析[J]. 微生物学通报, 2024, 51(11): 4451-4463

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  • 收稿日期:2024-03-06
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