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Distribution, germplasm characteristics, and flower color analysis of wild Lilium pumilum in Taigu district
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Affiliation:

1.College of Horticulture,Shanxi Agricultural University;2.College of Urban and Rural Construction,ShanxiAgricultural University;3.Modern Research Center for Traditional Chinese Medicine,Shanxi University;4.Shanxi Hetianyue Agricultural Technology Service Limited Company

Fund Project:

Fundamental Research Program of Shanxi Province(20210302123416); Commercial Project of Shanxi Agricultural University (2023HX292)

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    Abstract:

    An in-depth investigation into wild L. pumilum was conducted in Taigu, Jinzhong City, Shanxi Province. This study, for the first time, clearly delineated the distribution, germplasm diversity and the pattern governing flower color differentiation of L. pumilum in Taigu. Preliminary investigations were conducted into the genetic underpinnings and molecular mechanisms that drive flower color variation among wild L. pumilum populations in Taigu. These variations were evaluated from phenotypic, cytological, physiological and molecular perspectives. The results showed that L. pumilum in Taigu is distributed within a longitude range of 112° 39′ 50″ to 112° 95′ 64″, a latitude range of 37° 19′ 12″ to 37° 42′ 17″, and an altitude range of 963 m to 1430 m. Notably, L. pumilum was absent from Xiaobai, while 683 plants were found in Yangyi, 394 in Fancun and 246 in Houcheng, totaling 1323 plants. Phenotypic diversity of L. pumilum is evident in plant height, stem color, flower color, hairy flower buds and seed color. The diversity in plant height is significantly correlated with altitude, whereas the diversity in flower and stem color was significantly correlated with geographical distribution of the plants. Using a color card and colorimeter, the five flower colors of L. pumilum were identified as orange, orange red, red, dark red and purple red. Orange red was the most abundant color, accounting for 90.2% of the population. Xiaodian and Yangyi are the only locations where all five flower colors coexist. The color differences among these five flower colors are pronounced, with orange and orange red L. pumilum being the most vivid. Carotenoids in the plastids serve as the primary coloring substances found in L. pumilum. The varying carotenoid content in the upper and lower epidermis leads to changes in flower colors between orange, orange red and red varieties. In contrast, the dark red and purple red colors of L. pumilum are due to the carotenoids being largely obscured by anthocyanins present in the vacuoles. Expression analysis of genes involved in the anthocyanin biosynthesis pathway suggests that LpDFR and LpbHLH2 may be the key genes responsible for this color differentiation observed in L. pumilum flowers. This study provides a theoretical foundation for the formulation of protection and innovative utilization strategies for L. pumilum germplasm resources. Additionally, it offers potential germplasm resources for genetic improvement and the cultivation of new varieties of L. pumilum.

    Reference
    [1] Matsuo Y, Takaku R, Mimaki Y. Novel steroidal glycosides from the bulbs of Lilium pumilum. Molecules, 2015, 20(9): 16255-16265
    [2] Liang Z, Zhang J, Sun M, Zhang Y, Zhang X, Li H, Shi L. Variation of phenolic compounds and antioxidant capacities in different organs of Lilium pumilum. Natural Product Communications, 2018, 13(6): 1934578X1801300616
    [3] So K, Wang J, Sun S, Che H, Zhang Y. Comprehensive analysis of MYB gene family and their expression under various stress conditions in Lilium pumilum. Scientia Horticulturae, 2024, 327: 112764
    [4] Wang Z, Wan W, Shi M, Ji S, Zhang L, Wang X, Zhang L, Cui H, Liu X, Sun H, Yang F, Jin S. GDSL in Lilium pumilum (LpGDSL) confers saline-alkali resistance to the plant by enhancing the lignin content and balancing the ROS. International Journal of Molecular Sciences, 2024, 25(17): 9319
    [5] 郝凯凯. 延安地区野生山丹种质资源遗传多样性研究. 延安: 延安大学, 2017Hao K K. Research on genetic diversity of wild Lilium pumlium DC germplasm resources in Yan’an area. Yan’an: Yan’an University, 2017
    [6] 雷家军, 荣立苹, 毕晓颖, 郑洋, 于殿成. 辽宁省野生百合资源的调查与分类研究. 沈阳农业大学学报, 2008, 39(2): 161-164Lei J J, Rong L P, Bi X Y, Zheng Y, Yu D C. Investigation and classification of Lilium germplasm resources in Liaoning province. Journal of Shenyang Agricultural University, 2008, 39(2): 161-164
    [7] 张述景, 智利红, 焦乐勤, 许文营. 豫西山区野生百合形态特征的研究. 安徽农业科学, 2008, 36(16): 6760-6761,6800Zhang S J, Zhi L H, Jiao L Q, Xu W Y. Study on the morphological characteristics of wild lily from the mountainous area of western Henan province. Journal of Anhui Agricultural Sciences, 2008, 36(16):6760-6761,6800
    [8] 靳磊, 刘师源, 袁博, 李越, 张萍. 罗山细叶百合资源的初步调查. 农业科学研究, 2015, 36(3): 90-93Jin L, Liu S Y, Yuan B, Li Y, Zhang P. Preliminary investigation of Lilium pumilum DC. in Luoshan Mountain. Journal of Agricultural Sciences, 2015, 36(3): 90-93
    [9] 靳洋洋. 长白山区五种百合属植物保护研究. 长春:吉林大学, 2017Jin Y Y. Conversation Studies of five Lilium species located in Mountain Changbai area. Chang’chun: Jilin University, 2017
    [10] 刘冬云, 刘燕. 山丹不同居群花器官的形态多样性研究. 植物遗传资源学报, 2012, 13(6): 997-1004Liu D Y, Liu Y. Floral diversity of the different populations of Lilium pumilum DC. Journal of Plant Genetic Resources, 2012, 13(6): 997-1004
    [11] 郭鸿飞, 张延龙, 牛立新, 罗建让. 8种中国野生百合花色素成分分析. 西北农林科技大学学报:自然科学版, 2015, 43(3): 98-104Guo H F, Zhang Y L, Niu L X, Luo J R. Petal pigments of eight wild Lilium species native to China. Journal of Northwest A F University:Natural Sciences Edition, 2015, 43(3): 98-104
    [12] Kautt AF, Kratochwil CF, Nater A, Machado-schiaffino G, Olave M, Henning F, Torres-dowdall J, H?rer A, Hulsey CD, Franchini P, Pippel M, Myers EW, Meyer A. Contrasting signatures of genomic divergence during sympatric speciation. Nature, 2020. 588(7836): 106-111
    [13] Tanaka Y, Sasaki N, Ohmiya A. Biosynthesis of plant pigments: anthocyanins, betalains and carotenoids. Plant J, 2008, 54(4): 733–49
    [14] Ye L, M?ller M, Luo Y, Zou J, Zheng W, Wang Y, Liu J, Zhu A, Hu J, Li D, Gao L. Differential expressions of anthocyanin synthesis genes underlie flower color divergence in a sympatric Rhododendron sanguineum complex. BMC Plant Biology, 2021, 21(1): 204
    [15] 王雪. 山西红色文化遗产的空间分布及分异格局形成机制. 中国文化遗产, 2024, (4): 51-57Wang X. Spatial distribution and forming mechanism of differentiation pattern of Shanxi’s red cultural heritage.China Cultural Heritage, 2024,(4): 51-57
    [16] 李合生. 植物生理生化实验原理和技术. 北京: 高等教育出版社. 2000.130-134Li H S. Principles and techniques of plant physiology and biochemical experiments. Beijing:Higher Education Press. 2000.130-134
    [17] Han M, Lu R, Liu C, Zhao S, Du F, Yang X, Zhen Z, Chen X. Multi-omics analysis revealed the difference in pigment accumulation profiles between Syringa oblata and S. oblata var. alba. Scientia Horticulturae, 2024, 337: 113467
    [18] Livak K J, Schmittgen T D. Analysis of relative gene expression data using real- time quantitative PCR and the 2? ΔΔCT method. methods, 2001, 25(4): 402-408
    [19] 万萍萍, 王利松, 吴少东, 谢明华. 江西省重点保护野生维管植物的比较研究和地理分布. 广西植物, 2024, 1-19Wang P P, Wang L S, Wu S D, Xie M H. Comparative study and geographical distribution of keyprotected wild vascular plants in Jiangxi Province, China. Guihaia, 2024, 1-19
    [20] 中国科学院中国植物志编辑委员会编.中国植物志-第14卷. 北京: 科学出版社, 1980.Editorial Committee of Flora Reipublicae Popularis Sinicae, Flora of China - Volume 14. Beijing: Science Press, Chinese Academy of Sciences. 1980
    [21] 冯晨, 张洁, 黄宏文. 统筹植物就地保护与迁地保护的解决方案:植物并地保护(parallel situ conservation). 生物多样性, 2023, 31(9): 38-48Feng C, Zhang J, Huang H W. Parallel situ conservation: A new plant conservation strategy to integrate in situ and ex situ conservation of plants. Biodiversity Science, 2023, 31(9): 38-48
    [22] 李洁. 山丹花蕾表皮毛发生规律与30种百合花粉的形态研究. 邯郸: 河北工程大学, 2021Li J. Study on the occurrence pattern of Lilium pumilum flower bud trichome and pollen morphology of 30 Lilies. Han’dan: Hebei University of Engineering, 2021
    [23] 张绍斌. 云南淡黄花百合遗传多样性与进化研究. 成都: 四川大学,2003.Zhang S B. Studies on genetic diversity and evolution of Lilium sulphureum Baker apud Hook.f. in Yunnan. Cheng’du: Sichuan University. 2003
    [24] 梁振旭. 川、陕及其毗邻地区野生百合种质资源调查与评价. 咸阳: 西北农林科技大学, 2015Liang Z X. Investigation and evaluation on wild Lilium native to Sichuan、Shanxi Province and its adjacent area. Xian’yang: Northwest A F University, 2015
    [25] 王静, 徐雷锋, 王令, 祁先宇, 宋蒙, 曹雨薇, 何国仁, 唐玉超, 杨盼盼, 明军. 百合花色表型数量分类研究. 园艺学报, 2022. 49(3): 571-580Wang J, Xu L F, Wang L, Qi X Y, Song M, Cao Y W, He G R, Tang Y C, Yang P P, MING JUN. The numerical classification of flower color phenotype in lily. Acta Horticulturae Sinica, 2022, 49(3): 571-580
    [26] 毕蒙蒙, 曹雨薇, 宋蒙, 唐玉超, 何国仁, 杨悦, 杨盼盼, 徐雷锋, 明军. 百合花色研究进展. 园艺学报, 2021, 48(10): 2073-2086Bi M M, Cao Y W, Song Meng, Tang Y C, He G R ,Yang Y, Yang P P, Xu L F, Ming J. Advances in flower color research of Lilium. Acta Horticulturae Sinica, 2021, 48(10): 2073-2086
    [27] 汪章沛, 陈林, 王贤荣. 被子植物同域物种形成研究进展. 广西植物, 2022, 42(1): 14-24Wang Z P, Chen L, Wang X R. Research progress of angiosperms sympatric speciation. Guihaia, 2022, 42(1): 14-24
    [28] 杨利平. 细叶百合的生殖生态学研究. 哈尔滨: 东北林业大学, 2002Yang L P. Study on reproductive ecology of Lilium pumilum DC. Ha’erbin: Northeast Forestry University, 2002
    [29] Glover B J, Walker R H, Moyroud E, Edwige M, Samuel F. B. How to spot a flower. New Phytologist, 2013, 197(3): 687-689
    [30] Martins T R, Berg J J, Blinka S, Rausher M D, Baum, D A. Precise spatio- temporal regulation of the anthocyanin biosynthetic pathway leads to petal spot formation in Clarkia gracilis (Onagraceae). New Phytologist, 2013, 197(3): 958-969
    [31] Suzuki K, Tasaki K, Yamagishi M. Two distinct spontaneous mutations involved in white flower development in Lilium speciosum. Molecular breeding, 2015, 35:1-14
    [32] Yamagishi M. White with partially pink flower color in Lilium cernuum var. album is caused by transcriptional regulation of anthocyanin biosynthesis genes. Scientia Horticulturae, 2020, 260: 108880
    [33] Cao X, Du R, Xu Y, Wu Y, Ye K, Ma J, Lyu Y, Sun T, Zhu X, Liu Z, Yin J, Zhu G, Huang Z, Lyu H, Huang S, Zhang J. Phytoene synthases 1 modulates tomato fruit quality through influencing the metabolic flux between carotenoid and flavonoid pathways. Horticultural Plant Journal, 2023,1-15
    [34] Yu P, Piao M, Kong X, Liu Y, Gao L, Huang Y, Jin Z, Gong T, Lu J, Wu X, Gao X, He H, Jia G. The coordinated interaction or regulation between anthocyanin and carotenoid pathways in OT hybrid lilies based on metabolome and time-course transcriptomics analysis. Industrial Crops and Products, 2024, 222: 119795
    [35] Yokotani N, Sato Y, Tanabe S, Chujo T, Shimizu T, Okada K. Yamane H, Shimono M, Sugano S, Takatsuji H, Kaku H, Minami E, Nishizawa Y. WRKY76 is a rice transcriptional repressor playing opposite roles in blast disease resistance and cold stress tolerance. Journal of experimental botany, 2013, 64(16): 5085-5097
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History
  • Received:February 07,2025
  • Revised:March 06,2025
  • Adopted:March 10,2025
  • Online: March 24,2025
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