Advance Search
Duan Yi-Zhong, Yu Hui, Wang Hai-Tao, Du Zhong-Yu. Geographical distribution and prediction of potentially suitable regions of endangered relict plant Tetraena mongolica[J]. Plant Science Journal, 2019, 37(3): 337-347. DOI: 10.11913/PSJ.2095-0837.2019.30337
Citation: Duan Yi-Zhong, Yu Hui, Wang Hai-Tao, Du Zhong-Yu. Geographical distribution and prediction of potentially suitable regions of endangered relict plant Tetraena mongolica[J]. Plant Science Journal, 2019, 37(3): 337-347. DOI: 10.11913/PSJ.2095-0837.2019.30337
shu

Geographical distribution and prediction of potentially suitable regions of endangered relict plant Tetraena mongolica

  • 1. Yulin University, Yulin, Shaanxi 719000, China;

  • 2. Yulin District Southern Farm, Yulin, Shaanxi 719000, China;

  • 3. Breeding Base for State Key Laboratory of Land Degradation and Ecological Restoration in Northwest China, Ningxia University, Yinchuan 750021, China;

  • 4. Key Laboratory for Restoration and Reconstruction of Degraded Ecosystem in Northwest China of Ministry of Education, Ningxia University, Yinchuan 750021, China

Funds: 

This work was supported by a grant from the National Natural Science Foundation of China (41601059).

More Information
  • Received Date: October 28, 2018
  • Revised Date: December 10, 2018
  • Available Online: October 31, 2022
  • Published Date: June 27, 2019
    Graphical Abstract
    • Abstract
  • The endangered relict plant Tetraena mongolica Maxim was studied, with the MaxEnt and Bioclim models used to predict potentially suitable regions. We used the knife-cutting method and environmental variable response curves to evaluate the dominant environmental factors affecting the distribution of T. mongolica. Furthermore, we used the ArcGIS natural discontinuity method to divide fitness levels. Results showed that T. mongolica was mainly distributed in the Xinjiang Uygur Autonomous Region, Tibet Region, Ningxia Hui Autonomous Region, Inner Mongolia, and the Gansu, Qinghai, Shaanxi, Shanxi, Hebei, Liaoning, Jilin, and Heilongjiang provinces in China, with a total area of 1.49×106 km2. Highly suitable zones were found in the Maowusu Sandy Land of Wuhai city, the Tengger Desert in the Alxa Left Banner, the southeastern part of Yinshan Mountain, and mountains in the Helan range. The potential distribution area of T. mongolica will be reduced to north of Inner Mongolia and western Northeast China by 2050. The Area Under Curve (AUC) average values of the two models were all above 0.8, justifying their application for predicting potential areas of T. mongolica. Among the 19 environmental variables, the main factors affecting the potential distribution of T. mongolica were average precipitation of the coldest quarter and temperature annual range, followed by the coefficient of variation of precipitation seasonality and standard deviation (SD) of temperature seasonality.
    • FullText(HTML)
    • References (43)
  • [1]
    Kozak KH, Graham CH, Wiens JJ. Integrating GIS-based environmental data into evolutionary biology[J]. Trends Ecol Evol, 2008, 23(3):141-148.
    [2]
    IPCC. Climate Change 2013:The Physical Science Basis Working group I to the Fifth Assessment Report[M/OL]. Cambridge:Cambridge University Press, 2013.
    [3]
    邹旭, 彭冶, 王璐, 李垚, 张往祥, 刘雪. 末次盛冰期以来气候变化对中国山荆子分布格局的影响[J]. 植物科学学报, 2018, 36(5):676-686.

    Zou X, Peng Y, Wang L, Li Y, Zhang WX, Liu X. Impact of climate change on the distribution pattern of Malus baccata (L.) Borkh. in China since the Last Glacial Maximum[J]. Plant Science Journal, 2018, 36(5):676-686.
    [4]
    Solomon S, Qin D, Manning M, et al. Climate Change 2007:The Physical Science Basis[M]. Cambridge:Cambridge University Press, 2007:18.
    [5]
    刘文胜, 游简舲, 曾文斌, 齐丹卉. 气候变化下青藏苔草地理分布的预测[J]. 中国草地学报, 2018, 40(5):43-49.

    Liu WS, You JL, Zeng WB, Qi DH. Prediction of the geographical distribution of Carex moorcroftii under global climate change based on MaxEnt model[J]. Chinese Journal of Grassland, 2018, 40(5):43-49.
    [6]
    乔慧捷, 胡军华, 黄继红. 生态位模型的理论基础、发展方向与挑战[J]. 中国科学:生命科学, 2013, 43(11):915-927.

    Qiao HJ, Hu JH, Huang JH. Theoretical basis, future directions, and challenges for ecological niche models[J]. Scientia Sinica Vitae, 2013, 43(11):915-927.
    [7]
    朱耿平, 刘国卿, 卜文俊, 高玉葆. 生态位模型的基本原理及其在生物多样性保护中的应用[J]. 生物多样性, 2013, 21(1):90-98.

    Zhu GP, Liu GQ, Pu WJ, Gao YB. Ecological niche modeling and its applications in biodiversity conservation[J]. Biodiversity Science, 2013, 21(1):90-98.
    [8]
    徐家文, 史家浩, 任强, 李绍勤. 基于BIOCLIM模型的扶桑绵粉蚧在中国的适生性分析[J]. 湖北农业科学, 2015, 54(11):2631-2633.

    Xu JW, Shi JH, Ren Q, Li SQ. Potential distribution of Phenacoccus solenopsis in China by the BIOCLIM model[J]. Hubei Agricultural Sciences, 2015, 54(11):2631-2633.
    [9]
    艾科拜尔·木哈塔尔, 热木图拉·阿卜杜克热木, 马合木提·哈力克. 基于生态位模型的艾比湖国家级自然保护区马鹿生境评价[J]. 生态学报, 2017, 37(11):3919-3925.

    Akbar Muhtar, Rahmutulla Abdukerim, Mahmut Halik. Assessing habitat suitability for Cervuselaphus in the Ebinur Lake National Nature Reserve[J]. Acta Ecologica Sinica, 2017, 37(11):3919-3925.
    [10]
    付贵全, 徐先英, 马剑平, 徐梦莎, 刘江, 丁爱强. 基于MaxEnt下梭梭潜在地理分布对水热条件的响应[J]. 草业科学, 2016, 33(11):2173-2179.

    Fu GQ, Xu XY, Ma JP, Xu MS, Liu J, Ding AQ. Responses of Haloxylon ammodendron potential geographical distribution to the hydrothermal conditions under MaxEnt model[J]. Pratacultural Science, 2016, 33(11):2173-2179.
    [11]
    王运生. 生态位模型在外来入侵物种风险评估中的应用研究[D]. 湖南:湖南农业大学, 2007.
    [12]
    杨持, 智颖飙, 征荣. 四合木种群的生态适应性[J]. 生态学报, 2006, 26(1):91-96.

    Yang C, Zhi YB, Zheng R. An analysis of ecological adaptability on Tetraena mongolica Maxim. populations[J]. Acta Ecologica Sinica, 2006, 26(1):91-96.
    [13]
    甄江红, 陈德喜, 玉山, 刘果厚. 濒危植物四合木生境适宜性变化分析[J]. 干旱区资源与环境, 2011, 25(7):188-195.

    Zheng JH, Chen DX, Yu S, Liu GH. Habitat suitability change for endangered plant Tetraena mongolica Maxim.[J]. Journal of Arid Land Resources and Environmen, 2011, 25(7):188-195.
    [14]
    张云飞, 杨持, 陈家宽. 四合木(Tetraena mongolica)分布区景观结构时空变化分析[J]. 武汉植物学研究, 2001, 19(1):25-30.

    Zhang YF, Yang C, Cheng JK. Spatial-temporal change of landscape structure in the distribution region of Tetraena mongolica[J]. Journal of Wuhan Botanical Research, 2001, 19(1):25-30.
    [15]
    甄江红. 濒危植物四合木生境的景观动态与适宜性评价研究[D]. 呼和浩特:内蒙古农业大学, 2008.
    [16]
    Wang WF, Hao WD, Bian ZF, Lei SG, Wang XS, Sang SX, Xu SC. Effect of coal mining activities on the environment of Tetraena mongolica in Wuhai, Inner Mongolia, China:A geochemical perspective[J]. Int J Coal Geol, 2014, 132(1):94-102.
    [17]
    Wang GL, Lin QQ, Xu YN. Tetraena mongolica Maxim. can accumulate large amounts of triacylglycerol in phloem cells and xylem parenchyma of stems[J]. Phytochemistry, 2007, 68(15):2112-2117.
    [18]
    Weselake RJ. Industrial Oil Crops[M]. New York:AOCS Press, 2016:413-434.
    [19]
    Lu KQ, Xie G, Li M, Li JF, Trivedi A, et al. Dataset of pollen morphological traits of 56 dominant species among desert vegetation in the eastern arid central Asia[J]. Data in Brief, 2018, 18:1022-1046.
    [20]
    Lu KQ, Gan Xie, Li M, Li JF, Anjali Trivedi, David K, et al. Pollen spectrum a cornerstone for tracing the evolution of the eastern central asian desert[J]. Quaternary Sci Rev, 2018, 186:111-122.
    [21]
    Wei XB, Xue JQ, Wang SL, Xue YQ, Lin H, Shao XF, et al. Fatty acid analysis in the seeds of 50Paeonia ostii individuals from the same population[J]. J Integr Agr, 2018, 17(8):1758-1767.
    [22]
    Lauterbach M, van der Merwe PW, Keßler L, Pirie MD, Bellstedt DU, Kadereit G. Evolution of leaf anatomy in arid environments:A case study in southern African Tetraena and Roepera (Zygophyllaceae)[J]. Mol Phylogenet Evol, 2016, 97:129-144.
    [23]
    王光明. 近二十年人为干扰对乌海市四合木景观格局影响研究[D]. 呼和浩特:内蒙古大学, 2012.
    [24]
    Vanagas G. Receiver operating characteristic curves and comparison of cardiac surgery risk stratification systems[J]. Interact Cardiov Th, 2004, 3(2):319-322.
    [25]
    张颖, 李君, 林蔚, 强胜. 基于最大熵生态位元模型的入侵杂草春飞蓬在中国潜在分布区的预测[J]. 应用生态学报, 2011, 22(11):2970-2976.

    Zhang Y, Li J, Lin W, Qiang S. Prediction of potentialt distriburion area of Erigeron philadelphicus in China based on MaxEnt model[J]. Chinese Journal of Applied Ecology, 2011, 22(11):2970-2976.
    [26]
    张路. MAXENT最大熵模型在预测物种潜在分布范围方面的应用[J]. 生物学通报, 2015, 50(11):9-12.

    Zhang L. Application of the MAXENT maximumentropy model in predicting the potential distribution of species[J]. Bulletin of Biology, 2015, 50(11):9-12.
    [27]
    李璇, 李垚, 方炎明. 基于优化的Maxent模型预测白栎在中国的潜在分布区[J]. 林业科学, 2018, 54(8):153-164.

    Li X, Li Y, Fang YM. Prediction of potential suitable distribution areas of Quercus fabri in China based on an optimized MaxEnt model[J]. Scientia Silvae Sinicae, 2018, 54(8):153-164.
    [28]
    王茹琳, 高晓清, 王闫利, 姜淦, 沈沾红, 林姗. 基于MaxEnt的非洲橘硬蓟马在全球及中国的潜在分布区预测[J]. 中国农学通报, 2014, 30(28):315-320.

    Wang RL, Gao XQ, Wang YL, Jiang G, Shen ZH, Lin S. Potential distribution of Scirtothrips aurantii in China and the world predicted by MaxEnt[J]. China Agricultural Science Bulletin, 2014, 30(28):315-320.
    [29]
    陈铁柱, 刘建辉, 周先建, 张美, 辜彬, 廖述吉. 基于MaxEnt和ArcGIS预测合欢潜在分布及适宜性评价[J]. 北方园艺, 2017, 41(16):191-195.

    Chen TZ, Liu JX, Zhou XJ, Zhang M, Gu B, Liao SJ. Potential distribution prediction and suitability evaluation of Albizia julibrissin Durazz. based on maxent modeling and GIS[J]. Northern Horticulture, 2017, 41(16):191-195.
    [30]
    陈林. 红火蚁(Solenopsis invicta)在我国的潜在分布研究[D]. 北京:中国农业科学院, 2007.
    [31]
    洪波. 基于GIS的有害生物空间分布预测系统研究[D]. 杨凌:西北农林科技大学, 2009.
    [32]
    宋花玲, 贺佳, 虞慧婷, 李玲. 应用ROC曲线下面积对两相关诊断试验进行评价和比较[J]. 第二军医大学学报, 2006, 27(5):562-563.

    Song HL, He J, Yu HT, Li L. Area under ROC curves in evaluation and comparison of two correlated diagnostic tests[J]. Academic Journal of Second Military Medical University, 2006, 27(5):562-563.
    [33]
    王运生, 谢丙炎, 万方浩, 肖启明, 戴良英. ROC曲线分析在评价入侵物种分布模型中的应用[J]. 生物多样性, 2007, 15(4):365-372.

    Wang YS, Xie BY, Wan FH, Xiao QM, Dai LY. Application of ROC curve analysis in evaluating the performance of alien species' potential distribution models[J]. Biodiversity Science, 2007, 15(4):365-372.
    [34]
    Hewitt GM. The genetic legacy of the Quaternary ice ages[J]. Nature, 2000, 405:907-913.
    [35]
    徐庆, 刘世荣, 臧润国, 郭泉水, 郝玉光. 中国特有植物四合木种群的生殖生态特征:种群生殖值及生殖分配研究[J]. 林业科学, 2001, 37(2):36-41.

    Xu Q, Liu SR, Zang RG, Guo QS, Hao YG. The characteristics of reproductive ecology of endemic species Tetraena mongolica population in China[J]. Scientia Silvae Sinicae, 2001, 37(2):36-41.
    [36]
    吴建国. 气候变化对我国7种植物潜在分布的影响[J]. 广西植物, 2011, 31(5):595-607, 694.

    Wu JG. The potential effects of climate change on the distributions of 7 plants in China[J]. Guihaia, 2011, 31(5):595-607, 694.
    [37]
    Mckenney DW, Pedlar JH, Lawrence K, Campbell K. Potential impacts of climate change on the distribution of North American trees[J]. BioScience, 2007, 57:939-948.
    [38]
    Lenoir J, Gegout JC, Marquet PA, de Ruffray P, Brisse H. A significant upward shift in plant species optimum elevation during the 20th century[J]. Science, 2008, 320:1768-1771.
    [39]
    Engler R, Randin CF, Thuiller W, Dullinger S. 21st century climate change threatens mountain flora unequally across Europe[J]. Global Change Biol, 2011, 17(7):2330-2341.
    [40]
    张兴旺, 李垚, 谢艳萍, 包先明, 方炎明. 气候变化对黄山花楸潜在地理分布的影响[J]. 植物资源与环境学报, 2018, 27(4):31-41.

    Zhang XW, Li Y, Xie YP, Bao XM, Fang YM. Effect of climate change on potential geographical distribution of Sorbus amabilis[J]. Journal of Plant Resources and Environment, 2018, 27(4):31-41.
    [41]
    孙平. 四合木(Tetraena mongolica)保护遗传学研究及三种西鄂尔多斯濒危植物微卫星标记的筛选[D]. 合肥:安徽大学, 2018.
    [42]
    杨超. 蒙古高原和青藏高原针茅属植物适宜分布区及其与气候因子的相关性[D]. 呼和浩特:内蒙古大学, 2016.
    [43]
    刘超, 霍宏亮, 田路明, 董星光, 齐丹, 张莹, 等. 基于MaxEnt模型不同气候变化情景下的豆梨潜在地理分布[J].应用生态学报, 2018, 29(11):3696-3704.

    Liu C, Huo HL, Tian LM, Dong XG, Qi D, Zhang Y, et al. Potential geographical distribution of Pyrus calleryana under different climate change scenarios based on the MaxEnt model[J]. Chinese Journal of Applied Ecology, 2018, 29(11):3696-3704.
    • Related Articles

  • Related Articles

    [1]Sun Linjuan, Liu Taoli, Liu Hai, Yuan Dingyang, Yang Xulei, Xu Yusheng, Chen Siyang, Zeng Jianguang, Huang Yubo, Tan Yanning. Effect of ascorbic acid oxidation inhibition on growth of Oryza sativa L. seedlings under abscisic acid (ABA) treatment[J]. Plant Science Journal, 2024, 42(6): 806-814. DOI: 10.11913/PSJ.2095-0837.23378
    [2]Sun De-Zhi, Han Xiao-Ri, Peng Jing, Fan Fu, Song Gui-Yun, Yang Heng-Shan. Effects of exogenous nitric oxide and salicylic acid on membrane peroxidation and the ascorbate-glutathione cycle in leaves of Lycopersicon esculentum seedlings under NaCl stress[J]. Plant Science Journal, 2018, 36(4): 612-622. DOI: 10.11913/PSJ.2095-0837.2018.40612
    [3]YAN Zhi-Ming, SUN Jin, GUO Shi-Rong, WEI Yue, HU De-Long, WANG Quan-Zhi. Effects of Exogenous Proline on the Ascorbate-Glutathione Cycle in Roots of Cucumis melo Seedlings under Salt Stress[J]. Plant Science Journal, 2014, 32(5): 502-508. DOI: 10.11913/PSJ.2095-0837.2014.50502
    [4]WEI Jin-Chi, YANG Hai-Ling. Functional Divergence of Two Glutathione Peroxidase Genes in Oryza sativa[J]. Plant Science Journal, 2013, 31(1): 64-72. DOI: 10.3724/SP.J.1142.2013.10064
    [5]QIU Zong-Bo, LI Fang-Min, WANG Fang, YUE Ming. Effects of CO2 Laser on Glutathione-dependent Antioxidative System in Wheat Seedling under Drought Stress[J]. Plant Science Journal, 2008, 26(4): 402-406.
    [6]LI Cong-Qiang, LIN Gang, LI Ke-Xiu, SONG Yun-Chun, XIONG Zhi-Yong, HE Guang-Yuan. Cytological Identification on the Interspecific Hybrid of Zea mays and Zea diploperennis[J]. Plant Science Journal, 2006, 24(1): 1-5.
    [7]DONG Gao-Feng, CHEN Yi-Zhu, LI Geng-Guang, HUANG Tao, YANG Cheng-Wei. Xanthophyll Cycle and Non-Radiative Energy Dissipation in Sun and Shade Plants[J]. Plant Science Journal, 2001, 19(2): 128-134.
    [8]Li Minghong, Yu Mingjian, Chen Qichang. ACCUMULATION AND CYCLING OF CALCIUM IN AN EVERGREEN BROAD-LEAVED FOREST DOMINATED BY CYCLOBALANOPSIS GLAUCA IN SE, CHINA[J]. Plant Science Journal, 2000, 18(2): 131-137.
    [9]Zhao Bosheng, Mo Hua. DETOXICATION OF ASCORBIC ACID AND MOLYSITE ON THE ROOT GROWTH OF GARLIC UNDER CADMIUM POLLUTION[J]. Plant Science Journal, 1997, 15(2): 167-172.
    [10]Lin Peng. BIOMASS AND ELEMENT CYCLE OF KANDELIA FOREST, CHINA[J]. Plant Science Journal, 1989, 7(3): 251-257.

  • Cited by

    Periodical cited type(9)

    1. 徐萌,王亚楠,李婷婷,赵新英. 拟南芥根中细胞器特异标记蛋白质的定位观察. 山东农业大学学报(自然科学版). 2025(01): 125-132 .
    2. 朱钰雅,倪雅迪,徐羚欣,肖平,段金廒. 中药蛋白结构与功能研究方法与策略探讨. 中国中药杂志. 2024(07): 1705-1716 .
    3. 陈甘露,颜彦,孟宪伟,付莉莉,邱先进,丁泽红,胡伟. 木薯MebZIP2基因克隆及其功能分析. 福建农业学报. 2024(02): 137-146 .
    4. 代蕊,陈崎,爽爽,张岩,张志强,米福贵. 紫花苜蓿MsJAR1基因克隆及表达分析. 草地学报. 2024(05): 1370-1377 .
    5. 韩青,张大伟. 植物蛋白的亚细胞定位观察虚拟仿真实验. 实验科学与技术. 2024(04): 84-89 .
    6. 韦鎔宜,段鹏,李培兰,罗丹,史国民,代吴斌,李凤珍,何涛. 水母雪兔子通气组织形成相关基因SmPAD4的克隆及表达分析. 广西植物. 2024(12): 2265-2278 .
    7. 黄馨田,韩慧杰,李宇琛,刘亚玲,张雅荣,赵彦. 蒙农杂种冰草AcdMYB1基因克隆及表达分析. 草地学报. 2023(08): 2334-2342 .
    8. 李佳楠,高兴泉,李卓,滕小华,黄斌,张继成,唐友. 四种机器学习算法预测大豆蛋白质定位对比研究. 大豆科学. 2022(03): 337-344 .
    9. 苏倩,杜文宣,马琳,夏亚迎,李雪,祁智,庞永珍. 紫花苜蓿MsCIPK2的克隆及功能分析. 中国农业科学. 2022(19): 3697-3709 .

    Other cited types(40)

Catalog

    Get Citation
    PDF
    XML
    Article views (1103) PDF downloads (631) Cited by(49)
    Turn off MathJax
    Article Contents
    Abstract
    References
    Related Articles
    Copyright © 2022 Plant Science Journal 鄂ICP备05004779号-3
    Address:No. 201, Jiufeng 1st Road, Donghu High tech Zone, WuhanPostal Code:430074

    Supported by: Beijing Renhe Information Technology Co., Ltd. Baidu Analytics

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return