Change of geographic distributions of the genus Morchella species responding to climate oscillations in East Asia.

doi:10.13287/j.1001-9332.202303.027

Abstract

Abstract: Morchella is a rare macrofungi taxon with high medicinal and edible values. Influenced by recent climate oscillations and human activities, habitat fragmentation of this genus has been critical, leading to a rapid decline of the resource of Morchella. It is thus urgent to preserve Morchella species. Based on maximum entropy model (MaxEnt), and 102 geographic distribution records of Morchella species with 10 environmental factors, we simulated the changes of potential geographic distributions under the climatic conditions of the last glacial maximum (LGM), last interglacial (LIG), in contemporary period and future (2050, 2070). We further analyzed the potential changes of geographic distributions of Morchella species in East Asia under climate change and formulated the effective conservation strategies for Morchella. The results showed that the dominant environmental factors affecting the geographic distributions of Morchella species were mean temperature of coldest quarter, annual precipitation, elevation and temperature annual range, with the mean temperature of coldest quarter having the greatest contribution. Results of the species distribution models showed that the highly suitable regions for Morchella species were mainly distributed in parts of western China under contemporary period. From the LIG to LGM and then the current to the future period, the total suitable regions of Morchella species showed a trend of firstly decrease and then increase, while the highly suitable regions showed similar change with the total suitable regions. At present, there is an urgent need to conduct in situ conservation for the resources of Morchella species in highly suitable regions in western China, and to carry out ex situ conservation in the marginal ranges of highly suitable regions and moderately suitable regions of Shaanxi, Hebei, Shandong, and other regions in China.

Key words: Morchella, maximum entropy model, environmental factor, species distribution, conservation strategy

ZUO Yifan, HE Yufan, WANG Lu, SA Wei, SHANG Qianhan, LIANG Jian, WANG Le, LI Zhonghu. Change of geographic distributions of the genus Morchella species responding to climate oscillations in East Asia.[J]. Chinese Journal of Applied Ecology, 2023, 34(3): 777-786.

References

[1] Fitzpatrick MC, Gove AD, Sanders NJ, et al. Climate change, plant migration, and range collapse in a global biodiversity hotspot: The Banksia (Proteaceae) of Western Australia. Global Change Biology, 2009, 14: 1337-1352
[2] 张爱平, 王毅, 熊勤犁, 等. 末次间冰期以来3种云杉属植物的历史分布变迁及避难所. 应用生态学报, 2018, 29(7): 2411-2412
[3] Lowe JJ, Walker MJC. Reconstructing Quaternary Environments. London: Addison Wesley Longman, 1997
[4] Mithen S. After the Ice. Cambridge: Harvard University Press, 2004
[5] 高健, 赵辉. 基于MaxEnt模型评估槭属鸡爪槭组物种的空间分布. 西北林学院学报, 2021, 36(1): 163-167
[6] Hewitt G. The genetic legacy of the quaternary ice ages. Nature, 2000, 405: 907-913
[7] Cong MY, Xu YY, Tang LY, et al. Predicting the dynamic distribution of Sphagnum bogs in China under climate change since the last interglacial period. PLoS One, 2020, 15(4): 0230969
[8] Bellard C, Bertelsmeier C, Leadley P, et al. Impacts of climate change on the future of biodiversity. Ecology Letters, 2012, 15: 365-377
[9] 赵儒楠, 何倩倩, 褚晓洁, 等. 气候变化下千金榆在我国潜在分布区预测. 应用生态学报, 2019, 30(11): 3833-3843
[10] Heikkinen RK, Luoto M, Araújo MB, et al. Methods and uncertainties in bioclimatic envelope modelling under climate change. Progress in Physical Geography, 2006, 30: 751-777
[11] Phillips SJ, Anderson RP, Schapire RE. Maximum entropy modeling of species geographic distributions. Ecological Modelling, 2006, 190: 231-259
[12] Phillips SJ, Dudík M. Modeling of species distributions with Maxent: New extensions and a comprehensive eva-luation. Ecography, 2008, 31: 161-175
[13] 塞依丁·海米提, 努尔巴依·阿布都沙力克, 阿尔曼·解思斯, 等. 人类活动对外来入侵植物黄花刺茄在新疆潜在分布的影响. 生态学报, 2019, 39(2): 629-636
[14] 冉巧, 卫海燕, 赵泽芳, 等. 气候变化对孑遗植物银杉的潜在分布及生境破碎度的影响. 生态学报, 2019, 39(7): 2481-2493
[15] 曹向锋, 钱国良, 胡白石, 等. 采用生态位模型预测黄顶菊在中国的潜在适生区. 应用生态学报, 2010, 21(12): 3063-3069
[16] 塞依丁·海米提, 努尔巴依·阿布都沙力克, 许仲林, 等. 基于MaxEnt模型对新疆地区的蒙古沙拐枣潜在分布预测及适生性分析. 西北林学院学报, 2018, 33(4): 71-77
[17] 李宁宁, 张爱平, 张林, 等. 气候变化下青藏高原两种云杉植物的潜在适生区预测. 植物研究, 2019, 39(3): 395-406
[18] 马军, 贾鹤鸣, 赵国强, 等. 基于优化粒子群的最大熵阈值法叶片图像分割. 森林工程, 2019, 35(3): 63-68
[19] 孟艺宏, 徐璕, 姜小龙, 等. 双花木属植物分布区模拟与分析. 生态学报, 2019, 39(8): 2816-2825
[20] 付天宇. 基于深层发酵的羊肚菌功能性食品研究. 硕士论文. 长春: 吉林大学, 2013
[21] 敬华英. 羊肚菌种属鉴定及活性成分保健功效研究进展. 安徽农业科学, 2018, 46(14): 34-36
[22] 陈彦, 潘见, 周丽伟, 等. 羊肚菌胞外多糖抗肿瘤作用的研究. 食品科学, 2008, 29(9): 553-556
[23] 殷伟伟, 张松, 吴金. 尖顶羊肚菌活性提取物降血脂作用的研究. 菌物学报, 2009, 28(6): 873-877
[24] Turkoglu A, Kivrak I, Mercan N, et al. Antioxidant and antimicrobial activities of Morchella conica Pers. African Journal of Biotechnology, 2006, 5: 1146-1150
[25] 武冬梅, 许文涛, 谢宗铭, 等. 新疆野生羊肚菌研究现状及展望. 食品工业科技, 2013, 34(1): 349-352
[26] 李懿, 余列. 汶川县羊肚菌资源及生态环境调查. 农业与技术, 2016, 36(17): 12-14,45
[27] 王龙, 郭瑞, 路等学, 等. 羊肚菌物种多样性研究现状. 西北农业学报, 2016, 25(4): 477-489
[28] 付晓燕. 羊肚菌菌丝体培养及菌丝分化研究. 硕士论文. 北京: 首都师范大学, 2006
[29] 武冬梅, 许文涛, 谢宗铭, 等. 新疆野生羊肚菌物种多样性研究. 食品工业科技, 2015, 36(2): 167-172
[30] 蔡英丽, 马晓龙, 路等学, 等. 野生羊肚菌Mel-21的系统发育分析和驯化. 食用菌学报, 2020, 27(3): 23-29
[31] 易思华, 张媱, 孙燕飞, 等. 新疆天山山脉地区野生羊肚菌ITS分析鉴定. 中国食用菌, 2019, 38(11): 47-51
[32] 刘伟. 梯棱羊肚菌生长发育过程及羊肚菌属的组学研究. 博士论文. 武汉: 华中农业大学, 2020
[33] 孙慧慧. 褐坑羊肚菌线粒体基因组及其与近缘种的比较. 硕士论文. 太原: 山西大学, 2021
[34] Kanwal HK, Acharya K, Ramesh G, et al. Molecular characterization of Morchella species from the western Himalayan region of India. Current Microbiology, 2011, 62: 1245-1252
[35] Du XH, Zhao Q, O’Donnell K, et al. Multigene mole-cular phylogenetics reveals true morels (Morchella) are especially species-rich in China. Fungal Genetics and Biology, 2012, 49: 455-469
[36] Du XH, Zhao Q, Xu J, et al. High inbreeding, limited recombination and divergent evolutionary patterns between two sympatric morel species in China. Scientific Reports, 2016, 6: 22434
[37] Du XH, Zhao Q, Xia EH, et al. Mixed-reproductive strategies, competitive mating-type distribution and life cycle of fourteen black morel species. Scientific Reports, 2017, 7: 1493
[38] Liu HG, Zhang J, Li T, et al. Mineral element levels in wild edible mushrooms from Yunnan, China. Biological Trace Element Research, 2012, 147: 341-345
[39] Phanpadith P, Yu Z, Li T. Retraction note: High diversity of Morchella and a novel lineage of the Esculenta clade from the north Qinling Mountains revealed by GCPSR-based study. Scientific Reports, 2021, 11: 14028
[40] Townsend PA, Cohoon KP. Sensitivity of distributional prediction algorithms to geographic data completeness. Ecological Modelling, 1999, 117: 159-164
[41] 邹萌, 蒋瑞平, 李佳伦, 等. 基于最大熵模型预测太白贝母的潜在分布. 中国中医药信息杂志, 2021, 28(9): 1-5
[42] 叶学敏, 陈伏生, 孙荣喜, 等. 基于MaxEnt模型的南酸枣潜在适生区预测. 江西农业大学学报, 2019, 41(3): 440-446
[43] Rong ZL, Zhao CY, Liu JJ, et al. Modeling the effect of climate change on the potential distribution of Qinghai spruce (Picea crassifolia Kom.) in Qilian mountains. Forests, 2019, 10: 62
[44] Wang JL, Feng LY, Tang X, et al. The implications of fossil fuel supply constraints on climate change projections: A supply-side analysis. Futures, 2017, 86: 58-72
[45] Nozawa T, Nagashima T, Ogura T, et al. Climate Change Simulations with a Coupled Ocean-atmosphere GCM Called the Model for Interdisciplinary Research on Climate: MIROC. Tsukuba: National Institute for Environmental Studies, 2007
[46] Dyderski MK, Paz S, Frelich LE, et al. How much does climate change threaten European forest tree species distributions. Global Change Biology, 2018, 24: 1150-1163
[47] 钟秀丽, 林而达. 气候变化对我国自然生态系统影响的研究综述. 生态学杂志, 2000, 19(5): 62-66
[48] Lenoir J, Gegout JC, Marquet PA, et al. A significant upward shift in plant species optimum elevation during the 20th century. Science, 2008, 320: 1768-1771
[49] 杨腾, 王世彤, 魏新增, 等. 中国特有属秤锤树属植物的潜在分布区预测. 植物科学学报, 2020, 38(5): 627-635
[50] 朱梦婕, 缪佳, 赵雪利. 基于最大熵模型的狸尾豆属植物在中国的潜在分布区模拟. 植物科学学报, 2020, 38(4): 476-482
[51] 陈冰瑞, 邹慧, 孟祥红, 等. 气候变化下中国地域内柴胡与狭叶柴胡适生区的分布格局与变迁预测. 生态学报, 2022, 42(20): 1-13
[52] 艾拉努尔·卡哈尔, 王鹏军, 逯永满, 等. 基于MaxEnt生态位模型预测木灵藓科三属植物在新疆的潜在分布区. 华中师范大学学报:自然科学版, 2022, 56(3): 487-496
[53] 权美平, 张丽芳. 羊肚菌生物学特征及价值的研究进展. 北方园艺, 2012(18): 178-180
[54] 冯建孟. 中国种子植物物种多样性的大尺度分布格局及其气候解释. 生物多样性, 2008, 16(5): 470-476
[55] Sekercioglu CH, Schneider SH, Fay JP, et al. Climate change, elevational range shifts, and bird extinctions. Conservation Biology, 2010, 22: 140-150
[56] 方精云, 朱江玲, 石岳. 生态系统对全球变暖的响应. 科学通报, 2018, 63(2): 136-140
[57] Feng L, Sun JJ, Shi YB, et al. Predicting suitable habitats of Camptotheca acuminata considering both climatic and soil variables. Forests, 2020, 11: 891
[58] Yu F, Wang T, Groen TA, et al. Climate and land use changes will degrade the distribution of Rhododendrons in China. Science of the Total Environment, 2019, 659: 515-528
[59] Bai YJ, Wei XP, Li XQ. Distributional dynamics of a vulnerable species in response to past and future climate change: A window for conservation prospects. PeerJ, 2018, 6: e4287
[60] 杜习慧, 赵琪, 杨祝良. 羊肚菌的多样性、演化历史及栽培研究进展. 菌物学报, 2014, 33(2): 183-197
[61] 杜习慧. 黑色羊肚菌支系的物种资源、生殖模式和遗传多样性研究进展. 菌物研究, 2019, 17(4): 240-251