Community structure of soil fauna under different tree species in subtropical forests

doi:10.13287/j.1001-9332.202310.031

Abstract

Abstract: Soil fauna play an important role in key functions of ecosystem such as material cycling. Litter quality and microenvironment of different tree species may regulate soil fauna community structure. In this study, we investigated soil fauna community structure, the differences of taxonomic and functional groups, and the regulatory factors under eight dominant tree species in August 2022. We captured 567 soil fauna (except for termites and ants), belonging to 3 phyla, 10 classes, 26 orders, and 99 families, with Achipteriidae, Trygoniidae, Poduridae, and Isotomidae as the dominant species. Tree species significantly affected soil fauna abundance, following an order: Michelia macclurei > Elaeocarpus decipiens > Castanopsis carlesii > Cunninghamia lanceolata > Lindera communis > Schima superba > Pinus massoniana > Liquidambar formosana. However, the richness, evenness, and diversity of soil fauna under different tree species were significantly different. Richness and diversity of M. macclurei, C. lanceolatas soil fauna were relatively high, while L. formosana, C. carlesii were relatively low. The evenness of meso-microfauna of L. formosana was the highest, which was significantly higher than that of M. macclureis and E. decipiens. The evenness of macrofauna and total soil fauna was not significantly different among the eight tree species. In addition, the abundance of omnivores and herbivores soil fauna was relatively high under M. macclurei, but relatively low under E. decipiens. The abundance of saprophages and predators soil fauna of E. decipiens, M. macclurei was higher than L. formosana, while saprophages was mainly meso-microfauna. Results of redundancy analysis showed that litter N, C:N, and K were the main factors affecting soil fauna community structure. The results indicated that the tree species with thicker litter layer and higher N and K contents may be conducive to enhancing the diversity of soil fauna community and affecting the distribution of different functional groups, thus contributing to the maintenance of forest biodiversity.

Key words: common garden, soil fauna, biodiversity, functional group, litter

WEN Huihui, WU Fuzhong, ZHANG Huiling, PENG Qingqing, QIU Danni, PENG Yan. Community structure of soil fauna under different tree species in subtropical forests[J]. Chinese Journal of Applied Ecology, 2023, 34(10): 2797-2804.

References

[1] 吴东辉, 傅声雷. 土壤动物多样性: 物种与群落研究. 生物多样性, 2022, 30(12): 5-10
[2] 傅声雷, 刘满强, 张卫信, 等. 土壤动物多样性的地理分布及其生态功能研究进展. 生物多样性, 2022, 30(10): 150-167
[3] Heděnec P, Jiménez JJ, Moradi J, et al. Global distribution of soil fauna functional groups and their estimated litter consumption across biomes. Scientific Reports, 2022, 12: 1-14
[4] Bardgett RD, van der Putten WH. Belowground biodiversity and ecosystem functioning. Nature, 2014, 515: 505-511
[5] Yoshikawa Y, Kawano K, Tsukamoto J. Litter quantity controls soil macro-invertebrate biomass in warm tempe-rate broad-leaved forests of Southwestern Japan. Applied Soil Ecology, 2021, 161: 103870
[6] Ganault P, Nahmani J, Hättenschwiler S, et al. Relative importance of tree species richness, tree functional type, and microenvironment for soil macrofauna communities in European forests. Oecologia, 2021, 196: 455-468
[7] Peng Y, Holmstrup M, Schmidt IK, et al. Litter quality, mycorrhizal association, and soil properties regulate effects of tree species on the soil fauna community. Geoderma, 2022, 407: 115570
[8] Peng Y, Schmidt IK, Zheng H, et al. Tree species effects on topsoil carbon stock and concentration are mediated by tree species type, mycorrhizal association, and N-fixing ability at the global scale. Forest Ecology and Management, 2020, 478: 118510
[9] Pollierer MM, Klarner B, Ott D, et al. Diversity and functional structure of soil animal communities suggest soil animal food webs to be buffered against changes in forest land use. Oecologia, 2021, 196: 195-209
[10] Fujii S, Berg MP, Cornelissen JHC. Living litter: Dynamic trait spectra predict fauna composition. Trends in Ecology and Evolution, 2020, 35: 886-896
[11] Zhang AJ, Zhang Y, Potapov AM, et al. Changes in diversity and functional groups of soil mite communities are associated with properties of food resources along a subalpine secondary succession. Geoderma, 2023, 432: 116395
[12] Kamath D, Barreto C, Lindo Z. Nematode contributions to the soil food web trophic structure of two contrasting boreal peatlands in Canada. Pedobiologia, 2022, 93: 150809
[13] 唐仕姗, 杨万勤, 殷睿, 等. 中国森林生态系统凋落叶分解速率的分布特征及其控制因子. 植物生态学报, 2014, 38(6): 529-539
[14] 张耀艺, 倪祥银, 杨静, 等. 中亚热带同质园不同树种氮磷重吸收及化学计量特征. 应用生态学报, 2021, 32(4): 1154-1162
[15] 李帆, 王党军, 林小元, 等. 八大公山亚热带森林木质残体中大型无脊椎动物群落特征. 生物多样性, 2022, 30(31): 31-43
[16] 杨光蓉, 豆鹏鹏, 马瑜, 等. 金佛山亚热带常绿阔叶林地表土壤动物群落特征及其影响因素. 生态学报, 2020, 40(21): 7602-7610
[17] 吴文佳, 袁也, 张静, 等. 南亚热带森林演替过程中土壤线虫群落结构变化. 生物多样性, 2022, 30(12): 44-53
[18] Vesterdal L, Elberling B, Christiansen JR, et al. Soil respiration and rates of soil carbon turnover differ among six common European tree species. Forest Ecology and Management, 2012, 264: 185-196
[19] 郑宪志, 张星星, 林伟盛, 等. 不同树种对土壤可溶性有机碳和微生物生物量碳的影响. 福建师范大学学报: 自然科学版, 2018, 34(6): 86-93
[20] Ma SJ, Wang QC, Zhang Y, et al. Effects of natural forest conversion and plantation tree species composition on soil macrofauna communities in Northeast China mountains. Journal of Forestry Research, 2023, doi: 10.1007/s11676-022-01581-3
[21] 王文君, 杨万勤, 谭波, 等. 四川盆地亚热带常绿阔叶林不同物候期凋落物分解与土壤动物群落结构的关系. 生态学报, 2013, 33(18): 5737-5750
[22] 尹文英. 中国土壤动物检索图鉴. 北京: 科学出版社, 1998
[23] 李鸿兴, 隋敬之, 周士秀. 昆虫分类检索. 北京: 农业出版社, 1987
[24] 张雪萍, 侯威岭, 陈鹏. 东北森林土壤动物同功能种团及其生态分布. 应用与环境生物学报, 2001, 7(4): 370-374
[25] 刘任涛, 李学斌, 辛明, 等. 荒漠草原地面节肢动物功能群对草地封育的响应. 应用生态学报, 2011, 22(8): 2153-2159
[26] Shannon CE. A mathematical theory of communication. The Bell System Technical Journal, 1948, 27: 379-423
[27] Pielou EC. Ecology Diversity. New York: John Wiley and Sons Press, 1975
[28] Simpson EH. Measurement of diversity. Nature, 1949, 163: 688
[29] 马克平. 生物群落多样性的测度方法Ⅰ: α多样性的测度方法(上). 生物多样性, 1994, 2(3): 162-168
[30] Sun F, Tariq A, Chen H, et al. Effect of nitrogen and phosphorus application on agricultural soil food webs. Archives of Agronomy and Soil Science, 2017, 63: 1176-1186
[31] Sauvadet M, Chauvat M, Brunet N, et al. Can changes in litter quality drive soil fauna structure and functions? Soil Biology and Biochemistry, 2017, 107: 94-103
[32] 侯春雨, 魏雪, 吴鹏飞. 种植黄连和重楼对小型土壤节肢动物群落的影响. 应用生态学报, 2022, 33(3): 813-820
[33] 张艳, 李勋, 宋思梦, 等. 马尾松与乡土阔叶树种混合凋落叶分解的质量损失. 林业科学研究, 2022, 35(5): 134-145
[34] Zhang W, Yang K, Liu Z, et al. Microbial groups and their functions control the decomposition of coniferous litter: A comparison with broadleaved tree litters. Soil Biology and Biochemistry, 2019, 133: 196-207
[35] Santonja M, Fernandez C, Proffit M, et al. Plant litter mixture partly mitigates the negative effects of extended drought on soil biota and litter decomposition in a Mediterranean oak forest. Journal of Ecology, 2017, 105: 801-815
[36] 何振, 赵琴, 李迪强, 等. 不同生境土壤跳虫及地表节肢动物群落结构和多样性特征. 北京林业大学学报, 2017, 39(5): 98-108
[37] 李娜, 张雪萍, 张利敏. 红松人工林与天然次生林大型土壤动物功能类群. 应用与环境生物学报, 2014, 20(1): 22-29
[38] Lavelle P, Mathieu J, Spain A, et al. Soil macroinvertebrate communities: A world-wide assessment. Global Ecology and Biogeography, 2022, 31: 1261-1276