The Effects of Soil Microorganisms on the Growth of Annual and Perennial Forages in the Desert Steppe

doi:10.11733/j.issn.1007-0435.2026.01.007

Acta Agrestia Sinica ›› 2026, Vol. 34 ›› Issue (1): 61-74.DOI: 10.11733/j.issn.1007-0435.2026.01.007

The Effects of Soil Microorganisms on the Growth of Annual and Perennial Forages in the Desert Steppe

CHEN Wen-mei^1,2, GAO Hui^1,2, HU Hai-na^1,2, HUANG Zhen-zhen^1,2, SUN Zhi^1,2, LI Hai-gang^1,2

1. Key Laboratory of Soil Quality and Nutrient Resources of Inner Mongolia Autonomous Region, Resource and Environment College, Inner Mongolia Agricultural University, Hohhot, Inner Mongolia 010018, China;
2. Key Laboratory of Agricultural Ecological Safety and Green Development of Autonomous Region in Higher Education, Hohhot, Inner Mongolia010018, China

Received:2025-02-13 Revised:2025-03-30 Published:2025-12-24

土壤微生物对荒漠草原一年生和多年生牧草生长发挥的效应

陈文美^1,2, 高卉^1,2, 胡海娜^1,2, 黄真真^1,2, 孙智^1,2, 李海港^1,2

1. 内蒙古农业大学资源与环境学院内蒙古自治区土壤质量与养分资源重点实验室, 内蒙古呼和浩特 010018;
2. 农业生态安全与绿色发展自治区高等学校重点实验室, 内蒙古呼和浩特 010018

通讯作者: 李海港,E-mail:haigangli@imau.edu.cn
作者简介:陈文美（1999-），女，汉族，内蒙古赤峰人，硕士研究生，主要从事荒漠草原牧草生长研究，E-mail:15847759542@163.com；
基金资助:
内蒙古自治区自然科学基金：用于补播修复退化荒漠草原的豆科牧草根际微生物多样性及功能解析（2023QN03001）；国家自然科学基金：土壤氮磷养分调控荒漠草原豆科植物生存与生长的机制（32360072）和促进荒漠草原豆科植物补播建植根际功能微生物组构建及其促生机制解析（32460071）；国家重点研发计划子课题：人工牧草驱动的典型“土壤-作物-动物”系统耦合机制（2022YFD1900301）资助

Abstract

Abstract: The exploration of the mutual relationships between soil microorganisms and different types of forages in desert steppes is crucial for maintaining and restoring desert steppe ecosystems. In this study， perennial forages [Stipa breviflora Griseb， S. glareosa P. Smirn， S. krylovii， Cleistogenes songorica （Roshev） Ohwi] and annual forage [Neopallasia pectinata （Pall） Poljak] in desert steppes were taken as the research objects to analyze the enhancement effects of soil microbial concentration on different species of forages. The results showed that：（1） Soil microbial concentration exerted a neutral effect on the growth of perennial forags， mainly due to the mutual offset between the negative effects of bacteria Sphingomonas and fungi Dominikia and the positive effects of bacteria norank_f_Longimicrobiaceae and fungi Rhizophlyctis on their growth. （2） Soil microbial concentration exerted an inhibitory effect on the growth of annual forage Neopallasia pectinata， and this effect intensified with the increase in microbial quantity. Soil microbial α diversity， Gemmatimonadaceae， Coprinopsis， Fusarium in rhizospheric soil， and Rubrobacter， Peziza in non-rhizospheric soil all showed inhibitory effects on its growth （P<0.05）. The analysis of key microbial groups provides a theoretical basis for subsequent related microbial studies， so as to enhance the growth stability of forages in desert steppes.

Key words: Soil microorganism, Desert steppe, Annual forage, Perennial forage, Enhancement effect

摘要： 探究土壤微生物与荒漠草原不同类型牧草之间的相互关系，对于维持和恢复荒漠草原生态系统至关重要。本研究以荒漠草原多年生牧草[短花针茅（Stipa breviflora Griseb）、沙生针茅（S. glareosa P. Smirn）、克氏针茅（S. krylovii）、无芒隐子草（Cleistogenes songorica （Roshev） Ohwi）]和一年生牧草[栉叶蒿（Neopallasia pectinata （Pall.） Poljak）]为研究对象，解析土壤微生物浓度对不同种类牧草生长发挥的增益效应。结果发现：（1）土壤微生物浓度对多年生牧草的生长发挥中性效应。主要是由细菌Sphingomonas、真菌Dominikia对其生长发挥的负效应与细菌norank_f_Longimicrobiaceae、真菌Rhizophlyctis发挥的正效应之间相互抵消的结果。（2）土壤微生物浓度对一年生牧草栉叶蒿生长发挥抑制效应，且随数量升高而增强。土壤微生物α多样性、根际土壤中Gemmatimonadaceae、Coprinopsis、Fusarium及非根际土壤中Rubrobacter、Peziza对其生长均产生抑制作用（P<0.05）。解析关键微生物类群，为后续相关微生物研究提供理论基础，以增强荒漠草原牧草生长的稳定性。

关键词: 土壤微生物, 荒漠草原, 一年生牧草, 多年生牧草, 增益效应

CLC Number:

S812

CHEN Wen-mei, GAO Hui, HU Hai-na, HUANG Zhen-zhen, SUN Zhi, LI Hai-gang. The Effects of Soil Microorganisms on the Growth of Annual and Perennial Forages in the Desert Steppe[J]. Acta Agrestia Sinica, 2026, 34(1): 61-74.

陈文美, 高卉, 胡海娜, 黄真真, 孙智, 李海港. 土壤微生物对荒漠草原一年生和多年生牧草生长发挥的效应[J]. 草地学报, 2026, 34(1): 61-74.

References

[1] YANG X G，LIU C H，WANG L， et al. Study on ecological restoration and reconstruction of desert steppe： a review[J]. Acta Ecologica Sinica，2023，43（1）：95-104 杨新国，刘春虹，王磊，等.荒漠草原生态恢复与重建：人工植被推动下水分介导的系统响应、生态阈值与互馈作用[J].生态学报，2023，43（1）：95-104
[2] ZAHNG F，LI S Y， YANG L Set al. Influencing factors of above-ground net primary productivity of plant communities under different grassland types in Inner Mongolia[J]. Acta Agrestia Sinica，2025，33（3）：902-909 张峰，李邵宇，杨立山，等. 内蒙古不同草地类型植物群落地上净初级生产力的影响因素[J]. 草地学报，2025，33（3）：902-909
[3] CHEN C. Spatio-temporal characteristics of vegetation cover in China from 2001 to 2017 and its response to moisture factors[D]. Chengdu： University of Electronic Science and Technology of China，2021：18-19 陈晨. 2001-2017年中国植被覆盖的时空特征及其对水分因子的响应[D]. 成都：电子科技大学，2021：18-19
[4] 朱小华，杨倩，丁子筱，等. 荒漠草原生态系统景观格局变化及其对气候的响应[J]. 生态学杂志，2023， 42（3）：748-758
[5] MU L，ZHANG P J，LIU Y H，et al. Effect of restoration measures on herbaceous community characteristics of abandoned land in desert steppe of Inner Mongolia[J]. Chinese Agricultural Science Bulletin，2016，32（16）：110-116 木兰，张璞进，刘亚红，等. 内蒙古荒漠草原农牧交错带植被恢复措施对弃耕地草本群落的影响[J]. 中国农学通报，2016，32（16）：110-116
[6] NING Z Y，LI Y L，ZHAO X Y，et al. Comparison of leaf and fine root traits between annuals and perennials，implicating the mechanism of species changes in desertified grasslands[J]. Frontiers in Plant Science，2022，12：778547-778547
[7] PETERS D P C，SAVOY H M. A sequence of multiyear wet and dry periods provides opportunities for grass recovery and state change reversals[J]. Ecological Monographs，2023，93（4）：e1590
[8] RUPPERT J C，HARMONEY K，HENKIN Z，et al. Quantifying drylands drought resistance and recovery： the importance of drought intensity， dominant life history and grazing regime[J]. Global Change Biology，2014，21（3）：1258-1270
[9] CUI Y，HOU D，WANG Z，et al. Increase in precipitation will facilitate the ecological stability of desert steppe in the future[J]. Global Ecology and Conservation，2024，52：e02958
[10] ZAKHARY A，NAGARAJAN A，NGO C，et al. Perennials have evolved a greater resistance to exogenous H₂O₂ than annuals， consistent with the oxidative stress theory of aging[J]. Biologia，2022，77（8）：2063-2080
[11] CLARK K M，EARL A G，LOPEZ I M，et al. Soil pooling often， but not always， alters the impacts of plant-microbe interactions on plant growth[J]. Plant and Soil， 2024，（prepublish）：1-9
[12] CHAPMAN S K，LANGLEY J A，HART S C，et al. Plants actively control nitrogen cycling： uncorking the microbial bottleneck[J]. New Phytologist，2006，169（1）：27-34
[13] VAN DER PUTTEN WIM H. Plant defense belowground and spatiotemporal processes in natural vegetation[J]. Ecology，2003，84（9）：2269-2280
[14] MENG T T. Effects of rhizosphere/endophytic microbial communities and growth-promoting microorganisms on host growth and metabolism of Codonopsis pilosula[D]. Lanzhou：Lanzhou University of Technology，2023：6-7 孟彤彤. 党参根际/内生微生物群落及促生微生物对宿主生长代谢的影响[D]. 兰州：兰州理工大学，2023：6-7
[15] NGUYEN T B H，HENRI-SANVOISIN A，LE FLOCH G，et al. Delving into the soil and phytomicrobiome for disease suppression： a case study for the control of Fusarium Head Blight of cereals[J]. Science of the Total Environment，2025，965：178655
[16] DONG Q，WANG Y M，GUAN P T，et al. Effects of soil micro-food web organisms and soil microorganisms on the growth of Carex angustior and soil nutrients[J]. Acta Ecologica Sinica，2023，43（23）：9784-9793 董琦，王一媚，管平婷，等. 土壤微食物网生物和土壤微生物对小星穗薹草生长和土壤养分的影响差异[J]. 生态学报，2023，43（23）：9784-9793
[17] BREIDENBACH A，SCHLEUSS P M，LIU S B，et al. Microbial functional changes mark irreversible course of Tibetan grassland degradation[J]. Nature Communications，2022，13（1）：2681-2681
[18] BIRNBAUM C，WOOD J，LILLESKOV E，et al. Degradation reduces microbial richness and alters microbial functions in an Australian peatland[J]. Microbial Ecology，2023，85（3）：875-891
[19] LI Y，LU X，SU J，et al. Phosphorus availability and planting patterns regulate soil microbial effects on plant performance in a semiarid steppe[J]. Annals of Botany，2023，131（7）：1081-1095
[20] TRIVEDI P，LEACH J E，TRINGE S G，et al. Plant-microbiome interactions： from community assembly to plant health[J]. Nature Reviews Microbiology，2020，18（11）：607-621
[21] WILSCHUT R A，HUME B C C，MAMONOVA E，et al. Plant-soil feedback effects on conspecific and heterospecific successors of annual and perennial Central European grassland plants are correlated[J]. Nature Plants，2023，9（7）：1057-1066
[22] SPITZER C M，WARDLE D A，LINDAHL B D，et al. Root traits and soil micro-organisms as drivers of plant-soil feedbacks within the sub‐Arctic tundra meadow[J]. Journal of Ecology，2022，110（2）：466-478
[23] ZHANG C Z，WANG J J，REN Z H，et al. Root traits mediate functional guilds of soil nematodes in an ex-arable field[J]. Soil Biology and Biochemistry，2020，151：108038-108038
[24] STEINAUER K，THAKUR M P，EMILIA HANNULA S，et al. Root exudates and rhizosphere microbiomes jointly determine temporal shifts in plant‐soil feedbacks[J]. Plant， Cell & Environment，2023，46（6）：1885-1899
[25] ZHAO Y L. The preparation of high-efficiency functional microbial agents and their application effect on degraded desert steppe[D].Hohhot： Inner Mongolia Agricultural University，2024：28-29 赵玉璐.高效功能菌剂制备及退化荒漠草原应用效果研究[D]. 呼和浩特：内蒙古农业大学，2024：28-29
[26] GAO X F，JIA Y. Analysis of organic acid components in root exudates and their ecological effects of the plants in desert steppe of Inner Mongolia[J]. Ecology and Environmental Sciences，2020，29（10）：1927-1934 高雪峰，贾渊. 荒漠草原植物根分泌物中有机酸组分分析及其生态效应研究[J]. 生态环境学报，2020，29（10）：1927-1934
[27] JIANG T H. A simple method for measuring the rated watering amount of potted soil[J]. Chinese Journal of Soil Science，1993，24（1）：48-49 蒋廷惠. 盆栽土壤额定浇水量的简易测定方法[J]. 土壤通报，1993，24（1）：48-49
[28] LI H M，LI Q F QU Y，et al. Effects of different plant growth regulatorson plant type and physiological characteristics of Hylotelephium erythrostictum[J]. Acta Agrestia Sinica，2022，30（12）：3294-3301 李浩铭，李青丰，曲艳，等. 不同植物生长调剂对八宝景天株型和生理特性的影响[J]. 草地学报，2022，30（12）：3294-3301
[29] KAN H M，XU H K，LU J N，et al. The influence of different arbuscular mycorrhizal fungi inoculation on the growth characteristics of three forage species[J]. Acta Agrestia Sinica，2023，31（7）：1922-1930 阚海明，徐恒康，鲁佳男，等. 不同丛枝菌根真菌接种对3种草地植物生长特性的影响[J]. 草地学报，2023，31（7）：1922-1930
[30] NOSSA C W，OBERDORF W E，YANG L Y，et al. Design of 16S rRNA gene primers for 454 pyrosequencing of the human foregut microbiome[J]. World Journal of Gastroenterology，2010，16（33）：4135-4144
[31] MUKHERJEE P K，CHANDRA J，RETUERTO M，et al. Oral mycobiome analysis of HIV-infected patients：identification of Pichia as an antagonist of opportunistic fungi[J]. PLoS Pathogens，2014，10（3）：e1003996
[32] ZHAO Y，YE H，WU Z D，et al. Effects of nitrogen deposition and precipitation changes on the soil ammonia-oxidizing bacteria community in desert steppe[J]. China Environmental Science，2024，44（10）：5757-5765 赵宇，叶贺，武振丹，等. 氮沉降和降水变化对荒漠草原土壤氨氧化细菌群落的影响[J]. 中国环境科学，2024，44（10）：5757-5765
[33] CHAO A，BUNGE J. Estimating the number of species in a stochastic abundance model[J]. Biometrics，2002，58（3）：531-539
[34] HILL T C J，WALSH K A，HARRIS J A，et al. Using ecological diversity measures with bacterial communities[J]. FEMS Microbiology Ecology，2003，43（1）：1-11
[35] BEVER J D，WESTOVER K M，ANTONOVICS J. Incorporating the soil community into plant population dynamics：the utility of the feedback approach[J]. The Journal of Ecology，1997，85（5）：561
[36] PAINA C，FOIS M，ASP T，et al. The soil microbiome of Lolium perenne L. depends on host genotype，is modified by nitrogen level and varies across season[J]. Scientific Reports，2024，14（1）：5767
[37] HUANG B W，WANG P，WANG Y，et al. Functional endophytic organic fertilizer alleviates phthalates burden and promotes vegetable growth with the assistance of indigenous Sphingomonas[J]. Case Studies in Chemical and Environmental Engineering，2024，9：100671
[38] BLASZKOWSKI J，NIEZGODA P，ZUBEK S，et al. Dominikia bonfanteae and Glomus atlanticum，two new species in the Glomeraceae （Phylum Glomeromycota） with molecular phylogenies reconstructed from two unlinked loci[J]. Mycological Progress，2021，20（2）：131-148
[39] PASCUAL J，GARCÍA-LÓPEZ M，BILLS G F，et al. Longimicrobium terrae gen. nov.，sp. nov.，an oligotrophic bacterium of the under-represented Phylum Gemmatimonadetes isolated through a system of miniaturized diffusion chambers[J]. International Journal of Systematic and Evolutionary Microbiology，2016，66（5）：1976-1985
[40] WANG X J，LIU E K，TIAN L. Impact of soil bacteria on amylose synthesis in maize kernels under the substitution of manure nitrogen for mineral fertilizer nitrogen[J]. International Journal of Biological Macromolecules，2024，282：136705-136705
[41] Karling John S. Zoosporic fungi of oceania. Ⅶ. fusions in rhizophlyctis[J]. American journal of botany，1969，56（2）：211
[42] WU J J，ZHU J H，ZHANG D Q，et al. Beneficial effect on the soil microenvironment of Trichoderma applied after fumigation for cucumber production[J]. PLoS One，2022，17（8）：e0266347
[43] AN Q R，ZHENG N，PAN J M，et al. Association between plant microbiota and cadmium uptake under the influence of microplastics with different particle sizes[J]. Environment International，2024，190：108938-108938
[44] PHILIPPOT L，CHENU C，KAPPLER A，et al. The interplay between microbial communities and soil properties[J]. Nature Reviews Microbiology，2023，22（4）：226-239
[45] JIANG F，BENNETT J A，CRAWFORD K M，et al. Global patterns and drivers of plant-soil microbe interactions[J]. Ecology Letters，2024，27（1）：e14364
[46] GÓRAL T，WIŚNIEWSKA H，OCHODZKI P，et al. Higher Fusarium toxin accumulation in grain of winter Triticale lines inoculated with Fusarium culmorum as compared with wheat[J]. Toxins，2016，8（10）：301-301
[47] DONG F，CHEN X X，LEI X Y，et al. Effect of crop rotation on Fusarium mycotoxins and Fusarium species in cereals in Sichuan Province（China）[J]. Plant Disease，2023，107（4）：1060-1066
[48] OSHIKI M，TOYAMA Y，SUENAGA T，et al. N₂O reduction by Gemmatimonas aurantiaca and potential involvement of gemmatimonadetes bacteria in N₂O reduction in agricultural soils[J]. Microbes and environments，2022，37（2）：ME21090
[49] CHIBA A，UCHIDA Y，KUBLIK S，et al. Soil bacterial diversity is positively correlated with decomposition rates during early phases of maize litter decomposition[J]. Microorganisms，2021，9（2）：357
[50] VIEIRA S，PASCUAL J，BOEDEKER C，et al. Terricaulis silvestris gen， a novel prosthecate， budding member of the family Caulobacteraceae isolated from forest soil[J]. International Journal of Systematic and Evolutionary Microbiology，2020，70（9）：4966-4977
[51] FIGUEIREDO G，GOMES M，COVAS C，et al. The unexplored wealth of microbial secondary metabolites：the Sphingobacteriaceae case study[J]. Microbial Ecology，2022，83（2）：470-481
[52] NEMERGUT D R，SCHMIDT S K，FUKAMI T，et al. Patterns and processes of microbial community assembly[J]. Microbiology and Molecular Biology Reviews，2013，77（3）：342-356
[53] LEKBERG Y，SCHNOOR T，KJØLLER R，et al. 454-sequencing reveals stochastic local reassembly and high disturbance tolerance within arbuscular mycorrhizal fungal communities[J]. Journal of Ecology，2012，100（1）：151-160
[54] LI Q M，ZHANG D，ZHANG J Z，et al. Crop rotations increased soil ecosystem multifunctionality by improving keystone taxa and soil properties in potatoes[J]. Frontiers in Microbiology，2023，14：1034761
[55] MIAO X Y，WANG E G，ZHOU Y，et al. Effect of ginsenosides on microbial community and enzyme activity in continuous cropping soil of ginseng[J]. Frontiers in Microbiology，2023，14：1060282
[56] CAO Y，DU P H，SHANG Y W，et al. Melatonin and dopamine alleviate waterlogging stress in apples by recruiting beneficial endophytes to enhance physiological resilience[J]. Journal of Integrative Agriculture，2024，23（7）：2270-2291
[57] LEITE M R L，DE ALCANTARA NETO F，DUTRA A F，et al. Silicon application influences the prokaryotic communities in the rhizosphere of sugarcane genotypes[J]. Applied Soil Ecology，2023，187：104818
[58] YU G，ULLAH H，LIN H，et al. Long-term phytoextraction potential and mechanism of Celosia argentea on soils with different levels of Cd and Mn co-contamination[J]. Journal of Environmental Chemical Engineering，2024，12（2）：112125

The Effects of Soil Microorganisms on the Growth of Annual and Perennial Forages in the Desert Steppe

土壤微生物对荒漠草原一年生和多年生牧草生长发挥的效应

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	JU Xin, WANG Xin-ya, WANG Bing-ying, HAN Guo-dong, WU Qian. Effects of Grazing Intensity on Plant Community Composition and Nutrient Quality of Forage in a Desert Steppe [J]. Acta Agrestia Sinica, 2025, 33(9): 2962-2972.
[2]	LI Jia-li, WANG Xing, WANG Juan, MIAO Chun-qin, WANG Tuo-he, GUAN Cheng-ping, JIA Gai-xiu, WU Gang, HU Hai-yan, CHEN Xiao-jun. Effects of Compound Microbial Agents Combined with Fertilizers Application on Maize continuous cropping Yield and Rhizosphere Bacterial Community [J]. Acta Agrestia Sinica, 2025, 33(9): 3108-3117.
[3]	ZHANG Lei, ZHANG Yu-juan, SUN Shi-xian, XU Xue-bao, XING Yue, LIU Xiao-li, GAO Cui-ping, WANG Cheng-jie. Effects of Different Grazing Intensities on Soil Organic Carbon Content in Desert Steppe [J]. Acta Agrestia Sinica, 2025, 33(8): 2541-2547.
[4]	ZHANG Li, YANG Xin-guo, WANG Lei, ZHANG Xue, QU Wen-jie, LIU Rong-guo, ZHANG Bo. Spatial Associations Analysis of Species in Sand-Fixing Community of Caragana korshinskii Based on Point Pattern [J]. Acta Agrestia Sinica, 2025, 33(6): 1886-1893.
[5]	JU Xin, WANG Wei, SHEN Ting-ting, WANG Yu-xin, HAN Guo-dong, WU Qian. Changes in Sheep Grazing Behavior under Different Grazing Intensities in Desert Steppe and Their Responses to Environmental Factors [J]. Acta Agrestia Sinica, 2025, 33(6): 1924-1933.
[6]	YANG Xin, XIAO Xue, NIU Qiong-mei, XIAO Wei, DUAN Rui, CI Wang, HOU Xiao-han, CHU Xiao-hui, SHAN Gui-lian. Effects of Euphorbia jolkinii Invasion on Soil Microbial Characteristics in Shangri La Mountain Meadows [J]. Acta Agrestia Sinica, 2025, 33(3): 778-788.
[7]	SUN Wen-qian, CHU Bin, YE Guo-hui, CAI Bin, ZHANG Jing, ZHANG Zhi-ying, HUA Li-min. Effects of Photovoltaic Power Station on Soil Bacterial Community Composition and Diversity in Alpine Meadow [J]. Acta Agrestia Sinica, 2025, 33(2): 440-450.
[8]	SUN Zhi-qiang, HAN Chun-xue, LI Hai-gang. Responses of Soil Respiration and its Components to Persistent Drought and Rewetting in Desert Steppe [J]. Acta Agrestia Sinica, 2025, 33(2): 535-546.
[9]	WANG Ning-bin, QIAO Ji-rong, LI Shao-yu, ZHENG Jia-hua, ZHANG Feng, ZHANG Bin, XU Long-chao, ZHOU Qing-ge, CHEN Xin-li, ZHAO Meng-li, JI Xiang. Effects of Grazing Intensity on Root Morphology of Stipa breviflora [J]. Acta Agrestia Sinica, 2025, 33(12): 4015-4022.
[10]	MENG Pu-jia, WANG Zi-han, YAN Bao-long, LYU Shi-jie, WANG Zhong-wu. Impacts of Stocking Rate on the Spatial Distribution of Soil Nutrients in the Vicinity of Ceratoides latens [J]. Acta Agrestia Sinica, 2025, 33(12): 4139-4151.
[11]	GUO Rong-ming, ZHAO Xin, YANG Jun-hui, CHENG Fang-fang, CHEN Xin-yan. Effects of Degradation of Alpine Desert Steppe on Soil Bacterial Community in Southwestern of the Xizang Plateau [J]. Acta Agrestia Sinica, 2025, 33(11): 3581-3592.
[12]	DUAN Lei-yu, LI Zhi-guo, CUI Le, SUN Xue-yan, WANG Xin-yu, LYU Shi-jie. Study on the Morphological Characteristics of Wind Erosion in Desert Steppe Under Different Grazing Intensities [J]. Acta Agrestia Sinica, 2025, 33(11): 3766-3773.
[13]	WANG Xiao-yan, LYU Shi-jie, WANG Rong, WANG Xin-yu, LI Zhi-guo. A Study of Soil Wind Erosion under Gradient Grazing in Desert Steppe Based on RWEQ [J]. Acta Agrestia Sinica, 2025, 33(11): 3799-3809.
[14]	HAN Yan-long, YANG Wen-yuan, HAN Min, GAO Yong, YUAN Xiao-man, YAN Ru. Bacterial Community Structure and Diversity in Rhizosphere Soil in Caragana tibetica Desert Grassland [J]. Acta Agrestia Sinica, 2025, 33(10): 3215-3224.
[15]	ZHANG Rui, CUI Yuan-yuan, WANG Yue-hua, ZHU Ai-min, WU Qian, HAN Guo-dong, HOU Dong-jie, WNAG Zhong-wu. Characteristics of Nitrogen and Phosphorus Utilization in Plants and the Relationships with Soil in Fenced Desert Grasslands Physicochemical Properties [J]. Acta Agrestia Sinica, 2025, 33(10): 3330-3340.