生草栽培对油茶林土壤微生物群落结构和稳定性的影响

doi:10.11707/j.1001-7488.20221106

摘要/Abstract

摘要：

目的: 探究生草栽培对南方红壤区油茶土壤微生物群落结构和稳定性的影响，为油茶林抚育及可持续经营提供理论依据。方法: 对保留自然杂草（TZ）、清耕抚育除草（TF）、间种金鸡菊（TJ）和间种百喜草（TB）的油茶林，用高通量测序法研究土壤微生物群落结构，用Brokenstick、Zipf、Mandelbrot等模型分析不同处理的土壤微生物群落多度格局，用零建模方法推断群落聚集过程，用群落平均变异度评价微生物群落稳定性，并通过网络分析预测菌群间相互作用。结果: 不同处理的土壤养分及酶活性存在差异。TF处理土壤的全碳、全氮、速效氮和速效磷含量最高，TF和TB处理间的土壤养分及酶活性无显著差异。TF、TJ和TB处理的土壤微生物群落组成较为相似，优势菌门为变形菌门和酸杆菌门，占比超过50%，优势菌科为克氏菌科，占比超过12%；TZ处理的优势菌门为变形菌门和拟杆菌门，约占55.1%，优势菌科为丛毛单胞菌科，约占12.8%。Zipf-Mandelbrot模型对生草栽培下土壤微生物物种多度格局的拟合效果最优，TZ处理的土壤微生物群落物种结构更加均衡，其多度下降的幅度与其他处理相比较小，土壤微生物群落中优势种的优势度较弱；TF和TB处理群落结构的均衡性较差。不同生草栽培处理间的土壤微生物群落稳定性存在显著差异，TF处理土壤微生物群落稳定性的平均变异度指数（AVD）值为0.411，稳定性最强；TZ处理的土壤微生物群落AVD值为0.634，稳定性最差。各土层的各处理间的β生物分类学指数（βNTI）绝对值均大于2，表明微生物群落变化为确定性演替过程，微生物群落结构变化主要受到决定性因素的影响。微生物群落的β多样性与环境距离呈显著正相关；在消除遗传差异后，环境对群落构建仍存在显著影响，而遗传距离和消除环境距离的遗传距离均对群落构建影响不显著，即生境过滤对油茶林土壤微生物群落的构建存在影响。在生草栽培处理下，维持油茶群落稳定性的核心菌属有代尔夫特菌属、Methylotenera、红育菌属、鞘脂菌属和韦荣氏球菌属等。研究发现变形菌门和绿弯菌门对环境变化的响应不敏感，全钾含量对酸杆菌门的影响极显著，对放线菌门和厚壁菌门的影响显著；全磷含量对厚壁菌门的影响极显著。结论: 生草栽培对南方红壤区油茶土壤微生物群落稳定性存在影响，土壤中钾含量显著影响微生物群落结构及稳定性，百喜草比较适宜作为油茶林的生草栽培草种。油茶林中保留自然杂草会降低土壤中的养分含量及土壤微生物的群落稳定性；清耕抚育除草提高了土壤微生物的群落稳定性，但群落组成格局不均衡，长期清耕会造成稀有种群损失，可能会导致生态服务功能减弱。

关键词: 油茶林, 生草栽培, 土壤微生物, 群落结构, 群落稳定性

Abstract:

Objective: The aim of this study was to explore the effect of herbage inter-planting on the stability of soil microbial community of Camellia oleifera plantations in southern red soil region. These findings would provide the theoretical basis for sustainable management of C. oleifera plantation. Method: The structure of soil microorganisms of C. oleifera plantations respectively with tending and weeding (TF), preserving natural weeds (TZ), inter-planting of Coreopsis basalis (TJ) and inter-planting of Paspalum notatum (TB) was studied by high-throughput sequencing method, the abundance pattern of soil microbial community was analyzed by using brokenstick, Zipf, Mandelbrot and other models, and the community aggregation process was inferred by zero modeling method. The stability of microbial community was evaluated by the average variation degree of community, and the interaction between microbial communities was predicted by network analysis. Result: There were differences in soil nutrients and enzyme activities under different herbage inter-planting treatments. The contents of total carbon, total nitrogen, available nitrogen, and available phosphorus were the highest in TF treatment, and there was no significant difference in soil nutrients and enzyme activities between TF and TB. The composition of soil microbial community under TF, TJ, and TB treatments were similar. Among them, Proteobacteria and Acidobacteria were the dominant phyla, accounting for more than 50% of the total soil microbial. Koribacteraceae was the dominant family, accounting for more than 12% of the total. The dominant phyla of TZ treatment were Proteobacteria and Bacteroidetes, accounting for 55.1%, and the dominant family was comamonadaceae, accounting for 12.8%. Zipf Mandelbrot model had the best fitting effect on soil microbial abundance pattern. The species structure of soil microbial community under TZ treatment was the most balanced, with a small decrease in abundance and a weak dominance of dominant species in soil microbial community. The balance of community structure in TF and TB treatments was poor. There were significant differences in the stability of soil microbial communities among different herbage inter-planting treatments. The average variation degree value (AVD) of TF treatment was 0.411, indicating that the stability of soil microbial communities was the strongest. The AVD value of TZ treatment was 0.634, indicating that the stability of soil microbial communities was the worst. The absolute value of beta nearest taxon index (βNTI) between each treatment was bigger than 2, indicating that the change of microbial community was a deterministic assembly process, and the change of microbial community structure was mainly affected by decisive factors. The β diversity of microbial community was significantly positively correlated with the environmental distance. When the genetic difference was eliminated, the environment still had a significant indigenous effect on community construction, while the genetic distance and the genetic distance to eliminate the environmental distance had no significant indigenous effect on community construction, that is, habitat filtering had an effect on the construction of soil microbial community in C. oleifera plantation. Delftia, Methylotenera, Rhodoferax, Sphingobium and Veillonella were the core genera for maintaining the network stability under herbage inter-planting treatments. The effects of soil environment on dominant flora were studied, and the results showed that Proteobacteria and Chloroflexi were not sensitive to environmental changes, and the effect of total potassium content on Acidobacteria was extremely significant, while that on Actinobacteria and Firmicutes was significant. Total phosphorus content had a significant effect on Firmicutes. Conclusion: The herbage inter-planting had an effect on the stability of soil microbial community in C. oleifera plantations in red soil area in southern China. Soil potassium content significantly affected the structure and stability of microbial community, and P. notatum is more suitable for herbage inter-planting in C. oleifera plantations. It is not suitable to inter-plant natural weeds in C.oleifera plantations, which can reduce soil nutrient content and soil microbial community stability. Although tillage and tending weeding improved the stability of soil microbial community, its composition pattern was not balanced. The long-term clearing and weeding would cause the loss of rare populations and may weaken the ecological service function.

Key words: Camellia oleifera plantation, herbage planting, soil microorganism, community structure, community stability

中图分类号:

陈永忠,刘彩霞,许彦明,张震,彭映赫,陈隆升,苏以荣,王瑞,唐炜. 生草栽培对油茶林土壤微生物群落结构和稳定性的影响[J]. 林业科学, 2022, 58(11): 61-70.

Yongzhong Chen,Caixia Liu,Yanming Xu,Zhen Zhang,Yinghe Peng,Longsheng Chen,Yirong Su,Rui Wang,Wei Tang. Effects of Herbage Inter-Planting on Structure and Stability of Soil Microbial Community in Camellia oleifera Plantations[J]. Scientia Silvae Sinicae, 2022, 58(11): 61-70.

图/表 8

图1

图2

图3

表1

图4

表2

图5

图6

参考文献 0

	鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2000.
	Bao S D . Soil agricultural chemistry analysis. Beijing: China Agriculture Press, 2000.
	陈俊. 2020. 干旱荒漠区苹果园自然生草效果研究. 新疆维吾尔自治区: 塔里木大学.
	Chen J. 2020. Effect of natural weeds on fuji apple orchard in arid desert area. Xinjiang Uygur Autonomous Region: Tarim University. [in Chinese]
	陈隆升, 梅莉, 陈永忠, 等. 油茶林生草栽培对地表径流及氮磷流失特征的影响. 南京林业大学学报(自然科学版), 2021, 45 (6): 127- 134.
	Chen L S , Mei L , Chen Y Z , et al. Effects of interplanting herbage on surface runoff associated with nitrogen and phosphorus losses in Camellia oleifera plantations. Journal of Nanjing Forestry University(Natural Sciences Edition), 2021, 45 (6): 127- 134.
	陈永忠, 邓绍宏, 陈隆升, 等. 油茶产业发展新论. 南京林业大学学报(自然科学版), 2020, 44 (1): 1- 10.
	Chen Y Z , Deng S H , Chen L S , et al. A new view on the development of soil tea camellia industry. Journal of Nanjing Forestry University(Natural Sciences Edition), 2020, 44 (1): 1- 10.
	丛微, 于晶晶, 喻海茫, 等. 不同气候带森林土壤微生物多样性和群落构建特征. 林业科学, 2022, 58 (2): 70- 79.
	Cong W , Yu J J , Yu H M , et al. Diversity and community assembly of forest soil microorganisms in different climatic zones. Scientia Silvae Sinicae, 2022, 58 (2): 70- 79.
	傅聿青, 李江, 李建安, 等. 生草栽培对油茶林地土壤养分特征和微生物及酶活性的影响. 经济林研究, 2018, 36 (3): 82- 88.
	Fu J Q , Li J , Li J A , et al. Effect of sod culture on soil characteristics, microorganisms and enzymatic activities of Camellia oleifera land. Non-Wood Forest Research, 2018, 36 (3): 82- 88.
	高翠萍, 李岩, 刘美英, 等. Vario MACRO cube元素分析仪测定土壤碳氮方法研究. 北方农业学报, 2017, 45 (1): 76- 79. doi: 10.3969/j.issn.2096-1197.2017.01.15
	Gao C P , Li Y , Liu M Y , et al. Study on the determination of soil carbon and nitrogen by vario MACRO cube elemental analyzer. Journal of Northern Agriculture, 2017, 45 (1): 76- 79. doi: 10.3969/j.issn.2096-1197.2017.01.15
	高尚坤, 肖文发, 曾立雄, 等. 马尾松人工林干扰对土壤微生物群落结构的短期影响. 林业科学, 2018, 54 (12): 92- 101. doi: 10.11707/j.1001-7488.20181210
	Gao S K , Xiao W F , Zeng L X , et al. Short term effects of Pinus massoniana plantation disturbance on soil microbial community structure. Scientia Silvae Sinicae, 2018, 54 (12): 92- 101. doi: 10.11707/j.1001-7488.20181210
	郭晓睿, 宋涛, 邓丽娟, 等. 果园生草对中国果园土壤肥力和生产力影响的整合分析. 应用生态学报, 2021, 32 (11): 4021- 4028.
	Guo X R , Song T , Deng L J , et al. Effects of grass growing on soil fertility and productivity of orchards in China: a meta-analysis. Chinese Journal of Applied Ecology, 2021, 32 (11): 4021- 4028.
	贺纪正, 李晶, 郑袁明. 土壤生态系统微生物多样性-稳定性关系的思考. 生物多样性, 2013, 21 (4): 411- 420.
	He J Z , Li J , Zheng Y M . Thoughts on the microbial diversity-stability relationship in soil ecosystems. Biodiversity Science, 2013, 21 (4): 411- 420.
	金翠萍, 向斯, 郭溪, 等. 不同碳源对Delftiatsuruhatensis HT01脱氮性能的影响. 中国环境科学, 2019, 39 (4): 1478- 1484.
	Jin C P , Xiang S , Guo X , et al. The influence of different carbon sources on the nitrogen removal characters of a Delftiatsuruhatensis HT01. China Environmental Science, 2019, 39 (4): 1478- 1484.
	林先贵, 冯有智, 陈瑞蕊. 农田潮土养分耦合循环的微生物学机理研究进展. 植物营养与肥料学报, 2017, 23 (6): 1575- 1589.
	Lin X G , Feng Y Z , Chen R R . Research progresses of soil microorganisms driven nutrient coupling cycles in fluvo-aquic soils of China. Journal of Plant Nutrition and Fertilizer, 2017, 23 (6): 1575- 1589.
	刘彩霞, 焦如珍, 董玉红, 等. 应用PLFA方法分析氮沉降对土壤微生物群落结构的影响. 林业科学, 2015, 51 (6): 155- 162.
	Liu C X , Jiao R Z , Dong Y H , et al. Effect of nitrogen deposition on soil microbial community structure determined with the PLFA method. Scientia Silvae Sinicae, 2015, 51 (6): 155- 162.
	钱雅丽, 梁志婷, 曹铨, 等. 陇东旱作果园生草对土壤细菌群落组成的影响. 生态学杂志, 2018, 37 (10): 3010- 3017.
	Qian Y L , Liang Z T , Cao Q , et al. Effects of grass-planting on soil bacterial community composition of apple orchard in Longdong arid region. Chinese Journal of Ecology, 2018, 37 (10): 3010- 3017.
	孙纪全, 梁斌, 黄星, 等. Sphingobium属细菌土壤中降解异丙隆的特性. 土壤学报, 2011, 48 (2): 383- 388.
	Sun J Q , Liang B , Huang X , et al. Characteristics of isoproturon degradation in soils by strains of Sphingobium. Acta Pedologica Sinica, 2011, 48 (2): 383- 388.
	吴希慧, 王蕊, 高长青, 等. 土地利用驱动的土壤性状变化影响微生物群落结构和功能. 生态学报, 2021, 41 (20): 7989- 8002.
	Wu X H , Wang R , Gao C Q , et al. Variations of soil properties effect on microbial community structure and functional structure under land uses. Acta Ecologica Sinica, 2021, 41 (20): 7989- 8002.
	吴玉森, 张艳敏, 冀晓昊, 等. 自然生草对黄河三角洲梨园土壤养分、酶活性及果实品质的影响. 中国农业科学, 2013, 46 (1): 99- 108.
	Wu Y S , Zhang Y M , Yi X H , et al. Effects of natural grass on soil nutrient, enzyme activity and fruit quality of pear orchard in Yellow River Delta. Scientia Agricultura Sinica, 2013, 46 (1): 99- 108.
	肖力婷, 杨慧林, 黄文新, 等. 生草栽培对南丰蜜橘园土壤酶活性及氮循环功能微生物的影响. 应用与环境生物学报, 2021, 27 (6): 1476- 1484.
	Xiao L T , Yang H L , Huang W X , et al. Effect of grass cultivation on soil enzyme activities and nitrogen cycling function microorganisms in Nanfeng Tangerine Orchard. Chinese Journal of Applied and Environmental Biology, 2021, 27 (6): 1476- 1484.
	颜晓捷, 黄坚钦, 邱智敏, 等. 生草栽培对杨梅果园土壤理化性质和果实品质的影响. 浙江农林大学学报, 2011, 28 (6): 850- 854.
	Yan X J , Huang J Q , Qiu Z M , et al. Soil physical and chemical properties and fruit quality with grass cover in a Myrica rubra orchard. Journal of Zhejiang A & F University, 2011, 28 (6): 850- 854.
	余锦林, 尤龙辉, 徐惠昌, 等. 果园生草改善土壤质量和锥栗农艺性状的效果. 草业科学, 2021, 38 (12): 2460- 2470.
	Yu J L , You L H , Xu H C , et al. Effects of artificial grass on improving soil quality and agronomic traits of chestnuts in a Castanea henryi orchard. Pratacultural Science, 2021, 38 (12): 2460- 2470.
	袁军, 谭晓风, 袁德义, 等. 油茶根系分布规律调查研究. 浙江林业科技, 2009, 29 (4): 30- 32.
	Yuan J , Tang X F , Yuan D Y , et al. Study on root system distribution of Camellia oleifera. Journal of Zhejiang Forestry Science and Technology, 2009, 29 (4): 30- 32.
	Bardgett R D , Putten W . Belowground biodiversity and ecosystem functioning. Nature, 2014, 515 (7528): 505- 511.
	Bai B , Liu W , Qiu X , et al. The root microbiome: community assembly and its contributions to plant fitness. Journal of Integrative Plant Biology, 2022, 64 (2): 230- 243.
	Jiao S , Yang Y , Xu Y , et al. Balance between community assembly processes mediates species coexistence in agricultural soil microbiomes across eastern China. The ISME Journal, 2020, 14 (1): 202- 216.
	Kader M , Lamb D T , Correll R , et al. Pore-water chemistry explains zinc phytotoxicity in soil. Ecotoxicology & Environmental Safety, 2015, 122, 252- 259.
	Li F , Chen L , Redmile-Gordon M , et al. Mortierellaelongata's roles in organic agriculture and crop growth promotion in amineral soil. Land Degradation & Development, 2018, 29 (6): 1642- 1651.
	Liu C , Chen L , Tang W , et al. Predicting potential distribution and evaluating suitable soil condition of oil tea Camellia in China. Forests, 2018, 9 (8): 487.
	Mcgill B J , Etienne R S , Gray J S , et al. Species abundance distributions: moving beyond single prediction theories to integration within an ecological framework. Ecology Letters, 2007, 10, 995- 1015.
	Ni Y , Yang T , Ma Y , et al. Soil pH determines bacterial distribution and assembly processes in natural mountain forests of eastern China. Global Ecology and Biogeography, 2021, 30 (11): 2164- 2177.
	Sunagawa S , Coelho L P , Chaffron S , et al. Structure and function of the global ocean microbiome. Science, 2015, 348 (6237): 1261359.
	Wei H , Zhang K , Zhang J , et al. Grass cultivation alters soil organic carbon fractions in a subtropical orchard of southern China. Soil and Tillage Research, 2018, 181, 110- 116.
	Widdig M , Heintz-Buschart A , Schleuss P M , et al. Effects of nitrogen and phosphorus addition on microbial community composition and element cycling in a grassland soil. Soil Biology and Biochemistry, 2020, 151, 108041.
	Xun W , Liu Y , Li W , et al. Specialized metabolic functions of keystone taxa sustain soil microbiome stability. Microbiome, 2021, 9 (1): 1- 15.
	Zhang S , Li K , Hu J , et al. Distinct assembly mechanisms of microbial sub-communities with different rarity along the Nu River. Journal of Soils and Sediments, 2022, 22 (5): 1530- 1545.
	Zhang X , Myrold D D , Shi L , et al. Resistance of microbial community and its functional sensitivity in the rhizosphere hotspots to drought. Soil Biology and Biochemistry, 2021, 161, 108360.

处理 Treatment	模型 Model	常数参数 Constant parameter	Gamma参数 Gamma parameter	Beta参数 Beta parameter	偏差 Deviation	AIC值 Akaike information criterion value	BIC值 Bayesian information criterion value
TF	Brokenstick	/	/	/	1 270.710	7 195.640	7 195.640
	Niche preemption	0.001	/	/	207.730	6 134.650	6 140.230
	Log-normal	1.204	0.590	/	482.540	6 411.460	6 422.610
	Zipf	0.005	-0.372	/	1 390.620	7 319.540	7 330.690
	Zipf-Mandelbrot	∞	-1.820×10⁵	1.537×10⁸	136.630	6 067.550	6 084.280
TZ	Brokenstick	/	/	/	786.400	5 470.870	5 470.870
	Niche preemption	0.001	/	/	131.510	4 817.910	4 823.450
	Log-normal	0.748	0.651	/	188.810	4 877.270	4 888.220
	Zipf	0.008	-0.436	/	542.410	5 230.870	5 241.820
	Zipf-Mandelbrot	13 894	-2.301	985.980	63.010	4 753.470	4 769.900
TJ	Brokenstick	/	/	/	939.896	6 579.064	6 579.064
	Niche preemption	0.001	/	/	112.468	5 753.636	5 759.237
	Log-normal	0.942	0.640	/	303.816	5 946.984	5 958.187
	Zipf	0.007	-0.414	/	962.700	6 605.868	6 617.071
	Zipf-Mandelbrot	∞	-56 428	4.551×10⁷	70.531	5 715.698	5 732.503
TB	Brokenstick	/	/	/	1 186.170	7 537.970	7 537.970
	Niche preemption	0.001	/	/	149.320	6 503.120	6 508.80
	Log-normal	1.078	0.610	/	385.290	6 741.100	6 752.460
	Zipf	0.006	-0.390	/	1 228.140	7 583.950	7 595.310
	Zipf-Mandelbrot	∞	-9.082×10⁶	8.303×10⁹	86.25	6 444.050	6 461.090

项目 Item	环境距离 Environment distance	环境距离(消除遗传距离) Environment distance eliminate genetic distance	遗传距离 Genetic distance	遗传距离(消除环境距离) Genetic distance eliminateenvironment distance
统计r值Statistic r	0.886	0.706	0.829	0.738
显著性Significance	0.042^*	0.042^*	0.125	0.208

[1]	李志,薛晓焱,刘震,蔡齐飞,耿晓东,冯建,周慧娜,张涛,李明婉,王艳梅. 山桐子健康和感病植株不同器官区细菌群落结构、多样性与功能预测分析[J]. 林业科学, 2022, 58(8): 136-148.
[2]	李斌,史鸿翔,刘兰兰,杨璞,张欣,陈航,冯颖,陈晓鸣. 女贞叶、茎、根及根际土壤真菌群落结构及功能群特征[J]. 林业科学, 2022, 58(5): 102-112.
[3]	丛微,于晶晶,喻海茫,丁易,张于光. 不同气候带森林土壤微生物多样性和群落构建特征[J]. 林业科学, 2022, 58(2): 70-79.
[4]	彭金根,龚金玉,范玉海,张华,张银凤,白宇清,王艳梅,谢利娟. 毛棉杜鹃根际与非根际土壤微生物群落多样性[J]. 林业科学, 2022, 58(2): 89-99.
[5]	曹俐, 王阳, 杨蕴力, 郑雨, 王伟, 刘桂丰, 姜静. 转BpGLK裂叶桦生长变异、根际土壤酶活性及微生物群落组成分析[J]. 林业科学, 2022, 58(12): 21-31.
[6]	张伟溪,王颜波,丁昌俊,朱文旭,苏晓华. 成龄转基因银中杨试验林外源基因水平转移及土壤微生物连年监测[J]. 林业科学, 2022, 58(1): 52-61.
[7]	赵鹏宇,白雪,燕平梅,赵晓东,武晓英,柴宝峰. 华北落叶松林土壤细菌群落结构与表型的环境异质性响应[J]. 林业科学, 2021, 57(7): 101-110.
[8]	郑翔,曹敏敏,纪小芳,方万力,刘胜龙,姜姜. 森林土壤氧化亚氮排放对磷添加响应的研究进展[J]. 林业科学, 2021, 57(6): 150-157.
[9]	谢云,郭芳芸,陈丽华,曹兵. 大气CO₂浓度升高对宁夏枸杞根区土壤微生物功能多样性及碳源利用特征的影响[J]. 林业科学, 2021, 57(4): 163-172.
[10]	李益,冯秀秀,赵发珠,郭垚鑫,王俊,任成杰. 秦岭太白山不同海拔锐齿栎林土壤微生物群落的变化特征[J]. 林业科学, 2021, 57(12): 22-31.
[11]	庞荣荣,彭潔莹,闫琰. 太白山次生锐齿栎林地上生物量影响因素[J]. 林业科学, 2021, 57(10): 157-165.
[12]	谢宪, 梁军, 朱彦鹏, 胡瑞瑞, 程元, 张星耀. 赤松纯林不同松枯梢病病级针叶的内生真菌多样性及群落结构[J]. 林业科学, 2020, 56(9): 51-57.
[13]	刘昌霖,周国英,肖柏,刘君昂. 降香黄檀心材和边材内生真菌多样性[J]. 林业科学, 2020, 56(4): 109-120.
[14]	王安宁, 黄秋娴, 李晓刚, 徐学华, 李玉灵. 冀北山区不同植被恢复类型根际土壤细菌群落结构及多样性[J]. 林业科学, 2019, 55(9): 130-141.
[15]	曹红雨, 高广磊, 丁国栋, 张英, 赵媛媛, 任悦, 陈宇轩, 郭米山. 呼伦贝尔沙区4种生境土壤真菌群落结构和多样性[J]. 林业科学, 2019, 55(8): 118-127.