有机无机肥长期配施对毛竹林土壤固碳和固氮微生物的影响

doi:10.11707/j.1001-7488.20220709

摘要/Abstract

摘要：

目的: 探讨毛竹林长期有机无机肥配施对土壤固碳和固氮微生物群落结构的影响，以期为我国竹林土壤肥力维持和提高提供理论依据。方法: 采集毛竹林集约经营6年(IM6)、10年(IM10)、15年(IM15)、20年(IM20)的表层(0~20 cm)和亚表层(20~40 cm)土壤，以立地条件相同且未施肥毛竹林为对照(CK)，采用荧光定量PCR(qPCR)、末端限制性片段长度多态分析(T-RFLP)和克隆文库，进行冗余分析(RDA)。结果: 1) 不同经营年限土壤pH值稳定在5.0~5.5，土壤有机碳(SOC)、全氮(TN)、碱解氮(AN)和速效钾(AP)含量波动较大，但与CK相比，经营20后土壤养分含量均显著上升(P < 0.05)。2) 与CK相比，表层土壤固碳基因cbbL丰度在IM6时显著降低(P < 0.05)，IM20时土壤cbbL基因丰度恢复至CK水平；而各经营年限的土壤固氮基因nifH丰度显著低于CK(P < 0.05)并持续下降。固碳和固氮微生物Shannon指数和均匀度指数在IM10显著下降(P < 0.05)，IM20时显著提高(P < 0.05)。毛竹林各经营年限固碳微生物群落结构与CK差异显著，而固氮微生物的IM20群落结构与CK相似。3) 系统发育分析表明，固碳微生物的优势菌群主要是变形菌门的慢生根瘤菌、百分红螺菌、运动硫黄球菌、美叶葡萄球菌、菊苣中根瘤菌、Starkeya novella；固氮微生物优势菌群主要是根瘤菌。4) 固碳微生物群落结构与土壤AP和NH₄⁺-N含量以及δ¹³C变化显著相关，固氮微生物群落结构与土壤AP、AK、SOC、NO₃^--N、C∶N和AN变化显著相关(P < 0.05)。结论: 毛竹林长期配施有机无机肥，提高了土壤养分含量，且未造成土壤酸化，对改善土壤养分具有积极作用，土壤养分变化是驱动毛竹林土壤中固碳和固氮微生物丰度、多样性和群落结构变化的重要原因。

关键词: 毛竹林, 有机无机配施, 固碳微生物, 固氮微生物

Abstract:

Objective: In this study, effects of long-term combined application of organic and inorganic fertilizers on soil carbon and nitrogen fixing microorganisms in Moso bamboo forests were investigated in order to provide theoretical basis for maintaining and improving soil fertility. Method: Soil samples were collected from surface (0 - 20 cm) and subsurface (20 - 40 cm) soil layers in moso bamboo forests intensively managed for 0(CK), 6, 10, 15, and 20 years. The fluorescence quantitative PCR (q-PCR), terminal restriction fragment length polymorphism (T-RFLP), and clone library of the cbbL and nifH genes, combined with redundancy analysis (RDA), were used to detect the differences in the community structure of CO₂- and N₂-fixing bacteria over time and reveal the effects of long-term combined application of organic and inorganic fertilizers on soil carbon and nitrogen fixation microbial community structure of Moso bamboo forests. Result: 1) The intensive management practice enhanced SOC and soil available N and K contents during 20 years, although they fluctuated during the process. The soil pH was generally stable between 5.0 and 5.5. 2) Compared with CK, the abundance of gene cbbL in topsoil decreased significantly at IM6 (P < 0.05), and then gradually recovered to the level of CK at IM20, while the abundance of gene nifH in management treatments was significantly decreased compared with CK (P < 0.05). Shannon index and evenness index of CO₂- and N₂-fixing bacteria decreased significantly after 10 years of management and increased significantly after 20 years of management (P < 0.05). The community structure of CO₂-fixing bacteria in CK was significantly different from that of all management treatments, while N₂- fixing bacterial community structure at IM20 was similar to that of CK. 3) Phylogenetic analysis showed that the dominant groups of CO₂- fixing microbials were Bradyrhizobium sp., Rhodospirillum centenum, Thioflavicoccus mobilis, Stappia meyerae, Mesorhizobium ciceri, and Starkeya novella, which all belonged to Proteobacteria, and the dominant group of N₂- fixing bacteria was Rhizobiales. 4) The community composition of CO₂- fixing bacteria was significantly correlated with contents of available phosphorus (AP) and NH₄⁺-N, and the change of δ¹³C. The community composition of N₂- fixing bacteria was significantly correlated with the changes of soil organic carbon (SOC), available phosphorus (AP), available potassium (AK), alkalytic nitrogen (N), NO₃^--N and C∶N. Conclusion: The long-term combined application of organic and inorganic fertilizer in Moso bamboo forests improves the soil nutrient content without causing soil acidification, which plays a positive role in improving the soil physicochemical properties. The changes in soil nutrient caused by the application of mineral fertilizer combined with manure is an important factor driving the changes of abundance, diversity and community structure of CO₂ -and N₂-fixing bacteria in the soil of Moso bamboo forests.

Key words: Moso bamboo forest, organic-mineral combined fertilzer, CO₂-fixing bacteria, N₂-fining bacteria

中图分类号:

S714.3

刘彩霞,陈俊辉,秦华,梁辰飞,徐秋芳. 有机无机肥长期配施对毛竹林土壤固碳和固氮微生物的影响[J]. 林业科学, 2022, 58(7): 82-92.

Caixia Liu,Junhui Chen,Hua Qin,Chenfei Liang,Qiufang Xu. Effects of Long-Term Combined Application of Organic and Inorganic Fertilizers on Soil CO₂- and N₂-Fixing Microorganisms in a Subtropical Bamboo Forest[J]. Scientia Silvae Sinicae, 2022, 58(7): 82-92.

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处理 Item	pH值 pH value	有机碳 Soil organic carbon/(g·kg^-1)	全氮 Total N/(g·kg^-1)	C∶N	碱解氮 Alkalytic N/(mg·kg^-1)	有效磷 Available P/(mg·kg^-1)	速效钾 Available K/(mg·kg^-1)	硝态氮 NO₃^--N/(mg·kg^-1)	铵态氮 NH₄⁺-N/(mg·kg^-1)	δ¹³C (‰)	δ¹⁵N (‰)
0~20 cm
CK	5.34±0.05a	10.74±1.02b	1.89±0.18b	5.67±0.05a	85.22±6.61b	2.40±0.33b	26.00±6.08b	36.28±8.39bc	6.25±1.53a	-26.88 ± 0.36c	3.46 ± 0.46b
IM6	5.36±0.12a	20.09±2.06a	2.97±0.26a	6.82±1.17a	164.2±12.88a	2.87±0.74b	21.44±4.23b	49.34±6.90a	3.81±0.60b	-26.56 ± 0.12bc	5.87 ± 0.58a
IM10	4.97±0.13b	10.76±2.00b	2.04±0.37b	5.28±0.13a	104.7±12.13b	4.15±1.94ab	24.66±2.88b	46.50±3.22ab	4.18±1.11ab	-26.24 ± 0.23ab	5.37 ± 0.28a
IM15	5.42±0.04a	10.75±0.94b	1.87±0.15b	5.76±0.04a	93.35±14.05b	5.47±1.25a	23.07±5.49b	32.74±2.94c	3.76±1.46b	-25.94 ± 0.22a	4.77 ± 0.69a
IM20	5.08±0.03b	18.10±1.89a	2.69±0.43a	6.87±1.46a	169.3±25.77a	2.63±0.74b	39.39±5.84a	37.85±3.58bc	2.45±0.78b	-26.31 ± 0.24ab	5.75 ± 0.93a
20~40 cm
CK	4.99±0.16A	5.68±1.78B	0.91±0.39B	6.52±1.79A	42.20±4.45C	6.92±2.32A	15.93±2.82D	22.29±4.95B	1.61±0.05B	-26.43 ± 0.10B	6.20 ± 0.85AB
IM6	5.10±0.15A	12.79±2.10A	2.36±0.37A	5.41±0.15A	105.20±31.93B	2.14±0.37B	25.39±4.18B	36.13±3.63A	2.65±0.22A	-26.11 ± 0.34BC	6.36 ± 0.37AB
IM10	5.07±0.17A	6.25±0.40B	1.15±0.04B	5.44±0.18A	52.68±3.44C	2.19±0.04B	22.76±0.82BC	23.17±2.61B	2.36±0.15A	-25.56 ± 0.12B	6.52 ± 0.55A
IM15	4.99±0.06A	5.43±1.44B	1.01±0.29B	5.38±0.10A	55.67±8.44C	2.17±0.37B	19.15±1.84CD	22.59±3.62B	2.40±0.33A	-24.65 ± 0.54A	5.44 ± 0.29B
IM20	5.04±0.07A	14.00±3.11A	2.61±0.55A	5.35±0.06A	141.20±8.68A	6.77±3.64A	34.87±2.13A	24.59±2.15B	2.90±0.61A	-25.70 ± 0.13B	6.09 ± 0.28AB

处理Item	cbbL			nifH
处理Item	香农指数 Shannon index	均匀度指数 Evenness index	辛普森指数 Simpson index	香农指数 Shannon index	均匀度指数 Evenness index	辛普森指数 Simpson index
0~20 cm
CK	1.73±0.19a	0.62±0.08a	0.22±0.03c	1.97±0.09a	0.81±0.01abc	0.18±0.01b
IM6	1.28±0.18a	0.62±0.08a	0.39±0.07ab	2.16±0.14a	0.91±0.02a	0.12±0.02b
IM10	0.83±0.03b	0.54±0.05a	0.51±0.03a	1.57±0.29b	0.71±0.11c	0.32±0.12a
IM15	1.16±0.24ab	0.59±0.08a	0.42±0.09ab	1.80±0.06ab	0.76±0.01bc	0.22±0.01ab
IM20	1.40±0.20a	0.72±0.07a	0.33±0.10bc	2.12±0.31a	0.86±0.06ab	0.14±0.05b
20~40 cm
CK	1.59±0.15AB	0.68±0.01A	0.26±0.03B	1.90±0.13A	0.80±0.05A	0.19±0.03A
IM6	1.43±0.03B	0.69±0.02A	0.28±0.02B	2.06±0.22A	0.86±0.04A	0.15±0.04A
IM10	1.01±0.14C	0.52±0.09B	0.49±0.09A	2.00±0.12A	0.85±0.03A	0.15±0.02A
IM15	1.47±0.10B	0.76±0.01A	0.27±0.04B	2.06±0.02A	0.84±0.02A	0.16±0.01A
IM20	1.76±0.06A	0.75±0.01A	0.21±0.03B	2.10±0.14A	0.87±0.04A	0.14±0.03A

土层深度Soil depth	9.95^**	2.36	11.61^**	2.39	4.07	5.54^*
经营时间Intensive management years	22.31^***	4.51^**	18.33^***	3.73^*	4.90^**	5.01^**
土层深度Soil depth× 经营时间Intensive management years	2.53	1.12	2.66	2.68	3.76	4.46^*

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