Effect of Straw Returning Years to Field after Deep Turning Back on Soil Bacterial Community in Continuous Cropping Corn Field in the West Liaohe Plain

doi:10.7668/hbnxb.20193953

Abstract

Abstract:

To explore the influence of straw returning years to the field after deep turning back on soil bacterial community in continuous cropping corn fields in the West Liaohe Plain,and provide theoretical guidance for continuous straw returning to improve soil fertility.This study takes corn straw leaving the field as a control (CK),based on the high-throughput sequencing technology of bacterial 16S rDNA V3-V4 region,combined with bioinformatics,we analyzed the characteristics of organic matter,nitrogen nutrients content,soil bacterial community structure and diversity changes in 0-20 cm and 20-40 cm soil layers of corn fields with continuous straw returning for 2(SR2),5(SR5) and 10 a (SR10).The results showed that SR2 had no significant difference with CK in soil organic matter and nitrogen nutrients content,while SR5 and SR10 significantly increased soil organic matter and nitrogen nutrient content;under different straw returning years,soil bacterial diversity was different and each had its own unique OTU,among which SR10 OTU had the largest number;alpha diversity index showed that the relative abundance and diversity of soil bacterial community were not significantly different between SR2 and CK,SR5 and SR10 increased significantly,and SR10 and CK had the largest difference;a total of 51 bacterial groups were obtained at the phyla level,including Actinobacteriota,Proteobacteria,Acidobacteriota,Crenarchaeota and Chloroflexi,whose relative abundance was more than 5%.The relative abundance of Proteobacteria,Acidobacteriota and Chloroflexi increased with the increase of returning years.RDA clustering analysis showed that the soil bacterial community structure of 0-20 cm soil layer SR2 was similar to CK,SR5 was more similar to SR10,20-40 cm soil layer,different straw returning years,treatments were different from CK,SR2 and SR5 were similar,SR10 had significant differences in community structure compared to SR5 and SR2.The contents of soil $NO 3 -$ -N, $NH 4 +$ -N,OM,and TN all had effects on bacterial flora,and they were soil $NO 3 -$ -N> $NH 4 +$ -N>OM>TN.The contents of soil organic matter and nitrogen nutrient had no significant difference between continuous straw returning for 2 a and CK,while continuous straw returning for 5 and 10 a were significantly increased.In summary,the microbial diversity and richness of bacteria showed minimal changes in the soil layers of 0-20 cm and 20-40 cm after continuous straws returning for 2 a.After continuous straws returning for 5 and 10 a,both soil layers significantly increased;the bacterial community structure continuous straw returning for 2 a was similar to CK in the 0-20 cm soil layer,while the bacterial community structure continuous straw returning for 2,5,10 a were changed in the 20-40 cm soil layer.

Key words: West Liaohe Plain, Straw returning years, Soil bacteria, Bacterial community, Bacterial diversity

HAN Meiqi, ZHANG Yuqin, YANG Hengshan, TAI Jicheng, WU Zhiyu, Sarula, FAN Xiuyan, MENG Fanhao, WANG Miao, LI Xiaona. Effect of Straw Returning Years to Field after Deep Turning Back on Soil Bacterial Community in Continuous Cropping Corn Field in the West Liaohe Plain[J]. Acta Agriculturae Boreali-Sinica, 2023, 38(5): 148-157. doi: 10.7668/hbnxb.20193953.

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Figures/Tables 10

Tab.1 Soil nutrient content of 0-20 cm soil layer in the test site

处理 Treatment	有机质/(g/kg) Organic matter	全氮/(g/kg) Total nitrogen	速效氮/(mg/kg) Available nitrogen	速效磷/(mg/kg) Available phosphorus	速效钾/(mg/kg) Available potassium
SR10	24.31	1.27	54.38	21.17	89.80
SR5	22.57	1.21	51.84	16.85	81.25
SR2	20.19	1.13	45.32	5.79	68.92
CK	19.86	1.08	42.71	4.32	61.79

Tab.2 Marks of different soil depth for different straw returning years

还田年限/a Years of straw returning	土层深度/cm Soil depth
还田年限/a Years of straw returning	0~20	20~40
10	SR10_1	SR10_2
5	SR5_1	SR5_2
2	SR2_1	SR2_2
0	CK_1	CK_2

Tab.3 Soil nutrient content under different straw returning years

土层/cm Soil layer	样品名称 Sample ID	有机质/ (g/kg) OM	有机碳/ (g/kg) SOC	全氮/ (g/kg) TN	速效氮/ (mg/kg) AN	铵态氮/ (mg/kg) N $H 4 +$ -N	硝态氮/ (mg/kg) N $O 3 -$ -N
0~20	SR10_1	25.61±0.72a	14.85±0.42a	1.32±0.03a	60.14±1.07a	5.32±0.13a	30.06±1.85a
	SR5_1	23.28±1.12b	13.50±0.65b	1.28±0.04a	58.67±2.99a	5.08±0.21a	28.40±0.33a
	SR2_1	21.39±0.53c	12.41±0.31c	1.18±0.03b	49.37±2.27b	3.85±0.18b	20.97±1.32b
	CK_1	20.20±0.44c	11.72±0.26c	1.13±0.02b	46.84±2.39b	3.61±0.16b	19.29±0.49b
20~40	SR10_2	23.25±1.67a	13.49±0.97a	1.21±0.01a	40.18±2.05a	3.94±0.28a	16.14±0.61a
	SR5_2	21.42±0.25ab	12.42±0.14ab	1.16±0.02ab	39.82±2.03a	3.64±0.04a	14.05±1.00b
	SR2_2	19.59±0.89bc	11.36±0.52bc	1.12±0.03bc	35.15±1.51b	3.46±0.44ab	10.75±0.76c
	CK_2	17.68±0.94c	10.26±0.54c	1.04±0.08c	33.36±1.04b	2.98±0.18b	9.85±0.60c

Tab.3 Soil nutrient content under different straw returning years

土层/cm Soil layer	样品名称 Sample ID	有机质/ (g/kg) OM	有机碳/ (g/kg) SOC	全氮/ (g/kg) TN	速效氮/ (mg/kg) AN	铵态氮/ (mg/kg) N $H 4 +$ -N	硝态氮/ (mg/kg) N $O 3 -$ -N
0~20	SR10_1	25.61±0.72a	14.85±0.42a	1.32±0.03a	60.14±1.07a	5.32±0.13a	30.06±1.85a
	SR5_1	23.28±1.12b	13.50±0.65b	1.28±0.04a	58.67±2.99a	5.08±0.21a	28.40±0.33a
	SR2_1	21.39±0.53c	12.41±0.31c	1.18±0.03b	49.37±2.27b	3.85±0.18b	20.97±1.32b
	CK_1	20.20±0.44c	11.72±0.26c	1.13±0.02b	46.84±2.39b	3.61±0.16b	19.29±0.49b
20~40	SR10_2	23.25±1.67a	13.49±0.97a	1.21±0.01a	40.18±2.05a	3.94±0.28a	16.14±0.61a
	SR5_2	21.42±0.25ab	12.42±0.14ab	1.16±0.02ab	39.82±2.03a	3.64±0.04a	14.05±1.00b
	SR2_2	19.59±0.89bc	11.36±0.52bc	1.12±0.03bc	35.15±1.51b	3.46±0.44ab	10.75±0.76c
	CK_2	17.68±0.94c	10.26±0.54c	1.04±0.08c	33.36±1.04b	2.98±0.18b	9.85±0.60c

Tab.4 Sample sequencing data processing results

土层/cm Soil layer	样品名称 Sample ID	原始序列数/条 Raw tags	优化序列数/条 Clean tags	OTUs
0~20	SR10_1	121 683	119 029	3 718
	SR5_1	72 534	70 792	3 338
	SR2_1	57 853	56 213	3 307
	CK_1	48 344	47 091	3 140
20~40	SR10_2	91 069	88 835	3 639
	SR5_2	55 978	54 921	3 623
	SR2_2	49 448	48 572	3 540
	CK_2	33 868	33 129	3 435

Fig.1 OTUs distribution of soil samples Petal diagram (A) and Venn diagram (B)

Fig.2 Shannon-Wiener index

Tab.5 Alpha diversity index

土层/cm Soil layer	样品名称 Sample ID	样品文库覆盖率 Goods_coverage	Chao1指数 Chao1 index	Shannon-Wiener 多样性指数 Shannon-Wiener index	辛普森多样性指数 Simpson index	分类OTUs数目 Observed species	谱系多样性 Phylogenetic diversity
0~20	SR10_1	0.95±0.05a	4 856.56±64.68a	9.95±0.51a	0.978±0.03a	3 718.00±49.18a	247.17±4.98a
	SR5_1	0.96±0.05a	4 622.23±123.60b	9.89±0.50a	0.970±0.01a	3 572.80±16.37b	244.19±3.36a
	SR2_1	0.96±0.05a	4 346.75±109.55c	9.82±0.05a	0.958±0.01ab	3 490.00±46.17c	229.59±3.21b
	CK_1	0.96±0.05a	4 294.98±48.84c	9.78±0.50a	0.936±0.01b	3 434.90±45.44c	224.44±12.67b
20~40	SR10_2	0.96±0.03a	4 525.33±92.20a	9.95±0.33a	0.969±0.01a	3 638.90±48.14a	220.82±22.31a
	SR5_2	0.95±0.03a	4 361.43±118.36ab	9.73±0.32a	0.958±0.01a	3 438.50±45.49a	218.27±22.05a
	SR2_2	0.96±0.03a	4 235.15±85.51bc	9.58±0.31a	0.955±0.02a	3 207.40±163.67b	210.77±21.29a
	CK_2	0.96±0.03a	4 076.77±95.77c	9.53±0.31a	0.933±0.03a	3 140.75±160.27b	208.75±21.09a

Fig.3 Horizontal taxonomic composition and distribution of soil bacteria

Fig.4 RDA results based on Phylum level The blue arrow.The species;The red arrow.Soil nutrients;The length of the arrow.The degree of impact of soil nutrients on species communities;N

O 3 -

-N.Nitrate nitrogen;N

H 4 +

-N.Ammonium nitrogen;TN.Total nitrogen;OM.Organic matter.

Fig.4 RDA results based on Phylum level The blue arrow.The species;The red arrow.Soil nutrients;The length of the arrow.The degree of impact of soil nutrients on species communities;N $O 3 -$ -N.Nitrate nitrogen;N $H 4 +$ -N.Ammonium nitrogen;TN.Total nitrogen;OM.Organic matter.

Fig.5 Bacteria UPGMA clustering histogram

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