施用贝壳粉对酸化土壤微生物多样性及平邑甜茶幼苗生长的影响

doi:10.11707/j.1001-7488.20200917

摘要/Abstract

摘要：

目的: 以苹果砧木平邑甜茶幼苗为材料，研究酸化土壤中加入贝壳粉土壤调理剂的改良效果。方法: 挖取果园酸化土壤（pH值为5.45），与调理剂混匀后采用盆栽方式栽植长势一致的平邑甜茶幼苗，3个调理剂处理分别为大粒（DLB）、中粒（ZLB）、小粒（XLB）贝壳粉，分别测定土壤pH值、幼苗株高、叶片叶绿素相对含量（SPAD）。处理6个月后，在距平邑甜茶幼苗5 cm处采集土样，提取基因组DNA扩增建立文库，检测土壤细菌16S rRNA基因V3+V4区域和真菌ITS1+ITS2区域的丰富度、多样性及群落结构。结果: 3种贝壳粉调理剂处理能将土壤pH值显著提高到6.5~7.2，比初始pH值提高19.26%~28.44%。DLB、ZLB处理均能显著提高幼苗株高和SPAD值。通过高通量测序，获得736 515个有效细菌序列数和782 991个有效真菌序列数，有效序列比例均大于72%。3个处理与对照的共有细菌和真菌OTU数分别为1 914个和446个。由各处理群落丰富度指数（Ace指数和Chao指数）和多样性指数（Simpson指数和Shannon指数）分析可知，调理剂处理均能显著提高土壤细菌群落的丰富度和多样性，其中，ZLB处理的效果最显著，其Ace、Chao和Shannon指数分别提高53.84%、49.85%和14.21%，Simpson指数降低54.76%。3种贝壳粉处理对真菌群落的丰富度无显著影响，但均能降低真菌群落的多样性，其中DLB的处理效果最显著，其Shannon指数降低44.02%，Simpson指数与CK相比提高11.5倍。由Beta多样性分析可知，在酸化土壤中加入3种贝壳粉调理剂后，土壤微生物发生显著变化。由菌群相对丰度组成分析可知，在科分类水平上，3种贝壳粉处理均显著提高细菌中劣势菌群ABS-19科和黄色单胞菌科以及真菌中劣势菌群毛壳菌科、小囊菌科、毛球壳科、粪盘菌科丰度，显著降低细菌中优势菌群酸杆菌科和Solibacteraceae科以及真菌中优势菌群丛赤壳科、被孢霉科、假球壳科、枝孢霉科丰度。结论: 施用3种粒径的贝壳粉土壤调理剂，均可提高酸化土壤pH值，改善平邑甜茶长势，改变酸化土壤中科分类水平细菌的丰富度、多样性及真菌的多样性。贝壳粉作为绿色生物调理剂具有极大的应用潜力。

关键词: 贝壳粉, 酸化土壤, 高通量测序, 细菌, 真菌

Abstract:

Objective: This paper aims to study the improvement effect of adding shell powder soil conditioner in acidified soil with Malus hupehensis var. mengshanensis seedlings as material. Method: The orchard acidified soil (pH value is 5.45) was dug out and mixed with conditioner,which was applied to potted M. hupehensis var. mengshanensis seedlings. The three conditioner treatments were:large grain shell powder (DLB),medium grain shell powder (ZLB) and small particle shell powder (XLB),and the pH value of soil,plant height and relative chlorophyll content were measured. After 6 months of treatment,soil samples were collected 5 cm away from the seedlings. Genomic DNA was extracted and amplified to establish a library. The abundance,diversity and community structure of soil bacterial 16S rRNA gene V3+V4 region and fungi ITS1 + ITS2 region were detected. Result: The three kinds of shell powder conditioner were able to significantly improve the soil pH value to 6.5-7.2,which was 19.26% to 28.44% higher than the initial pH value. Both DLB and ZLB treatments could significantly increase plant height and relative chlorophyll content in leaves. According to the results of high throughput sequencing,a total of 736 515 effective bacterial tags and 782 991 effective fungal tags were obtained from 12 soil samples. The proportion of effective sequences was more than 72%. There were 1914 bacterial OTU and 446 fungal OTU in the three treatment groups and the control group. According to the analysis of community abundance index (Ace index and Chao index) and diversity index (Simpson index and Shannon index),three kinds of shell powder treatments significantly improved the abundance and diversity of soil bacterial community. Among them,ZLB treatment had the most significant effect. Ace,Chao and Shannon index increased by 53.84%,49.85% and 14.21%,respectively. Simpson index decreased by 54.76%. Three kinds of shell powder treatments had no significant effect on the abundance of fungal communities,but all of them reduced the diversity of fungal communities. Among them,DLB treatment had the most significant effect,with Shannon index reduced by 44.02%,Simpson index increased by 11.5 times compared with CK treatment. According to the analysis of Beta diversity of each treatment community,the soil microorganisms changed significantly after adding three kinds of shell powder to acidified soil. According to the analysis of the relative abundance composition of flora,at the level of family classification,all three kinds of shell powder treatments significantly increased the abundance of inferior bacteria (ABS-19 and Xanthomonadales),also increased the abundance of inferior fungi (Chaetomiaceae,Microascaceae,Lasiosphaeriaceae,and Ascobolaceae). All three kinds of shell powder treatments significantly decreased the abundance of dominant bacteria of Acidobacteriaceae and Solibacteraceae,and decreased the abundance of dominant fungi of Nectriaceae,Mortierellaceae,Pleosporaceae,and Cladosporiaceae. Conclusion: The application of three kinds of shell powder soil conditioners can increase the soil pH value and improve the growth of M. hupehensis var. mengshanensis,also change the abundance and diversity of bacteria and the diversity of fungi in acidified soils. As a new type of green biological conditioner,shell powder has great application potential.

Key words: shell powder, acidified soil, high throughput sequencing, soil bacteria, soil fungi

中图分类号:

赵晓红,柴姗姗,张曼曼,范义昌,毛云飞,毛志泉,沈向. 施用贝壳粉对酸化土壤微生物多样性及平邑甜茶幼苗生长的影响[J]. 林业科学, 2020, 56(9): 153-163.

Xiaohong Zhao,Shanshan Chai,Manman Zhang,Yichang Fan,Yunfei Mao,Zhiquan Mao,Xiang Shen. Effects of Shell Powder on Microbial Diversity in Acidified Soil and Growth of Malus hupehensis var. mengshanensis Seedlings[J]. Scientia Silvae Sinicae, 2020, 56(9): 153-163.

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土壤调理剂 Shell powder conditioners	成分1 Ingredient 1	成分2 Ingredient 2	各成分体积比 Ingredients volume proportion	命名 Name
贝壳粉处理1 Large grain shell	大粒贝壳粉 Large grain shell powder	有机肥 Organic fertilizer	1:1	DLB
贝壳粉处理2 Medium grain shell	中粒贝壳粉 Medium grain shell powder	有机肥 Organic fertilizer	1:1	ZLB
贝壳粉处理3 Small grain shell	小粒贝壳粉 Small grain shell powder	有机肥 Organic fertilizer	1:1	XLB
对照 Control	河沙 Sand	有机肥 Organic fertilizer	1:1	CK

贝壳粉调理剂 Shell powder conditioners	细菌Bacteria			真菌Fungi
贝壳粉调理剂 Shell powder conditioners	原始序列数量 Total tag	有效序列数量 Effective tag	有效序列比例 Effective (%)	原始序列数量 Total tag	有效序列数量 Effective tag	有效序列比例 Effective (%)
DLB	64 913	57 604	72.04	68 323	66 897	83.65
	68 665	61 295	76.51	68 167	66 600	83.51
	68 306	61 356	76.61	68 933	67 481	84.02
ZLB	68 932	61 935	77.26	68 675	67 058	84.09
	68 594	61 647	77.07	67 106	65 497	81.89
	68 065	61 029	76.19	68 260	66 732	83.59
XLB	68 153	60 824	75.90	68 450	66 881	83.53
	69 024	61 101	76.17	69 053	67 548	84.01
	68 516	61 697	77.18	69 028	67 454	84.43
CK	68 597	62 178	77.78	51 749	50 616	82.69
	69 280	63 310	79.35	66 648	65 125	81.49
	68 766	62 539	78.38	66 654	65 102	81.45
总和Total	819 811	736 515	76.70	801 046	782 991	83.20

贝壳粉调理剂 Shell powder conditioners	细菌Bacteria				真菌Fungi
贝壳粉调理剂 Shell powder conditioners	Ace	Chao	Simpson	Shannon	Ace	Chao	Simpson	Shannon
DLB	1 837.98±16a	1 865.08±12a	0.0047±0.0b	6.39 ± 0.09a	380.20±13a	386.52±14a	0.25±0.04a	2.53±0.19 b
ZLB	1 873.62±15a	1 897.72±18a	0.0038±0.0b	6.51±0.08a	413.32±21a	419.61±21a	0.25±0.09a	2.81±0.52 b
XLB	1 833.93±9a	1 866.52 ±13a	0.0044±0.0b	6.40 ±0.06 a	419.63±7a	422.03±6a	0.15±0.07ab	3.23±0.38 b
CK	1 217.92±175b	1 266.29±185b	0.0084±0.0a	5.70±0.14 b	414.82±16a	414.07±14a	0.02±0.00b	4.52±0.06 a

分类水平 Classification level	细菌Bacteria				分类水平 Classification level	真菌Fungi
分类水平 Classification level	CK	DLB	XLB	ZLB	分类水平 Classification level	CK	DLB	XLB	ZLB
鞘脂单胞菌科 Sphingomonadaceae	5.75	6.41	6.02	5.82	毛壳菌科 Chaetomiaceae	3.69	47.61	41.37	49.35
ABS-19科 ABS-19 family	0.32	5.17	5.27	5.50	小囊菌科 Microascaceae	1.64	12.40	5.03	9.31
酸杆菌科 Acidobacteriaceae	13.11	0.16	0.15	0.20	粪盘菌科 Ascobolaceae	0.01	3.15	6.77	7.93
亚硝化单胞菌科 Nitrosomonadaceae	3.22	3.24	3.79	3.17	毛球壳科 Lasiosphaeriaceae	0.85	5.81	6.35	4.32
黄色单胞菌科 Xanthomonadales_ Sedis_Incertae	0.94	4.02	4.09	3.65	丛赤壳科 Nectriaceae	5.60	1.85	2.96	1.74
厌氧绳菌科 Anaerolineaceae	0.32	3.58	4.85	3.56	肉座菌科 Cordycipitaceae	0.18	6.05	3.73	0.37
Solibacteraceae	6.30	1.86	1.95	1.80	Piskurozymaceae	2.75	3.50	1.82	1.37
芽单胞菌科 Gemmatimonadaceae	0.65	3.96	2.77	3.37	被孢霉科 Mortierellaceae	4.39	1.97	0.82	1.02
噬纤维菌科 Cytophagaceae	0.32	2.88	3.41	3.21	假球壳科 Pleosporaceae	4.33	0.07	0.26	0.12
泉发菌科 Chitinophagaceae	2.33	1.81	1.86	1.70	枝孢霉科 Cladosporiaceae	3.64	0.10	0.52	0.11

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