抗虫转基因水稻及其杂交水稻对土壤微生物群落多样性与组成的影响

宋亚娜; 陈在杰; 林艳; 胡太蛟; 吴明基; 王锋

doi:10.12357/cjea.20230267

抗虫转基因水稻及其杂交水稻对土壤微生物群落多样性与组成的影响

doi: 10.12357/cjea.20230267

福建省农业科学院生物技术研究所/福建省农业遗传工程重点实验室　福州　350003

基金项目: 福建省公益类科研院所专项(2021R1027002)、福建省农业高质量发展超越“5511”协同创新工程项目(XTCXGC2021002)和福建省科技重大专项(2020NZ08017)资助

详细信息

作者简介:
宋亚娜, 主要研究方向为微生物分子生态。E-mail: syana@sina.com

通讯作者:
王锋, 主要研究方向为作物遗传育种。E-mail: wf@fjage.org

中图分类号: S154.
计量
- 文章访问数: 73
- HTML全文浏览量: 50
- PDF下载量: 11
- 被引次数: 0
出版历程
- 收稿日期: 2023-05-15
- 录用日期: 2023-08-21
- 修回日期: 2023-10-13
- 网络出版日期: 2023-10-16

Effect of insect-resistant transgenic rice and its hybrid combination rice on diversity and composition of soil microbial community

Institute of Biological Technology, Fujian Academy of Agricultural Sciences/Fujian Provincial Key Laboratory of Genetic Engineering for Agriculture, Fuzhou 350003, China

Funds: This study was supported by Fujian Provincial Public Welfare Research Institute Special Project (2021R1027002), The ‘5511’ Collaborative Innovation Project for High-quality Development and Surpasses of Agriculture between Government of Fujian Province and Chinese Academy of Agricultural Sciences (XTCXGC2021002), and Fujian Province Science and Technology Major Project (2020NZ08017).

More Information

Corresponding author: E-mail: wf@fjage.org

摘要

摘要: 微生物是土壤物质循环与肥力演变的驱动者, 其群落组成关系到土壤微生态系统的稳定与可持续性。对抗虫转基因水稻土壤微生物群落变化的研究是其环境安全性评价的重要内容。本研究基于细菌16S rRNA基因和真菌ITS基因的高通量测序, 分析了田间试验中抗虫转基因水稻‘MFB’及其转基因杂交水稻‘闽丰A/MFB’ ‘天丰A/MFB’和‘谷丰A/MFB’与非转基因常规水稻‘闽恢3301’及杂交水稻‘天优华占’的土壤微生物群落多样性与组成的差异, 并得出以下结果。首先, 与非转基因常规水稻‘闽恢3301’或杂交水稻‘天优华占’相比, 抗虫转基因水稻‘MFB’及转基因杂交水稻‘闽丰A/MFB’ ‘天丰A/MFB’和‘谷丰A/MFB’均能显著增产(P<0.05)。同时, 高通量测序结果表明, 除水稻成熟期的土壤真菌群落外, 与‘闽恢3301’相比 ‘MFB’的土壤细菌或真菌群落的α-多样性指数Chao1、Observed_species和Shannon均有所提高, 且分别在水稻成熟期或分蘖期达到显著性水平(P<0.05); 水稻齐穗期时转基因杂交水稻‘闽丰A/MFB’ ‘天丰A/MFB’和‘谷丰A/MFB’的土壤细菌及真菌群落的多样性指数Shannon均介于‘MFB’与‘天优华占’之间; 微生物群落β-多样性分析结果表明, 本田间试验中不同品种水稻土壤细菌或真菌的群落组成均没有显著差异。但与‘闽恢3301’相比, 稻田土壤细菌中丰度最高的变形菌门(Proteobacteria)的相对丰度在‘MFB’土壤中明显增加, 且在水稻分蘖期及成熟期时达到显著性水平(P<0.05), 而土壤真菌中丰度最高的子囊菌门(Ascomycota)的相对丰度在‘MFB’土壤中明显减少, 且在水稻分蘖期及齐穗期时差异显著(P<0.05); 水稻齐穗期时, ‘闽丰A/MFB’ ‘天丰A/MFB’和‘谷丰A/MFB’的土壤变形菌门或子囊菌门的相对丰度也均介于‘MFB’与‘天优华占’之间。此外, 通过对微生物群落的功能组成预测可见, 随水稻生长, ‘MFB’与‘闽恢3301’的土壤细菌群落功能组成间差异存在增大的趋势。综上所述, 本研究田间试验中, 抗虫转基因水稻及其转基因杂交水稻在增产的同时提高了稻田土壤细菌或真菌群落的多样性, 改变了主要细菌或真菌种类的相对丰度, 但对细菌或真菌的群落及功能组成的影响不显著。
- 抗虫转基因水稻 /
- 细菌群落 /
- 真菌群落 /
- 高通量测序
Abstract: Microorganisms are the drivers of soil material cycle and fertility evolution, and their community composition is related to the stability and sustainability of soil microecosystems. The study of soil microbial community changes in insect-resistant transgenic rice is an important part of its environmental safety assessment. Based on high-throughput sequencing of bacterial 16S rRNA gene and fungal ITS gene, this study analyzed the differences in diversity and composition of microbial communities in paddy soils of field experiment between with insect-resistant transgenic rice ‘MFB’, insect-resistant transgenic hybrid rice ‘Minfeng A/MFB’ ‘Tianfeng A/MFB’ or ‘Gufeng A/MFB’ and with non-transgenic conventional rice ‘Minhui 3301’ or hybrid rice ‘Tianyouhuazhan’. The results showed, firstly, compared with non-transgenic conventional rice ‘Minhui 3301’ or hybrid rice ‘Tianyouhuazhan’, both insect-resistant transgenic rice ‘MFB’ and transgenic hybrid rice ‘Minfeng A/MFB’ ‘Tianfeng A/MFB’ or ‘Gufeng A/MFB’ could significantly increase rice yield (P<0.05). At the same time, except for the soil fungal communities during the rice maturation stage, the result of high-throughput sequencing showed that the α-diversity index of Chao1, Observed_species and Shannon of bacterial or fungal communities in paddy soil with ‘MFB’ were all higher than those of with ‘Minhui 3301’, and the most significant in rice maturation stage or tillering stage respectively (P<0.05). At the heading stage of rice, the Shannon index of bacterial or fungal communities in paddy soils with the insect-resistant transgenic hybrid rice ‘Minfeng A/MFB’ ‘Tianfeng A/MFB’ or ‘Gufeng A/MFB’ were between those of with ‘MFB’ and ‘Tianyouhuazhan’. The results of β-diversity analysis of bacterial or fungal communities showed there were no significant differences in the composition of microbial communities in paddy soils with different varieties of rice in this field experiment. However, compared with ‘Minhui 3301’, the relative abundance of Proteobacteria with the highest abundance of bacteria increased in the paddy soil with ‘MFB’, and reached the significance level at the tillering and maturation stages of rice (P<0.05), while the relative abundance of Ascomycota with the highest abundance of fungi decreased in the paddy soil with ‘MFB’, and reached the significance level at the tillering and heading stages of rice (P<0.05). At the heading stage of rice, the relative abundance of Proteobacteria or Ascomycota in paddy soils with ‘Minfeng A/MFB’ ‘Tianfeng A/MFB’ or ‘Gufeng A/MFB’ were between those of with ‘MFB’ and ‘Tianyouhuazhan’. According to the functional prediction of microbial communities, the differences in functional composition of bacterial communities in paddy soil between with ‘MFB’ and ‘Minhui 3301’ gradually increased along with the rice growth. In summary, in the field experiment of this study, insect-resistant transgenic rice and its transgenic hybrid rice increased the diversity of soil bacterial or fungal communities, changed the relative abundance of major species of bacteria or fungi with increasing rice yield, but did not have significant effects on the community and functional composition of bacteria or fungi.
- Insect-resistant transgenic rice /
- Bacterial community /
- Fungal community /
- High throughput sequencing

HTML全文

图 1 水稻不同生育期稻田土壤细菌群落β-多样性的主坐标分析

A: ‘闽丰A/MFB’; B: ‘天丰A/MFB’; C: ‘谷丰A/MFB’; D: ‘天优华占’; E: ‘MFB’; F: ‘闽恢3301’。A: ‘Minfeng A/MFB’; B: ‘Tianfeng A/MFB’; C: ‘Gufeng A/MFB’; D: ‘Tianyouhuazhan’; E: ‘MFB’; F: ‘Minhui 3301’.

Figure 1. Principal co-ordinates analysis for beta diversity of bacterial communities in paddy soil at different growth stages of rice

下载: 全尺寸图片幻灯片

图 2 水稻不同生育期稻田土壤真菌群落β-多样性的主坐标分析

Figure 2. Principal co-ordinates analysis for beta diversity of fungal communities in paddy soil at different growth stages of rice

下载: 全尺寸图片幻灯片

图 3 水稻不同生育期稻田土壤主要细菌门的相对丰度

不同小写字母表示相同菌门不同处理在P<0.05 水平差异显著。Different lowercase letters mean significant differences among different treatments of the same bacterial phylum at P<0.05 level .

Figure 3. Relative abundance of main bacterial phylum in paddy soil at different growth stages of rice

下载: 全尺寸图片幻灯片

图 4 水稻不同生育期稻田土壤主要真菌门的相对丰度

不同小写字母表示相同菌门不同处理在P<0.05 水平差异显著。

Figure 4. Relative abundance of main fungal phylum in paddy soil at different growth stages of rice

Different lowercase letters mean significant differences among different treatments of the same fungal phylum at P<0.05 level.

下载: 全尺寸图片幻灯片

图 5 水稻不同生育期稻田土壤细菌群落的物种组成聚类热图

Figure 5. Cluster heat map of bacterial communities in paddy soil at different growth stages of rice

下载: 全尺寸图片幻灯片

图 6 水稻不同生育期稻田土壤真菌群落的物种组成聚类热图

Figure 6. Cluster heat map of fungal communities in paddy soil at different growth stages of rice

下载: 全尺寸图片幻灯片

图 7 水稻不同生育期稻田土壤细菌群落功能单元主坐标分析

Figure 7. Principal co-ordinates analysis for functional unit of bacterial communities in paddy soil under different growth stages of rice

下载: 全尺寸图片幻灯片

图 8 水稻不同生育期稻田土壤真菌群落功能单元主坐标分析

Figure 8. Principal co-ordinates analysis for functional unit of fungal communities in paddy soil under different growth stages of rice

下载: 全尺寸图片幻灯片

表 1 不同品种水稻的产量性状

Table 1. Yield characteristics of different rice varieties

水稻品种 Rice variety	有效穗数 Effective panicle number	结实率 Setting rate (%)	千粒重 1000-grain weight (g)	单株产量 Yield per plant (g∙plant⁻¹)
‘闽丰A/MFB’ ‘Minfeng A/MFB’	11.8±1.2ab	71.7±5.4a	30.7±0.5a	57.9±6.2a
‘天丰A/MFB’ ‘Tianfeng A/MFB’	12.2±1.0a	64.6±1.9b	31.8±0.7a	55.7±5.1a
‘谷丰A/MFB’ ‘Gufeng A/MFB’	9.9±1.2b	62.4±5.2bc	33.7±1.6a	44.8±6.1b
‘天优华占’ ‘Tianyouhuazhan’	11.4±2.2ab	45.9±3.6d	33.4±3.9a	32.7±10.1cd
‘MFB’	11.9±1.1a	58.1±3.0c	30.6±1.9a	41.4±8.2bc
‘闽恢3301’ ‘Minhui 3301’	12.8±2.0a	51.6±3.2d	30.9±4.8a	27.6±6.6d
同列不同小写字母表示同一指标在不同品种间差异显著(P<0.05)。Lowercase letters in the same column refer to significant difference of the same indicator for different rice varieties (P<0.05).

下载: 导出CSV

表 2 水稻不同生育期稻田土壤细菌群落的α-多样性指数

Table 2. Alpha diversity index of bacterial communities in paddy soil under different growth stages of rice

生育期 Growth stage	水稻品种 Rice variety	丰富度指数 Richness index		多样性指数 Diversity index		均匀度指数 Pielou_e
生育期 Growth stage	水稻品种 Rice variety	Chao1	Observed_species	香农多样性指数 Shannon	辛普森多样性指数 Simpson	均匀度指数 Pielou_e
分蘖期 Tillering stage	‘闽丰A/MFB’ ‘Minfeng A/MFB’	5842±815a	5310±495ab	11.20±0.13ab	0.9987±0.0001c	0.9054±0.0022b
	‘天丰A/MFB’ ‘Tianfeng A/MFB’	5552±201a	4929±99b	11.10±0.01b	0.9990±0.0000b	0.9047±0.0011b
	‘谷丰A/MFB’ ‘Gufeng A/MFB’	5718±288a	5116±140ab	11.21±0.03ab	0.9991±0.0000a	0.9097±0.0015a
	‘天优华占’ ‘Tianyouhuazhan’	5753±326a	4970±186b	11.19±0.05ab	0.9991±0.0000a	0.9112±0.0002a
	‘MFB’	6286±214a	5501±134a	11.30±0.03a	0.9991±0.0000a	0.9096±0.0010a
	‘闽恢3301’ ‘Minhui3301’	5731±502a	4937±342b	11.10±0.11b	0.9990±0.0001b	0.9047±0.0020b
齐穗期 Heading stage	‘闽丰A/MFB’ ‘Minfeng A/MFB’	6481±133a	6131±116ab	11.04±0.03a	0.9982±0.0001a	0.8777±0.0029b
	‘天丰A/MFB’ ‘Tianfeng A/MFB’	6280±211a	5796±178ab	10.76±0.01b	0.9960±0.0001c	0.8611±0.0024c
	‘谷丰A/MFB’ ‘Gufeng A/MFB’	6450±240a	6124±180ab	10.76±0.04b	0.9961±0.0002c	0.8550±0.0018d
	‘天优华占’ ‘Tianyouhuazhan’	5971±169a	5692±197b	10.68±0.12b	0.9959±0.0006c	0.8563±0.0060cd
	‘MFB’	6492±295a	6221±215a	11.06±0.04a	0.9972±0.0001b	0.8773±0.0022b
	‘闽恢3301’ ‘Minhui3301’	6012±621a	5684±491b	11.03±0.07a	0.9981±0.0001a	0.8847±0.0034a
成熟期 Maturation stage	‘闽丰A/MFB’ ‘Minfeng A/MFB’	5051±357c	4879±295c	10.87±0.09c	0.9980±0.0002b	0.8876±0.0019b
	‘天丰A/MFB’ ‘Tianfeng A/MFB’	5120±20c	4980±40c	11.00±0.04b	0.9985±0.0001a	0.8960±0.0025a
	‘谷丰A/MFB’ ‘Gufeng A/MFB’	4730±130c	4551±119c	10.80±0.05c	0.9980±0.0001b	0.8888±0.0013b
	‘天优华占’ ‘Tianyouhuazhan’	5157±478c	4897±352c	10.99±0.08b	0.9984±0.0001a	0.8969±0.0011a
	‘MFB’	6646±720a	6240±459a	11.23±0.07a	0.9983±0.0000a	0.8910±0.0020b
	‘闽恢3301’ ‘Minhui3301’	5923±97b	5620±52b	11.05±0.04b	0.9981±0.0001b	0.8875±0.0029b
同列不同小写字母表示同一指标在不同品种间差异显著(P<0.05)。Different lowercase letters in the same column mean significant difference of the same indicator for different rice varieties (P<0.05).

下载: 导出CSV

表 3 水稻不同生育期稻田土壤真群落的α-多样性指数

Table 3. Alpha diversity index of fungal communities in paddy soil under different growth stages of rice

生育期 Growth stage	水稻品种 Rice variety	丰富度指数 Chao1	丰富度指数 Observed_species	香农多样性指数 Shannon	辛普森多样性指数 Simpson	均匀度指数 Pielou_e
分蘖期 Tillering stage	‘闽丰A/MFB’ ‘Minfeng A/MFB’	254±2a	254±3a	5.94±0.12b	0.9605±0.0043b	0.7437±0.0136c
	‘天丰A/MFB’ ‘Tianfeng A/MFB’	178±6c	178±5c	6.03±0.06ab	0.9725±0.0035ab	0.8070±0.0073a
	‘谷丰A/MFB’ ‘Gufeng A/MFB’	245±28a	245±28a	6.26±0.30ab	0.9740±0.0082a	0.7894±0.0215ab
	‘天优华占’ ‘Tianyouhuazhan’	223±3b	222±3b	6.33±0.12a	0.9751±0.0032a	0.8116±0.0172a
	‘MFB’	194±7c	193±7c	6.21±0.22ab	0.9776±0.0047a	0.8173±0.0241a
	‘闽恢3301’ ‘Minhui 3301’	155±7d	154±6d	5.50±0.30c	0.9527±0.0136b	0.7569±0.0365bc
齐穗期 Heading stage	‘闽丰A/MFB’ ‘Minfeng A/MFB’	654±48c	653±47c	6.19±0.48bc	0.9544±0.0271b	0.6618±0.0448bc
	‘天丰A/MFB’ ‘Tianfeng A/MFB’	787±20b	783±22b	6.34±0.12b	0.9484±0.0037bc	0.6599±0.0097c
	‘谷丰A/MFB’ ‘Gufeng A/MFB’	784±48b	775±45b	6.35±0.07b	0.9553±0.0024b	0.6617±0.0097bc
	‘天优华占’ ‘Tianyouhuazhan’	696±44c	690±41c	5.91±0.10c	0.9341±0.0012c	0.6267±0.0052c
	‘MFB’	919±56a	906±56a	7.18±0.26a	0.9832±0.0038a	0.7310±0.0212a
	‘闽恢3301’ ‘Minhui 3301’	852±13ab	840±16ab	6.79±0.13a	0.9758±0.0037a	0.6992±0.0124ab
成熟期 Maturation stage	‘闽丰A/MFB’ ‘Minfeng A/MFB’	948±44ab	936±43ab	7.24±0.0ab	0.9825±0.0008a	0.7335±0.0046a
	‘天丰A/MFB’ ‘Tianfeng A/MFB’	797±20c	796±18c	7.11±0.06b	0.9811±0.0009a	0.7376±0.0074a
	‘谷丰A/MFB’ ‘Gufeng A/MFB’	972±70ab	954±65ab	7.24±0.15ab	0.9807±0.0048a	0.7316±0.0225a
	‘天优华占’ ‘Tianyouhuazhan’	1038±54a	1013±54a	7.29±0.08a	0.9796±0.0038a	0.7304±0.0131a
	‘MFB’	884±102b	872±91b	7.27±0.09ab	0.9837±0.0005a	0.7442±0.0056a
	‘闽恢3301’ ‘Minhui 3301’	943±107ab	922±97ab	7.33±0.14a	0.9832±0.0011a	0.7443±0.0043a
同一生长时期中同列不同小写字母表示同一指标在同一生长时期不同品种间差异显著(P<0.05)。Different lowercase letters in the same column at the same growth stage mean significant difference of the same indicator at the same growth stage for different rice varieties (P<0.05).

下载: 导出CSV

参考文献(30)

[1]	国际农业生物技术应用服务组织. 2019年全球生物技术/转基因作物商业化发展态势[J]. 中国生物工程杂志, 2021, 41(1): 114−119 International Service for the Acquisition of Agri-biotech Applications. Global commercialization of biotechnology/transgenic crops in 2019[J]. China Biotechnology, 2021, 41(1): 114−119
[2]	BAUDOIN E, BENIZRI E, GUCKERT A. Impact of artificial root exudates on the bacterial community structure in bulk soil and maize rhizosphere[J]. Soil Biology and Biochemistry, 2003, 35(9): 1183−1192 doi: 10.1016/S0038-0717(03)00179-2
[3]	AIRA M, GÓMEZ-BRANDÓN M, LAZCANO C, et al. Plant genotype strongly modifies the structure and growth of maize rhizosphere microbial communities[J]. Soil Biology and Biochemistry, 2010, 42(12): 2276−2281 doi: 10.1016/j.soilbio.2010.08.029
[4]	BERG G, SMALLA K. Plant species and soil type cooperatively shape the structure and function of microbial communities in the rhizosphere[J]. FEMS Microbiology Ecology, 2009, 68(1): 1−13 doi: 10.1111/j.1574-6941.2009.00654.x
[5]	INCEOĞLU O, SALLES J F, VAN OVERBEEK L, et al. Effects of plant genotype and growth stage on the betaproteobacterial communities associated with different potato cultivars in two fields[J]. Applied and Environmental Microbiology, 2010, 76(11): 3675−3684 doi: 10.1128/AEM.00040-10
[6]	LU G H, ZHU Y L, KONG L R, et al. Impact of a glyphosate-tolerant soybean line on the rhizobacteria, revealed by illumina MiSeq[J]. Journal of Microbiology and Biotechnology, 2017, 27(3): 561−572 doi: 10.4014/jmb.1609.09008
[7]	杨永华. 转基因作物对土壤微生物群落的影响及主要研究策略[J]. 农业生物技术学报, 2011, 19(1): 1−8 doi: 10.3969/j.issn.1674-7968.2011.01.001 YANG Y H. Advances on the effects of genetically modified crops on soil microbial community and main countermeasures of their approaches[J]. Journal of Agricultural Biotechnology, 2011, 19(1): 1−8 doi: 10.3969/j.issn.1674-7968.2011.01.001
[8]	JAMES C. 2011. Global Status of Commercialized Biotech/GM Crops: 2011[M]. ISAAA: Ithaca, NY.
[9]	DONEGAN K K, PALM C J, FIELAND V J, et al. Changes in levels, species and DNA fingerprints of soil microorganisms associated with cotton expressing the Bacillus thuringiensis var. kurstaki endotoxin[J]. Applied Soil Ecology, 1995, 2(2): 111−124 doi: 10.1016/0929-1393(94)00043-7
[10]	CASTALDINI M, TURRINI A, SBRANA C, et al. Impact of Bt corn on rhizospheric and soil eubacterial communities and on beneficial mycorrhizal symbiosis in experimental microcosms[J]. Applied and Environmental Microbiology, 2005, 71(11): 6719−6729 doi: 10.1128/AEM.71.11.6719-6729.2005
[11]	WU W X, YE Q F, MIN H, et al. Bt-transgenic rice straw affects the culturable microbiota and dehydrogenase and phosphatase activities in a flooded paddy soil[J]. Soil Biology and Biochemistry, 2004, 36(2): 289−295 doi: 10.1016/j.soilbio.2003.09.014
[12]	LU H H, WU W X, CHEN Y X, et al. Decomposition of Bt transgenic rice residues and response of soil microbial community in rapeseed-rice cropping system[J]. Plant and Soil, 2010, 336(1): 279−290
[13]	SONG Y N, SU J, CHEN R, et al. Diversity of microbial community in a paddy soil with cry1Ac/cpti transgenic rice[J]. Pedosphere, 2014, 24(3): 349−358 doi: 10.1016/S1002-0160(14)60021-7
[14]	楼骏, 柳勇, 李延. 高通量测序技术在土壤微生物多样性研究中的研究进展[J]. 中国农学通报, 2014, 30(15): 256−260 doi: 10.11924/j.issn.1000-6850.2013-2513 LOU J, LIU Y, LI Y. Review of high-throughput sequencing techniques in studies of soil microbial diversity[J]. Chinese Agricultural Science Bulletin, 2014, 30(15): 256−260 doi: 10.11924/j.issn.1000-6850.2013-2513
[15]	郑燕, 贾仲君. 新一代高通量测序与稳定性同位素示踪DNA/RNA技术研究稻田红壤甲烷氧化的微生物过程[J]. 微生物学报, 2013, 53(2): 173−184 ZHENG Y, JIA Z J. Next generation sequencing and stable isotope probing of active microorganisms responsible for aerobic methane oxidation in red paddy soils[J]. Acta Microbiologica Sinica, 2013, 53(2): 173−184
[16]	陈庆荣, 王成己, 陈曦, 等. 施用烟秆生物黑炭对红壤性稻田根际土壤微生物的影响[J]. 福建农业学报, 2016, 31(2): 184−188 CHEN Q R, WANG C J, CHEN X, et al. Effect of tobacco stalk-derived biochar on microbes in rhizosphere soil at red paddy fields[J]. Fujian Journal of Agricultural Sciences, 2016, 31(2): 184−188
[17]	张芳, 林绍艳, 徐颖洁. 水稻连作对江苏地区稻田土细菌微生物多样性的影响[J]. 山东农业大学学报(自然科学版), 2014, 45(2): 161−165 ZHANG F, LIN S Y, XU Y J. The effect of continuous cropping rice on diversity of soil bacteria microbial in Jiangsu Province[J]. Journal of Shandong Agricultural University (Natural Science Edition), 2014, 45(2): 161−165
[18]	SONG Y N, SU J, WU M J, et al. Effect of Hvsusiba2 transgenic rice on soil bacterial community and functional gene in paddy field in Fujian Province China[J]. Journal of Agricultural and Crop Research, 2021, 9(5): 112−120
[19]	CAPORASO J G, BITTINGER K, BUSHMAN F D, et al. PyNAST: a flexible tool for aligning sequences to a template alignment[J]. Bioinformatics, 2010, 26(2): 266−267 doi: 10.1093/bioinformatics/btp636
[20]	LOZUPONE C, KNIGHT R. UniFrac: a new phylogenetic method for comparing microbial communities[J]. Applied and Environmental Microbiology, 2005, 71(12): 8228−8235 doi: 10.1128/AEM.71.12.8228-8235.2005
[21]	单贞. 异源表达Hvsusiba2籼稻“明恢86”稻田甲烷减排研究[D]. 福州: 福建农林大学, 2017 SHAN Z. Study on mitigating methane in paddy fields of Indica rice “Minghui86” with heterologous expression of Hvsusiba2[D]. Fuzhou: Fujian Agriculture and Forestry University, 2017
[22]	FLORES S, SAXENA D, STOTZKY G. Transgenic Bt plants decompose less in soil than non-Bt plants[J]. Soil Biology and Biochemistry, 2005, 37(6): 1073−1082 doi: 10.1016/j.soilbio.2004.11.006
[23]	POERSCHMANN J, GATHMANN A, AUGUSTIN J, et al. Molecular composition of leaves and stems of genetically modified Bt and near-isogenic non-Bt maize—Characterization of lignin patterns[J]. Journal of Environmental Quality, 2005, 34(5): 1508−1518 doi: 10.2134/jeq2005.0070
[24]	POERSCHMANN J, RAUSCHEN S, LANGER U, et al. Molecular level lignin patterns of genetically modified Bt-maize MON88017 and three conventional varieties using tetramethylammonium hydroxide (TMAH)-induced thermochemolysis[J]. Journal of Agricultural and Food Chemistry, 2008, 56(24): 11906−11913 doi: 10.1021/jf8023694
[25]	POERSCHMANN J, RAUSCHEN S, LANGER U, et al. Fatty acid patterns of genetically modified Cry3Bb1 expressing Bt-maize MON88017 and its near-isogenic line[J]. Journal of Agricultural and Food Chemistry, 2009, 57(1): 127−132 doi: 10.1021/jf803009u
[26]	曾千春, 周开达, 朱祯, 等. 中国水稻杂种优势利用现状[J]. 中国水稻科学, 2000, 14(4): 243−246 doi: 10.3321/j.issn:1001-7216.2000.04.012 ZENG Q C, ZHOU K D, ZHU Z, et al. Current status in the use of hybrid rice heterosis in China[J]. Chinese Journal of Rice Science, 2000, 14(4): 243−246 doi: 10.3321/j.issn:1001-7216.2000.04.012
[27]	BERENDSEN R L, PIETERSE C M J, BAKKER P A H M. The rhizosphere microbiome and plant health[J]. Trends in Plant Science, 2012, 17(8): 478−486 doi: 10.1016/j.tplants.2012.04.001
[28]	BULGARELLI D, SCHLAEPPI K, SPAEPEN S, et al. Structure and functions of the bacterial microbiota of plants[J]. Annual Review of Plant Biology, 2013, 64: 807−838 doi: 10.1146/annurev-arplant-050312-120106
[29]	MASOERO F, MOSCHINI M, ROSSI F, et al. Nutritive value - mycotoxin contamination and in vitro rumen fermentation of normal and genetically modified corn (cry1A(b)) grown in Northern Italy[J]. Maydica, 1999, 44: 205−209
[30]	SONG Y N, CHEN Z J, WU M J, et al. Changes in bacterial community and abundance of functional genes in paddy soil with cry1Ab transgenic rice[J]. Journal of Integrative Agriculture, 2021, 20(6): 1674−1686 doi: 10.1016/S2095-3119(20)63271-3