苹小吉丁自然种群肠道微生物多样性

doi:10.11707/j.1001-7488.20220310

摘要/Abstract

摘要：

目的: 明确不同虫态、不同环境苹小吉丁自然种群肠道真菌和细菌种类组成及其可能对宿主生长发育和生理变化的影响。方法: 分别将新疆野果林(W)和栽培果园(C)获取的成虫(A)与幼虫(L)进行完整肠道解剖，利用Illumina MiSeq技术对ITS2基因(真菌)和16S rRNA V3-V4变异区(细菌)进行测定，统计肠道微生物的操作分类单元(operational taxonomic unit，OTU)数量，分析物种丰度、组成及Alpha多样性，并运用PICRUSt2对其功能进行预测。结果: 获得苹小吉丁肠道真菌ITS2优质序列177 028条，细菌16S rRNA优质序列253 712条，聚类分析分别获得285和1 470个OTUs。最终注释到真菌5门22纲50目92科122属，细菌40门103纲231目364科594属。从属级水平来看，不同虫态、不同环境苹小吉丁肠道微生物各具特有的真菌和细菌类群，其中，其中CA特有真菌11属，特有细菌2属；CL特有真菌28属，特有细菌223属；WA特有真菌37属，特有细菌47属；WL特有真菌12属，特有细菌68属，而核心菌群中真菌7属，细菌21属。多样性分析结果表明野果林苹小吉丁肠道真菌群落丰富度和物种多样性成虫均大于幼虫，细菌群落丰富度成虫小于幼虫，但物种多样性成虫却大于幼虫，同时苹小吉丁幼虫肠道微生物群落丰富度和物种多样性在栽培果园远大于野果林。此外，通过MetaCyc Pathway注释74条真菌代谢通路，426条细菌代谢通路；通过KEGG注释868条真菌代谢通路，2 188条细菌代谢通路。结论: 不同虫态、不同环境苹小吉丁肠道真菌和细菌种类与丰度均存在差异，肠道真菌种类和丰度成虫大于幼虫，而细菌幼虫大于成虫，说明真菌对于成虫的生长发育起着关键性作用，而细菌对于幼虫的生长发育起着关键性作用。此外，不同的肠道微生物结构与组成，呈现出大致相同的功能，因此推测在苹小吉丁肠道中发挥功能的为一些固定类群，这可能是与其宿主长期协同进化的结果。

关键词: 苹小吉丁, 肠道微生物, 高通量测序, 多样性, PICRUSt2功能预测

Abstract:

Objective: This study aims to clarify the composition of gut fungi and bacteria of Agrilus mali in natural population in different developmental stages and different environmental conditions, and infer the possible effects on growth, development and physiological changes of the hosts. Method: The intact intestines of the adult (A) and larva (L) of Agrilus mali collected from wild fruit forest (W) and cultivated orchard (C) were dissected. The ITS2 sequence (fungi) and V3-V4 variant region (bacteria) of 16S rRNA were determined by Illumina MiSeq technology. The number of operating taxonomic units (OTU) of gut symbiotic microorganisms was counted, the species abundance, composition and alpha diversity were analyzed, and PICRUSt2 was used to predict function of OTUs. Result: A total of 177 028 ITS2 sequences of intestinal fungi and 253 712 16S rRNA high-quality sequences of bacteria were obtained from the gut microorganisms of A. mali. After cluster analysis, 285 (fungi) and 1 470 (bacteria) OTUs were obtained, respectively. For fungi, 5 phyla, 22 classes, 50 orders, 92 families, and 122 genera were identified; and for bacteria, totally 40 phyla, 103 classes, 231 orders, 364 families, and 594 genera were identified. There were 11 unique genera of fungi in CA, 28 in CL, 37 in WA, 12 in WL, and there were 2 unique genera of bacteria in CA, 223 in CL, 47 in WA, 68 in WL. A total of 7 genera of fungal communities and 21 genera of bacterial communities were determined as the core taxa. In addition, for intestinal fungal community, both the species diversity and richness of adults were greater than those of larvae, however for the bacterial community, species diversity in adults was greater than that in larvae, but the richness in the former was lower than in the later. Also, both the species diversity and richness of gut microorganism community of the larvae were much greater in cultivated than those in wild. Furthermore, a total of 74 fungal metabolic pathways and 426 bacterial metabolic pathways were annotated through MetaCyc Pathway. A total of 868 fungal metabolic pathways and 2 188 bacterial metabolic pathways were annotated through KEGG. Conclusion: There are differences in species and abundance of gut fungi and bacteria communities of A. mali at different developmental stages and in different environments. The species diversity and abundance of gut fungi in adults are greater than those in larvae. However, the intestinal bacteria in adults have lower abundance than that in larvae, suggesting that fungi play a significant role during developing process of adults while bacteria play a significant role during developing process of larvae. Additionally, although the species and abundance of intestinal microorganisms are quite difference, their functions are almost the same, indicating that a fixed group or symbiotic bacteria play a role in the gut of A. mali, which may be the result of long-term co-evolution between A. mali and its host.

Key words: Agrilus mali, gut microorganisms, high throughput sequencing, diversity, PICRUSt2 function prediction

中图分类号:

S718.7

贾斐然,周忠福,赵文霞,孙荟荃,姚艳霞. 苹小吉丁自然种群肠道微生物多样性[J]. 林业科学, 2022, 58(3): 86-96.

Feiran Jia,Zhongfu Zhou,Wenxia Zhao,Huiquan Sun,Yanxia Yao. Diversity of Gut Microorganisms in Natural Population of Agrilus mali (Coleoptera: Buprestidae)[J]. Scientia Silvae Sinicae, 2022, 58(3): 86-96.

图/表 10

表1

表2

图1

表3

图2

图3

表4

不同寄主不同虫态苹小吉丁肠道内COG预测功能类别占比"

类别 Category	描述 Description	样本 Sample(%)
类别 Category	描述 Description	CA	CL	WA	WL
M	细胞壁/膜/膜生物发生 Cell wall/membrane/envelope biogenesis	8.08	21.43	31.98	38.50
H	辅酶转运与代谢 Coenzyme transport and metabolism	6.43	19.99	40.60	32.97
A	RNA加工与修饰 RNA processing and modification	11.54	27.90	4.91	55.65
Q	次生代谢物生物合成、运输和分解代谢 Secondary metabolites biosynthesis, transport and catabolism	6.62	20.34	32.38	40.66
G	碳水化合物运输和代谢 Carbohydrate transport and metabolism	11.41	19.47	26.22	42.89
V	防御机制 Defense mechanisms	6.22	21.68	36.71	35.39
T	信号转导机制 Signal transduction mechanisms	7.02	20.56	41.78	30.65
D	细胞周期控制，细胞分裂，染色体分割 Cell cycle control, cell division, chromosome partitioning	8.78	22.97	33.78	34.47
Z	细胞骨架 Cytoskeleton	0.07	16.52	17.65	65.76
B	染色质结构与动力学 Chromatin structure and dynamics	0.08	21.26	57.19	21.47
K	转录 Transcription	9.13	22.34	25.14	43.39
N	细胞运动 Cell motility	11.51	27.56	24.76	36.17
C	能源生产和转换 Energy production and conversion	6.95	22.64	34.08	36.33
F	核苷酸转运与代谢 Nucleotide transport and metabolism	7.08	20.78	35.40	36.75
L	复制、重组和修复 Replication, recombination and repair	7.57	22.15	34.12	36.16
J	翻译、核糖体结构与生物发生 Translation, ribosomal structure and biogenesis	6.78	22.61	37.28	33.32
O	翻译后修饰、蛋白质周转、伴侣 Posttranslational modification, protein turnover, chaperones	6.64	20.33	39.57	33.46
S	功能未知 Function unknown	8.16	19.36	33.31	39.17
W	细胞外结构 Extracellular structures	0.00	9.89	22.46	67.65
P	无机离子转运与代谢 Inorganic ion transport and metabolism	8.83	18.98	31.41	40.77
E	氨基酸转运与代谢 Amino acid transport and metabolism	7.90	20.67	30.04	41.38
I	脂质转运与代谢 Lipid transport and metabolism	6.70	24.99	30.09	38.22
U	细胞内运输、分泌和囊泡运输 Intracellular trafficking, secretion, and vesicular transport	7.26	24.23	31.11	37.40

表4

图4

图5

图6

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地点 Site	样品类型 Sample type	编号 Code	经纬度 Latitude and longitude	海拔 Altitude/m	温度 Temperature/℃
综合农场 Zonghe Farm	成虫 Adult	CA	43.39°N, 82.04°E	816	14~26
综合农场 Zonghe Farm	幼虫 Larva	CL	43.39°N, 82.04°E	816
库尔德宁 Kuerdening	成虫 Adult	WA	43.15°N, 82.49°E	1 190
库尔德宁 Kuerdening	幼虫 Larva	WL	43.15°N, 82.49°E	1 190

类群 Groups	样本编号 Sample code	多样性指数 Diversity indices
类群 Groups	样本编号 Sample code	Shannon	Simpson	Ace	Chao	Coverage
真菌 Fungi	CA	1.20	0.47	41.67	42.00	0.999 9
	CL	3.26	0.07	70.00	70.00	1.000 0
	WA	3.18	0.09	98.00	98.00	1.000 0
	WL	2.89	0.15	53.25	53.00	0.998 8
细菌 Bacteria	CA	0.80	0.49	37.23	24.25	0.998 7
	CL	3.47	0.16	894.64	717.56	0.962 5
	WA	3.57	0.08	278.88	273.77	0.994 5
	WL	2.46	0.24	397.08	373.73	0.980 8

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