基于16S rDNA高通量测序方法检测猪舍环境微生物群落多样性

doi:10.12160/j.issn.1672-5190.2023.06.013

摘要/Abstract

摘要： [目的]研究猪舍环境微生物群落多样性,了解不同类型猪舍环境中细菌群落的结构差异以及潜在的致病菌属。[方法]利用空气沉降法采集规模化猪场妊娠猪舍、保育猪舍、分娩猪舍的环境微生物样本,每种类型猪舍选取3栋猪舍采样,共9个样本。采用Illumina Miseq技术,以细菌16S rDNA的V3~V4变异区为对象进行高通量测序;采用QIIME2软件对测序数据进行分析,比较不同类型猪舍环境微生物群落组成。[结果]在97%相似度阈值下9个样本共得到OTU 29 126个,涵盖31门66纲160目320科899属1 831种的细菌。分娩猪舍以及保育猪舍的Chao1指数、Shannon指数及谱系多样性指数整体高于妊娠猪舍。变形菌门（Proteobacteria）、拟杆菌门（Bacteroidota）、厚壁菌门（Firmicutes）和放线菌门（Actinobacteriota）为猪舍环境的四大优势菌群;变形菌门在3个类型的猪舍中相对丰度均最高,厚壁菌门、放线菌门以及拟杆菌门相对丰度在不同类型猪舍中差异较大。不动杆菌属（Acinetobacter）、棒杆菌属（Corynebacterium）、寡养单胞菌属（Stenotrophomonas）分别是分娩猪舍、妊娠猪舍以及保育猪舍中相对丰度最高的菌属。猪舍环境空气中存在创伤球菌属（Helcococcus）、链球菌属（Streptococcus）、军团菌属（Legionella）、沙雷菌属（Serratia）等多个对动物具有潜在致病力的菌属。[结论]猪舍环境微生物群落多样性丰富,分娩猪舍以及保育猪舍在细菌种类、系统进化多样性以及丰富程度上高于妊娠猪舍。研究发现的猪舍环境中潜在动物致病菌属为猪舍环境消毒的药物选择提供了依据。

关键词: 16S rDNA高通量测序, 猪舍, 环境微生物, 群落分析, 多样性

Abstract: [Objective] This study was conducted to characterize the microbial community diversities in pig house environments, to understand the structural differences of bacterial communities in different types of pig house environments, and to identify the potentially pathogenic bacterial genera. [Method] Environmental microbial samples were collected from pregnant sow houses, nursery pig houses and farrowing houses in a large-scale pig farm using air sedimentation method. Three houses were sampled for each type of pig house, with a total of 9 samples. Using Illumina Miseq technology, the high-throughput sequencing was performed targeting on the V3-V4 variant region of bacterial 16S rDNA. The sequencing data were analyzed by QIIME2 software to compare the composition of microbial communities in different types of pig house environments. [Result] At the similarity threshold of 97%, a total of 29 126 OTUs were obtained from the 9 samples, covering 31 phyla, 66 classes, 160 orders, 320 families, 899 genera and 1 831 species of bacteria. The Chao1 index, Shannon index and phylogenetic diversity index of the farrowing houses and nursery pig houses were generally higher than those of the pregnant sow houses. Proteobacteria, Bacteroidota, Firmicutes and Actinobacteriota were the four dominant bacterial groups at the phylum level in the pig house environments. The relative abundance of Proteobacteria was the highest in all three types of pig houses, while the relative abundance of Firmicutes, Actinobacteria and Bacteroidetes varied greatly among different types of pig houses. Acinetobacter, Corynebacterium and Stenotrophomonas were the genera with the highest relative abundance in farrowing houses, pregnant sow houses and nursery pig houses, respectively. There were multiple genera of bacteria with potential pathogenicity to animals, such as Helcococcus, Streptococcus, Legionella and Serratia, in the air of pig houses. [Conclusion] The pig house environments were rich in microbial community diversities. Farrowing houses and nursery pig houses had higher bacterial diversity, evolutionary diversity and abundance than the pregnant sow houses. The potentially pathogenic bacteria found in this study provided references for the selection of disinfection drugs used in pig house environments.

Key words: 16S rDNA high-throughput sequencing, pig house, environmental microorganism, community analysis, diversity

中图分类号:

S828.46

樊梅娜, 张修, 王丽荣. 基于16S rDNA高通量测序方法检测猪舍环境微生物群落多样性[J]. 畜牧与饲料科学, 2023, 44(6): 100-107.

FAN Meina, ZHANG Xiu, WANG Lirong. Characterization of Microbial Community Diversities in Pig House Environments by 16S rDNA High-throughput Sequencing[J]. Animal Husbandry and Feed Science, 2023, 44(6): 100-107.

参考文献

[1] 刘小红,陈瑶生.2021年生猪产业发展状况、未来发展趋势与建议[J].中国畜牧杂志,2022,58(3):204-209.
[2] 胡成波. “双疫”困扰之下我国养猪业发展趋势与对策建议[J].养猪,2020(3):92-94.
[3] 廖晓君. 规模猪场生猪疫病综合防控技术:以湖南省衡东县为例[J].养殖与饲料,2020,19(8):99-103.
[4] ELLIOTT L F, MCCALLA T M, DESHAZER J A.Bacteria in the air of housed Swine units[J].Applied and Environmental Microbiology,1976,32(2):270-273.
[5] HUYBENS N, HOUEIX J, LICOIS D, et al.Pyrosequencing of epizootic rabbit enteropathy inocula and rab-bit caecal samples[J].The Veterinary Journal,2013,196(1):109-110.
[6] HIGHLANDER S K.High throughput sequencing methods for microbiome profiling: Application to food animal systems[J].Animal Health Research Reviews,2012,13(1):40-53.
[7] POŁKA J, REBECCHI A, PISACANE V, et al. Bacterial diversity in typical Italian salami at different ripening stages as revealed by high-throughput sequencing of 16S rRNA amplicons[J].Food Microbiology,2015,46:342-356.
[8] 刘洋. 奶牛舍空气微生物菌群组成及对乳中微生物影响的研究[D].哈尔滨:东北农业大学,2016.
[9] MOTOS G A,BARBETA E,BOBI J,et al. Novel swine ARDS model induced by Pseudomonas aeruginosa pneumonia and VILI[EB/OL].(2020-09-01)[2023-08-24].https://erj.ersjournals.com/content/56/suppl_64/2755.
[10] 田秋丰,张红,尹珺伊,等.1株奶牛源约翰逊不动杆菌的分离鉴定[J].畜牧兽医学报,2022,53(1):324-328.
[11] 邓阳,姜竹鸣,张玉琴.寡养单胞菌属细菌的研究进展[J].生物资源,2021,43(1):1-9.
[12] XU E, YANG H, REN M M, et al.Identification of enterotype and its effects on intestinal butyrate production in pigs[J].Animals,2021,11(3):730.
[13] 孙健,孙先枝,安朋朋,等.上海地区奶牛乳房炎致病菌基因诊断结果分析[J].中国奶牛,2018(2):28-31.
[14] SUN Y, MEN M Q, XU B S, et al.Assessing key microbial communities determining nitrogen transformation in composting of cow manure using illumina high-throughput sequencing[J].Waste Management,2019,92:59-67.
[15] FORD A, PALINSKI R, LUBBERS B, et al.Placentitis and abortion in domestic pigs (Sus scrofa domesticus) associated with Trueperella abortisuis on US swine farms[J].Journal of Swine Health and Production, 2022, 30(2):95-100.
[16] 李润成,杨宇,汤起武.努比亚山羊巴氏杆菌羊创伤球菌混合感染的诊治[J].中国兽医杂志,2016,52(2):48-49.
[17] 王晓华. 猪链球菌病的防治[J].中国畜禽种业,2019,15(2):110.
[18] 史晓红,冀涛,王芳芳,等.肺部感染患者军团菌属感染的调查[J].中华医院感染学杂志,2011,21(4):679-681.
[19] WANG N, CHEN X M, JI Y J, et al.Enhanced sludge reduction during swine wastewater treatment by the dominant sludge-degrading strains Chryseobacterium sp. B4 and Serratia sp. H1[J].Bioresource Technology,2021,330:124983.
[20] 张玲艳,宋丽丽,贾伟娟,等.炭疽芽孢杆菌的研究进展[J].黑龙江畜牧兽医,2020(15):43-47.
[21] MORENO E, BLASCO J M, LETESSON J J, et al.Pathogenicity and its implications in taxonomy:The Brucella and Ochrobactrum case[J].Pathogens,2022,11(3):377.
[22] 胡文举,宋艳画,秦佳辰,等.产后牛子宫内菌群变化规律及致病性研究[J].湖北农业科学,2014,53(17):4115-4119.
[23] 李红梅,白林,姜冬梅,等.基于16S rDNA高通量测序方法检测猪舍空气微生物多样性[J].中国畜牧杂志,2015,51(3):81-84.
[24] 黄凯,唐倩,沈丹,等.冬季不同类型猪舍内颗粒物与微生物气溶胶浓度分布规律研究[J].农业环境科学学报,2019,38(7):1616-1623.
[25] 李卓君,陈春香,钟小菊,等.猪肠道微生物组成、影响因素及其对重要经济性状的影响研究进展[J].中国畜牧兽医,2022,49(7):2557-2566.
[26] 张鹏飞,王印,杨泽晓,等.猪源嗜麦芽寡养单胞菌的分离鉴定与生物学分析[J].中国农业大学学报,2018,23(4):45-52.
[27] 李超,郝海玉,孙玲玉,等.猪舍环境气载微生物监测[J].畜牧兽医学报,2014,45(10):1684-1692.
[28] 张永灿. 猪棒状杆菌病的防治[J].养殖与饲料,2019(8):84-85.
[29] 邱立,王兴龙,郝华芳,等.仔猪鲍曼不动杆菌的分离鉴定及生物学特性研究[J].中国预防兽医学报,2012,34(11):882-885.
[30] 孙泉云,张维谊,夏炉明,等.上海地区规模猪场环境中主要致病菌的检测[J].畜禽业,2016(10):54-55.
[31] 张怡. 以神经系统症状为首发症状的重症军团菌肺炎1例[J].中国临床研究,2021,34(11):1544-1546.
[32] 陈翔,高晓东,胡必杰,等.宏基因二代测序技术指导下的皮肤炭疽院内感染防控1例报告[J].中国临床医学,2020,27(4):575-577.
[33] DUAN H Y,CHAI T J,LIU J Z,et al.Source identification of airborne Escherichia coli of swine house surroundings using ERIC-PCR and REP-PCR[J].Environmental Research,2009,109(5):511-517.