青藏高原4类典型水化学特征湖泊的细菌多样性差异及影响因素

doi:10.17520/biods.2021420

生物多样性 ›› 2022, Vol. 30 ›› Issue (4): 21420. DOI: 10.17520/biods.2021420

所属专题：青藏高原生物多样性与生态安全

• 研究报告: 微生物多样性 • 上一篇下一篇

青藏高原4类典型水化学特征湖泊的细菌多样性差异及影响因素

沈国平¹, 韩睿², 缪增强¹, 邢江娃¹, 李永臻¹, 王嵘¹, 朱德锐¹^,^*()

1.青海大学医学院基础医学研究中心, 西宁 810016
2.青海大学农林科学院青海省蔬菜遗传与生理重点实验室, 西宁 810016

收稿日期:2021-10-22 接受日期:2022-02-18 出版日期:2022-04-20 发布日期:2022-03-13
通讯作者: 朱德锐
作者简介:*E-mail: zhuderui2005@126.com
基金资助:
国家自然科学基金(31860030);青海省基础应用研究计划(2020-ZJ-767)

Bacterial diversity differences and influence factors of four types of hydrochemical characteristic lakes in the Qinghai-Tibet Plateau

Guoping Shen¹, Rui Han², Zengqiang Miao¹, Jiangwa Xing¹, Yongzhen Li¹, Rong Wang¹, Derui Zhu¹^,^*()

1 Research Center for Basic Medical Science, Medical College, Qinghai University, Xining 810016
2 Qinghai Provincial Key Laboratory of Vegetable Genetics and Physiology, Academy of Agriculture and Forestry Sciences, Qinghai University, Xining 810016

Received:2021-10-22 Accepted:2022-02-18 Online:2022-04-20 Published:2022-03-13
Contact: Derui Zhu

摘要/Abstract

摘要：

青藏高原分布着我国最密集的极端环境湖泊群, 湖泊类型和水化学特征多样, 而不同类型湖泊的细菌群落组成与多样性差异的系统研究相对较少。本文以青藏高原4类典型水化学特征湖泊(即氯化物型、MgSO₄亚型、Na₂SO₄亚型、碳酸盐型)为研究对象, 借助Illumina测序16S rRNA基因(V₃‒V₄区)分析细菌多样性、群落组成差异及其优势属与环境因素的制约关系。结果表明: MgSO₄亚型与氯化物型湖泊多属于超盐环境, 而大多数Na₂SO₄亚型与碳酸盐型湖泊属于咸水、微咸水或淡水环境。4类湖泊获得分类地位明确的细菌共计45门81纲1,148属(52,031个OTUs), 细菌Shannon指数为碳酸盐型(5.27 ± 0.57) > Na₂SO₄亚型(4.96 ± 0.51) > 氯化物型(4.12 ± 0.80) > MgSO₄亚型(3.64 ± 1.04)。优势细菌门是变形菌门、厚壁菌门和拟杆菌门。变形菌门的相对多度总体较高, 优势纲是γ-、α-和β-变形菌纲; 厚壁菌门多分布于MgSO₄亚型和氯化物型湖泊, 优势纲是芽孢杆菌纲; 拟杆菌门主要分布于碳酸盐型和Na₂SO₄亚型湖泊, 优势纲是黄杆菌纲。全部氯化物型和少数MgSO₄亚型湖泊的细菌组成相似, 优势属是假单胞菌属(Pseudomonas)、乳球菌属(Lactococcus)和不动杆菌属(Acinetobacter), 其聚集分布与总盐度、主要离子(Mg²⁺、Cl^-、Na⁺与K⁺)和温度相关; MgSO₄亚型湖泊独有的常见属是芽孢杆菌属(Bacillus)、气单胞菌属(Aeromonas)、大洋芽孢杆菌属(Oceanobacillus)等, 其聚集分布与SO₄^2-浓度正相关; Na₂SO₄亚型与碳酸盐型湖泊的细菌组成相似, 优势属是水弯曲菌属(Aquiflexum)、海仙菌属(Haliea)与苍黄杆菌属(Luteolibacter), 其聚集分布与HCO₃^-浓度、pH值和海拔高度呈显著正相关。与世界上其他湖泊组/群相比, 青藏高原湖泊具有独特的细菌优势属和常见属, 不同类型湖泊的细菌群落组成存在显著差异, 可能与水化学类型或地理位置有关。

关键词: 青藏高原, 高原湖泊, 细菌, 生物多样性, 水化学特征

Abstract

Aim: Extreme environmental lakes are most densely distributed in the Qinghai-Tibet Plateau (QTP) in China, and the lake types and the hydrochemical characteristics are diverse. However, little is known about the bacterial community composition and diversity of these lakes in the QTP.

Methods: This study was carried out in four hydrochemical types of lakes on the QTP (e.g. chloride type, MgSO₄ subtype, Na₂SO₄ subtype, and carbonate type). Illumina 16S rRNA gene (V₃‒V₄ region) sequencing was used to analyze the bacterial diversity, community composition, and the associations between dominant taxa and environmental factors in the QTP.

Results: The hydrochemical characteristics indicated that two lake groups of MgSO₄ subtype and chloride type belonged to extremely hypersaline environment, while most samples of Na₂SO₄ subtype and carbonate type groups belonged to mesosaline, brackish or fresh water environments. A total of 45 phyla, 81 classes, and 1,148 genera (52,031 OTUs) of bacteria were investigated. The Shannon diversity index of bacteria was carbonate type (5.27 ± 0.57) > Na₂SO₄ subtype (4.96 ± 0.51) > chloride type (4.12 ± 0.80) > MgSO₄ subtype (3.64 ± 1.04). The dominant phyla within the bacterial communities were Proteobacteria, Bacteroidetes, and Firmicutes. The relative abundance of Proteobacteria was high, and the dominant classes were γ-, α- and β-Proteobacteria. Firmicutes mainly distributed in the MgSO₄ subtype and chloride-type lakes, and the dominant class was Bacilli. Bacteroidetes mainly distributed in the carbonate type and Na₂SO₄ subtype lakes, and the dominant class was Flavobacteriia. The bacterial community composition of chloride type lakes was similar to a few samples of MgSO₄ subtype lakes, and the distribution of the dominant genera (Pseudomonas, Lactococcus, and Acinetobacter) positively correlated with the total salinity, main ion (Mg²⁺, Cl^-, Na⁺ and K⁺), and temperature. Among the MgSO₄ subtype lakes, the distribution of the uniquely common genera Bacillus, Aeromonas, and Oceanobacilluspositively correlated with the concentration of SO₄^2-. The bacterial community composition of the Na₂SO₄ subtype lakes was similar to the carbonate type lakes, while the distribution of some dominant genera, e.g. Aquiflexum, Haliea and Luteolibacter, significantly and positively correlated with the environment variables, including HCO₃^-content, altitude, and pH value.

Conclusion: Compared with other lake groups in the world, lakes in the QTP have unique dominant and common bacterial genera. Bacterial community composition varies in different lake types, which may be related to hydrochemical type or geographical location.

Key words: Qinghai-Tibet Plateau, plateau lake, bacteria, biodiversity, hydrochemical characteristic

沈国平, 韩睿, 缪增强, 邢江娃, 李永臻, 王嵘, 朱德锐 (2022) 青藏高原4类典型水化学特征湖泊的细菌多样性差异及影响因素. 生物多样性, 30, 21420. DOI: 10.17520/biods.2021420.

Guoping Shen, Rui Han, Zengqiang Miao, Jiangwa Xing, Yongzhen Li, Rong Wang, Derui Zhu (2022) Bacterial diversity differences and influence factors of four types of hydrochemical characteristic lakes in the Qinghai-Tibet Plateau. Biodiversity Science, 30, 21420. DOI: 10.17520/biods.2021420.

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链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2021420

https://www.biodiversity-science.net/CN/Y2022/V30/I4/21420

图/表 5

图1 4类典型水化学特征湖泊组的细菌门水平群落组成。CHLO: 氯化物型组; MGSO: MgSO4亚型组; NASO: Na2SO4亚型组; NACO: Na2CO3/NaHCO3型组。

Fig. 1 Community composition of bacteria at phylum level in four typically hydrochemical characteristic lake groups. CHLO, Chloride type group; MGSO, MgSO4 subtype group; NASO, Na2SO4 subtype group; NACO, Na2CO3/NaHCO3 type group.

图2 4类典型水化学特征湖泊的细菌纲水平群落组成。CHLO: 氯化物型组; MGSO: MgSO4亚型组; NASO: Na2SO4亚型组; NACO: Na2CO3/NaHCO3型组。

Fig. 2 Community composition of bacteria at class level in four typically hydrochemical characteristic lake groups. CHLO, Chloride type group; MGSO, MgSO4 subtype group; NASO, Na2SO4 subtype group; NACO, Na2CO3/NaHCO3 type group.

图3 4类典型水化学特征湖泊组的细菌属水平群落组成。CHLO: 氯化物型组; MGSO: MgSO4亚型组; NASO: Na2SO4亚型组; NACO: Na2CO3/NaHCO3型组。

Fig. 3 Community composition of bacteria at genus level in four typically hydrochemical characteristic lake groups. CHLO, Chloride type group; MGSO, MgSO4 subtype group; NASO, Na2SO4 subtype group; NACO, Na2CO3/NaHCO3 type group.

图4 环境因子与样本、优势细菌属的相关性RDA分析。空心圆圈(○)、加号(+)和箭头(↑)分别表示样本、优势细菌属和环境因子; Hs: 霍布逊盐场; Hl: 霍布逊湖; Qs: 察尔汗盐场; Ql: 察尔汗湖; Ks: 昆特依盐场; Bl: 巴伦马海湖; Ns: 牛郎织女湖盐场; Db: (东)达布逊湖; Dt: 东台吉乃尔湖; Zm: (德)宗马海湖; My: 茫崖翡翠湖; C: 茶卡盐湖; K: 柯柯盐湖; D: 大柴旦盐湖; X: 小柴旦盐湖; Q: 青海湖; Pk: 佩枯措; Cc: 措戳龙; Dw: 达瓦措; Zr: 扎日南木措; Ga: 尕海; Ha: 哈拉湖; Xl: 希里沟湖; Zb: 扎布耶湖; B: 巴木措; Mq: 麦穷措; Dz: 达则措; Gz: 公珠措; Cn: 错纳措; Al: 昂拉仁措; S: 色林措; Dr: 当惹雍措。

Fig. 4 Redundancy analysis (RDA) of dominant bacterial genera, samples and environment factors. The hollow circles (○), plus signs (+) and arrows (↑) were shown for different samples, bacterial dominant genus and environmental factors, respectively. Hs, Hulsan Saltern; Hl, Hulsan Lake; Ql, Qarhan Lake; Qs, Qarhan Saltern; Ks, Kunteyi Saltern; Bl, Baluan Mahai Lake; Ns, Niulang Zhinü Saltern; Db, Dabsan Lake; Dt, Dong Taijnar Lake; Zm, Dezongmahai Lake; My, Mangnai Lake; C, Caka Lake; K, Keke Lake; D, Da Qaidam Lake; X, Xiao Qaidam Lake; Pk, Peikü Co; Cc, Cocholong Lake; Dw, Dawa Co; Zr, Zhari Nam Co; Ga, Gahai Lake; Xl, Xiligou Lake; Q, Qinghai Lake; Ha, Hala Lake; Zb, Zabuye Lake; B, Bam Co; Mq, Mêrqung Co; Dz, Dagzê Co; Gz, Gongzhu Co; Cn, Chani Co; Al, Ngangla Ring Co; S, Siling Co; Dr, DangraYum Co.

图5 非度量多维尺度(NMDS)分析样本的相似性分布

Fig. 5 Non-metric multi-dimensional scaling (NMDS) analysis of the similarity distribution of samples

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青藏高原4类典型水化学特征湖泊的细菌多样性差异及影响因素

Bacterial diversity differences and influence factors of four types of hydrochemical characteristic lakes in the Qinghai-Tibet Plateau

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