北极斯瓦尔巴群岛冰川流域可培养细菌的系统发育多样性及固氮菌初步研究

doi:10.13679/j.jdyj.2017.4.496

极地研究 ›› 2017, Vol. 29 ›› Issue (4): 496-505.DOI: 10.13679/j.jdyj.2017.4.496

北极斯瓦尔巴群岛冰川流域可培养细菌的系统发育多样性及固氮菌初步研究

刘杰¹ 李胜男¹ 郭昱东¹ 张丹丹¹ 王能飞²

1. 青岛科技大学, 海洋科学与生物工程学院, 山东青岛 266042;
2. 国家海洋局第一海洋研究所, 山东青岛 266061

收稿日期:2016-05-10 修回日期:2016-11-17 出版日期:2017-12-30 发布日期:2017-12-30
通讯作者: 王能飞
基金资助:
南北极环境综合考察与评估专项(CHINARE-2015-02-01)、中央级公益性科研院所基本科研业务专项(2015T04)和山东省重点研发计划(2015GSF115004)资助

Preliminary Study on Phylogenetic Diversity of Culturable Bacteria and Nitrogen-fixing Bacteria in Svalbard Glaciers of Arctic

Liu Jie¹, Li Shengnan¹, Guo Yudong¹, Zhang Dandan¹, Wang Nengfei²

Received:2016-05-10 Revised:2016-11-17 Online:2017-12-30 Published:2017-12-30

摘要/Abstract

摘要：

从北极斯瓦尔巴群岛冰川流域的上、中、下游采集了5种代表性土壤和冰川融水样品(MT、AT、TN、BT、MS), 采用常规LB和严格无氮培养基低温培养方法, 对其中的可培养细菌和潜在固氮细菌进行了总菌计数以及菌株的富集、分离与纯化。经菌落菌体形态观察、16S rRNA基因初步测序排重、固氮基因nifH的PCR检测, 分别选取48株可培养分离细菌和31株潜在固氮菌进行了基于16S rRNA基因全序列测定的系统发育分析。目的是初步了解该特殊生境中可培养细菌(包括潜在固氮菌)的多样性及其分布状况, 为进一步研究它们在此生境中的生态功能奠定基础。实验结果表明, 可培养细菌在5个采集样品中的总菌数为BT>TN> AT>MT=MS, 严格无氮培养基分离菌总菌数为BT > AT > MT > TN > MS。48株可培养代表菌分属于Proteobacteria、Actinobacteria、Bacteroidetes、Firmicutes 4个门的7纲、14属之中, 它们在5个样品中的多样性程度为BT(6纲、6属)> MT(4纲、6属)> AT、MS(均为3纲、3属)> TN(2纲、3属), 优势菌群主要分布在γ-proteobacteria纲的Pseudomonas属(20.8%, 集中在AT、BT、MS样品中)和β-proteobacteria纲的Janthinobacterium属(35.4%, 集中在MS样品中), 表现出一定程度的系统发育多样性。潜在固氮菌实验结果表明, 能在严格无氮培养基上生长且可检测到nifH的31株代表菌具有极为单一的系统发育多样性。其中90.32%菌株集中在
γ-proteobacteria纲的Pseudomonas属, 仅在MT和MS样品中有3株菌分布在α-proteobacteria纲的Rhizobium属、β-proteobacteria纲的Janthinobacterium属和Actinobacteria纲的Arthrobacter属, 它们与分离自其他极端环境的相关标准菌株具有高度16S rRNA基因同源性。另外, 本实验还发现有8株菌的16S rRNA基因序列与相关标准菌株的相似度低于98.50%, 推测它们具有成为该特殊生境下新种的潜质。

关键词: 北极, 斯瓦尔巴冰川流域, 可培养细菌, 潜在固氮菌, 系统发育多样性, 分布状况

Abstract:

Five different samples of representative soil and meltwater (MT, AT, TN, BT, MS) were collected from the upstream, midstream and downstream of the Arctic Svalbard glaciers. The culturable bacteria and potential nitrogen-fixing bacteria were counted, enriched and isolated by using LB medium and strict nitrogen-free medium at the low temperature, respectively. After colony observation, preliminary 16S rRNA gene sequencing and nifH -PCR, 48 culturable bacterial strains and 31 potential nitrogen-fixing bacterial strains were selected to examine the phylogenetic diversity based on the almost full-length 16S rRNA gene sequences. The purpose was to obtain a preliminary understanding of the diversity and distribution of these bacteria in this special area, and to provide a basis for further research on their ecological functions. The results showed that the populations of the culturable bacteria in the five samples were ordered as BT > TN > AT > MT=MS. The populations of potential nitrogen-fixing bacteria were ordered as BT > AT > MT > TN > MS. Forty-eight culturable bacteria belonged to 4 phyla (Proteobacteria, Actinobacteria, Bacteroidetes, Firmicutes), 7 classes and 14 genera, and their degrees of diversity were ordered as BT(6 classes, 6 genera)> MT(4 classes, 6 genera)> AT=MS(3 classes, 3 genera)> TN(2 classes, 3 genera). Meanwhile, the majority of culturable bacterial isolates were composed of Pseudomonas of γ-proteobacteria (20.8%, isolated from the AT, BT and MS samples) and Janthinobacterium of β-proteobacteria(35.4%, isolated from the MS sample). The experimental results of the potential nitrogen-fixing bacteria showed that the diversity of 31 strains isolated from the five samples was very low. Of the strains, 90.32% belonged mainly to Pseudomonas(γ- proteobacteria), only 3 strains isolated from the MT and MS samples belonged to Rhizobium (α-proteo¬bacteria), Janthinobacterium (β-proteobacteria) and Arthrobacter (Actinobacteria C), respectively. There was high 16S rRNA gene homology among these potential nitrogen-fixing strains and some related standard-type strains isolated from other extreme environment. In addition, eight strains that showed less than 98.6% 16S rRNA gene-sequence similarity with strains of related type may represent potential novel species in this special ecological environment.

Key words: Arctic, Svalbard glaciers, culturable bacteria, potential nitrogen-fixing bacteria, phylogenetic diversity, distribution

刘杰李胜男郭昱东张丹丹王能飞. 北极斯瓦尔巴群岛冰川流域可培养细菌的系统发育多样性及固氮菌初步研究[J]. 极地研究, 2017, 29(4): 496-505.

Liu Jie, Li Shengnan, Guo Yudong, Zhang Dandan, Wang Nengfei. Preliminary Study on Phylogenetic Diversity of Culturable Bacteria and Nitrogen-fixing Bacteria in Svalbard Glaciers of Arctic[J]. , 2017, 29(4): 496-505.

[1]	胡海涵张智伦李新情惠凤鸣赵杰臣庄齐枫. 2000-2019年北极多年冰时空变化分析[J]. 极地研究, 2022, 34(4): 0-0.
[2]	赵立清王晓春李佳琦. CMIP6计划中我国地球气候系统模式海冰范围的模拟评价[J]. 极地研究, 2022, 34(4): 0-0.
[3]	黄睿王常颖李劲华隋毅. HY-2B、OUC与NSIDC三种海冰密集度产品在北极与东北航道区域的海冰监测能力分析[J]. 极地研究, 2022, 34(4): 0-0.
[4]	刘科侯书贵. 极地冰芯气候及环境记录指标研究现状与展望[J]. 极地研究, 2022, 34(4): 0-0.
[5]	温世强常亮. 北极水汽输送的时空分布特征研究[J]. 极地研究, 2022, 34(3): 265-277.
[6]	岳鹏陈慧文高晓艳. 面向新十年的瑞典北极战略评析[J]. 极地研究, 2022, 34(3): 340-351.
[7]	寿建敏周紫荆. 基于北极航道全成本模型的液化天然气进口船队规模研究[J]. 极地研究, 2022, 34(3): 317-328.
[8]	张晓谢瑱瑮张瑜张艳艳陈长胜徐丹亚胡松. 北极冰间湖时空变化过程及其形成机制研究进展[J]. 极地研究, 2022, 34(3): 380-396.
[9]	王宇蓉谢瑱瑮张瑜陈长胜徐丹亚胡松. 加拿大北极群岛区域海洋环流及水文特征变化及其影响因素研究进展[J]. 极地研究, 2022, 34(3): 367-379.
[10]	李妍星, 常亮, 张春玲. 春季云属性的空间分布特征及其对北极海冰减退的影响[J]. 极地研究, 2022, 34(2): 177-188.
[11]	孙从容, 刁宁辉, 韩静雨, 刘金普, 刘建强. 海洋卫星北极多区域遥感成像任务规划及应用评估[J]. 极地研究, 2022, 34(2): 189-197.
[12]	马晓雪, 何佩龙, 乔卫亮, 刘阳. 韧性视域下北极航行风险级联效应分析[J]. 极地研究, 2022, 34(2): 219-238.
[13]	杨艳丽常亮. MODIS北极气溶胶光学厚度的精度验证与分布特征研究[J]. 极地研究, 2022, 34(1): 62-71.
[14]	朱兵袁东方夏寅月. “雪龙”号北极西北航道航行实践与探索研究[J]. 极地研究, 2022, 34(1): 101-113.
[15]	何剑锋, 张侠, 陆志波, 王娟, 陈之依. 北极海运对航道生态环境的潜在影响分析[J]. 极地研究, 2021, 33(4): 473-481.

北极斯瓦尔巴群岛冰川流域可培养细菌的系统发育多样性及固氮菌初步研究

Preliminary Study on Phylogenetic Diversity of Culturable Bacteria and Nitrogen-fixing Bacteria in Svalbard Glaciers of Arctic

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价