Swan Brandon K, Chaffin Mark D, Martinez-Garcia Manuel, Morrison Hilary G, Field Erin K, Poulton Nicole J, Masland E Dashiell P, Harris Christopher C, Sczyrba Alexander, Chain Patrick S G, Koren Sergey, Woyke Tanja, Stepanauskas Ramunas
Single Cell Genomics Center, Bigelow Laboratory for Ocean Sciences, East Boothbay, Maine, United States of America.
Single Cell Genomics Center, Bigelow Laboratory for Ocean Sciences, East Boothbay, Maine, United States of America; Department of Biology, Colby College, Waterville, Maine, United States of America.
PLoS One. 2014 Apr 17;9(4):e95380. doi: 10.1371/journal.pone.0095380. eCollection 2014.
Marine Group I (MGI) Thaumarchaeota are one of the most abundant and cosmopolitan chemoautotrophs within the global dark ocean. To date, no representatives of this archaeal group retrieved from the dark ocean have been successfully cultured. We used single cell genomics to investigate the genomic and metabolic diversity of thaumarchaea within the mesopelagic of the subtropical North Pacific and South Atlantic Ocean. Phylogenetic and metagenomic recruitment analysis revealed that MGI single amplified genomes (SAGs) are genetically and biogeographically distinct from existing thaumarchaea cultures obtained from surface waters. Confirming prior studies, we found genes encoding proteins for aerobic ammonia oxidation and the hydrolysis of urea, which may be used for energy production, as well as genes involved in 3-hydroxypropionate/4-hydroxybutyrate and oxidative tricarboxylic acid pathways. A large proportion of protein sequences identified in MGI SAGs were absent in the marine cultures Cenarchaeum symbiosum and Nitrosopumilus maritimus, thus expanding the predicted protein space for this archaeal group. Identifiable genes located on genomic islands with low metagenome recruitment capacity were enriched in cellular defense functions, likely in response to viral infections or grazing. We show that MGI Thaumarchaeota in the dark ocean may have more flexibility in potential energy sources and adaptations to biotic interactions than the existing, surface-ocean cultures.
海洋第一类(MGI)奇古菌是全球黑暗海洋中数量最多、分布最广的化能自养生物之一。迄今为止,从黑暗海洋中获取的该古菌组的代表菌株均未成功培养。我们利用单细胞基因组学研究了北太平洋亚热带和南大西洋中层带中奇古菌的基因组和代谢多样性。系统发育和宏基因组招募分析表明,MGI单扩增基因组(SAG)在遗传和生物地理上与从表层水体获得的现有奇古菌培养物不同。证实了之前的研究,我们发现了编码用于好氧氨氧化和尿素水解的蛋白质的基因,这些基因可能用于能量产生,以及参与3-羟基丙酸/4-羟基丁酸和氧化三羧酸途径的基因。在MGI SAG中鉴定出的很大一部分蛋白质序列在海洋培养物共生嗜 Cenarchaeum和嗜盐亚硝化球菌中不存在,从而扩展了该古菌组的预测蛋白质空间。位于宏基因组招募能力较低的基因组岛上的可识别基因在细胞防御功能中富集,可能是对病毒感染或捕食的响应。我们表明,黑暗海洋中的MGI奇古菌在潜在能量来源和对生物相互作用的适应方面可能比现有的表层海洋培养物具有更大的灵活性。
