Jonas Lauren, Lee Yi-Ying, Bachvaroff Tsvetan, Hill Russell T, Li Yantao
Institute of Marine and Environmental Technology, Baltimore, Maryland, USA.
University of Maryland Center for Environmental Science, Baltimore, Maryland, USA.
mBio. 2025 Jul 9;16(7):e0123125. doi: 10.1128/mbio.01231-25. Epub 2025 Jun 12.
The functional roles of bacterial symbionts associated with microalgae remain understudied despite the importance of microalgae in biotechnology and environmental microbiology. 16S rRNA gene sequencing was conducted to analyze bacterial communities associated with two microalgae optimized for growth with flue gas containing 5%-10% CO. Two dominant bacteria with no taxonomic classification beyond the class level (Paceibacteria) were discovered repeatedly in the most productive algal cultures. Long-read metagenomic sequencing was conducted to yield high-quality metagenomes, from which two novel species were discovered under the Seqcode (seqco.de/r:ywe1blo2), gen. nov. sp. nov. and gen. nov. sp. nov. The genus gen. nov. was proposed as the nomenclatural type of the family Phycocordibacteraceae fam. nov. and the order Phycocordibacterales ord. nov. Both bacteria possessed features typical of Patescibacteria such as reduced genomes (<800 kbp), lack of complete glycolysis and tricarboxylic acid (TCA) cycle pathways, and inability to synthesize amino acids. Instead, they rely on the reductive pentose phosphate pathway (Calvin cycle) for essential biosynthesis and redox balance. may also rely on elemental sulfur oxidation (), partial nitrite reduction (), and sulfur-related amino acid metabolism (SAMe → SAH). Both bacteria were found in high relative abundance in cultures of HTB1 (freshwater) and IMET1 (marine), suggesting a tight association with microalgae in various environments. The absence of full metabolic pathways for energy production suggests extreme metabolic limitations and obligate symbiosis, most likely with other bacteria associated with the microalgae.IMPORTANCETo our knowledge, this is the first report of Patescibacteria as dominant bacteria associated with microalgae or within a biologically mediated carbon capture system. Two novel Patescibacteria were found in two ecologically distinct microalgal cultures (one freshwater strain and one marine) regardless of whether the cultures were bubbled with air, 5% CO, or 10% CO. This unexpected and unprecedented dominance led to long-read sequencing and the assembly of high-quality metagenomes for both Patescibacteria, as well as five other bacteria in the system. The discovery of two novel species belonging to two novel genera, one novel family, and one novel order has enabled us to fill in gaps of a major, uncharacterized branch within the bacterial tree of life. Additionally, the extreme gene loss found in both Patescibacteria, and , contributes knowledge to a rapidly advancing body of research on the scavenging metabolic nature of this enigmatic and largely unclassified phylum.
尽管微藻在生物技术和环境微生物学中具有重要意义,但与微藻相关的细菌共生体的功能作用仍未得到充分研究。进行了16S rRNA基因测序,以分析与两种微藻相关的细菌群落,这两种微藻针对含5%-10% CO的烟道气进行了生长优化。在生产力最高的藻类培养物中反复发现了两种优势细菌,它们在类水平以上没有分类学分类(Paceibacteria)。进行了长读长宏基因组测序以产生高质量的宏基因组,从中在Seqcode(seqco.de/r:ywe1blo2)下发现了两个新物种,gen. nov. sp. nov. 和gen. nov. sp. nov.。提议将gen. nov. 属作为Phycocordibacteraceae fam. nov. 科和Phycocordibacterales ord. nov. 目的命名模式。这两种细菌都具有Patescibacteria的典型特征,如基因组减少(<800 kbp)、缺乏完整的糖酵解和三羧酸(TCA)循环途径以及无法合成氨基酸。相反,它们依靠还原性戊糖磷酸途径(卡尔文循环)进行基本的生物合成和氧化还原平衡。 也可能依靠元素硫氧化()、部分亚硝酸盐还原()和与硫相关的氨基酸代谢(SAMe → SAH)。在HTB1(淡水)和IMET1(海洋)的培养物中发现这两种细菌的相对丰度都很高,这表明它们在各种环境中与微藻紧密相关。缺乏完整的能量产生代谢途径表明存在极端的代谢限制和专性共生,很可能与微藻相关的其他细菌共生。重要性据我们所知,这是关于Patescibacteria作为与微藻相关或在生物介导的碳捕获系统中的优势细菌的首次报告。在两种生态上不同的微藻培养物(一种淡水菌株和一种海洋菌株)中发现了两种新的Patescibacteria,无论培养物是用空气、5% CO还是10% CO鼓泡。这种意想不到且前所未有的优势导致对这两种Patescibacteria以及系统中的其他五种细菌进行了长读长测序和高质量宏基因组的组装。发现属于两个新属、一个新科和一个新目的两个新物种,使我们能够填补细菌生命树中一个主要的未表征分支的空白。此外,在两种Patescibacteria, 和 中发现的极端基因丢失,为关于这个神秘且大部分未分类的门的清除代谢性质的快速发展的研究提供了知识。
