Department of Biological and Chemical Engineering, Aarhus University, Gustav Wieds Vej 10, 8000, Arhus, Denmark.
Present address: National Food Institute, Technical University of Denmark, Kgs. Lyngby, Denmark.
Microbiome. 2024 Sep 19;12(1):178. doi: 10.1186/s40168-024-01863-4.
Microbial pdu and cob-cbi-hem gene clusters encode the key enzyme glycerol/diol dehydratase (PduCDE), which mediates the transformation of dietary nutrients glycerol and 1,2-propanediol (1,2-PD) to a variety of metabolites, and enzymes for cobalamin synthesis, a co-factor and shared good of microbial communities. It was the aim of this study to relate pdu as a multipurpose functional trait to environmental conditions and microbial community composition. We collected fecal samples from wild animal species living in captivity with different gut physiology and diet (n = 55, in total 104 samples), determined occurrence and diversity of pdu and cob-cbi-hem using a novel approach combining metagenomics with quantification of metabolic and genetic biomarkers, and conducted in vitro fermentations to test for trait-based activity.
Fecal levels of the glycerol transformation product 1,3-propanediol (1,3-PD) were higher in hindgut than foregut fermenters. Gene-based analyses indicated that pduC harboring taxa are common feature of captive wild animal fecal microbiota that occur more frequently and at higher abundance in hindgut fermenters. Phylogenetic analysis of genomes reconstructed from metagenomic sequences identified captive wild animal fecal microbiota as taxonomically rich with a total of 4150 species and > 1800 novel species but pointed at only 56 species that at least partially harbored pdu and cbi-cob-hem. While taxonomic diversity was highest in fecal samples of foregut-fermenting herbivores, higher pduC abundance and higher diversity of pdu/cbi-cob-hem related to higher potential for glycerol and 1,2-PD utilization of the less diverse microbiota of hindgut-fermenting carnivores in vitro.
Our approach combining metabolite and gene biomarker analysis with metagenomics and phenotypic characterization identified Pdu as a common function of fecal microbiota of captive wild animals shared by few taxa and stratified the potential of fecal microbiota for glycerol/1,2-PD utilization and cobalamin synthesis depending on diet and physiology of the host. This trait-based study suggests that the ability to utilize glycerol/1,2-PD is a key function of hindgut-fermenting carnivores, which does not relate to overall community diversity but links to the potential for cobalamin formation. Video Abstract.
微生物 pdu 和 cob-cbi-hem 基因簇编码关键酶甘油/二醇脱水酶(PduCDE),它介导膳食营养物甘油和 1,2-丙二醇(1,2-PD)向多种代谢物的转化,以及钴胺素合成所需的酶,钴胺素是微生物群落的辅因子和共有物。本研究旨在将 pdu 作为一种多用途功能特征与环境条件和微生物群落组成联系起来。我们收集了来自具有不同肠道生理学和饮食的圈养野生动物物种的粪便样本(n=55,共 104 个样本),使用一种新的方法将宏基因组学与代谢物和遗传生物标志物的定量相结合,来确定 pdu 和 cob-cbi-hem 的存在和多样性,并进行体外发酵以测试基于特征的活性。
后肠发酵器中的粪便 1,3-丙二醇(1,3-PD)的甘油转化产物水平高于前肠发酵器。基于基因的分析表明,pduC 携带的分类群是圈养野生动物粪便微生物群的共同特征,在后肠发酵器中更频繁且丰度更高。基于从宏基因组序列重建的基因组的系统发育分析表明,圈养野生动物粪便微生物群在分类上非常丰富,共有 4150 个物种和 >1800 个新物种,但至少部分携带 pdu 和 cbi-cob-hem 的物种只有 56 个。虽然前肠发酵的草食动物的粪便样本具有最高的分类多样性,但后肠发酵的肉食动物的粪便微生物群较低的多样性与更高的甘油和 1,2-PD 利用潜力相关,这与 pduC 丰度较高和 pdu/cbi-cob-hem 多样性较高有关。
我们将代谢物和基因生物标志物分析与宏基因组学和表型特征相结合的方法确定了 Pdu 是圈养野生动物粪便微生物群的一个共同功能,由少数分类群共享,并根据宿主的饮食和生理学对粪便微生物群利用甘油/1,2-PD 和钴胺素合成的潜力进行分层。这项基于特征的研究表明,利用甘油/1,2-PD 的能力是后肠发酵肉食动物的关键功能,它与整体群落多样性无关,但与钴胺素形成的潜力有关。
