Alrubaye Hisham S, Kohl Kevin D
Department of Biological Sciences, University of Pittsburghgrid.21925.3d, Pittsburgh, Pennsylvania, USA.
mSystems. 2021 Aug 31:e0031321. doi: 10.1128/mSystems.00313-21.
Mammals maintain close associations with gut microbes that provide numerous nutritional benefits, including vitamin synthesis. While most mammals obtain sufficient vitamins from their diets, deficiencies in various B vitamins (biotin, cobalamin, riboflavin, thiamine, etc.) are reported in captive animals. Biomedical and agricultural research has shown that gut microbes are capable of synthesizing B vitamins and assisting with host vitamin homeostasis. However, we have a poor understanding of distribution and abundance of B-vitamin synthesis across mammalian hosts. Here, we leveraged a publicly available metagenomic data set from 39 mammalian species and used MG-RAST to compare the abundance and composition of B-vitamin-synthesizing microbes across mammalian feeding strategies. We predicted that herbivores would have the highest abundance of genes associated with vitamin synthesis, as plant material is often low in B vitamins. However, this hypothesis was not supported. Instead, we found that relative abundances of genes associated with cobalamin and thiamine synthesis were significantly enriched in carnivorous mammals. The taxonomic community structure of microbes predicted to be involved in B-vitamin synthesis also varied significantly based on host feeding strategy. For example, the genus primarily contributed to predicted biotin synthesis in carnivores but was not predicted to contribute to biotin synthesis in herbivores or omnivores. Given that B vitamins cannot be stored within the body, we hypothesize that microbial synthesis of B vitamins could be important for wild carnivores that regularly experience periods of fasting. Overall, these results shed light on the distribution and abundance of microbial B-vitamin synthesis across mammalian groups, with potential implications for captive animals. Microbial communities offer numerous physiological services to their hosts, but we still have a poor understanding of how these functions are structured across mammalian species. Specifically, our understanding of processes of vitamin synthesis across animals is severely limited. Here, we compared the abundance of genes associated with the synthesis of B vitamins and the taxonomic composition of the microbes containing these genes. We found that herbivores, omnivores, and carnivores harbor distinct communities of microbes that putatively conduct vitamin synthesis. Additionally, carnivores exhibited the highest abundance of genes associated with synthesis of specific B vitamins, cobalamin and thiamine. These data uncover the potential importance of microbes in the vitamin homeostasis of various mammals, especially carnivorous mammals. These findings have implications for understanding the microbial interactions that contribute to the nutritional requirements of animals held in captivity.
哺乳动物与肠道微生物保持着密切的联系,这些微生物提供了许多营养益处,包括维生素合成。虽然大多数哺乳动物从饮食中获取足够的维生素,但圈养动物中仍有各种B族维生素(生物素、钴胺素、核黄素、硫胺素等)缺乏的报道。生物医学和农业研究表明,肠道微生物能够合成B族维生素并协助宿主维持维生素稳态。然而,我们对B族维生素合成在哺乳动物宿主中的分布和丰度了解甚少。在这里,我们利用了一个来自39种哺乳动物的公开宏基因组数据集,并使用MG-RAST来比较不同哺乳动物摄食策略下B族维生素合成微生物的丰度和组成。我们预测食草动物中与维生素合成相关的基因丰度最高,因为植物性食物中的B族维生素含量通常较低。然而,这一假设并未得到支持。相反,我们发现与钴胺素和硫胺素合成相关的基因相对丰度在肉食性哺乳动物中显著富集。预计参与B族维生素合成的微生物的分类群落结构也因宿主摄食策略而有显著差异。例如,该属主要促成了肉食动物中预计的生物素合成,但预计不会促成食草动物或杂食动物中的生物素合成。鉴于B族维生素不能在体内储存,我们假设微生物合成B族维生素对经常经历禁食期的野生肉食动物可能很重要。总体而言,这些结果揭示了微生物B族维生素合成在哺乳动物群体中的分布和丰度,对圈养动物具有潜在影响。微生物群落为其宿主提供了许多生理服务,但我们对这些功能在哺乳动物物种中的组织方式仍了解甚少。具体而言,我们对动物体内维生素合成过程的了解严重有限。在这里,我们比较了与B族维生素合成相关的基因丰度以及含有这些基因的微生物的分类组成。我们发现食草动物、杂食动物和肉食动物拥有不同的假定进行维生素合成的微生物群落。此外,肉食动物中与特定B族维生素(钴胺素和硫胺素)合成相关的基因丰度最高。这些数据揭示了微生物在各种哺乳动物,尤其是肉食性哺乳动物的维生素稳态中的潜在重要性。这些发现对于理解有助于圈养动物营养需求的微生物相互作用具有启示意义。
