食用相同有毒食物的啮齿动物拥有独特的功能性核心微生物群。

IF 4.9 Q1 MICROBIOLOGY
Tess E Stapleton, LeAnn M Lindsey, Hari Sundar, M Denise Dearing
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引用次数: 0

摘要

肠道微生物群是草食性生活方式所固有的,但人们对通常有毒的植物次生化合物(PSCs)如何影响这些共生伙伴知之甚少。在这里,我们研究了两种木鼠(Neotoma lepida 和 bryanti)种群中独特的功能性核心微生物群的可能性,这两种木鼠各自以相同的有毒食物(杂酚油灌木;Larrea tridentata)为食,并将它们与不以杂酚油灌木为食的种群进行了比较。利用这一自然实验,我们在美国西南部沙漠的一个大地理区域收集了 20 个不同摄食杂酚油灌木的种群(约 150 个个体)的样本,并利用 16S 测序和霰弹枪元基因组学分析了三个肠道区域(前肠、盲肠和后肠)。在取样的每个肠道区域,我们都发现以杂酚油灌木为食的个体体内存在一组独特的微生物,它们的数量比其他 ASV 更多,富集于以杂酚油为食的林鼠体内,而且出现的频率比偶然预测的要高。杂酚油核心成员来自已知代谢植物次生化合物的微生物科(如蛋壳菌科),已确定的三个核心 KEGG 同源物(4-羟基苯甲酸脱羧酶、苯甲酰-CoA 还原酶亚基 B 和 2-吡喃酮-4,6-二羧酸内酯酶)编码的酶在植物次生化合物代谢中发挥重要作用。研究结果支持这样的假设:摄入杂酚油灌木会改变肠道所有主要区域的微生物组,从而选择与降解这种独特食物中的植物次生化合物相关的功能特性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Rodents consuming the same toxic diet harbor a unique functional core microbiome.

Gut microbiota are intrinsic to an herbivorous lifestyle, but very little is known about how plant secondary compounds (PSCs), which are often toxic, influence these symbiotic partners. Here we interrogated the possibility of unique functional core microbiomes in populations of two species of woodrat (Neotoma lepida and bryanti) that have independently converged to feed on the same toxic diet (creosote bush; Larrea tridentata) and compared them to populations that do not feed on creosote bush. Leveraging this natural experiment, we collected samples across a large geographic region in the U.S. desert southwest from 20 populations (~ 150 individuals) with differential ingestion of creosote bush and analyzed three gut regions (foregut, cecum, hindgut) using16S sequencing and shotgun metagenomics. In each gut region sampled, we found a distinctive set of microbes in individuals feeding on creosote bush that were more abundant than other ASVs, enriched in creosote feeding woodrats, and occurred more frequently than would be predicted by chance. Creosote core members were from microbial families e.g., Eggerthellaceae, known to metabolize plant secondary compounds and three of the identified core KEGG orthologs (4-hydroxybenzoate decarboxylase, benzoyl-CoA reductase subunit B, and 2-pyrone-4, 6-dicarboxylate lactonase) coded for enzymes that play important roles in metabolism of plant secondary compounds. The results support the hypothesis that the ingestion of creosote bush sculpts the microbiome across all major gut regions to select for functional characteristics associated with the degradation of the PSCs in this unique diet.

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来源期刊
CiteScore
7.20
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审稿时长
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