Abstract
Gut microbe–derived metabolites influence human physiology and disease. However, establishing mechanistic links between gut microbial metabolites and disease pathogenesis in animal models remains challenging. The major route of absorption for microbe-derived small molecules is venous drainage via the portal vein to the liver. In the event of presystemic hepatic metabolism, the route of metabolite administration becomes critical. To our knowledge, we describe here a novel portal vein cannulation technique using a s.c. implanted osmotic pump to achieve continuous portal vein infusion in mice. We first administered the microbial metabolite trimethylamine (TMA) over 4 weeks, during which increased peripheral plasma levels of TMA and its host liver-derived cometabolite, trimethylamine-N-oxide, were observed when compared with a vehicle control. Next, 4-hydroxyphenylacetic acid (4-HPAA), a microbial metabolite that undergoes extensive presystemic hepatic metabolism, was administered intraportally to examine effects on hepatic gene expression. As expected, hepatic levels of 4-HPAA were elevated when compared with the control group while peripheral plasma 4-HPAA levels remained the same. Moreover, significant changes in the hepatic transcriptome were revealed by an unbiased RNA-Seq approach. Collectively, to our knowledge this work describes a novel method for administering gut microbe–derived metabolites via the portal vein, mimicking their physiologic delivery in vivo.
Highlights
Recent efforts have underscored the importance of the gut microbial community as a meta-endocrine organ, impacting host physiology through systemic delivery of gut-microbial metabolites [1]
It is critical to ensure that strict adherence to sterile technique is maintained for the duration of the procedure given this is a survival surgery designed for long-term metabolite infusion
The catheter is externalized from the peritoneal cavity, where it is connected to a mini osmotic pump (Figure 1J and Supplemental Video 3)
Summary
Recent efforts have underscored the importance of the gut microbial community as a meta-endocrine organ, impacting host physiology through systemic delivery of gut-microbial metabolites [1]. In efforts to overcome this, the physiological impact of microbial metabolites is often studied by intermittent exogenous administration of a metabolite in a nonphysiologically relevant manner, such as i.v. injection, i.p. injection, or s.c. administration, all placing a relatively large proportion of the metabolite directly into the peripheral circulation. These approaches can effectively raise circulating metabolites levels in some cases, they do not mimic the natural delivery of gut microbial–derived small molecules through the portal circulation to the liver. This model will improve the interrogation of gut microbial metabolites and their associations to disease by providing an unmatched level of control when manipulating the portal blood metabolome
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