Effect and mechanism of Huangkui capsuleon reduction of uremic toxin accumulation in an animal model of chronic kidney disease / 药学学报

ABSTRACT

Uremic toxins are harmful substances that accumulate in the body when the renal function declines in patients with chronic kidney disease (CKD). It is an important factor contributing to accelerated progression of CKD. There is no effective treatment for reducing uremic toxins. As an extensively used medicine for treatment of CKD in the clinic, Huangkui capsule is effective but the mechanism of its action remains unclear. This study investigated the effect of Huangkui on the accumulation of uremic toxins in CKD rats, with the discussion about its mechanism of action. UPLC-TQ/MS was used to detect the accumulation of uremic toxins in CKD rats after oral gavage with Huangkui. 16S rDNA sequencing technology was used to analyze the gut bacteria composition in rats. HPLC-FLD was used to detect the uremic toxins and their molecular precursors in feces. The effect and mechanism of Huangkui on the uremic toxin precursor in gut bacteria were studied by anaerobic culture system in vitro. All procedures were approved by the Institutional Animal Care and Use Committee of the Nanjing University of Chinese Medicine. The results showed that Huangkui (0.675 g·kg-1) could effectively inhibit the accumulation of uremic toxin indoxyl sulfate (IS) in CKD rats, with IS concentration in rat's plasma, liver and kidney decreased by 49.5%, 68.9% and 40.6%, respectively. Huangkui didn't affect the metabolic pathway of IS in host liver, didn't intervene the process of the IS precursor molecule indole conversion to IS. Instead, Huangkui significantly decreased the indole content in gut, with the indole in CKD rat's feces decreased by 46.4%, suggesting that the gut bacteria may be a target for intervene IS biosynthesis by Huangkui. Huangkui didn't affect the abundance of enterobacteriaceae bacteria (the main gut flora of indole synthesis) in CKD rats, suggesting that Huangkui didn't interfere with indole biosynthesis by directly affecting the abundance of indole synthesis related bacteria. Huangkui at 4 000, 400, 40, and 4 μg·mL-1 showed a dose-dependent inhibition of the indole production by gut bacteria in vitro. The bacteria tryptophan transport concentration decreased from 83.4 μmol·L-1 to 43.6 μmol·L-1 after co-incubated with Huangkui for 12 h, suggesting that Huangkui inhibited indole production of gut bacteria by interfering with tryptophan transportation. These results indicate that gut bacteria may be a potential target for alleviation of uremic toxin accumulation and for delaying CKD progression.