Project description:Approximately 15% of US adults have circulating levels of uric acid above its solubility limit, which is causally linked to the inflammatory disease gout. In most mammals, uric acid elimination is facilitated by the enzyme uricase. However, human uricase is a pseudogene, having been inactivated early in hominid evolution. Though it has long been known that a substantial amount of uric acid is eliminated in the gut, the role of the gut microbiota in hyperuricemia has not been studied. Here we identify a gene cluster, widely distributed in the gut microbiome, that encodes a pathway for uric acid degradation. Stable isotope tracing demonstrates that gut bacteria metabolize uric acid to xanthine or short chain fatty acids such as acetate, lactate and butyrate. Ablation of the microbiota in uricase-deficient mice causes profound hyperuricemia, and anaerobe-targeted antibiotics increase the risk of gout in humans. These data reveal a role for the gut microbiota in uric acid excretion and highlight the potential for microbiome-targeted therapeutics in hyperuricemia.

Project description:Rat hyperuricemia microbiome study

Project description:Sunflower (Helianthus annuus L.) calathide is becoming more well-known as a result of its anti-hyperuricemia bioactivity. Aiming at developing anti-hyperuricemic ingredients in sunflower calathide extract (SCE), we were fortunate to discover abietic acid (AA), identified from SCE, has the capacity to inhibit xanthine oxidase activity at low concentrations (IC50 = 10.60 µM and inhibition constant was 193.5 nM) that examined by inhibitor screening experiment in vitro and computer-simulated molecular docking. To further explore the anti-hyperuricemia effects, the UA-stimulated human embryonic kidney (HEK) 293T cells were evaluated as a conceivable model in the current study. The huge amounts of high-throughput sequencing data, which mapping to reference genome, were analyzed by bioinformatics approaches: Weighted Gene Co-Expression Network Analysis (WGCNA) along with Kyoto Encyclopedia of Genes and Genomes (KEGG). Interestingly, the purine metabolism-related genes expressed in the AA treatment were nearly opposite to that of the UA group, indicating negative feedback regulations that AA perhaps contributes to maintain urate homeostasis in the high UA-exposed kidney cellular environment. Here, we consider that HEK293T cells ought to be an achievable in vitro model for UA metabolism research because the PNPase, PRPS1, PRPS2, and RPIA, which participate in UA generation, widely expressed in the untreated 293T cells as well. And AA markedly suppressed the PNPase, PRPS2, and RPIA expressed in UA-stimulated 293T cells, implying inhibitions for UA biosynthesis. As a result, AA not only inhibited xanthine oxidase activity efficiently but also regulated genes PNPase, PRPS2, and RPIA. It is promising to be developed as an inhibitor against hyperuricemia. Therefore, abietic acid, which could be isolated from plants, has the potential for anti-hyperuricemia, and the current study provided a precedent for pharmacology analysis of natural ingredients.

Project description:Interventions: Hyperuricemia group:No;Non-hyperlactateemia group:No Primary outcome(s): Overall survival;Progression-free survival Study Design: Factorial

Project description:Hyperuricemia Predisposes to the Onset of Diabetes

Project description:Studies of gut microbiota related to hyperuricemia.

Project description:Uromodulin-associated kidney disease (UAKD) summarizes different clinical features of an autosomal dominant heritable disease syndrome in humans with a proven uromodulin (UMOD) mutation involved. It is often characterized by hyperuricemia, gout, alteration of urine concentrating ability, as well as a variable rate of disease progression inconstantly leading to renal failure and histological alterations of the kidneys. We recently established the two Umod mutant mouse lines UmodC93F and UmodA227T on the C3H inbred genetic background both showing kidney defects analogous to those found in human UAKD patients. The aim of this study was the further analysis of the phenotypic alterations by examining the kidneys as primarily affected organs. Transcriptome and quantitative PCR analyses as well as IHC analyses found significant changes related to the phenotyping changes. 4 male mice of each mutant cohort (Umod C93F & Umod A227T) and the corresponding wildtype controls, each mutant mouse was compared to the mean of the corresponding wildtype including a technical replicate (dye swap)

Project description:Study on the Diversity of Fecal Microbes in Hyperuricemia Rat

Project description:We performed label-free liquid chromatography MS/MS spectrometry analysis of urine samples from 26 HUA patients and 25 healthy controls, attempting to establish the possible protein links between hyperuricemia and these diseases by profiling urine proteome.

Project description:Study on the mechanism of improving hyperuricemia in mice by EH-TDM