Gut dysbiosis contributes to TMAO accumulation in CKD.

Abstract Background and Aims Chronic kidney disease (CKD) patients face a substantial morbidity risk, especially related to cardiovascular complications. The imbalance of circulating metabolites influences inter-organ crosstalk and disease pathophysiology. In this regard, metabolites of microbial origin have gained increasing attention. Trimethylamine N-oxide (TMAO) originates from microbial Trimethylamine (TMA) metabolism and is found at high concentrations in the blood of CKD patients. A high TMAO concentration is known to be an independent risk factor for cardiovascular disease. This study aims to investigate the extent to which high concentrations of TMAO in the blood are due to increased bacterial production or are mainly a consequence of impaired renal clearance. Methods We used existing biomaterials and clinical data of a pediatric CKD cohort, consisting of patients enrolled at CKD stage G3-5, including G5 patients treated with hemodialysis (HD), as well as patients after kidney transplantation (KT) and individuals with normal kidney function. We analyzed TMAO in plasma and urine samples using LC-MS/MS and developed a novel gene targeting assay (GTA) that quantifies the abundance of the bacterial target genes (CutC, CntA) encoding for the key enzymes of microbial TMA synthesis in each fecal sample. Results Plasma TMAO levels were stage-dependently elevated in CKD, with HD patients showing the highest levels (75 ± 46 µmol/l). While urinary TMAO levels were lower in the CKD groups, TMAO/creatinine ratios and fractional excretion were not significantly different in CKD compared to controls. Fecal microbial gene abundance of both CutC and CntA genes was elevated across CKD stages and correlated with both plasma TMAO levels and eGFR. Although KT patients exhibited an eGFR range comparable to controls, they still showed higher plasma TMAO levels and elevated TMAO-associated gene abundances. In a regression analysis, this gene abundance was associated with plasma TMAO independent of eGFR in a model adjusted for age, sex, and BMI. Using a likelihood ratio test, we showed that adding fecal microbial gene abundance to the model provided a significantly better fit compared to only eGFR, age, sex, and BMI. Conclusion Our data indicate that the production of TMA by intestinal bacteria contributes significantly to the accumulation of TMAO in patients with CKD and after kidney transplantation. This finding opens the possibility for new potential interventions in the management of patients with CKD.