A substantial body of evidence points to the importance of renal filtration and the elimination of microbiome-derived metabolites. Chronic kidney disease can lead to renal failure, which can have detrimental consequences for the elimination of microbiome metabolites. Specifically, p-cresyl sulfate and indoxyl sulfate are cometabolites between human metabolism and microbiome fermentation. Kidney failure or loss of renal function can lead to retention of these metabolites, and they can induce toxic harm by remaining in systemic circulation. While there has been significant interest in this field, much is unknown regarding CKD’s influence on microbiota function and metabolism. Researchers in Belgium sought to address this and identify what role CKD would have on the microbiota metabolism in the colon in patients on hemodialysis.

The experimenters examined 20 patients on hemodialysis. These fecal metabolites profiles of these patients were compared to 20 healthy controls using gas chromatography-mass spectrometry. Initial observations revealed that healthy controls had a significantly higher number of volatile organic compounds (VOCs) – an indicator of microbiota metabolism - as compared to the patients on hemodialysis. After adjusting the data for statistical confounders and discriminating VOCs between groups, the researchers determined that 81 individual VOCs were significantly different between hemodialysis patients and healthy controls. Consistent with previous findings and known clinical conditions, both p-cresol and indole were significantly upregulated in hemodialysis patients. A major confounder in this study is diet, as hemodialysis patients are on a very restricted diet, and as we know, dietary intake impacts microbiome composition and metabolism. The researchers conducted the same analysis with the hemodialysis patients with household contacts who were on the same diets. Interestingly, no significant difference in VOCs was observed between groups.

The researchers demonstrated that CKD patients on hemodialysis experience an altered microbiota metabolism; however, dietary influence may be driving this effect rather than loss of renal function. It was good to see the researchers included the household controls, as this evidence suggests renal function by itself may not have direct impacts on gut microbiota function. Regardless, much of the CKD-microbiome research to this date has focused on the microbiome’s role in CKD or CKD-mediated downstream maladies. It was interesting to see a study that took the opposite approach, as we know microbiome health is important for homeostatic mechanisms that maintain a healthy body.

It’s becoming increasingly recognized that dysbiosis in the gut microbiome can result in the development of sickness or disease. Understanding these implications, researchers have also turned to studying biomarkers and indicators that can better predict this outcome and disease onset. A novel and easily detectable biomarker could serve as an indicator of dysbiosis and facilitate therapeutic development. Renal function decline is a disorder that can eventually lead to chronic kidney disease (CKD )and impacts many people worldwide. A conglomerate team of researchers investigated whether metabolites produced from bacterial fermentation could serve as early indicators of renal function decline, and whether or not disruption to taxonomic units are detectible in this stage of the disease.

The researchers measured circulating metabolites in 4439 individual healthy patients with minimal renal function decline. Estimated glomerular filtration rate (eGFR) was measured as an indicator for reduced renal function, and the onset of CKD was defined by the kidney losing half of its filtration capacity. It was found that indoxyl-sulfate, p-cresyl-sulfate, and phenylacetylglutamine –metabolic products of gut microbiota fermentation of tyrosine and tryptophan – were associated with reduction in eGFR, suggesting that these markers could be indicators of early renal function decline. The researchers were also able to correlate these metabolite levels with changes to in intestinal flora. 16S sequencing revealed that 3 operational taxonomic units were correlated with indoxyl-sulfate, 52 with phenylacetylglutamine, and 1 with p-cresyl sulfate.

Specific changes within the gut microbiome could indicate disease onset, and these changes could perhaps be monitored by circulating metabolic products. Following metabolic activity could allow clinicians to treat disease early in its progression, and this principle could theoretically apply to a variety of host diseases, not just kidney failure. Metabolic products of the microbiome could serve as a useful tool that can lead to novel therapy development.

Chronic kidney disease and its effect on microbiome metabolism

Gut-microbiota metabolites could be associated with renal failure