Faculty Bibliography

Background.: Observational studies have suggested a relationship between the plasma concentration of indoxyl sulfate (IS) and p -cresyl sulfate (PCS), small gut-derived 'uremic solutes', and the high incidence of uremic cardiomyopathy in patients with end-stage renal disease (ESRD). IS and PCS are derived from the metabolism of dietary components (tryptophan and tyrosine) by gut bacteria. This pilot study was designed to examine the effects of a poorly absorbable antibiotic (vancomycin) on the plasma concentration of two gut-derived 'uremic solutes', IS and PCS, and on the composition of the gut microbiome. Methods.: Plasma concentrations of IS and PCS were measured by MS-HPLC. The gut microbiome was assessed in stool specimens sequenced for the 16S rRNA gene targeting the V4 region. Results.: The pre-dialysis mean plasma concentrations of both IS and PCS were markedly elevated. Following the administration of vancomycin (Day 0), the IS and PCS concentrations decreased at Day 2 or Day 5 and returned to baseline by Day 28. Following vancomycin administration, several changes in the gut microbiome were observed. Most striking was the decrease in diversity, a finding that was evident on Day 7 and was still evident at Day 28. There was little change at the phylum level but at the genus level, broad population changes were noted. Changes in the abundance of several genera appeared to parallel the concentration of IS and PCS. Conclusions.: These findings suggest that alteration of the gut microbiome, by an antibiotic, might provide an important strategy in reducing the levels of IS and PCS in ESRD.

Background: There is growing evidence that the accumulation of protein-bound uremic retention solutes, such as indoxyl sulfate (IS), p-cresyl sulfate (PCS) and kynurenic acid (KA), play a role in the accelerated cardiovascular disease seen in patients undergoing chronic hemodialysis. Protein-binding, presumably to albumin, renders these solutes poor-dialyzable. We had previously observed that the concentration of free solute and its unbound fraction were markedly reduced at the end of hemodialysis. We hypothesized that solute binding might be pH-dependent and the changes attributable to the higher serum pH at the end of hemodialysis. In vitro, acidification of uremic plasma to pH 6 greatly increased the proportion of unbound indoxyl sulfate.
Method(s): We tested our hypothesis by reducing the dialysate bicarbonate buffer concentration to 25 mEq/L for the initial half of hemodialysis ('isohydric dialysis'). Eight stable hemodialysis patients underwent 'isohydric dialysis' and, midway, were switched to standard buffer (37 mEq/L). A second dialysis, 2 days later, employed standard buffer throughout.
Result(s): We found a clearcut separation of blood pH and bicarbonate concentrations 90 minutes following 'isohydric dialysis' (pH = 7.37, HCO3 =22.4 mEq/l) and standard dialysis (pH= 7.49, HCO3 = 29.5). Analysis of free and bound concentrations of uremic retention solutes confirmed our prediction that binding of solute is affected by pH. However, in mixed models analysis, we found that the reduction in total uremic solute concentration during dialysis accounted for a greater proportion of the variation in free concentration, presumably an effect of saturation binding to albumin, than did the relatively small change in pH produced by isohydric dialysis.
Conclusion(s): These findings suggest that modification of dialysis technique that would expose blood to a transient decrease in pH might increase the free fraction of solute and enhance the efficacy of hemodialysis in the removal of protein-bound uremic retention solutes

Residual renal function (RRF) in patients undergoing dialysis treatments is currently viewed as glomerular filtrate that has escaped tubular reabsorption. RRF has been quantified as a clearance of urea or creatinine, or urea + creatinine. A major paradigm shift has followed the recognition that a substantial number of organic anion retention solutes (possible "uremic toxins") are protein-bound and therefore are not readily filtered. These protein-bound aryl compounds are secreted by renal tubular organic anion transporters (OATs). This has led to the recognition that RRF in dialysis patients probably represents not only unreabsorbed glomerular filtrate but also a contribution of renal tubular transporters that secrete organic anions. Tubular secretion of hippurate, indoxyl sulfate, and p-cresol sulfate, protein-bound organic anions retained in the plasma of end-stage renal disease patients, can be quantified and used to evaluate the integrity of a function dependent on active solute transport. Here we propose a shift away from the exclusive "glomerulocentric" view of RRF as unreabsorbed glomerular filtrate and of the progression of renal disease as progressive glomerular loss. We expand the definition of RRF to include the combined renal and tubule functions remaining after a disease begins to destroy nephrons and proceeds to anuria. We propose renewed application of the first principles of renal physiology, articulated in the last century by Homer Smith, to the understanding and monitoring of RRF and progression of renal injury in patients during the sometimes long course of and at the end stage of chronic renal disease.

The measurement of glomerular filtration rate by the clearance of inulin or creatinine has evolved over the past fifty years into an estimated value (eGFR) based solely on plasma creatinine concentration. We have examined some of the misconceptions and misunderstanding of the classification of renal disease and its course which have followed this evolution. Further, renal plasma flow and tubular function, which in the past were estimated by the clearance of the exogenous aryl amine, para amino hippurate, are no longer measured. Over the past decade, studies in experimental animals with reduced nephron mass and in patients with reduced renal function have identified small gut-derived, protein-bound uremic retention solutes ("uremic toxins") that are poorly filtered but are secreted into the lumen by organic anion transporters (OAT) in the proximal renal tubule. These are not effectively removed by conventional hemodialysis or peritoneal dialysis. Residual renal function, urine produced in patients with advanced renal failure or undergoing dialysis treatment, may represent, at least in part, secretion of fluid and uremic toxins such as indoxyl sulfate, mediated by proximal tubule OATs, and might serve a useful survival function. In light of this new evidence of the physiologic role of proximal tubule OATs, we suggest that measurement of renal tubular function and renal plasma flow may be of considerable value in understanding and managing chronic kidney disease (CKD). Data obtained in normal subjects indicate that renal plasma flow and renal tubular function might be measured by the clearance of the endogenous arylamine, hippurate.

BACKGROUND: Chronic renal failure is characterized by progressive renal scarring and accelerated arteriosclerotic cardiovascular disease despite what is considered to be adequate hemodialysis or peritoneal dialysis. In rodents with reduced renal mass, renal scarring has been attributed to poorly filtered, small protein-bound molecules. The best studied of these is indoxyl sulfate (IS). METHODS: We have attempted to establish whether there are uremic toxins that are not effectively removed by hemodialysis. We examined plasma from patients undergoing hemodialysis, employing global gene expression in normal human renal cortical cells incubated in pre- and post- dialysis plasma as a reporter system. Responses in cells incubated with pre- and post-dialysis uremic plasma (n = 10) were compared with responses elicited by plasma from control subjects (n = 5). The effects of adding IS to control plasma and of adding probenecid to uremic plasma were examined. Plasma concentrations of IS were measured by HPLC (high pressure liquid chromatography). RESULTS: Gene expression in our reporter system revealed dysregulation of 1912 genes in cells incubated with pre-dialysis uremic plasma. In cells incubated in post-dialysis plasma, the expression of 537 of those genes returned to baseline but the majority of them (1375) remained dysregulated. IS concentration was markedly elevated in pre- and post-dialysis plasma. Addition of IS to control plasma simulated more than 80% of the effects of uremic plasma on gene expression; the addition of probenecid, an organic anion transport (OAT) inhibitor, to uremic plasma reversed the changes in gene expression. CONCLUSION: These findings provide evidence that hemodialysis fails to effectively clear one or more solutes that effect gene expression, in our reporter system, from the plasma of patients with uremia. The finding that gene dysregulation was simulated by the addition of IS to control plasma and inhibited by addition of an OAT inhibitor to uremic plasma identifies IS as a major, poorly dialyzable, uremic toxin. The signaling pathways initiated by IS and possibly other solutes not effectively removed by dialysis may participate in the pathogenesis of renal scarring and uremic vasculopathy.

Chronic kidney disease (CKD) is a condition that affects approximately 10% of the adult population in developed countries. In patients with CKD adequate renal clearance is compromised, resulting in the accumulation of a plethora of uremic solutes. These uremic retention solutes, also known as uremic toxins, are a heterogeneous group of organic compounds, many are too large to be filtered (middle molecules) or are protein-bound. Tubular secretion shifts the binding and allows for active secretion of such solutes. To mediate urinary solute excretion, renal proximal tubules are equipped with a range of transporters that cooperate in basolateral uptake and luminal excretion. These putative uremic toxins are poorly filtered across dialysis membranes because they are protein bound and current dialysis therapy does not correct the full spectrum of uremic toxicity. Residual renal function, which may represent an important contribution of solutes secreted by the proximal tubule rather than unreabsorbed filtrate, is an important predictor of survival of CKD patients. Many of the transporters that mediate the renal excretion of uremic retention solutes were first recognized as mediators of drug trafficking and drug-drug interactions, and a considerable amount of literature concerning the actions of these transporters antedates the recognition of their importance in the proximal renal tubular transport of uremic retention solutes. These transporters include members belonging to the organic cation/anion/zwitterion solute carrier family, such as the organic anion transporters (OAT)1, OAT3, and OATP4C1, and to the adenosine triphosphate binding cassette superfamily of transmembrane transporters, including the multidrug resistance proteins and breast cancer resistance protein. This article draws on this body of information to describe the renal tubular clearance mechanisms for uremic toxins, as well as the intracellular events associated with their accumulation, involving activation of the aryl hydrocarbon receptor, disturbance of mitochondrial functioning, and competition with metabolizing enzymes.