The role of low protein diet in ameliorating proteinuria and deferring dialysis initiation: what is old and what is new.

In the management of patients with chronic kidney diseases (CKD), a low-protein diet usually refers to a diet with protein intake of 0.6 to 0.8 grams per kilogram of body weight per day (g/kg/day) and should include at least 50% high-biologic-value protein. It may be supplemented with essential acids or nitrogen-free ketoanalogues if <0.6 g/kg/d. Low-protein diet can reduce proteinuria especially in non-diabetic CKD patients. In hypoalbuminemic patients it may lead to an increase in serum albumin level. By lowering proteinuria, decreasing nitrogen waste products, ameliorating metabolic burden, mitigating oxidative stress and acidosis, and lowering phosphorus burden, a low-protein diet can help delay dialysis start in advanced CKD. Low-protein diet is safe, since most CKD patients can maintain nitrogen balance by mechanisms of decreasing amino acid oxidation and protein degradation in addition to increased utilization of amino acids for protein synthesis. We suggest a dietary protein intake below 1.0 g/kg/day when estimated glomerular filtration rate (eGFR) falls below 60 mL/min/1.73 m2 or when there is solitary kidney or proteinuria at any level of GFR. Protein intake should be reduced progressively based on severity and progression of CKD and patient's nutritional status with a target of 0.6-0.8 g/kg/d in most patients with eGFR <45 mL/min/1.73 m2. The risk of protein-energy wasting can be overcome by careful attention to quantity and quality of the ingested proteins, sufficient energy intake of 30-35 Kcal/kg/d, and use of dietary supplements. Long-term observations and individualized approaches are needed to further demonstrate the benefits and safety of low-protein diet.

Resistant starch alters gut microbiome and metabolomic profiles concurrent with amelioration of chronic kidney disease in rats.

Patients and animals with chronic kidney disease (CKD) exhibit profound alterations in the gut environment including shifts in microbial composition, increased fecal pH, and increased blood levels of gut microbe-derived metabolites (xenometabolites). The fermentable dietary fiber high amylose maize-resistant starch type 2 (HAMRS2) has been shown to alter the gut milieu and in CKD rat models leads to markedly improved kidney function. The aim of the present study was to identify specific cecal bacteria and cecal, blood, and urinary metabolites that associate with changes in kidney function to identify potential mechanisms involved with CKD amelioration in response to dietary resistant starch. Male Sprague-Dawley rats with adenine-induced CKD were fed a semipurified low-fiber diet or a high-fiber diet [59% (wt/wt) HAMRS2] for 3 wk (n = 9 rats/group). The cecal microbiome was characterized, and cecal contents, serum, and urine metabolites were analyzed. HAMRS2-fed rats displayed decreased cecal pH, decreased microbial diversity, and an increased Bacteroidetes-to-Firmicutes ratio. Several uremic retention solutes were altered in the cecal contents, serum, and urine, many of which had strong correlations with specific gut bacteria abundances, i.e., serum and urine indoxyl sulfate were reduced by 36% and 66%, respectively, in HAMRS2-fed rats and urine p-cresol was reduced by 47% in HAMRS2-fed rats. Outcomes from this study were coincident with improvements in kidney function indexes and amelioration of CKD outcomes previously reported for these rats, suggesting an important role for microbial-derived factors and gut microbe metabolism in regulating host kidney function.