The gut flora modulates intestinal barrier integrity but not progression of chronic kidney disease in hyperoxaluria-related nephrocalcinosis.

BACKGROUND: Dysbiosis, bacterial translocation and systemic inflammation have been found to be associated with human and experimental forms of chronic kidney disease (CKD), but the functional contribution of the intestinal microbiota to CKD-related intestinal barrier dysfunction and CKD progression is unknown, especially in CKD secondary to hyperoxaluria and nephrocalcinosis. METHODS: C57BL/6N mice fed an oxalate-rich diet for either 10 or 20 days developed reversible or progressive kidney disease, respectively. RESULTS: Oxalate-induced CKD manifested as azotaemia, renal anaemia and hyperkalaemia. CKD was associated with persistent dysbiosis and intestinal barrier dysfunction. Local as well as systemic inflammation was evident and partially persisted despite better renal function after returning to an oxalate-free diet, indicating some innate immune memory. Eradication of the microbiota with a combination of antibiotics improved intestinal barrier function but had no effect on renal function, nephrocalcinosis, kidney remodelling and atrophy compared with control mice not receiving antibiotics. CONCLUSIONS: Together, in chronic oxalate nephropathy, the intestinal microbiota contributes to the CKD-related dysfunction of the intestinal barrier but not to the progression of nephrocalcinosis itself, as well to its related kidney atrophy and excretory dysfunction.

Intestinal Dysbiosis, Barrier Dysfunction, and Bacterial Translocation Account for CKD-Related Systemic Inflammation.

CKD associates with systemic inflammation, but the underlying cause is unknown. Here, we investigated the involvement of intestinal microbiota. We report that collagen type 4 α3-deficient mice with Alport syndrome-related progressive CKD displayed systemic inflammation, including increased plasma levels of pentraxin-2 and activated antigen-presenting cells, CD4 and CD8 T cells, and Th17- or IFNγ-producing T cells in the spleen as well as regulatory T cell suppression. CKD-related systemic inflammation in these mice associated with intestinal dysbiosis of proteobacterial blooms, translocation of living bacteria across the intestinal barrier into the liver, and increased serum levels of bacterial endotoxin. Uremia did not affect secretory IgA release into the ileum lumen or mucosal leukocyte subsets. To test for causation between dysbiosis and systemic inflammation in CKD, we eradicated facultative anaerobic microbiota with antibiotics. This eradication prevented bacterial translocation, significantly reduced serum endotoxin levels, and fully reversed all markers of systemic inflammation to the level of nonuremic controls. Therefore, we conclude that uremia associates with intestinal dysbiosis, intestinal barrier dysfunction, and bacterial translocation, which trigger the state of persistent systemic inflammation in CKD. Uremic dysbiosis and intestinal barrier dysfunction may be novel therapeutic targets for intervention to suppress CKD-related systemic inflammation and its consequences.

The NLRP3/ASC inflammasome promotes T-cell-dependent immune complex glomerulonephritis by canonical and noncanonical mechanisms.

Interleukin (IL)-1ß contributes to renal injury in immune complex glomerulonephritis. However, production of mature IL-1ß depends on activation of the inflammasome that cleaves pro-IL-1ß into its secretable form. A functional role of the NLRP3-containing inflammasome, which responds to various endogenous danger signals, was found in tubulointerstitial nephropathies, but its function in glomerular disease has not been established. To determine whether NLRP3 and its adapter molecule ASC contribute to glomerulonephritis, we induced T-cell-dependent autologous nephrotoxic serum nephritis in Nlrp3- and Asc-deficient mice. Renal expression of NLRP3/ASC inflammasome components and pro-IL-1ß increased during nephrotoxic serum nephritis and was abundant in renal dendritic cells. This was associated with renal production of mature IL-1ß, indicating inflammasome activation. Nlrp3 and Asc deficiency significantly attenuated glomerular injury, renal leukocyte infiltration, and T-cell activation. Production of mature IL-1ß was abrogated in Asc-deficient mice, consistent with a loss of inflammasome-dependent IL-1ß activation. Surprisingly, renal IL-1ß secretion remained intact in Nlrp3-deficient mice, indicating noncanonical pro-inflammatory effects of NLRP3 in autologous nephrotoxic serum nephritis. This may include NLRP3-mediated glomerular release of pro-inflammatory high-mobility group box 1 protein as a noncanonical function of NLRP3/ASC in glomerulonephritis. Thus, therapeutic blockade of the NLRP3/ASC/IL-1ß axis may be beneficial in glomerulonephritis.

The intestinal microbiota, a leaky gut, and abnormal immunity in kidney disease.

Chronic kidney disease (CKD) and end-stage renal disease (ESRD) are associated with systemic inflammation and acquired immunodeficiency, which promote cardiovascular disease, body wasting, and infections as leading causes of death. This phenomenon persists despite dialysis-related triggers of immune deregulation having been largely eliminated. Here we propose a potential immunoregulatory role of the intestinal microbiota in CKD/ESRD. We discuss how the metabolic alterations of uremia favor pathogen overgrowth (dysbiosis) in the gut and an increased translocation of living bacteria and bacterial components. This process has the potential to activate innate immunity and systemic inflammation. Persistent innate immune activation involves the induction of immunoregulatory mediators that suppress innate and adaptive immunity, similar to the concept of 'endotoxin tolerance' or 'immune paralysis' in advanced sepsis or chronic infections. Renal science has largely neglected the gut as a source of triggers for CKD/ESRD-related immune derangements and complications and lags behind on the evolving microbiota research. Interdisciplinary research activities at all levels are needed to unravel the pathogenic role of the intestinal microbiota in kidney disease and to evaluate if therapeutic interventions that manipulate the microbiota, such as pre- or probiotics, have a therapeutic potential to correct CKD/ESRD-related immune deregulation and to prevent the associated complications.