Biocompatibility reduces inflammation-induced apoptosis in mesothelial cells exposed to peritoneal dialysis fluid.

BACKGROUND/AIMS: Peritonitis is a major complication that arises out of peritoneal dialysis (PD), leading to death and loss of mesothelium and peritoneal injury, which may impede PD. We studied the combined impact of inflammatory mediators and PD fluids on mesothelial cell death. METHODS: Cultured human mesothelial cells. RESULTS: Inflammatory cytokines (TNF-α and interferon-γ) cooperate with bioincompatible PD fluids containing high glucose degradation product (GDP) concentrations to promote mesothelial cell death. Thus, the inflammatory cytokine cocktail induced a higher rate of death in cells cultured in high GDP PD fluid than in low GDP PD fluid or cell culture medium (cell death expressed as % hypodiploid cells: TNF-α and interferon-γ in RPMI: 14.15 ± 1.68, TNF-α and interferon-γ in 4.25% low GDP PD fluid 13.16 ± 3.29, TNF-α and interferon-γ in 4.25% high GDP PD fluid 25.88 ± 2.18%, p < 0.05 vs. the other two groups). BclxL BH4 peptides, Apaf-1 inhibition or caspase inhibition failed to protect from apoptosis induced by the combination of inflammatory cytokines and bioincompatible PD fluids, although they protected from other forms of mesothelial cell apoptosis. CONCLUSION: Inflammation cooperates with high GDP PD fluids to promote mesothelial cell death, which is resistant to several therapeutic approaches. This information provides a framework for selection of PD fluid during peritonitis.

Osteoprotegerin in exosome-like vesicles from human cultured tubular cells and urine.

Urinary exosomes have been proposed as potential diagnostic tools. TNF superfamily cytokines and receptors may be present in exosomes and are expressed by proximal tubular cells. We have now studied the expression of selected TNF superfamily proteins in exosome-like vesicles from cultured human proximal tubular cells and human urine and have identified additional proteins in these vesicles by LC-MS/MS proteomics. Human proximal tubular cells constitutively released exosome-like vesicles that did not contain the TNF superfamily cytokines TRAIL or TWEAK. However, exosome-like vesicles contained osteoprotegerin (OPG), a TNF receptor superfamily protein, as assessed by Western blot, ELISA or selected reaction monitoring by nLC-(QQQ)MS/MS. Twenty-one additional proteins were identified in tubular cell exosome-like vesicles, including one (vitamin D binding protein) that had not been previously reported in exosome-like vesicles. Twelve were extracellular matrix proteins, including the basement membrane proteins type IV collagen, nidogen-1, agrin and fibulin-1. Urine from chronic kidney disease patients contained a higher amount of exosomal protein and exosomal OPG than urine from healthy volunteers. Specifically OPG was increased in autosomal dominant polycystic kidney disease urinary exosome-like vesicles and expressed by cystic epithelium in vivo. In conclusion, OPG is present in exosome-like vesicles secreted by proximal tubular epithelial cells and isolated from Chronic Kidney Disease urine.

A nanoconjugate Apaf-1 inhibitor protects mesothelial cells from cytokine-induced injury.

BACKGROUND: Inflammation may lead to tissue injury. We have studied the modulation of inflammatory milieu-induced tissue injury, as exemplified by the mesothelium. Peritoneal dialysis is complicated by peritonitis episodes that cause loss of mesothelium. Proinflammatory cytokines are increased in the peritoneal cavity during peritonitis episodes. However there is scarce information on the modulation of cell death by combinations of cytokines and on the therapeutic targets to prevent desmesothelization. METHODOLOGY: Human mesothelial cells were cultured from effluents of stable peritoneal dialysis patients and from omentum of non-dialysis patients. Mesothelial cell death was studied in mice with S. aureus peritonitis and in mice injected with tumor necrosis factor alpha and interferon gamma. Tumor necrosis factor alpha and interferon gamma alone do not induce apoptosis in cultured mesothelial cells. By contrast, the cytokine combination increased the rate of apoptosis 2 to 3-fold over control. Cell death was associated with the activation of caspases and a pancaspase inhibitor prevented apoptosis. Specific caspase-8 and caspase-3 inhibitors were similarly effective. Co-incubation with both cytokines also impaired mesothelial wound healing in an in vitro model. However, inhibition of caspases did not improve wound healing and even impaired the long-term recovery from injury. By contrast, a polymeric nanoconjugate Apaf-1 inhibitor protected from apoptosis and allowed wound healing and long-term recovery. The Apaf-1 inhibitor also protected mesothelial cells from inflammation-induced injury in vivo in mice. CONCLUSION: Cooperation between tumor necrosis factor alpha and interferon gamma contributes to mesothelial injury and impairs the regenerative capacity of the monolayer. Caspase inhibition attenuates mesothelial cell apoptosis but does not facilitate regeneration. A drug targeting Apaf-1 allows protection from apoptosis as well as regeneration in the course of inflammation-induced tissue injury.

Taming apoptosis in peritoneal dialysis.

Excessive, insufficient, or untimely apoptosis may result in disorders of cell numbers. Peritoneal demesothelization is an example of disease by decreased cell number; untimely leukocyte apoptosis impairs peritoneal defense. Conventional peritoneal dialysis solutions accelerate neutrophil apoptosis. Glucose degradation products such as 3,4-dideoxyglucosone-3-ene (3,4-DGE) decisively contribute to apoptosis induced by these solutions, in both leukocytes and mesothelial cells and in both culture and peritoneal dialysis patients. Pan-caspase inhibition retards neutrophil apoptosis and improves peritoneal clearance of Staphylococcus aureus in animal models. However, regulation of apoptosis in mesothelial cells is more complex than in leukocytes, and caspase inhibitors may not be the optimal drugs to modulate apoptosis in these cells. In this regard, Bax antagonistic peptides protect mesothelial cells from 3,4-DGE. In addition, novel molecular targets have been identified. Short-term modulation of apoptosis may be useful to accelerate recovery and to prevent irreversible peritoneal injury following peritonitis.

Bcl-xL prevents peritoneal dialysis solution-induced leukocyte apoptosis.

Conventional glucose-containing peritoneal dialysis solutions (PDS) with a high glucose degradation product content accelerate leukocyte apoptosis and impair peritoneal defense. Mononuclear cells are less sensitive than neutrophils to PDS-induced apoptosis, suggesting that they may express antiapoptotic molecules. Since apoptosis induced by PDS requires Bax, we explored the role of an antiapoptotic protein of the same family, Bcl-xL, in PDS-induced apoptosis in cultured peripheral blood mononuclear cells and monocytic THP-1 cells. In these cells, conventional PDS decreased the expression of Bcl-xL protein with a temporal pattern compatible with their lethal effect. Inhibition of Bcl-xL also induced mononuclear cell apoptosis. A cell-permeable TAT-BH4 peptide that contains the BH4 domain of Bcl-xL prevented mononuclear cell apoptosis induced by PDS. These data suggest that Bcl-xL protects mononuclear cells from apoptosis induced by bioincompatible PDS and that Bcl-xL-like molecules should be explored to prolong leukocyte survival and potentiate peritoneal defense during peritonitis.