Sandra Müller-Krebs

Cytoprotective signaling by activated protein C requires protease activated receptor-3 in podocytes

The cytoprotective effects of activated protein C (aPC) are well established. In contrast, the receptors and signaling mechanism through which aPC conveys cytoprotection in various cell types remain incompletely defined. Thus, within the renal glomeruli, aPC preserves endothelial cells via a protease-activated receptor-1 (PAR-1) and endothelial protein C receptor-dependent mechanism. Conversely, the signaling mechanism through which aPC protects podocytes remains unknown. While exploring the latter, we identified a novel aPC/PAR-dependent cytoprotective signaling mechanism. In podocytes, aPC inhibits apoptosis through proteolytic activation of PAR-3 independent of endothelial protein C receptor. PAR-3 is not signaling competent itself as it requires aPC-induced heterodimerization with PAR-2 (human podocytes) or PAR-1 (mouse podocytes). This cytoprotective signaling mechanism depends on caveolin-1 dephosphorylation. In vivo aPC protects against lipopolysaccharide-induced podocyte injury and proteinuria. Genetic deletion of PAR-3 impairs the nephroprotective effect of aPC, demonstrating the crucial role of PAR-3 for aPC-dependent podocyte protection. This novel, aPC-mediated interaction of PARs demonstrates the plasticity and cell-specificity of cytoprotective aPC signaling. The evidence of specific, dynamic signaling complexes underlying aPC-mediated cytoprotection may allow the design of cell type specific targeted therapies.

Pharmacokinetic and pharmacodynamic analysis of enteric-coated mycophenolate sodium: limited sampling strategies and clinical outcome in renal transplant patients

AIMS Pharmacokinetic (PK) and pharmacodynamic (PD) monitoring strategies and clinical outcome were evaluated in enteric-coated mycophenolate sodium (EC-MPS)-treated renal allograft recipients. METHODS PK [mycophenolic acid (MPA)] and PD [inosine monophosphate dehydrogenase (IMPDH) activity] data were analysed in 66 EC-MPS and ciclosporin A (CsA)-treated renal allograft recipients. Adverse events were considered in a follow-up period of 12 weeks. RESULTS Analyses confirmed a limited sampling strategy (LSS) consisting of PK and PD data at predose, 1, 2, 3 and 4 h after oral intake as an appropriate sampling method (MPA r(2)= 0.812; IMPDH r(2)= 0.833). MPA AUC(0-12) of patients with early biopsy-proven acute rejection was significantly lower compared with patients without a rejection (median MPA AUC(0-12) 28 microg*h ml(-1) (7-45) vs. 40 microg*h ml(-1) (16-130), P < 0.01), MPA AUC(0-12) of patients with recurrent infections was significantly higher compared with patients without infections (median MPA AUC(0-12) 65 microg*h ml(-1) (range 37-130) vs. 37 microg*h ml(-1) (range 7-120), P < 0.005). Low 12-h IMPDH enzyme activity curve (AEC(0-12)) was associated with an increased frequency of gastrointestinal side-effects (median IMPDH AEC(0-12) 43 nmol*h mg(-1) protein h(-1)[range 12-67) vs. 75 nmol*h mg(-1) protein h(-1) (range 15-371), P < 0.01]. CONCLUSIONS Despite highly variable absorption data, an appropriate LSS might be estimated by MPA AUC(0-4) and IMPDH AEC(0-4) in renal transplant patients treated with EC-MPS and CsA. Regarding adverse events, the suggested MPA-target AUC(0-12) from 30 to 60 microg*h ml(-1) seems to be appropriate in renal allograft recipients.

Benfotiamine Protects against Peritoneal and Kidney Damage in Peritoneal Dialysis

Residual renal function and the integrity of the peritoneal membrane contribute to morbidity and mortality among patients treated with peritoneal dialysis. Glucose and its degradation products likely contribute to the deterioration of the remnant kidney and damage to the peritoneum. Benfotiamine decreases glucose-induced tissue damage, suggesting the potential for benefit in peritoneal dialysis. Here, in a model of peritoneal dialysis in uremic rats, treatment with benfotiamine decreased peritoneal fibrosis, markers of inflammation, and neovascularization, resulting in improved characteristics of peritoneal transport. Furthermore, rats treated with benfotiamine exhibited lower expression of advanced glycation endproducts and their receptor in the peritoneum and the kidney, reduced glomerular and tubulointerstitial damage, and less albuminuria. Increased activity of transketolase in tissue and blood contributed to the protective effects of benfotiamine. In primary human peritoneal mesothelial cells, the addition of benfotiamine led to enhanced transketolase activity and decreased expression of advanced glycation endproducts and their receptor. Taken together, these data suggest that benfotiamine protects the peritoneal membrane and remnant kidney in a rat model of peritoneal dialysis and uremia.

Low but sustained coagulation activation ameliorates glucose induced podocyte apoptosis: protective effect of factor V Leiden in diabetic nephropathy

Whereas it is generally perceived to be harmful, enhanced coagulation activation can also convey salutary effects. The high prevalence of the prothrombotic factor V Leiden (FVL) mutation in whites has been attributed to a positive selection pressure (eg, resulting from reduced blood loss or improved survival in sepsis). The consequences of enhanced coagulation activation, as observed in FVL carriers, on microvascular diabetic complications remain unknown. We therefore investigated the role of FVL in diabetic nephropathy. In heterozygous or homozygous diabetic FVL mice, albuminuria and indices of diabetic nephropathy were reduced compared with diabetic wild-type mice. This was associated with reduced glomerular apoptosis and preservation of podocytes in diabetic FVL-positive mice. In vitro, low-dose thrombin (50pM) prevented, whereas high-dose thrombin (20nM) aggravated, glucose-induced apoptosis in podocytes. In diabetic patients, the FVL mutation, but not the plasminogen activator inhibitor-1 4G/5G polymorphism, is associated with reduced albuminuria, which is consistent with a nephroprotective role of low but sustained thrombin generation. Consistently, anticoagulation of diabetic FVL-positive mice with hirudin abolished the nephroprotective effect. These results identify a nephroprotective function of low but sustained thrombin levels in FVL carriers, supporting a dual, context-dependent function of thrombin in chronic diseases.

Renal toxicity mediated by glucose degradation products in a rat model of advanced renal failure

Background  In peritoneal dialysis (PD) residual renal function contributes to improved patient survival and quality of life. Glucose degradation products (GDP) generated by heat sterilization of PD fluids do not only impair the peritoneal membrane, but also appear in the systemic circulation with the potential for organ toxicity. Here we show that in a rat model of advanced renal failure, GDP affect the structure and function of the remnant kidney.

RAGE expression in the human peritoneal membrane

BACKGROUND Experimental animal models have demonstrated that the interaction of advanced glycation end-products (AGE) with their receptor RAGE is, at least in part, responsible for peritoneal damage. This study investigates the in vivo expression of RAGE in the peritoneal membrane of uraemic human patients. METHODS Peritoneal biopsies of 89 subjects (48 uraemic and 41 healthy age-matched patients) were examined. The expression of CD3, IL-6, activated NFkappaBp65, VEGF, transforming growth factor (TGF)-beta1, smooth-muscle actin (SMA), methylglyoxal (MGO) and RAGE was analysed immunohistochemically. Additionally, in 4 of the 48 uraemic patients, peritoneal biopsies were repeated after 15 months at the time of catheter removal to analyse the above parameters and the extent of NFkappaB-binding activity determined by electrophoretic mobility shift assay (EMSA) in the long-term follow-up. RESULTS In comparison to the healthy controls, uraemic patients showed a significant increase in fibrosis, angiogenesis, submesothelial thickness, MGO-derived protein adducts, RAGE, IL-6, VEGF, TGF-beta1, SMA and NFkappaBp65 in their peritonea. Four patients, followed up longitudinally from peritoneal dialysis (PD) catheter insertion to removal, demonstrated further significant increase in the above parameters, particularly in RAGE expression and NFkappaB activation. CONCLUSIONS Along with a higher expression of several indicators for inflammation, angiogenesis, fibrosis and AGE accumulation, the peritoneal membrane of the uraemic patients showed an increased submesothelial thickness and a marked induction of RAGE expression and NFkappaB-binding activity, which both further increased after PD treatment. These findings in human peritoneum support the concept of the AGE-RAGE interaction being crucial in peritoneal damage due to uraemia and PD.

Cellular Effects of Everolimus and Sirolimus on Podocytes

Everolimus (EVL) and Sirolimus (SRL) are potent immunosuppressant agents belonging to the group of mammalian target of rapamycin (mTOR) inhibitors used to prevent transplant rejection. However, some patients develop proteinuria following a switch from a calcineurin inhibitor regimen to mTOR inhibitors. Whether different mTOR inhibitors show similar effects on podocytes is still unknown. To analyze this, human podocytes were incubated with different doses of EVL and SRL. After incubation with EVL or SRL, podocytes revealed a reduced expression of total mTOR. Phosphorylation of p70S6K and Akt was diminished, whereas pAkt expression was more reduced in the SRL group. In both groups actin cytoskeletal reorganization was increased. Synaptopodin and podocin expression was reduced as well as nephrin protein, particularly in the SRL group. NFκB activation and IL-6 levels were lower in EVL and SRL, and even lower in SRL. Apoptosis was more increased in SRL than in the EVL group. Our data suggests that mTOR inhibitors affect podocyte integrity with respect to podocyte proteins, cytoskeleton, inflammation, and apoptosis. Our study is the first to analyze both mTOR inhibitors, EVL and SRL, in parallel in podocytes. Partially, the impact of EVL and SRL on podocytes differs. Nevertheless, it still remains unclear whether these differences are of relevance regarding to proteinuria in transplant patients.

Human RAGE antibody protects against AGE-mediated podocyte dysfunction

BACKGROUND Residual renal function (RRF) contributes to better patient survival in peritoneal dialysis (PD). It is known that glucose degradation products (GDP) and advanced glycation end-products (AGE) resorbed from the peritoneal cavity do not only cause local peritoneal toxicity but also systemic damage resulting in a loss of RRF. We hypothesize that GDP and AGE affect the structure and function of podocytes and investigate whether these effects can be rescued by human RAGE antibody (hRAGEab) to prevent AGE/RAGE interaction and podocyte damage. METHODS Differentiated human podocytes were pre-incubated with ±hRAGEab to block the AGE/RAGE interaction and incubated afterwards either with control solution (control), PD fluid (PDF) or a GDP mixture (GDP) for 48 h. We analysed podocyte damage and rescue by hRAGEab using immunofluorescence, western blot, enzyme-linked immunosorbent assay and a functional migration assay. For quantitation, a semiquantitative score was used. RESULTS When pre-incubating podocytes with hRAGEab, damage mediated by PDF and GDP was reduced. We observed lower expression of AGE in PDF and GDP as well as decreased levels of inflammation as shown by activation of nuclear factor kappa B and interleukin-6 release. The reorganization of the podocyte actin cytoskeleton was reduced in the presence of hRAGEab as well as ameliorated synaptopodin expression could be observed, both functionally associated with normal podocyte motility. Finally, podocytes underwent less apoptosis. CONCLUSIONS It has been investigated that GDP-containing PDF causes a loss of RRF in PD. Our findings suggest that hRAGEab confers protection against PDF- and GDP-induced podocyte dysfunction. Blocking the AGE/RAGE interaction provides specific protective effects against PDF- and GDP-induced cytoskeletal reorganization, dynamics and stabilizes podocyte survival; this might be an implication for the preservation of RRF in PD.

GLUCOSE DEGRADATION PRODUCTS RESULT IN CARDIOVASCULAR TOXICITY IN A RAT MODEL OF RENAL FAILURE

♦ Background: It has been shown that glucose degradation products (GDP) generated during heat sterilization of peritoneal dialysis (PD) fluids impair the peritoneal membrane locally, then enter the systemic circulation and cause damage to the remnant kidney. Here we examined in subtotally nephrectomized (SNX) rats whether GDP also affect the cardiovascular system. ♦ Materials and Methods: Standard 5/6 nephrectomy was carried out in Sprague–Dawley rats; other rats were sham operated and left untreated for 3 weeks. Through an osmotic mini-pump, SNX+GDP group received GDP intravenously for 4 weeks; the SNX and the sham-operated groups remained without GDP. The experiment was terminated for all groups 7 weeks postoperatively. We analyzed cardiovascular damage by serum analyses and immunohistochemical investigation. ♦ Results: In SNX+GDP animals, expression of the advanced glycation end product (AGE) marker carboxymethyllysine and receptor of AGE (RAGE) were significantly higher in the myocardium and the aorta compared to the SNX rats. We also found significantly higher levels of apoptosis measured by caspase 3 staining in the cardiovascular system in the SNX+GDP group. Moreover, we observed a more pronounced expression of oxidative stress in the SNX+GDP rats compared to the SNX rats. In serum analyses, advanced oxidation protein products and reactive oxygen species were increased, as was immunohistochemical endothelial nitric oxide synthase. ♦ Conclusions: In addition to local toxic effects, GDP cause systemic toxicity. Here we showed that, in SNX rats, administration of GDP increased cardiovascular damage. In particular, we found increased levels of AGE, RAGE, oxidative stress, and apoptosis. Whether these findings are of clinical relevance has to be further investigated.

Dual regulation of renal Kir7.1 potassium channels by protein Kinase A and protein Kinase C.

The renal inward rectifier potassium channel Kir7.1 has been proposed to be functionally important for tubular K(+) recycling and secretion. This study investigated the regulation of Kir7.1 by PKA and PKC. Cloned human Kir7.1 channels were expressed heterologously in Xenopus oocytes. After pharmacological PKC activation, Kir7.1 currents were strongly inhibited. Co-application of PKC inhibitors attenuated this effect. Inactivation of PKC consensus sites also strongly attenuated the effect with a single site ((201)S) being essential for almost the total PKC sensitivity. In contrast, PKA activation induced an increase of Kir7.1 currents. This effect was absent in mutant Kir7.1 channels lacking PKA consensus site (287)S. In summary, this study demonstrates the dual regulation of Kir7.1 channel function by PKA and PKC. Structurally, these regulations depend on two key residues in the C-terminal channel domain ((Ser)201 for PKC and (Ser)287 for PKA).