Juan Torras

Postischemic renal oxidative stress induces inflammatory response through PAF and oxidized phospholipids. Prevention by antioxidant treatment

Reperfusion injury is considered primarily an inflammatory response to oxidative stress. In vitro, oxygen free radicals induce the formation of oxidized phospholipids with platelet‐activating factor (PAF) activity (PAF‐like lipids). We examined the following: 1) whether PAF and PAF‐like lipids are released during reperfusion; 2) the relationship between these phospholipids and oxidative damage on the one hand, and leukocyte recruitment in renal tissue on the other; and 3) whether antioxidant treatment influences the behavior of these phospholipids, the renal inflammatory response, and the outcome of postischemic acute renal failure. After 60 min of warm renal ischemia in rabbits, a release of PAF and, particularly, PAF‐like lipids was seen in the first 15 min of reperfusion. In addition, the release of those phospholipids was associated with intense tissue DNA oxidation and with an increase in myeloperoxidase activity. Vitamin C was able to attenuate these postischemic oxidative changes, decrease PAF and PAF‐like lipid levels, and, consequently, reduce myeloperoxidase activity. After 40 min of warm renal ischemia in rats, vitamin C treatment ameliorated renal function and structure. This is the first in vivo demonstration of the release of phospholipid oxidation products as part of an oxidative‐inflammatory response after renal ischemia‐reperfusion, with the release of phospholipid oxidation products significantly reduced by antioxidant treatment.

Rapamycin has dual opposing effects on proteinuric experimental nephropathies: is it a matter of podocyte damage?

BACKGROUND In clinical renal transplantation, an increase in proteinuria after conversion from calcineurin inhibitors to rapamycin has been reported. In contrast, there are studies showing a nephro-protective effect of rapamycin in proteinuric diseases characterized by progressive interstitial inflammatory fibrosis. METHODS Because of the contradictory reports concerning rapamycin on proteinuria, we examined proteinuria and podocyte damage markers on two renal disease models, with clearly different pathophysiological mechanisms: a glomerular toxico-immunological model induced by puromycin aminonucleoside, and a chronic hyperfiltration and inflammatory model by mass reduction, both treated with a fixed high rapamycin dose. RESULTS In puromycin groups, rapamycin provoked significant increases in proteinuria, together with a significant fall in podocin immunofluorescence, as well as clear additional damage to podocyte foot processes. Conversely, after mass reduction, rapamycin produced lower levels of proteinuria and amelioration of inflammatory and pro-fibrotic damage. In contrast to the puromycin model, higher glomerular podocin and nephrin expression and amelioration of glomerular ultrastructural damage were found. CONCLUSIONS We conclude that rapamycin has dual opposing effects on subjacent renal lesion, with proteinuria and podocyte damage aggravation in the glomerular model and a nephro-protective effect in the chronic inflammatory tubulointerstitial model. Rapamycin produces slight alterations in podocyte structure when acting on healthy podocytes, but it clearly worsens those podocytes damaged by other concomitant injury.

Influence of MRP2 on MPA pharmacokinetics in renal transplant recipients–results of the Pharmacogenomic Substudy within the Symphony Study

BACKGROUND The aim of this study was to determine the relationship between single-nucleotide polymorphisms (SNPs) in MRP2 genes and mycophenolic acid (MPA) pharmacokinetics in renal transplant recipients of the Symphony Pharmacogenomic substudy. METHODS Sixty-six renal transplant recipients of eight Spanish centres were randomized into four branches of immunosuppressive regimen: low dose of cyclosporine, standard dose of cyclosporine, tacrolimus and sirolimus, all in addition to mycophenolate mofetil and steroids. Fifty-five patients were genotyped for SNPs in MRP2, C24T and C3972T. Pharmacokinetic sampling was done before MPA administration and up to 12 h post-dose at Day 7, 1 month and 3 months post-transplant. Relationships of area under the curve (AUC) of MPA and MPAG plasma sampling with the presence of MRP2 SNPs and with the immunosuppressive regimens were studied. RESULTS At steady-state conditions, MPA-reduced exposure was observed in C24T variant allele in MRP2 (CC: 68.73 ± 6.78; *T: 48.12 ± 4.90, P = 0.023); no significant differences linked to C3972T SNP were observed. Taking into account groups of treatment, lower MPA AUC in variant allele of C24T was only found under macrolides treatment with statistically significant differences at Month 3 (Tac and SRL, CC: 86.52 ± 10.98 versus *T: 41.99 ± 4.82, P = 0.001; CsA, CC: 52.31 ± 5.30 versus *T: 54.24 ± 8.30, P = 0.772); for C3972T, the same tendency was found but differences at steady state did not reach statistical significance. CONCLUSIONS Renal transplant recipients T carriers of C24T MRP2 with macrolides treatment were associated with reduced MPA AUC in steady-state conditions. Patients treated with cyclosporine lost the effect of this polymorphism.

CD40 gene silencing reduces the progression of experimental lupus nephritis modulating local milieu and systemic mechanisms.

Lupus nephritis (LN) is an autoimmune disorder in which co-stimulatory signals have been involved. Here we tested a cholesterol-conjugated-anti-CD40-siRNA in dendritic cells (DC) in vitro and in a model of LPS to check its potency and tissue distribution. Then, we report the effects of Chol-siRNA in an experimental model of mice with established lupus nephritis. Our in vitro studies in DC show a 100%intracellular delivery of Chol-siRNA, with a significant reduction in CD40 after LPS stimuli. In vivo in ICR mice, the CD40-mRNA suppressive effects of our Chol-siRNA on renal tissue were remarkably sustained over a 5 days after a single preliminary dose of Chol-siRNA. The intra-peritoneal administration of Chol-siRNA to NZB/WF1 mice resulted in a reduction of anti-DNA antibody titers, and histopathological renal scores as compared to untreated animals. The higher dose of Chol-siRNA prevented the progression of proteinuria as effectively as cyclophosphamide, whereas the lower dose was as effective as CTLA4. Chol-siRNA markedly reduced insterstitialCD3+ and plasma cell infiltrates as well as glomerular deposits of IgG and C3. Circulating soluble CD40 and activated splenic lymphocyte subsets were also strikingly reduced by Chol-siRNA. Our data show the potency of our compound for the therapeutic use of anti-CD40-siRNA in human LN and other autoimmune disorders.

CD154-CD40 T-cell co-stimulation pathway is a key mechanism in kidney ischemia-reperfusion injury

Ischemia-reperfusion occurs in a great many clinical settings and contributes to organ failure or dysfunction. CD154-CD40 signaling in leukocyte–endothelial cell interactions or T-cell activation facilitates tissue inflammation and injury. Here we tested a siRNA anti-CD40 in rodent warm and cold ischemia models to check the therapeutic efficacy and anti-inflammatory outcome of in vivo gene silencing. In the warm ischemia model different doses were used, resulting in clear renal function improvement and a structural renoprotective effect. Renal ischemia activated the CD40 gene and protein expression, which was inhibited by intravenous siRNA administration. CD40 gene silencing improved renal inflammatory status, as seen by the reduction of CD68 and CD3 T-cell infiltrates, attenuated pro-inflammatory, and enhanced anti-inflammatory mediators. Furthermore, siRNA administration decreased a spleen pro-inflammatory monocyte subset and reduced TNFα secretion by splenic T cells. In the cold ischemia model with syngeneic and allogeneic renal transplantation, the most effective dose induced similar functional and structural renoprotective effects. Our data show the efficacy of our siRNA in modulating both the local and the systemic inflammatory milieu after an ischemic insult. Thus, CD40 silencing could emerge as a novel therapeutic strategy in solid organ transplantation.

Online haemodiafiltration improves inflammatory state in dialysis patients: A longitudinal study

Background Patients undergoing conventional hemodialysis (C-HD) present a greater immuno-inflammatory state probably related to uremia, sympathetic nervous system (SNS) activation and /or membrane bioincompatibility, which could improve with a technique-switching to online hemodiafiltration (OL-HD). The antigen-independent pathway activation of this modified immunologic state turns dendritic cells (DC) into an accurate cell model to study these patients. The aim of this study is to further evaluate the immune-inflammatory state of patients in C-HD assessed by DC maturation. Methods 31 patients were submitted to C-HD and after 4 months switched to the OL-HD technique. Monocytes-derived DCs from HD patients were cultured in the presence of IL-4/GM-CSF. DC-maturation was evaluated by assessing the maturation phenotype by flow cytometry (FACs). DCs-functional capacity to elicit T-cell alloresponse was studied by mixed leucocyte reaction. Cytokine release was assessed by FACs and SNS was evaluated measuring renalase levels by ELISA. Results An up-regulation of maturation markers was observed in C-HD DCs which induced two fold more T cells proliferation than OL-HD DCs. Also, C-HD-mDCs presented with over-production of pro-inflammatory cytokines (IL-6, IL-1β, IL-8, IL-10 and TNF-α) compared with OL-HD-mDC (P<0·05). Results were correlated with clinical data. When SNS was evaluated, hypotension events and blood pressure were significantly lower and renalase levels were significantly higher after conversion to OL-HD. Diabetes mellitus type 2 patients also found beneficial reduction of mDC when converted to OL-HD compared to non-diabetics. Conclusions OL-HD could interfere with immuno-inflammatory state in HD patients with an improvement of renalase levels as potential key mediators in the mechanistic pathway of down-regulation of DC maturation.

Cold ischaemia, innate immunity and deterioration of the glomerular filtration barrier in antibody-mediated acute rejection

BACKGROUND In renal transplantation, cold ischaemia (CI) determines acute rejection through innate immunity among others. Acute rejection episodes are a risk factor for late allograft dysfunction and proteinuria. This implies some alteration of the glomerular filtration barrier (GFB). Besides its effects on acute rejection, we hypothesized that CI might somehow damage the GFB being directly responsible for late proteinuria. METHODS On rat kidney allografts suffering from antibody-mediated acute rejection with or without CI and compared with syngeneic grafts, we quantified the gene expression of innate and adaptive immune mediators and assessed the capillary glomerular basement membranes (CapBM) by immunostaining collagen-IV (ColIV). ColIV was also assessed in equivalent groups from a previous chronic study followed up for 24 weeks. RESULTS CI up-regulated enzymes critical in the stabilization of collagen chains, increasing ColIV deposition and thickening the CapBM. CI increased the C4d and IgG deposits within grafts, amplified innate immunity (heat shock protein 70, fibronectin, Toll-like-receptor-4 and MyD88) and synergized with alloreactivity in triggering adaptive response through CD40. CONCLUSIONS Initial CI increased the ColIV deposition in CapBM, damaging the GFB and being responsible for part of the proteinuria associated with late allograft dysfunction. This deterioration of the GFB is related to the early innate immunity activation and subsequent up-regulation of CD40 in acute rejected grafts. In chronic rejected allografts, thickened CapBM may be a consequence of an unresolved immune-inflammatory response worsened by CI.

Gene Therapy for Acute Renal Failure

Thanks to the progressive understanding of the cellular and molecular basis of renal function and disease, during the next several decades new therapeutic approaches to a wide range of kidney disorders, including acute renal failure (ARF), will be developed. In this regard, the repair of ischemic and toxic ARF is critically dependent on a redundant, interactive cytokine and growth factors network to return kidney function to near-normal baseline function. A newer strategy in biotechnology is the development of recombinant genetic engineered compounds and, recently, cell therapy derivatives. Gene therapy offers a novel approach for prevention and treatment of renal diseases. Technical advances in viral vector systems and the development of fusigenic liposome vectors have been crucial to the progress of effective gene therapy strategies directed at renal structures in animal models. Many investigations have provided experimental models for gene delivery systems but the most efficient renal gene transfer was obtained from intrarenal injection or perfusion of explanted kidneys in transplantation. Continued technologic advances in vector systems and promising results in human and animal gene transfer studies make the use of gene therapy an encouraging strategy. Cell therapy, a tool for gene therapy, is based on the ability to expand specific cells in tissue culture to perform differentiated tasks and to introduce these cells into the patient either in extracorporeal circuits or as implants as drug delivery vehicles of a single protein or to provide physiological functions. These new approaches may result in therapeutic modalities that diminish the degree of renal failure and the time needed to recover renal function in acute tubular necrosis. This article specifically examines the present prospects of gene developing therapies in the treatment of ARF.

RNAi-Based Therapy in Experimental Ischemia-Reperfusion Injury. The New Targets

BACKGROUND Ischemia reperfusion injury is an important pathophysiological process in many fields such as transplantation, stroke, atherosclerosis, trauma and myocardial infarction. Recent advances in gene silencing may help to reduce ischemic effects, targeting molecules related to this pathological process. METHODS AND RESULTS Here, we review the different silencing approaches in ischemic injury, highlighting the role of co-stimulatory molecules in renal transplantation. CONCLUSION Gene silencing appears as a new strategy to prevent the inflammation and injury associated with ischemia.

New approaches for the treatment of lupus nephritis in the 21st century: from the laboratory to the clinic.

Systemic lupus erythematosus is a complex autoimmune disorder affecting multiple organ systems. Glomerulonephritis leading to severe proteinuria, chronic renal failure and end-stage renal disease remains one of the most severe complications of systemic lupus erythematosus and is associated with significant morbidity and mortality. Conventional lupus nephritis (LN) treatment based on cyclophosphamide, steroids and, recently, mycophenolatemofetil has improved the outcome of the disease over the last 50 years, although failure to achieve remission or treatment resistance has been reported in 18-57% of patients. Chronic complications such as long-term toxicity dampen their ability to maintain disease remission. There is a need to develop more specific pharmacological agents for patients to provide choices that are equally effective, less toxic and have fewer complications. During the last 10 years, experimental studies based on different pathogenesis pathways of LN have provided an enormous amount of knowledge and have offered the possibility to target the disease with selective approaches. In this article, we summarize the new experimental strategies that have recently been utilized to target LN, focusing on mechanisms of action.