Antonia Loverre

Rapamycin for Treatment of Chronic Allograft Nephropathy in Renal Transplant Patients

Chronic allograft nephropathy (CAN) represents the main cause of renal allograft loss after 1 yr of transplantation. Calcineurin inhibitor (CNI) use is associated with increased graft expression of profibrotic cytokines, whereas rapamycin inhibits fibroblast proliferation. The aim of this randomized, prospective, open-label, single-center study was to evaluate the histologic and clinical effect of rapamycin on biopsy-proven CAN. Eighty-four consecutive patients who had biopsy-proven CAN and received a transplant were randomized to receive either a 40% CNI reduction plus mycophenolate mofetil (group 1; 50 patients) or immediate CNI withdrawal and rapamycin introduction with a loading dose of 0.1 mg/kg per d and a maintaining dose aiming at through levels of 6 to 10 ng/ml (group 2; 34 patients). The follow-up period was 24 mo. At the end of follow-up, 25 patients (group 1, 10 patients; group 2, 15 patients) underwent a second biopsy. CAN lesions were graded according to Banff criteria. alpha-Smooth muscle actin (alpha-SMA) protein expression was evaluated in all biopsies as a marker of fibroblast activation. Graft function and Banff grading were superimposable at randomization. Graft survival was significantly better in group 2 (P = 0.0376, chi2 = 4.323). CAN grading worsened significantly in group 1, whereas it remained stable in group 2. After 24 mo, all group 1 biopsies showed an increase of alpha-SMA expression at the interstitial and vascular levels (P < 0.001); on the contrary, alpha-SMA expression was dramatically reduced in group 2 biopsies (P = 0.005). This study demonstrates that rapamycin introduction/CNI withdrawal improves graft survival and reduces interstitial and vascular alpha-SMA expression, slowing down the progression of allograft injury in patients with CAN.

Therapeutic Targeting of Classical and Lectin Pathways of Complement Protects from Ischemia-Reperfusion-Induced Renal Damage

Ischemia-reperfusion injury is the major cause of delayed graft function in transplanted kidneys, an early event significantly affecting long-term graft function and survival. Several studies in rodents suggest that the alternative pathway of the complement system plays a pivotal role in renal ischemia-reperfusion injury. However, limited information is currently available from humans and larger animals. Here we demonstrated that 30 minutes of ischemia resulted in the induction of C4d/C1q, C4d/MLB, and MBL/MASP-2 deposits in a swine model of ischemia-reperfusion injury. The infusion of C1-inhibitor led to a significant reduction in peritubular capillary and glomerular C4d and C5b-9 deposition. Moreover, complement-inhibiting treatment significantly reduced the numbers of infiltrating CD163(+), SWC3a(+), CD4a(+), and CD8a(+) cells. C1-inhibitor administration led to significant inhibition of tubular damage and tubular epithelial cells apoptosis. Interestingly, we report that focal C4d-deposition colocalizes with C1q and MBL at the peritubular and glomerular capillary levels also in patients with delayed graft function. In conclusion, we demonstrated the activation and a pathogenic role of classical and lectin pathways of complement in a swine model of ischemia-reperfusion-induced renal damage. Therefore, inhibition of these two pathways might represent a novel therapeutic approach in the prevention of delayed graft function in kidney transplant recipients.

TLR2 plays a role in the activation of human resident renal stem/progenitor cells

In the past few years, adult renal progenitor/stem cells (ARPCs) have been identified in human kidneys, and particularly in Bowmans capsule and proximal tubules. They may play an important role in the kidney regenerative processes and might prospectively be the ideal cell type for the treatment of both acute and chronic renal injury. In this study, microarray analysis identified 6 gene clusters that discriminated normal human glomerular and tubular ARPCs from renal proximal tubular epithelial cells and mesenchymal stem cells. The top‐scored pathway in the ARPC gene expression profile contained growth factor receptors and immune system‐related genes, including tolllike receptor 2 (TLR2). Stimulation of TLR2 by ligands that mime inflammatory mediators or damage associated molecular pattern molecules induced secretion of elevated amounts of monocyte chemoattractant protein‐1 (MCP‐1), IL‐6, IL‐8, and C3 via NF‐κB activation. TLR2 stimulation also increased the ARPC proliferation rate, suggesting a role for TLR2 in ARPC activation via autocrine signaling. Moreover, TLR2 stimulation improved ARPC differentiation into renal epithelial cells and was responsible of ARPC branching morphogenesis and tubule‐like structures formation. For the first time, this study provides a genomic characterization of renal multipotent progenitor cells and shows that TLR2 found on ARPCs might be responsible for their activation in the kidney, orchestrating the activation of crucial signaling networks necessary for renal repair.—Sallustio, F., De Benedictis, L., Castellano, G., Zaza, G., Loverre, A., Costantino, V., Grandaliano, G., Schena, F. P. TLR2 plays a role in the activation of human resident renal stem/progenitor cells. FASEB J. 24, 514–525 (2010). www.fasebj.org

Ischemia-Reperfusion Induces Glomerular and Tubular Activation of Proinflammatory and Antiapoptotic Pathways: Differential Modulation by Rapamycin

Ischemia-reperfusion (I-R) injury in transplanted kidney, a key pathogenic event of delayed graft function (DGF), is characterized by tubular cell apoptosis and interstitial inflammation. Akt-mammalian target of rapamycin-S6k and NF-kappaB-inducing kinase (NIK)-NF-kappaB axis are the two main signaling pathways regulating cell survival and inflammation. Rapamycin, an immunosuppressive drug inhibiting the Akt axis, is associated with a prolonged DGF. The aim of this study was to evaluate Akt and NF-kappaB axis activation in patients who had DGF and received or not rapamycin and in a pig model of I-R and the role of coagulation priming in this setting. In graft biopsies from patients who were not receiving rapamycin, phosphorylated Akt increased in proximal tubular, interstitial, and mesangial cells with a clear nuclear translocation. The same pattern of activation was observed for S6k and NIK. However, in rapamycin-treated patients, a significant reduction of S6k but not Akt and NIK activation was observed. A time-dependent activation of phosphatidylinositol 3-kinase, Akt, S6k, and NIK was observed in the experimental model with the same pattern reported for transplant recipients who did not receive rapamycin. Extensive interstitial and glomerular fibrin deposition was observed both in pig kidneys upon reperfusion and in DGF human biopsies. It is interesting that the activation of both Akt and NIK-NF-kappaB pathways was induced by thrombin in cultured proximal tubular cells. In conclusion, the data suggest that (1) coagulation may play a pathogenic role in I-R injury; (2) the Akt axis is activated after I-R, and its inhibition may explain the prolonged DGF observed in rapamycin-treated patients; and (3) NIK activation in I-R and DGF represents a proinflammatory, rapamycin-insensitive signal, potentially leading to progressive graft injury.

Human renal stem/progenitor cells repair tubular epithelial cell injury through TLR2-driven inhibin-A and microvesicle-shuttled decorin

Acute kidney injury (AKI) is emerging as a worldwide public health problem. Recent studies have focused on the possibility of using human adult renal stem/progenitor cells (ARPCs) to improve the repair of AKI. Here we studied the influence of ARPCs on the healing of cisplatin-injured renal proximal tubular epithelial cells. Tubular, but not glomerular, ARPCs provided a protective effect promoting proliferation of surviving tubular cells and inhibiting cisplatin-induced apoptosis. The recovery effect was specific to tubular ARPCs, occurred only after damage sensing, and was completely cancelled by TLR2 blockade on tubular ARPCs. Moreover, tubular, but not glomerular, ARPCs were resistant to the apoptotic effect of cisplatin. Tubular ARPCs operate mainly through the engagement of TLR2, the secretion of inhibin-A protein, and microvesicle-shuttled decorin, inhibin-A, and cyclin D1 mRNAs. These factors worked synergistically and were essential to the repair process. The involvement of tubular ARPC-secreted inhibin-A and decorin mRNA in the pathophysiology of AKI was also confirmed in transplant patients affected by delayed graft function. Hence, identification of this TLR2-driven recovery mechanism may shed light on new therapeutic strategies to promote the recovery capacity of the kidney in acute tubular damage. Use of these components, derived from ARPCs, avoids injecting stem cells.

IL‐17 Expression by Tubular Epithelial Cells in Renal Transplant Recipients with Acute Antibody‐Mediated Rejection

Acute rejection is still a common complication of kidney transplantation. IL‐17 is known to be associated with allograft rejection but the cellular source and the role of this cytokine remains unclear. We investigated IL‐17 graft expression in renal transplant recipients with acute antibody‐mediated rejection (ABMR), acute T‐cell‐mediated rejection (TCMR), interstitial fibrosis and tubular atrophy (IFTA) and acute tubular damage due to calcineurin‐inhibitor toxicity (CNI). In acute ABMR, tubular IL‐17 protein expression was significantly increased compared to TCMR, where most of the IL‐17+cells were CD4+graft infiltrating lymphocytes, IFTA and CNI control groups. The tubular expression of IL‐17 in acute ABMR colocalized with JAK2 phosphorylation and peritubular capillaries C4d deposition. In addition, IL‐17 tubular expression was directly and significantly correlated with the extension of C4d deposits. In cultured proximal tubular cells, C3a induced IL‐17 gene and protein expression along with an increased in JAK2 phosphorylation. The inhibition of JAK2 abolished C3a‐induced IL‐17 expression. The use of steroids and monoclonal antibodies reduced IL‐17 expression, JAK2 phosphorylation and C4d deposition in acute ABMR patients. Our data suggest that tubular cells represent a significant source of IL‐17 in ABMR and this event might be mediated by the complement system activation featuring this condition.

Sirolimus and proteinuria in renal transplant patients: evidence for a dose-dependent effect on slit diaphragm-associated proteins.

Background. The mechanisms underlying the development of proteinuria in renal-transplant recipients converted from calcineurin inhibitors to sirolimus are still unknown. Methods. This is a single-center cohort study. One hundred ten kidney transplant recipients converted from calcineurin inhibitors to sirolimus in the period from September 2000 to December 2005 were included in the study. All patients underwent a graft biopsy before conversion (T0) and a second protocol biopsy 2 years thereafter (T2), according to our standard clinical protocol. On the basis of the changes observed in proteinuria between T0 and T2 (median 70%), the patients were divided into two groups: group I (<70%) and group II (>70%). The authors blinded the sirolimus blood trough levels. We investigated in vivo the effects of sirolimus on nephrin, podocin, CD2ap, and actin protein expression. Slit diaphragm (SD)-associated protein expressions were evaluated in T0 and T2 biopsies. The same analysis was performed in cultured human podocytes treated with different doses of sirolimus (5, 10, 20, and 50 ng/mL). Results. The SD protein expression in group II T2 biopsies was significantly reduced compared with the T0 biopsies and with T2 group I biopsies. In addition, sirolimus blood trough levels directly and significantly correlated with the SD protein expression at T2 graft biopsies. Group II patients presented significantly higher sirolimus blood levels than group I. In vitro study confirmed that sirolimus effect on podocytes was dose dependent. Conclusions. Our data suggest that sirolimus-induced proteinuria may be a dose-dependent effect of the drug on key podocyte structures.

The possible role of ChemR23/Chemerin axis in the recruitment of dendritic cells in lupus nephritis

Dendritic cells (DCs) have a pivotal role in the autoimmune response of systemic lupus erythematosus. Plasmacytoid DCs infiltrate the kidney of patients with lupus nephritis, but factors regulating their recruitment to the kidney are unknown. Chemerin is the recently identified natural ligand of ChemR23, a receptor highly expressed by plasmacytoid DCs. We performed immunohistochemical and immunofluorescence analysis to study the ChemR23/Chemerin axis in renal biopsies from patients with lupus nephritis. We found ChemR23-positive DCs had infiltrated the kidney tubulointerstitium in patients with severe lupus nephritis. Chemerin association with tubular epithelial cells and renal lymphatic endothelial cells was found in patients with lupus nephritis but not in normal kidneys. Proximal tubular epithelial cells produced Chemerin in vitro, which was significantly down-modulated by added tumor necrosis factor (TNF)-α and interferon-γ as measured by quantitative PCR and enzyme-linked immunosorbent assay. Interestingly, TNF-α was capable of inducing a functionally active form of renal Chemerin, resulting in an efficient transendothelial migration of plasmacytoid DCs measured in transwell systems. Thus, the ChemR23/Chemerin axis may have a role in the recruitment of DCs within the kidney in patients affected by lupus nephritis.

Endothelial-to-mesenchymal transition and renal fibrosis in ischaemia/reperfusion injury are mediated by complement anaphylatoxins and Akt pathway

BACKGROUND Increasing evidence demonstrates a phenotypic plasticity of endothelial cells (ECs). Endothelial-to-mesenchymal transition (EndMT) contributes to the development of tissue fibrosis. However, the pathogenic factors and signalling pathways regulating this process in ischaemia/reperfusion (I/R) injury are still poorly understood. METHODS We investigated the possible role of complement in the induction of this endothelial dysfunction in a swine model of renal I/R injury by using recombinant C1 inhibitor in vivo. RESULTS Here, we showed that I/R injury reduced the density of renal peritubular capillaries and induced tissue fibrosis with generation of CD31(+)/α-SMA(+) and CD31(+)/FPS-1(+) cells indicating EndMT. When we inhibited complement, the process of EndMT became rare, with preserved density of peritubular capillaries and significant reduction in renal fibrosis. When we activated ECs by anaphylatoxins in vitro, C3a and C5a led to altered endothelial phenotype with increased expression of fibroblast markers and decrease expression of specific endothelial markers. The activation of Akt pathway was pivotal for the C3a and C5a-induced EndMT in vitro. In accordance, inhibition of complement in vivo led to the abrogation of Akt signalling, with hampered EndMT and tissue fibrosis. CONCLUSIONS Our data demonstrate a critical role for complement in the acute induction of EndMT via the Akt pathway. Therapeutic inhibition of these systems may be essential to prevent vascular damage and tissue fibrosis in transplanted kidney.

Increase of Proliferating Renal Progenitor Cells in Acute Tubular Necrosis Underlying Delayed Graft Function

Background. Delayed graft function (DGF) is associated with acute tubular necrosis. In this setting, surviving tubular cells may proliferate and replace injured cells. CD133+Pax-2+cells may play a role in the regeneration of tubular damage. The aim of this study was to demonstrate the presence of these cells in human kidneys before transplantation and in grafts with DGF. Methods. Ten normal kidneys (group 1) and pretransplant biopsy of 25 deceased donors (group 2) were examined. The latter group included 10 kidneys with early graft function (2A) and 15 with DGF (2B). Group 2B patients received a second biopsy during DGF (2C). CD133, Pax-2, and Ki-67 protein expression was investigated by confocal microscopy. Results. CD133+Pax-2+ and CD133−Pax-2+cells were present within the Bowman’s capsule and proximal tubules in all groups except group 2B. Number of CD133+Pax-2+ and CD133−Pax-2+cells at tubular level was similar in groups 1 and 2A. Within group 2B we observed a striking reduction in both cell types. There was a significant increase of both cell populations within group 2C, compared with group 2B. CD133+Pax-2+ and CD133−Pax-2+cell number in group 2 correlated inversely with cold ischemia time. Pax-2+Ki-67+cells were absent from group 1 and 2B samples, and increased significantly in groups 2A and 2C. Proliferating CD133+ cells increased significantly in group 2C. Conclusions. Our data suggest that regenerative response in posttransplant acute tubular necrosis, underlying DGF, is characterized by an increase in proliferating renal progenitor/stem cells CD133+Pax-2+ and CD133−Pax-2+ cells involved in repairing tubular damage.