Development of initial idiopathic nephrotic syndrome and post-transplantation recurrence: evidence of the same biological entity.

BACKGROUND: Buffalo/Mna rats spontaneously develop a nephrotic syndrome (NS). We have demonstrated that this rat nephropathy recurs after renal transplantation. We studied this recurrence by kinetic analysis of graft lesions, infiltrating cells and cytokines. METHODS: Kidneys from LEW.1 W rats were grafted into proteinuric Buff/Mna or healthy Wistar Furth recipients. Kidney samples were harvested before, during and after the occurrence of proteinuria and analysed for renal histology, cell populations and cytokine transcripts. Results were compared with the evolution of the initial disease studied previously. RESULTS: Both groups showed normal graft histology at Day 7 and an increasing podocyte swelling at Day 45 was seen only in the Buff/Mna recipients. At Day 80, glomerular atrophy with podocytosis and focal segmental glomerular sclerosis lesions, accompanied by tubular dilatation, appeared in the Buff/Mna group. At Day 122, the intensity of the tubular and glomerular lesions increased in Buff/Mna recipients but not in the control group. An analysis of desmin and Kim-1 (early markers of glomerular and tubular damage, respectively) transcripts expression showed that glomerular lesions precede tubular injury in this model. A monocyte infiltration associated with an increase in TNFα, IL1 and IL12 transcripts appeared before the recurrence. An early increase in Cbeta TCR transcripts with a predominant Th2 profile was observed, highlighting a Th2 polarization in the Buff/Mna recurrence. CONCLUSIONS: The comparison of profiles of recurrence and initial disease highlighted the same mediators for both events. We propose that initial Buff/Mna idiopathic nephrotic syndrome (INS) and post-transplantation recurrence represent the same entity and a valuable tool for the study of recurring INS.

Potential role of soluble ST2 protein in idiopathic nephrotic syndrome recurrence following kidney transplantation.

BACKGROUND: Corticosteroid-resistant idiopathic nephrotic syndrome (INS) recurs rapidly after transplantation in 30% to 50% of transplant recipients, suggesting the presence of 1 or more circulating factors that alter the glomerular filtration barrier. We investigated the possible role in INS recurrence of soluble ST2 (sST2) protein, a marker of T helper type 2 (T(H)2) cells and a factor predicted to be regulated by the transcription factor c-Maf; involvement of sST2 protein would be consistent with the observation that both T(H)2 cells and c-Maf appear to be activated during INS relapse. STUDY DESIGN: Retrospective observational study. SETTING & PARTICIPANTS: Patients with biopsy-proven corticosteroid-resistant INS who had undergone kidney transplantation between September 1983 and April 2007 (n = 71). A control group consisting of proteinuric transplant recipients with kidney failure unrelated to INS (n = 34). PREDICTOR: Patients who developed INS recurrence after transplantation (n = 31) were compared with those in whom INS did not recur (n = 40) and the control group. Recurrence of INS was defined as urine protein excretion greater than 2 g/d immediately after transplantation that persisted at greater than 1 g/d despite treatment or a kidney graft biopsy showing minimal change glomerulonephritis or focal segmental glomerulosclerosis. OUTCOMES & MEASUREMENTS: Urine protein excretion in the 3 groups was 5.0 g/d (range, 1.3 to 10.5), 0.14 g/d (range, 0 to 0.46), and 4.3 g/d (range, 3 to 6.2). The sST2 protein was analyzed both quantitatively and qualitatively in patient sera, and its activity was tested in vitro on a mouse podocyte cell line and in vivo in rats. RESULTS: sST2 protein levels were significantly increased after transplantation in patients with INS recurrence compared with the 2 other groups (617.5 versus 23 pg/mL; P < 0.001 and 158.5 pg/mL; P < 0.01 respectively). However, patients with recurrence expressed a normal sST2 isoform, and the sST2 protein was unable to induce podocyte injury in vitro or trigger proteinuria in rats. LIMITATIONS: Pretransplantation and posttransplantation sera do not always represent paired samples. CONCLUSIONS: These data suggest that sST2 protein is a marker of INS recurrence that does not seem to be involved in the development of INS.

Induction of T regulatory cells attenuates idiopathic nephrotic syndrome.

Buffalo/Mna rats spontaneously develop FSGS and nephrotic syndrome as a result of an immune disorder. Similar to some humans with FSGS, the disease recurs after renal transplantation, suggesting the involvement of a circulating factor. Here, we tested the effect of several immunosuppressive treatments on these rats. Although corticosteroids, cyclosporin A, and anti-T cell receptor treatment reduced proteinuria, only the deoxyspergualin derivative LF15-0195 led to a rapid and complete normalization of proteinuria. Furthermore, this compound led to the regression of renal lesions during both the initial disease and posttransplantation recurrence. The frequency of splenic and peripheral CD4+CD25+FoxP3+ T lymphocytes significantly increased with remission. Moreover, the transfer of purified LF15-0195-induced CD4+CD25+ T cells to irradiated Buff/Mna rats significantly reduced their proteinuria compared with the transfer of untreated control cells, suggesting that LF15-0195 induces regulatory T cells that are able to induce regression of rat nephropathy. These data suggest that idiopathic nephrotic syndrome/FSGS disease can be regulated by cellular transfer, but how this regulation leads to the reorganization of the podocyte cytoskeleton remains to be determined.

The study of mitoxantrone as a potential immunosuppressor in transgenic pig renal xenotransplantation in baboons: comparison with cyclophosphamide.

Mounting evidence suggests that delayed xenograft rejection (DXR) of discordant xenografts has a strong humoral component. To explore the possibility of targeting this humoral response more efficiently, we performed a preliminary study in baboons immunized against pig blood cells using the immunosuppressor mitoxantrone (Mx). The results from this study showed that, in comparison with cyclophosphamide (CyP), Mx induced a long-lasting depletion of circulating B cells within 6 days of its administration and delayed secondary anti-Gal antibody (Ab) responses to pig blood cell immunizations. Given these results, we next evaluated Mx in an in vivo model of pig to baboon renal xenotransplantation. We performed a series of renal xenotransplantations in baboons using human CD55-CD59 transgenic donor pigs. In the first group of baboons (Mx group; n = 4) Mx was administered 6 days prior to the day of transplantation, the objective being to perform the xenotransplantation in a context where the recipient would have few remaining circulating B cells and thus have an impaired capacity to mount an Ab response to the xenograft. We compared this group to a second group of baboons treated with CyP starting 1 day prior to transplantation (CyP group; n = 2). All baboons receiving Mx or CyP received an additional immunosuppression of cyclosporin A, mycophenolate mofetil and steroids. No hyperacute rejection was observed in either group but all xenografts underwent DXR. Mx did not show superiority to CyP in terms of graft survival with a mean survival time of 8 +/- 2 days compared with 9 days for both CyP-treated baboons. Neither CyP nor Mx decreased serum levels of pre-existing anti-Gal Abs but levels of these Abs decreased dramatically within 1 day of transplantation, likely reflecting their immediate trapping within the xenograft. Interestingly however, in contrast to CyP, Mx inhibited the return of anti-Gal immunoglobulin M (IgM) to the circulation, even at the time of rejection. Nevertheless, strong intragraft deposits of IgM, IgG and the activated complement complex C5b-9 were observed in biopsies at rejection. Furthermore, despite the expected profound depletion of circulating B cells by Mx within 6 days of its administration, biopsies from both groups at rejection displayed a mild B cell infiltrate accompanied by a strong macrophage and intermediate T-cell infiltration, the latter tending to be more abundant in Mx-treated animals. Our data show that in this particular model of pig to baboon xenotransplantation and at the dose used, Mx was not superior to CyP in conferring protection against rejection, despite its capacity to profoundly deplete circulating B cells and to inhibit anti-Gal Ab responses to xenografts. DXR was thus possible without the return of anti-Gal Abs and may have been mediated by the early fixation of pre-existing Abs with secondary complement activation. However, although Mx was not more efficient than CyP in controlling DXR, its capacity to deplete B cells and delay Ab recovery may be beneficial in the context of Gal knockout organ transplantation where the induced Ab response is likely to take precedence over the preformed response.