Sandra Merscher-Gomez

The actin cytoskeleton of kidney podocytes is a direct target of the antiproteinuric effect of cyclosporine A

The immunosuppressive action of the calcineurin inhibitor cyclosporine A (CsA) stems from the inhibition of nuclear factor of activated T cells (NFAT) signaling in T cells. CsA is also used for the treatment of proteinuric kidney diseases. As it stands, the antiproteinuric effect of CsA is attributed to its immunosuppressive action. Here we show that the beneficial effect of CsA on proteinuria is not dependent on NFAT inhibition in T cells, but rather results from the stabilization of the actin cytoskeleton in kidney podocytes. CsA blocks the calcineurin-mediated dephosphorylation of synaptopodin, a regulator of Rho GTPases in podocytes, thereby preserving the phosphorylation-dependent synaptopodin–14-3-3β interaction. Preservation of this interaction, in turn, protects synaptopodin from cathepsin L–mediated degradation. These results represent a new view of calcineurin signaling and shed further light on the treatment of proteinuric kidney diseases. Novel calcineurin substrates such as synaptopodin may provide promising starting points for antiproteinuric drugs that avoid the serious side effects of long-term CsA treatment.

Rituximab Targets Podocytes in Recurrent Focal Segmental Glomerulosclerosis

Rituximab treatment in high-risk patients with focal segmental glomerulosclerosis directly affects podocyte function and is linked to reduced incidence of recurrent proteinuria after kidney transplantation. Rituximab Prods Podocytes to Action Rituximab is a monoclonal antibody against CD20, a protein located on the surface of B cells. It is typically used to treat certain cancers and autoimmune disorders, but has also treated kidney conditions, including focal segmental glomerulosclerosis (FSGS)—a disorder that can affect both pediatric and adult patients. Recurrent FSGS is a problem for 30 to 40% of patients who have undergone kidney transplantation, and can be characterized by progression to end-stage renal disease and recurrence of proteinuria after transplant. Despite the ability of rituximab to treat FSGS, it has been unclear exactly how this drug achieves success in some patients, but not others. Fornoni and colleagues hypothesized that rituximab operates in a B cell–independent manner, targeting instead specific kidney cells called podocytes. To test this hypothesis, Fornoni et al. studied 41 patients at high risk for FSGS: 14 historical control patients who were not treated with rituximab and 27 patients who received rituximab at the time of kidney transplant. They found fewer podocytes with sphingomyelin phosphodiesterase acid-like 3b (SMPDL-3b) protein in biopsies from patients who later developed recurrent FSGS. The authors had also collected serum from all patients before transplant and then later treated normal human podocytes in culture with the sera. Serum from patients who would later develop recurrent FSGS caused a decrease in both SMPDL-3b protein and acid sphingomyelinase activity. This phenomenon was prevented by rituximab. The FSGS serum from patients also disrupted the actin cytoskeleton of cultured podocytes, but pretreatment with rituximab, or even overexpression of SMPDL-3b protein, partially prevented this phenotype. Together, these data suggest that modulation of sphingolipid-related proteins plays a role in the pathogenesis of recurrent FSGS and, moreover, that these proteins and enzymes might be targets of rituximab treatment. With the mechanism solved, rituximab may represent a new therapeutic strategy to prevent recurrent proteinuria after kidney transplantation. Here’s to happy and healthy kidneys! Focal segmental glomerulosclerosis (FSGS) is a glomerular disease characterized by proteinuria, progression to end-stage renal disease, and recurrence of proteinuria after kidney transplantation in about one-third of patients. It has been suggested that rituximab might treat recurrent FSGS through an unknown mechanism. Rituximab not only recognizes CD20 on B lymphocytes, but might also bind sphingomyelin phosphodiesterase acid-like 3b (SMPDL-3b) protein and regulate acid sphingomyelinase (ASMase) activity. We hypothesized that rituximab prevents recurrent FSGS and preserves podocyte SMPDL-3b expression. We studied 41 patients at high risk for recurrent FSGS, 27 of whom were treated with rituximab at time of kidney transplant. SMPDL-3b protein, ASMase activity, and cytoskeleton remodeling were studied in cultured normal human podocytes that had been exposed to patient sera with or without rituximab. Rituximab treatment was associated with lower incidence of posttransplant proteinuria and stabilization of glomerular filtration rate. The number of SMPDL-3b+ podocytes in postreperfusion biopsies was reduced in patients who developed recurrent FSGS. Rituximab partially prevented SMPDL-3b and ASMase down-regulation that was observed in podocytes treated with the sera of patients with recurrent FSGS. Overexpression of SMPDL-3b or treatment with rituximab was able to prevent disruption of the actin cytoskeleton and podocyte apoptosis induced by patient sera. This effect was diminished in cultured podocytes where SMPDL-3b was silenced. Our study suggests that treatment of high-risk patients with rituximab at time of kidney transplant might prevent recurrent FSGS by modulating podocyte function in an SMPDL-3b–dependent manner.

Rituximab is a safe and effective long-term treatment for children with steroid and calcineurin inhibitor–dependent idiopathic nephrotic syndrome

In children with idiopathic nephrotic syndrome, rituximab can maintain short-term remission with withdrawal of prednisone and calcineurin inhibitors. Long-term effects including the number of repeated infusions to maintain remission are unknown. To test this, we treated 46 consecutive children with idiopathic nephrotic syndrome lasting for at least 1 year (mean 6.3 years), maintained in remission with oral prednisone and calcineurin inhibitors. They received 1-5 rituximab courses during a median follow-up of 3 years. Oral agents were tapered after each infusion, and completely withdrawn within 45 days. Rituximab was well tolerated. Six-month probabilities of remission were 48% after the first infusion and 37% after subsequent infusions. One- and 2-year-remission probabilities were, respectively, 20 and 10%. Median time intervals between complete oral-agent withdrawal and relapse were 5.6 and 8.5 months, respectively, following the first and subsequent courses. The time to reconstitution of CD20 cells correlated with the duration of remission, but was not associated with variation in FcyR, CD20, or SMPDL-3B polymorphisms. Podocyte Src phosphorylation was normal. Thus, rituximab can be safely and repeatedly used as a prednisone and calcineurin inhibitor-sparing therapy in a considerable proportion of children with dependent forms of idiopathic nephrotic syndrome. Further study is needed to identify patients who will benefit most from rituximab therapy.In children with idiopathic nephrotic syndrome rituximab can maintain short-term remission with withdrawal of prednisone and calcineurin-inhibitors. Long-term effects including number of repeated infusions to maintain remission are unknown. We treated with rituximab 46 consecutive children with idiopathic nephrotic syndrome lasting for at least one year (6.3±4.1 years), who were maintained in remission with oral prednisone and calcineurin inhibitors. They received 1–5 rituximab courses during a median follow-up of three years (range 1–5). Oral agents were tapered after each infusion, and completely withdrawn within 45 days. Rituximab was well tolerated. Six-month probabilities of remission were 48% after the first infusion and 37% after subsequent infusions. One- and two-year-remission probabilities were respectively 20% and 10%. Median time intervals between complete oral-agent withdrawal and relapse were 5.6 and 8.5 months respectively following the first and subsequent courses. Time to reconstitution of CD20 cells correlated with the duration of remission, but was not associated with variation in FcyR, CD20 or SMPDL-3B polymorphisms. Podocyte Src phosphorylation was normal. Rituximab can be safely and repeatedly used as prednisone and calcineurin-inhibitor-sparing therapy in a considerable proportion of children with dependent forms of idiopathic nephrotic syndrome. Further research is needed to identify patients who will benefit most from rituximab therapy.

Cyclodextrin Protects Podocytes in Diabetic Kidney Disease

Diabetic kidney disease (DKD) remains the most common cause of end-stage kidney disease despite multifactorial intervention. We demonstrated that increased cholesterol in association with downregulation of ATP-binding cassette transporter ABCA1 occurs in normal human podocytes exposed to the sera of patients with type 1 diabetes and albuminuria (DKD+) when compared with diabetic patients with normoalbuminuria (DKD−) and similar duration of diabetes and lipid profile. Glomerular downregulation of ABCA1 was confirmed in biopsies from patients with early DKD (n = 70) when compared with normal living donors (n = 32). Induction of cholesterol efflux with cyclodextrin (CD) but not inhibition of cholesterol synthesis with simvastatin prevented podocyte injury observed in vitro after exposure to patient sera. Subcutaneous administration of CD to diabetic BTBR (black and tan, brachiuric) ob/ob mice was safe and reduced albuminuria, mesangial expansion, kidney weight, and cortical cholesterol content. This was followed by an improvement of fasting insulin, blood glucose, body weight, and glucose tolerance in vivo and improved glucose-stimulated insulin release in human islets in vitro. Our data suggest that impaired reverse cholesterol transport characterizes clinical and experimental DKD and negatively influences podocyte function. Treatment with CD is safe and effective in preserving podocyte function in vitro and in vivo and may improve the metabolic control of diabetes.

Podocyte-specific GLUT4-deficient mice have fewer and larger podocytes and are protected from diabetic nephropathy.

Podocytes are a major component of the glomerular filtration barrier, and their ability to sense insulin is essential to prevent proteinuria. Here we identify the insulin downstream effector GLUT4 as a key modulator of podocyte function in diabetic nephropathy (DN). Mice with a podocyte-specific deletion of GLUT4 (G4 KO) did not develop albuminuria despite having larger and fewer podocytes than wild-type (WT) mice. Glomeruli from G4 KO mice were protected from diabetes-induced hypertrophy, mesangial expansion, and albuminuria and failed to activate the mammalian target of rapamycin (mTOR) pathway. In order to investigate whether the protection observed in G4 KO mice was due to the failure to activate mTOR, we used three independent in vivo experiments. G4 KO mice did not develop lipopolysaccharide-induced albuminuria, which requires mTOR activation. On the contrary, G4 KO mice as well as WT mice treated with the mTOR inhibitor rapamycin developed worse adriamycin-induced nephropathy than WT mice, consistent with the fact that adriamycin toxicity is augmented by mTOR inhibition. In summary, GLUT4 deficiency in podocytes affects podocyte nutrient sensing, results in fewer and larger cells, and protects mice from the development of DN. This is the first evidence that podocyte hypertrophy concomitant with podocytopenia may be associated with protection from proteinuria.

Dynamin-mediated Nephrin Phosphorylation Regulates Glucose-stimulated Insulin Release in Pancreatic Beta Cells

Background: Nephrin is an immunoglobulin-like protein that facilitates insulin release by pancreatic beta cells. Results: Nephrin phosphorylation at tyrosine residues responsible for SH2 domain binding is a Dynamin-dependent phenomenon, and it is necessary for glucose-stimulated insulin release in insulinoma cells and human islets. Conclusion: Dynamin-dependent Nephrin phosphorylation is necessary for glucose-stimulated insulin secretion. Significance: Pharmacological modulation of Nephrin phosphorylation may facilitate pancreatic beta cell function. We have previously demonstrated a role for Nephrin in glucose stimulated insulin release (GSIR). We now hypothesize that Nephrin phosphorylation is required for GSIR and that Dynamin influences Nephrin phosphorylation and function. MIN6-C3 Nephrin-deficient pancreatic beta cells and human islets were transfected with WT-Nephrin or with a mutant Nephrin in which the tyrosine residues responsible for SH2 domain binding were substituted with phenylalanine (3YF-Nephrin). GSIR and live images of Nephrin and vesicle trafficking were studied. Immunoprecipitation experiments and overexpression of WT-Dynamin or dominant negative Dynamin mutant (K44A-Dynamin) in WT-Nephrin, 3YF-Nephrin, or Nephrin siRNA-transfected cells were utilized to study Nephrin-Dynamin interaction. In contrast to WT-Nephrin or to single tyrosine mutants, 3YF-Nephrin did not positively affect GSIR and led to impaired cell-cell contacts and vesicle trafficking. K44A-Dynamin prevented the effect of Nephrin on GSIR in the absence of protein-protein interaction between Nephrin and Dynamin. Nephrin gene silencing abolished the positive effects of WT-Dynamin on GSIR. The effects of protamine sulfate and vanadate on Nephrin phosphorylation and GSIR were studied in MIN6 cells and human islets. WT-Nephrin phosphorylation after glucose occurred at Tyr-1176/1193 and resulted in improved GSIR. On the contrary, protamine sulfate-induced phosphorylation at Tyr-1176/1193/1217 was associated with Nephrin degradation and impaired GSIR. Vanadate, which prevented Nephrin dephosphorylation after glucose stimulation, improved GSIR in human islets and MIN6 cells. In conclusion, Dynamin-dependent Nephrin phosphorylation occurs in response to glucose and is necessary for Nephrin-mediated augmentation of GSIR. Pharmacological modulation of Nephrin phosphorylation may thus facilitate pancreatic beta cell function.

Use of Rituximab in Children with Steroid- and Calcineurin-Inhibitor-Dependent Idiopathic Nephrotic Syndrome

In children with idiopathic nephrotic syndrome, rituximab can maintain short-term remission with withdrawal of prednisone and calcineurin inhibitors. Long-term effects including the number of repeated infusions to maintain remission are unknown. To test this, we treated 46 consecutive children with idiopathic nephrotic syndrome lasting for at least 1 year (mean 6.3 years), maintained in remission with oral prednisone and calcineurin inhibitors. They received 1-5 rituximab courses during a median follow-up of 3 years. Oral agents were tapered after each infusion, and completely withdrawn within 45 days. Rituximab was well tolerated. Six-month probabilities of remission were 48% after the first infusion and 37% after subsequent infusions. One- and 2-year-remission probabilities were, respectively, 20 and 10%. Median time intervals between complete oral-agent withdrawal and relapse were 5.6 and 8.5 months, respectively, following the first and subsequent courses. The time to reconstitution of CD20 cells correlated with the duration of remission, but was not associated with variation in FcyR, CD20, or SMPDL-3B polymorphisms. Podocyte Src phosphorylation was normal. Thus, rituximab can be safely and repeatedly used as a prednisone and calcineurin inhibitor-sparing therapy in a considerable proportion of children with dependent forms of idiopathic nephrotic syndrome. Further study is needed to identify patients who will benefit most from rituximab therapy.In children with idiopathic nephrotic syndrome rituximab can maintain short-term remission with withdrawal of prednisone and calcineurin-inhibitors. Long-term effects including number of repeated infusions to maintain remission are unknown. We treated with rituximab 46 consecutive children with idiopathic nephrotic syndrome lasting for at least one year (6.3±4.1 years), who were maintained in remission with oral prednisone and calcineurin inhibitors. They received 1–5 rituximab courses during a median follow-up of three years (range 1–5). Oral agents were tapered after each infusion, and completely withdrawn within 45 days. Rituximab was well tolerated. Six-month probabilities of remission were 48% after the first infusion and 37% after subsequent infusions. One- and two-year-remission probabilities were respectively 20% and 10%. Median time intervals between complete oral-agent withdrawal and relapse were 5.6 and 8.5 months respectively following the first and subsequent courses. Time to reconstitution of CD20 cells correlated with the duration of remission, but was not associated with variation in FcyR, CD20 or SMPDL-3B polymorphisms. Podocyte Src phosphorylation was normal. Rituximab can be safely and repeatedly used as prednisone and calcineurin-inhibitor-sparing therapy in a considerable proportion of children with dependent forms of idiopathic nephrotic syndrome. Further research is needed to identify patients who will benefit most from rituximab therapy.

Clinical InvestigationRituximab is a safe and effective long-term treatment for children with steroid and calcineurin inhibitor–dependent idiopathic nephrotic syndrome

In children with idiopathic nephrotic syndrome, rituximab can maintain short-term remission with withdrawal of prednisone and calcineurin inhibitors. Long-term effects including the number of repeated infusions to maintain remission are unknown. To test this, we treated 46 consecutive children with idiopathic nephrotic syndrome lasting for at least 1 year (mean 6.3 years), maintained in remission with oral prednisone and calcineurin inhibitors. They received 1-5 rituximab courses during a median follow-up of 3 years. Oral agents were tapered after each infusion, and completely withdrawn within 45 days. Rituximab was well tolerated. Six-month probabilities of remission were 48% after the first infusion and 37% after subsequent infusions. One- and 2-year-remission probabilities were, respectively, 20 and 10%. Median time intervals between complete oral-agent withdrawal and relapse were 5.6 and 8.5 months, respectively, following the first and subsequent courses. The time to reconstitution of CD20 cells correlated with the duration of remission, but was not associated with variation in FcyR, CD20, or SMPDL-3B polymorphisms. Podocyte Src phosphorylation was normal. Thus, rituximab can be safely and repeatedly used as a prednisone and calcineurin inhibitor-sparing therapy in a considerable proportion of children with dependent forms of idiopathic nephrotic syndrome. Further study is needed to identify patients who will benefit most from rituximab therapy.In children with idiopathic nephrotic syndrome rituximab can maintain short-term remission with withdrawal of prednisone and calcineurin-inhibitors. Long-term effects including number of repeated infusions to maintain remission are unknown. We treated with rituximab 46 consecutive children with idiopathic nephrotic syndrome lasting for at least one year (6.3±4.1 years), who were maintained in remission with oral prednisone and calcineurin inhibitors. They received 1–5 rituximab courses during a median follow-up of three years (range 1–5). Oral agents were tapered after each infusion, and completely withdrawn within 45 days. Rituximab was well tolerated. Six-month probabilities of remission were 48% after the first infusion and 37% after subsequent infusions. One- and two-year-remission probabilities were respectively 20% and 10%. Median time intervals between complete oral-agent withdrawal and relapse were 5.6 and 8.5 months respectively following the first and subsequent courses. Time to reconstitution of CD20 cells correlated with the duration of remission, but was not associated with variation in FcyR, CD20 or SMPDL-3B polymorphisms. Podocyte Src phosphorylation was normal. Rituximab can be safely and repeatedly used as prednisone and calcineurin-inhibitor-sparing therapy in a considerable proportion of children with dependent forms of idiopathic nephrotic syndrome. Further research is needed to identify patients who will benefit most from rituximab therapy.

Dynamin-mediated nephrin phosphorylation regulates glucose-stimulated insulin release in pancreatic beta cells (Journal of Biological Chemistry (2012) 287, (28932-28942))

Theauthors havebecomeawareof severalmistakes inFig. 2A. In the second row, the second and thirdpanels are identical, and the fourth and fifth panels are also the same. In the third row, the third and fourth panels are repeated. In reviewing the errors, the authors caught another mistake with the black-and-white digital subtraction images shown in the first and third rows. The figure and figure legend claim to show FM4-64, which is incorrect. The corrected Fig. 2A is shown below. The duplicated images in the second and third rows have replaced with ones taken at 5-, 8-, 12-, and 18-minute time points. The black-and-white representative images in the first and third rows are now digital subtraction images of the GFP signal forWT-N and 3YF-N. Data shown in the quantitative analysis were also checked for completeness and have been confirmed to be correct. The authors regret any confusion the incorrect figure may have caused. This correction does not influence the validity of the results and conclusions of the original article.