Congenital nephrotic syndrome (CNS) is a genetic disease that is present in the antenatal period or during the first 3 months of life. In this study, we aimed to compare growth parameters of patients with CNS who received kidney transplants and either (1) had a normal glomerular filtration rate (GFR) at the time of transplant or (2) chronic kidney disease (CKD) at the time of transplant. Patients with a diagnosis of CNS who had a minimum follow-up period of 6 months were evaluated retrospectively. Children at stages 4 or 5 CKD or patients receiving dialysis during the pretransplant period were defined as group 1; patients with normal GFR at the time of transplantation were classified as group 2. Short stature and low weight were defined as less than -2 standard deviation scores (SDS) for height and weight according to their age. A total of 17 patients were included in the study. Thirteen of 17 patients had NPHS1 gene mutations. Group 1 and group 2 consisted of 8 and 9 patients, respectively. Mean height SDS and mean weight SDS in group 2 were higher than group 1 in the pretransplant period (-4.34 ± 1.74 vs -2.84 ± 1.56; P = .011 and -3.54 ± 0.93 vs -1.83 ± 1.13; P = .008). In the post-transplant period, the significant difference in height SDS continued in favor of group 2 (-3.16 ± 1.11 vs -1.16 ± 0.87; P = .002). The short stature rate was 83% in group 1 and 72% in group 2 in the pretransplant period (P = .62), and 83% in group 1 and 27% in group 2 in the post-transplant period (P = .02). Early renal transplantation seems to be effective for optimal height gain in children with CNS.

Mutations in the NPHS1 gene, which encodes NEPHRIN, cause congenital nephrotic syndrome, resulting from impaired slit diaphragm (SD) formation in glomerular podocytes. We previously reported NEPHRIN and SD abnormalities in the podocytes of kidney organoids generated from patient-derived induced pluripotent stem cells (iPSCs) with an NPHS1 missense mutation (E725D). However, the mechanisms underlying the disease may vary depending on the mutations involved, and thus generation of iPSCs from multiple patients is warranted. Here we established iPSCs from two additional patients with different NPHS1 mutations and examined the podocyte abnormalities in kidney organoids derived from these cells. One patient had truncating mutations, and NEPHRIN was undetectable in the resulting organoids. The other patient had a missense mutation (R460Q), and the mutant NEPHRIN in the organoids failed to accumulate on the podocyte surface to form SD precursors. However, the same mutant protein behaved normally when overexpressed in heterologous cells, suggesting that NEPHRIN localization is cell context-dependent. The localization of another SD-associated protein, PODOCIN, was impaired in both types of mutant organoids in a cell domain-specific manner. Thus, the new iPSC lines and resultant kidney organoids will be useful resources for dissecting the disease mechanisms, as well as for drug development for therapies.

We report a consanguineous family from Saudi Arabia with three affected children presenting with infantile nephrotic syndrome. In order to provide a molecular diagnosis, a genome-wide SNP analysis of the affected patients was performed. We identified a region of homozygosity on chromosome 1, containing the NPHS2 gene. Direct sequencing, by exon PCR, of NPHS2 identified a homozygous nucleotide change 385C>> T within exon 3 in the three affected children, leading to a premature stop codon (Q129X). This homozygous truncating mutation in NPHS2 is novel and was associated with a severe clinical phenotype. Additional mutations in related genes NPHS1, PLCE1 and NEPH1 were not identified, excluding tri-allelism within these genes in this family.

Focal segmental glomerulosclerosis (FSGS) is a common cause of steroid-resistant nephrotic syndrome. Spontaneous remission of FSGS is rare and steroid-resistant FSGS frequently progresses to renal failure. Many inheritable forms of FSGS have been described, caused by mutations in proteins that are important for podocyte function. Here, we show that a basic leucine zipper transcription factor, MafB, protects against FSGS. MAFB expression was found to be decreased in the podocytes of patients with FSGS. Moreover, conditional podocyte-specific MafB-knockout mice developed FSGS with massive proteinuria accompanied by depletion of the slit diaphragm-related proteins (Nphs1 and Magi2), and the podocyte-specific transcription factor Tcf21. These findings indicate that MafB plays a crucial role in the pathogenesis of FSGS. Consistent with this, adriamycin-induced FSGS and attendant proteinuria were ameliorated by MafB overexpression in the podocytes of MafB podocyte-specific transgenic mice. Thus, MafB could be a new therapeutic target for FSGS.

Keywords: MafB; focal segmental glomerulosclerosis; podocyte; transcription factor.

Many mutations in the NPHS1 gene were detected among patients with congenital nephrotic syndrome. Functional analysis of those mutations was done with a stable-expression cell line. Nevertheless, establishing such a cell line is time-consuming.

We established an easier method using automatic counting software for functional analysis with transient-transfection cells rather than a stable-expression cell line. We demonstrated maltrafficking to the plasma membrane of abnormal nephrin for immunostaining on transient-expression cells by comparison without Triton X (detecting proteins on the cell membrane only) and with Triton X (detecting proteins both on the cell membrane and inside the cell cytoplasm). We obtained relevant results with data obtained previously using a stable-expression cell line. Furthermore, we conducted functional analysis of NPHS1 mutations in Japanese patients with congenital nephrotic syndrome using this simple method, which revealed that all pathogenic mutations impaired trafficking to the protein plasma membrane.

Functional analysis using transient-expression cells with automatic counting software was useful to demonstrate maltrafficking to the plasma membrane of a protein. All pathogenic mutations detected in Japanese patients impaired trafficking to the protein plasma membrane.

Aim: Sodium retention is the hallmark of nephrotic syndrome (NS) and mediated by the proteolytic activation of the epithelial sodium channel (ENaC) by aberrantly filtered serine proteases. Plasmin is highly abundant in nephrotic urine and has been proposed to be the principal serine protease responsible for ENaC activation in NS. However, a proof of the essential role of plasmin in experimental NS is lacking.

Methods: We used a genetic mouse model of NS based on an inducible podocin knockout (Bl6-Nphs2^tm3.1Antc *Tg(Nphs1-rtTA*3G)^8Jhm *Tg(tetO-cre)^1Jaw or nphs2^Δipod ). These mice were crossed with plasminogen deficient mice (Bl6-Plg^tm1Jld or plg^-/- ) to generate double knockout mice (nphs2^Δipod *plg^-/- ). NS was induced after oral doxycycline treatment for 14 days and mice were followed for subsequent 14 days.

Results: Uninduced nphs2^Δipod *plg^-/- mice had normal kidney function and sodium handling. After induction, proteinuria increased similarly in both nphs2^Δipod *plg^+/+ and nphs2^Δipod *plg^-/- mice. Western blot revealed the urinary excretion of plasminogen and plasmin in nphs2^Δipod *plg^+/+ mice which were absent in nphs2^Δipod *plg^-/- mice. After the onset of proteinuria, amiloride-sensitive natriuresis was increased compared to the uninduced state in both genotypes. Subsequently, urinary sodium excretion dropped in both genotypes leading to an increase in body weight and development of ascites. Treatment with the serine protease inhibitor aprotinin prevented sodium retention in both genotypes.

Conclusions: This study shows that mice lacking urinary plasminogen are not protected from ENaC-mediated sodium retention in experimental NS. This points to an essential role of other urinary serine proteases in the absence of plasminogen.

Keywords: epithelial sodium channel; nephrotic syndrome; plasminogen; proteasuria; sodium retention.

Mutations in NPHS1 can lead to disruption of the filtration barrier and cause proteinuria in nephrotic syndrome (NS). The aim of the study was to evaluate NPHS1 mutations, its susceptibility to the disease, and their association in children with steroid-resistant NS; mutation frequency of 9% was observed in patients with steroid-resistant NS, of which, six mutations and two single-nucleotide polymorphisms observed in the study population were found to be novel.

Cell differentiation and cell fate determination in sensory systems are essential for stimulus discrimination and coding of environmental stimuli. Color vision is based on the differential color sensitivity of retinal photoreceptors, however the developmental programs that control photoreceptor cell differentiation and specify color sensitivity are poorly understood. In Drosophila melanogaster, there is evidence that the color sensitivity of different photoreceptors in the compound eye is regulated by inductive signals between cells, but the exact nature of these signals and how they are propagated remains unknown. We conducted a genetic screen to identify additional regulators of this process and identified a novel mutation in the hibris gene, which encodes an irre cell recognition module protein (IRM). These immunoglobulin super family cell adhesion molecules include human KIRREL and nephrin (NPHS1). hibris is expressed dynamically in the developing Drosophila melanogaster eye and loss-of-function mutations give rise to a diverse range of mutant phenotypes including disruption of the specification of R8 photoreceptor cell diversity. We demonstrate that hibris is required within the retina, and that hibris over-expression is sufficient to disrupt normal photoreceptor cell patterning. These findings suggest an additional layer of complexity in the signaling process that produces paired expression of opsin genes in adjacent R7 and R8 photoreceptor cells.

The in vivo engraftment of induced pluripotent stem cell (iPSC)-derived podocytes following allogeneic transplantation into host kidneys remains a challenge. Here we investigate the survival and engraftment of human dermal fibroblasts-derived differentiated iPSCs using a newborn mouse model, which represents a receptive immunoprivileged host environment. iPSCs were generated from skin biopsies of patients using Sendai virus reprogramming. Differentiation of nephrin (NPHS1)-green fluorescent protein (GFP) iPSCs into kidney podocytes (iPSC-PODs) was performed by the addition of Activin A, bone morphogenetic protein 7 (BMP7), and retinoic acid over 10 days of culture. To assess the in vivo incorporation of cells, undifferentiated iPSCs or day 10 iPSC-PODs, were labeled with either carboxyfluorescein succinimidyl ester (CFSE) or Qdot nanocrystals (Q705). Thereafter, 1 × 10⁵ differentiated iPSC-PODs were injected directly into the kidneys of mouse pups at postnatal day one (P1). Using co-expression analysis of glomerular and podocyte-specific markers, Day 10 differentiated iPSC-PODs that were positive for podocin, were detected following direct kidney injection into newborn mice up to 1 week after transplantation. Undifferentiated iPSC-PODs were not detected at the same timepoint. The transplanted cells were viable and located in the outer nephrogenic zone where they were found to colocalize with, or sit adjacent to, cells positive for glomerular-specific markers including podocin, synaptopodin, and Wilms' tumor 1 (WT1). This study provides proof-of-principle that transplanted iPSC-POD can survive in recipient newborn mouse kidneys due to the immature and immunoprivileged nature of the developing postnatal kidneys.

Transthyretin related amyloidosis is a nosological entity that leads to disability, diminished quality of life, all stages of chronic kidney disease and eventually death. Podocytes are polarized, highly differentiated epithelial cells important for proper nephron function. In the present study we investigated whether deposited TTRVal30Met (TTRV30M) molecules could be localized within podocytes in situ under the effect of different housing conditions (i.e. specific pathogen free [SPF] vs. non-SPF). Murine renal glomeruli from human TTRV30M (hTTRV30M) transgenic mice were examined via direct and indirect immunofluorescence techniques for the presence of hTTRV30M, murine serum amyloid P, activated caspase-3 and NPHS1. Association strength and amount of colocalization for NPHS1-hTTRV30M, NPHS1-activated caspase-3, hTTRV30M-murine serum amyloid P were estimated. Localization of hTTRV30M in podocytes was demonstrated by immuno-electron microscopy. Renal hTTRV30M gene and NPHS1 gene expression levels were estimated. Non-SPF transgenic mice showed increased glomerular hTTRV30M deposition compared to their SPF counterparts. Furthermore increased podocytic localization of hTTRV30M was noticed in non-SPF mice. Glomerular caspase-3 activation was increased only in the non SPF housing conditions. Podocytic caspase-3 activation was increased in SPF and in non-SPF transgenic mice when compared to non transgenic controls. Environmental conditions influence glomerular deposition and podocytic localization of hTTRV30M. In this context increased caspase-3 activation occurred.

Steroid-resistant nephrotic syndrome poses a significant clinical challenge. Its pathogenesis has not been fully elucidated. In recent years, numerous studies have shown that podocyte-specific gene mutations may play important roles in the development of steroid-resistant nephrotic syndrome. Among the identified genes mutated in podocytes include NPHS2, NPHS1, WT1, TRPC6, MDR1, PLCE1, LMX1B, and LAMB2. This review aims to summarize the characteristics of these mutated genes in podocytes. The putative role for these podocyte-specific mutated genes in the pathogenesis, diagnosis, treatment and prognosis of steroid-resistant nephrotic syndrome is also discussed.

Idiopathic Nephrotic Syndrome (NS) is the prevalent glomerular disease in childhood. It is treated with steroid and according to its response is defined as steroid sensitive NS (SSNS) and steroid resistance NS (SRNS). Mutation in NPHS 1 gene is reported in children with SRNS and few cases of SSNS. The aim of current study is to evaluate NPHS1 gene mutations in idiopathic NS (SSNS and SSRS) in Northwest Iran. In this cross-sectional analytic study 20 children from Azeri population in Iran with idiopathic NS including 10 cases with SRNS (5 male and 5 female) and 10 cases with SSNS (7 male and 3 female) were evaluated for NPHS1 gene mutations. DNA was extracted from peripheral blood and NPHSI gene analysis was performed by PCR and direct sequencing method with the use of standard primers. Mutations in NPHS1 gene occurred in 6 cases of SSNS including 3 heterozygous and 3 homozygous mutations and in 8 cases of SRNS including 5 homozygous, one compound heterozygous and 2 heterozygous mutations. Overall 6 different mutations were detected in NPHS1 gene: one deletion, one insertion, 3 missense and one nonsense mutations. Mutations in exon 4 and 27 were only seen in SRNS patients. Mutations in NPHS1 gene could occur in both SRNS and SSNS patients; however, considering higher incidence of heterozygous mutations in SSNS, the existence of milder phenotype in these cases would be the reason for steroid response.

Hereditary nephrotic syndrome often presents with steroid-resistance and onset within the first year of life. Mutations in genes highly expressed in podocytes have been found in two thirds of these patients, especially NPHS1 and NPHS2 among at least 29 genetic causes that have been discovered. We reported two siblings with steroid-resistant nephrotic syndrome caused by co-inheritance of mutations at NPHS1 (c.1339G>A, p.E447K) and ACDK4 (c.748G>C, p.D250H) genes. The siblings presented with steroid-resistant nephrotic syndrome and pathological lesions of focal segmental glomerulosclerosis (FSGS), while the elder sister also developed hypertension, renal failure and cardiac dysfunction.

While chronic kidney disease is prevalent in adults, obstructive nephropathy (ON) has been reported in both young and old patients. In ON, tubulointerstitial lesions (TILs) have been widely investigated, but glomerular lesions (GLs) have been largely neglected. Here, we show a novel mechanism underlying GL development in ON in young and old mice. TILs develop earlier than GLs owing to infiltration of inflammatory cells in the tubulointerstitium, but GLs develop following the activation of Toll-like receptor 8 (Tlr8) even though the absence of inflammatory cells infiltrating the glomerulus. TLR8 and interleukin 1 beta (IL1β) proteins colocalize with reducing podocyte function markers (PFMs), indicating the activation of TLR8 signaling in injured podocytes. Furthermore, glomerular and serum levels of miR-21, an endogenous ligand for Tlr8, were higher in the ON mouse model than in the sham control. The glomerular expression of Tlr8 positively correlates with miR-21 and the downstream cytokines Il1b and Il6 and negatively correlated with PFMs (Nphs1 and Synpo). We also show the colocalization of TLR8 and IL1β proteins with reducing PFMs in both obstructed and collateral kidney of young and old mice. Furthermore, in vitro study results revealed higher expression of Tlr8 and its downstream cytokines in glomeruli from obstructed kidneys following treatment with miR-21 mimic than in the control. In conclusion, the overexpression of Tlr8 may serve as a plausible mechanism underlying GL development in ON through podocyte injury.

Keywords: TLR8; chronic kidney disease; obstructed and collateral kidney; obstructive nephropathy; podocyte.

Diabetic nephropathy (DN) is one of the major complications of type 2 diabetes and is associated with coronary disease. Nephrin, a protein mainly expressed in glomeruli, is decreased in DN and other kidney diseases. Since insulin levels are misregulated in type 2 diabetes, a possible connection between DN and its decreased nephrin expression could be the presence of regulatory elements responsive to insulin in the nephrin gene (NPHS1) promoter region. In this work, using bioinformatic tools, we identified a purine-rich GAGA element in the nephrin gene promoter and conducted a genomic study in search of the presence of polymorphisms in this element and its possible association with DN in type 2 diabetic patients. We amplified and sequenced a 514 bp promoter region of 100 individuals and found no genetic variants in the purine-rich GAGA-box of the nephrin gene promoter between groups of patients with diabetes type 2 with and without renal and coronary complications, control patients without diabetes and healthy controls.

Objective: To detect genetic variant in a sib-pair with Finnish type congenital nephrotic syndrome (CNF).

Methods: Clinical data of the sib-pair was reviewed. Coding regions of the NPHS1 gene was analyzed for the sib-pair and both parents.

Results: The sister and brother respectively developed severe proteinuria 1 month and 28 days after birth, in addition with low serum albumin, hypercholesterolemia and severe edema, which were suggestive of CNF. Genetic testing identified that the sib-pair has both carried two heterozygous variants of NPHS1 gene, namely c.2605G>C (p.P869>A) and c.-61G>A, for which their father and mother were heterozygous carriers.

Conclusion: The c.2605G>C (p.869P>A) and c.-61G>A variants of the NHPS1 gene probably underlay the CNF in both sibs. The c.2605G>C(p.869P>A) was unreported previously.

Idiopathic nephrotic syndrome (INS) is characterized by diffuse foot process effacement on electron microscopy and minimal changes (called minimal change nephropathy [MCN]), focal segmental glomerular sclerosis (FSGS), or the mesangial variant with proliferation on light microscopy. No evidence of immune deposits is seen. MCN is the most common form of INS in children and is sensitive to corticosteroid therapy in 90% of cases. FSGS accounts for 20-30% of biopsy-proven glomerulopathies in adult patients. Fifty percent of drug-resistant patients develop terminal renal failure in 6-8 years. Moreover, FSGS reappears in 15-50% of cases after the first transplant and in a higher percentage after the second graft. Genetic forms of INS, with mutation of the NPHS1 and NPHS2 genes encoding nephrin and podocin, are mostly steroid resistant and very rarely recur in the transplant. On the basis of any clinical pattern they are indistinguishable from idiopathic forms. Sera from patients with FSGS may contain some proteinuric or permeability factors (PFs), which have been partially identified and are predictive of recurrence in kidney grafts. Removal of PFs by means of plasmapheresis or plasma immunoadsorption by protein A or LDL apheresis has been associated with proteinuria reduction in cases of FSGS both of native and transplanted kidneys, in small series or cohort studies described by many authors. In this review of the main studies we will analyze the results of the apheretic treatments and the role of some clinical, serological and histological parameters in determining the outcome of patients.

Recent studies of Mendelian disease have begun to clarify the clinical spectrum of the group of disorders that make up familial, focal segmental glomerulosclerosis (FSGS) and nephrotic syndromes. In familial forms of focal segmental glomerulosclerosis (FSGS), both autosomal recessive and dominant inheritance patterns have been reported. At least three genes have been identified which, when defective, cause familial FSGS or nephrosis: the NPHS1 gene, encoding nephrin; the NPHS2 gene, encoding podocin; and the ACTN4 gene, encoding a-actinin-4. Because the majority of FSGS cases occur as sporadic disease, the recently described mutations in the NPHS2 gene "in approximately 25 percent of cases of apparently sporadic, steroid-resistant FSGS in children" have claimed great interest. The applicability of these observations to adults, including the possible importance of the nephrin and alpha-actinin-4 genes in the sporadic disease, remain to be determined. Finally, the mechanisms of podocyte damage and the molecular basis of glomerulosclerosis are reviewed.

OBJECTIVE

Recurrent disease occurs in around 30% of children transplanted for steroid-resistant nephrotic syndrome. Its precipitating risk factors have rarely been studied in the Middle East. The aim of our study was to determine what characterizes posttransplant recurrence of nephrotic syndrome in Syrian children.

METHODS

We performed a retrospective analysis of 12 nephrotic children who received 1 renal allograft at the Kidney Hospital in Damascus from 2002 to 2013.

RESULTS

Native kidney biopsy results showed focal segmental glomerulosclerosis in 9 of 10 patients. Four patients had 1 or more sibling affected with nephrotic syndrome, and the remaining patients were labeled as having sporadic disease. Genetic screening for NPHS2, NPHS1, and Wilms tumor gene (WT1) mutations were done for 6 patients, and 1 novel homozygous NPHS2 mutation was identified in 1 patient. All patients received transplants from living donors. Four patients had recurrence of initial disease after transplant (overall recurrence rate of 33%). However, 1 patient showed complete and spontaneous remission 20 months after transplant; As expected, the patient with NPSH2 mutation had no recurrence. Patients with sporadic disease showed risk of recurrence 5 times higher than patients with familial disease (P = .24). Interestingly, all recurrent cases had received a kidney from a related donor and were initially classified as having sporadic disease. Although not statistically significant, the risk of recurrence from related donor grafts was 6.75 times higher than from unrelated donors (P = .16). To the best of our knowledge, this observation, the first of its kind, has never been investigated or pointed out in the literature.

CONCLUSIONS

Further research is needed to confidently determine whether living related donor grafts are associated with increased incidence of recurrence of nephrotic syndrome.

Mutations in the transmembrane protein nephrin (encoded by NPHS1) underlie nearly half of all cases of congenital nephrotic syndrome (CNS), which is caused by aberrations in the blood filtering function of glomerular podocytes. Nephrin directly contributes to the structure of the filtration barrier, and it also serves as a signaling scaffold in podocytes, undergoing tyrosine phosphorylation on its cytoplasmic tail to recruit intracellular effector proteins. Nephrin phosphorylation is lost in several human and experimental models of glomerular disease, and genetic studies have confirmed its importance in maintenance of the filtration barrier. To date, however, the effect of CNS-associated NPHS1 variants on nephrin phosphorylation remains to be determined, which hampers genotype-phenotype correlations. Here, we have characterized a novel nephrin sequence variant, A419T, which is expressed along with C623F in a patient presenting with CNS. Nephrin localization is altered in kidney biopsies, and we further demonstrate reduced surface expression and ER retention of A419T and C623F in cultured cells. Moreover, we show that both mutations impair nephrin tyrosine phosphorylation, and they exert dominant negative effects on wildtype nephrin signaling. Our findings thus reveal that missense mutations in the nephrin extracellular region can impact nephrin signaling, and they uncover a potential pathomechanism to explain the spectrum of clinical severity seen with mild NPHS1 mutations.