NPHS2 mutation analysis shows genetic heterogeneityof steroid-resistant nephrotic syndrome and lowpost-transplant recurrence

NPHS2 mutation analysis shows genetic heterogeneity of steroid-resistant nephrotic syndrome and low post-transplant recurrence.BackgroundMutations of NPHS2 are causative in familial autosomal-recessive (AR) and sporadic steroid-resistant nephrotic syndrome (SRNS). This study aimed to determine the spectrum of NPHS2 mutations and to establish genotype-phenotype correlations.MethodsNPHS2 mutation analysis was performed in 338 patients from 272 families with SRNS: 81 families with AR SRNS, 172 patients with sporadic SRNS, and 19 patients with diffuse mesangial sclerosis (DMS).ResultsTwenty-six different pathogenic NPHS2 mutations were detected, including 13 novel mutations. The mutation detection rate was 43% for familial AR and 10.5% for sporadic SRNS, confirming genetic heterogeneity. No pathogenic NPHS2 mutations were found in DMS patients. Age at onset in patients with two pathogenic mutations was earlier, especially in cases with frameshift, truncating, and the R138Q missense mutations. Patients with only one NPHS2 mutation or variant had late-onset NS. Triallelic inheritance was observed in one patient with a homozygous R138Q mutation and a de novo NPHS1 mutation. Among 32 patients with two NPHS2 mutations who underwent kidney transplantation, only one developed late recurrence of focal segmental glomerulosclerosis (FSGS). Among 25 patients with sporadic SRNS and post-transplantation recurrence, we detected a heterozygous NPHS2 mutation in one case, and heterozygous variants/polymorphisms in 3 cases.ConclusionPatients with two pathogenic NPHS2 mutations present with early-onset SRNS and very low incidence of post-transplantation recurrence. Heterozygous NPHS2 variants may play a role in atypical cases with mild, late-onset course, and recurrence after transplantation

NPHS2 mutation analysis shows genetic heterogeneityof steroid-resistant nephrotic syndrome and lowpost-transplant recurrence

NPHS2 mutation analysis shows genetic heterogeneity of steroid-resistant nephrotic syndrome and low post-transplant recurrence.BackgroundMutations of NPHS2 are causative in familial autosomal-recessive (AR) and sporadic steroid-resistant nephrotic syndrome (SRNS). This study aimed to determine the spectrum of NPHS2 mutations and to establish genotype-phenotype correlations.MethodsNPHS2 mutation analysis was performed in 338 patients from 272 families with SRNS: 81 families with AR SRNS, 172 patients with sporadic SRNS, and 19 patients with diffuse mesangial sclerosis (DMS).ResultsTwenty-six different pathogenic NPHS2 mutations were detected, including 13 novel mutations. The mutation detection rate was 43% for familial AR and 10.5% for sporadic SRNS, confirming genetic heterogeneity. No pathogenic NPHS2 mutations were found in DMS patients. Age at onset in patients with two pathogenic mutations was earlier, especially in cases with frameshift, truncating, and the R138Q missense mutations. Patients with only one NPHS2 mutation or variant had late-onset NS. Triallelic inheritance was observed in one patient with a homozygous R138Q mutation and a de novo NPHS1 mutation. Among 32 patients with two NPHS2 mutations who underwent kidney transplantation, only one developed late recurrence of focal segmental glomerulosclerosis (FSGS). Among 25 patients with sporadic SRNS and post-transplantation recurrence, we detected a heterozygous NPHS2 mutation in one case, and heterozygous variants/polymorphisms in 3 cases.ConclusionPatients with two pathogenic NPHS2 mutations present with early-onset SRNS and very low incidence of post-transplantation recurrence. Heterozygous NPHS2 variants may play a role in atypical cases with mild, late-onset course, and recurrence after transplantation

Podocin Inactivation in Mature Kidneys Causes Focal Segmental Glomerulosclerosis and Nephrotic Syndrome

Podocin is a critical component of the glomerular slit diaphragm, and genetic mutations lead to both familial and sporadic forms of steroid-resistant nephrotic syndrome. In mice, constitutive absence of podocin leads to rapidly progressive renal disease characterized by mesangiolysis and/or mesangial sclerosis and nephrotic syndrome. Using established Cre-loxP technology, we inactivated podocin in the adult mouse kidney in a podocyte-specific manner. Progressive loss of podocin in the glomerulus recapitulated albuminuria, hypercholesterolemia, hypertension, and renal failure seen in nephrotic syndrome in humans. Lesions of FSGS appeared after 4 wk, with subsequent development of diffuse glomerulosclerosis and tubulointerstitial damage. Interestingly, conditional inactivation of podocin at birth resulted in a gradient of glomerular lesions, including mesangial proliferation, demonstrating a developmental stage dependence of renal histologic patterns of injury. The development of significant albuminuria in this model occurred only after early and focal foot process effacement had progressed to diffuse involvement, with complete absence of podocin immunolabeling at the slit diaphragm. Finally, we identified novel potential mediators and perturbed molecular pathways, including cellular proliferation, in the course of progression of renal disease leading to glomerulosclerosis, using global gene expression profiling

Maternal Environment Interacts with Modifier Genes to Influence Progression of Nephrotic Syndrome

Mutations in the NPHS2 gene, which encodes podocin, are responsible for some cases of sporadic and familial autosomal recessive steroid-resistant nephrotic syndrome. Inter- and intrafamilial variability in the progression of renal disease among patients bearing NPHS2 mutations suggests a potential role for modifier genes. Using a mouse model in which the podocin gene is constitutively inactivated, we sought to identify genetic determinants of the development and progression of renal disease as a result of the nephrotic syndrome. We report that the evolution of renal disease as a result of nephrotic syndrome in Nphs2-null mice depends on genetic background. Furthermore, the maternal environment significantly interacts with genetic determinants to modify survival and progression of renal disease. Quantitative trait locus mapping suggested that these genetic determinants may be encoded for by genes on the distal end of chromosome 3, which are linked to proteinuria, and on the distal end of chromosome 7, which are linked to a composite trait of urea, creatinine, and potassium. These loci demonstrate epistatic interactions with other chromosomal regions, highlighting the complex genetics of renal disease progression. In summary, constitutive inactivation of podocin models the complex interactions between maternal and genetically determined factors on the progression of renal disease as a result of nephrotic syndrome in mice

Nephrin Mutations Can Cause Childhood-Onset Steroid-Resistant Nephrotic Syndrome

Classically, infants with mutations in NPHS1, which encodes nephrin, present with nephrotic syndrome within the first 3 mo of life (congenital nephrotic syndrome of the Finnish-type), and children with mutations in NPHS2, which encodes podocin, present later with steroid-resistant nephrotic syndrome. Recently, however, NPHS2 mutations have been identified in children with congenital nephrotic syndrome. Whether NPHS1 mutations similarly account for some cases of childhood steroid-resistant nephrotic syndrome is unknown. In this study, 160 patients who belonged to 142 unrelated families and presented with nephrotic syndrome at least 3 mo after birth were screened for NPHS1 variants once mutations in NPHS2 had been excluded. Compound heterozygous NPHS1 mutations were identified in one familial case and nine sporadic cases. Mutations included protein-truncating nonsense and frameshift mutations, as well as splice-site and missense variants. Mutations were classified as “severe” or “mild” using prediction algorithms and functional assays. Most missense variants trafficked normally to the plasma membrane and maintained the ability to form nephrin homodimers and to heterodimerize with NEPH1, suggesting retained function. The presence of at least one “mild” mutation in these patients likely explains the later onset and milder course of disease. These results broaden the spectrum of renal disease related to nephrin mutations