The four lead investigators of this project have assembled ~10,000 patients with focal and segmental glomerulosclerosis (FSGS) and steroid-resistant nephrotic syndrome (SRNS). With this largest ever FSGS/NS cohort assembled, the vast majority whom have already undergone genome-wide sequencing, we propose a collaborative effort to understand the genetic basis of this disease. The increasing number of identified genes that can cause FSGS/SRNS when altered shows that these phenotypes are genetically highly complex. Understanding the genetic basis of FSGS and NS is important: (1) Work to date has been the major driver in understanding the molecular structure of the glomerulus; (2) Genetic diagnosis affects therapy: some mutations predict lack of response to steroid therapies, others predict response to nutritional supplementation; (3) Genetics affects renal transplant planning and outcome. Major gaps remain: (1) Most FSGS/NS cases still are genetically unresolved; (2) The basis of disease is complex and involves the contribution of different variants across the spectrum of allelic frequency and penetrance; (3) Our ability to declare genetic causality at the single-patient level is limited; (4) Therapeutic options are limited. Thus, we will use this large cohort and new analytic methods to address these gaps. We will functionally characterize many of the new alleles and new FSGS genes that we discover. We will develop and distribute reagents, including patient-derived iPS cells. We will create a database by aggregating exome and genome sequencing data from our patients, and make this data available via web browser to assist the research community. We plan to:
Aim 1 : Understand the spectrum of rare genetic variation that causes (or increases risk of) FSGS and NS in humans. By leveraging large sample sizes, we can use approaches that are not otherwise powerful enough for disease gene identification. We will discover novel genes associated with FSGS/NS to identify highly penetrant variants (including burden tests of rare sequence changes and copy-number variants), define the spectrum of SNV and structural variants in known FSGS/NS genes, and identify glomerular genes co-expressed with disease-related genes.
Aim 2 : Define functional effects of disease-associated variants. We will test effects of variants/mutations in cell-based assays, develop new zebrafish models by mutating FSGS/NS genes, and generate a panel of iPS cells from patients with FSGS/NS-associated mutations.
Aim 3 : We will bring together all of our genotyping data, generated from SNP arrays, WES, and WGS, to build and maintain a publicly available variant browser, the ?Nephrotic Syndrome Genomic Portal? (NSGP). NSGP will include allele frequency data, functional classification, and clinical correlates for FSGS/NS. We will summarize, at a site- level, SNVs, insertion-deletions, structural variants (CNV) observed in our FSGS/NS cohort and provide quality metrics of variants reported. NSGP will also have the capability to accept and incorporate data from other investigators and clinical genetics laboratories.
The identification of new focal segmental glomerulosclerosis (FSGS) and nephrotic syndrome (NS) genes and further genetic characterization of known FSGS/NS genes will have significant implications for understanding, and ultimately, treating, common forms of kidney disease and progression to kidney failure. In the more immediate future, identification and characterization of FSGS/NS gene defects will have implications for the development of diagnostic tools. !
