Brandon M Lane1, Susan Murray2, Katherine Benson3, Agnieszka Bierzynska4, Megan Chryst-Stangl1, Liming Wang5, Guanghong Wu1, Gianpiero Cavalleri3, Brendan Doyle6, Neil Fennelly6, Anthony Dorman6, Shane Conlon2, Virginia Vega-Warner7, Damian Fermin7, Poornima Vijayan8, Mohammad Azfar Qureshi8, Shirlee Shril9, Moumita Barua8, Friedhelm Hildebrandt9, Martin Pollak10, David Howell11, Matthew G Sampson9,12, Moin Saleem4, Peter J Conlon2,13, Robert Spurney5, Rasheed Gbadegesin14,5. 1. Division of Nephrology, Department of Pediatrics, Duke Molecular Physiology Institute, Duke University School of Medicine, Durham, North Carolina. 2. Irish Kidney Gene Project, Department of Genetics, Royal College of Surgeons of Ireland, Dublin, Republic of Ireland. 3. School of Pharmacy and Biomolecular Sciences, Royal College of Surgeons of Ireland, Dublin, Republic of Ireland. 4. Department of Pediatrics, Bristol Royal Hospital for Children and University of Bristol, Bristol, United Kingdom. 5. Division of Nephrology, Department of Medicine, Duke University School of Medicine, Durham, North Carolina. 6. Department of Pathology, Beaumont General Hospital, Dublin, Republic of Ireland. 7. Department of Pediatrics, University of Michigan, Ann Arbor, Michigan. 8. Division of Nephrology, Department of Medicine, University of Toronto and Toronto General Hospital, Toronto, Ontario, Canada. 9. Division of Nephrology, Department of Pediatrics, Boston Children's Hospital and Harvard University Medical School, Boston, Massachusetts. 10. Division of Nephrology, Department of Medicine, Beth Israel Hospital and Harvard University Medical School, Boston, Massachusetts. 11. Department of Pathology, Duke University School of Medicine, Durham, North Carolina. 12. Broad Institute of Harvard and Massachusetts Institute of Technology, Cambridge, Massachusetts. 13. Division of Nephrology, Department of Medicine, Beaumont General Hospital, Dublin, Republic of Ireland. 14. Division of Nephrology, Department of Pediatrics, Duke Molecular Physiology Institute, Duke University School of Medicine, Durham, North Carolina rasheed.gbadegesin@duke.edu.
Abstract
BACKGROUND: Podocyte dysfunction is the main pathologic mechanism driving the development of FSGS and other morphologic types of steroid-resistant nephrotic syndrome (SRNS). Despite significant progress, the genetic causes of most cases of SRNS have yet to be identified. METHODS: Whole-genome sequencing was performed on 320 individuals from 201 families with familial and sporadic NS/FSGS with no pathogenic mutations in any known NS/FSGS genes. RESULTS: Two variants in the gene encoding regulator of calcineurin type 1 (RCAN1) segregate with disease in two families with autosomal dominant FSGS/SRNS. In vitro, loss of RCAN1 reduced human podocyte viability due to increased calcineurin activity. Cells expressing mutant RCAN1 displayed increased calcineurin activity and NFAT activation that resulted in increased susceptibility to apoptosis compared with wild-type RCAN1. Treatment with GSK-3 inhibitors ameliorated this elevated calcineurin activity, suggesting the mutation alters the balance of RCAN1 regulation by GSK-3β, resulting in dysregulated calcineurin activity and apoptosis. CONCLUSIONS: These data suggest mutations in RCAN1 can cause autosomal dominant FSGS. Despite the widespread use of calcineurin inhibitors in the treatment of NS, genetic mutations in a direct regulator of calcineurin have not been implicated in the etiology of NS/FSGS before this report. The findings highlight the therapeutic potential of targeting RCAN1 regulatory molecules, such as GSK-3β, in the treatment of FSGS.
BACKGROUND: Podocyte dysfunction is the main pathologic mechanism driving the development of FSGS and other morphologic types of steroid-resistant nephrotic syndrome (SRNS). Despite significant progress, the genetic causes of most cases of SRNS have yet to be identified. METHODS: Whole-genome sequencing was performed on 320 individuals from 201 families with familial and sporadic NS/FSGS with no pathogenic mutations in any known NS/FSGS genes. RESULTS: Two variants in the gene encoding regulator of calcineurin type 1 (RCAN1) segregate with disease in two families with autosomal dominant FSGS/SRNS. In vitro, loss of RCAN1 reduced human podocyte viability due to increased calcineurin activity. Cells expressing mutant RCAN1 displayed increased calcineurin activity and NFAT activation that resulted in increased susceptibility to apoptosis compared with wild-type RCAN1. Treatment with GSK-3 inhibitors ameliorated this elevated calcineurin activity, suggesting the mutation alters the balance of RCAN1 regulation by GSK-3β, resulting in dysregulated calcineurin activity and apoptosis. CONCLUSIONS: These data suggest mutations in RCAN1 can cause autosomal dominant FSGS. Despite the widespread use of calcineurin inhibitors in the treatment of NS, genetic mutations in a direct regulator of calcineurin have not been implicated in the etiology of NS/FSGS before this report. The findings highlight the therapeutic potential of targeting RCAN1 regulatory molecules, such as GSK-3β, in the treatment of FSGS.
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Authors: Brandon M Lane; Megan Chryst-Stangl; Guanghong Wu; Mohamed Shalaby; Sherif El Desoky; Claire C Middleton; Kinsie Huggins; Amika Sood; Alejandro Ochoa; Andrew F Malone; Ricardo Vancini; Sara E Miller; Gentzon Hall; So Young Kim; David N Howell; Jameela A Kari; Rasheed Gbadegesin Journal: JCI Insight Date: 2022-01-25