Yu L Phua1, Jacqueline Ho. 1. aRangos Research Center, Children's Hospital of Pittsburgh of UPMC bDepartment of Pediatrics, Division of Nephrology, School of Medicine, University of Pittsburgh, Pittsburgh, Pennsylvania, USA.
Abstract
PURPOSE OF REVIEW: Renal dysplasia is classically described as a developmental disorder whereby the kidneys fail to undergo appropriate differentiation, resulting in the presence of malformed renal tissue elements. It is the commonest cause of chronic kidney disease and renal failure in the neonate. Although several genes have been identified in association with renal dysplasia, the underlying molecular mechanisms are often complex and heterogeneous in nature, and remain poorly understood. RECENT FINDINGS: In this review, we describe new insights into the fundamental process of normal kidney development, and how the renal cortex and medulla are patterned appropriately during gestation. We review the key genes that are indispensable for this process, and discuss how patterning of the kidney is perturbed in the absence of these signaling pathways. The recent use of whole exome sequencing has identified genetic mutations in patients with renal dysplasia, and the results of these studies have increased our understanding of the pathophysiology of renal dysplasia. SUMMARY: At present, there are no specific treatments available for patients with renal dysplasia. Understanding the molecular mechanisms of normal kidney development and the pathogenesis of renal dysplasia may allow for improved therapeutic options for these patients.
PURPOSE OF REVIEW: Renal dysplasia is classically described as a developmental disorder whereby the kidneys fail to undergo appropriate differentiation, resulting in the presence of malformed renal tissue elements. It is the commonest cause of chronic kidney disease and renal failure in the neonate. Although several genes have been identified in association with renal dysplasia, the underlying molecular mechanisms are often complex and heterogeneous in nature, and remain poorly understood. RECENT FINDINGS: In this review, we describe new insights into the fundamental process of normal kidney development, and how the renal cortex and medulla are patterned appropriately during gestation. We review the key genes that are indispensable for this process, and discuss how patterning of the kidney is perturbed in the absence of these signaling pathways. The recent use of whole exome sequencing has identified genetic mutations in patients with renal dysplasia, and the results of these studies have increased our understanding of the pathophysiology of renal dysplasia. SUMMARY: At present, there are no specific treatments available for patients with renal dysplasia. Understanding the molecular mechanisms of normal kidney development and the pathogenesis of renal dysplasia may allow for improved therapeutic options for these patients.
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