An Integrated Genetic and Physical Map of the Autosomal Recessive Polycystic Kidney Disease Region (original) (raw)
Related papers
Spectrum of Mutations in the Gene for Autosomal Recessive Polycystic Kidney Disease (ARPKD/PKHD1)
Journal of the American Society of Nephrology, 2003
Autosomal recessive polycystic kidney disease (ARPKD/PKHD1) is an important cause of renal-related and liver-related morbidity and mortality in childhood. Recently mutations in the PKHD1 gene on chromosome 6p21.1-p12 have been identified as the molecular cause of ARPKD. The longest continuous open reading frame (ORF) is encoded by a 67-exon transcript and predicted to yield a 4074-amino acid protein ("polyductin") of thus far unknown function. By now, a total of 29 different PKHD1 mutations have been described. This study reports mutation screening in 90 ARPKD patients and identifies mutations in 110 alleles making up a detection rate of 61%. Thirty-four of the detected mutations have not been reported previously. Two underlying mutations in 40 patients and one mutation in 30 cases are disclosed, and no mutation was detected on the remaining chromosomes. Mutations were found to be scattered throughout the gene without evidence of clustering at specific sites. About 45% of the
Genomics, 1998
We recently mapped the gene for ARPKD to chromo-A total of 33 polymorphic markers were analyzed to some 6p21-cen , refined the map, generate a high-resolution genetic linkage map of the and defined flanking markers and locus PKHD1 (polycystic kidney and hepatic disease 1) were able to confirm linkage of the severe phenotype to for the autosomal recessive polycystic kidney disease the same locus in 21 European and American families (ARPKD), using a combination of recombination map- (Guay-Woodford et al., 1995). The polycystic kidney ping and linkage analysis in 164 families. Recombinants and hepatic disease 1 (PKHD1) interval was narrowed narrowed the PKHD1 region from 3.8 cM to a 1-cM interto a genetic distance of approximately 3.8 cM. No evival flanked by the markers D6S1024 and D6S1714. Linkdence of genetic heterogeneity was found. A physical age disequilibrium analysis in 13 Finnish ARPKD famimap of the critical region suggests that the length of lies identified two different highly conserved haplothe interval is less than 3.1 Mb (Lens et al., 1997).
Incompletely Penetrant PKD1 Alleles Mimic the Renal Manifestations of ARPKD
Autosomal dominant polycystic kidney disease (ADPKD), caused by mutation in PKD1 or PKD2, is usually an adult-onset disorder but can rarely manifest as a neonatal disease within a family characterized by otherwise typical ADPKD. Coinheritance of a hypomorphic PKD1 allele in trans with an inactivating PKD1 allele is one mechanism that can cause early onset ADPKD. Here, we describe two pedigrees without a history of cystic kidney disease that each contain two patients with onset of massive PKD in utero. The presentations were typical of autosomal recessive PKD (ARPKD) but they were not linked to the known ARPKD gene, PKHD1. Mutation analysis of the ADPKD genes provided strong evidence that both families inherited, in trans, two incompletely penetrant PKD1 alleles. These patients illustrate that PKD1 mutations can manifest as a phenocopy of ARPKD with respect to renal involvement and highlight the perils of linkage-based diagnostics in ARPKD without positive PKHD1 mutation data. Furthermore, the phenotypic overlap between ARPKD and these patients resulting from incomplete penetrant PKD1 alleles support a common pathogenesis for these diseases.
Comprehensive genetic testing in children with a clinical diagnosis of ARPKD identifies phenocopies
Pediatric nephrology (Berlin, Germany), 2018
Autosomal recessive polycystic kidney disease (ARPKD) is genetically one of the least heterogeneous ciliopathies, resulting primarily from mutations of PKHD1. Nevertheless, 13-20% of patients diagnosed with ARPKD are found not to carry PKHD1 mutations by sequencing. Here, we assess whether PKHD1 copy number variations or second locus mutations explain these cases. Thirty-six unrelated patients with the clinical diagnosis of ARPKD were screened for PKHD1 point mutations and copy number variations. Patients without biallelic mutations were re-evaluated and screened for second locus mutations targeted by the phenotype, followed, if negative, by clinical exome sequencing. Twenty-eight patients (78%) carried PKHD1 point mutations, three of whom on only one allele. Two of the three patients harbored in trans either a duplication of exons 33-35 or a large deletion involving exons 1-55. All eight patients without PKHD1 mutations (22%) harbored mutations in other genes (PKD1 (n = 2), HNF1B (...
Pediatric research, 2002
for their help with both technical and experimental issues and well as lively scientific discussions. I would like to thank the Department of Molecular Biology and Microbiology staff and faculty for their administrative help and support. I would also like to thank the Neurosciences Imaging Center and Maryanne Pendergast for the patient technical support. Lastly, I would like to thank my friends and family that have supported and encouraged me throughout this project.
Pediatric Nephrology, 2013
Autosomal recessive polycystic kidney disease (ARPKD), although less frequent than the dominant form, is a common, inherited ciliopathy of childhood that is caused by mutations in the PKHD1-gene on chromosome 6. The characteristic dilatation of the renal collecting ducts starts in utero and can present at any stage from infancy to adulthood. Renal insufficiency may already begin in utero and may lead to early abortion or oligohydramnios and lung hypoplasia in the newborn. However, there are also affected children who have no evidence of renal dysfunction in utero and who are born with normal renal function. Up to 30 % of patients die in the perinatal period, and those surviving the neonatal period reach end stage renal disease (ESRD) in infancy, early childhood or adolescence. In contrast, some affected patients have been diagnosed as adults with renal function ranging from normal to moderate renal insufficiency to ESRD. The clinical spectrum of ARPKD is broader than previously recognized. While bilateral renal enlargement with microcystic dilatation is the predominant clinical feature, arterial hypertension, intrahepatic biliary dysgenesis remain important manifestations that affect approximately 45 % of infants. All patients with ARPKD develop clinical findings of congenital hepatic fibrosis (CHF); however, non-obstructive dilation of the intrahepatic bile ducts in the liver (Caroli's disease) is seen at the histological level in only a subset of patients. Cholangitis and variceal bleeding, sequelae of portal hypertension, are life-threatening complications that may occur more often in advanced cases of liver disease. In this review we focus on common and uncommon kidney-related and non-kidney-related phenotypes. Clinical management of ARPKD patients should include consideration of potential problems related to these manifestations.
PKD1 and PKD2 mutations in Slovenian families with autosomal dominant polycystic kidney disease
BMC Medical Genetics, 2006
Background Autosomal dominant polycystic kidney disease (ADPKD) is a genetically heterogeneous disorder caused by mutations in at least two different loci. Prior to performing mutation screening, if DNA samples of sufficient number of family members are available, it is worthwhile to assign the gene involved in disease progression by the genetic linkage analysis. Methods We collected samples from 36 Slovene ADPKD families and performed linkage analysis in 16 of them. Linkage was assessed by the use of microsatellite polymorphic markers, four in the case of PKD1 (KG8, AC2.5, CW3 and CW2) and five for PKD2 (D4S1534, D4S2929, D4S1542, D4S1563 and D4S423). Partial PKD1 mutation screening was undertaken by analysing exons 23 and 31–46 and PKD2 . Results Lod scores indicated linkage to PKD1 in six families and to PKD2 in two families. One family was linked to none and in seven families linkage to both genes was possible. Partial PKD1 mutation screening was performed in 33 patients (including 20 patients from the families where linkage analysis could not be performed). We analysed PKD2 in 2 patients where lod scores indicated linkage to PKD2 and in 7 families where linkage to both genes was possible. We detected six mutations and eight polymorphisms in PKD1 and one mutation and three polymorphisms in PKD2. Conclusion In our study group of ADPKD patients we detected seven mutations: three frameshift, one missense, two nonsense and one putative splicing mutation. Three have been described previously and 4 are novel. Three newly described framesfift mutations in PKD1 seem to be associated with more severe clinical course of ADPKD. Previously described nonsense mutation in PKD2 seems to be associated with cysts in liver and milder clinical course.