Detection of PKD1 and PKD2 Somatic Variants in Autosomal Dominant Polycystic Kidney Cyst Epithelial Cells by Whole-Genome Sequencing.

BACKGROUND: Autosomal dominant polycystic kidney disease (ADPKD) is a genetic disorder characterized by the development of multiple cysts in the kidneys. It is often caused by pathogenic mutations in PKD1 and PKD2 genes that encode polycystin proteins. Although the molecular mechanisms for cystogenesis are not established, concurrent inactivating germline and somatic mutations in PKD1 and PKD2 have been previously observed in renal tubular epithelium (RTE). METHODS: To further investigate the cellular recessive mechanism of cystogenesis in RTE, we conducted whole-genome DNA sequencing analysis to identify germline variants and somatic alterations in RTE of 90 unique kidney cysts obtained during nephrectomy from 24 unrelated participants. RESULTS: Kidney cysts were overall genomically stable, with low burdens of somatic short mutations or large-scale structural alterations. Pathogenic somatic "second hit" alterations disrupting PKD1 or PKD2 were identified in 93% of the cysts. Of these, 77% of cysts acquired short mutations in PKD1 or PKD2 ; specifically, 60% resulted in protein truncations (nonsense, frameshift, or splice site) and 17% caused non-truncating mutations (missense, in-frame insertions, or deletions). Another 18% of cysts acquired somatic chromosomal loss of heterozygosity (LOH) events encompassing PKD1 or PKD2 ranging from 2.6 to 81.3 Mb. 14% of these cysts harbored copy number neutral LOH events, while the other 3% had hemizygous chromosomal deletions. LOH events frequently occurred at chromosomal fragile sites, or in regions comprising chromosome microdeletion diseases/syndromes. Almost all somatic "second hit" alterations occurred at the same germline mutated PKD1/2 gene. CONCLUSIONS: These findings further support a cellular recessive mechanism for cystogenesis in ADPKD primarily caused by inactivating germline and somatic variants of PKD1 or PKD2 genes in kidney cyst epithelium.

Somatic Mutations in Renal Cyst Epithelium in Autosomal Dominant Polycystic Kidney Disease.

BACKGROUND: Autosomal dominant polycystic kidney disease (ADPKD) is a ciliopathy caused by mutations in PKD1 and PKD2 that is characterized by renal tubular epithelial cell proliferation and progressive CKD. Although the molecular mechanisms involved in cystogenesis are not established, concurrent inactivating constitutional and somatic mutations in ADPKD genes in cyst epithelium have been proposed as a cellular recessive mechanism. METHODS: We characterized, by whole-exome sequencing (WES) and long-range PCR techniques, the somatic mutations in PKD1 and PKD2 genes in renal epithelial cells from 83 kidney cysts obtained from nine patients with ADPKD, for whom a constitutional mutation in PKD1 or PKD2 was identified. RESULTS: Complete sequencing data by long-range PCR and WES was available for 63 and 65 cysts, respectively. Private somatic mutations of PKD1 or PKD2 were identified in all patients and in 90% of the cysts analyzed; 90% of these mutations were truncating, splice site, or in-frame variations predicted to be pathogenic mutations. No trans-heterozygous mutations of PKD1 or PKD2 genes were identified. Copy number changes of PKD1 ranging from 151 bp to 28 kb were observed in 12% of the cysts. WES also identified significant mutations in 53 non-PKD1/2 genes, including other ciliopathy genes and cancer-related genes. CONCLUSIONS: These findings support a cellular recessive mechanism for cyst formation in ADPKD caused primarily by inactivating constitutional and somatic mutations of PKD1 or PKD2 in kidney cyst epithelium. The potential interactions of these genes with other ciliopathy- and cancer-related genes to influence ADPKD severity merits further evaluation.

Evaluation of a human adenovirus viral load assay using the Altona RealStar® PCR test.

This study evaluated the performance of the Altona Diagnostics RealStar® Adenovirus Research Use Only (RUO) real-time PCR reagents for HAdV quantitation in plasma samples from immunodeficient patients. The assay was linear from 2.30-9.17 log10 copies/mL (coefficient of determination; R2=0.998) with limits of detection and quantification of 2.19 log10 and 2.30 log10 copies/mL (>95% positivity rate), respectively. Assay precision was highly reproducible with coefficients of variance ranging from 0% to 4.7%. A comparison of 66 matched samples showed good agreement (R2=0.845) between the Altona and the reference laboratory assay, with an average negative bias (-0.24 log10 copies/mL). Genotyping analysis demonstrated that HAdV species B and C accounted for 77% of the positive samples. A significant (≥0.9 log10) difference in quantitation between both tests was found for three HAdV types (HAdV types A12, B14 and F41). In conclusion, the Altona RealStar® test is a reliable and sensitive assay for HAdV DNA quantitation.

Papillary renal cell carcinoma with a somatic mutation in MET in a patient with autosomal dominant polycystic kidney disease.

Autosomal-dominant polycystic kidney disease (ADPKD) is caused by mutations in PKD1 and PKD2 and is characterized by proliferation of renal tubular epithelium and progressive chronic kidney disease. Derangements in similar cellular signaling pathways occur in ADPKD and renal malignancies, although an association of these disorders has not been established. Herein, we present a case of papillary RCC (pRCC) incidentally discovered in a patient with ADPKD following bilateral native nephrectomy during renal transplantation. Whole exome sequencing of the pRCC found a somatic missense mutation in MET proto-oncogene, p.Val1110Ile, not present in kidney cyst epithelium or non-cystic tissue. RNA sequencing demonstrated increased mRNA expression of MET and pathway-related genes, but no significant copy number variation of MET was detected. Genetic analysis of PKD genes from peripheral blood lymphocytes and renal cyst epithelium identified a constitutional PKD1 germline mutation, p.Trp1582Ser, predicted to be pathogenic. Unique somatic mutations in PKD1 were also detected in 80% of the renal cysts analyzed, but not in the pRCC. These results suggest that, in this patient, the pRCC utilized a signaling pathway involving MET that was distinct from the pathogenesis of ADPKD. This is the first report of PKD1 mutations and a somatic mutation of the MET oncogene in a pRCC in ADPKD.

Development and validation of a whole genome amplification long-range PCR sequencing method for ADPKD genotyping of low-level DNA samples.

Autosomal dominant polycystic kidney disease (ADPKD) is caused by mutations in two large genes, PKD1 and PKD2, but genetic testing is complicated by the large transcript sizes and the duplication of PKD1 exons 1-33 as six pseudogenes on chromosome 16. Long-range PCR (LR-PCR) represents the gold standard approach for PKD1 genetic analysis. However, a major issue with this approach is that it requires large quantities of genomic DNA (gDNA) material limiting its application primarily to DNA extracted from blood. In this study, we have developed a whole genome amplification (WGA)-based genotyping assay for PKD1 and PKD2, and examined whether this approach can be applied to biosamples with low DNA yield, including blood, buccal cells and urine. DNA samples were amplified by multiple displacement amplification (MDA) and a high-fidelity DNA polymerase followed by LR-PCR and exon-specific amplifications of PKD1 and PKD2 respectively, and Sanger sequencing. This method has generated large amounts of DNA with high average product length (>10 kb), which were uniformly amplified across all sequences assessed. When compared to the gDNA direct sequencing method for six ADPKD samples, a total of 89 variants were detected including all 86 variations previously reported, in addition to three new variations, including one pathogenic mutation not previously detected by the standard gDNA-based analysis. We have further applied WGA to ADPKD mutation analysis of low DNA-yield specimens, successfully detecting all 63 gene variations. Compared to the gDNA method the WGA-based assay had a sensitivity and specificity of 100%. In conclusion, WGA-based LR-PCR represents a major technical improvement for PKD genotyping from trace amounts of DNA.

Molecular diagnosis of autosomal dominant polycystic kidney disease using next-generation sequencing.

Autosomal dominant polycystic kidney disease (ADPKD) is caused by mutations in PKD1 and PKD2. However, genetic analysis is complicated by six PKD1 pseudogenes, large gene sizes, and allelic heterogeneity. We developed a new clinical assay for PKD gene analysis using paired-end next-generation sequencing (NGS) by multiplexing individually bar-coded long-range PCR libraries and analyzing them in one Illumina MiSeq flow cell. The data analysis pipeline has been optimized and automated with Unix shell scripts to accommodate variant calls. This approach was validated using a cohort of 25 patients with ADPKD previously analyzed by Sanger sequencing. A total of 250 genetic variants were identified by NGS, spanning the entire exonic and adjacent intronic regions of PKD1 and PKD2, including all 16 pathogenic mutations. In addition, we identified three novel mutations in a mutation-negative cohort of 24 patients with ADPKD previously analyzed by Sanger sequencing. This NGS method achieved sensitivity of 99.2% (95% CI, 96.8%-99.9%) and specificity of 99.9% (95% CI, 99.7%-100.0%), with cost and turnaround time reduced by as much as 70%. Prospective NGS analysis of 25 patients with ADPKD demonstrated a detection rate comparable with Sanger standards. In conclusion, the NGS method was superior to Sanger sequencing for detecting PKD gene mutations, achieving high sensitivity and improved gene coverage. These characteristics suggest that NGS would be an appropriate new standard for clinical genetic testing of ADPKD.

A novel long-range PCR sequencing method for genetic analysis of the entire PKD1 gene.

Genetic testing of PKD1 and PKD2 is useful for the diagnosis and prognosis of autosomal dominant polycystic kidney disease; however, analysis is complicated by the large transcript size, the complexity of the gene region, and the high level of gene variations. We developed a novel mutation screening assay for PKD1 by directly sequencing long-range (LR) PCR products. By using this method, the entire PKD1 coding region was amplified by nine reactions, generating product sizes from 2 to 6 kb, circumventing the need for specific PCR amplification of individual exons. This method was compared with direct sequencing used by a reference laboratory and the SURVEYOR-WAVE Nucleic Acid High Sensitivity Fragment Analysis System (Transgenomic) screening method for five patients with autosomal dominant polycystic kidney disease. A total of 53 heterozygous genetic changes were identified by LR PCR sequencing, including 41 (of 42) variations detected by SURVEYOR nuclease and all 32 variations reported by the reference laboratory, detecting an additional 12 intronic changes not identified by the other two methods. Compared with the reference laboratory, LR PCR sequencing had a sensitivity of 100%, a specificity of 98.5%, and an accuracy of 98.8%; compared with the SURVEYOR-WAVE method, it had a sensitivity of 97.1%, a specificity of 100%, and an accuracy of 99.4%. In conclusion, LR PCR sequencing was superior to the direct sequencing and screening methods for detecting genetic variations, achieving high sensitivity and improved intronic coverage with a faster turnaround time and lower costs, and providing a reliable tool for complex genetic analyses.