The purpose of the present study was to determine the role of inositol 1,4,5-trisphosphate receptor 3 (IP₃R3) in renal cyst development in autosomal dominant polycystic kidney disease (ADPKD). 2-aminoethoxy-diphenyl borate (2-APB) and shRNA were used to suppress the expression of IP₃R3. The effect of IP₃R3 on cyst growth was investigated in Madin-Darby canine kidney (MDCK) cyst model, embryonic kidney cyst model and kidney specific Pkd1 knockout (PKD) mouse model. The underlying mechanism of IP₃R3 in promoting renal cyst development was investigated by Western blot and immunofluorescence staining. The results showed that the expression level of IP₃R3 was significantly increased in the kidneys of PKD mice. Inhibiting IP₃R3 by 2-APB or shRNA significantly retarded cyst expansion in MDCK cyst model and embryonic kidney cyst model. Western blot and immunofluorescence staining results showed that hyperactivated cAMP-PKA signaling pathway in the growth process of ADPKD cyst promoted the expression of IP₃R3, which was accompanied by a subcellular redistribution process in which IP₃R3 was translocated from endoplasmic reticulum to intercellular junction. The abnormal expression and subcellular localization of IP₃R3 further promoted cyst epithelial cell proliferation by activating MAPK and mTOR signaling pathways and accelerating cell cycle. These results suggest that the expression and subcellular distribution of IP₃R3 are involved in promoting renal cyst development, which implies IP₃R3 as a potential therapeutic target of ADPKD.
Animals ; Dogs ; Mice ; Cysts/genetics* ; Inositol 1,4,5-Trisphosphate Receptors/pharmacology* ; Kidney/metabolism* ; Polycystic Kidney Diseases/metabolism* ; Polycystic Kidney, Autosomal Dominant/drug therapy* ; Madin Darby Canine Kidney Cells

OBJECTIVE: To detect potential variants in eight Chinese pedigrees affected with autosomal dominant polycystic kidney disease (ADPKD) and provide prenatal diagnosis for two of them. METHODS: Whole exome sequencing and high-throughput sequencing were carried out to detect variants of PKD1 and PKD2 genes in the probands. Sanger sequencing was used to validate the variants, and their pathogenicity was predicted by searching the ADPKD and protein variation databases. RESULTS: Eight PKD1 variants were detected, which have included five nonsense mutations and three missense mutations. Among these, four nonsense variants (PKD1: c.7555C>T, c.7288C>T, c.4957C>T, c.11423G>A) were known to be pathogenic, whilst one missense variant (PKD1: c.2180T>G) was classified as likely pathogenic. Three novel variants were detected, which included c.6781G>T (p.Glu2261*), c.109T>G (p.Cys37Gly) and c.8495A>G (p.Asn2832Ser). Prenatal testing showed that the fetus of one family has carried the same mutation as the proband, while the fetus of another family did not. CONCLUSION PKD1 variants, including three novel variants, have been identified in the eight pedigrees affected with ADPKD. Based on these results, prenatal diagnosis and genetic counseling have been provided.
DNA Mutational Analysis/methods* ; Female ; Humans ; Mutation ; Pedigree ; Polycystic Kidney, Autosomal Dominant/genetics* ; Pregnancy ; Prenatal Diagnosis ; TRPP Cation Channels/genetics*

OBJECTIVE: To detect the mutation site in a pedigree affected with autosomal dominant polycystic kidney disease (ADPKD) and verify its impact on the protein function. METHODS: Peripheral blood samples were collected from the proband and his pedigree members for the extraction of genomic DNA. Mutational analysis was performed on the proband through whole-exome sequencing. Suspected variant was verified by Sanger sequencing. A series of molecular methods including PCR amplification, restriction enzyme digestion, ligation and transformation were also used to construct wild-type and mutant eukaryotic expression vectors of the PKD2 gene, which were transfected into HEK293T and HeLa cells for the observation of protein expression and cell localization. RESULTS: The proband was found to harbor a c.2051dupA (p. Tyr684Ter) frame shift mutation of the PKD2 gene, which caused repeat of the 2051st nucleotide of its cDNA sequence and a truncated protein. Immunofluorescence experiment showed that the localization of the mutant protein within the cell was altered compared with the wild-type, which may be due to deletion of the C-terminus of the PKD2 gene. CONCLUSION The c.2051dupA (p. Tyr684Ter) mutation of the PKD2 gene probably underlay the pathogenesis of ADPKD in this pedigree.
DNA Mutational Analysis ; Female ; Frameshift Mutation ; HEK293 Cells ; HeLa Cells ; Humans ; Male ; Pedigree ; Polycystic Kidney, Autosomal Dominant/physiopathology* ; Protein Kinases/genetics* ; Protein Transport/genetics* ; Whole Exome Sequencing

OBJECTIVE: To carry out genetic analysis for a family with a fetus manifesting bilateral polycystic renal dysplasia and oligohydramnios at 16 gestational week and a previous history for fetal renal anomaly. METHODS: Ultrasound scan was carried out to detect the morphological changes. Following genetic counselling, the parents had decided to terminate the pregnancy. Fetal kidneys were subjected to histological examination. Target capture and next generation sequencing (NGS) was applied to the abortus to detect potential variants. The results were verified by Sanger sequencing. RESULTS: Histological examination of fetal kidneys revealed cystic changes without cortex, medulla or normal renal structure. NGS has identified a heterozygous c.100+1G>A variant and deletion of exon 3 of the INVS gene, which were respectively inherited from the mother and father. CONCLUSION Through NGS and Sanger sequencing, the fetus was diagnosed with type II nephronophthisis (NPHP2). Above result can provide guidance for further pregnancy and enforce understanding of clinical features and genetic etiologies for NPHP.
Female ; Fetus ; Genetic Testing ; Heterozygote ; Humans ; Mutation ; Polycystic Kidney, Autosomal Dominant ; diagnostic imaging ; genetics ; Pregnancy ; Sequence Deletion ; genetics ; Transcription Factors ; genetics ; Ultrasonography

ObjectiveAutosomal dominant polycystic kidney disease (ADPKD) is one of the most common genetic renal diseases, which may cause oligoasthenospermia and azoospermia and result in male infertility. This study aimed to analyze the outcomes of preimplantation genetic diagnosis (PGD) in male patients with ADPKD-induced infertility.

METHODSWe retrospectively analyzed the clinical data on 7 male patients with ADPKD-induced infertility undergoing PGD from April 2015 to February 2017, including 6 cases of oligoasthenospermia and 1 case of obstructive azoospermia, all with the PKD1 gene heterozygous mutations. Following intracytoplasmic sperm injection (ICSI), we performed blastomere biopsy after 5 or 6 days of embryo culture and subjected the blastomeres to Sureplex whole-genome amplification, followed by haplotype linkage analysis, Sanger sequencing, array-based comparative genomic hybridization to assess the chromosomal ploidy of the unaffected embryos, and identification of the unaffected euploid embryos for transfer.

RESULTSOne PGD cycle was completed for each of the 7 patients. Totally, 26 blastocysts were developed, of which 12 were unaffected and diploid. Clinical pregnancies were achieved in 6 cases following 7 cycles of frozen embryo transplantation, which included 5 live births and 1 spontaneous abortion.

CONCLUSIONSFor males with ADPKD-induced infertility, PGD may contribute to high rates of clinical pregnancy and live birth and prevent ADPKD in the offspring as well. This finding is also meaningful for the ADPKD patients with normal fertility.

Abortion, Spontaneous ; genetics ; Biopsy ; Blastocyst ; Comparative Genomic Hybridization ; Embryo Transfer ; Female ; Humans ; Infertility, Male ; etiology ; genetics ; Male ; Mutation ; Polycystic Kidney, Autosomal Dominant ; complications ; diagnosis ; genetics ; prevention & control ; Pregnancy ; Pregnancy Outcome ; Preimplantation Diagnosis ; Retrospective Studies ; Sperm Injections, Intracytoplasmic

OBJECTIVETo determine the molecular etiology for a family affected with autosomal dominant polycystic kidney disease and provide prenatal diagnosis for the family.

METHODSClinical data of the family was collected. Target region sequencing with monogenetic disorders capture array combined with Sanger sequencing and bioinformatics analysis were performed in turn. SIFT and NCB1 were used to evaluate the conservation of the gene and pathogenicity of the identified mutation.

RESULTSTarget region sequencing has identified a novel c.11333C to A (p.T3778N) mutation of the PKD1 gene in the proband and the fetus, which was confirmed by Sanger sequencing in three affected individuals from the family. The same mutation was not detected in healthy members of the pedigree. Bioinformatics analysis suggested that the mutation has caused a likely pathogenic amino acid substitution of Threonine by Aspartic acid, and Clustal analysis indicated that the altered amino acid is highly conserved in mammals.

CONCLUSIONA novel mutation of the PKD1 gene has been identified in an affected Chinese family. The mutation is probably responsible for a range of clinical manifestations, for which reliable prenatal diagnosis and genetic counseling may be provided.

Adult ; Amino Acid Sequence ; Asian Continental Ancestry Group ; genetics ; Base Sequence ; China ; DNA Mutational Analysis ; Exons ; Female ; Humans ; Male ; Middle Aged ; Molecular Sequence Data ; Mutation ; Pedigree ; Polycystic Kidney, Autosomal Dominant ; genetics ; TRPP Cation Channels ; genetics ; Young Adult

OBJECTIVETo identify potential mutations of PKD1 gene in a family affected with autosomal dominant polycystic kidney disease (ADPKD).

METHODSThe coding regions of the PKD1 gene were subjected to PCR and Sanger sequencing. Reverse transcription-PCR (RT-PCR) was used to determine the relative mRNA expression in the patient.

RESULTSA splicing site mutation, c.8791+1_8791+5delGTGCG (IVS23+1_+5delGTGCG), was detected in the PKD1 gene in all 5 patients from the pedigree but not in 6 phenotypically normal relatives and 40 healthy controls. Sequencing of RNA has confirmed that there were 8 bases inserted in the 3' end of exon 23 of the PKD1 gene.

CONCLUSIONThe novel c.8791+1_8791+5delGTGCG mutation has created a new splice site and led to a frameshift, which probably underlies the ADPKD in the family. Above finding has enriched the mutation spectrum of the PKD1 gene.

Adult ; Female ; Humans ; Male ; Mutation ; genetics ; Pedigree ; Polycystic Kidney, Autosomal Dominant ; genetics ; RNA Splicing ; genetics ; TRPP Cation Channels ; genetics ; Young Adult

The primary cilium of renal epithelia acts as a transducer of extracellular stimuli. Polycystin (PC)1 is the protein encoded by the PKD1 gene that is responsible for the most common and severe form of autosomal dominant polycystic kidney disease (ADPKD). PC1 forms a complex with PC2 via their respective carboxy-terminal tails. Both proteins are expressed in the primary cilia. Mutations in either gene affect the normal architecture of renal tubules, giving rise to ADPKD. PC1 has been proposed as a receptor that modulates calcium signals via the PC2 channel protein. The effect of PC1 dosage has been described as the rate-limiting modulator of cystic disease. Reduced levels of PC1 or disruption of the balance in PC1/PC2 level can lead to the clinical features of ADPKD, without complete inactivation. Recent data show that ADPKD resulting from inactivation of polycystins can be markedly slowed if structurally intact cilia are also disrupted at the same time. Despite the fact that no single model or mechanism from these has been able to describe exclusively the pathogenesis of cystic kidney disease, these findings suggest the existence of a novel cilia-dependent, cyst-promoting pathway that is normally repressed by polycystin function. The results enable us to rethink our current understanding of genetics and cilia signaling pathways of ADPKD.
Calcium ; Cilia* ; Genetics ; Kidney Diseases, Cystic ; Polycystic Kidney, Autosomal Dominant* ; Transducers ; TRPP Cation Channels*

Adolescent ; Child ; Child, Preschool ; DNA Mutational Analysis ; Diagnosis, Differential ; Humans ; Infant ; Infant, Newborn ; Liver Diseases ; diagnosis ; genetics ; pathology ; Lung Diseases ; diagnosis ; genetics ; pathology ; Magnetic Resonance Imaging ; Mutation ; Polycystic Kidney, Autosomal Dominant ; diagnosis ; genetics ; pathology ; Polycystic Kidney, Autosomal Recessive ; diagnosis ; genetics ; pathology ; Prenatal Diagnosis ; Receptors, Cell Surface ; genetics ; Tomography, X-Ray Computed

OBJECTIVETo identify the responsible mutation of autosomal dominant polycystic kidney disease (ADPKD) in two Chinese families.

METHODSTotal genomic DNA of all available family members and 100 unrelated healthy controls was extracted from peripheral blood leukocytes using a standard phenol-chloroform procedure. All exons with intronic flanking sequences of the PKD1 and PKD2 genes in the probands were amplified by PCR. Mutations were detected directly by DNA sequencing. To evaluate the pathogenicity of the variations, family and control based analyses were performed.

RESULTSFive sequence variants were identified in the two families including PKD1 :c.2469G to A, PKD1:c.5014_5015delAG, PKD1:c.10529 C to T, PKD2:c.568G to A and PKD2:c.2020 1_2020delAG. Among them, PKD1:c.2469G to A and PKD2:c.2020 1_2020 delAG were novel mutations. Furthermore, the frameshift and splicing site mutations detected in the affected individuals were not detected in their unaffected relatives and 100 unrelated normal controls.

CONCLUSIONPKD1:c.5014_5015delAG and PKD2:c.2020 1_2020delAG are the responsible mutations of family A and B, respectively, and PKD2:c.2020 1_2020delAG is a de novo mutation.

Adult ; Amino Acid Substitution ; Asian Continental Ancestry Group ; genetics ; Base Sequence ; China ; Exons ; Female ; Humans ; Male ; Middle Aged ; Mutation ; genetics ; Polycystic Kidney, Autosomal Dominant ; genetics ; Polymorphism, Single Nucleotide ; genetics ; TRPP Cation Channels ; genetics