PKD1 interacts with PKD2 through a probable coiled-coil domain.

Autosomal dominant polycystic kidney disease (ADPKD) describes a group of at least three genetically distinct disorders with almost identical clinical features that collectively affects 1:1,000 of the population. Affected individuals typically develop large cystic kidneys and approximately one half develop end-stage renal disease by their seventh decade. It has been suggested that the diseases result from defects in interactive factors involved in a common pathway. The recent discovery of the genes for the two most common forms of ADPKD has provided an opportunity to test this hypothesis. We describe a previously unrecognized coiled-coil domain within the C terminus of the PKD1 gene product, polycystin, and demonstrate that it binds specifically to the C terminus of PKD2. Homotypic interactions involving the C terminus of each are also demonstrated. We show that naturally occurring pathogenic mutations of PKD1 and PKD2 disrupt their associations. We have characterized the structural basis of their heterotypic interactions by deletional and site-specific mutagenesis. Our data suggest that PKD1 and PKD2 associate physically in vivo and may be partners of a common signalling cascade involved in tubular morphogenesis.

Cardiac defects and renal failure in mice with targeted mutations in Pkd2.

PKD2, mutations in which cause autosomal dominant polycystic kidney disease (ADPKD), encodes an integral membrane glycoprotein with similarity to calcium channel subunits. We induced two mutations in the mouse homologue Pkd2 (ref.4): an unstable allele (WS25; hereafter denoted Pkd2WS25) that can undergo homologous-recombination-based somatic rearrangement to form a null allele; and a true null mutation (WS183; hereafter denoted Pkd2-). We examined these mutations to understand the function of polycystin-2, the protein product of Pkd2, and to provide evidence that kidney and liver cyst formation associated with Pkd2 deficiency occurs by a two-hit mechanism. Pkd2-/- mice die in utero between embryonic day (E) 13.5 and parturition. They have structural defects in cardiac septation and cyst formation in maturing nephrons and pancreatic ducts. Pancreatic ductal cysts also occur in adult Pkd2WS25/- mice, suggesting that this clinical manifestation of ADPKD also occurs by a two-hit mechanism. As in human ADPKD, formation of kidney cysts in adult Pkd2WS25/- mice is associated with renal failure and early death (median survival, 65 weeks versus 94 weeks for controls). Adult Pkd2+/- mice have intermediate survival in the absence of cystic disease or renal failure, providing the first indication of a deleterious effect of haploinsufficiency at Pkd2on long-term survival. Our studies advance our understanding of the function of polycystin-2 in development and our mouse models recapitulate the complex human ADPKD phenotype.

Corrigendum to "WCN23-1242 Genetic interaction between XBP1 and Pkd1 modulates ADPKD progression" [Kidney International Reports Volume 8, Issue 3, Supplement, March 2023, Page S250].

[This corrects the article DOI: 10.1016/j.ekir.2023.02.564.].

Secondary and tertiary structure modeling reveals effects of novel mutations in polycystic liver disease genes PRKCSH and SEC63.

Polycystic liver disease (PCLD) is characterized by intralobular bile duct cysts in the liver. It is caused by mutations in PRKCSH, encoding hepatocystin, and SEC63, encoding Sec63p. The main goals of this study were to screen for novel mutations and to analyze mutations for effects on protein structure and function. We screened 464 subjects including 76 probands by direct sequencing or conformation-sensitive capillary electrophoresis. We analyzed the effects of all known and novel mutations using a combination of splice site recognition, evolutionary conservation, secondary and tertiary structure predictions, PolyPhen, and pMut and sift. We identified a total of 26 novel mutations in PRKCSH (n = 14) and SEC63 (n = 12), including four splice site mutations, eight insertions/ deletions, six non-sense mutations, and eight missense mutations. Out of 48 PCLD mutations, 13 were predicted to affect splicing. Most mutations were located in highly conserved regions and homology modeling for two domains of Sec63p showed severe effects of the residue substitutions. In conclusion, we identified 26 novel mutations associated with PCLD and we provide in silico analysis in order to delineate the role of these mutations.

PKD2, a gene for polycystic kidney disease that encodes an integral membrane protein.

A second gene for autosomal dominant polycystic kidney disease was identified by positional cloning. Nonsense mutations in this gene (PKD2) segregated with the disease in three PKD2 families. The predicted 968-amino acid sequence of the PKD2 gene product has six transmembrane spans with intracellular amino- and carboxyl-termini. The PKD2 protein has amino acid similarity with PKD1, the Caenorhabditis elegans homolog of PKD1, and the family of voltage-activated calcium (and sodium) channels, and it contains a potential calcium-binding domain.

Human disease: calcium signaling in polycystic kidney disease.

Polycystic kidney disease results from loss of function of either of two novel proteins, polycystin-1 or polycystin-2. Recent studies show that intracellular calcium signaling is important in kidney development, and define defects in this signaling pathway as the basis of cyst formation in polycystic kidney disease.

Genomic structure of the gene for the human P1 protein (MCM3) and its exclusion as a candidate for autosomal recessive polycystic kidney disease.

The locus PKHD1 (polycystic kidney and hepatic disease 1) has been linked to all typical forms of the autosomal recessive polycystic kidney disease (ARPKD) and maps to chromosome 6p21.1-p12. We previously defined its genetic interval by the flanking markers D6S1714 and D6S1024. In our current work, we have fine-mapped the gene for the human P1 protein (MCM3), thought to be involved in the DNA replication process, to this critical region. We have also established its genomic structure. Mutation analyses using SSCP were performed in ARPKD patients' cDNA samples, leading to the exclusion of this gene as a candidate for this disorder. We also identified two intragenic polymorphisms that allowed families with critical recombination events to be evaluated. Although neither marker was informative in these individuals, they are the closest yet described for PKHD1 and may help to refine the candidate region.

Mutations in autosomal dominant polycystic kidney disease 2 gene: Reduced expression of PKD2 protein in lymphoblastoid cells.

The polycystic kidney disease 2 (PKD2) gene, encoding a 968-amino acid integral membrane protein with six predicted membrane-spanning domains and intracellular NH2 and COOH termini, is mutated in approximately 15% of the cases of autosomal dominant polycystic kidney disease (ADPKD), a common genetic disease frequently resulting in renal failure. For a better understanding of the cause of this disorder, we searched for mutations in the PKD2 gene in two PKD2-linked families characterized by different clinical phenotypes. A common polymorphism, a nonsense mutation, and a frameshift mutation were found. Both mutations are predicted to produce truncated proteins of 314 and 386 amino acids, arrested at the first extracellular loop of the protein. Restriction enzyme analysis of polymerase chain reaction (PCR) and reverse transcriptase (RT)-PCR products, respectively, showed that mutations cosegregated with the disease and mutated alleles were expressed at the messenger RNA level in lymphoblastoid cell lines. However, in these cells, Western blot analysis showed only PKD2 normal protein, and it was expressed at a lower level than that found in cells without the PKD2 mutation. These findings suggest that in lymphoblastoid cells, the truncated protein product of the mutant allele may not be stable.

Prenatal diagnosis of autosomal recessive polycystic kidney disease (ARPKD): molecular genetics, clinical experience, and fetal morphology.

Autosomal recessive polycystic kidney disease (ARPKD) is one of the most common hereditary renal cystic diseases and has a high infant mortality. Prenatal diagnosis using fetal sonography can be unreliable, especially in early pregnancy. The ARPKD locus has been mapped to proximal chromosome 6p allowing haplotype-based prenatal diagnosis in "at-risk" families. From December 1994 to March 1997, we received 258 inquiries regarding prenatal evaluation and we have completed analyses in 212 families. To date, 65 prenatal analyses have been performed in 57 families. In the majority of the requesting families (45/57), the index children are deceased and their DNA was extracted from paraffin-embedded tissue. Eighteen fetuses were homozygous for the disease-associated haplotypes. In 12 of these fetuses, pathoanatomical examination demonstrated typical ARPKD changes consisting of dilated collecting ducts and the characteristic hepatic ductal plate malformation. These changes were detected in two fetuses as early as 13 weeks gestational age. These cases represent the earliest demonstration of ARPKD-associated histopathology reported to date. One high risk fetus was carried to term and turned out to be unaffected. However, the diagnosis of ARPKD remained doubtful in the index patient. Forty-three fetuses were either heterozygous or homozygous for a nondisease-associated haplotype and all infants born were phenotypically unaffected at birth. In four cases, a recombination event occurred between the flanking markers and no genotypic prediction was possible. Three of these pregnancies were terminated and necropsy of the fetuses confirmed ARPKD, while one fetus was carried to term and showed no abnormalities at birth. These results show that haplotype-based prenatal testing is feasible and reliable in pregnancies "at risk" for ARPKD. An absolute prerequisite for these studies is an accurate diagnosis of ARPKD in previously affected sib(s).

Positional cloning approach to the dominant polycystic kidney disease gene, PKD1.

Positional cloning is a powerful strategy for identifying the site of disease-producing mutations when the underlying biochemical defect is unknown. The approach also offers new methods for the presymptomatic diagnosis of genetic disease. Using these methods we have localized the PKD1 gene, mutated in the majority of PKD1 families, to a small (500 kb) segment of chromosome 16, band p13.3. Virtually all of this interval has been cloned in cosmids and lambda bacteriophage. Over 20 sets of non-overlapping cDNA clones have been isolated from the region. Sequence and mutational analyses are currently underway. In addition, a set of polymorphic clones has been identified for presymptomatic diagnosis. Included in this set are several highly variable [CA]n microsatellite repeats. These highly informative markers can be rapidly assayed from a small amount of genomic DNA using the polymerase chain reaction. Despite these advances, presymptomatic diagnosis cannot be established with certainty in many families. However, identification of the PKD1 gene itself will eventually allow diagnosis by direct detection of mutations.

Identification of two Fas-associated phosphatase-1 (FAP-1) promoters in human cancer cells.

Fas-associated phosphatase-1 (FAP-1) has been reported as a negative regulator of Fas-mediated signal transduction in human cancer cells. To obtain insights into the potential carcinogenesis of the FAP-1 gene, we investigated its transcriptional regulation in normal and cancerous cells. To identify the FAP-1 promoter sequences, we first isolated P1 and cosmid clones that contained the regulatory region upstream from the FAP-1 gene by using the PCR products of 5' rapid amplification of cDNA end (5'-RACE) as probes. Genomic analysis of positive clones revealed that the major FAP-1 mRNA was transcribed from its proximal promoter (pPRM) in all human cancer cell lines tested, but 1 additional large transcript derived from its distal promoter (dPRM) was found in the human colon cancer cell line DLD-1. This suggests that the FAP-1 gene may be aberrantly dysregulated in some types of human cancers, including colon carcinoma. Sequence analysis of the region upstream from the FAP-1 gene strongly suggests that the transcript of the FAP-1 gene may be controlled by a variety of transcriptional regulatory elements, including NF-kappa B, NF-IL6, and p53 in its 2 promoters. These results imply that the FAP-1 gene may be a target gene under the control of important apoptosis-related nuclear factors in human cancers.

Molecular genetics and mechanism of autosomal dominant polycystic kidney disease.

Considerable progress toward understanding pathogenesis of autosomal dominant polycystic disease (ADPKD) has been made during the past 15 years. ADPKD is a heterogeneous human disease resulting from mutations in either of two genes, PKD1 and PKD2. The similarity in the clinical presentation and evidence of direct interaction between the COOH termini of polycystin-1 and polycystin-2, the respective gene products, suggest that both proteins act in the same molecular pathway. The fact that most mutations from ADPKD patients result in truncated polycystins as well as evidence of a loss of heterozygosity mechanism in individual PKD cysts indicate that the loss of the function of either PKD1 or PKD2 is the most likely pathogenic mechanism for ADPKD. A novel mouse model, WS25, has been generated with a targeted mutation at Pkd2 locus in which a mutant exon 1 created by inserting a neo(r) cassette exists in tandem with the wild-type exon 1. This causes an unstable allele that undergoes secondary recombination to produce a true null allele at Pkd2 locus. Therefore, the model Pkd2(WS25/-), which carries the WS25 unstable allele and a true null allele, produces somatic second hits during mouse development or adult life and establishes an extremely faithful model of human ADPKD.

Inherited diseases of the kidney.

It has long been known that a number of diseases affecting the kidney are the result of genetic defects passed on through the generations. Whereas some of these defects are rare, others, eg, the cystic diseases, are among the most common. Our understanding of the underlying pathobiology in these disorders based on physiologic and cell biologic studies is variable--we suspect that the V2 vasopressin receptor is defective in nephrogenic diabetes insipidus; we know that the glomerular basement membrane in Alport syndrome is abnormal; we suspect that a tumor suppressor gene is defective in Wilms tumor; and we lack a unifying hypothesis regarding cystic degeneration of the kidney. The advent and rapid progress of molecular biology have permitted an entirely new approach to understanding these diseases, allowing the expected identification of mutations in the V2 receptor, the unexpected finding that a novel collagen gene is responsible for many Alport syndrome cases, and the somewhat less-unexpected finding that only one of several genes responsible for renal cancers has been identified. Further, we are beginning to unravel the complex pathways responsible for cystic changes in the kidney. This review integrates these molecular biologic discoveries with the known pathobiology of disease to achieve a more complete understanding of the whole process.

The pathogenesis of autosomal dominant polycystic kidney disease: an update.

The identification of PKD1 and PKD2, the two major genes responsible for autosomal dominant polycystic kidney disease, are the seminal discoveries upon which much of the current investigation into the pathogenesis of this common heritable disease is based. A major mechanistic insight was achieved with the discovery that autosomal dominant polycystic kidney disease occurs by a two-hit mechanism requiring somatic inactivation of the normal allele in individual polarized epithelial cells. Most recent advances are focused on the function of the respective protein products, polycystin-1 and polycystin-2. Indirect evidence supports an interaction between polycystin-1 and -2, albeit it is unlikely that they work in concert in all tissues and at all times. They associate in yeast two hybrid and cotransfection assays and there is a striking similarity in the renal and pancreatic cystic phenotypes of Pkd2-/- and Pkd1del34/del34 mice. Also, the respective homologues of both proteins are expressed in the same sensory neuronal cells in the nematode and the human disease phenotypes remain completely overlapping with the major difference being in relative severity. Mounting evidence supports the hypothesis that polycystin-1 is a cell surface receptor. A close homologue in the sea urchin sperm mediates the acrosome reaction in response to contact with egg-jelly, the nematode homologue functions in mechano- or chemosensation, and the solution structure of the repeated extracellular polycystic kidney disease domains reveals a beta-sandwich fold commonly found in surface receptor molecules. Indirect evidence also supports the initial hypothesis that polycystin-2 is a calcium channel subunit. Several closely related homologues retain the calcium channel signature motif but differ in their predicted interaction domains, and one of these homologues has been shown to be a calcium regulated cation channel. Several important distinctions in polcystin-1 and -2 function have also been discovered. Polycystin-2 has a role in cardiac development that polcystin-1 does not. High level polycystin-2 expression in renal epithelial cells coincides with maturation and elongation of tubules and, unlike polycystin-1, persists into adulthood. In cells in tissue culture, polycystin-2 is expressed exclusively in the endoplasmic reticulum whilst the cellular expression of polycystin-1 remains unknown. Overall, the difficult task of understanding the autosomal dominant polycystic disease process is proceeding apace.

Evidence for a third genetic locus for autosomal dominant polycystic kidney disease.

Autosomal dominant polycystic kidney disease (ADPKD) is a genetically heterogeneous disease with loci on chromosomes 16p and 4q. It has a moderately high spontaneous mutation rate, although the relative frequency of such mutations at each gene locus is unknown. In studying genetic heterogeneity in the French-Canadian population, we identified a family in which a classical clinical presentation of ADPKD resulted from a mutation at a locus genetically distinct from either of the previously described loci for this disease. This suggests the existence of a third genetic locus for ADPKD.

A transducin-like gene maps to the autosomal dominant polycystic kidney disease gene region.

A novel human gene (sazD) that maps to the autosomal dominant polycystic kidney disease region shares sequence similarity with members of the beta-transducin superfamily. The cDNA sazD-c predicts an approximately 58-kDa protein (sazD) with seven internal repeats, similar to the WD-40 motif of the transducin family. The size of this protein family has been expanding rapidly; however, neither the structure nor the function of this repeated motif is known. Preliminary data do not suggest that sazD is mutated in patients with polycystic kidney disease.