Expression of the PAX2 gene in human fetal kidney and Wilms' tumor.

We have examined the pattern of expression of the human PAX2 gene in Wilms' tumors and human fetal kidney by Northern blot and in situ hybridization. Human PAX2 encodes a paired box-containing protein and has a high degree of homology with mouse and Drosophila paired box genes. In situ hybridization analysis reveals that PAX2 is expressed in nephrogenic structures in fetal kidney and also in Wilms' tumors. This pattern of expression suggests that PAX2 may have a role in differentiation of tissues in the kidney. In fetal kidney, PAX2 expression rapidly attenuates following the initial differentiation, but no evidence of attenuation was found in Wilms' tumors. The timing of PAX2 expression is restricted to fetal development, although high levels of expression were also observed in nephrogenic rests of residual normal juvenile kidney tissue adjacent to a Wilms' tumor. Nephrogenic rests are the presumptive precursors of Wilms' tumor but are not necessarily neoplastic. The failure of PAX2 expression to attenuate in Wilms' tumors and nephrogenic rests may be associated with events leading to the onset of Wilms' tumor. By somatic cell hybrid mapping, the PAX2 gene was localized to chromosome 10q22.1-q24.3, although this region has not previously been implicated in Wilms' tumor.     

Nephroblastomatosis and nephroblastoma in nonhuman primates

Wilms' tumors, or nephroblastomas, are renal embryonal malignancies with a high incidence in humans. Nephroblastomas are uncommon in nonhuman primates. This report describes three cases of spontaneous proliferative renal tumors in young monkeys: two cases of unilateral kidney nephroblastomas in baboons and a nephroblastomatosis in a cynomolgus macaque. Histologically, both baboon tumors were typical of Wilms' tumors found in humans, with proliferative epithelial cells forming tubules and aborted glomeruli, nephrogenic rests and proliferative fibrovascular tissue. The left kidney of the macaque was markedly enlarged and histologically similar to the baboon tumors, although normal kidney architecture was completely effaced by primitive tubules and occasional glomeruli surrounded by edematous stromal tissue. Cytogenetic analysis did not detect any macaque or baboon equivalents to human Wilms' tumor chromosomal abnormalities. By human pathology classification, the diffuse nature of the macaque tumor is more consistent with nephroblastomatosis than nephroblastoma. This differentiation is the first to be reported in a species other than human. The nephroblastomas described here are the first nephroblastomas to be reported in baboons. Our observations indicate that nonhuman primate nephroblastomatosis and nephroblastomas develop in a similar way to Wilms' tumors in humans, although no genetic marker has been associated with nephroblastomas of nonhuman primates thus far.     

Parental origin of de novo constitutional deletions of chromosomal band 11p13.

One-half of all cases of Wilms tumor (WT), a childhood kidney tumor, show loss of heterozygosity at chromosomal band 11p13 loci, suggesting that mutation of one allele and subsequent mutation or loss of the homologous allele are important events in the development of these tumors. The previously reported nonrandom loss of maternal alleles in these tumors implied that the primary mutation occurred on the paternally derived chromosome and that it was "unmasked" by loss of the normal maternal allele. This, in turn, suggests that the paternally derived allele is more mutable than the maternal one. To investigate whether germinal mutations are seen with equal frequency in maternally versus paternally inherited chromosomes, we determined the parental origin of the de novo germinal 11p13 deletions in eight children by typing lymphocyte DNA from these children and from their parents for 11p13 RFLPs. In seven of the eight cases, the de novo deletion was of paternal origin. The one case of maternal origin was unremarkable in terms of the size or extent of the 11p13 deletion, and the child did develop WT. Transmission of 11p13 deletions by both maternal and paternal carriers of balanced translocations has been reported, although maternal inheritance predominates. These data, in addition to the general preponderance of paternally derived, de novo mutations at other loci, suggest that the increased frequency of paternal deletions we observed is due to an increased germinal mutation rate in males.     

Ferritin H gene polymorphism in idiopathic hemochromatosis

Summary We have analysed karyotypes and DNA from three patients with aniridia (congenital absence of irises) and Wilms' tumour. All three had constitutional deletions from the short arm of chromosome 11. The minimum region of overlap of the deletion involves a small region of band 11p13 presumed to contain the genetic loci responsible for both phenotypic abnormalities. Using cells from these patients, somatic cell hybrids with transformed mouse cells have been prepared. Individual subclones retaining either the deletion-11 chromosome or the normal chromosome 11, in addition to a variety of other human chromosomes, have been identified. The relative position of these breakpoints have been determined and the panel of hybrids has been used to map randomly-isolated 11p13 DNA sequences. The characterisation of these deletions has provided a useful panel of hybrids for random mapping strategies designed to identify the Wilms' and aniridia genes.     

An internal deletion within an 11p13 zinc finger gene contributes to the development of Wilms' tumor

We have recently described the isolation of a candidate for the Wilms' tumor susceptibility gene mapping to band p13 of human chromosome 11. This gene, primarily expressed in fetal kidney, appears to encode a DNA binding protein. We now describe a sporadic, unilateral Wilms' tumor in which one allele of this gene contains a 25 bp deletion spanning an exon-intron junction and leading to aberrant mRNA splicing and loss of one of the four zinc finger consensus domains in the protein. The mutation is absent in the affected individual's germline, consistent with the somatic inactivation of a tumor suppressor gene. In addition to this intragenic deletion affecting one allele, loss of heterozygosity at loci along the entire chromosome 11 points to an earlier chromosomal nondisjunction and reduplication. We conclude that inactivation of this gene, which we call WT1, is part of a series of events leading to the development of Wilms' tumor.     

A novel imprinted gene, KCNQ1DN, within the WT2 critical region of human chromosome 11p15.5 and its reduced expression in Wilms' tumors

WT2 is defined by a maternal-specific loss of heterozygosity on human chromosome 11p15.5 in Wilms' and other embryonal tumors. Therefore, the imprinted genes in this region are candidates for involvement in Wilms' tumorigenesis. We now report a novel imprinted gene, KCNQ1DN (KCNQ1 downstream neighbor). This gene is located between p57(KIP2) and KvLQT1 (KCNQ1) of 11p15.5 within the WT2 critical region. KCNQ1DN is imprinted and expressed from the maternal allele. We examined the expression of KCNQ1DN in Wilms' tumors. Seven of eighteen (39%) samples showed no expression. In contrast, other maternal imprinted genes in this region, including p57(KIP2), IMPT1, and IPL exhibited almost normal expression in these samples, although some samples expressed IGF2 biallelically. These results suggest that KCNQ1DN existing far from the H19/IGF2 region may play some role in Wilms' tumorigenesis along with IGF2.     

WT1 mutations in patients with Denys-Drash syndrome: a novel mutation in exon 8 and paternal allele origin

Denys-Drash syndrome (DDS) is characterized by early onset nephropathy, pseudohermaphroditism in males and a high risk for developing Wilms' tumour (WT). The exact cause of DDS is unknown but germline mutations in the Wilms' tumour suppressor gene (WT1) have recently been described in the majority of DDS patients studied. These mutations occur de novo and are clustered around the zinc finger (ZF) coding exons of the WT1 gene. Analysis of exons 2–10 of the WT1 gene in constitutional DNA from five patients with DDS was carried out using the polymerase chain reaction (PCR) and direct DNA sequencing. In four out of the five patients, heterozygous germline mutations were found: a novel point mutation in exon 8 (ZF₂) at codon 377 altering the wild-type histidine to arginine, and three previously described point mutations in exon 9 (ZF₃) in the codons corresponding to amino acids ³⁹⁴Arg and ³⁹⁶Asp. In one patient, no mutations could be demonstrated. In three patients where parental DNA was available, the mutations were shown to have occurred de novo. Furthermore, since tumour DNA in two of these cases had lost the wild-type allele, polymorphic markers from the short arm of chromosome 11 were used to determine the parental origin of the mutant chromosome. In both cases, the mutant chromosome was shown to be of paternal origin. Since the majority of published WT1 mutations in DDS patients alter a RsrII restriction site in exon 9, we were able to perform PCR-based diagnosis in a female patient with early renal insufficiency and normal external genitalia.     

Evaluation of polysialic acid in the diagnosis of Wilms' tumor. A comparative study on urinary tract tumors and non-neuroendocrine tumors

The polysialic acid moiety of the neural cell adhesion molecule has been shown to represent an onco-developmental antigen which can be detected in both embryonic human kidney and Wilms' tumor but not in normal adult human kidney. In the present comparative study, Wilms' tumors, clear cell (bone-metastasizing) sarcomas of kidney, cystic nephromas, renal cell carcinomas, transitional cell carcinomas and papillomas of the renal pelvis, ureter and urinary bladder (as well normal transitional epithelium from these regions). Ewing sarcomas, hepatoblastomas, rhabdomyosarcomas, and carcinomas of the stomach, colon, exocrine pancreas, lung, and esophagus, were investigated immunohistochemically for the presence of polysialic acid. In addition, immunoblot analysis was performed in selected tumors. With the exception of Wilms' tumor, none of the tumors investigated was positive for polysialic acid. In Wilms' tumor, blastemal cells and all epithelial components were positive but no immunostaining was observed in the stroma. These observations emphasize the potential value of a monoclonal anti-polysialic acid antibody in identifying blastemal metanephric cells and their epithelial differentiatives in Wilms' tumor.     

Insertional inactivation of the WT1 gene in tumour cells from a patient with WAGR syndrome

The WT1 gene was analysed using DNA from a Wilms' tumour derived from a patient with the WAGR syndrome using single strand conformation polymorphism analysis and polymerase chain reaction sequencing. A 14-bp insertion was found in the intron part of the splice donor site of exon 7 and was a tandem duplication of an upstream exon sequence. This mutation would be expected to disrupt the correct processing of the WT1 mRNA and is predicted to result in a non-functional protein. This observation further supports the role of WT1 in Wilms' tumorigenesis in patients with constitutional 11p13 deletions.     

Wilms' tumour: reconciling genetics and biology.

Wilms' tumour, a paediatric malignancy of the kidney, is a striking example of the relationship between aberrant development and cancer. Several different genetic loci have been implicated in the aetiology of the tumour; genomic imprinting also plays a role. One Wilms' tumour predisposition gene (WT1), encoding a zinc finger protein, is expressed in a limited set of tissues, including developing nephrons and gonads. The biology and genetics of Wilms' tumour underline the developmental relationship between kidneys and gonads.     

An 11-bp deletion in the arylsulfatase A gene of a patient with late infantile metachromatic leukodystrophy

Summary Metachromatic leukodystrophy is a lysosomal storage disorder caused by the deficiency of arylsulfatase A. Examination of the arylsulfatase A gene in a patient suffering from late infantile metachromatic leukodystrophy revealed an 11-bp deletion in exon 8. Although this allele produces normal amounts of ASA mRNA, no arylsulfatase A cross-reacting material could be detected in cultured fibroblasts from the patient. The patient was found to be a compound heterozygote, the other allele is also known to generate no ASA polypeptides. This patient is another example where absence of ASA polypeptides correlates with the severe late infantile form of metachromatic leukodystrophy.     

WT1 and glomerular function

The Wilms' Tumour 1 (WT1) gene plays an important role at three different stages of kidney development. The onset of kidney formation, the progression of kidney formation and the maintenance of normal kidney function. Disruption of WT1 may lead to a whole spectrum of kidney diseases ranging from tumour development to mild forms of renal failure. However, the underlying mechanisms are largely unknown. The WT1 proteins have been implicated in various cellular processes like proliferation, differentiation and apoptosis and in agreement with these diverse functions, the number of target genes is still mounting. The development of mouse models in recent years has contributed considerably to a better understanding of the biological activities of WT1, and in this article we will discuss the role of WT1 during kidney formation and kidney function.     

A new point mutation in the beta-hexosaminidase alpha subunit gene responsible for infantile Tay-Sachs disease in a non-Jewish Caucasian patient (a Kpn mutant).

The abnormality in the gene coding for the beta-hexosaminidase alpha subunit was analyzed in a non-Jewish patient with clinically typical infantile Tay-Sachs disease. The family was Catholic, and the father and the mother were of Irish and German descent, respectively. A hitherto undescribed single nucleotide transversion was found within exon 11 (G1260----C; Trp420----Cys). The coding sequence was otherwise entirely normal. Expression in the COS I cell system confirmed that the mutant gene does not produce functional enzyme protein. The mutation can be identified rapidly and reliably because it abolishes one of the two KpnI sites in the coding sequence. The patient was a compound heterozygote with one allele carrying this mutation. The nature of the abnormality in the other allele remains unidentified. Examination of genomic DNA from the parents demonstrated that this "Kpn mutation" was inherited from the maternal side of the family.     

Molecular analysis of mutations in a patient with purine nucleoside phosphorylase deficiency.

Purine nucleoside phosphorylase (PNP) deficiency is an inherited autosomal recessive disorder resulting in severe combined immunodeficiency. The purpose of this study was to determine the molecular defects responsible for PNP deficiency in one such patient. The patient's PNP cDNA was amplified by PCR and sequenced. Point mutations leading to amino acid substitutions were found in both alleles. One point mutation led to a Ser-to-Gly substitution at amino acid 51 and was common to both alleles. In addition, an Asp-to-Gly substitution at amino acid 128 and an Arg-to-Pro substitution at amino acid 234 were found in the maternal and paternal alleles, respectively. In order to prove that these mutations were responsible for the disease state, each of the three mutations was constructed separately by site-directed mutagenesis of the normal PNP cDNA, and each was transiently expressed in COS cells. Lysates from cells transfected with the allele carrying the substitution at amino acid 51 retained both function and immunoreactivity. Lysates from cells transfected with PNP alleles carrying a substitution at either amino acid 128 or amino acid 234 contained immunoreactive material but had no detectable human PNP activity. In summary, molecular analysis of this patient identified point mutations within the PNP gene which are responsible for the enzyme deficiency.     

Harvey-ras allele deletion detected by in situ hybridization to Wilms' tumor chromosomes

Summary We have examined the chromosomes from a case of sporadic Wilms' tumor using in situ hybridization to determine whether the Ha-ras (c-Ha-ras 1) oncogene had been deleted as the result of a reciprocal chromosomal translocation between the short arm of chromosome 11 (breakpoint 11p13) and the long arm of chromosome 12 (breakpoint 12q13). Neither the derivative 11 nor derivative 12 chromosome hybridized significantly to the Ha-ras probe, which indicated that this cellular oncogene was deleted as a consequence of the translocation. This conclusion is supported by a Southern blot analysis which demonstrates loss of a Harvey-ras allele. These results support the view that the Ha-ras oncogene may be functionally involved in Wilms' tumor development.     

Decrease in the CGGn trinucleotide repeat mutation of the fragile X syndrome to normal size range during paternal transmission.

The fragile X syndrome, the most common inherited form of mental retardation, is caused by the expansion of a CGGn trinucleotide repeat in the FMR-1 gene. Although the repeat number usually increases during transmission, few cases with reduction of an expanded CGGn repeat back to the normal size range have been reported. We describe for the first time a family in which such reduction has occurred in the paternal transmission. The paternal premutation (delta = 300 bp) was not detected in one of the five daughters or in the son of this daughter, although he had the grandpaternal RFLP haplotype. Instead, fragments indicating the normal CGGn repeat size were seen on a Southern blot probed with StB12.3. PCR analysis of the CGGn repeat confirmed this; in addition to a maternal allele of 30 repeats, an allele of 34 repeats was detected in the daughter and, further, in her son. Sequencing of this new allele revealed a pure CGGn repeat configuration without AGG interruptions. No evidence for a somatic mosaicism of a premutation allele in the daughter or a normal allele in her father was detected when investigating DNA derived from blood lymphocytes and skin fibroblasts. Another unusual finding in this family was lack of the PCR product of the microsatellite marker RS46 (DXS548) in one of the grandmaternal X chromosomes, detected as incompatible inheritance of RS46 alleles. The results suggest an intergenerational reduction in the CGGn repeat from premutation size to the normal size range and stable transmission of the contracted repeat to the next generation. However, paternal germ-line mosaicism could not be excluded as an alternative explanation for the reverse mutation.     

Mutational analysis of a patient with mucopolysaccharidosis type VII, and identification of pseudogenes.

PCR of cDNA produced from patient fibroblasts allowed us to determine the paternal mutation in the first patient reported with beta-glucuronidase-deficiency mucopolysaccharidosis type VII (MPS VII). The G-->T transversion 1,881 bp downstream of the ATG translation initiation codon destroys an MboII restriction site and converts Trp627 to Cys (W627C). Digestion of genomic DNA PCR fragments with MboII indicated that the patient and the father were heterozygous for this missense mutation in exon 12. Failure to find cDNAs from patient RNA which did not contain this mutation suggested that the maternal mutation leads to greatly reduced synthesis or reduced stability of mRNA from the mutant allele. In order to identify the maternal mutation, it was necessary to analyze genomic sequences. This approach was complicated by the finding of multiple unprocessed pseudogenes and/or closely related genes. Using PCR with a panel of human/rodent hybrid cell lines, we found that these pseudogenes were present over chromosomes 5-7, 20, and 22 and the Y chromosome. Conditions were defined which allowed us to amplify and characterize genomic sequences for the true beta-glucuronidase gene despite this background of related sequences. The patient proved to be heterozygous for a second mutation, in which a C-->T transition introduces a termination codon (R356STOP) in exon 7. The mother was also heterozygous for this mutation. Expression of a cDNA containing the maternal mutation produced no enzyme activity, as expected. Expression of the paternal mutation in COS-7 cells produced a surprisingly high (65% of control) level of activity. However, activity was 13% of control in transiently transfected murine MPS VII cells. The level of activity of this mutant allele appears to correlate with the level of overexpression, suggesting that high concentrations of mutant monomers can drive the folding and tetramerization of mutant enzyme to produce an active and stable enzyme.     

The impact of imprinting: Prader-Willi syndrome resulting from chromosome translocation, recombination, and nondisjunction.

Prader-Willi syndrome (PWS) is most often the result of a deletion of bands q11.2-q13 of the paternally derived chromosome 15, but it also occurs either because of maternal uniparental disomy (UPD) of this region or, rarely, from a methylation imprinting defect. A significant number of cases are due to structural rearrangements of the pericentromeric region of chromosome 15. We report two cases of PWS with UPD in which there was a meiosis I nondisjunction error involving an altered chromosome 15 produced by both a translocation event between the heteromorphic satellite regions of chromosomes 14 and 15 and recombination. In both cases, high-resolution banding of the long arm was normal, and FISH of probes D15S11, SNRPN, D15S10, and GABRB3 indicated no loss of this material. Chromosome heteromorphism analysis showed that each patient had maternal heterodisomy of the chromosome 15 short arm, whereas PCR of microsatellites demonstrated allele-specific maternal isodisomy and heterodisomy of the long arm. SNRPN gene methylation analysis revealed only a maternal imprint in both patients. We suggest that the chromosome structural rearrangements, combined with recombination in these patients, disrupted normal segregation of an imprinted region, resulting in uniparental disomy and PWS.