Wilms tumour histology is determined by distinct types of precursor lesions and not epigenetic changes.

Current models of Wilms tumour development propose that histological features of the tumours are programmed by the underlying molecular aberrations. For example, tumours associated with WT1 mutations arise from intralobar nephrogenic rests (ILNR), concur with CTNNB1 mutations and have distinct histology, whereas tumours with IGF2 loss of imprinting (LOI) often arise from perilobar nephrogenic rests (PLNR). Intriguingly, ILNR and PLNR are found simultaneously in Wilms tumours in children with overgrowth who have constitutional IGF2 LOI. We therefore examined whether the precursor lesions or early epigenetic changes are the primary determinant of Wilms tumour histology. We examined the histological features and gene expression profiles of IGF2 LOI tumours and WT1-mutant tumours which are associated with PLNR and/or ILNR. Two distinct types of IGF2 LOI tumours were identified: the first type had a blastemal-predominant histology associated with PLNR, while the second subtype had a myogenic histology, increased expression of mesenchymal lineage genes and an association with ILNR, similar to WT1-mutant tumours. These ILNR-associated IGF2 LOI tumours also showed signatures of activation of the WNT signalling pathway: differential expression of beta-catenin targets (MMP2, RARG, DKK1) and WNT antagonist genes (DKK1, WIF1, SFRP4). Unexpectedly, the majority of these tumours had CTNNB1 mutations, which are normally only seen in WT1-mutant tumours. The absence of WT1 mutations in tumours with IGF2 LOI indicated that CTNNB1 mutations occur predominantly in tumours arising from ILNR independent of the presence or absence of WT1 mutations. Thus, even though these two classes of tumours with IGF2 LOI have the same underlying predisposing epigenetic error, the tumour histology and the gene expression profiles are determined by the nature of the precursor cells within the nephrogenic rests and subsequent CTNNB1 mutations.

The prevalence of PAX2 mutations in patients with isolated colobomas or colobomas associated with urogenital anomalies.

The PAX2 gene is mutated in patients with ocular colobomas, vesicoureteral reflux (VUR), and kidney anomalies (renal-coloboma syndrome, OMIM 120330). The three abnormalities which make up this syndrome also occur in isolation, but the causal genes are not known. PAX2 encodes a transcription factor of the paired box class of DNA binding proteins, important for the development of the urogenital tract, optic nerve and adjacent retina, inner ear, and CNS. In this paper we have investigated the prevalence of PAX2 mutations in patients with ocular colobomas, microphthalmos, or retinal anomalies, either in isolation or with associated urogenital anomalies. Using PCR-SSCP, most or all exons of PAX2 were examined in blood DNA from 99 patients who have either ocular anomalies alone or a combination of ocular and urogenital conditions. PAX2 mutations were not detected in patients with ocular colobomas, either in isolation or with associated abnormalities, except in one patient with typical renal-coloboma syndrome. We conclude that PAX2 mutations are unlikely to be common in patients with ocular colobomas in isolation or in patients with ocular colobomas and associated anomalies, except for patients with typical renal-coloboma syndrome where PAX2 is known to be the aetiological cause.

Absence of PAX2 gene mutations in patients with primary familial vesicoureteric reflux.

Vesicoureteric reflux (VUR) is a common childhood condition characterised by regurgitation of urine from the bladder to the kidney. It is the commonest cause of end stage renal failure in children and an important cause in adults. Primary VUR is often familial, suggesting that genetic factors play an important role in its aetiology. Recently, VUR was observed as part of a syndrome, involving optic nerve colobomas and renal anomalies, caused by mutations of the PAX2 gene. PAX2 is a member of the paired box family of genes and is expressed in the ureteric bud and differentiating nephrogenic mesenchyme of the developing kidney. PAX2 has been shown to play a critical role in the development of both the kidney and the ureter. The occurrence of VUR in one family with the PAX2 mutation, and the expression pattern of PAX2 in developing ureteric bud, strongly suggested that PAX2 could be the cause of primary familial VUR. Single strand conformational polymorphism (SSCP) analysis of 23 affected subjects in eight families with primary familial VUR showed no alterations in exons 2-5 of the PAX2 gene. In addition, a polymorphic dinucleotide repeat marker located within the PAX2 gene segregated independently of the disease trait in one large family who primarily had VUR or reflux nephropathy. These results suggest that PAX2 is not a major cause of primary familial reflux.

Molecular and clinical studies of three cases of female pseudohermaphroditism with caudal dysplasia suggest multiple etiologies.

Female pseudohermaphroditism with caudal dysplasia is a clinical entity in which normal-appearing male genitalia may occur in the apparent absence of testosterone or the sex-determining gene (SR Y). We have extended observations of two previously reported cases, and report a third case, which strongly suggests multiple etiologies. The first case was one of identical twins. The other identical twin did not show female pseudohermaphroditism with caudal dysplasia, but both patients had the rare birth defect of neonatal cataracts. We have explored skewed X-inactivation as a possible difference between the two twins, with a negative result. The second case had a deletion at 10q25.3-->ter. This is near the location of PAX2, and we searched for mutations in PAX2 in both this and the first case, with negative results. Neither patient had a scrotal raphe, suggesting that a failure of division of the cloacal membrane was an important step in their development of female pseudohermaphroditism. The final case is newly described and differed from the above two in the presence of a scrotal raphe and an elevated testosterone level. Although no source for the testosterone was found, this case suggests that the etiology in this patient was different and that the presence of a scrotal raphe can be used to distinguish between at least two etiologies.

Further delineation of renal-coloboma syndrome in patients with extreme variability of phenotype and identical PAX2 mutations.

Renal-coloboma syndrome is a recently described autosomal dominant syndrome of abnormal optic nerve and renal development. Two families have been reported with renal-coloboma syndrome and mutations of the PAX2 gene. The PAX2 gene, which encodes a DNA-binding protein, is expressed in the developing ear, CNS, eye, and urogenital tract. Ocular and/or renal abnormalities have been consistently noted in the five reports of patients with renal-coloboma syndrome, to date, but PAX2 expression patterns suggest that auditory and CNS abnormalities may be additional features of renal-coloboma syndrome. To determine whether additional clinical features are associated with PAX2 mutations, we have used PCR-SSCP to identify PAX2 gene mutations in patients. We report here four patients with mutations in exon 2, one of whom has severe ocular and renal disease, microcephaly, and retardation, and another who has ocular and renal disease with high-frequency hearing loss. Unexpectedly, extreme variability in clinical presentation was observed between a mother, her son, and an unrelated patient, all of whom had the same PAX2 mutation as previously described in two siblings with renal-coloboma syndrome. These results suggest that a sequence of seven Gs in PAX2 exon 2 may be particularly prone to mutation.

Genomic structure of the human PAX2 gene.

PAX2 is one of nine PAX genes that have been described in vertebrates. Each PAX gene contains a conserved paired box domain that was first identified in Drosophila. PAX2 encodes a transcription factor that has a critical role in the development of the urogenital tract, the eyes, and the CNS. Recently, we reported a mutation of PAX2 in patients with optic nerve coloboma, vesicoureteric reflux, and renal anomalies. To facilitate further analysis of PAX2 mutations in human disease, we have now determined the complete structure of the human PAX2 gene. Five genomic lambda clones containing human PAX2 gene sequences were isolated. Sequencing and restriction mapping of these clones showed that human PAX2 was composed of 12 exons spanning approximately 70 kb. Two alternatively spliced exons and a dinuclotide repeat polymorphism were also determined in PAX2. These data will be useful in characterizing the role of PAX2 in human disease.

Mutation of the PAX2 gene in a family with optic nerve colobomas, renal anomalies and vesicoureteral reflux.

Paired box (PAX) genes play a critical role in human development and disease. The PAX2 gene is expressed in primitive cells of the kidney, ureter, eye, ear and central nervous system. We have conducted a mutational analysis of PAX2 in a family with optic nerve colobomas, renal hypoplasia, mild proteinuria and vesicoureteral reflux. We report a single nucleotide deletion in exon five, causing a frame-shift of the PAX2 coding region in the octapeptide domain. The phenotype resulting from the PAX2 mutation in this family was very similar to abnormalities that have been reported in Krd mutant mice. These data suggest that PAX2 is required for normal kidney and eye development.

Human insulin-like growth factor type I and type II receptors are not imprinted.

We have shown that the insulin-like growth factor type I and II receptors are expressed equally from the maternal and paternal alleles in human tissues. The imprinting status of the type I insulin-like growth factor receptor has not been reported while the type II receptor has previously been shown to be maternally expressed in the mouse. That the imprinting of the insulin-like growth factor type II receptor is not conserved between mouse and humans suggests that the physiological role of the IGF2 receptor may differ between these two species.

Relaxation of insulin-like growth factor II gene imprinting implicated in Wilms' tumour.

Genomic imprinting has been implicated in the onset of several embryonal tumours but the mechanism is not well understood. Maternal chromosome 11p15 loss of heterozygosity and paternal chromosome 11 isodisomy suggest that imprinted genes are involved in the onset of Wilms' tumour and the Beckwith-Wiedemann syndrome. The insulin-like growth factor II (IGF2) gene located at 11p15.5 has been put forward as a candidate gene as it is maternally imprinted (paternally expressed) in the mouse, and is expressed at high levels in Wilms' tumours. We report here that the IGF2 gene is expressed from the paternal allele in human fetal tissue, but that in Wilms' tumour expression can occur biallelically. These results provide, to our knowledge, the first evidence that relaxation of imprinting may play a role in the onset of disease and suggest a new genetic mechanism involved in the development of cancer.