WT1 mutations contribute to abnormal genital system development and hereditary Wilms' tumour

Association studies of a polymorphism in the Wilms' tumor 1 locus in Norwegian patients with testicular cancer

One strategy for identifying genes involved in genetic predisposition to testicular germ-cell tumors (TC) is to perform association studies with polymorphic loci at or closely linked to candidate genes. Genes involved in normal fetal genital development, such as the Wilms' tumor 1 gene (WT1) located at 11p13, are among such candidates. The present study compares a TC (n = 442) and a control (n = 384) population for the allele frequencies of 2 polymorphic loci located at chromosome band 11p13. One of the polymorphisms (WT) was located within and the other (D11S325) in close proximity to the WT1 gene. No differences in allele frequencies between cancer patients and controls were found. However, the frequency of the Al allele of the WT polymorphism was significantly increased in one of the cancer subgroups most likely to carry susceptibility genes (patients with bilateral cancer) compared to controls. Furthermore, the frequency of the Al allele was increased in patients with metastatic disease. Such differences in allele frequencies were not observed for the D11S325 locus. The findings might indicate an involvement of the WT1 gene both in susceptibility to TC and in progression of the disease.

DNA recognition by splicing variants of the Wilms' tumor suppressor, WT1

The Wilms' tumor suppressor, WT1, is a zinc finger transcriptional regulator which exists as multiple forms owing to alternative mRNA splicing. The most abundant splicing variants contain a nine-nucleotide insertion encoding lysine, threonine, and serine (KTS) in the H-C link region between the third and fourth WT1 zinc fingers which disrupts binding to a previously defined WT1-EGR1 binding site. We have identified WT1[+KTS] binding sites in the insulin-like growth factor II gene and show that WT1[+KTS] represses transcription from the insulin-like growth factor II P3 promoter. The highest affinity WT1[+KTS] DNA binding sites included nucleotide contacts involving all four WT1 zinc fingers. We also found that different subsets of three WT1 zinc fingers could bind to distinct DNA recognition elements. A tumor-associated, WT1 finger 3 deletion mutant was shown to bind to juxtaposed nucleotide triplets for the remaining zinc fingers 1, 2, and 4. The characterization of novel WT1 DNA recognition elements adds a new level of complexity to the potential gene regulatory activity of WT1. The results also present the possibility that altered DNA recognition by the dominant WT1 zinc finger 3 deletion mutant may contribute to tumorigenesis.

DNA recognition by splicing variants of the Wilms' tumor suppressor, WT1

The Wilms' tumor suppressor, WT1, is a zinc finger transcriptional regulator which exists as multiple forms owing to alternative mRNA splicing. The most abundant splicing variants contain a nine-nucleotide insertion encoding lysine, threonine, and serine (KTS) in the H-C link region between the third and fourth WT1 zinc fingers which disrupts binding to a previously defined WT1-EGR1 binding site. We have identified WT1[+KTS] binding sites in the insulin-like growth factor II gene and show that WT1[+KTS] represses transcription from the insulin-like growth factor II P3 promoter. The highest affinity WT1[+KTS] DNA binding sites included nucleotide contacts involving all four WT1 zinc fingers. We also found that different subsets of three WT1 zinc fingers could bind to distinct DNA recognition elements. A tumor-associated, WT1 finger 3 deletion mutant was shown to bind to juxtaposed nucleotide triplets for the remaining zinc fingers 1, 2, and 4. The characterization of novel WT1 DNA recognition elements adds a new level of complexity to the potential gene regulatory activity of WT1. The results also present the possibility that altered DNA recognition by the dominant WT1 zinc finger 3 deletion mutant may contribute to tumorigenesis.

Molecular genetic analysis of chromosome 11p in familial Wilms tumour

In the family reported here, a mother and both of her children developed a Wilms tumour, and all three tumours were of the relatively rare monomorphous epithelial histopathological subtype. Using restriction fragment length polymorphism analysis, both sibs were shown to inherit the same maternal allele from the 11p13 region but different maternal alleles from the 11p15 region. Using a combination of single-strand conformation polymorphism (SSCP) and polymerase chain reaction (PCR) sequencing techniques, no mutations were identified in the WT1 tumour-suppressor gene from the 11p13 region, but a novel polymorphism was identified in exon 1. mRNA expression studies using the insulin-like growth factor II (IGF-II) gene, located in 11p15, showed that there was no relaxation of imprinting at this locus. There was also no evidence of loss of heterozygosity on the long arm of chromosome 16. These findings indicate that the WT1 and IGF-II genes, together with the long arm of chromosome 16, are not directly implicated in tumorigenesis in this Wilms family, but that a recombination event has occurred on the short arm of chromosome 11.

The Denys-Drash syndrome

Images

Molecular mechanisms possibly affecting WT1 function in human ovarian tumors

The frequent allelic deletions observed on the short arm of chromosome 11 in ovarian tumors suggest that the WT1 gene, a proposed tumor-suppressor gene located on chromosome 11p13 and expressed in the human fetal genitourinary system, may contribute to the development of ovarian neoplasms. Structural and sequence analysis of the entire coding portions of the WT1 gene did not reveal any abnormalities in the 20 ovarian tumor specimens (13 of which showed 11p13 allelic deletions) and 5 cell lines which we analyzed. These findings invalidate the hypothesis that the WT1 gene functions as a classical tumor-suppressor gene in ovarian tumorigenesis and suggest that a different recessive oncogene may be "exposed" by the observed 11p13 allelic deletions. Expression analysis showed that the WT1 gene was transcriptionally active in all the tumors tested, but considerable variations in the mRNA levels were found. This apparent variability, which should be confirmed at the cellular level in the tumor specimens, was also observed in the ovarian tumor-cell lines. Finally, WT1 expression data were evaluated in conjunction with immunohistochemical data on p53. The possible functional effects of altered WT1 mRNA expression in ovarian tumors are discussed, taking into account the potential WT1/p53 protein interaction.

Identification of genetically aberrant cell lineages in Wilms' tumors

Most Wilms' tumors contain several predominant cell types, of which a primitive blastemal population is often the most prominent. Other typical components include undifferentiated mesenchymal and epithelial cells, but it has not been demonstrated that these components are neoplastic. We used a combined cytogenetic and fluorescence in situ hybridization approach to determine the clonal relationship of different cell populations within six Wilms' tumors. Clonal numerical chromosome aberrations in three Wilms' tumors were found in blastemal cells, but not in mesenchymal cells. Loss of one WT1 allele in two other tumors was detected in both blastemal and mesenchymal cells. Tetrasomy 18 in a sixth case was observed in mesenchymal and epithelial cells; blastemal cells could not be evaluated in this tumor. These findings demonstrate that mesenchymal and epithelial cells in some Wilms' tumors are neoplastic. Different histologic components in some Wilms' tumors derive from a single chromosomally aberrant ancestor which is most likely to be the primitive blastemal cell.

Anaplastic Wilms' tumour, a subtype displaying poor prognosis, harbours p53 gene mutations

The genetics of Wilms' tumour (WT), a paediatric malignancy of the kidney, is complex. Inactivation of the tumour suppressor gene, WT1, is associated with tumour aetiology in approximately 10-15% of WTs. Chromosome 17p changes have been noted in cytogenetic studies of WTs, prompting us to screen 140 WTs for p53 mutations. When histopathology reports were available, p53 mutations were present in eight of eleven anaplastic WTs, a tumour subtype associated with poor prognosis. Amplification of MDM2, a gene whose product binds and sequesters p53, was excluded. Our results indicate that p53 alterations provide a molecular marker for anaplastic WTs.

Fine structure analysis of the WT1 gene in sporadic Wilms tumors

Molecular genetic studies indicate that the etiology of Wilms tumor (WT) is complex, involving at least three loci. Germ-line mutations in the tumor suppressor gene, WT1, have been documented in children with WTs and urogenital developmental anomalies. Sporadic tumors constitute the majority (> 90%) of WT cases and previous molecular analyses of the WT1 gene have focused only on the DNA-binding domain. Using the single-strand conformational polymorphism (SSCP) assay, we analyzed the structural integrity of the entire WT1 gene in 98 sporadic WTs. By PCR-SSCP we find that mutations in the WT1 gene are rare, occurring in only six tumors analyzed. In one sample, two independent intragenic mutations inactivated both WT1 alleles, providing a singular example of two different somatic alterations restricted to the WT1 gene. This case is consistent with the existence of only one tumor suppressor gene at 11p13 involved in the pathogenesis of WTs. Our data, together with the previously ascertained occurrence of large deletions/insertions in WT1, define the frequency at which the WT1 gene is altered in sporadic tumors.

Testicular germ cell tumors of adults show deletions of chromosomal bands 11p13 and 11p15.5, but no abnormalities within the zinc-finger regions and exons 2 and 6 of the Wilms' tumor 1 gene

We have studied the involvement of chromosomal bands 11p13 and 11p15.5 in 15 testicular seminomas (SE) and 18 testicular nonseminomatous germ cell tumors (NS). No allelic imbalances were found in 40% of the SE and 44% of the NS. Loss of heterozygosity (LOH) at 11p15.5 was seen in 21% of the SE and 47% of the NS; the corresponding frequencies for 11p13 were 47% and 44%. Both regions were deleted in 13% of the SE and 44% of the NS, indicating that all NS with a complete LOH of 11p13 also lost the 11p15.5 region. In one (out of two) SE and in five (out of eight) NS, this was due to at least two separate deletions. Loss of the whole p-arm was likely in one SE and two NS. No gross genomic changes of the Wilms' tumor 1 (WT1) tumor suppressor gene were found using a cDNA probe (WT33). Nor were aberrations found in the zinc-finger regions and exons 2 and 6 of this gene, using polymerase chain reaction amplification, single stranded DNA polymorphism analysis, and sequencing. We suggest that loss of genetic information from the short arm of chromosome 11, without affecting the WT1 gene in the regions studied, is relatively frequent but not crucial in the pathogenesis of testicular germ cell tumors of adults.

Transcriptional regulation of gene expression: mechanisms and pathophysiology

Transcription factors are key mediators of the genetic programs that underlie human development and physiology. Mutations in genes that encode transcription factors or in DNA sequences to which these factors bind may adversely affect gene expression and result in disease. Mutations in genes encoding transcription factors often have pleiotropic effects because each transcription factor is involved in the regulation of multiple genes. For several transcription factors, germline mutations have been shown to result in malformation syndromes whereas somatic mutations in the same genes contribute to the multistep process of tumorigenesis. The study of transcription factors and their involvement in human disease thus provides insight into the molecular mechanisms underlying human development, physiology, dysmorphology, and oncology.

Infrequent mutation of the WT1 gene in 77 Wilms' Tumors

Homozygous deletions in Wilms' tumor DNA have been a key step in the identification and isolation of the WT1 gene. Several additional loci are also postulated to contribute to Wilms' tumor formation. To assess the frequency of WT1 alterations we have analyzed the WT1 locus in a panel of 77 Wilms' tumors. Eight tumors showed evidence for large deletions of several hundred or thousand kilobasepairs of DNA, some of which were also cytogenetically detected. Additional intragenic mutations were detected using more sensitive SSCP analyses to scan all 10 WT1 exons. Most of these result in premature stop codons or missense mutations that inactivate the remaining WT1 allele. The overall frequency of WT1 alterations detected with these methods is less than 15%. While some mutations may not be detectable with the methods employed, our results suggest that direct alterations of the WT1 gene are present in only a small fraction of Wilms' tumors. Thus, mutations at other Wilms' tumor loci or disturbance of interactions between these genes likely play an important role in Wilms' tumor development.

Genitourinary tumors in the families of children with renal tumors

The occurrence of genitourinary tumors in the relatives of a population-based series of 218 children diagnosed with renal tumors was investigated. Family data on 92% (176 of 192) of Wilms' tumor (WT) patients and 77% (20 of 26) of other renal tumor patients were obtained. In all, 21 genitourinary tumors in first-degree relatives in 19 families were ascertained, together with 30 such tumors in second-degree relatives. Ten families were diagnosed with multiple genitourinary tumors, although none of these manifested familial WT. It is proposed that a small proportion of families of children with renal tumors has a genetic predisposition to develop genitourinary tumors and that these tumors may represent further manifestations of the pleiotropic effects of the WT1 gene or of other genes involved in WT predisposition.

The molecular genetics of Wilms tumor: a paradigm of heterogeneity in tumor development

The evidence that genes on chromosome 11 are involved in Wilms tumor development is convincing; however, it is also evident that the mechanisms of tumorigenesis are more complex than the two-mutation model originally proposed. Potentially several genetic loci participate in Wilms tumor development. This should not be too surprising considering the complexity of pathways regulating growth and differentiation in nephrogenesis. It is possible that these various genes act at different points in the differentiation pathway and disruption of their normal function contributes to tumorigenesis. In fact, these loci may interact with one another in tumor formation. Certain types of genetic alterations may be the rate-limiting steps, but other changes may also contribute or be necessary for tumor development. Homozygous inactivation of specific genes, combinations of mutated alleles, and relaxation of genetic imprinting, or even interactions between different mutated alleles may all be part of the process for individual tumors. It has been found that some patients with the WAGR syndrome who are hemizygous for WT1 at 11p13 have in addition loss of heterozygosity within 11p15, and a sporadic tumor has been shown to have a WT1 mutation and loss of heterozygosity at loci at both 11p15 and 11p13 (59,85). These observations suggest the potential for interaction among the various Wilms tumor loci. Not only are there likely to be a number of different genetic loci linked to Wilms tumor development, but the mechanisms underlying altered gene function may be more variable than originally believed. It is probably not correct to think of Wilms tumor as a homogeneous entity. Mutations at different loci or various combinations of genetic lesions could well be responsible for the different categories of Wilms tumors. This apparent genetic complexity of Wilms tumor development is a concept that can very likely be applied to many other types of neoplasms. A complete understanding of Wilms tumorigenesis awaits identification of all members of the Wilms tumor gene family and the functional significance of their alterations.

Inactivation of WT1 in nephrogenic rests, genetic precursors to Wilms' tumour

Nephrogenic rests consist of foci of primitive renal cells, typically microscopic, that are found within the normal kidney tissue of children with Wilms' tumour. To study the relationship between nephrogenic rests and the associated tumours, we screened these lesions for mutations in the 11p13 Wilms' tumour suppressor gene, WT1. In two cases in which the Wilms' tumour contained a somatic WT1 mutation, the nephrogenic rest had the identical mutation. Nephrogenic rests and Wilms' tumours are therefore topographically distinct lesions that are clonally derived from an early renal stem cell. Inactivation of WT1 appears to be an early genetic event which can lead to the formation of nephrogenic rests, enhancing the probability that additional genetic hits will lead to Wilms' tumour.

Nuclear localization of the protein encoded by the Wilms' tumor gene WT1 in embryonic and adult tissues

The human Wilms' tumor gene WT1 encodes a putative transcription factor implicated in tumorigenesis and in specifying normal urogenital development. We have studied the distribution of WT1 protein and mRNA using immunohistochemistry and in situ hybridization. Monoclonal antibodies were raised against a peptide specific to the first alternative splice site of WT1. Two antibodies specifically reacted on Western blot to this WT1 isoform. Immunofluorescence localized WT1 protein to podocytes during mesonephric and metanephric development. In situ hybridization revealed a similar pattern of expression except that WT1 mRNA was also present in metanephric blastema and renal vesicles. Messenger RNA expression was most pronounced in the kidneys during early fetal development and declined thereafter. In contrast, WT1 protein was readily detectable in glomerular podocytes throughout adulthood. WT1 protein in Wilms' tumor was present in blastema and glomeruloid structures. Expression in the female gonad was linked to the different stages of granulosa cell development. In the male gonad, expression was restricted to Sertoli cells and their precursors, the embryonic tunica albuginea and the rete testis. The intracellular distribution of the WT1 protein was investigated by confocal laser microscopy and was demonstrated to be exclusively nuclear. The nuclear distribution and the selective pattern of expression support the proposed role of WT1 as a transcription factor active during urogenital development. The persistence of WT1 expression in the adult kidney suggests a role in homeostasis of the podocyte.

Three non-overlapping regions of chromosome arm 11p allele loss identified in infantile tumors of adrenal and liver

Tumor and constitutional chromosome arm 11p genotypes were compared in 6 hepatoblastoma (HB) patients and 2 adrenal adenoma (AA) patients, with one HB patient and both AA patients displaying clinical features associated with the Beckwith-Wiedemann syndrome (BWS). Using up to 14 chromosome 11 polymorphic markers, loss of constitutional heterozygosity (LOH) was demonstrated in both AA patients and in 4 of 6 HB patients. This identified three distinct and non-overlapping regions of 11p within which LOH occurred, which were defined as lying distal to the gamma-globin locus (11p15.5), proximal to the gamma-globin locus but distal to 11p13 (LOH being detected at 11p15.1), and restricted to the 11p13 region. Specific LOH within each 11p15 region was observed in HB, and this represents the first demonstration by a single study of LOH clearly affecting separate regions of chromosome band 11p15 in a particular tumor type. One AA showed LOH restricted to 11p13 loci, implicating the involvement of the WT1 gene. The second AA patient presented with genitourinary abnormalities and we therefore examined sequences coding for 3 zinc finger domains of WT1 in both AAs. No point mutations were identified in sequence from either patient. Nonetheless our results indicate that 3 separate 11p loci may be significant in the development of tumors which arise in association with BWS.

Low frequency of mutations in the WT1 coding region in Wilms' tumor

A series of twenty unselected Wilms' tumors were analysed for alterations in the WT1 tumor suppressor gene. The entire coding region of WT1 was amplified by RNA-PCR, and then screened for mutations by single-strand conformational polymorphism analysis (SSCP). This method was shown to be capable of detecting point mutations in the WT1 gene, by using an experimentally produced mutation. A single mutation, a 226 bp intragenic deletion, was detected in a tumor from a patient with the WAGR syndrome. These results suggest that alterations in the WT1 gene may be involved in only a subset of Wilms' tumors, and that other loci need to be investigated as potential suppressor genes in sporadic Wilms' tumors.

Mutational screening of the Wilms's tumour gene, WT1, in males with genital abnormalities

Several lines of evidence suggest that the Wilms's tumour susceptibility gene, WT1, has an important role in genital as well as kidney development. WT1 is expressed in developing kidney and genital tissues. Furthermore, mutations in WT1 have been detected in patients with the Denys-Drash syndrome (DDS), which is characterised by nephropathy, genital abnormalities, and Wilms's tumour. It is possible that WT1 mutations may cause genital abnormalities in the absence of kidney dysfunction. We tested this hypothesis by screening the WT1 gene for mutation in 12 46,XY patients with various forms of genital abnormality. Using single strand conformation polymorphism (SSCP) we did not detect any WT1 mutations in these patients. However, in addition to the 12 patients, three DDS patients were also analysed using SSCP, and in all three cases heterozygous WT1 mutations were found which would be predicted to disrupt the DNA binding activity of WT1 protein. These results support the notion that DDS results from a dominant WT1 mutation. However, WT1 mutations are unlikely to be a common cause of male genital abnormalities when these are not associated with kidney abnormalities.

WT-1 is required for early kidney development

In humans, germline mutations of the WT-1 tumor suppressor gene are associated with both Wilms' tumors and urogenital malformations. To develop a model system for the molecular analysis of urogenital development, we introduced a mutation into the murine WT-1 tumor suppressor gene by gene targeting in embryonic stem cells. The mutation resulted in embryonic lethality in homozygotes, and examination of mutant embryos revealed a failure of kidney and gonad development. Specifically, at day 11 of gestation, the cells of the metanephric blastema underwent apoptosis, the ureteric bud failed to grow out from the Wolffian duct, and the inductive events that lead to formation of the metanephric kidney did not occur. In addition, the mutation caused abnormal development of the mesothelium, heart, and lungs. Our results establish a crucial role for WT-1 in early urogenital development.

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.

The Wilms tumour gene WT1 is expressed in murine mesoderm-derived tissues and mutated in a human mesothelioma

The tumour suppressor gene WT1 encodes a transcription factor expressed in tissues of the genito-urinary system. Inactivation of this gene is associated with the development of Wilms tumour a pediatric kidney cancer. We show that WT1 is also expressed at high levels in many supportive structures of mesodermal origin in the mouse. We also describe a case of adult human mesothelioma, a tumour derived from the peritoneal lining, that contains a homozygous point mutation within WT1. This mutation, within the putative transactivation domain, converts the protein from a transcriptional repressor of its target sequence to a transcriptional activator. The role of WT1 in normal development thus extends to diverse structures derived from embryonic mesoderm and disruption of WT1 function contributes to the onset of adult, as well as pediatric, tumours.

Nephrotic syndrome in the 1st year of life

Among the various primary conditions which may be associated with a nephrotic syndrome at birth or within the 1st year of life, the best known is the congenital nephrotic syndrome of finnish type (CNF) characterized by irregular pseudocystic dilatation of proximal tubules. This disease, very frequent in Finland, is often familial with an autosomal recessive mode of inheritance. Patients are steroid resistant, but the cause of death is usually not uraemia but infection or severe diarrhoea with electrolyte imbalance. The second condition is idiopathic nephrosis including minimal change disease, diffuse mesangial proliferation and focal segmental glomerular sclerosis. As opposed to CNF, infants with "early onset nephrosis" may respond to steroid therapy as older children do and may even recover. However, there are no histopathological criteria which allow the certain differentiation of idiopathic nephrosis from CNF. The third condition is diffuse mesangial sclerosis (DMS), a clinicopathological entity which can occur as an isolated finding or be associated with male pseudohermaphroditism and/or Wilms' tumour (Drash syndrome). From a morphological point of view, DMS is easy to differentiate from CNF because of the characteristic pattern of involvement of the glomeruli. From a clinical point of view, the nephropathy, almost always characterized by a nephrotic syndrome, has two distinct features: it is most often diagnosed in the first 2 years of life and it progresses rapidly to end-stage renal failure, which usually occurs before the age of 3 years. The clinical findings in 36 patients with DMS are presented. The nephropathy was isolated in 22 infants and associated with male pseudohermaphroditism and/or Wilms' tumour in 14.(ABSTRACT TRUNCATED AT 250 WORDS)

Homozygous inactivation of WT1 in a Wilms' tumor associated with the WAGR syndrome

Wilms' tumor is a childhood nephroblastoma that is postulated to arise through the inactivation of a tumor suppressor gene by a two-hit mechanism. A candidate 11p13 Wilms' tumor gene, WT1, has been cloned and shown to encode a zinc finger protein. Patients with the WAGR syndrome (Wilm's tumor, aniridia, genitourinary abnormalities, and mental retardation) have a high risk of developing Wilms' tumor and they carry constitutional deletions of one chromosome 11 allele encompassing the WT1 gene. Analysis of the remaining WT1 allele in a Wilms' tumor from a WAGR patient revealed the deletion of a single nucleotide in exon 7. This mutation likely played a key role in tumor formation, as it prevents translation of the DNA-binding zinc finger domain that is essential for the function of the WT1 polypeptide as a transcriptional regulator.

Complete and partial XY sex reversal associated with terminal deletion of 10q: report of 2 cases and literature review

We describe 2 karyotypically male infants with terminal deletion of 10q and mental retardation, multiple phenotypic anomalies and abnormal genitalia. One [karyotype 46,XY, del(10)(q26.1)] had female external genitalia; the other [karyotype 46,XY,-10,+der(10)t (10;16)(q26.2;q21)] had an intersex phenotype. Of 8 males previously reported with terminal 10q deletion as the major or only cytogenetic abnormality, 2 had an intersex phenotype, and the others all had combinations of cryptorchidism, micropenis, and hypospadias. Terminal 10q deletions appear to be strongly associated with abnormal male genital development, and should be specifically searched for in the cytogenetic workup of such cases.

Loss of heterozygosity at 11p13 in Wilms' tumours does not necessarily involve mutations in the WT1 gene

Loss of heterozygosity (LOH) in tumour cells is generally accepted as 'exposing' recessive cancer genes. The short arm of chromosome 11 shows consistent LOH in Wilms' tumours along its entire length. Occasionally, however, only the 11p13 and/or the 11p15 regions are involved. Deletions of the 11p13 region consistently predisposes to Wilms' tumorigenesis. We have analysed the recently cloned WT1 gene from the 11p13 region exon-by-exon in five tumours previously shown to have undergone LOH for the 11p13 region, using single strand conformation polymorphism analysis (SSCP) and PCR sequencing. Our analysis using SSCP failed to identify any band shifts in the WT1 gene from these tumours. In addition we also sequenced the zinc finger region of WT1, which is the part of the gene most frequently showing mutations. Only the normal sequence was found in all of these tumours. These results demonstrate that LOH in Wilms' tumours is not always related to mutations in the WT1 genes and argues strongly that another gene, probably in the 11p15 region, may be more important in Wilms' tumorigenesis.

Frequent loss of 11p13 and 11p15 loci in male germ cell tumours

Deletions within the short arm of the human chromosome 11 have been found to be involved in the genesis of several tumours, including different urogenital neoplasms. We have studied 31 male germ cell tumours (19 seminomas and 12 nonseminomas), and observed loss of heterozygosity at 11p loci in 40% (12/30) of these tumours [35% (9/26) at 11p13 and 31% (8/26) at 11p15]. Our data suggest that inactivation of one or more tumour suppressor genes on 11p are involved in the genesis of testicular cancer. In addition, identification of the parental origin of the allelic losses revealed a paternal loss in six patients and a maternal loss in one case.

Deletion of WT1 and WIT1 genes and loss of heterozygosity on chromosome 11p in Wilms tumors in Japan

Six of 39 sporadic Wilms tumors had gross homozygous or hemizygous WT1 and WIT1 deletions. Two Wilms tumor-aniridia-genitourinary abnormalities-mental retardation syndrome patients had total hemizygous WT1 and WIT1 deletions in both constitutional and nonsporadic type tumor cells. Four of the 8 tumors with WT1 and WIT1 deletions showed loss of constitutional heterozygosity (LOH) for markers limited to the 11p13 region. Seven of 19 Wilms tumors with neither WT1 nor WIT1 deletions also had LOH on 11p; 4 in the 11p15-11p13 region, one in the 11p15 and possibly also 11p13 regions, and two solely in the 11p15 region. Thus, 15 of the 41 Wilms tumors (37%) had WT1 and WIT1 deletions or LOH on 11p, and only 2 of the 27 tumors whose nonneoplastic normal tissues were available for study showed LOH limited to the 11p15 region. None of the 7 non-Wilms childhood renal tumors showed WT1 or WIT1 deletions, or LOH on 11p. These data suggest that Japanese Wilms tumors may be characterized by a higher incidence of the gross WT1 deletion and a lower incidence of LOH limited to the 11p15 region than the Caucasian counterparts. These molecular-genetic features may be contributing to the lower incidence of Wilms tumors in Japanese children than in Caucasian ones.

Wilms' tumour gene and function

The Wilms' tumour gene, WT1, encodes a protein with four zinc fingers that is probably a transcription factor. In humans, WT1 mutations can lead to childhood kidney tumours and to developmental defects of the kidney and gonad. The WT1 gene may have a role in the mesenchyme to epithelial switch in a range of mesodermally derived tissues. Furthermore, growth-factor genes may be targets for repression by the WT1 protein during development. WT1 is the first example of a tumour-suppressor gene with a specific developmental role.

Genetic implications for long-term survivors of childhood cancer

The author reviews current findings regarding inherited cancer predisposition and childhood cancer and proposes development of genetic services for long-term survivors of childhood cancer. Overall, it is suggested that relatively rare germline mutations in the tumor suppressor genes, Rb, p53, and WT1, may have important implications for long-term survivors relevant to familial cancer, second malignant neoplasms, and developmental disorders. Although continued research clearly is needed, planning for genetic services for long-term survivors should begin now.

Pericentric intrachromosomal insertion responsible for recurrence of del(11)(p13p14) in a family

The combined use of qualitative and quantitative analysis of 11p13 polymorphic markers together with chromosomal in situ suppression hybridization (CISS) with biotin labeled probes mapping to 11p allowed us to characterize a complex rearrangement segregating in a family. We detected a pericentric intrachromosomal insertion responsible for recurrence of del(11)(p13p14) in the family: an insertion of brand 11p13-p14 carrying the genes for predisposition to Wilms' tumor, WT1, and for aniridia, AN2, into the long arm of chromosome 11 in 11q13-q14. Asymptomatic balanced carriers were observed over three generations. Classical cytogenetics had failed to detect this anomaly in the balanced carriers, who were first considered to be somatic mosaics for del(11)(p13). Two of these women gave birth to children carrying a deleted chromosome 11, most likely resulting from the loss of the 11p13 band inserted in 11q. Although in both cases the deletion encompassed exactly the same maternally inherited markers, there was a wide variation in clinical expression. One child, with the karyotype 46,XY, del(11)(p13p14), presented the full-blown WAGR syndrome with aniridia, mental retardation, Wilms' tumor, and pseudohermaphroditism, but also had proteinuria and glomerular sclerosis reminiscent of Drash syndrome. In contrast, the other one, a girl with the karyotype 46,XX,del(11)(p13), only had aniridia. Although a specific set of mutational sites has been observed in Drash patients, these findings suggest that the loss of one copy of the WT1 gene can result in similar genital and kidney abnormalities.

Wilms' tumour and parental age: a report from the National Wilms' Tumour Study

Age distributions of parents at birth of patients registered in the National Wilms' Tumour Study were compared to those of the general population. An increasing incidence of sporadic Wilms' tumour with increasing paternal age was found, with a relative risk of 2.1 of tumour in children of fathers over 55 compared to children of fathers younger than 20. A similar effect for maternal age was found, with a relative risk of 1.4 in children of mothers over 40 compared to children of mothers younger than 20. The maternal age effect was much weaker among patients registered later in the study; in the later, more completely ascertained cohort, paternal age appears to be the major contributor to the parental age effect. Little difference in paternal age distribution was found between patients with bilateral and unilateral tumour and between male and female patients. In contrast, patients with reported associated congenital anomalies, patients with evidence of nephrogenic rests, and patients with early or late age-of-onset of tumour had parents who were, on average, substantially older than the remainder. These findings lend support to the idea that many Wilms' tumours result from new germline mutations. Further, the histologic composition of such tumours may be sufficiently distinct as to provide a valuable diagnostic indicator of the etiology of these tumours.

Homozygous somatic Wt1 point mutations in sporadic unilateral Wilms tumor

Wilms tumor may be caused by loss of function of genes at different loci. A Wilms tumor suppressor gene, WT1, at chromosome 11 band p13, has recently been cloned and characterized. WT1 has been implicated in the development of Wilms tumor by virtue of mutations in patients with genitourinary anomalies and susceptibility to Wilms tumor. Homozygous intragenic mutations have been reported in Wilms tumors, but usually not in sporadic unilateral Wilms tumors, which constitute the majority of Wilms tumor cases. Using the single-strand conformational polymorphism assay, we have identified three sporadic unilateral Wilms tumors with homozygous point mutations: one with a de novo germ-line nonsense point mutation within WT1 exon 8, and two carrying a somatic mutation within WT1 exon 10. In all three cases loss of the wild-type allele was demonstrated by tumor loss of heterozygosity. This report provides an example of two somatic mutations in the same tumor expected to inactivate WT1 function.

A point mutation found in the WT1 gene in a sporadic Wilms' tumor without genitourinary abnormalities is identical with the most frequent point mutation in Denys-Drash syndrome

We have analyzed exon 9 of the WT1 gene of 18 non-familial/sporadic unilateral Wilms' tumors (WTs) from Japanese patients, by the polymerase chain reaction single-strand conformation polymorphism (PCR-SSCP) method. After screening these WTs, a nucleotide alternation, which was present on both alleles, was found in only one case. Furthermore, PCR-SSCP analysis of the constitutional DNA revealed that this patient carried the mutation on only one allele in the germline. Sequence analysis showed that the tumor carried a point mutation (C-1180 to T-1180) in WT1 exon 9 of both alleles, resulting in an Arg-394 to Trp-394 amino acid substitution within the third zinc finger domain of the WT1 product. Interestingly, this mutation is identical with the most frequent point mutation associated with the Denys-Drash syndrome. However, the classical triad of Denys-Drash syndrome does not apply to this patient. This is in the first report of the point mutation in the zinc finger domain of both WT1 alleles in a sporadic unilateral WT without genitourinary abnormalities, and the mutation suggests that some sporadic WTs carry the Denys-Drash WT1 mutations.

Genetic mosaicism in normal tissues of Wilms' tumour patients

We describe the partial loss of heterozygosity (LOH) at chromosome 11p loci in normal tissues (normal kidney and/or blood) from four of 67 Wilms' tumour patients. Autologous tumour DNA showed complete loss of the same, maternally derived, alleles. These observations indicate that the normal tissues were mosaic for cells heterozygous and homozygous for 11p markers and that tumours subsequently developed from the homozygous cells that had undergone an 11p somatic recombination event. We suggest that LOH for 11p alleles is compatible with normal growth and differentiation and is significant pathologically only when accompanied by other genetic alterations.

Chromosomal localisation of two putative 11p oncosuppressor genes involved in human ovarian tumours

In this study, 44 primary or metastatic human ovarian tumours were tested for allelic deletions on the short arm of chromosome 11. Analysis of 12 polymorphic loci by Southern blotting evidenced loss of heterozygosity (LOH) in at least one locus in 41% of cases. Moreover, two hot spots of deletions were tentatively mapped on 11p13 and 11p15.5. Our results demonstrated that LOH at 11p is a common event in ovarian carcinomas and were indicative of the possible existence in 11p of two oncosuppressor genes involved in ovarian carcinogenesis. The similarity observed with 11p allelic losses in Wilms tumours, clustered in 11p13 and 11p15.5 too, suggests that deletion and possibly inactivation of the same growth regulatory genes (WT genes) could also contribute to development of the malignant phenotype in ovarian carcinomas. Finally, a statistically significant association (P = 0.005) between 11p deletions and hepatic involvement was suggested by the analysis of distribution of 11p LOH relative to different clinical and pathological parameters of the tumour patients.

Introduction to the genetics of primary renal tumors in children

Wilms tumor can be explained only partially by the "two hit" model that was originally developed for retinoblastoma. Heterogeneity of two kinds operates. The first is that four other primary tumors are regularly observed in children, and the second is that Wilms tumor itself appears to represent more than one genetic entity. All five of these primary renal tumors arise from primary or secondary mesenchyme, renal blastema, or renal epithelium. Mesoblastic nephroma, and possibly clear cell sarcoma, may have some genetic affinity with Wilms tumor, but rhabdoid tumor of the kidney and renal carcinoma do not. At least three different genes seem to be important in the origin of Wilms tumor. One, WT1, whose mutations may be associated with aniridia, may follow the "two hit" model in that there are cases in which both copies of the gene are defective or lost, as expected for a tumor suppressor gene. A second gene, which is associated with Beckwith-Wiedemann Syndrome (BWS) and which has not been cloned, appears to be imprinted in females, and may have an oncogene function. It is evidently activated by gain of a paternal allele or by loss of the inactive, but possibly trans-sensing, maternal allele. Activation of the insulin-like growth factor II gene may be a final common pathway for mutation in both WT1 and BWS. A third gene is unlinked to either of the other two, but its location and function are unknown. It shares with WT1 specificity for Wilms tumor, which is not true of the BWS gene.

Epidemiology of Wilms tumor

Wilms tumor affects approximately one child per 10,000 worldwide before the age of 15 years. Incidence rates appear to be slightly elevated for U.S. and African Blacks in comparison to Whites, but are only half as great among Asians. Several case-control studies have suggested that paternal occupational or maternal hormonal exposures during pregnancy may increase the risk of Wilms tumor, but small numbers of subjects and inconsistencies in the patterns of exposures do not permit firm conclusions to be drawn. It is unlikely that such environmental exposures play a major role in the etiology of Wilms tumor. The median age-at-onset of Wilms tumor is 38 months in the U.S. National Wilms Tumor Study series, with cases in girls occurring on average 6 months later than in boys. Patients with bilateral tumors, aniridia, cryptorchism/hypospadias, Beck-with-Wiedemann syndrome, or intralobar nephrogenic rests tend to be diagnosed much younger than average (median 17-27 months). Those with familial disease or multicentric tumors have intermediate age-at-onset distributions, while those with perilobar nephrogenic rests are diagnosed at older ages. The epidemiologic features suggest that somatic mosaicism, rather than a germline mutation, may be responsible for some of the bilateral and multicentric cases.

The expression of the Wilms' tumour gene, WT1, in the developing mammalian embryo

In the developing mouse, the Wilms' tumour gene, WT1, is first expressed in the intermediate mesenchyme lateral to the coelomic cavity (13 somite, early 9 dpc embryo). A few hours later, it is present around all the cavity and in the urogenital ridge (the earliest mesonephric tubules) and the differentiating heart mesothelium. By 11 dpc, expression is in the uninduced metanephric mesenchyme and in the presumptive motor neurons of the spinal cord. By 12.5 dpc, WT1 expression has increased in the induced mesenchyme of the kidney and a day later is particularly marked in the nephrogenic condensations. At 13.5 dpc, WT1 is briefly expressed in some differentiating body-wall musculature, while two days later, there is a small domain of expression in the roof of the fourth ventricle of the brain. By day 20, however, expression has become restricted to the kidney glomeruli. RNA-PCR analysis on 12.5 dpc embryos and on adult tissues shows that WT1 is weakly expressed in both eye and tongue. The expression pattern in human embryos (28-70 days) is very similar to that in the equivalent mouse stages (10-15 dpc). The results indicate that WT1 is mainly present in mesodermally derived tissues, although exceptions are ectodermally derived spinal cord and brain. The data indicate that WT1 plays a role in mediating some cases of the mesenchyme-to-epithelial transition, but its expression elsewhere argues that it has other tissue-specific roles in development.

Clinical phenotypes and Wilms tumor

Wilms tumor can occur in association with a number of recognizable patterns of malformation, as first described by Miller et al. in 1964. This paper represents a synthesis of the current state of knowledge regarding recognizable phenotypes associated with Wilms tumor. Specific disorders discussed include the Beckwith-Wiedemann syndrome, which has been localized to 11p15.5; isolated hemihypertrophy; sporadic aniridia, which is almost always associated with del(11p13); genital anomalies, particularly male pseudohermaphroditism and the Denys-Drash syndrome; and more weakly associated or uncommon conditions, such as neurofibromatosis and Perlman syndrome, respectively. Wilms tumor (WT) surveillance for specific high risk phenotypes should include a rational schedule of abdominal ultrasound examinations, taking into account the epidemiology of WT associated with specific disorders. Physical examination, with emphasis on abdominal palpation, and urinalysis should also be performed on a rational schedule. The schedule of examinations needs to be arrived at with input from clinical geneticists, oncologists, epidemiologists and pathologists with WT expertise. Lastly, care-takers of high risk individuals should be taught abdominal palpation, to be performed daily at home.

Mutations of the APC (adenomatous polyposis coli) gene

Several investigators have reported germline mutations of the APC gene in patients with familial adenomatous polyposis (FAP) as well as somatic mutations in tumors developed in digestive organs (stomach, pancreas, colon, and rectum). Those results provide evidence that inactivation of the APC gene plays a significant role in FAP and in sporadic tumors of these tissues. APC mutations have led to some interesting observations. First, the great majority of the mutations found to date would result in truncation of the APC product. Second, almost all the mutations have occurred within the first half of the coding sequence, and somatic mutations in colorectal tumors are further clustered in a particular region called MCR (mutation cluster region). Third, most identified point mutations in the APC gene are transitions from cytosine to other nucleotides. Fourth, the location of germ-line mutations tends to correlate with the number of colorectal polyps in FAP patients. Furthermore, inactivation of both alleles of the APC gene seems to be required as an early event to develop most of adenomas and carcinomas in the colon and rectum as well as some of those in the stomach.