Treatment with nephrectomy only for small, stage I/favorable histology Wilms' tumor: a report from the National Wilms' Tumor Study Group.

PURPOSE: Children younger than 24 months with small (< 550 g), favorable histology (FH) Wilms tumors (WTs) were shown in a pilot study to have an excellent prognosis when treated with nephrectomy only. PATIENTS AND METHODS: A study of nephrectomy only for the treatment of selected children with FH WT was undertaken. Stringent stopping rules were designed to insure closure of the study if the true 2-year relapse-free survival rate was 90% or lower. RESULTS: Seventy-five previously untreated children younger than 24 months with stage I/FH WTs for which the surgical specimen weighed less than 550 g were treated with nephrectomy only. Three patients developed metachronous, contralateral WT 1.1, 1.4, and 2.3 years after nephrectomy, and eight patients relapsed 0.3 to 1.05 years after diagnosis (median, 0.4 years; mean, 0.51 years). The sites of relapse were lung (n = 5) and operative bed (n = 3). The 2-year disease-free (relapse and metachronous contralateral WT) survival rate was 86.5%. The 2-year survival rate is 100% with a median follow-up of 2.84 years. The 2-year disease-free survival rate (excluding metachronous contralateral WT) was 89.2%, and the 2-year cumulative risk of metachronous contralateral WT was 3.1%. CONCLUSION: Children younger than 24 months treated with nephrectomy only for a stage I/FH WT that weighed less than 550 g had a risk of relapse, including the development of metachronous contralateral WT, of 13.5% 2 years after diagnosis. All patients who experienced relapse on this trial are alive at this time. This approach will be re-evaluated in a clinical trial using a less conservative stopping rule.

Absence of PPP2R1A mutations in Wilms tumor.

Evidence from genetic linkage analysis indicates that a gene located at 19q13.4, FWT2, is responsible for predisposition to Wilms tumor in many Wilms tumor families. This region has also been implicated in the etiology of sporadic Wilms tumor through loss of heterozygosity analyses. The PPP2R1A gene, encoding the alpha isoform of the heterotrimeric serine/threonine protein phosphatase 2A (PP2A), is located within the FWT2 candidate region and is altered in breast and lung carcinomas. PPP2R1B, encoding the beta isoform, is mutated in lung, colon, and breast cancers. These findings suggested that both PPP2R1A and PPP2R1B may be tumor suppressor genes. Additionally, PP2A is important in fetal kidney growth and differentiation and has an expression pattern similar to that of the Wilms tumor suppressor gene WT1. Since PPP2R1A was therefore a compelling candidate for the FWT2 gene, we analysed the coding region of PPP2R1A in DNA and RNA samples from affected members of four Wilms tumor families and 30 sporadic tumors and identified no mutations in PPP2R1A in any of these 34 samples. We conclude that PPP2R1A is not the 19q familial Wilms tumor gene and that mutation of PPP2R1A is not a common event in the etiology of sporadic Wilms tumor.

Pulmonary dysplasia, Denys-Drash syndrome and Wilms tumor 1 gene mutation in twins.

While a genetic basis for the association of developmental lung and kidney defects has been suspected, the involvement of specific genes in this process is under active investigation. We report such a possible genetic linkage present in identical twins with a mutant Wilms tumor (WT1) gene. Twin girls, born at 35 weeks gestation, manifested symptoms of congenital nephrotic syndrome, renal failure, and severe respiratory abnormalities refractory to assisted ventilation. Both died at 1 month of age. Renal biopsies and autopsy kidney tissue from both the girls revealed diffuse mesangial sclerosis (DMS). Autopsy lung tissue revealed pulmonary dysplasia and hypoplasia in both twins. The WT1 gene from renal tissue in both twins was analyzed for mutations using polymerase chain reaction (PCR) amplification and the single-strand conformation polymorphism (SSCP) technique. Both twins possessed an identical missense mutation in exon 8 of the WT1 gene, resulting in replacement of arginine by histidine at amino acid 366 (arg366his) in the WTI protein. This mutation has previously been described in Denys-Drash syndrome. The WT1 gene plays a role in mesenchymal epithelial (ME) interactions in the developing urogenital system, and possibly has a similar role during lung morphogenesis. We propose that this WT1 gene mutation contributes to both DMS and developmental pulmonary abnormalities by altering ME interactions in both organs.

Frequent association of beta-catenin and WT1 mutations in Wilms tumors.

The etiology of Wilms tumor, an embryonic kidney tumor, is genetically heterogeneous. One Wilms tumor gene, WT1, which encodes a zinc finger transcription factor, is mutated in 10-20% of Wilms tumors, but it is still not clear what critical cellular pathway(s) is affected by these mutations. Recently beta-catenin mutations have been reported in 6 of 40 (15%) of Wilms tumors. Beta-catenin is the central effector in the Wnt signal transduction pathway, and deregulation of beta-catenin signaling is critical in the development of a number of malignancies. The observation of beta-catenin mutations in Wilms tumors suggests that abrogation of the Wnt signaling pathway also plays a role in some Wilms tumors. To assess the relationship of WT1 mutations vis-à-vis beta-catenin mutations in Wilms tumor, we analyzed 153 primary tumors, and 21 of 153 (14%) carried beta-catenin mutations. Surprisingly, we observed a highly significant (P = 3.6 x 10(-13)) association between WT1 and beta-catenin mutations; 19 of 20 beta-catenin-mutant tumors had also sustained WT1 mutations. By analogy to the patterns of concordant and discordant gene mutations observed in other tumors, our data suggest that mutation of WT1 and beta-catenin affects two different cellular pathways, both of which are critically altered in at least a subset of Wilms tumors.

Familial Wilms' tumor with neural elements: characterization by histology, immunohistochemistry, and genetic analysis.

Wilms' tumor (WT) is the most common renal malignancy of children. While most occur sporadically, a small percentage are familial or occur as part of a developmental syndrome. Classic WTs exhibit a triphasic histologic pattern composed of blastema, epithelium, and stroma. Occasionally, heterologous elements may also be observed. In this study we investigated a series of four WTs that occurred within a single familial aggregate and contained focal areas of neural differentiation. The tumors were evaluated histologically for the presence of neural elements and immunohistochemically for expression of neural-related markers. Genetic linkage analysis was performed on 3 of the 4 WTs. In addition to the classic triphasic histology, the WTs contained tumor rosettes (4/4), ganglion cells (2/4), foci of ganglioneuromatous differentiation (2/4), and anaplasia (1/4). Staining for chromogranin, S-100, synaptophysin, vimentin, and neuron-specific enolase was positive in all 4 tumors within the areas of neural differentiation whereas staining for CD99 (013) and glial fibrillary acidic protein was negative. Linkage analysis studies suggest that the familial predisposition gene segregating in this family is at 19q13.4. To our knowledge, this is the first reported series of WTs with neural differentiation that occurred within a single family aggregate. Genetic linkage analysis of this family is consistent with linkage to the FWT2 WT predisposition gene at 19q13.4. We propose that these tumors may represent a unique manifestation of tumor susceptibility in this family.

Mutation in the PAX6 gene in twenty patients with aniridia.

This is a report on the nature of the mutations in the PAX6 gene in twenty patients with aniridia. Five of the twenty patients had sporadic aniridia with deletions in chromosome 11p13. Three of the five had WAGR syndrome (Wilms tumor, aniridia, genitourinary anomalies, mental retardation), and the other two had deletions whose breakpoints occurred between the PAX6 and the WT1 genes. Allelic losses at PAX6 were of paternal origin. The remaining fifteen patients with aniridia had intragenic mutations in the PAX6 gene, with mutations found from exon 5 to exon 12. Twelve cases of dysfunctional PAX6 were due to premature termination of the protein by nonsense mutations (five cases), splicing defect (one case), deletion (two cases), deletion-insertions (two cases), and tandem repeat insertions (two cases). One patient (P2) had a PAX6 protein with de novo in-frame deletion of alanine, arginine, and proline at codon positions 37, 38, and 39. These codons are in the paired box region, and codon 38 is in contact with the phosphate group of the sugar-phosphate backbone of the target DNA. Another patient (P8) had a single nucleotide transition at c.1182 (nucleotide number, Genbank accession #M93650, used as in Glaser et al. [1992]), which generated both a missense mutation (Q255H) and a splicing defect. A missense mutation was found at G387E in a third patient (P10). All observed mutations support the notion that haploinsufficiency in PAX6 results in aniridia and associated eye anomalies.

Frequent loss of imprinting at the IGF2 and H19 genes in head and neck squamous carcinoma.

Genomic imprinting is an inherited epigenetic phenomenon that results in parental-origin-specific gene expression in somatic cells. Relaxation or loss of this feature in certain genes has been demonstrated in several pediatric and adult neoplasms, suggesting an association with tumorigenesis. We analysed 64 primary untreated head and neck squamous carcinoma for the loss of imprinting in the IGF2 and H19 genes to determine the implications of this alteration in the development and progression of these tumors. Forty-nine (77%) of the 64 tumors were informative for imprinting analyses of these genes. IGF2 and H19 were imprinted in all normal squamous epithelium examined. Twelve (37.5%) of 32 tumors informative for H19 and 11 (40.7%) of 27 tumors informative for IGF2 manifested loss of imprinting. Ten tumors were informative for both genes, of which four maintained the constitutional imprinting and six showed loss of imprinting at either H19 or IGF2. These data suggest that loss of imprinting at the IGF2 and H19 loci play a role in the oncogenesis of head and neck carcinoma.

Wilms tumor genetics.

Wilms tumor (WT), a sporadic and familial childhood kidney tumor, is genetically heterogeneous. One WT gene, WT1 at 11p13, has been cloned, but only a minority of WTs carry detectable mutations at that locus. WT1 can also be excluded as the predisposition gene in most WT families, implying the existence of other WT genes. Studies of WT families have demonstrated that familial predisposition is also heterogeneous and involves at least two other loci besides WT1. In addition to WT1 and the familial predisposition genes, a role for other genes in the development of WTs is implied by the somatic occurrence of genetic and epigenetic alterations such as loss of heterozygosity and loss of imprinting in tumors and, rarely, the observation of nonchromosome-11 constitutional aberrations in WT patients. Determining the pattern of presence or absence of these various genetic alterations in tumors and elucidating the function of the genes involved will provide a better understanding of the cellular processes that are critical for normal cell growth and differentiation, but are abrogated in the course of tumorigenesis.

Linkage of familial Wilms' tumor predisposition to chromosome 19 and a two-locus model for the etiology of familial tumors.

Familial predisposition to Wilms' tumor (WT), a childhood kidney tumor, is inherited as an autosomal dominant trait. For most WT families studied, the 11p13 gene WT1 and genomic regions implicated in tumorigenesis in a subset of tumors can be ruled out as the site of the familial predisposition gene. Following a genome-wide genetic linkage scan, we have obtained strong evidence (log of the odds ratio = 4.0) in five families for an inherited WT predisposition gene (FWT2) at 19q13.3-q13.4. In addition, we observed loss of heterozygosity at 19q in tumors from individuals from two families in which 19q can be ruled out as the site of the inherited predisposing mutation. From these data, we hypothesize that alterations at two distinct loci are critical rate-limiting steps in the etiology of familial WTs.

Evidence for genetic heterogeneity in familial Wilms' tumor.

Wilms' tumor (WT), a childhood kidney cancer, occurs both sporadically and, less frequently, in a familial context. Genetic linkage studies of several large WT families have excluded the one cloned WT gene, WT1, as the locus responsible for familial predisposition. These data demonstrate the existence of a familial predisposition gene distinct from WT1 and, more broadly, imply that the genetic etiology of WT is heterogenous. However, it has been unknown whether the predisposition observed in large WT families is also heterogenous or perhaps is due to mutations at a single locus. Recently, examination of a large French-Canadian WT family has demonstrated genetic linkage to 17q12-q21. We report here the results from a genetic linkage study of six WT pedigrees. Analyses of genotype data from eight loci within the 17q12-q21 region in these families resulted in cumulative lod scores of <-4.0 through the region, thereby excluding linkage. The ability to rule out the 17q region as the site of a predisposition gene in several of these pedigrees individually demonstrates the existence of more than one gene that predisposes to WT in large pedigrees and again emphasizes that the etiology of WT is genetically heterogenous.

Genotype/phenotype correlations in Wilms' tumor.

Study of genotype/phenotype relationships involving the Wilms' tumor (WT) gene, WT1, in WT patients has provided insights into the function of the WT1 protein, a transcriptional regulator, and has suggested possible mutational mechanisms important in the etiology of WT. For example, the identification of deletion/insertion mutations in the first exon implicates a deletion hotspot consensus sequence in the etiology of these mutations. The disproportionate number of WT/aniridia patients with such mutations further suggest that this genetic mechanism may be enhanced by the hemizygous state. WT1 mutations are observed throughout the gene and, as predicted by the two hit mutational model, germline mutations predominantly occur in patients with congenital genitourinary (GU) anomalies and/or bilateral disease. The presence of hemizygous mutations in tumors from individuals with germline 11p13 deletions encompassing WT1 supports the hypothesis that inactivation of both WT1 alleles is important in tumorigenesis. Analyses of WT1 mutations in individuals with WT-associated Drash syndrome and WT patients with GU anomalies in the absence of Drash syndrome indicate that Drash patients almost invariably carry germline missense mutations in the zinc finger domains whereas WT/GU patients carry germline mutations that delete the WT1 gene or encode truncated proteins. These data suggest a functional difference between mutant WT1 protein carrying a single amino acid substitution versus mutant WT1 protein that is grossly truncated or WT1 haploinsufficiency. These and other genotype/phenotype correlations in WT patients will be discussed in more detail.

Analysis of possible WT1 RNA processing in primary Wilms tumors.

WT1 RNA processing abnormalities have been suggested to play a role in the development of Wilms tumor by reports of editing at codon 280 in the rat WT1 transcript (codon 281 in humans) and aberrant splicing of exon 2 in WT1 transcripts from Wilms tumor xenograft cell lines. Both events result in a functionally changed WT1 protein and are potential mechanisms of altering normal protein function in the absence of WT1 DNA mutations. To determine whether either of these RNA processing events occurs in primary Wilms tumors, we analysed WT1 mRNA from 15 primary tumors. There was no evidence of WT1 RNA editing at codon 281, and only one primary tumor displayed aberrant splicing of exon 2. Sequence and Southern analysis of DNA from this tumor did not reveal any alteration in or around exon 2. These results suggest that neither RNA editing at codon 281 nor aberrant exon 2 splicing is a frequent mechanism of WT1 alteration during tumorigenesis.

Microsatellite instability in preinvasive and invasive head and neck squamous carcinoma.

To investigate the extent and significance of microsatellite instability in head and neck carcinogenesis we analyzed DNA extracted from normal squamous epithelium, severe dysplasia, and corresponding carcinoma specimens from 20 patients by multiplex polymerase chain reaction. Loci on chromosomes 3p, 5p, 5q, 8p, 9p, 9q, 11q, 17p, 17q, 18p, 18q were selected for analysis. Our results show that three of the dysplasias (15.0%) and six of the invasive carcinoma (30.0%) manifested instability at multiple loci. Two of the dysplastic lesions had identical alterations in the corresponding carcinomas and one showed instability differences in only two of eight loci. Normal squamous epithelium lacked microsatellite instability. No apparent association between smoking, alcohol use, or family history of cancer and instability was found in this small cohort. Invasive carcinomas with instability were relatively more poorly differentiated and had a higher stage and a high proliferative fraction. Our study indicates that microsatellite instability is 1) noted in a small subset of dysplastic lesions of head and neck squamous epithelium and 2) present in approximately one-third of invasive lesions, usually with aggressive characteristics, and may clinically be a late event associated with tumor progression.

Allelic loss and replication errors at microsatellite loci on chromosome 11p in head and neck squamous carcinoma: association with aggressive biological features.

The frequent loss of heterozygosity (LOH) demonstrated at chromosome 11p regions in several sporadic malignancies has suggested the presence of tumor suppressor genes at these locations. To obtain detailed mapped incidence of the microsatellite alterations at these regions and to investigate the possible correlation between the genotype and the pathobiological characteristics of head and neck squamous carcinoma, we analyzed paired DNA samples from normal mucosa and primary tumor specimens from 56 patients with these tumors. Our results show that 50.9% of the tumors had microsatellite alterations at one or more of these loci. LOH was manifested in 45. 5% and instability in 5.5% of the tumors. 11p15 loci showed more frequent LOH (39.6%) than those of 11p13 (29.3%) and 11p11-12 (18. 8%); the D11S988 (11p15) marker showed the highest single locus incidence of LOH (29.7%). Eight tumors (22.2%) demonstrated simultaneous LOH at both the 11p15 and 11p13 regions. LOH was significantly associated with poor histological differentiation, DNA aneuploidy, and high proliferative activity in these neoplasms. Our study extends the involvement of the 11p13 and 11p15 regions to head and neck squamous tumorigenesis and indicates that the terminal loci of 11p may harbor a tumor suppressor gene(s) associated with the progression of these tumors.

Pleuropulmonary blastoma: a marker for familial disease.

OBJECTIVE: To catalog and evaluate patterns of disease in families of children with pleuropulmonary blastoma (PPB). METHODS: Data have been collected since 1988 on 45 children with PPB and their families. All pathologic materials were centrally reviewed. Preliminary molecular genetic analyses were performed when possible. RESULTS: In 12 of 45 patients, an association was found between PPB and other dysplasias, neoplasias, or malignancies in the patients with or in their young relatives. The diseases found to be associated with PPB include other cases of PPB, pulmonary cysts, cystic nephromas, sarcomas, medulloblastomas, thyroid dysplasias and neoplasias, malignant germ cell tumors, Hodgkin disease, leukemia, and Langerhans cell histiocytosis. Abnormalities of the p53 tumor suppressor gene, Wilms tumor suppressor gene (WT1), and the putative second genetic locus for Wilms tumor (WT2) were not found in preliminary investigations. CONCLUSIONS: The occurrence of PPB appears to herald a constitutional and heritable predisposition to dysplastic or neoplastic disease in approximately 25% of cases. All patients with PPB and their families should be investigated carefully. Further research of this new family cancer syndrome may provide insight into the genetic basis of these diseases.

Inheritance of unequal numbers of the genes encoding the human neutrophil defensins HP-1 and HP-3.

It is unclear whether the six known human defensin peptides are all encoded by separate genes or whether some of them are allelic. Three of the peptides, HP-1, HP-2, and HP-3, differ by only one amino acid, and it is thought that HP-2 may represent a proteolytic product of HP-1 and/or HP-3. To help determine the relationship of these three proteins, we isolated a nearly full-length cDNA encoding HP-1 with a sequence very similar to, but different from, the previously isolated HP-1 and -3 cDNAs. Gene copy number experiments established that there were at least two but fewer than five defensin genes with a high level of similarity to the HP-1 cDNA (HP-1/3-like). Three genomic clones were isolated that contained two different configurations of the HP-1/3-like sequences. Sequencing established that one encoded the HP-1 peptide, whereas the other encoded HP-3. Analysis of DNAs obtained from 18 unrelated individuals by Southern blot analysis revealed the expected fragments as well as additional fragments that were not present in the genomic clones. This suggested the possibility of alleles; however, when DNAs from families were examined, these fragments did not segregate in an obvious Mendelian fashion. The HP-1/3-like defensin genes are on human chromosome 8. Surprisingly, somatic cell hybrid mapping showed that the number of HP-1/3-like genes on isolated copies of chromosome 8 was variable. We conclude that individuals can inherit versions of chromosome 8 harboring either two or three copies of the genes that encode the HP-1, HP-2, and/or HP-3 peptides.

Sequential loss of heterozygosity at microsatellite motifs in preinvasive and invasive head and neck squamous carcinoma.

Studies of sequential molecular alterations in noninvasive and invasive head and neck squamous carcinoma are few in number. Consequently, the genetic changes associated with the neoplastic transformation of these carcinomas have not been defined. To identify chromosomal alterations in preinvasive and invasive head and neck squamous carcinoma, we analyzed DNA from microdissected normal squamous epithelium, severe dysplasia, and invasive carcinoma samples from 20 patients for loss of heterozygosity (LOH) at microsatellite loci by multiplex PCR. Twenty-five microsatellite repeats on chromosomes 3p, 5q, 8p, 9p and 9q, 11q, 17p, 17q, and 18p and 18q regions were used. In informative cases, LOH in noninvasive lesions was observed in 9p (28%), 9q and 18q (10%), 11q and 17p (7%), and 3p and 18p (5%). A high incidence of LOH in invasive carcinoma was observed at 9p (72%), 8p (53%), 3p (47%), 9q (35%), and 11q (33%). LOH was also associated with DNA aneuploidy, high tumor stage, and poor histological differentiation. Our results indicate that: (a) the high incidence of LOH at loci on chromosomes 9p, 8p, 3p, 9q, and 11q implicate these regions in head and neck squamous carcinoma tumorigenesis; (b) 9p loci alterations are manifested in the early development of these tumors; (c) LOH is correlated with poor prognostic clinicopathological factors; and (d) LOH at 8p loci appears to be associated with the tumor's aggressive features.

Hereditary hyperparathyroidism-jaw tumor syndrome: the endocrine tumor gene HRPT2 maps to chromosome 1q21-q31.

The syndrome of hereditary hyperparathyroidism and jaw tumors (HPT-JT) is characterized by inheritance, in an autosomal dominant pattern, of recurrent parathyroid adenomas, fibro-osseous tumors of the mandible and/or maxilla, Wilms tumor, and parathyroid carcinoma. This syndrome is clinically and genetically distinct from other endocrine neoplasia syndromes and appears to result from mutation of an endocrine tumor gene designated "HRPT2." We studied five HPT-JT families (59 persons, 20 affected); using PCR-based markers, we instituted a genomewide linkage search after excluding several candidate genes. Lod scores were calculated at various recombination fractions (theta), penetrance 90%. We mapped HRPT2 to the long arm of chromosome 1 (1q21-q31). The maximal lod score was 6.10 at theta = .0 with marker D1S212, or > 10(6) odds in favor of linkage. In six hereditary Wilms tumor families (96 persons, 29 affected), we found no linkage to 1q markers closely linked with HRPT2 (lod scores -15.6 [D1S191] and -17.8 [D1S196], theta = .001). Nine parathyroid adenomas and one Wilms tumor from nine members of three HPT-JT families were examined for loss of heterozygosity at linked loci. The parathyroid adenomas and Wilms tumor showed no loss of heterozygosity for these DNA markers. Our data establish that HRPT2, an endocrine tumor gene on the long arm of chromosome 1, is responsible for the HPT-JT syndrome but not for the classical hereditary Wilms tumor syndrome.

WT1 exon 1 deletion/insertion mutations in Wilms tumor patients, associated with di- and trinucleotide repeats and deletion hotspot consensus sequences.

The WT1 gene is known to play a role in at least some cases of Wilms tumor (WT). The first exon of the gene is highly GC rich and contains many short tandem di- and trinucleotide repeats, interrupted direct repeats, and CCTG (CAGG) motifs that have been identified as hotspots for DNA deletions. We have analyzed 80 WT patient samples for mutations in the first exon of WT1, either by SSCP analysis of the first 131 bp of the coding portion of WT1 exon 1 or by size analysis of a PCR product encompassing the coding region of exon 1 in addition to flanking noncoding regions. We report here the occurrence of somatic and germ-line deletion and insertion mutations in this portion of the gene in four WT patients. The mutations are flanked by short direct repeats, and the breakpoints are within 5 nt of a CCTG (CAGG) sequence. These data suggest that a distinctive mutational mechanism, previously unrecognized for this gene, is important for the generation of DNA mutations at the WT1 locus.