Two splice variants of the Wilms' tumor 1 gene have distinct functions during sex determination and nephron formation.

Alternative splicing of Wt1 results in the insertion or omission of the three amino acids KTS between zinc fingers 3 and 4. In vitro experiments suggest distinct molecular functions for + and -KTS isoforms. We have generated mouse strains in which specific isoforms have been removed. Heterozygous mice with a reduction of +KTS levels develop glomerulosclerosis and represent a model for Frasier syndrome. Homozygous mutants of both strains die after birth due to kidney defects. Strikingly, mice lacking +KTS isoforms show a complete XY sex reversal due to a dramatic reduction of Sry expression levels. Our data demonstrate distinct functions for the two splice variants and place the +KTS variants as important regulators for Sry in the sex determination pathway.

[Genetics of renal tumors]. / Vesedaganatok genetikája.

The quintessence of malignant transformation is the genetic alteration of the tumor progenitor cell, i.e. somatic mutation. The genetic change appearing at chromosome and/or gene level results in the disturbance of the balance of cell proliferation and differentiation. In solid tumors, including renal tumors, the basic genetic mechanism proved to be the loss of function of a specific gene pair caused by loss of the particular chromosome or chromosomal region (monosomy, deletion) or by mutation of the gene. In the well studied Wilms' tumor-aniridia-syndrome the distal part of 11p13 region is deleted. The responsible gene is the WT-1 tumor suppressor gene, a Zn finger type transcription factor. In the majority of cases the mutation of this gene leads to the tumor formation without cytogenetically detectable deletion. For manifestation of the tumor the functional damage of both alleles is needed. In other histological types of renal tumors a great variation of chromosome losses and gains, as well as translocations can be identified. In Wilms tumor of embryonic origin, tumor suppressor genes located on the short arms of chromosomes 16 and 17 play a role in the pathogenesis. Besides, the significance of abnormal genomic imprinting of IGF2 and H19 genes located on 11p15 has also been confirmed. If a part of the embryonic cells do not regress, they may develop to papillary carcinoma together with the appearance of trisomies of chromosomes 7 and 17 and loss of Y. In the transformation process from papillary adenoma to carcinoma, duplication of several chromosomal regions is involved (3q+, +8, +12, +16, +20). The origin of renal carcinoma developing from normal nephron cells is associated with a deletion of 3p and 5q+, while during the progression of the disease further variable chromosome losses appear (6q-, 8p-, 14q-, -9). Tumor-specific cytogenetic and molecular genetic changes confirm the morphological classification of epithelial renal tumors pointing at the relation of the various entities or their independence. Based on cytogenetic alterations, a sequential predictive model of renal tumors can be developed. Individual types, together with joining and sequential appearance of aberrations are in line with the multistep mechanism of carcinogenesis. At the same time, the specific cytogenetic and molecular genetic changes confirm the diagnosis, provide further information about the histological type and progression of the disease. In hereditary cases, the members of the family at risk can be identified by recognizing the possibly associating clinical symptoms and/or by detecting the constitutional mutation of the gene using molecular genetic methods. Consequently, the genetic study of renal tumors plays important role not only in diagnosis and choosing adequate therapy but also in prevention of the disease.

Frasier syndrome with childhood-onset renal failure.

BACKGROUND: The Wilms' tumour 1 (WT1) gene encodes a protein which is believed to exert transcriptional and tumour-suppressor activities. Mutations of this gene have occasionally been associated with Wilms' tumour (<15% of cases) and, more consistently, with three syndromes characterized by urogenital abnormalities (WAGR, Denys-Drash and Frasier syndrome). SUBJECT/METHOD: A 25-year-old phenotypic female with a 46,XY karyotype presented with amenorrhoea. An ultrasound scan showed streak gonads and a rudimentary uterus. The patient had a history of post-streptococcal glomerulonephrosis, when aged 4 years, which had rapidly progressed to kidney failure, requiring transplantation at age 8. RESULT: Frasier syndrome was suspected and confirmed by genetic analysis. In fact, direct sequencing of the PCR product of the intron 9 donor splice site revealed a substitution of guanine for adenine in position +5. CONCLUSION: Besides being one of the few Frasier syndrome cases to be genetically characterized, this case is interesting because of the unusually early-onset renal failure.

Ancient and recent duplications of the rainbow trout Wilms' tumor gene.

The Wilms' tumor suppressor (WT1) gene plays an important role in the development and functioning of the genitourinary system, and mutations in this gene are associated with nephroblastoma formation in humans. Rainbow trout (Oncorhynchus mykiss) is one of the rare animal models that readily form nephroblastomas, yet trout express three distinct WT1 genes, one of which is duplicated and inherited tetrasomically. Sequence analyses suggest an ancient gene duplication in the common ancestor of bony fishes resulted in the formation of two WT1 gene families, that conserve the splicing variations of tetrapod WT1, and a second duplication event occurred in the trout lineage. The WT1 genes of one family map to linkage groups 6 and 27 in the trout genome map. Reverse transcribed polymerase chain reaction (RT-PCR) expression analysis demonstrated little difference in W

Association of partial gonadal dysgenesis, nephropathy and WT1 gene mutation without Wilms' tumor: incomplete Denys-Drash syndrome.

The concurrence of ambiguous genitalia, nephropathy and predisposition to Wilms' tumor are characteristics of Denys-Drash syndrome. Some of the reported patients do not express the full spectrum of the syndrome, while the occurrence of nephropathy has become a generally accepted common feature of this syndrome. We report an infant with male pseudohermaphroditism due to partial gonadal dysgenesis and nephropathy without Wilms' tumor but with a Wilms' tumor suppressor gene (WT1) mutation. The high risk of Wilms' tumor mandates regular surveillance and the use of prophylactic bilateral nephrectomy as a treatment is not yet clear.

Contribution of individual amino acids to the nucleic acid binding activities of the Xenopus zinc finger proteins TFIIIIA and p43.

Xenopus transcription factor IIIIA (TFIIIA) binds to both 5S RNA and the 5S RNA gene in immature oocytes, an interaction mediated by nine zinc fingers. To determine the role of the central zinc fingers of the protein in these nucleic acid binding activities, a series of substitution mutants of TFIIIA were constructed and expressed as recombinant proteins in Escherichia coli. The mutant proteins were purified to homogeneity and analyzed for DNA and RNA binding activities using a nitrocellulose filter binding assay. Finger 5, but not finger 4, 6, or 7, is involved in sequence-specific binding to the 5S RNA gene. A TWT amino acid motif in finger 6 makes a significant contribution to the binding of TFIIIA to 5S RNA, while mutations in fingers 4, 5, and 7 have little or no effect on RNA binding by TFIIIA. In striking contrast, a TWT motif in finger 6 of p43, another Xenopus zinc finger protein that binds to 5S RNA, is not necessary for 5S RNA binding by this protein. Evidence for the presence of inhibitory finger-finger interactions that limit the nucleic acid binding properties of individual zinc fingers within TFIIIA and p43 is discussed.

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.

Case report: Teenage girl with proteinuria and amenorrhea.

Recent research has advanced the understanding of many diseases to a molecular level. Described here is the case of a teenage girl with proteinuria and primary amenorrhea. We present the current knowledge of her underlying disorder, Frasier syndrome, and its genetic basis, which are specific mutations in the Wilms tumor gene. The findings in Frasier syndrome research are contrasted with those of a related disorder, Denys-Drash syndrome, which is caused by different mutations in the same gene.

Germline Wilms tumor suppressor gene (WT1) mutation leading to isolated genital malformation without Wilms tumor or nephropathy.

Mutations of the Wilms tumor suppressor gene (WT1 ) have been described only in patients with syndromes associated with urogenital malformation and Wilms tumor or nephropathy. We present a male patient with an isolated genital malformation caused by a WT1 mutation.

Isolated diffuse mesangial sclerosis and Wilms tumor suppressor gene.

Diffuse mesangial sclerosis is a rare renal disease, occurring either in isolation or as part of Denys-Drash syndrome. Denys-Drash syndrome originates from mutations of the Wilms tumor suppressor gene (WT1 ). We describe the presence of WT1 mutations in 7 Japanese children with isolated diffuse mesangial sclerosis.

Wilms' tumor suppressor gene (WT1) is expressed in primary breast tumors despite tumor-specific promoter methylation.

We analyzed Wilms' tumor suppressor 1 (WT1) expression and its regulation by promoter methylation in a panel of normal breast epithelial samples and primary carcinomas. Contrary to previous reports, WT1 protein was strongly expressed in primary carcinomas (27 of 31 tumors) but not in normal breast epithelium (1 of 20 samples). Additionally, the WT1 promoter was methylated in 6 of 19 (32%) primary tumors, which nevertheless expressed WT1. The promoter is not methylated in normal epithelium. Thus, although tumor-specific methylation of WT1 is established in primary breast cancer at a low frequency, other transcriptional regulatory mechanisms appear to supercede its effects in these tumors. Our results demonstrate expression of WT1 in mammary neoplasia, and that WT1 may not have a tumor suppressor role in breast cancer.

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.

Wilms' tumor suppressor gene WT1: from structure to renal pathophysiologic features.

Normal development of the kidney is a highly complex process that requires precise orchestration of proliferation, differentiation, and apoptosis. In the past few years, a number of genes that regulate these processes, and hence play pivotal roles in kidney development, have been identified. The Wilms' tumor suppressor gene WT1 has been shown to be one of these essential regulators of kidney development, and mutations in this gene result in the formation of tumors and developmental abnormalities such as the Denys-Drash and Frasier syndromes. A fascinating aspect of the WT1 gene is the multitude of isoforms produced from its genomic locus. In this review, our current understanding of the structural features of WT1, how they modulate the transcriptional and post-transcriptional activities of the protein, and how mutations affecting individual isoforms can lead to diseased kidneys is summarized. In addition, results from transgenic experiments, which have yielded important findings regarding the function of WT1 in vivo, are discussed. Finally, data on the unusual feature of RNA editing of WT1 transcripts are presented, and the relevance of RNA editing for the normal functioning of the WT1 protein in the kidney is discussed.

Detection of a novel truncated WT1 transcript in human neoplasia.

BACKGROUND: The Wilms' tumor 1 (WT1) gene encodes a transcription factor critical in urogenital development. Using a new model of prostate cancer progression that permits comparison of the cellular and molecular properties of increasingly aggressive sublines of simian virus 40 large T-antigen-immortalized human prostate epithelial cells within the same lineage, the role of WT1 in tumorigenesis was investigated. METHODS AND RESULTS: Using RT-PCR and northern blotting, we identified a novel truncated WT1 transcript in these prostate cancer cell lines. This 2.1-kb transcript consisted of the coding region of the zinc-finger domain of WT1, together with a portion of intron 5 at the 5' end of the transcript. Furthermore, two peptides were detected by western blotting using antibodies to epitopes of the COOH terminus of WT1. Using RT-PCR, the 2.1-kb transcript was also detected in leukemia cell line K562, breast cancer cell line MCF7, and blood samples from patients with acute leukemia. CONCLUSION: These novel findings in both cell lines and patient-derived specimens suggest this new WT1 gene alteration has a potential role in the development of new diagnostic assays for some human malignancies.

Principles of Wilms' tumor biology.

The last few years have provided dramatic breakthroughs in understanding the genetic factors involved in Wilms' tumorigenesis and normal kidney development. The implications of these findings for the clinical management of children with Wilms' tumor are only now becoming apparent. Over 80% of patients with Wilms' tumor can be cured using contemporary multimodality therapy. As a consequence, the current NWTSG is attempting to intensify treatment for patients with poor prognostic features while decreasing therapy, and thereby adverse late effects, for patients with favorable prognosticators.

Molecular heterogeneity and function of EWS-WT1 fusion transcripts in desmoplastic small round cell tumors.

Desmoplastic small round cell tumor (DSRCT) is a primitive sarcoma with a consistent cytogenetic abnormality, t(11;22)(p13;q12). This chromosomal translocation generates a chimeric transcript that is formed by fusion of the 5' region of the Ewing's sarcoma gene, EWS, with the 3' DNA-binding segment of WT1, the Wilms' tumor suppressor gene. We collected 14 DSRCT tumor samples and examined the hybrid transcripts. We identified: (a) combinatorial heterogeneity of EWS exons fused to WT1 including use of EWS exons 7, 8, and 9; (b) subpopulations of variant transcripts in 6 of 14 tumors characterized by aberrant splicing resulting in loss of EWS exon 6 or WT1 exon 9; (c) multiple cDNA products with large internal deletions; and (d) insertion of small stretches of heterologous DNA at the fusion site or exon splice region in transcripts from two tumors. Most of the splice variants were in-frame, and in vitro translated fusion proteins with intact DNA-binding motifs formed complexes with a WT1 response element in gel mobility assays. Each of the chimeric proteins retains the ability to bind to the GC and TC elements of the early transcription factor EGR-1 as well as WT1 consensus sequences. We present evidence that various EWS-WT1 proteins up-regulated EGR-1 promoter activity and that this up-regulation is specifically dependent upon the absence of the exon 9 KTS domain of WT1. The molecular diversity and functionality exhibited by these fusion transcripts may have significant biological implications for their transactivating and tumorigenic potential.

Immunohistochemical expression of WT1 by desmoplastic small round cell tumor: a comparative study with other small round cell tumors.

Desmoplastic small round cell tumors (DSRCTs) present a reciprocal chromosomal translocation, t(11;22)(p13;q12), that results in fusion of Ewing's sarcoma and Wilms' tumor (WT1) genes. The authors evaluated 15 DSRCTs and 71 other tumors often considered in the differential diagnosis for immunoreactivity using a polyclonal antibody directed against the WT1 part of the chimeric protein resulting from this translocation. WT1 immunostaining was performed on paraffin material using the WT(C-19) antibody after heat-antigen retrieval. All the DSRCTs (15 of 15, 100%) demonstrated strong WT1 nuclear immunoreactivity. Ten of 14 nephroblastomas (71%) disclosed WT1-positive nuclei in accordance with the staining reported by others, and rare and focal nuclear positivity was detected in two of 17 rhabdomyosarcomas. WT1 immunoreactivity was not observed in Ewing's sarcoma/primitive neuroectodermal tumors (zero of 21, 0%), neuroblastomas (zero of 17, 0%), or rhabdoid tumors of the kidney (zero of two, 0%). In nephroblastoma, differential diagnosis with DSRCT was not difficult: Clinical and morphologic data are not similar for these two entities. The current study validates WT1 immunoreactivity as a useful marker to separate DSRCT from other small round cell tumors.

O enigma da determinaçäo gonadal: o que existe além do cromossomo Y? / The enign of gonadal determination: there are Beyond Y chromosome?

Os autores revisam os vários fatores envolvidos no complexo processo de determinação gonadal, passando pelo já clássico SRY (fator de determinação testicular, no braço curto do cromossomo Y) e ressaltando os principais genes candidatos a participarem desta verdadeira "cascata" de determinação gonadal. Os genes candidatos se avolumam e têm mostrado os vários caminhos por que passa o processo-chave da diferenciação sexual, qual seja, a diferenciação de um testículo ou de um ovário. Genes localizados upstream em relação ao SRY (WT1, SF-1, DAX-1 e SOX9), suas interdependências e a ativação de promotores de outros genes, como o promotor do gene do hormônio anti-mülleriano são abordados neste artigo. Apesar de a lista de genes candidatos ter crescido, ainda restam muitas interrogações e ainda resta muito trabalho a ser desenvolvido para que se esclareça com maior precisão este passo crucial no mecanismo de diferenciação sexual.

Alternative splicing of Wilms' tumor suppressor protein modulates DNA binding activity through isoform-specific DNA-induced conformational changes.

The Wilms' tumor suppressor protein (WT1) is a zinc finger transcription factor that appears to function differently according to the presence of a posttranscriptional modification that adds three amino acids into one of the linker regions between the zinc fingers. We have investigated the structural consequences of the insertion of the Lys-Thr-Ser (KTS) sequence by preparing recombinant protein constructs of the four zinc finger DNA-binding domain of WT1 corresponding to the two isoforms with (+KTS) and without (-KTS) the insertion, which is located in the linker region between the third and fourth zinc fingers. NMR resonance assignments were used to estimate the structural differences between the two isoforms both free in solution and in complex with a 14 base pair DNA duplex corresponding to the WT1 recognition element. The NMR spectra indicate that the two isoforms are nearly identical in structure in the absence of the DNA. Only the immediate region of the insertion showed any change in chemical shifts. Upon DNA binding, the NMR spectrum of each isoform changed to indicate greater structure formation in the linker regions. Significant differences were observed between the spectra of the DNA complexes of the +KTS and -KTS isoforms, with the -KTS construct forming a more stable complex, consistent with prior biochemical assays. The majority of the differences between the spectra of the two complexes occur in the immediate region of the insertion, which appears to be closer in structure to the free form of the protein in the case of the +KTS complex. The insertion of the KTS sequence disrupts important interactions of the linker region with the adjacent zinc fingers, thus lowering the stability of the complex. The "normal" (-KTS) sequence of the linker appears to be involved in a C-terminal helix-capping interaction with the helix of the preceding zinc finger, a stabilizing interaction which is abrogated in the +KTS isoform.