WT1-mediated growth suppression of Wilms tumor cells expressing a WT1 splicing variant

Molecular cloning, expression and purification of truncated midkine and its growth stimulatory activity on Wilms' tumor (G401) cells

Midkine (MK) is a heparin binding growth factor identified as a product of a retinoic acid-responsive gene; it is frequently expressed at high levels in many human carcinomas. Although the expression of the mRNA encoding truncated MK (tMK) in unique human cancer cells has been reported, the tMK polypeptide itself has not yet been identified. In order to clarify the biological role of tMK, recombinant tMK was expressed in Escherichia coli and purified. Recombinant tMK was purified as a single band in SDS-PAGE under reducing conditions showing an apparent molecular mass of 10 kDa. Purified recombinant tMK showed the same extent of proliferative activity towards Wilms' tumor (G401) cells as full length human MK. These results suggest that the structure of this recombinant tMK is same as the native polypeptide.

Detection of truncated midkine in Wilms' tumor by a monoclonal antibody against human recombinant truncated midkine

Although the expression of a truncated midkine (tMK) mRNA has been detected in many cancer cells, the tMK protein itself has not yet been identified. The expression, purification and characterization of human recombinant tMK were described in the former report. A mouse hybridoma cell line producing an IgG2b monoclonal antibody (mab) against purified recombinant tMK was established. This anti-tMK mab did not cross react with synthetic full length (or c-half) human midkine. A putative native tMK was identified in G401 cells using this mab, and showed the same apparent Mw as the recombinant tMK in SDS-PAGE. This mab was also used in an immunohistochemical study to evaluate the expression of tMK in Wilms' tumor cell line, G401 cells, as well as in Wilms' tumor patient specimens. G401 cells and all Wilms' tumor patient specimens immunoreacted with this anti-tMK mab. We conclude that Wilms' tumor cells express tMK and that this mab is useful for the detection of tMK in the Wilms' tumor.

Expression of c-met and WT-1

Protooncogenes and tumor-suppressor genes are two types of genes associated with cancer development.

E-cadherin is a WT1 target gene

The WT1 tumor suppressor gene encodes a transcription factor that can activate and repress gene expression. Transcriptional targets relevant for the growth suppression functions of WT1 are poorly understood. We found that mesenchymal NIH 3T3 fibroblasts stably expressing WT1 exhibit growth suppression and features of epithelial differentiation including up-regulation of E-cadherin mRNA. Acute expression of WT1 in NIH 3T3 fibroblasts after retroviral infection induced murine E-cadherin expression. In transient transfection experiments, the human and murine E-cadherin promoters were activated by co-expression of WT1. E-cadherin promoter activity was increased in cells overexpressing WT1 and was blocked by a dominant negative form of WT1. WT1 activated the murine E-cadherin promoter through a conserved GC-rich sequence similar to an EGR-1 binding site as well as through a CAAT box sequence. WT1 produced in vitro or derived from nuclear extracts bound to the WT1-response element within the murine E-cadherin promoter, but not the CAAT box. E-cadherin, a gene important in epithelial differentiation and neoplastic transformation, represents a downstream target gene that links the roles of the WT1 in differentiation and growth control.

The role of NF-kappaB in the regulation of the expression of wilms tumor suppressor gene WT1

The Wilms tumor suppressor gene, WT1, plays an important role in genitourinary development and the etiology of Wilms tumor. WT1 has a spatially and temporally defined expression in the developing genitourinary system and in specific cells of the hematopoietic system, but the regulatory pathways that control WT1 expression are not well understood. Recently, members of the NF-kappaB family of transcription factors have been proposed as potent activators of the murine WT1 promoter through binding to a NF-kappaB site. Because the human WT1 promoter contains a conserved NF-kappaB site, we investigated whether NF-kappaB also regulates the expression of the human WT1 gene. We activated NF-kappaB through cytokine stimulation or inhibited NF-kappaB through expression of a NF-kappaB "super repressor" in WT1 expressing Wilms tumor, renal carcinoma, and erythroleukemia cultures and examined the level of endogenous WT1 gene expression. Although a transfected NF-kappaB reporter construct was responsive to these manipulations, we found that altering NF-kappaB activity had no effect on endogenous WT1 expression in the cell types used in our study. We conclude that despite the presence of conserved NF-kappaB elements in the murine and human WT1 promoters, NF-kappaB is not required to regulate the expression of the WT1 gene in its natural context.

Stable overexpression of MEN1 suppresses tumorigenicity of RAS

Although there is indirect genetic evidence that MEN1, the gene for multiple endocrine neoplasia type 1, is a tumor suppressor gene, little is known about the MEN1-encoded protein, menin. Menin was stably overexpressed in a well-characterized murine tumor cell line, (valine-12)-RAS-transformed NIH3T3 cells. Menin overexpression reverted the morphology of the RAS-transformed NIH3T3 cells towards the more flattened and more spread, fibroblastic shape of wild type NIH3T3 cells. The proliferation rate of the RAS-transformed cells in 0.5% calf serum was also slower with menin overexpression. Menin overexpression reduced the RAS-induced clonogenicity in soft agar. Menin also reduced tumor growth after injection of cells in nude mice. In conclusion, stable overexpression of MEN1 suppressed partially the RAS-mediated tumor phenotype in vitro and in vivo. Overexpressed menin protein had biological effects, directly supporting MEN1 gene function as a tumor suppressor.

The Wilms tumor suppressor WT1 encodes a transcriptional activator of amphiregulin

WT1 encodes a zinc finger transcription factor implicated in kidney differentiation and tumorigenesis. In reporter assays, WT1 represses transcription from GC- and TC-rich promoters, but its physiological targets remain uncertain. We used hybridization to high-density oligonucleotide arrays to search for native genes whose expression is altered following inducible expression of WT1. The major target of WT1 was amphiregulin, a member of the epidermal growth factor family. The WT1(-KTS) isoform binds directly to the amphiregulin promoter, resulting in potent transcriptional activation. The in vivo expression profile of amphiregulin during fetal kidney development mirrors the highly specific pattern of WT1 itself, and recombinant Amphiregulin stimulates epithelial branching in organ cultures of embryonic mouse kidney. These observations suggest a model for WT1 as a transcriptional regulator during kidney differentiation.

Tumor-associated WT1 missense mutants indicate that transcriptional activation by WT1 is critical for growth control

The WT1 gene encodes a zinc finger DNA binding transcription factor and is mutated in up to 15% of Wilms tumor cases. The WT1 protein binds to the promoters of many genes through GC- or TC-rich sequences and can function both as a transcriptional repressor and an activator in co-transfection assays depending on the cell type, the structure of the test promoter, and even the expression vectors used. Engineered expression of WT1 can lead to growth suppression by both cell cycle arrest and induction of apoptosis. However, the transcriptional activity of WT1 that is required for growth control was not defined. We found that three N-terminal tumor-associated missense mutations of WT1 were defective for activation of both a synthetic reporter containing WT1-binding sites as well as the promoter of a WT1 responsive gene, p21. These mutants failed to inhibit cell growth but still retain their ability to repress several putative WT1 target promoters. These results indicate that activation and not repression by WT1 is the critical transcriptional activity of the protein responsible for its growth suppressing properties.

Advances in the molecular basis of renal neoplasia

The past 2 years have provided exciting progress in elucidating the molecular basis of renal cancer. Work on the von Hippel-Lindau tumor suppressor, pVHL, in clear-cell renal cancer is already suggesting new potential therapies, and should have important implications in the pathogenesis of renal cystic disease and tumor angiogenesis. In addition, study of the Wilms' tumor suppressor, WT1, is revealing much about the pathogenesis of Wilms' tumor, urogenital development, and glomerular podocyte biology. c-met, the gene encoding the hepatocyte growth factor receptor, has recently been identified as a causative gene for hereditary papillary renal cancer. This review will highlight these and other new molecular advances in the renal cancer field.

Prognostic significance of Bcl-2 in Wilms' tumor and oncogenic potential of Bcl-X(L) in rare tumor cases

Anaplastic Wilms' tumors are commonly believed to be rare forms of progression, driven by p53 mutations, of the more common classical Wilms' tumor or nephroblastoma Contrary to classical Wilms' tumors, anaplastic tumors traditionally tend to metastasize, to be drug-resistant and to have a poor prognosis. The Bcl-2 gene product protects cells from programmed cell death, and its over-expression has been proposed to be tumorigenic and to mediate resistance to therapy. Because Bcl-2 has been reported to be transcriptionally repressed by p53, using immuno-histochemistry and mRNA analyses, we have examined Bcl-2 expression in a panel of 10 classical and 3 anaplastic nephroblastomas in which the p53 status had been previously analyzed. We found that classical Wilms' tumors expressed significant amounts of Bcl-2 mRNA and protein, whereas anaplastic tumors did not, regardless of p53 mutations. However, because mortality occurred both among patients with classical and among those with anaplastic tumors, which had divergent Bcl-2 expression, analysis of variance failed to demonstrate prognostic Bcl-2 significance. Therefore, we examined the expression of the Bcl-X and Bax genes, which are known to synergize and antagonize Bcl-2, respectively. With the exception of anaplastic tumor W17, the monotony of Bcl-X and Bax mRNA levels did not suggest that the expression of these apoptosis-regulating genes could have a role in the prognosis of nephroblastoma. In addition to the standard 2.7-kb Bcl-X(L) mRNA, W17 expressed a 3.5-kb mRNA species which had the same coding capacity for Bcl-X(L) as the 2.7-kb mRNA. Western analysis demonstrated that W17 had the highest level of Bcl-X(L) protein, suggesting that Bcl-X(L) over-expression could play a part in the development of anaplasia in rare Wilms' tumor cases without affecting prognosis.

Overexpression of midkine in lung tumors induced by N-nitrosobis(2-hydroxypropyl)amine in rats and its increase with progression

The expression of midkine (MK) in lung tumors induced by N-nitrosobis(2-hydroxypropyl)amine (BHP) in rats was examined. The animals were administered 2000 p.p.m. of BHP in their drinking water for 12 weeks, then maintained without further treatment until being killed 20-28 weeks after the beginning of the experiment. MK mRNA expression of adenocarcinomas and squamous cell carcinomas assessed by means of the reverse transcriptase-polymerase chain reaction and northern blot analysis was significantly higher than in rat embryonic tissues (positive controls) and contrasted strongly with the lack in normal lungs. MK protein was detected immunohistochemically in 58.3% of alveolar hyperplasias, 92.3% of adenomas and 100% of adenocarcinomas and squamous cell carcinomas. The extent of staining significantly increased along with malignant progression in adenomatous (pre-)neoplastic lesions and tended to become more pronounced with malignant progression in squamous lesions. The results suggest that MK may play some essential roles in the development and progression of lung tumors induced by BHP in rats.

WT1: what has the last decade told us?

When positionally cloned in late 1989, it was anticipated that mutations within the Wilms' tumour suppressor gene (WT1) would prove responsible for this common solid kidney cancer of childhood. Characterisation of the WT1 expression pattern and of the structure of the encoded protein isoforms and their mode of action has now spanned almost a decade. WT1 proteins act as nucleic acid-binding zinc finger-containing transcription factors involved in both transactivation and repression. These activities are facilitated and constrained by interactions with other proteins. Expression analyses and knockout mice indicate that WT1 protein plays a critical role in normal kidney and gonad development. Specific constitutional WT1 mutations results in several urogenital anomaly syndromes. While only 10% of sporadic Wilms' tumours do display WT1 mutation, WT1 is mutated in other cancers, including acute myeloid leukaemia. Much is still to be determined in WT1 biology. The next decade will see at least three streams of attention. The first two, elucidation of the role of WT1 in RNA metabolism and the characterisation of further protein partners, may together explain the distinct tissue-specific functions of WT1. Finally, further research into the role of WT1 in haematopoiesis will improve our understanding of WT1 in leukaemia.

Ornithine decarboxylase is a transcriptional target of tumor suppressor WT1

The product of the Wilm's tumor suppressor gene, WT1, is a zinc-finger DNA-binding protein, which is thought to be a transcription factor. Two genes, those encoding epidermal growth factor receptor and syndecan-1, are known to be endogenous targets of WT1. Previous studies had identified binding sites for WT1 in the promoter of the ornithine decarboxylase (ODC) gene. In this paper, we tested whether the endogenous ODC gene might be a target of WT1 by establishing lines of baby hamster kidney (BHK) cells that expressed WT1 isoform A under control of a tetracycline-regulated expression system. When expression of WT1 was activated in BHK cells, the cellular level of ODC mRNA declined, with kinetics that correlated with the increase in WT1 level, demonstrating that the endogenous ODC gene was indeed responsive to cellular level of WT1. WT1 isoforms A and B inhibited the activity of the ODC promoter by approximately fivefold in transiently transfected BHK cells, while isoforms C and D, which have altered DNA binding domains, had no significant effect. The sequence CTCCCCCGC, located at nucleotides -106 to -98 relative to the site of transcriptional initiation in the ODC gene, interacted with the zinc-finger domain of isoforms A and B of WT1 with high affinity and specificity. A mutation in the binding site that disrupted this interaction partially removed the inhibition of ODC promoter activity by WT1, as did mutation of the two E-box sequences in intron I of the ODC gene. Simultaneous mutation of the WT1-binding motif and the two E-boxes completely abolished inhibition by WT1 of ODC promoter activity. These results, taken together, implicate the ODC gene as a downstream target of the tumor suppressor WT1.

Expression of von Hippel-Lindau protein in normal and pathological human tissues

To examine the localization of von Hippel-Lindau (VHL) protein in human tissues, we produced four novel monoclonal antibodies against human VHL protein. Western blot analysis revealed that two of these antibodies recognized the epitope in amino acid sequence 60-89 of the VHL protein and the others recognized sequences 54-60 and 189-213. In a wild-type VHL gene-transfected cell line, immunocytochemistry and immunoelectron microscopy demonstrated the intracytoplasmic localization of VHL protein, particularly in mitotic cells. In normal human tissues, VHL protein was detected immunohistochemically in epithelial cells covering the body surface and the alimentary, respiratory, and genitourinary tracts; in secretory epithelial cells of exocrine and endocrine organs; in parenchymal cells of visceral organs; in cardiomyocytes; in neurons in nervous tissue; in lymphocytes in lymphoid tissue; and in macrophages. In pathological specimens, VHL protein was expressed in VHL-related tumor, as well as in endothelial cells, fibroblasts, and pericytes, all of which are involved in active angiogenesis. These findings suggest that these monoclonal antibodies can be useful for various immunological assays and that the VHL protein plays fundamental roles in physiological and pathological situations, especially in neovascularization.

Expression of the Wilms' tumor gene WT1 in solid tumors and its involvement in tumor cell growth

To determine the role of the Wilms' tumor gene WT1 in tumorigenesis of solid tumors, expression of the WT1 gene was examined in 34 solid tumor cell lines (four gastric cancer cell lines, five colon cancer cell lines, 15 lung cancer cell lines, four breast cancer cell lines, one germ cell tumor cell line, two ovarian cancer cell lines, one uterine cancer cell line, one thyroid cancer cell line, and one hepatocellular carcinoma cell line) by means of quantitative reverse transcriptase-polymerase chain reaction. WT1 gene expression was detected in three of the four gastric cancer cell lines, all of the five colon cancer cell lines, 12 of the 15 lung cancer cell lines, two of the four breast cancer cell lines, the germ cell tumor cell line, the two ovarian cancer cell lines, the uterine cancer cell line, the thyroid cancer cell line, and the hepatocellular carcinoma cell line. Therefore, of the 34 solid tumor cell lines examined, 28 (82%) expressed WT1. Three cell lines expressing WT1 (gastric cancer cell line AZ-521, lung cancer cell line OS3, and ovarian cancer cell line TYK-nu) were further analyzed for mutations and/or deletions in the WT1 gene by means of single-strand conformation polymorphism analysis. However, no mutations or deletions were detected in the region of the WT1 gene ranging from the 3' end of exon 1 to exon 10 (the WT1 gene consists of 10 exons) in these three cell lines. Furthermore, when AZ-521, OS3, and TYK-nu cells were treated with WT1 antisense oligomers, the growth of these cells was significantly inhibited in association with a reduction in WT1 protein levels. Furthermore, constitute expression of the transfected WT1 gene in cancer cells inhibited the antisense effect of WT1 antisense oligomer on cell growth. These results indicated that the WT1 gene plays an essential role in the growth of solid tumors and performs an oncogenic rather than a tumor-suppressor gene function.

WT1 expression induces features of renal epithelial differentiation in mesenchymal fibroblasts

The WT1 tumor suppressor gene, implicated in hereditofamilial and sporadic Wilms' tumor, is required for normal renal development and is up-regulated during the mesenchymal-epithelial transition. NIH3T3 fibroblasts overexpressing WT1 were less proliferative, larger in size and more firmly attached to tissue culture plastic, suggesting an alteration of their state of differentiation. These cells were studied in vivo by subcutaneous injection into nude mice. The resulting tumors exhibited epithelioid histopathology and formed desmosome-like structures. Molecular analyses of these WT1 expressing fibroblasts grown in culture and in nude mice revealed significant alterations in the expression of many kidney epithelial markers. These studies indicate that WT1 expression can initiate features of a program of epithelial differentiation consistent with a prominent role for WT1 in the mesenchymal epithelial transition that occurs during renal development. Through this work we identified a number of novel target genes for the WT1 transcription factor, including uvomorulin, integrin alpha8 and perlecan, and suggest that WTI may activate the IGF-II gene, also implicated in the development of Wilms' tumor.

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.

Wilms tumor gene (WT1) as a new marker for the detection of minimal residual disease in leukemia

WT1 (Wilms tumor gene) expression is a new tumor marker of leukemic blast cells of AML, ALL, and CML. Minimal residual disease (MRD) of leukemia can be detected at frequencies as low as 1 in 10(3) to 10(4) normal bone marrow (BM) cells and 1 in 10(5) normal peripheral blood (PB) cells by means of the quantitation of expression levels of the WT1 gene using reverse transcriptase-polymerase chain reaction (RT-PCR). This is regardless of the types of leukemia or the presence or absence of tumor-specific DNA markers. Thus, the WT1 assay makes it possible to rapidly assess the effectiveness of treatment and to evaluate the degree of eradication of leukemic cells in individual leukemia patients. Moreover, molecular relapse using PCR can be diagnosed by the monitoring of WT1 expression levels in BM or PB 1-24 months (means, 7 months for BM and 8 months for PB) before the clinical relapse became apparent. In case of rapid or gradual increase in WT1 expression levels to or over 10(-2) after return to normal BM levels during CR; or retention of the WTI expression at levels near or over 10(-2) in BM without return to normal BM levels even in CR (WT1 expression level in K562 cells was defined as 1.0), it seems that clinical relapse is impending. Since WT1 antisense oligomers inhibit the growth of leukemic cells, it is apparent that the WT1 gene plays an important role in leukemogenesis.

No evidence of WT1 involvement in a Burkitt's lymphoma in a patient with Denys-Drash syndrome

BACKGROUND

We previously reported the case of a patient affected with Denys-Drash syndrome (DDS), who developed disseminated EBV-related Burkitt's lymphoma (BL) after kidney transplantation. Here, we describe the molecular characterisation of the WT1 gene in the constitutional and tumour DNA of this patient.

PATIENTS AND METHODS

WT1 exons 2 to 10 were sequenced in constitutional and tumour DNAs. By Southern blotting the latter was also investigated for the presence of gene rearrangements. Gene expression analysis in tumour cells was performed by reverse transcriptase-polymerase chain reaction (RT-PCR).

RESULTS

A germline missense mutation affecting one of the zinc finger domains of the gene, and previously reported in other DDS cases, was observed. No alterations of the constitutionally wild-type WT1 allele and no expression of the gene were observed in BL cells. A small group of BLs from other paediatric patients showed a variable expression of WT1.

CONCLUSIONS

Our findings indicate that WT1 is unlikely to be involved in the onset of BL in our case. However, a possible role of the gene in at least a subset of these lymphoproliferative diseases may be suggested.

Ciao 1 is a novel WD40 protein that interacts with the tumor suppressor protein WT1

The Wilms tumor suppressor protein, WT1, is a transcription factor capable of activating or repressing transcription of various cellular genes. The mechanisms involved in regulating the transcriptional activities of WT1 are beginning to be unraveled. It appears that physical interactions of other cellular proteins (p53 and par-4) with WT1 can modulate the function of WT1. Here, we report the identification and cloning of a novel WT1-interacting protein termed Ciao 1, a member of the WD40 family of proteins. Ciao 1 specifically interacts with WT1 both in vitro and in vivo. This interaction alters the mobility of a WT1.DNA complex in gel shift assays, and results in a decrease in transcriptional activation mediated by WT1. Ciao 1 does not inhibit binding of WT1 to its consensus nucleotide sequence and does not affect the repression activity of WT1. Thus, Ciao 1 appears to specifically modulate the transactivation activity of WT1 and may function to regulate the physiological functions of WT1 in cell growth and differentiation.

Tumor suppressor p53 can participate in transcriptional induction of the GADD45 promoter in the absence of direct DNA binding

The GADD45 gene is a growth arrest-associated gene that is induced by certain DNA-damaging agents and other stresses, such as starvation, in all mammalian cells. In addition to a strong p53-binding element in an intronic sequence, we have recently found that p53, while not required or sufficient alone, may contribute to the stress responsiveness of the promoter. Much of the responsiveness was localized to a GC-rich motif in the proximal promoter which contains multiple Egr1 sites and a larger WT1 site; this 20-bp WT1 motif is identical to the WT1-binding site in the PDGF-A gene. In extracts from a human breast carcinoma cell line expressing p53 and WT1, which is known to associate with p53 in vivo, evidence was obtained that these proteins are in a complex that binds this 20-bp element. A combination of p53 and WT1 expression vectors strongly induced a GADD45-reporter construct, while mutation of the WT1-Egr1 site in the promoter prevented this induction. Abrogation of p53 function by a dominant-negative vector or abrogation of WT1 function by an antisense vector markedly reduced the induction of this promoter. Since p53 does not bind directly to the promoter, these results indicate that p53 can contribute to the positive regulation of a promoter by protein-protein interactions.

Inhibition of cellular proliferation by the Wilms tumor suppressor WT1 requires association with the inducible chaperone Hsp70

The Wilms tumor suppressor WT1 encodes a zinc finger transcription factor that is expressed in glomerular podocytes during a narrow window in kidney development. By immunoprecipitation and protein microsequencing analysis, we have identified a major cellular protein associated with endogenous WT1 to be the inducible chaperone Hsp70. WT1 and Hsp70 are physically associated in embryonic rat kidney cells, in primary Wilms tumor specimens and in cultured cells with inducible expression of WT1. Colocalization of WT1 and Hsp70 is evident within podocytes of the developing kidney, and Hsp70 is recruited to the characteristic subnuclear clusters that contain WT1. The amino-terminal transactivation domain of WT1 is required for binding to Hsp70, and expression of that domain itself is sufficient to induce expression of Hsp70 through the heat shock element (HSE). Substitution of a heterologous Hsp70-binding domain derived from human DNAJ is sufficient to restore the functional properties of a WT1 protein with an amino-terminal deletion, an effect that is abrogated by a point mutation in DNAJ that reduces binding to Hsp70. These observations indicate that Hsp70 is an important cofactor for the function of WT1, and suggest a potential role for this chaperone during kidney differentiation.

The Wilms' tumor 1 gene: oncogene or tumor suppressor gene?

The Wilms' tumor 1 (wt1) gene is one of at least three genes that are involved in the development of Wilms' tumor, a pediatric kidney cancer. The expression pattern of the gene indicates that wt1 not only plays a role during kidney development but is also involved in the development and homeostasis of several other tissues. The physiological function of the gene, however, remains to be elucidated. The gene products have been implicated in many processes like proliferation, differentiation, and programmed cell death (apoptosis). The WT1 proteins function as transcription factors but may additionally be involved in splicing. Disruption of these activities may lead to aberrant development. In this paper we will discuss the role of the wt1 gene during normal development and homeostasis of several tissues. In addition, we will address the involvement of the gene products in processes like apoptosis and tumorigenesis.

Molecular cloning of human TAK1 and its mutational analysis in human lung cancer

In previous reports, we described that DPC4/Smad4 and Smad2 are mutated in a fraction of human lung cancers and suggested possible roles of the downstream mediators of transforming growth factor-beta (TGF-beta)-elicited signals in the pathogenesis of this most common cancer. In the present study, we investigated whether another downstream mediator, human TGF-beta-activated kinase 1 (hTAK1), also is altered in lung cancer. For this purpose, the hTAK1 gene was cloned with the aid of an expression sequence tag database search and cDNA library screening, and hTAK1 was found to be expressed ubiquitously in 2 distinct isoforms regulated in a tissue-specific manner in fetal and adult normal tissues. Interestingly, hTAK1 was assigned to the chromosome region 6q14-21, which is deleted frequently in various human malignancies, including lung cancer. Despite our extensive search for alterations in 39 lung cancer specimens as well as in 16 lung cancer cell lines, somatic mutations of hTAK1 were not identified, indicating that hTAK1 itself is not a frequent target for genetic alterations in lung cancer.

Consequences of chromosomal abnormalities in tumor development

This article highlights recent advances in the molecular structure and function of proteins that are activated or created by chromosomal abnormalities and discusses their possible role in tumor development. The molecular characterization of these proteins has revealed that tumor-specific fusion proteins are the consequence of most chromosome translocations associated with leukemias and solid tumors. An emerging common theme is that creation of these proteins disrupts the normal development of tumor-specific target cells by blocking apoptosis. These insights identify these chromosomal translocation-associated genes as potential targets for improved cancer therapies.

Loss of an estrogen receptor isoform (ER alpha delta 3) in breast cancer and the consequences of its reexpression: interference with estrogen-stimulated properties of malignant transformation

Comparison of mRNA ratios of a non-DNA-binding estrogen receptor (ER(alpha)) isoform, missing exon 3 (ER(alpha)delta3), to the full-length ER(alpha), in normal breast epithelium to that in primary breast cancers and breast cancer cell lines revealed a 30-fold reduction of this ratio in cancer cells (P < 0.0001). To test what functions may have been affected by the loss of ER(alpha)delta3, stable clones of MCF-7 cells expressing ectopic ER(alpha)delta3 protein, at the range of physiological ER(alpha), were generated. In vector-transfected controls the ER(alpha)delta3-mRNA and protein were less than 10% while in the ER(alpha)delta3-expressing clones, ER(alpha)delta3-mRNA and protein ranged from 36-76% of the total ER(alpha). Estrogen (E2) stimulated the expression of pS2-mRNA in pMV7 vector control cells, but the stimulation was reduced by up to 93% in ER(alpha)delta3-expressing clones. In addition, several properties associated with the transformed phenotype were also strongly affected when ER(alpha)delta3 protein was reexpressed. Compared with vector-transfected control cells, the saturation density of the ER(alpha)delta3-expressing clones was reduced by 50-68%, while their exponential growth rate was only slightly (14.5 +/- 5%) lower. The in vivo invasiveness of the ER(alpha)delta3-expressing cells was significantly reduced (P = 0.007) by up to 79%. E2 stimulated anchorage-independent growth of the pMV7 vector control cells, but reduced it to below baseline levels in ER(alpha)delta3 clones. The reduction of the pS2 response to E2 in the ER(alpha)delta3-expressing clones and the E2 block of anchorage-independent growth to below baseline were more pronounced than expected from the dominant negative function of ER(alpha)delta3. These observations suggest that E2 may activate an additional ER(alpha)delta3-dependent inhibitory pathway. The drastic reduction of ER(alpha)delta3 to ER(alpha) ratio in breast cancer, and the fact that when present in breast cancer cells this isoform leads to a suppression, rather than enhancement, of the transformed phenotype by E2 suggests that the regulation of ER(alpha)-mRNA splicing may need to be altered for the breast carcinogenesis to proceed.

The EWS-WT1 translocation product induces PDGFA in desmoplastic small round-cell tumour

Chromosomal translocations resulting in chimaeric transcription factors underlie specific malignancies, but few authentic target genes regulated by these fusion proteins have been identified. Desmoplastic small round-cell tumour (DSRT) is a multiphenotypic primitive tumour characterized by massive reactive fibrosis surrounding nests of tumour cells. The t(11;22)(p13;q12) chromosomal translocation that defines DSRT produces a chimaeric protein containing the potential transactivation domain of the Ewing-sarcoma protein (EWS) fused to zinc fingers 2-4 of the Wilms tumour suppressor and transcriptional repressor WT1 (refs 2,3). By analogy with other EWS fusion products, the EWS-WT1 chimaera may encode a transcriptional activator whose target genes overlap with those repressed by WT1 (ref. 4). To characterize its functional properties, we generated osteosarcoma cell lines with tightly regulated inducible expression of EWS-WT1. Expression of EWS-WT1 induced the expression of endogenous platelet-derived growth factor-A (PDGFA), a potent secreted mitogen and chemoattractant whose promoter contains the many potential WT1-binding sites. Native PDGFA was not regulated by wild-type WT1, indicating a difference in target gene specificity between this tumour suppressor and its oncogenic derivative. PDGFA was expressed within tumour cells in primary DSRT specimens, but it was absent in Wilms tumours expressing WT1 and Ewing sarcomas with an EWS-Fli translocation. We conclude that the oncogenic fusion of EWS to WT1 in DSRT results in the induction of PDGFA, a potent fibroblast growth factor that contributes to the characteristic reactive fibrosis associated with this unique tumour.

The Wilms tumour gene WT1 in leukaemia

The WT1 gene is essential for kidney development and is mutated in some Wilms tumours. It is also expressed at a high level in many acute leukaemias and in some haematopoietic progenitor cells, and mutations have been found in leukaemias. The function of WT1, which is a zinc finger protein and has domains characteristic of transcription factors, is not well understood. The level of expression is highest in leukaemias with immature phenotypes. Expression of WT1 is downregulated during differentiation of leukaemic cell lines and high levels of WT1 expression can cause cell cycle arrest and/or apoptosis. This may reflect a role in the control of normal haematopoiesis, which can be abrogated by mutations in the gene and form part of the pathway towards leukaemogenesis.

Differential splicing of exon 5 of the Wilms tumour (WTI) gene

The WTI gene encodes a developmentally regulated transcription factor whose function is altered by alternative splicing at two sites: the 17 amino acids of exon 5, whose functional effects are ill-defined, and the 3 amino acids (KTS) between exons 9 and 10, which determine sequence-specific DNA binding and nuclear localisation. Germline mutations, which prevent normal KTS splicing, can underlie the Denys-Drash syndrome, and disruptions of splicing of exon 5 may occur in Wilms tumours. We analysed by reverse transcriptase polymerase chain reaction (RT-PCR) amplification the relative ratios of the four splice variants of WTI mRNA in normal and tumour tissues and found tissue-specific, developmental stage-specific, and species-specific differences in the splicing of exon 5 but not of KTS. We found no evidence for disrupted splicing in acute leukaemias or gonadal tumours. The significance of these findings is discussed, and the possibility is raised that WTI may orchestrate the appropriate response to growth and differentiation factor signalling, mediated by alterations in the relative levels of exon 5 containing WTI isoforms.

Expression and function of the leucine zipper protein Par-4 in apoptosis

The prostate apoptosis response-4 (par-4) gene was identified by differential screening for genes that are upregulated when prostate cancer cells are induced to undergo apoptosis. The par-4 gene is induced by apoptotic signals but not by growth-arresting, necrotic, or growth-stimulatory signals. The deduced amino acid sequence of par-4 predicts a protein with a leucine zipper domain at its carboxy terminus. We have recently shown that the Par-4 protein binds, via its leucine zipper domain, to the zinc finger domain of Wilms' tumor protein WT1 (R. W. Johnstone et al., Mol. Cell. Biol. 16:6945-6956, 1996). In experiments aimed at determining the functional role of par-4 in apoptosis, an antisense par-4 oligomer abrogated par-4 expression and activator-driven apoptosis in rat prostate cancer cell line AT-3, suggesting that par-4 is required for apoptosis in these cells. Consistent with a functional role for par-4 in apoptosis, ectopic overexpression of par-4 in prostate cancer cell line PC-3 and melanoma cell line A375-C6 conferred supersensitivity to apoptotic stimuli. Transfection studies with deletion mutants of Par-4 revealed that full-length Par-4, but not mutants that lacked the leucine zipper domain of Par-4, conferred enhanced sensitivity to apoptotic stimuli. Most importantly, ectopic coexpression of the leucine zipper domain of Par-4 inhibited the ability of Par-4 to enhance apoptosis. Finally, ectopic expression of WT1 attenuated apoptosis, and coexpression of Par-4 but not a leucine zipperless mutant of Par-4 rescued the cells from the antiapoptotic effect of WT1. These findings suggest that the leucine zipper domain is required for the Par-4 protein to function in apoptosis.

Wilms tumor gene expression in acute myeloid leukemias

The Wilms' tumor gene product (WT-1) is suggested to act as a tumor suppressor in childhood malignancies of the kidney and as a transcription factor with regulating activity on a number of growth and differentiation factors. Wt-1 has been shown to be expressed in blast cells of the vast majority of patients with acute myeloid and lymphoblastic leukemias (AL) by a number of workers. High levels of wt-1 mRNA expression in blast cells of newly diagnosed AML patients predict worse prognosis when compared to patients with no or low wt-1 mRNA expression. Patients achieving complete responses after chemotherapy usually lose detectable signals of wt-1. In relapse of the disease reoccurrence of wt-1 mRNA can be determined in almost all patients with initially detectable wt-1 mRNA. Using sensitive techniques such as reverse transcription polymerase chain reaction (RT-PCR) relapses are preceded by wt-1 expression in some cases. Although a subpopulation of normal hematopoietic precursor cells has also been shown to express message for wt-1, detectable levels of wt-1 during follow-ups in AML patients have been shown to be useful as a marker for residual blast populations or even to predict relapse of AML. Whether the high level of wt- expression is a non-specific phenomenon resulting from malignant transformation or whether it has an impact on the pathophysiology of AML or the uncontrolled growth of AML blasts is still controversial. However, there are indicators for an involvement of wt-1 in malignant events of AML blasts such as the downregulation of wt-1 in chemically induced differentiation of AML blast cell lines or the interactions of wt-1 with the protooncogene bcl-2 and the tumor suppressor gene p53. In conclusion, its possible relevance as an AML marker and its role in pathophysiological mechanisms in AML will still have to be defined in the future.

Dominant-negative mutations of the Wilms' tumour predisposing gene (WT1) are infrequent in CML blast crisis and de novo acute leukaemia

To determine if mutations of the Wilms' tumor predisposing gene (WT1) are associated with haematological malignancies, we have investigated 65 cases of acute leukaemia, including 39 patients in blast crisis of chronic myeloid leukaemia (CML), by amplification of WT1 exons 7, 8 and 9 followed by single-strand conformation polymorphism analysis. WT1 transcripts were detected by RT-PCR in all samples. An exon 7 silent polymorphism (A-->G; Arg 313) was identified in 17 individuals, 5 of whom were homozygous, but no other lesions were found. In 1 sample from a patient with acute lymphoblastic leukaemia a smaller size transcript missing exon 9 was detected; a similar abnormality has been described previously in a patient with Wilms' tumour and the resultant protein shown to act in a dominant-negative manner. No mutations of the exon 9 donor or acceptor splice sites were found in this patient and the basis of the abnormal transcript remains obscure. We conclude that dominant-negative mutations of the zinc finger region of the WT1 gene are uncommon in CML blast crisis. Abnormalities of this gene may, however, contribute to a small proportion of cases of de novo acute leukaemia.

Midkine expression in human breast cancers: expression of truncated form

The expression of midkine (MK), a growth/differentiation factor, was assessed in 34 surgically resected specimens of primary breast cancer or mastopathy. Using reverse transcriptase-polymerase chain reaction (RT-PCR) analysis, all of the non-cancerous and cancerous tissues were found to express MK except for one breast cancer specimen. Northern blot analysis revealed that MK mRNA was also expressed in the normal breast tissues examined. Immunohistochemical analysis of the MK protein was performed on a limited number of the specimens, showing that some cancerous tissues were immunoreactive with anti-MK antibodies. Furthermore, using RT-PCR analysis, expression of not only the wild-type but also a truncated form of MK, which was recently found in various human tumor cell lines, was detected in 6 of 26 cancerous tissues but not in non-cancerous tissues.

Sp1 is a critical regulator of the Wilms' tumor-1 gene

We performed deletion analysis of WT1-reporter constructs containing up to 24 kilobases of 5'-flanking and first intron WT1 sequence in stably transfected cultured cells as an unbiased approach to identify cis elements critical for WT1 transcription. Although not a tissue-specific element, a proximate 9-base pair CTC repeat accounted for approximately 80% of WT1 transcription in this assay. Enhancer activity of the element and mutated versions correlated completely with their ability to form a DNA-protein complex in gel shifts. Antibody supershift, oligonucleotide competition, and Southwestern studies indicated that the CTC-binding factor is the transcriptional activator Sp1. Sp1 binds the CTC repeat with an affinity, KD = 0.37 nM, at least as high as the consensus GC box. Similar CTC repeats are found in promoters of other growth-related genes. Because Sp1 is important for WT1 expression, we examined Sp1 immunohistochemistry in fetal and adult kidney. In a pattern that precedes that of WT1 message, Sp1 immunostaining was highest in uninduced mesenchyme, early tubules, developing podocytes, and mature glomeruli, but was minimal in mature proximal tubules. This work suggests abundant Sp1 may be a prerequisite for WT1 expression, and that Sp1 may have a wider role in nephrogenesis.

Regulation of dopamine-1A (D1A) receptor gene transcription

The D1A receptor is expressed primarily in the brain and kidney. The D1A receptor gene has been cloned from human, rat and pig and is organized similarly in each species. The 5' flanking region of the D1A receptor gene is high in GC content, is TATA box-less and contains multiple Sp1 binding sites. Comparison and alignment of the nucleotide sequences within the 5' flanking and 5' untranslated regions of each gene indicates that the highest sequence identity is in the area centered approximately 100 bases upstream from the transcription start site. There are numerous binding sites for transcription factors, including Sp1 and AP-2, in the 5' flanking region. Approximately 200 bases upstream is a conserved cAMP regulatory element-like sequence. The conserved position of certain cis-acting elements in each gene suggests that the essential elements for regulated expression of the D1A receptor gene are contained within the first 300 bases of the 5' flanking region.

A novel repressor, par-4, modulates transcription and growth suppression functions of the Wilms' tumor suppressor WT1

The tumor suppressor WT1 represses and activates transcription. The loss and/or imbalance of the dual transcriptional activity of WT1 may contribute to Wilms' tumor. In this study, we identified par-4 (for prostate apoptosis response) as a WT1-interacting protein that itself functions as a transcriptional repressor. par-4 contains a putative leucine zipper domain and is specifically upregulated during apoptosis of prostate cells (S. F. Sells, D. P. Wood, Jr., S. S. Joshi-Barve, S. Muthukkumar, R. J. Jacob, S. A. Crist, S. Humphreys, and V. M. Rangnekar, Cell Growth Differ. 5:457-466, 1994). The leucine repeat domain of par-4 was shown to interact with the zinc finger DNA binding domain of WT1. Immunoprecipitation-Western blot (immunoblot) analyses demonstrated in vivo WT1-par-4 interactions. par-4 was ubiquitously expressed, and the protein was found in both the nucleus and the cytoplasm. Functionally, par-4 inhibited transcription activated by WT1, but not by the related protein EGR1. Inhibition of WT1-mediated transcription was dependent on the domain of par-4 that mediates its physical association with WT1. In addition, par-4 augmented WT1-mediated repression, possibly by contributing an additional repression domain. Consistent with these results, par-4 functioned as a transcriptional repressor when brought to a promoter via a heterologous DNA binding domain. Significantly, par-4, but not a mutant unable to interact with WT1, rescued growth suppression caused by WT1. Thus, we identified a novel repressor that modulates transcription as well as growth suppression functions of WT1.

Functional properties of WT1

WT1 encodes a zinc finger transcription factor that is inactivated in a subset of Wilms' tumors. We have recently shown that introduction of wild-type WT1 into a Wilms' tumor-derived cell line, RM1, results in growth suppression, consistent with its function as a tumor suppressor gene. WT1-mediated growth suppression was also observed in other cells derived from embryonal tumors, including two osteosarcoma cell lines, U2OS and Saos-2, notable for the respective presence or absence of wild-type p53. To further characterize the functional properties of WT1, multiple U2OS and Saos-2 cell lines were established, expressing either wild-type WT1 splicing variants or naturally occurring mutants under control of a tightly regulated tetracycline repressable promoter. Induction of WT1 in these cells resulted in programmed cell death. This effect was preferentially mediated by WT1 isoform B (encoding alternative splice I, lacking alternative splice II "KTS"), and it was independent of p53, occurring in both U2OS and Saos-2 cells. WT1-mediated apoptosis was associated with transcriptional repression of the epidermal growth factor receptor (EGFR) and reduced synthesis of endogenous EGFR protein synthesis. Constitutive expression of EGFR abrogated WT1-mediated cell death. We conclude that wild-type WT1 can induce apoptosis in embryonal cancer cells, presumably through the withdrawal of required growth factor survival signals, and that EGFR is a physiological target gene for WT1.

cDNA cloning and its pronephros-specific expression of the Wilms' tumor suppressor gene, WT1, from Xenopus laevis

The Wilms' tumor suppressor gene, WT1, plays a crucial role during early urogenital development in mammals. To elucidate the function of WT1 in other vertebrates, we isolated the Xenopus WT1 homolog (XeWT1) from a testis cDNA library. Comparison of the XeWT1 protein with other WT1 proteins revealed that the zinc finger domain of XeWT1 is identical to that of the human WT1 except for the first two amino acid residues. An alternative splice II site, located between the third and the fourth zinc finger is also conserved. In the transcriptional regulatory region, however, three domains, a glycine stretch, a proline stretch and one alternative splice site which are present in the mammalian WT1, are not conserved in amphibians. The XeWT1 gene is expressed in testis and kidney, and whole mount in situ hybridization revealed that the onset of the WT1 gene expression coincides with the early stages of pronephros development in Xenopus. These findings implicate the involvement of WT1 protein during urogenital development in amphibians as well as in mammals.

Regulation of insulin-like growth factor I receptor gene expression by the Wilms' tumor suppressor WT1

THe insulin-like growth factor I receptor (IGF-I-R) has been implicated in the etiology and/or progression of Wilms' tumor, or nephroblastoma, a pediatric neoplasm of the kidney that is often associated with deletion or mutation of the WT1 tumor suppressor gene. The levels of IGF-I-R mRNA in the tumors were sixfold higher than in normal adjacent kidney tissue and were inversely correlated to the levels of WT1 mRNA, suggesting that the expression of the IGF-I-R gene is under inhibitory control by WT1. Cotransfection of an IGF-I-R promoter-luciferase reporter construct together with a WT1 expression vector resulted in a dose-dependent suppression of promoter activity. Multiple WT1 binding sites were mapped in the 5'-flanking and 5'-untranslated regions of the IGF-I-R gene using gel retardation and DNaseI footprinting assays. Thus, suppression of the IGF-I-R promoter by WT1 involves multiple interactions of its zinc finger domain with sites located both upstream and downstream of the transcription initiation site. Finally, we showed that expression of the endogenous IGF-I-R gene is decreased in G401 cells stably transfected with a WT1 expression vector. Reduction in expression of the IGF-I-R gene is associated with a decrease in a number of IGF-I-mediated biological effects. Thus, deletion or mutation of the WT1 gene in Wilms' tumor and other malignancies can result in overexpression of the receptor, with enhanced autocrine/paracrine activation by locally produced or circulating IGFs.

MCC, a cytoplasmic protein that blocks cell cycle progression from the G0/G1 to S phase

The MCC gene was isolated from the human chromosome 5q21 by positional cloning and was found to be mutated in several colorectal tumors. In this study, we prepared specific antibodies and detected the MCC gene product as a cytoplasmic 100-kDa phosphoprotein in mouse NIH3T3 cells. Immunoelectron microscopic analysis showed that the MCC protein is associated with the plasma membrane and membrane organelles in mouse intestinal epithelial cells and neuronal cells. The amount of the MCC protein remained constant during the cell cycle progression of NIH3T3 cells, while its phosphorylation state changed markedly in a cell cycle-dependent manner, being weakly phosphorylated in the G0/G1 and highly phosphorylated during the G1 to S transition. Overexpression of the MCC protein blocked the serum-induced cell cycle transition from the G1 to S phase, whereas a mutant MCC, initially identified in a colorectal tumor, did not exhibit this activity. These results suggest that the MCC protein may play a role in the signaling pathway negatively regulating cell cycle progression.

A nude mouse Wilms' tumor line (KCMC-WT-1) derived from an aniridia patient with monoalleleic partial deletion of chromosome 11p

BACKGROUND

A candidate tumor suppressor gene, WT-1, is believed to have an important role in the pathogenesis of Wilms' tumor, especially that occurring in patients with congenital aniridia.

METHODS

To obtain a stable tumor line to work with, Wilms' tumor tissue was serially transplanted in athymic nude mice. Biopsied Wilms' tumor tissue, derived from an aniridia patient, was transplanted subcutaneously to an athymic nude mouse, and then transplanted serially. Histopathologic and molecular biologic studies were performed on the xenotransplants.

RESULTS

The aniridia patient showed partial deletion in one short arm of chromosome 11, which bears the WT-1 gene. The tumor was successfully transplanted in the nude mouse. Although the tumor contained blastemic, organoid, and stromal histologic elements, the organoid element began to decrease after more than 20 passages. Cytogenetic analysis revealed an additional abbreviation of one long arm of chromosome 6. Dot blot analysis showed that the copy number of WT-1 gene was decreased to half the amount in the tumor, in spite of the WT-1 transcript with normal size detected by Northern blotting.

CONCLUSIONS

The tumor is expected to bear one WT-1 gene with minute abnormalities as well as one congenitally deleted gene. This tumor line is useful when examining the effect caused by introduction of WT-1 gene to Wilms' tumor in vivo.

Localization of a tumor suppressor gene in 11p15.5 using the G401 Wilms' tumor assay

Multiple studies have underscored the importance of loss of tumor suppressor genes in the development of human cancer. To identify these genes, we used somatic cell hybrids in a functional assay for tumor suppression in vivo. A tumor suppressor gene in 11p15.5 was detected by transferring single human chromosomes into the G401 Wilms' tumor cell line. In order to better map this gene, we created a series of radiation-reduced t(X;11) chromosomes and characterized them at 24 loci between H-RAS and beta-globin. Interestingly, three of the chromosomes were indistinguishable as determined by genomic and cytogenetic analyses. Each contains an interstitial deletion with one breakpoint in 11p14.1 and the other breakpoint between the D11S601 and D11S648 loci in 11p15.5. PFGE analysis localized the 11p15.5 breakpoints to a 175 kb MluI fragment that hybridized to D11S601 and D11S648 probes. Genomic fragments from this 175 kb region were hybridized to DNA from mouse hybrid lines containing the delta t(X;11) chromosomes. This analysis detected the identical 11p15.5 breakpoint which disrupts a 7.8 kb EcoRI fragment in all three of the delta t(X;11) chromosomes, suggesting they are subclones of the same parent colony. Upon transfer into G401 cells, one of the chromosomes suppressed tumor formation in nude mice, while the other two chromosomes lacked this ability. Thus, our mapping data indicate that the gene in 11p15.5 which suppresses tumor formation in G401 cells must lie telomeric to the D11S601 locus. Koi et al. (Science 260: 361-364, 1993) have used a similar functional assay to localize a growth suppressor gene for the RD cell line centromeric to the D11S724 locus. The combination of functional studies by our lab and theirs significantly narrows the location of the tumor suppressor gene in 11p15.5 to the approximately 500 kb region between D11S601 and D11S724.

Translocations in solid tumours

Specific chromosomal translocations have now been identified in a variety of solid tumour types. Recent developments in this field include the identification of novel genes involved in the t(X;18) synovial sarcoma translocation and the discovery that the high-mobility group protein gene, HMGI-C, is involved in the chromosome 12 rearrangements found in lipomas and uterine leiomyomas. These discoveries may have important implications for the strategies used in tumour diagnosis and treatment.

Truncated WT1 mutants alter the subnuclear localization of the wild-type protein

WT1 encodes a zinc-finger protein, expressed as distinct isoforms, that is inactivated in a subset of Wilms tumors. Both constitutional and somatic mutations disrupting the DNA-binding domain of WT1 result in a potentially dominant-negative phenotype. In generating inducible cell lines expressing wild-type isoforms of WT1 and WT1 mutants, we observed dramatic differences in the subnuclear localization of the induced proteins. The WT1 isoform that binds with high affinity to a defined DNA target, WT1(-KTS), was diffusely localized throughout the nucleus. In contrast, expression of an alternative splicing variant with reduced DNA binding affinity, WT1 (+KTS), or WT1 mutants with a disrupted zinc-finger domain resulted in a speckled pattern of expression within the nucleus. Although similar in appearance, the localization of WT1 variants to subnuclear clusters was clearly distinct from that of the essential splicing factor SC35, suggesting that WT1 is not directly involved in pre-mRNA splicing. Localization to subnuclear clusters required the N terminus of WT1, and coexpression of a truncated WT1 mutant and wild-type WT1(-KTS) resulted in their physical association, the redistribution of WT1(-KTS) from a diffuse to a speckled pattern, and the inhibition of its transactivational activity. These observations suggest that different WT1 isoforms and WT1 mutants have distinct subnuclear compartments. Dominant-negative WT1 proteins physically associate with wild-type WT1 in vivo and may result in its sequestration within subnuclear structures.