Nephropathy and defective spermatogenesis in mice transgenic for a single isoform of the Wilms' tumour suppressor protein, WT1-KTS, together with one disrupted Wt1 allele

The Wilms' tumour suppressor protein, WT1, is a zinc finger protein essential for the development of several organs, including the kidney and gonads. In each of these tissues WT1 is required at multiple stages of development and its persistent expression in podocytes and Sertoli cells suggests WT1 may also have a role in the maintenance of kidney and testis function throughout adult life. Naturally occurring isoforms of WT1 are generated by alternative mRNA splicing. An altered ratio of the splice isoforms WT1-KTS and WT1 + KTS appears to be sufficient to account for the developmental abnormalities (pseudohermaphroditism and nephropathy) characteristic of Frasier syndrome. We show that mice with a transgene encoding WT1-KTS do not differ from their wild-type littermates unless they are also heterozygous for a null mutation at the endogenous Wt1 locus. Animals with both genetic modifications develop proteinuria, together with multiple glomerular cysts, and male infertility. These pathologic changes may be explained as a consequence of altering the WT1 isoform ratio in tissues that express WT1 during adulthood. The results suggest WT1 misexpression could contribute to human glomerulocystic kidney disease.     

Soluble expression and purification of tumor suppressor WT1 and its zinc finger domain

Full length murine WT1 and its zinc finger domain were separately inserted into Escherichia coli expression vectors with various fusion tags on either terminus by Gateway technology (Invitrogen) and expression of soluble protein was assessed. Fusion proteins including the four zinc finger domains of WT1 were used to optimize expression and purification conditions and to characterize WT1:DNA interactions in the absence of WT1:WT1 interactions. Zinc finger protein for in vitro characterization was prepared by IMAC purification of WT1 residues 321-443 with a thioredoxin-hexahistidine N-terminal fusion, followed by 3C protease cleavage to liberate the zinc fingers and cation exchange chromatography to isolate the zinc fingers and reduce the level of the truncated forms. Titration of zinc finger domain with a binding site from the PDGFA promoter gave a K(d) of 100±30nM for the -KTS isoform and 130±40nM for the +KTS isoform. The zinc finger domain was also co-crystallized with a double-stranded DNA oligonucleotide, yielding crystals that diffract to 5.5?. Using protocols established for the zinc finger domain, we expressed soluble full-length WT1 with an N-terminal thioredoxin domain and purified the fusion protein by IMAC. In electro-mobility shift assays, purified full-length WT1 bound double-stranded oligonucleotides containing known WT1 binding sites, but not control oligonucleotides. Two molecules of WT1 bind an oligonucleotide presenting the full PDGFA promoter, demonstrating that active full-length WT1 can be produced in E. coli and used to investigate WT1 dimerization in complex with DNA in vitro.     

Physical and functional interaction between the HCMV IE2 protein and the Wilms' tumor suppressor WT1

Human cytomegalovirus (HCMV) is a major renal pathogen in congenitally infected infants and renal allograft recipients. It has been shown that human kidney cells of glomerular, tubular, and vascular origin were all infected by HCMV in vitro. It has previously been demonstrated that the IE2 protein of HCMV directly associates with the zinc finger domain of Egr-1. The zinc finger region of WT1 is a sequence-specific DNA-binding domain which also recognizes the consensus DNA binding site (5'-CGCCCCCGC-3') of Egr-1, thus suggesting a possible interaction between WT1 and IE2. Here we demonstrate that HCMV IE2 binds to the C-terminal region of WT1 containing zinc finger domain in vivo as well as in vitro and that WT1 can inhibit IE2-driven transactivation of the responsive promoter. Our results suggest that WT1 may be able to regulate the functional activity of HCMV IE2. Furthermore, these data may provide new insights into the possible involvement of HCMV in WT1-related pathogeneses.     

Characterization of RNA aptamer binding by the Wilms' tumor suppressor protein WT1

The interaction of the zinc finger protein WT1 with RNA aptamers has been investigated using a quantitative binding assay, and the results have been compared to those from a previous study of the DNA binding properties of this protein. A recombinant peptide containing the four zinc fingers of WT1 (WT1-ZFP) binds to representatives of three specific families of RNA aptamers with apparent dissociation constants ranging from 13.8 +/- 1.1 to 87.4 +/- 10.4 nM, somewhat higher than the dissociation constant of 4.12 +/- 0.4 nM for binding to DNA. An isoform that contains an insertion of three amino acids between the third and fourth zinc fingers (WT1[+KTS]-ZFP) also binds to these RNAs with slightly reduced affinity (the apparent dissociation constants ranging from 22.8 to 69.8 nM) but does not bind to DNA. The equilibrium binding of WT1-ZFP to the highest-affinity RNA molecule was compared to the equilibrium binding to a consensus DNA molecule as a function of temperature, pH, monovalent salt concentration, and divalent salt concentration. The interaction of WT1-ZFP with both nucleic acids is an entropy-driven process. Binding of WT1-ZFP to RNA has a pH optimum that is narrower than that observed for binding to DNA. Binding of WT1-ZFP to DNA is optimal at 5 mM MgCl(2), while the highest affinity for RNA was observed in the absence of MgCl(2). Binding of WT1 to both nucleic acid ligands is sensitive to increasing monovalent salt concentration, with a greater effect observed for DNA than for RNA. Point mutations in the zinc fingers associated with Denys-Drash syndrome have dramatically different effects on the interaction of WT1-ZFP with DNA, but a consistent and modest effect on the interaction with RNA. The role of RNA sequence and secondary structure in the binding of WT1-ZFP was probed by site-directed mutagenesis. Results indicate that a hairpin loop is a critical structural feature required for protein binding, and that some consensus nucleotides can be substituted provided proper base pairing of the stem of the hairpin loop is maintained.