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.

Origin of the glomerular vasculature in the developing kidney.

Mechanisms regulating the establishment of the glomerular endothelium and mesangium during glomerulogenesis are not understood. In this article, we discuss two different blood vessel growth processes: vasculogenesis and angiogenesis, with particular attention on how these processes might operate in the developing kidney. Results from metanephric organ cultures and interspecies grafts are also interpreted with an emphasis on generation of the renal microvasculature. Among the several growth factors identified in the metanephros, many (eg, fibroblast growth factor [FGF], vascular endothelial growth factor [VEGF], platelet-derived growth factor [PDGF], epidermal growth factor/transforming growth factor-alpha [EGF/TGF-alpha], hepatocyte growth factor/scatter factor [HGF/SF], and insulinlike growth factor [IGF]) have angiogenic properties, and these are discussed in relation to formation of the glomerulus. How extracellular matrices and proteases might be involved in vascularization are also considered.

Origins and formation of microvasculature in the developing kidney.

Regulation of microvessel assembly in the developing kidney is not known and may occur through vasculogenic, angiogenic, or both processes. To examine this question, we grafted rat and mice embryonic (E) day 12 (E12) kidneys, which have only a rudimentary vasculature, into anterior eye chambers of mouse and rat hosts. Species-specific, monoclonal anti-basement membrane antibodies showed that glomerular basement membranes, mesangial matrices, and microvessel basement membranes were always derived from the graft. When wild-type E12 mouse kidneys were grafted into anterior chambers of ROSA26 mice, in which the beta-galactosidase transgene is expressed ubiquitously, glomerular and microvascular endothelial cells stemmed from the graft, even after maintenance of kidneys in organ culture for 6 days before grafting. Immunolabeling with antibodies against the vascular endothelial growth factor (VEGF) receptor, Flk1, the EphB1 receptor, and its ligand, ephrin-B1, labeled discrete mesenchymal cells in embryonic and newborn kidney cortex, as well as developing microvessel and glomerular endothelium. In adult kidneys, Flk1 labeled glomeruli weakly, other vascular structures were unlabeled. When wild-type E12 kidneys were grafted under renal capsules of adult ROSA26 hosts, endothelium developing within the graft again came from the implanted kidney. In contrast, when E12 kidneys were grafted into renal cortices of newborns, glomeruli within grafts now contained host-derived endothelium. Similarly, when ROSA26 E12 kidneys were implanted into newborn wild-type hosts, chimeric vessels containing graft- and host-derived endothelium were seen in nearby host tissue. Our results indicate that cells capable of forming the entire microvascular tree of grafted metanephroi are already present in the E12 kidney. We hypothesize that Flk1/VEGF and EphB1/ephrin-B1 mediate renal endothelial mitosis-motility and cell guidance-aggregation behavior, respectively.

Evidence that embryonic kidney cells expressing flk-1 are intrinsic, vasculogenic angioblasts.

Renal glomerular capillary tufts have been believed to arise from angiogenic ingrowth of extrinsic vessels. We found, however, that when embryonic day 12 (E12) mouse kidneys were maintained in culture for 6 days and then grafted into anterior eye chambers of adult transgenic ROSA26 host mice (which carry the beta-galactosidase transgene), glomerular endothelial cells within the grafts were predominantly of intrinsic, kidney origin. To identify potential endothelial precursors, we immunolabled kidneys with antibodies against the vascular endothelial growth factor receptor, flk-1. Numerous discrete cells expressing flk-1 were scattered throughout the nephrogenic mesenchyme of both E12 and newborn kidneys, and with development these cells became concentrated in microvessels, glomerular vascular clefts, and glomerular tufts. In adults, flk-1 was weakly expressed in glomeruli but absent elsewhere. To examine abilities of flk-1-positive cells to establish glomeruli, E12 kidneys were grafted into kidney cortices of adult and newborn ROSA26 hosts. Grafts into adults resulted in few glomeruli containing host-derived endothelium, whereas a majority of glomeruli grafted into newborns contained host cells. Cells of graft origin were found in vessels forming in renal cortices of newborn hosts, but not in adults. Our findings indicate that embryonic kidney cells expressing flk-1 are angioblasts that create microvessels and glomeruli by vasculogenesis.

Expression of the urate transporter/channel is developmentally regulated in human kidneys.

Recombinant protein prepared from cDNA cloned from rat kidney and its human homolog function as urate transporter/channels in lipid bilayers. Using the antibody (anti-uricase) that detected the rat cDNA clone, we now demonstrate that normal human kidneys contain an immunoreactive protein of identical size to that in rat kidney (36-37 kDa), presumably the human urate transporter/channel (hUAT). The amount of hUAT in kidney homogenates increases progressively from 13 wk of gestation to the early postnatal period. During gestation, hUAT expression is confined to the cytoplasm of proximal tubules of Stage III and/or IV nephrons. However, at 1 yr of age hUAT is primarily located subapically and within brush borders of proximal tubules. Xenopus laevis oocytes and differentiated A6 cells injected with cRNA and transfected with cDNA of hUAT, respectively, demonstrated a similar pattern: hUAT is not detected in oocytes but is abundantly expressed in cytoplasm and plasma membranes of A6 cells. These data imply that different developmental factors regulate the initiation of cytoplasmic hUAT expression and subsequent insertion into human proximal tubule brush-border membranes.

Endogenous origin of glomerular endothelial and mesangial cells in grafts of embryonic kidneys.

To address origins of glomerular endothelial and mesangial cells in embryonic mammalian kidneys, we established interspecies grafts between rats and mice, in which fetal kidneys were implanted into the anterior eye chamber of adult hosts. After 5-7 days, hosts bearing grafts received intravenous injections with species-specific monoclonal antibodies (MAbs) to matrix components. In all cases, glomerular basement membranes and mesangial matrices labeled solely for donor-derived matrix. Additionally, microvessel extracellular matrices within grafts were usually of donor origin. To examine directly the origin of glomerular endothelial and mesangial cells, we grafted embryonic gestational days 11-12 (E11-12) kidneys from normal mice into anterior eye chambers of host reverse-orientation splice acceptor 26 mice, which are transgenic animals that express beta-galactosidase in every cell. When grafts were developed for beta-galactosidase activity, host cells were seen in peripheral vessels, but the majority of glomerular endothelial cells were of donor, not host, origin. Where host-derived-endothelial cells were found in glomeruli, donor endothelial cells were present as well. Mesangial cells were always of donor origin. When E11 mouse kidneys were labeled with the endothelial cell-specific Bandeiraea simplicifolia isolectin B4, we determined that endothelial cells are present from the inception of metanephrogenesis. Together, the evidence shows that cells of endogenous kidney origin were almost entirely responsible for development of the glomerular microvasculature in oculo. External vessels from the host, although important for graft maintenance, were not major contributors to the glomerulus.