The canonical WNT signaling pathway plays a crucial role in patterning of the embryo during development, but little is known about the specific developmental events which are under WNT control. To understand more about how the WNT pathway orchestrates mammalian organogenesis, we studied the canonical -catenin-mediated WNT signaling pathway in kidneys of mice bearing a -catenin-responsive TCF/Gal reporter transgene. In metanephric kidney, intense canonical WNT signaling was evident in epithelia of the branching ureteric bud and in nephrogenic mesenchyme during its transition into renal tubules. WNT signaling activity is rapidly downregulated in maturing nephrons and becomes undetectable in postnatal kidney. Sites of TCF/Gal activity are in proximity to the known sites of renal WNT2b and WNT4 expression, and these WNTs stimulate TCF reporter activity in kidney cell lines derived from ureteric bud and metanephric mesenchyme lineages. When fetal kidney explants from HoxB7/GFP mice were exposed to the canonical WNT signaling pathway inhibitor, Dickkopf-1, arborization of the ureteric bud was significantly reduced. We conclude that restricted zones of intense canonical WNT signaling drive branching nephrogenesis in fetal kidney. nephrogenesis; -catenin; branching morphogenesis THE WNT FAMILY is comprised of 19 secreted glycoproteins which act as short-range intercellular signaling molecules, recognizing one of the 10 frizzled receptors expressed at the surface of nearby target cells. The canonical signaling pathway is activated by WNTs which bind to cognate frizzled receptors heterodimerized with LRP5 or LRP6 coreceptors (2). Activated receptors recruit dishevelled protein (Dvl) and inhibit degradation of cytoplasmic -catenin via the GSK3-axin-APC complex (11). When its degradation is blocked, cytoplasmic -catenin is available to translocate to the nucleus, dimerize with partners belonging to the T-cell factor (TCF) family, and activate target genes. TCF recognition motifs have been well-studied, allowing design of vectors (e.g., TOPFlash) which drive transcription of reporter genes in response to canonical WNT signaling activity (32). In general, canonical -catenin/TCF signaling is thought to activate gene targets (e.g., c-myc) involved in cell proliferation (3, 27).More than 35 years ago, Unsworth and Grobstein (33) reported that tissue from spinal cord could induce formation of renal tubules when cocultured with isolated metanephric mesenchyme. In 1994, Herzlinger et al. (12) found that WNT1-expressing NIH3T3 cells were also able to induce tubule formation in the coculture assay, suggesting that the canonical (-catenin-mediated) WNT signaling pathway is essential for mammalian nephrogenesis. However, the precise function of canonical WNT signaling in renal development is unknown. Surprisingly, WNT1 is not present in the developing kidney, but numerous other WNTs are transiently expressed in specific cell lineages (34). Several of these are able to activate the canonical signaling pathway in other context...
Cystinosis is a rare disease caused by homozygous mutations of the CTNS gene, encoding a cystine efflux channel in the lysosomal membrane. In Ctns knockout mice, the pathologic intralysosomal accumulation of cystine that drives progressive organ damage can be reversed by infusion of wildtype bone marrow-derived stem cells, but the mechanism involved is unclear since the exogeneous stem cells are rarely integrated into renal tubules. Here we show that human mesenchymal stem cells, from amniotic fluid or bone marrow, reduce pathologic cystine accumulation in co-cultured CTNS mutant fibroblasts or proximal tubular cells from cystinosis patients. This paracrine effect is associated with release into the culture medium of stem cell microvesicles (100–400 nm diameter) containing wildtype cystinosin protein and CTNS mRNA. Isolated stem cell microvesicles reduce target cell cystine accumulation in a dose-dependent, Annexin V-sensitive manner. Microvesicles from stem cells expressing CTNSRed transfer tagged CTNS protein to the lysosome/endosome compartment of cystinotic fibroblasts. Our observations suggest that exogenous stem cells may reprogram the biology of mutant tissues by direct microvesicle transfer of membrane-associated wildtype molecules.
Human nephrons are formed during fetal life through an interaction between the branching ureteric bud and progenitor cells. The wide variation in final nephron number has been attributed to allelic variants of genes regulating ureteric bud arborization. Here, we hypothesize that dysfunctional variants of the Odd-Skipped Related 1 (OSR1) gene which compromise the renal progenitor cell pool might also limit newborn kidney size and function. We show that OSR1 is expressed in human mesenchymal stem cells, the blastemal component of Wilms tumors and CD24+/CD133+ progenitor cells isolated from the mature kidney. We identified an OSR1(rs12329305(T)) allele in 6% of normal Caucasians which alters an exon2 splice enhancer. This variant is predicted to reduce spliceosome-binding affinity and stability of the OSR1 mRNA. In cultured cells, the OSR1(rs12329305)(T) allele produced no identifiable transcript. Normal Caucasian newborns from Montreal with the OSR1(rs12329305)(T) allele had kidney volume 11.8% smaller (P= 0.006) and cord blood cystatin C levels 12.6% higher (P = 0.005) than those with wild-type genotype. Effects of the OSR1(rs12329305)(T) allele are additive with genes that alter ureteric bud branching. Kidney volume was reduced more in newborns bearing both RET(rs1800860)(A) and OSR1(rs12329305)(T) alleles (22%, P= 0.0008) and cystatin C was increased by 17% (P= 0.006) versus newborns with wild-type alleles. Although only two subjects had PAX2(rs11599825)(A) and OSR1(rs12329305)(T) alleles, kidney size was reduced by 27% and cystatin C was increased by 14% versus wild-types (P= NS).
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