Embryonic nephron progenitor cells are segregated in molecularly distinct compartments of unknown function. Our study reveals an integral role for bone morphogenetic protein-SMAD in promoting transition of progenitors from the primitive Cbp/p300-interacting transactivator 1 expressing (CITED1+) compartment to the uniquely sine oculis-related homeobox 2 expressing (SIX2-only) compartment where they become inducible by wingless-type mouse mammary tumor virus integration site family member (WNT)/β-catenin signaling. Significantly, CITED1+ cells are refractory to WNT/β-catenin induction. We propose a model in which the primitive CITED1 + compartment is refractory to induction by WNT9b/β-catenin, ensuring maintenance of undifferentiated progenitor cells for future nephrogenesis. Bone morphogenetic protein 7-SMAD is then required for transition to a distinct compartment in which cells become inducible by WNT9b/β-catenin, allowing them to progress toward epithelialization.cap mesenchyme | niche | pretubular aggregate | nephrogenic zone | kidney development
Forkhead transcription factors are essential for diverse processes in early embryonic development and organogenesis. Foxd1 is required during kidney development and its inactivation results in failure of nephron progenitor cell differentiation. Foxd1 is expressed in interstitial cells adjacent to nephron progenitor cells, suggesting an essential role for the progenitor cell niche in nephrogenesis. To better understand how cortical interstitial cells in general, and FOXD1 in particular, influence the progenitor cell niche, we examined the differentiation states of two progenitor cell subtypes in Foxd1 −/− tissue. We found that although nephron progenitor cells are retained in a primitive CITED1-expressing compartment, cortical interstitial cells prematurely differentiate. To identify pathways regulated by FOXD1, we screened for target genes by comparison of Foxd1 null and wild-type tissues. We found that the gene encoding the small leucine-rich proteoglycan decorin (DCN) is repressed by FOXD1 in cortical interstitial cells, and we show that compound genetic inactivation of Dcn partially rescues the failure of progenitor cell differentiation in the Foxd1 null. We demonstrate that DCN antagonizes BMP/SMAD signaling, which is required for the transition of CITED1-expressing nephron progenitor cells to a state that is primed for WNT-induced epithelial differentiation. On the basis of these studies, we propose a mechanism for progenitor cell retention in the Foxd1 null in which misexpressed DCN produced by prematurely differentiated interstitial cells accumulates in the extracellular matrix, inhibiting BMP7-mediated transition of nephron progenitor cells to a compartment in which they can respond to epithelial induction signals.
Bone morphogenic proteins (BMPs) play diverse roles in embryonic kidney development, regulating essential aspects of both ureteric bud and nephron development. In this review, we provide an overview of reported expression patterns and functions of BMP signaling components within the nephrogenic zone or nephron progenitor niche of the developing kidney. Reported in situ hybridization results are relatively challenging to interpret and sometimes conflicting. Comparing these with high-resolution microarray gene expression data available in Gudmap, we propose a consensus gene expression pattern indicating that essential components of both the Smad-mediated pathway and the Smad-independent mitogen activated protein kinase (MAPK) pathways are expressed in the nephron progenitor cell compartment and may be activated by BMPs, but that cortical interstitium may only be able to respond to BMPs through MAPK signaling. Localization of phosphorylated Smad transcription factors and studies of a BMP reporter mouse strain however indicate limited transcriptional responsiveness to Smad-mediated signaling in cap mesenchyme. An overview of genetic inactivation, organ culture, and primary cell studies indicates that BMP signaling may elicit two important biological outcomes in the nephrogenic zone: survival of the cap mesenchyme, and the physical segregation of interstitial and progenitor cell compartments. Ongoing studies using a novel primary cell system that establishes the nephrogenic zone ex vivo are pursuing the concept that the balance between Smad-mediated and Smad-independent responses to BMP ligand may underlie these distinct outcomes.
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