Evidence that bone morphogenetic protein 4 has multiple biological functions during kidney and urinary tract development

BACKGROUND: We have suggested that bone morphogenetic protein 4 (BMP4), acting on the Wolffian duct and ureter epithelium, determines the budding site of the ureter by locally antagonizing ubiquitous inductive signal(s) from the metanephric mesenchyme. In the present study, we examine the effect of BMP4 on the development of metanephric and periureteral mesenchymal cells, which express the BMP type I receptor gene, Bmpr1a (Alk3). METHODS: Urogenital tissues obtained from Bmp4 heterozygous null mutant (Bmp4+/-) embryos at different stages, and metanephric and ureteral tissue explants cultured in the presence of recombinant BMP4 were subjected to morphologic, immunohistochemical and in situ hybridization analyses. To examine the chemotactic activity of BMP4 for periureteral mesenchymal cells, a modified Boyden chamber assay was performed. RESULTS: Many of the kidneys of newborn Bmp4+/- mice contained multicystic dysplastic regions. This morphology was preceded by abnormally high apoptotic activity in the metanephric mesenchyme of mutant embryos at E14.5. In whole metanephric explants, BMP4 uniformly promoted the expansion of the Pax2-negative and weakly Foxd1 (previously Bf2) -positive peripheral stromal compartment of metanephric mesenchyme in the presence of fibroblast growth factor 2 (FGF2). In addition, in isolated metanephric mesenchyme, BMP4-loaded beads prevented apoptosis locally. Thus, BMP4 prevents cell death and promotes the growth of the metanephric mesenchyme. The effect of BMP4 on periureteral mesenchyme is different from its effect on metanephric mesenchyme. In utero, periureteral mesenchymal cells condense around the ureter epithelium, followed by differentiation into smooth muscle cells at a site where Bmp4 is intensely expressed. Analysis of Bmp4+/- ureters at E15.5 reveals that the alpha-smooth muscle actin (alpha-SMA)-positive cells are low in number. In vitro, BMP4-loaded beads promote the accumulation of periureteral mesenchymal cells to form several cell layers surrounding the beads. In addition, in a Boyden chamber assay, BMP4 increases the migration of periureteral mesenchymal cells through the filter. Thus, BMP4 can serve as a chemoattractant for periureteral mesenchymal cells and induce locally the smooth muscle layer of the ureter at Bmp4-expressing sites. CONCLUSION: Depending on local context, BMP4 has several biological actions on the morphogenesis of different portions of the excretory system, namely, the development of the ureterovesical junction, the ureter, and the kidney.     

Identifying the molecular phenotype of renal progenitor cells

Although many of the molecular interactions in kidney development are now well understood, the molecules involved in the specification of the metanephric mesenchyme from surrounding intermediate mesoderm and, hence, the formation of the renal progenitor population are poorly characterized. In this study, cDNA microarrays were used to identify genes enriched in the murine embryonic day 10.5 (E10.5) uninduced metanephric mesenchyme, the renal progenitor population, in comparison with more rostral derivatives of the intermediate mesoderm. Microarray data were analyzed using R statistical software to determine accurately genes differentially expressed between these populations. Microarray outliers were biologically verified, and the spatial expression pattern of these genes at E10.5 and subsequent stages of early kidney development was determined by RNA in situ hybridization. This approach identified 21 genes preferentially expressed by the E10.5 metanephric mesenchyme, including Ewing sarcoma homolog, 14-3-3 theta, retinoic acid receptor-alpha, stearoyl-CoA desaturase 2, CD24, and cadherin-11, that may be important in formation of renal progenitor cells. Cell surface proteins such as CD24 and cadherin-11 that were strongly and specifically expressed in the uninduced metanephric mesenchyme and mark the renal progenitor population may prove useful in the purification of renal progenitor cells by FACS. These findings may assist in the isolation and characterization of potential renal stem cells for use in cellular therapies for kidney disease.     

Essential roles of Sall1 in kidney development

SALL1 is a mammalian homologue of the Drosophila region-specific homeotic gene spalt (sal) and heterozygous mutations in SALL1 in humans lead to Townes-Brocks syndrome. We isolated a mouse homologue of SALL1 (Sall1) and found that mice deficient in Sall1 die in the perinatal period with kidney agenesis. Sall1 is expressed in the metanephric mesenchyme surrounding ureteric bud and homozygous deletion of Sall1 results in an incomplete ureteric bud outgrowth. Therefore, Sall1 is essential for ureteric bud invasion, the initial key step for metanephros development. We also generated mice in which a green fluorescent protein (GFP) gene was inserted into the Sall1 locus and we isolated the GFP-positive population from embryonic kidneys of these mice by fluorescence-activated cell sorting (FACS). We then compared gene expression profiles in the GFP-positive and -negative population using microarray analysis, followed by in situ hybridization. We detected many genes known to be important for metanephros development, and genes expressed abundantly in the metanephric mesenchyme. We also found groups of genes which are not known to be expressed in the metanephric mesenchyme. Thus a combination of microarray technology and Sall1-GFP mice is useful for systematic identification of genes expressed in the developing kidney.     

Stem cells in the embryonic kidney

The mammalian kidney, the metanephros, is formed by a reciprocally inductive interaction between two precursor tissues, the metanephric mesenchyme and the ureteric bud. The ureteric bud induces the metanephric mesenchyme to differentiate into the epithelia of glomeruli and renal tubules. Multipotent renal progenitors that form colonies upon Wnt4 stimulation and strongly express Sall1 exist in the metanephric mesenchyme; these cells can partially reconstitute a three-dimensional structure in an organ culture setting. Six2 maintains this mesenchymal progenitor population by opposing Wnt4-mediated epithelialization. Upon epithelial tube formation, Notch2 is required for the differentiation of proximal nephron structures (podocyte and proximal tubules). In addition, the induction methods of the intermediate mesoderm, the precursor of the metanephric mesenchyme, begin to be elucidated. If derivation of metanephric mesenchyme becomes possible, we will be closer to the generation and manipulation of multiple cell lineages in the kidney.     

Identification and initial characterization of 5000 expressed sequenced tags (ESTs) each from adult human normal and osteoarthritic cartilage cDNA libraries

OBJECTIVE: To prepare, sequence and analyse adult human cartilage cDNA libraries to study the gene expression pattern between normal and osteoarthritic cartilage. METHODS: Poly A(+)RNA from adult human normal and osteoarthritic articular cartilage was isolated and used to prepare cDNA libraries. Approximately 5000 ESTs from each library were sequenced and analysed using bioinformatic tools. The expression of select genes was confirmed by Northern blot and in situ hybridization analysis. RESULTS: Multiple gene families including several classical cartilage matrix protein encoding genes were identified. Approximately 28-40% of the genes sequenced from these libraries were novel, while half of the genes encoded known proteins and 4-6% of the genes encoded novel homologs of known proteins. Several known genes, whose expression has not been reported previously in cartilage, were also identified. We have confirmed the cartilage expression of three known (CTGF, CTGF-L and clusterin) and two novel homologs of known genes (PCPE-2 and Gal-Nac transferase) by Northern blot and in situ hybridization analysis. CONCLUSION: This is the first report of the preparation and sequencing of cDNA libraries from adult human normal and osteoarthritic articular cartilage. Further analysis of genes identified from these libraries may provide molecular targets for diagnosis and/or treatment of osteoarthritis (OA).     

Defining and redefining the nephron progenitor population

It has long been appreciated that the mammalian kidney arises via reciprocal interactions between an epithelial ureteric epithelium and the surrounding metanephric mesenchyme. More recently, lineage tracing has confirmed that the portion of the metanephric mesenchyme closest to the advancing ureteric tips, the cap mesenchyme, represents the progenitor population for the nephron epithelia. This Six2⁺Cited1⁺ population undergoes self-renewal throughout nephrogenesis while retaining the potential to epithelialize. In contrast, the Foxd1⁺ portion of the metanephric mesenchyme shows no epithelial potential, developing instead into the interstitial, perivascular, and possibly endothelial elements of the kidney. The cap mesenchyme rests within a nephrogenic niche, surrounded by the stroma and the ureteric tip. While the role of Wnt signaling in nephron induction is known, there remains a lack of clarity over the intrinsic and extrinsic regulation of cap mesenchyme specification, self-renewal, and nephron potential. It is also not known what regulates cessation of nephrogenesis, but there is no nephron generation in response to injury during the postnatal period. In this review, we will examine what is and is not known about this nephron progenitor population and discuss how an increased understanding of the regulation of this population may better explain the observed variation in final nephron number and potentially facilitate the reinitiation or prolongation of nephron formation.     

cDNA cloning and embryonic expression of mouse nuclear pore membrane glycoprotein 210 mRNA.

BACKGROUND: In embryonic kidneys, mesenchymal cells convert into epithelium in response to an induction by the tip of the ureter bud. Metanephric mesenchyme can also be induced to convert into epithelium in vitro. It is a model system to identify genes that could be important for epithelial development. METHODS: By differential screening of a cDNA library made from mesenchymes induced in transfilter cultures by embryonic spinal cord for 24 hours, we selected cDNA clones representing genes that were preferentially expressed in 24-hour-induced mesenchyme and not in uninduced mesenchyme. The sequence of one clone was determined and used to obtain the sequence of a complete open reading frame. By Northern blotting and in situ hybridization, the expression of the mRNA in embryonic kidneys was determined. RESULTS: We report the sequence and expression pattern of a marker for the 24-hour-induced state, mouse nuclear pore membrane glycoprotein 210 (mPOM210). The deduced 1886 amino acid sequence shows a 95% identity to the sequence of rat gp210. Northern blotting revealed a single 7.5 kb mRNA in 24-hour-induced mesenchyme, whereas message levels were fourfold to fivefold lower in uninduced mesenchyme. In situ hybridization of in vivo development confirmed the preferential expression of mPOM210 in epithelial cells. In the kidney, expression was seen in both the epithelium derived from the ureteric tree and the mesenchyme-derived epithelium. In other tissues of 13-day-old embryos, expression was also confined to the epithelium. In nervous tissues, the olfactory epithelium and walls of the lateral ventricle were the most prominently stained. Weak expression was seen in the heart. CONCLUSIONS: mPOM210 mRNA is an early marker for developing epithelial cells. Furthermore, our results suggest that nuclear pore membrane proteins could be more cell-type specific than previously anticipated.     

Hox genes and kidney development

The adult mammalian kidney is generated by the differentiation and integration of several distinct cell types, including the nephrogenic mesenchyme, ureteric epithelium, stromal and endothelial cells. How and where these cell types are generated and what signals lead to their differentiation and integration into a functional organ system is a main focus of current studies. Herein, we review the formation of distinct cell types within the adult mammalian kidney; what is understood regarding their origin and the signaling pathways that lead to their formation and integration; morphogenetic changes the metanephric kidney undergoes during development; and what is known regarding the role of Hox genes in these processes.     

A strategy for in vitro propagation of rat nephrons

BACKGROUND: Recent advances in the understanding of the molecular biology of rodent renal development have lead to the ability to culture the components of the developing rat kidney-the ureteric bud (UB) and the metanephric mesenchyme (MM)-in isolation from one another. Here we here describe a method for subculturing and propagating either whole rat metanephric rudiments or isolated rat UBs. Exploiting the branching program intrinsic to the UB, propagated rat UBs can be recombined with fresh rat mesenchyme to form a large number of rat "neokidneys" derived from a single progenitor that may be amenable to site-specific modulation of function. METHODS: Whole rat metanephric rudiments or isolated rat UBs were cultured and subdivided through several generations. Both cultured progenitor and subsequent generations of isolated rat UBs were recombined with freshly isolated rat metanephric mesenchyme. The tubules of these rat neokidneys were examined for expression of epithelial markers. RESULTS: Isolated rat UBs and whole rat metanephric rudiments could be propagated through several generations and appeared morphologically identical to their progenitors. Generations of isolated rat UB could be recombined with fresh rat mesenchyme and the resultant neokidney displayed the same morphologic appearance as the whole rat kidney rudiment. The UB-derived and MM-derived portions of the tubules of these rat neokidneys appear contiguous. CONCLUSIONS: The recombination of cultured and propagated rat UB with rat mesenchyme yielded rat neokidneys with tubular structures that appeared morphologically identical to whole rat kidney. In vitro propagation of rat metanephric rudiments and recombination of rat UB and MM suggest the possibility of designing nephrons that possess specific desirable functions that can be propagated in vitro.