Urothelial transdifferentiation to prostate epithelia is mediated by paracrine TGF-β signaling

The embryonic urogenital sinus mesenchyme (UGM) induces prostate epithelial morphogenesis in development. The molecular signals that drive UGM-mediated prostatic induction have not been defined. We hypothesized that the TGF-β signaling directed the prostatic induction. UGM from TGF-β type II receptor stromal conditional knockout mice (Tgfbr2^fspKO) or control mice (Tgfbr2^{floxE2/floxE2}) was recombined with wild-type adult mice bladder urothelial cells. The resulting urothelium associated with Tgfbr2^{floxE2/floxE2} UGM was instructively differentiated into prostatic epithelium, as expected. In contrast, the urothelium associated with Tgfbr2^fspKO UGM permissively maintained the phenotype of bladder epithelial cells. Microarray analysis of UGM tissues suggested the down-regulation of multiple Wnt ligands and the up-regulation of the Wnt antagonist, Wif 1, by the Tgfbr2^fspKO UGM compared with Tgfbr2^{floxE2/floxE2} UGM. The overexpression of Wif-1 by wild-type UGM resulted in the inhibition of prostatic induction. These data suggest that the stromal TGF-β activity mediated by paracrine Wnt is necessary for the induction of prostatic differentiation. As Wnt ligands mediate differentiation and maintain the stem cell phenotype, the contribution of mouse stem cells and somatic cells to prostatic epithelium in the tissue recombination models was tested. The directed differentiation of mouse embryonic stem cells by UGM is suggested by a threshold number of mouse stem cells required in prostatic differentiation. To determine the contribution of somatic cells, the adult bladder epithelial compartment was labeled with green-fluorescent vital dye (CMFDA) and the stem-like cells marked by bromodeoxyuridine (BrdU) label-retention. The resulting prostatic epithelia of the tissue recombinants maintained the CMFDA dye, suggesting minimal cell division. Thus, the UGM can induce endoderm-derived epithelia and stem cells to form prostate through a transdifferentiation mechanism that requires stromal TGF-β signaling to mediate epithelial Wnt activity.     

The effect of epidermal growth factor and transforming growth factor β1 on proliferation and differentiation of urothelial cells in urinary bladder explant culture

The effects of two growth factors, EGF and TGFβ₁, on growth and differentiation of different populations of urothelial cells in explant cultures of mouse urinary bladder have been studied by electron microscopy and lectin analysis. In an explant culture 10 days after the implantation three different populations of urothelial cells can be distinguished. Original urothelial cells, which are integral part of the explant, new urothelial cells, which cover the baso-lateral sides of the explant and are organized in a multilayer epithelium, and new urothelial cells, which are not any more in direct contact with the explant and grow over the membrane in epithelium-like structure. Exogenously added EGF or TGFβ₁ did not affect either the formation or the thickness of multilayered urothelium, so cells were proliferating on the free surfaces of stroma as well as on the epithelium expanding over the membrane. In the absence of growth factors in medium, the newly formed baso-lateral multilayered epithelium bordering the stroma shows ultrastructural signs of terminal differentiation suggesting that for cell proliferation and differentiation the action of stroma is of crucial importance. On the other hand, the differentiation of the epithelium spreading over the membrane, but not its thickness, is affected by exogenously added TGFβ₁. Solely in TGFβ₁-treated cultures a differentiation sirnilar to that in vivo takes place. The apoptosis of the urothelial cells was not increased by TGFβ₁. The lectin analysis by WGA and ConA conjugated with ferritin revealed that ConA-ferritin combines only with the surface cells which grow over the membrane in the absence of TGFβ₁.     

Aquaporin Expression Contributes to Human Transurothelial Permeability In Vitro and Is Modulated by NaCl

It is generally considered that the bladder is impervious and stores urine in unmodified form on account of the barrier imposed by the highly-specialised uro-epithelial lining. However, recent evidence, including demonstration of aquaporin (AQP) expression by human urothelium, suggests that urothelium may be able to modify urine content. Here we have we applied functional assays to an in vitro-differentiated normal human urothelial cell culture system and examined both whether AQP expression was responsive to changes in osmolality, and the effects of blocking AQP channels on water and urea transport. AQP3 expression was up-regulated by increased osmolality, but only in response to NaCl. A small but similar effect was seen with AQP9, but not AQP4 or AQP7. Differentiated urothelium revealed significant barrier function (mean TER 3862 Ω.cm²), with mean diffusive water and urea permeability coefficients of 6.33×10⁻⁵ and 2.45×10⁻⁵ cm/s, respectively. AQP blockade with mercuric chloride resulted in decreased water and urea flux. The diffusive permeability of urothelial cell sheets remained constant following conditioning in hyperosmotic NaCl, but there was a significant increase in water and urea flux across an osmotic gradient. Taken collectively with evidence emerging from studies in other species, our results support an active role for human urothelium in sensing and responding to hypertonic salt concentrations through alterations in AQP protein expression, with AQP channels providing a mechanism for modifying urine composition. These observations challenge the traditional concept of an impermeable bladder epithelium and suggest that the urothelium may play a modulatory role in water and salt homeostasis.     

Bladder cancer cell in co-culture induces human stem cell differentiation to urothelial cells through paracrine FGF10 signaling

Fibroblast growth factor 10 (FGF10) is required for embryonic epidermal morphogenesis including brain development, lung morphogenesis, and initiation of limb bud formation. In this study, we investigated the role of FGF10 as a lead induction factor for stem cell differentiation toward urothelial cell. To this end, human multipotent stem cell in vitro system was employed. Human amniotic fluid stem cells were co-cultured with immortalized bladder cancer lines to induce directed differentiation into urothelial cells. Urothelial markers, uroplakin II, III, and cytokeratin 8, were monitored by RT-PCR, immunocytochemistry, and Western blot analysis. Co-cultured stem cells began to express uroplakin II, III, and cytokeratin 8. Targeted FGF10 gene knockdown from bladder cancer cells abolished the directed differentiation. In addition, when FGF10 downstream signaling was blocked with the Mek inhibitor, the co-culture system lost the capacity to induce urothelial differentiation. Exogenous addition of recombinant FGF10 protein promoted stem cell differentiation into urothelium cell lineage. Together, this report suggests that paracrine FGF10 signaling stimulates the differentiation of human stem cell into urothelial cells. Current study provides insight into the potential role of FGF10 as a lead growth factor for bladder regeneration and its therapeutic application for bladder transplantation.     

Claudin-4 Deficiency Results in Urothelial Hyperplasia and Lethal Hydronephrosis

Claudin (Cld)-4 is one of the dominant Clds expressed in the kidney and urinary tract, including selective segments of renal nephrons and the entire urothelium from the pelvis to the bladder. We generated Cldn4 ^−/− mice and found that these mice had increased mortality due to hydronephrosis of relatively late onset. While the renal nephrons of Cldn4 ^−/− mice showed a concomitant diminution of Cld8 expression at tight junction (TJ), accumulation of Cld3 at TJ was markedly enhanced in compensation and the overall TJ structure was unaffected. Nonetheless, Cldn4 ^−/− mice showed slightly yet significantly increased fractional excretion of Ca²⁺ and Cl⁻, suggesting a role of Cld4 in the specific reabsorption of these ions via a paracellular route. Although the urine volume tended to be increased concordantly, Cldn4 ^−/− mice were capable of concentrating urine normally on dehydration, with no evidence of diabetes insipidus. In the urothelium, the formation of TJs and uroplaques as well as the gross barrier function were also unaffected. However, intravenous pyelography analysis indicated retarded urine flow prior to hydronephrosis. Histological examination revealed diffuse hyperplasia and a thickening of pelvic and ureteral urothelial layers with markedly increased BrdU uptake in vivo. These results suggest that progressive hydronephrosis in Cldn4 ^−/− mice arises from urinary tract obstruction due to urothelial hyperplasia, and that Cld4 plays an important role in maintaining the homeostatic integrity of normal urothelium.     

Plasticity of the urothelial phenotype: effects of gastro-intestinal mesenchyme/stroma and implications for urinary tract reconstruction

The present study tests the hypothesis that heterotypic stromal-epithelial interactions cause phenotypic changes in urothelium. The rational for the experimental design is to simulate heterotypic stromal-epithelial interactions that are created at the anastomotic site of intestinal-bladder augmentations and internal urinary diversions where the urothelium is in direct contact with the gastro-intestinal tract tissues. Tissue recombination experiments were performed by combining 14-day embryonic rat and mouse rectal mesenchyme with urothelium from embryonic, newborn, and adult mice or rats. All tissue recombinants were grown beneath the renal capsule of athymic mouse hosts for 6-16 weeks. Analyses were performed to detect expression of uroplakins, cytokeratin 7, 14, 19 and mucin secreting epithelial cells via Periodic Acid-Schiff (PAS). The phenotype of both mouse and rat urothelium was changed to a glandular morphology under the influence of rectal mesenchyme. Immunohistochemical staining revealed a loss of the urothelial specific uroplakins and cytokeratins 7, 14, and 19 (characteristic of urothelium). Histologic analysis revealed the presence of mucin secreting glandular structures which stained positive for PAS. The urothelial transdifferentiation into glandular epithelium was not a function of epithelial age and occurred in the embryonic, newborn and adult urothelium. Likewise, rectal mesenchyme from embryonic, neonatal, and adult animals was able to induce glandular differentiation in bladder epithelium. Urothelium exhibits the plasticity to change into an intestinal like epithelium as a result of mesenchymal/stromal stimulation from the gastro-intestinal tract. This experimental result is germane to heterotypic stromal-epithelial interactions that are created in patients with urinary tract reconstructions (intestinal augmentations, de-mucosalized urothelial lined bladder patches, and internal urinary diversion such as ureterosigmoidostomies). We propose that heterotypic stromal-epithelial interactions may play a role in determining histodifferentiation of urothelial cells at the anastomotic site between bowel and bladder tissue in patients with gastro-intestinal urothelial reconstructions.     

小鼠膀胱上皮的中间层细胞中存在Uroplakins

本文运用超薄切片、冰冻蚀刻及免疫胶体金标记等多种电镜技术并结合免疫组化、免疫荧光染色技术,直观地显示出小鼠膀胱上皮的中间层细胞存在Uroplakins,并在梭形泡膜上形成了与表层细胞类似的AUM结构,而且梭形泡的AUM结构也结合在中间纤维上。蛋白质免疫印迹反应进一步证实中间层细胞含有与表层细胞相同的Uroplakin Ⅰ和UroplakinⅢ等AUM蛋白的主要成份,从而为AUM的发生及其与细胞分化关系的研究提供了重要的实验证据。     

A simple method for in vitro studies with rodent urinary blandders

Summary A method was developed for the in vitro study of rodent urinary bladders. The method consists of everting and distending the urinary bladder in a manner to allow exposure of the luminal surface of the urothelium during in vitro incubation while maintaining the integrity of the structure and morphology of the bladder. A technique for selectively removing the urothelium with SDS buffer for biochemical analysis was described. Incorporation of [³H]leucine into urothelial protein was linear over a 4 h period in the presence of tissue culture medium, but no significant incorporation occurred when urine was used as incubation medium. Autoradiography indicated the [³H]leucine incorporation was almost exclusively in the urothelial cells with essentially no incorporation by cells below the tunica propria.