PPARγ‐regulated tight junction development during human urothelial cytodifferentiation
Urothelial barrier function is maintained by apical membrane plaques and intercellular tight junctions (TJ). Little is known about the composition and regulation of TJ expression in human urothelium. In this study, we have characterised the expression of TJ components in situ and their regulation in an in vitro model of differentiating normal human urothelial (NHU) cells. In normal ureteric urothelium in situ, there was a differentiation-associated profile of claudins 3, 4, 5, 7, ZO1 and occludin proteins. Proliferating NHU cells in vitro expressed predominantly claudin 1 protein and transcripts for claudins 1-5 and 7. Following induction of differentiation by pharmacological activation of PPARγand blockade of EGFR, there was de novo expression of claudin 3 mRNA and protein and downregulation of claudin 2 transcription. There was also a massive increase in expression of claudin 4 and 5 proteins which was due to inhibition of proteasomal degradation of claudin 4 and consequential stabilisation of the claudin 5 heterodimerisation partner. NHU cell differentiation was accompanied by relocalisation of TJ proteins to intercellular junctions. The differentiation-associated development of TJ formation in vitro reflected the stage-related TJ expression seen in situ. This was distinct from changes in TJ composition of NHU cells mediated by increasing the calcium concentration of the medium. Our results imply a role for PPARγ and EGFR signalling pathways in regulating TJ formation in NHU cells and support the hypothesis that TJ development is an integral part of the urothelial differentiation programme.The maintenance of epithelial barrier function requires that the transepithelial passage of water and solutes be tightly regulated. Ion channels and membrane pumps located in the apical and basolateral membrane compartments control transcellular ion transport, whereas tight junctions (TJ), located at the superior aspect of the intercellular junctional complex, control paracellular diffusion (Schneeberger and Lynch, 2004). TJ are composed of cytoplasmic plaque proteins, such as the zonular occludens (ZO) proteins that link the TJ to the cytoskeleton, and integral transmembrane proteins, such as occludin, junctional adhesion molecule (JAM) and claudins that define the properties of the paracellular pore (Tsukita and Furuse, 2002; GonzalezMariscal et al., 2003). The TJ not only limits paracellular movement, but maintain polarity by restricting the movement of proteins and lipids between apical and basolateral membrane compartments. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author ManuscriptThe claudins, which represent a multigene family of some 24 members ranging from 20,000 to 27,000 Mr, are considered to represent the primary seal-forming fibrils of the TJ. Claudins are tetra-spanning proteins, comprising two extracellular loops and short amino and carboxy termini (Schneeberger and Lynch, 2004). The expression of different claudin proteins and the pairing of claudins to form homotypic or heterotypic f...
Differentiation potential of urothelium from patients with benign bladder dysfunction
LKT and IE contributed equally assessed by the acquisition of a transitional cell morphology, a switch from a cytokeratin (CK)13 lo /CK14hi to a CK13 hi /CK14 lo phenotype, expression of claudin 3, 4 and 5 proteins, and induction of uroplakin gene transcription. RESULTSTwo of 12 SUI cell lines showed early senescent changes in culture and were not characterized further; one of seven IC, one of five IDO and a further three SUI cell lines had some evidence of senescence at passage 3. Of the seven IC-derived cell lines, four showed a near normal range of differentiationassociated responses, but the remainder showed little or no response. Most IDO cell lines (four of five) showed a normal differentiation response, but at least three of the 10 SUI cell lines showed some compromise of differentiation potential. CONCLUSIONThis study supports the existence of a subset of patients with IC in whom a failure of urothelial cytodifferentiation might contribute to the disease, and provides a novel platform for investigating the cell biology of urothelium from SUI and other benign dysfunctional conditions.
Despite major advances in high-throughput and computational modelling techniques, understanding of the mechanisms regulating tissue specification and differentiation in higher eukaryotes, particularly man, remains limited. Microarray technology has been explored exhaustively in recent years and several standard approaches have been established to analyse the resultant datasets on a genome-wide scale. Gene expression time series offer a valuable opportunity to define temporal hierarchies and gain insight into the regulatory relationships of biological processes. However, unless datasets are exactly synchronous, time points cannot be compared directly. Here we present a data-driven analysis of regulatory elements from a microarray time series that tracked the differentiation of non-immortalised normal human urothelial (NHU) cells grown in culture. The datasets were obtained by harvesting differentiating and control cultures from finite bladder- and ureter-derived NHU cell lines at different time points using two previously validated, independent differentiation-inducing protocols. Due to the asynchronous nature of the data, a novel ranking analysis approach was adopted whereby we compared changes in the amplitude of experiment and control time series to identify common regulatory elements. Our approach offers a simple, fast and effective ranking method for genes that can be applied to other time series. The analysis identified ELF3 as a candidate transcriptional regulator involved in human urothelial cytodifferentiation. Differentiation-associated expression of ELF3 was confirmed in cell culture experiments and by immunohistochemical demonstration in situ. The importance of ELF3 in urothelial differentiation was verified by knockdown in NHU cells, which led to reduced expression of FOXA1 and GRHL3 transcription factors in response to PPARγ activation. The consequences of this were seen in the repressed expression of late/terminal differentiation-associated uroplakin 3a gene expression and in the compromised development and regeneration of urothelial barrier function.
BackgroundThere is an emerging association between ketamine abuse and the development of urological symptoms including dysuria, frequency and urgency, which have a neurological component. In addition, extreme cases are associated with severe unresolving bladder pain in conjunction with a thickened, contracted bladder and an ulcerated/absent urothelium. Here we report on unusual neuropathological features seen by immunohistology in ketamine cystitis.ResultsIn all cases, the lamina propria was replete with fine neurofilament protein (NFP+) nerve fibres and in most patients (20/21), there was prominent peripheral nerve fascicle hyperplasia that showed particular resemblance to Morton’s neuroma. The nerve fascicles, which were positive for NFP, S100 and the p75 low-affinity nerve growth factor receptor (NGFR), were generally associated with a well-developed and in places, prominent, epithelial membrane antigen+/NGFR+ perineurium. This peripheral nerve fascicle hyperplasia is likely to account for the extreme pain experienced by ketamine cystitis patients. Urothelial damage was a notable feature of all ketamine cystitis specimens and where urothelium remained, increased NGFR expression was observed, with expansion from a basal-restricted normal pattern of expression into the suprabasal urothelium.ConclusionsThe histological findings were distinguishing features of ketamine cystitis and were not present in other painful bladder conditions. Ketamine cystitis afflicts predominantly young patients, with unknown long-term consequences, and requires a strategy to control severe bladder pain in order to remove a dependency on the causative agent. Our study indicates that the development of pain in ketamine cystitis is mediated through a specific neurogenic mechanism that may also implicate the urothelium.
Transplantation of Autologous Differentiated Urothelium in an Experimental Model of Composite Cystoplasty
BackgroundEnterocystoplasty is associated with serious complications resulting from the chronic interaction between intestinal epithelium and urine. Composite cystoplasty is proposed as a means of overcoming these complications by substituting intestinal epithelium with tissue-engineered autologous urothelium.ObjectiveTo develop a robust surgical procedure for composite cystoplasty and to determine if outcome is improved by transplantation of a differentiated urothelium.Design, setting, and participantsBladder augmentation with in vitro–generated autologous tissues was performed in 11 female Large-White hybrid pigs in a well-equipped biomedical centre with operating facilities. Participants were a team comprising scientists, urologists, a veterinary surgeon, and a histopathologist.MeasurementsUrothelium harvested by open biopsy was expanded in culture and used to develop sheets of nondifferentiated or differentiated urothelium. The sheets were transplanted onto a vascularised, de-epithelialised, seromuscular colonic segment at the time of bladder augmentation. After removal of catheters and balloon at two weeks, voiding behaviour was monitored and animals were sacrificed at 3 months for immunohistology.Results and limitationsEleven pigs underwent augmentation, but four were lost to complications. Voiding behaviour was normal in the remainder. At autopsy, reconstructed bladders were healthy, lined by confluent urothelium, and showed no fibrosis, mucus, calculi, or colonic regrowth. Urothelial morphology was transitional with variable columnar attributes consistent between native and augmented segments. Bladders reconstructed with differentiated cell sheets had fewer lymphocytes infiltrating the lamina propria, indicating more effective urinary barrier function.ConclusionsThe study endorses the potential for composite cystoplasty by (1) successfully developing reliable techniques for transplanting urothelium onto a prepared, vascularised, smooth muscle segment and (2) creating a functional urothelium-lined augmentation to overcome the complications of conventional enterocystoplasty.
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