We suggest that reductions in these components could be linked with downregulation of the survival mediated Akt pathway and suggested an active role of the Akt pathway in bladder cancer. Altogether, our in vitro and pre-clinical model data support the potential use of an AZ + SFN combination for the treatment of bladder cancer.
Sonic hedgehog (Shh) signaling pathway has emerged as a critical component of bladder development, cancer initiation, and progression. While the role of Shh signaling in bladder development is well documented, its role in bladder cancer progression is uncertain. Additionally, epithelial-to-mesenchymal transition (EMT) has been identified to promote bladder cancer progression in the initial stages and also contribute to drug resistance in the later stage and ultimately metastasis. We speculate that epithelial-to-mesenchymal transitions (EMT) and Shh fuel the carcinogenesis process. This review presents the most recent studies focusing on the role of Shh signaling in bladder cancer progression.
Disorders of sexual development (DSD) encompass a broad spectrum of urogenital malformations and are amongst the most common congenital birth defects. Although key genetic factors such as the hedgehog (Hh) family have been identified, a unifying postnatally viable model displaying the spectrum of male and female urogenital malformations has not yet been reported. Since human cases are diagnosed and treated at various stages postnatally, equivalent mouse models enabling analysis at similar stages are of significant interest. Additionally, all non-Hh based genetic models investigating DSD display normal females, leaving female urogenital development largely unknown. Here, we generated compound mutant mice, Gli2+/–;Gli3Δ699/+, which exhibit a spectrum of urogenital malformations in both males and females upon birth, and also carried them well into adulthood. Analysis of embryonic day (E)18.5 and adult mice revealed shortened anogenital distance (AGD), open ventral urethral groove, incomplete fusion of scrotal sac, abnormal penile size and structure, and incomplete testicular descent with hypoplasia in male mice, whereas female mutant mice displayed reduced AGD, urinary incontinence, and a number of uterine anomalies such as vaginal duplication. Male and female fertility was also investigated via breeding cages, and it was identified that male mice were infertile while females were unable to deliver despite becoming impregnated. We propose that Gli2+/–;Gli3Δ699/+ mice can serve as a genetic mouse model for common DSD such as cryptorchidism, hypospadias, and incomplete fusion of the scrotal sac in males, and a spectrum of uterine and vaginal abnormalities along with urinary incontinence in females, which could prove essential in revealing new insights into their equivalent diseases in humans.
Traditional methods of cartilage tissue engineering rely on the use of scaffolds. Although successful chondrogenesis has been reported in scaffold-based constructs, the use of exogenous materials has limited their application due to eliciting host immunogenic responses and potentially resulting in construct failure. As a result, tissue engineering approaches, which aim to generate scaffold-free cartilaginous constructs, have become of particular interest. Here, we generated stable three-dimensional scaffold-free cartilaginous constructs by cultivating expanded pediatric nasal chondrocyte multilayers in a slow turning lateral vessel bioreactor system under chemically defined media. Bioreactor cultivation resulted in increased construct cellularity, fourfold tissue thickness, and 200% sulfated glycosaminoglycan deposition with respect to static culture equivalent cultures. These improvements led to significantly enhanced mechanical and biochemical properties of bioreactor-cultivated constructs, allowing them to support their own weight, while static culture constructs remained fragile. Consequently, bioreactor-cultivated constructs closely resembled native nasal cartilage tissue histologically, mechanically, and biochemically. We propose that this method of cartilage construct formation could be used to obtain readily available human scaffold-free cartilaginous constructs.
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