Tumor Necrosis Factor-α Initiates miRNA-mRNA Signaling Cascades in Obstruction-Induced Bladder Dysfunction.

Bladder outlet obstruction (BOO) and the ensuing clinical lower urinary tract dysfunction are common in elderly patients. BOO is accompanied by urodynamic changes in bladder function and leads to organ fibrosis and ultimately loss of contractility. Comprehensive transcriptome analysis of bladder samples from human patients with different urodynamically defined phenotypes of BOO revealed tumor necrosis factor (TNF)-α as the top upstream signaling pathway regulator. Herein, we validated next-generation sequencing and pathway analysis in cell-based models using bladder smooth muscle and urothelial cells exposed to TNF-α. miRNA profiling and transcriptome analysis of TNF-α-treated bladder smooth muscle cells revealed striking similarities with human BOO. Using a comparative approach, TNF-specific and TNF-independent pathways were delineated in human biopsy specimens. Concomitant down-regulation of smooth muscle cell-specific miRNAs and smooth muscle markers after TNF-α treatment was in accordance with the loss of contractility in humans in advanced obstruction-induced bladder remodeling. The expression levels of four abundant TNF-regulated miRNAs were modulated; the compensatory up-regulation of miR-199a-5p reduced NF-κB signaling. Essential hubs of TNF-α signaling pathways mitogen-activated protein kinase kinase kinase (apoptosis signal-regulating kinase 1) and inhibitor of nuclear factor κ B kinase subunit ß (IκB kinase ß) were targeted by miR-199a-5p. miR-199a-5p might be part of a negative feedback loop, reducing the impact of TNF, whereas its down-regulation in acontractile bladders from BOO patients advances the disease. The compensatory up-regulation of miR-199a-5p together with TNF-α inhibition may be therapeutically beneficial.

The ESRP1-GPR137 axis contributes to intestinal pathogenesis.

Aberrant alternative pre-mRNA splicing (AS) events have been associated with several disorders. However, it is unclear whether deregulated AS directly contributes to disease. Here, we reveal a critical role of the AS regulator epithelial splicing regulator protein 1 (ESRP1) for intestinal homeostasis and pathogenesis. In mice, reduced ESRP1 function leads to impaired intestinal barrier integrity, increased susceptibility to colitis and altered colorectal cancer (CRC) development. Mechanistically, these defects are produced in part by modified expression of ESRP1-specific Gpr137 isoforms differently activating the Wnt pathway. In humans, ESRP1 is downregulated in inflamed biopsies from inflammatory bowel disease patients. ESRP1 loss is an adverse prognostic factor in CRC. Furthermore, generation of ESRP1-dependent GPR137 isoforms is altered in CRC and expression of a specific GPR137 isoform predicts CRC patient survival. These findings indicate a central role of ESRP1-regulated AS for intestinal barrier integrity. Alterations in ESRP1 function or expression contribute to intestinal pathology.

Activation of common signaling pathways during remodeling of the heart and the bladder.

The heart and the urinary bladder are hollow muscular organs, which can be afflicted by pressure overload injury due to pathological conditions such as hypertension and bladder outlet obstruction. This increased outflow resistance induces hypertrophy, marked by dramatic changes in the organs' phenotype and function. The end result in both the heart and the bladder can be acute organ failure due to advanced fibrosis and the subsequent loss of contractility. There is emerging evidence that microRNAs (miRNAs) play an important role in the pathogenesis of heart failure and bladder dysfunction. MiRNAs are endogenous non-coding single-stranded RNAs, which regulate gene expression and control adaptive and maladaptive organ remodeling processes. This Review summarizes the current knowledge of molecular alterations in the heart and the bladder and highlights common signaling pathways and regulatory events. The miRNA expression analysis and experimental target validation done in the heart provide a valuable source of information for investigators working on the bladder and other organs undergoing the process of fibrotic remodeling. Aberrantly expressed miRNA are amendable to pharmacological manipulation, offering an opportunity for development of new therapies for cardiac and bladder hypertrophy and failure.