Phosphodiesterases in the Liver as Potential Therapeutic Targets of Cirrhotic Portal Hypertension.
Wolfgang KreiselDenise SchaffnerAdhara LazaroJonel TrebickaIrmgard MerfortAnnette Schmitt-GraeffPeter DeibertPublished in: International journal of molecular sciences (2020)
Liver cirrhosis is a frequent condition with high impact on patients' life expectancy and health care systems. Cirrhotic portal hypertension (PH) gradually develops with deteriorating liver function and can lead to life-threatening complications. Other than an increase in intrahepatic flow resistance due to morphological remodeling of the organ, a functional dysregulation of the sinusoids, the smallest functional units of liver vasculature, plays a pivotal role. Vascular tone is primarily regulated by the nitric oxide-cyclic guanosine monophosphate (NO-cGMP) pathway, wherein soluble guanylate cyclase (sGC) and phosphodiesterase-5 (PDE-5) are key enzymes. Recent data showed characteristic alterations in the expression of these regulatory enzymes or metabolite levels in liver cirrhosis. Additionally, a disturbed zonation of the components of this pathway along the sinusoids was detected. This review describes current knowledge of the pathophysiology of PH with focus on the enzymes regulating cGMP availability, i.e., sGC and PDE-5. The results have primarily been obtained in animal models of liver cirrhosis. However, clinical and histochemical data suggest that the new biochemical model we propose can be applied to human liver cirrhosis. The role of PDE-5 as potential target for medical therapy of PH is discussed.
Keyphrases
- nitric oxide
- healthcare
- blood pressure
- end stage renal disease
- electronic health record
- endothelial cells
- newly diagnosed
- ejection fraction
- chronic kidney disease
- poor prognosis
- big data
- hydrogen peroxide
- nitric oxide synthase
- protein kinase
- peritoneal dialysis
- risk factors
- transcription factor
- prognostic factors
- patient reported outcomes
- risk assessment
- data analysis
- human health
- social media
- stem cells
- climate change
- health information