Phosphodiesterase 6 generates intracellular cGMP microdomains in the native endothelium

Endothelial cells (EC) are essential regulator of vascular homeostasis through the generation and release of various bioactive agents, including nitric oxide (NO). NO modulates several vascular functions such as vascular tone and permeability, through the stimulation of soluble guanylate cyclase (sGC) leading to the production of cGMP. Conversely, phosphodiesterases (PDEs) are enzymes metabolizing cyclic nucleotides (cGMP and cAMP) and are therefore major regulatory players for cGMP and cAMP signalling pathways. Although ECs are the main source of NO, little is known on the endothelial NO-cGMP signalling pathway and cellular outcomes. It was then hypothesized that a specific population of cGMP-phosphodiesterases allows ECs to stabilize cGMP levels despite the elevated production of NO. Expression of cGMP-phosphodiesterases was initially studied in resistance mesenteric arteries from mice. PDE5 and PDE6 were both found at mRNA and protein levels in native arteries but PDE6 is not found in cultured ECs. Interestingly, subcellular distributions of both enzymes were distinct. PDE5 appeared to be homogeneously distributed whilst PDE6 catalytic subunits (PDE6 and PDE6) showed a preferential staining in the perinuclear region. These results suggest that PDE6 might be involved in the regulation of cGMP microdomains. Based on these findings, a mathematical model was developed. Simulations of dynamic cGMP levels in ECs support the notion of cGMP microdomains dependent on PDE6 expression and localization. In the absence of PDE6, application of NO either as a single bolus or repetitive pulses led to a homogeneous increase in cGMP levels in ECs despite PDE5 homogeneous distribution. However, PDE6 subcellular targeting to the perinuclear membrane generated a cGMP-depleted perinuclear space. The findings from this study provide the first evidence of the expression and specific intracellular distribution of PDE6 in native endothelial cells that strongly support their involvement in the generation of cGMP microdomains

Phosphodiesterase 6 generates intracellular cGMP microdomains in the native endothelium

Endothelial cells (EC) are essential regulator of vascular homeostasis through the generation and release of various bioactive agents, including nitric oxide (NO). NO modulates several vascular functions such as vascular tone and permeability, through the stimulation of soluble guanylate cyclase (sGC) leading to the production of cGMP. Conversely, phosphodiesterases (PDEs) are enzymes metabolizing cyclic nucleotides (cGMP and cAMP) and are therefore major regulatory players for cGMP and cAMP signalling pathways. Although ECs are the main source of NO, little is known on the endothelial NO-cGMP signalling pathway and cellular outcomes. It was then hypothesized that a specific population of cGMP-phosphodiesterases allows ECs to stabilize cGMP levels despite the elevated production of NO. Expression of cGMP-phosphodiesterases was initially studied in resistance mesenteric arteries from mice. PDE5 and PDE6 were both found at mRNA and protein levels in native arteries but PDE6 is not found in cultured ECs. Interestingly, subcellular distributions of both enzymes were distinct. PDE5 appeared to be homogeneously distributed whilst PDE6 catalytic subunits (PDE6 and PDE6) showed a preferential staining in the perinuclear region. These results suggest that PDE6 might be involved in the regulation of cGMP microdomains. Based on these findings, a mathematical model was developed. Simulations of dynamic cGMP levels in ECs support the notion of cGMP microdomains dependent on PDE6 expression and localization. In the absence of PDE6, application of NO either as a single bolus or repetitive pulses led to a homogeneous increase in cGMP levels in ECs despite PDE5 homogeneous distribution. However, PDE6 subcellular targeting to the perinuclear membrane generated a cGMP-depleted perinuclear space. The findings from this study provide the first evidence of the expression and specific intracellular distribution of PDE6 in native endothelial cells that strongly support their involvement in the generation of cGMP microdomains

Diclofenaco comparado con ibuprofeno para el cierre de Ductus arterioso persistente, en recién nacidos prematuros

Introducción: El Ductus arterioso persistente (DAP), es uno de los defectos congénitos cardiacos más comunes, requiere manejo farmacológico y/o quirúrgico; presenta complicaciones hemodinámicas, respiratorias y muerte. Los medicamentos de elección para su manejo son indometacina e ibuprofeno, pero su costo y accesibilidad llevo al uso de diclofenaco como alternativa de manejo en algunos hospitales. Objetivo: Comparar respuesta al tratamiento con diclofenaco vs ibuprofeno en cierre de DAP. Materiales y Métodos: Estudio observacional analítico retrospectivo, que compara los resultados obtenidos al usar Diclofenaco e Ibuprofeno para el cierre del DAP en recién nacidos pretérmino. Se recolecto información de pacientes hospitalizados en la Unidad Neonatal de un Hospital II nivel de Bogotá. Se revisaron las historias clínicas de pacientes de edad gestacional entre 24 y 36 semanas por Ballard con los criterios para diagnóstico de DAP y recibieron tratamiento farmacológico con una de las siguientes opciones: Ibuprofeno 10 mg/Kg dosis inicial después 5mg/Kg a las 24 48 horas, o Diclofenaco 0.2 mg/Kg dosis cada 12 horas tres dosis. Se comparó el Diclofenaco y el Ibuprofeno para el tratamiento farmacológico de DAP en recién nacidos prematuros. Resultados: Fueron evaluados 103 pacientes, el diagnóstico de DAP se realizó con ecocardiograma transtorácico, el 66.6 % de los pacientes presentó cierre farmacológico con Diclofenaco y 69 % con Ibuprofeno, La mortalidad fue de 17.65 % con Diclofenaco y 11.54 % con ibuprofeno; en ambos casos asociadas a la prematurez. Conclusiones: El éxito farmacológico fue similar en ambos grupos, el diclofenaco es una alternativa interesante cuando la terapia convencional no esté disponible.