Alteration of Renal Natriuretic Systems Is Associated with the Development of Hypertension and Precedes the Presence of Renal Damage in a Model of Metabolic Syndrome / La alteración de sistemas natriuréticos renales se asocia con el desarrollo de hipertensión arterial y precede en el tiempo a la aparición de daño renal en un modelo de síndrome metabólico

ABSTRACT: Background: The aim of this study was to determine the presence of alterations in the natriuretic systems of atrial natriuretic peptide and renal dopamine in a model of metabolic syndrome induced by fructose overload and to associate them with changes in systolic blood pressure, renal function, Na+/K+-ATPase status and microalbuminuria. Methods: Male Sprague-Dawley rats were divided into control (C) and fructose (F) groups receiving drinking water or a fructose so-lution (10% W/V), respectively, for 4, 8 and 12 weeks. L-dopa and dopamine, sodium, creatinine and albumin were measured in urine and ANP, insulin, sodium and creatinine in plasma. Systolic blood pressure was measured by indirect method and the renal activity and expression of Na+/K+-ATPase as well as the renal expression of A- and C-type natriuretic peptide receptors were assessed. results: Fructose overload was associated with a significant increase in insulinemia and systolic blood pressure levels and a decrease in urinary sodium excretion since week 4. A significant increase in L-dopa excretion and a decrease in dopamine excretion (increased urinary L-dopa/dopamine ratio) due to fructose overload were observed since week 4 with a decrease in plasma atrial natriuretic peptide at weeks 8 and 12. These changes were accompanied by increased activity and expression of Na+/ K+-ATPase, decreased A-type natriuretic peptide receptor and increased C-type natriuretic peptide receptor expression. Microalbuminuria was observed at week 12 of fructose overload.

RESUMEN: Objetivos: El objetivo del trabajo consistió en determinar la existencia de alteraciones en los sistemas natriuréticos del péptido natriurético atrial y dopamina renal en un modelo de síndrome metabólico por sobrecarga de fructosa y asociarlas con cambios en la presión arterial sistólica, función renal, estado de la Na+, K+-ATPasa y microalbuminuria. Material y Métodos: Ratas macho Sprague-Dawley fueron divididas en grupos control (C) y fructosa (F) con agua o solución de F (10%P/V) para beber durante 4, 8 y 12 semanas. En orina, se midió L-dopa y dopamina, sodio, creatinina y albúmina; y en plasma péptido natriurético atrial, insulina, sodio y creatinina. La presión arterial sistólica fue medida por método indirecto. Se midió la actividad y expresión de la Na+, K+-ATPasa así como la expresión del receptor de péptidos natriuréticos A y C renales. resultados: La sobrecarga de fructosa se asoció con el aumento de la insulinemia y la presión arterial sistólica, y con la disminución en la excreción urinaria de sodio desde la semana 4. La excreción urinaria de L-dopa se incrementó y la de dopamina disminuyó (cociente L-dopa/dopamina incrementado) por sobrecarga de fructosa desde la semana 4 y el péptido natriurético atrial plasmático se redujo en las semanas 8 y 12. Estos cambios fueron acompañados por un incremento de la actividad y expresión de la Na+, K+-ATPasa, disminución del receptor de péptidos natriuréticos A y aumento del C. La microalbuminuria se observó en la semana 12 de sobrecarga de fructosa. Conclusiones: Las alteraciones del péptido natriurético atrial y de la dopamina renal se asociaron con el desarrollo de hipertensión arterial y precedieron a la aparición de microalbuminuria, por lo que se pudo establecer una asociación temporal entre la alteración de ambos sistemas y el desarrollo de daño renal.

Synthesis and Biological Evaluation of New N-(4-Substituted phenyl)glycine Derivatives as Potential Anti-inflammatory Agents.

BACKGROUND: Designing new anti-inflammatory agents possessing safe therapeutic profiles and devoid of potential undesirable side effects is an active field in medicinal chemistry. Thus, a series of N-(4-substituted phenyl)glycine derivatives was designed and synthesized. The idea behind the design is to utilize the bifunctionality of 4-aminoacetophenone via converting the amino group into glycine derivative as a side arm to mimic the glycine amino acid enhancing the overall physicochemical and biological characteristics. In addition, the opposite acetyl group was used as a center for modification and derivatization. METHODS: The starting N-(4-acetylphenyl)glycine was converted into two intermediates: the chalcone analog 2 and the thiosemicarbazone derivative 8. Both 2 and 8 were derivatized and/or cyclized into different heterocyclic target derivatives (3-7 and 9-12). The target compounds were screened for anti-inflammatory activity using carrageenan-induced rat paw edema assay. RESULTS: The results showed that compounds 6, 7, and 3, were the most active among the tested compounds at 50 mg/kg dose level with % inhibition of edema of 51.82, 43.80, and 40.39, respectively. CONCLUSION: The authors succeeded to introduce a simple and versatile skeleton with a side arm resembling the glycine amino acid; imparting a potential improvement in physicochemical properties. We utilize the other side of the skeleton's aromatic ring as a center for derivatization. The chalcone analog and its cyclized heterocyclic derivatives were of remarkably higher anti-inflammatory activity than the thiosemicarbazone and its derivatives.