BACKGROUND: Renal fibrosis, a common complication of hypertension and diabetes is considered as a non-curable disease and is characterized by the abnormal accumulation of collagen I within the kidney. Chronic inhibition of nitric oxide (NO) synthesis is a model of hypertension associated with the development of nephroangiosclerosis. The present study investigated whether halt of NO inhibition leads to the regression of renal sclerotic lesions. METHODS: The NO deficiency (N(G)-nitro-L-arginine methylester; L-NAME) model of hypertension was applied in transgenic mice harbouring the luciferase reporter gene under the control of the collagen I-alpha2 chain promoter. RESULTS: Systolic pressure gradually increased following the administration of L-NAME, and reached 160 mmHg after 8-10 weeks. Activation of collagen I gene within the renal vasculature preceded the blood pressure increase and was accompanied by the appearance of sclerotic glomeruli and tubulointerstitial infiltration. After renal lesions had been established (20 weeks), animals were divided in three subgroups for an additional experimental period of 10 weeks: first group continued to receive L-NAME, in the second, L-NAME administration was stopped to allow endogenous NO synthesis and in the third the removal of L-NAME was combined with endothelin receptor antagonism. Removal of L-NAME decreased, without normalizing, systolic pressure and collagen I gene activity; renal morphology was substantially improved, and tubulointerstitial infiltration disappeared. Combination of L-NAME removal with endothelin antagonism normalized collagen I gene expression and further improved renal morphology without further decreasing blood pressure. CONCLUSION: Manipulating the balance between NO/vasoconstrictors in favour of NO could provide a curative approach against renal inflammatory and fibrotic complications associated to hypertension.
BACKGROUND:Renal fibrosis, a common complication of hypertension and diabetes is considered as a non-curable disease and is characterized by the abnormal accumulation of collagen I within the kidney. Chronic inhibition of nitric oxide (NO) synthesis is a model of hypertension associated with the development of nephroangiosclerosis. The present study investigated whether halt of NO inhibition leads to the regression of renal sclerotic lesions. METHODS: The NO deficiency (N(G)-nitro-L-arginine methylester; L-NAME) model of hypertension was applied in transgenic mice harbouring the luciferase reporter gene under the control of the collagen I-alpha2 chain promoter. RESULTS: Systolic pressure gradually increased following the administration of L-NAME, and reached 160 mmHg after 8-10 weeks. Activation of collagen I gene within the renal vasculature preceded the blood pressure increase and was accompanied by the appearance of sclerotic glomeruli and tubulointerstitial infiltration. After renal lesions had been established (20 weeks), animals were divided in three subgroups for an additional experimental period of 10 weeks: first group continued to receive L-NAME, in the second, L-NAME administration was stopped to allow endogenous NO synthesis and in the third the removal of L-NAME was combined with endothelin receptor antagonism. Removal of L-NAME decreased, without normalizing, systolic pressure and collagen I gene activity; renal morphology was substantially improved, and tubulointerstitial infiltration disappeared. Combination of L-NAME removal with endothelin antagonism normalized collagen I gene expression and further improved renal morphology without further decreasing blood pressure. CONCLUSION: Manipulating the balance between NO/vasoconstrictors in favour of NO could provide a curative approach against renal inflammatory and fibrotic complications associated to hypertension.
Authors: Maritza J Romero; Lin Yao; Supriya Sridhar; Anil Bhatta; Huijuan Dou; Ganesan Ramesh; Michael W Brands; David M Pollock; Ruth B Caldwell; Stephen D Cederbaum; C Alvin Head; Zsolt Bagi; Rudolf Lucas; Robert W Caldwell Journal: Front Immunol Date: 2013-12-24 Impact factor: 7.561