BACKGROUND: Massive DNA destruction/accumulation of cell-free DNA debris is a sensitive biomarker of progressive organ/tissue damage. Deleterious consequences of DNA debris accumulation are evident in cardiac ischemia, thrombosis, auto-inflammatory diseases, SLE-induced lupus nephritis and cystic fibrosis. In case of renal pathologies, degradation and elimination of DNA debris are suppressed, due to downregulated DNAse-I activity within the diseased kidneys. The aim of the current study was to evaluate whether exogenous DNAse-I administration might exert renoprotective effects in the setting of acute kidney injury (AKI or acute renal failure). METHODS: Sprague-Dawley rats underwent unilateral nephrectomy, with simultaneous clamping of contralateral kidney artery. The treated group received DNAse-I injection before discontinuing anesthesia. Positive (ischemic) controls received saline injection. Negative (non-ischemic) controls were either non-operated or subjected to surgery of similar duress and duration without ischemia. Renal perfusion was evaluated using the Laser-Doppler technique. Blood was procured for evaluating DNAse-I activity, renal functioning, renal perfusion. The kidneys were allocated for histopathologic examinations and for the evaluation of renal hypoxia, intra-renal apoptosis and proliferation. RESULTS: Contrary to the situation in untreated ischemic rats, renal perfusion was significantly improved in DNAse-treated animals, concomitantly with significant amelioration of damage to renal functioning and tissue integrity. Treatment with DNAse-I significantly decreased the ischemia-induced renal hypoxia and apoptosis, simultaneously stimulating renal cell proliferation. Exogenous DNAse-I administration accelerated the clearance of intra-renal apoptotic DNA debris. CONCLUSION: Functional/histologic hallmarks of renal injury were ameliorated, renal functioning improved, intra-renal hypoxia decreased and intra-renal regeneration processes were activated. Thus, DNAse-I treatment protected the kidney from deleterious consequences of ischemia-induced AKI.
BACKGROUND: Massive DNA destruction/accumulation of cell-free DNA debris is a sensitive biomarker of progressive organ/tissue damage. Deleterious consequences of DNA debris accumulation are evident in cardiac ischemia, thrombosis, auto-inflammatory diseases, SLE-induced lupus nephritis and cystic fibrosis. In case of renal pathologies, degradation and elimination of DNA debris are suppressed, due to downregulated DNAse-I activity within the diseased kidneys. The aim of the current study was to evaluate whether exogenous DNAse-I administration might exert renoprotective effects in the setting of acute kidney injury (AKI or acute renal failure). METHODS:Sprague-Dawley rats underwent unilateral nephrectomy, with simultaneous clamping of contralateral kidney artery. The treated group received DNAse-I injection before discontinuing anesthesia. Positive (ischemic) controls received saline injection. Negative (non-ischemic) controls were either non-operated or subjected to surgery of similar duress and duration without ischemia. Renal perfusion was evaluated using the Laser-Doppler technique. Blood was procured for evaluating DNAse-I activity, renal functioning, renal perfusion. The kidneys were allocated for histopathologic examinations and for the evaluation of renal hypoxia, intra-renal apoptosis and proliferation. RESULTS: Contrary to the situation in untreated ischemicrats, renal perfusion was significantly improved in DNAse-treated animals, concomitantly with significant amelioration of damage to renal functioning and tissue integrity. Treatment with DNAse-I significantly decreased the ischemia-induced renal hypoxia and apoptosis, simultaneously stimulating renal cell proliferation. Exogenous DNAse-I administration accelerated the clearance of intra-renal apoptotic DNA debris. CONCLUSION: Functional/histologic hallmarks of renal injury were ameliorated, renal functioning improved, intra-renal hypoxia decreased and intra-renal regeneration processes were activated. Thus, DNAse-I treatment protected the kidney from deleterious consequences of ischemia-induced AKI.
Authors: Wesley M Raup-Konsavage; Yanming Wang; Wei Wei Wang; Denis Feliers; Hong Ruan; W Brian Reeves Journal: Kidney Int Date: 2017-10-20 Impact factor: 10.612
Authors: Fien A von Meijenfeldt; R Todd Stravitz; Jingwen Zhang; Jelle Adelmeijer; Yoh Zen; Valerie Durkalski; William M Lee; Ton Lisman Journal: Hepatology Date: 2021-12-12 Impact factor: 17.298
Authors: Jules H Eustache; Samer Tohme; Simon Milette; Roni F Rayes; Allan Tsung; Jonathan D Spicer Journal: Ann Surg Date: 2020-08 Impact factor: 13.787