BACKGROUND: Diabetes impairs the ability of tissue to respond adequately to ischemia. The underlying mechanisms contributing to this impaired response remain unknown. Because increases in apoptosis have been linked to a spectrum of diabetic complications, the authors examined whether programmed cell death is involved in the pathogenesis of poor diabetic tissue responses to ischemia. METHODS: Analysis for apoptosis and levels of proaptotic protein, p53, were performed on streptozocin-induced diabetic mice and wild-type controls in a murine model of soft-tissue ischemia (n = 6). In vitro, chronic hyperglycemic culture conditions were used to test inducibility and reversibility of the diabetic phenotype. Small interfering RNA was used to assess the role of p53. RESULTS: Ischemia-induced apoptosis and p53 levels were increased significantly in diabetic dermal fibroblasts both in vivo and in vitro. Chronic hyperglycemic culture was sufficient to induce the increased apoptotic phenotype, and this was not reversible with long-term normoglycemic conditions. Blocking p53 with small interfering RNA resulted in significant protection against ischemic apoptosis. CONCLUSIONS: These findings suggest that diabetes causes an increased apoptotic response to ischemia through a p53-mediated mechanism. This increase is not reversible by exposure to low-glucose conditions. This suggests that glycemic control alone will be unable to prevent tissue necrosis in diabetic patients and suggests novel therapeutic strategies for this condition.
BACKGROUND:Diabetes impairs the ability of tissue to respond adequately to ischemia. The underlying mechanisms contributing to this impaired response remain unknown. Because increases in apoptosis have been linked to a spectrum of diabetic complications, the authors examined whether programmed cell death is involved in the pathogenesis of poor diabetic tissue responses to ischemia. METHODS: Analysis for apoptosis and levels of proaptotic protein, p53, were performed on streptozocin-induced diabeticmice and wild-type controls in a murine model of soft-tissue ischemia (n = 6). In vitro, chronic hyperglycemic culture conditions were used to test inducibility and reversibility of the diabetic phenotype. Small interfering RNA was used to assess the role of p53. RESULTS:Ischemia-induced apoptosis and p53 levels were increased significantly in diabetic dermal fibroblasts both in vivo and in vitro. Chronic hyperglycemic culture was sufficient to induce the increased apoptotic phenotype, and this was not reversible with long-term normoglycemic conditions. Blocking p53 with small interfering RNA resulted in significant protection against ischemic apoptosis. CONCLUSIONS: These findings suggest that diabetes causes an increased apoptotic response to ischemia through a p53-mediated mechanism. This increase is not reversible by exposure to low-glucose conditions. This suggests that glycemic control alone will be unable to prevent tissue necrosis in diabeticpatients and suggests novel therapeutic strategies for this condition.
Authors: Phuong D Nguyen; John Paul Tutela; Vishal D Thanik; Denis Knobel; Robert J Allen; Christopher C Chang; Jamie P Levine; Stephen M Warren; Pierre B Saadeh Journal: Wound Repair Regen Date: 2010-10-18 Impact factor: 3.617
Authors: Elizabeth Yohannes; Jinsook Chang; Moses T Tar; Kelvin P Davies; Mark R Chance Journal: Mol Cell Proteomics Date: 2009-12-10 Impact factor: 5.911
Authors: Shiva Roshankhah; Ahmad Shabanizadeh; Amir Abdolmaleki; Mohammad Reza Gholami; Mohammad Reza Salahshoor Journal: J Diabetes Metab Disord Date: 2020-08-15
Authors: Glenn D Hoke; Corrine Ramos; Nicholas N Hoke; Mary C Crossland; Lisa G Shawler; Joseph V Boykin Journal: J Diabetes Res Date: 2016-10-20 Impact factor: 4.011