Mitochondrial Ca2+/Na+ exchange in cardiac protection against ischemia/reperfusion...
Cyclosporin in renal protection through strength of plasma NGAL and cystatin EC NG...
Involvement of energy metabolism and oxidative stress in cell death
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Author(s): |
Héberty di Tarso Fernandes Facundo
Total Authors: 1
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Document type: | Doctoral Thesis |
Press: | São Paulo. |
Institution: | Universidade de São Paulo (USP). Conjunto das Químicas (IQ e FCF) (CQ/DBDCQ) |
Defense date: | 2007-03-22 |
Examining board members: |
Alícia Juliana Kowaltowski;
Etelvino José Henriques Bechara;
Kleber Gomes Franchini;
Lino Manuel Martins Gonçalves;
Marisa Helena Gennari de Medeiros
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Advisor: | Alicia Juliana Kowaltowski |
Abstract | |
Ischemia followed by reperfusion results in impairment of cellular and mitochondrial functionality due to opening of mitochondrial permeability transition (MPT) pores. Nevertheless, preconditioning rescues cells from ischemic damage. Mitochondrial ATP-sensitive K+ channel (mitoKATP) opening also prevents cardiac ischemic cell death. Here we show the signaling mechanisms that activate mitoKATP during preconditioning, the redox role of these channels and consequent protective mechanisms. Using cardiac HL-1 cells, we found that increases in reactive oxygen species (ROS) observed during preconditioning were not inhibited by mitoKATP antagonists, although these drugs significantly avoided the protection afforded by preconditioning, suggesting their activation occurrs upstream of channel activity. Consistent with this, catalase addition to perfused rat hearts and HL-1 cells reversed the beneficial effects of preconditioning, but not of diazoxide (a mitoKATP agonist). On the other hand, 2-mercaptopropionylglycine prevented cardioprotection in both cases, suggesting this compound may present effects other than scavenging ROS. Indeed, thiol reducing agents impaired diazoxide-mediated activation of mitoKATP in isolated rat heart mitochondria. We found that endogenous or exogenous ROS strongly enhanced mitoKATP activity, suggesting that moderate increments in ROS release during preconditioning may activate mitoKATP. Furthermore, mitoKATP prevented conditions (Ca2+ uptake and ROS formation) that favor the opening of MPT pores under ischemic conditions. MitoKATP opening decreased ROS generation physiologically and during both ischemia and reperfusion, consequently avoiding cellular damage. This prevention does not involve an increase in oxidant removal systems. On the other hand, the inhibition of MPT, using cyclosporin A, prevented oxidative stress only during simulated reperfusion, but protected cells in a manner indistinguishable from mitoKATP opening. Collectively, our results suggest that mitoKATP acts as a ROS sensor that decreases mitochondrial ROS generation in response to enhanced local levels of oxidants. As a result, these channels regulate mitochondrial redox state under physiological conditions and prevent oxidative stress under pathological conditions, inhibiting MPT opening and ischemic cardiac damage. (AU) |