Although the inhibition of Cl? channels while inhibiting AVD, does not usually reduce activation of caspases

Although the inhibition of Cl? channels while inhibiting AVD, does not usually reduce activation of caspases. 9 Different inducers of apoptosis trigger both accumulation of intracellular Na+ and loss of intracellular K+2, 7, 10, 11, 12, 13 and these events are associated with PMP depolarization.2 It has been also shown that this reduction in the intracellular [K+] and PMP depolarization are a late event since involve inhibition of Na+/K+ pump by caspase-mediated degradation of its (cyt release in both HeLa and neuroblastoma cells (SK-N-BE(2)) is not inhibited by avoiding reduction of [K+]i.16 Actually, it appears that high intracellular K+ protects against apoptosis by inhibiting the apoptosome assembly.13, 16, 18 Apparently, the procaspase-3 activity is inhibited by high [K+] because its activity decrease to 50% in [K+] above 25?mM K, in contrast mature caspase-3 activity is unaltered by reducing [K+].18 Recently, it has been suggested that this apoptosome assembly is regulated by ion strength more than a direct effect of K+ release (Supplementary Determine 3). channels activated by STS are not responsible for the reduction in the [K+]i associated with apoptosis. Pamidronate Disodium release, apoptosis Cell transformations associated with apoptosis result from the biochemical action of an execution program, whose main characteristic is usually activation of caspases.1 Different inducers of apoptosis trigger plasma membrane potential (PMP) depolarization2 while the inhibition of apoptosis by Bcl-2 and Mcl-1 is associated with PMP hyperporlarization.3, 4 It has been shown that ion fluxes, particularly K+ efflux, have a key role in apoptosis. The activation of both K+5, 6 and Cl? channels is necessary for apoptotic volume decrease (AVD) Rabbit polyclonal to Complement C3 beta chain or cell shrinkage and also for activation of caspases.7, 8 It has been shown that, before AVD, there is an initial movement of monovalent ions. Although the inhibition of Cl? channels while inhibiting AVD, does not usually reduce activation of caspases.9 Different inducers Pamidronate Disodium of apoptosis induce both accumulation of intracellular Na+ and loss of intracellular K+2, 7, 10, 11, 12, 13 and these events are associated with PMP depolarization.2 It has been also shown that this reduction in the intracellular [K+] and PMP depolarization are a late event since involve inhibition of Na+/K+ pump by caspase-mediated degradation of its (cyt release in both HeLa and neuroblastoma cells (SK-N-BE(2)) is not inhibited by avoiding reduction of [K+]i.16 Actually, it appears that high intracellular K+ protects against apoptosis by inhibiting the apoptosome assembly.13, 16, 18 Apparently, the procaspase-3 activity is inhibited by Pamidronate Disodium high [K+] because its activity decrease to 50% in [K+] above 25?mM K, in contrast mature caspase-3 activity is unaltered by reducing [K+].18 Recently, it has been suggested that this apoptosome assembly is regulated by ion strength more than a direct effect of K+ release (Supplementary Determine 3). STS-induced caspase-3 activation was much larger when compared with other apoptosis inducers, such as H2O2 and thapsigargin (not shown). Under our assay conditions (cells were in serum-free culture medium for 24?h) both caspase-9 and caspase-8 displayed a larger Pamidronate Disodium basal activity than caspase-3 when compared with the corresponding maximal response obtained with STS. Interestingly, STS induced a significant activation of caspase-8, the main effector of the extrinsic pathway in apoptosis. Caspase-8 can be activated by caspase-3 (Tang was released to the cytoplasm in response to STS by a mechanism that does not involve the activation of caspases (Physique 3a). We also studied the role of external [K+] on STS-induced cyt release by incubating cells in either 70 or 140?K solutions (Physique 3b). The addition of STS to cells in 70?K solution did not inhibit cyt release (Physique 3c). However, STS-induced cyt release was significantly reduced when cells were incubated in 140?K solution (Figures 3b and c). Preincubation of HeLa cells with the combination of ion channel inhibitors for 30?min reduced STS-induced cyt release (Physique 4a). This effect was only significant for K+ channels inhibitors alone or in combination with FA (Physique 4b). FA alone did not have any effect on STS-induced cyt release. These data suggest that only K+ channels have a role, still a limited one, in the STS-induced cyt release. Open in a separate window Physique 3 High external [K+] reduces STS-induced cyt release. (a) Incubation of cells with either 10 or 50?release (release by western blot assay and using was high because of the absence of serum for 24?h (see Supplementary Physique 1). However, the STS-induced cyt release was significantly reduced only by 140?K (release. (a) The presence of cyt in the cytosol was detected by western blot assay. The optical density ratio (cyt release, but the combination of K+ channel inhibitors (T+4) reduced significantly the STS-induced cyt release, while the addition of FA did not increase any further the inhibitory effect of the combination of K+ channel inhibitors (for the assembly of the apoptosome, which in turn activates caspase-9. Open in.