The release of proteins from the intermembrane space of mitochondria is one of the pivotal events in the apoptotic process, which can lead to the activation of caspases and the ultimate demise of the cell. How these proteins exit the mitochondria is still a matter of intense debate. Here, we discuss the possible mechanisms behind the release of apoptogenic proteins, the ways in which cancer cells subvert these mechanisms, and the therapeutic regimens that aim to promote the timely loss of integrity of the outer mitochondrial membrane.
The mechanisms by which the progression of eukaryotic replication forks is controlled after DNA damage are unclear. We have found that fork progression is slowed by cisplatin or UV treatment in intact vertebrate cells and in replication assays in vitro. Fork slowing is reduced or absent in irs1SF CHO cells and XRCC3(-/-) chicken DT40 cells, indicating that fork slowing is an active process that requires the homologous recombination protein XRCC3. The addition of purified human Rad51C-XRCC3 complex restores fork slowing in permeabilized XRCC3(-/-) cells. Moreover, the requirement for XRCC3 for fork slowing can be circumvented by addition of human Rad51. These data demonstrate that the recombination proteins XRCC3 and Rad51 cooperatively modulate the progression of replication forks on damaged vertebrate chromosomes.
Didanosine (2',3'-dideoxyinosine; ddI) requires intracellular metabolism to its active triphosphate, 2',3'-dideoxyadenosine 5'-triphosphate (ddATP), to inhibit the replication of human immunodeficiency virus (HIV). We have investigated the metabolism of ddI to ddATP in the presence and absence of a range of compounds. In addition, we determined the levels of the endogenous competitor of ddATP, 2'-deoxyadenosine 5'-triphosphate (dATP), and calculated ddATP/dATP ratios. None of the nucleoside analogs studied had any effect on ddI phosphorylation at 1 and 10 microM concentrations. At 100 microM concentrations, ddC reduced total ddA phosphates (82% of control total ddA phosphates; p < 0.001). ZDV significantly decreased the levels of dATP, whereas ddC significantly increased dATP pools (e.g., at 100 microM ZDV, 82% of control dATP levels; p < 0.001). Hence, the ddATP/dATP ratio was increased in the presence of ZDV, but was decreased in the presence of ddC. Neither d4T nor 3TC affected the ddATP/dATP ratio. Deoxyinosine (dI) significantly reduced ddA phosphate production at 100 microM concentrations, with ddATP reduced to undetectable levels (p < 0.001). Hydroxyurea (HU) did not affect the activation of ddI, but significantly reduced dATP pools at 100 microM concentrations (67% of control dATP levels; p < 0.001), enhancing the ddATP/dATP ratio. ddA phosphate production was significantly reduced by pentoxyfylline (PXF) at 10 and 100 microM concentrations. dATP levels were unaffected, but the ddATP/dATP ratio was reduced. Finally, 8-aminoguanosine (8-AMG) had no effect on either ddI activation or dATP pools. These studies demonstrate the importance of determining both the active TP and the competing endogenous TP, as changes to the resulting ratio could alter the efficacy of the nucleoside analog in question.
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