OAR@UM Collection:/library/oar/handle/123456789/322262025-12-23T04:33:50Z2025-12-23T04:33:50ZAspirin-induced apoptosis in yeast/library/oar/handle/123456789/322642020-11-23T16:05:04Z2007-01-01T00:00:00ZTitle: Aspirin-induced apoptosis in yeast
Abstract: In this study, the effect of aspirin on yeast cells with differential protection against
reactive oxygen species (ROS), as obtained with wild-type, manganese superoxide
dismutase (MnSOD)-deficient and copper, zinc superoxide dismutase (CuZnSOD)deficient
Saccharomyces cerevisiae cells was investigated, when grown on fermentable
and non-fermentable carbon sources. Aspirin was found to induce apoptosis in MnSODdeficient
cells cultivated in ethanol medium, whereas the CuZnSOD-deficient and wildtype
yeast strains remained viable. The deleterious effect of aspirin on MnSOD-deficient
cells in ethanol medium, was not reversed by the antioxidants N-acetylcysteine and
vitamin E, or by the SOD mimetics, TEMPO and TEMPOL. Furthermore, aspirin itself
appeared to act as an antioxidant in these cells, until the onset of overt apoptosis, when a
moderate increase in the intracellular oxidation level occurred.
The reducing power, as measured by the NADPHlNADP+ concentration ratio in the
MnSOD-deficient cells cultivated in ethanol medium was significantly lower than in
wild-type cells. In the presence of aspirin, an early shift in the redox balance in MnSOD-deficient cells was detected, due to depletion of NADPH and NADP+, which led to a
dramatic drop in the GSH/GSSG ratio. Aspirin did not inhibit glucose-6-phosphate
dehydrogenase activity in the MnSOD-deficient cells, and the apoptotic effect of aspirin
does not seem to involve enzyme acetylation. However, catalase activity decreased
significantly with aspirin, possibly due to decreased protection of the enzyme by
NADPH. The decreased reducing power as observed in MnSOD-deficient cells in
ethanol medium, may be linked to apoptotic induction by aspirin, independently of the
level of ROS. The protective effect of MnSOD, exerted in the isogenic wild-type cells,
appears to be related to the cellular reducing power, which is essential for sustaining
growth.
Aspirin caused a significant drop in the intracellular pH (PHi) in the MnSOD-deficient
cells, growing in ethanol medium. This finding suggests that pHi plays a role in the
apoptotic process, however, it does not seem to be the initial trigger committing these
cells to aspirin-induced apoptosis. No decrease in the pHi of wild-type cells was detected
on treatment with aspirin, indicating that the MnSOD-deficient cells were unable to
maintain a homeostatic cytosolic pH.
Mitochondria were found to play an important role in aspirin-induced apoptosis in
MnSOD-deficient cells cultivated in ethanol medium. Aspirin triggered an initial release
of mitochondrial cytochrome c, and after 96 h of cultivation, most of the mitochondrial
cytochrome c was detected in the cytosol. This correlated with a dramatic drop in the
∆Ѱm, which decreased to nearly half that of untreated control cells. Mitochondrial mass
in the MnSOD-deficient cells was unaltered on treatment with aspirin, even after
cytochrome c release from mitochondria. Hence, mitochondrial mass did not influence
the data obtained on the ∆Ѱm of aspirin-treated and untreated cells, using Rhodamine
123. These findings indicate that loss of ∆Ѱm is not required for aspirin induced release
of cytochrome c. Indeed, the initial release of cytochrome c occurred prior to the
disruption of the ∆Ѱm. It may thus be possible that cytochrome c release does not
involve the early onset of the mitochondrial permeability transition but only an alteration
of the permeability of the outer mitochondrial membrane.
Description: PH.D.2007-01-01T00:00:00ZRNA profiling and the genetics of myocardial infarction/library/oar/handle/123456789/316582020-11-19T14:43:39Z2007-01-01T00:00:00ZTitle: RNA profiling and the genetics of myocardial infarction
Abstract: Notwithstanding our increase in knowledge on the events that lead to
atherosclerosis and myocardial infarction, the literature on the genetic determinants
of these related diseases is ridden with conflicting results. In this study a novel
RNA profiling technique was applied in a case-control setting including 524 men
with a history of myocardial infarction and 628 control subjects. The relationship
between a selection of polymorphisms, RNA expression and other intermediate
phenotypes, and disease outcome was investigated. Patients had higher levels of
inflammatory molecules and Toll-like receptors (TLRs) than controls. Macrophage
migration inhibitory factor (MlF) and the intracellular regulator proteinase inhibitor
9 (PI9) gave the highest odds ratios for myocardial infarction. Analysis of genetic
data with the RNA data revealed that DNA changes in inflammation-related genes
can influence several disease-related intermediate phenotypes. The underlying
levels of expression of genes of related function were shown to have considerable
impact on the effect of a particular gene on disease outcome. The overall effect of
polymorphisms on risk outcome tended to be small, but additive, and was
frequently modified by smoking. Aberrant RNA profiles acted as sentinels for
particularly deleterious or protective outcomes. Bioinformatics tools were applied
to detect a new MlF splice variant and to determine different roles of alternative
transcripts of TLR4. To date, this is the largest RNA profiling study on myocardial
infarction. This innovative approach highlights a degree of complexity in the
expression and regulation of inflammatory molecules that needs to be accounted for
to improve our understanding of the mechanism of genetic risk in atherosclerosis
and myocardial infarction.
Description: PH.D.PHYSIOLOGY2007-01-01T00:00:00Z