Susan L. DeMeester scite author profile

Cellular injury induces an adaptive response whether the insult is physical (e.g., heat, radiation), chemical (e.g., reactive oxygen species), infectious (e.g., bacteria), or inflammatory (e.g., lipopolysaccharide). Recent data indicate that the interactions of these responses are not predictable and that sequence permutations can have opposite effects on outcome after injury. Our overarching hypothesis is that interactions among stress responses contribute to the fate of cells, tissues, and organisms and that modulation of these interactions can have important affects on both function and survival. For example, whereas it is well known that a prior heat shock stress can protect cells against inflammatory stress both in vitro and in vivo, we and others have shown that induction of a subsequent heat stress in cells 'primed' by inflammation can precipitate cell death by apoptosis. We call this seemingly paradoxical ability of heat shock to induce cytoprotection and cytotoxicity the heat shock paradox. The molecular mechanisms by which cells integrate responses to these and other stresses are poorly understood. We present data linking the heat shock paradox to the activity of the acute-phase transcription factor nuclear factor kappa B (identifying an 'NF-kappaB paradox') and hypothesize that the mechanism is linked to the downstream effects of induction of NF-kappaB's endogenous inhibitor, IkappaBalpha, a putative heat shock protein.

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Dynamic pelvic magnetic resonance imaging and cystocolpoproctography alter surgical management of pelvic floor disorders

Kaufman¹,

Buller²,

Thompson³

et al. 2001

124

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Heat Shock Induces IκB-α and Prevents Stress-Induced Endothelial Cell Apoptosis

et al. 1997

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Arsenite, an inducer of the heat shock response, decreased stress-induced endothelial cell apoptosis. The mechanism of this protection may include decreased nuclear factor kappa B activity or increased inducible heat shock protein 70 levels. Heat shock protein 70 may serve as a molecular marker to determine not only the phenotypic state of the cell but also the durability of protection afforded by heat shock. These data support the hypothesis that stress-induced changes in transcription factor activity and protein expression can regulate the induction of apoptosis.

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Nitric oxide inhibits stress-induced endothelial cell apoptosis

DeMeester

Qiu

Buchman

et al. 1998

Critical Care Medicine

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