Necrotic volume increase and the early physiology of necrosis

L. F. Barros; T. Hermosilla; J. Castro

doi:10.1016/S1095-6433(01)00438-X

Necrotic volume increase and the early physiology of necrosis

L. F. Barros, T. Hermosilla, J. Castro

Research output: Contribution to journal › Review article › peer-review

121 Citations (Scopus)

Abstract

Whether a lethally injured mammalian cell undergoes necrosis or apoptosis may be determined by the early activation of specific ion channels at the cell surface. Apoptosis requires K⁺ and Cl^- efflux, which leads to cell shrinking, an active phenomenon termed apoptotic volume decrease (AVD). In contrast, necrosis has been shown to require Na⁺ influx through membrane carriers and more recently through stress-activated non-selective cation channels (NSCCs). These ubiquitous channels are kept dormant in viable cells but become activated upon exposure to free-radicals. The ensuing Na⁺ influx leads to cell swelling, an active response that may be termed necrotic volume increase (NVI). This review focuses on how AVD and NVI become conflicting forces at the beginning of cell injury, on the events that determine irreversibility and in particular, on the ion fluxes that decide whether a cell is to die by necrosis or by apoptosis.

Original language	English
Pages (from-to)	401-409
Number of pages	9
Journal	Comparative Biochemistry and Physiology - A Molecular and Integrative Physiology
Volume	130
Issue number	3
DOIs	https://doi.org/10.1016/S1095-6433(01)00438-X
Publication status	Published - 1 Oct 2001
Externally published	Yes

Keywords

Apoptosis
Cell death
Cell volume regulation
Membrane channels
Necrosis

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T1 - Necrotic volume increase and the early physiology of necrosis

AU - Barros, L. F.

AU - Hermosilla, T.

AU - Castro, J.

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N2 - Whether a lethally injured mammalian cell undergoes necrosis or apoptosis may be determined by the early activation of specific ion channels at the cell surface. Apoptosis requires K+ and Cl- efflux, which leads to cell shrinking, an active phenomenon termed apoptotic volume decrease (AVD). In contrast, necrosis has been shown to require Na+ influx through membrane carriers and more recently through stress-activated non-selective cation channels (NSCCs). These ubiquitous channels are kept dormant in viable cells but become activated upon exposure to free-radicals. The ensuing Na+ influx leads to cell swelling, an active response that may be termed necrotic volume increase (NVI). This review focuses on how AVD and NVI become conflicting forces at the beginning of cell injury, on the events that determine irreversibility and in particular, on the ion fluxes that decide whether a cell is to die by necrosis or by apoptosis.

AB - Whether a lethally injured mammalian cell undergoes necrosis or apoptosis may be determined by the early activation of specific ion channels at the cell surface. Apoptosis requires K+ and Cl- efflux, which leads to cell shrinking, an active phenomenon termed apoptotic volume decrease (AVD). In contrast, necrosis has been shown to require Na+ influx through membrane carriers and more recently through stress-activated non-selective cation channels (NSCCs). These ubiquitous channels are kept dormant in viable cells but become activated upon exposure to free-radicals. The ensuing Na+ influx leads to cell swelling, an active response that may be termed necrotic volume increase (NVI). This review focuses on how AVD and NVI become conflicting forces at the beginning of cell injury, on the events that determine irreversibility and in particular, on the ion fluxes that decide whether a cell is to die by necrosis or by apoptosis.

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KW - Cell volume regulation

KW - Membrane channels

KW - Necrosis

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Necrotic volume increase and the early physiology of necrosis

Abstract

Keywords

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