Receptor‐mediated control of regulatory volume decrease (RVD) and apoptotic volume decrease (AVD)

Okada, Yasunobu; Maeno, Emi; Shimizu, Takahiro; Dezaki, Katsuya; Wang, Jun; Morishima, Shigeru

doi:10.1111/j.1469-7793.2001.0003g.x

Cited by 492 publications

(476 citation statements)

References 161 publications

(169 reference statements)

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“…msy1 -msy2 -undergoes osmotic stress-induced cell death. Upon hypo-osmotic shock, mammalian cells undergo osmotic stress-induced death, such as necrosis 28 , whereas prokaryotic cells experience cell lysis 6 . Thus, to examine whether the decreased viability of msy2 -cells and msy1 -msy2 -cells is due to osmoticinduced cell death or cell lysis, we performed a time-lapse imaging analysis with cells that express EGFP to monitor cell lysis.…”

Section: Evolutionary Relationship Of Mscs Homologues In Fungimentioning

confidence: 99%

“…0 16 20 21 23 25 32 45 58 71 129 0 16 20 21 23 25 32 45 58 71 129 30 40 50 60 70 80 90 Cell volume regulation has been well studied in mammalian cells. Following hypo-osmotic shock, the cells swell quickly, but soon start recovering their volume near the original level by a mechanism called regulatory volume decrease (RVD) 28 . During this process, cell swelling induces a [Ca 2 + ] i increase that has a regulatory role for ion homoeostasis across the plasma membrane.…”

Section: Msy1 Functions As a Mechanosensitive Channelmentioning

confidence: 99%

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Organellar mechanosensitive channels in fission yeast regulate the hypo-osmotic shock response

2012

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A key molecule of sensing machineries essential for survival upon hypo-osmotic shock is the mechanosensitive channel. The bacterial mechanosensitive channel mscs functions directly for this purpose by releasing cytoplasmic solutes out of the cell, whereas plant mscs homologues are found to function in chloroplast organization. Here we show that the fission yeast mscs homologues, designated msy1 and msy2, participate in the hypo-osmotic shock response by a mechanism different from that operated by the bacterial mscs. upon hypoosmotic shock, msy2 -and msy1 -msy2 -cells display greater cell swelling than wild-type cells and undergo cell death. Cell swelling precedes an intracellular Ca 2 + increase, which was greater in msy1 -and msy1 -msy2 -cells than in wild-type cells. Fluorescent microscopy showed that msy1 and msy2 localize mainly to the endoplasmic reticulum. These observations suggest that organellar msy1 and msy2 regulate intracellular Ca 2 + and cell volume for survival upon hypo-osmotic shock.

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Section: Evolutionary Relationship Of Mscs Homologues In Fungimentioning

confidence: 99%

Section: Msy1 Functions As a Mechanosensitive Channelmentioning

confidence: 99%

Organellar mechanosensitive channels in fission yeast regulate the hypo-osmotic shock response

2012

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“…This can be measured with a spectrophotometer. There are conflicting results on the correlation with platelet viability [3,4], [5].…”

Section: Hypotonic Shock Responsementioning

confidence: 99%

Methods for evaluation of platelet function

Lindahl

Ramström

2009

Transfusion and Apheresis Science

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“…In majority of cell types, cell swelling activates Cl − efflux via the above mentioned VRAC in conjunction with K + loss via SWELLING-ACTIVATED K + CHANNELS. Under physiological conditions these two independent permeability pathways mediate electrically coupled loss of K + and Cl − , which is accompanied by an efflux of osmotically obligated water, and REGULATORY VOLUME DECREASE, or RVD [30,33,34]. However, in pathology, anoxic and/or glutamate-driven depolarization disrupts cell volume regulation due to an inhibition of the Na + ,K + -pump, dissipation of K + and Cl − electrochemical gradients, and blockade of volume regulatory channels [13,21,25,35].…”

Section: Introduction: Overview Of Ischemic Brain Damagementioning

confidence: 99%

“…Uncontrolled cell swelling is frequently associated with necrosis and may be harmful to neuronal and glial cells for multiple reasons [13,30]. The simplest mechanism of cell damage is osmotic lysis.…”

Section: Introduction: Overview Of Ischemic Brain Damagementioning

confidence: 99%

Disruption of ionic and cell volume homeostasis in cerebral ischemia: The perfect storm

Mongin

2007

Pathophysiology

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The mechanisms of brain tissue damage in stroke are strongly linked to the phenomenon of excitotoxicity, which is defined as damage or death of neural cells due to excessive activation of receptors for the excitatory neurotransmitters glutamate and aspartate. Under physiological conditions, ionotropic glutamate receptors mediate the processes of excitatory neurotransmission and synaptic plasticity. In ischemia, sustained pathological release of glutamate from neurons and glial cells causes prolonged activation of these receptors, resulting in massive depolarization and cytoplasmic Ca 2+ overload. The NMDA subtype of glutamate receptors is particularly important as it represents the main initial route for the Ca 2+ influx. High cytoplasmic levels of Ca 2+ activate many degradative processes that, depending on the metabolic status, cause immediate or delayed death of neural cells. This traditional view has been expanded by a number of observations that implicate Cl − channels and several types of non-channel transporter proteins, such as the Na + ,K + ,2Cl − cotransporter, Na + /H + exchanger, and Na + /Ca 2+ exchanger, in the development of glutamate toxicity. Some of these ion transporters increase tissue damage by promoting pathological cell swelling and necrotic cell death, while others contribute to a long term accumulation of cytoplasmic Ca 2+ . This brief review is aimed at illustrating how the dysregulation of various ion transport processes combine in a 'perfect storm' that disrupts neural ionic homeostasis and culminates in the irreversible damage and death of neural cells. The clinical relevance of individual transporters as targets for therapeutic intervention in stroke is also briefly discussed.

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Receptor‐mediated control of regulatory volume decrease (RVD) and apoptotic volume decrease (AVD)

Cited by 492 publications

References 161 publications

Organellar mechanosensitive channels in fission yeast regulate the hypo-osmotic shock response

Organellar mechanosensitive channels in fission yeast regulate the hypo-osmotic shock response

Methods for evaluation of platelet function

Disruption of ionic and cell volume homeostasis in cerebral ischemia: The perfect storm

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