Dominant role of mitochondria in protection against a delayed neuronal Ca<sup>2+</sup> overload induced by endogenous excitatory amino acids following a glutamate pulse

Bi, Khodorov; Pinelis, V. G.; Storozhevykh, T. P.; Vergun, O; Vinskaya, N.

doi:10.1016/0014-5793(96)00873-3

Cited by 49 publications

(27 citation statements)

References 12 publications

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“…However, it is at present unclear which processes may be participating in this Ca¥ transport. Several previous studies have documented the role of mitochondria in buffering depolarization-or glutamateinduced [Ca¥]é changes in neurones (Thayer & Miller, 1990;Werth & Thayer, 1994;White & Reynolds, 1995;Kiedrowski & Costa, 1995;Wang & Thayer, 1996;Khodorov et al 1996). However, these previous studies have not explicitly documented the role of mitochondria in kainateinduced [Ca¥]é changes.…”

Section: Discussionmentioning

confidence: 99%

“…Previous studies that have focused on NMDA receptor-mediated Ca¥ loads have suggested that Ca¥ uptake by mitochondria is an important mechanism for buffering [Ca¥]é changes, and that mitochondria become progressively more important as the intensity of the stimulus increases (White & Reynolds, 1995, 1997Wang & Thayer, 1996;Khodorov, Pinelis, Storozhevykh, Vergun & Vinskaya, 1996). It has also become evident that mitochondrial Ca¥ loading shapes the recovery from increases in [Ca¥]é because the time necessary for [Ca¥]é to return to baseline following NMDA receptor activation is dominated by the Ca¥ release from the mitochondrial pool that is mediated by mitochondrial Na¤-Ca¥ exchange (Nicholls & Akerman, 1982;Kiedrowski & Costa, 1995;Wang & Thayer, 1996;White & Reynolds, 1997).…”

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confidence: 99%

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The role of intracellular Na⁺ and mitochondria in buffering of kainate‐induced intracellular free Ca²⁺ changes in rat forebrain neurones

Hoyt

Stout

Cardman

et al. 1998

The Journal of Physiology

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We have examined the mechanisms by which cultured central neurones from embryonic rat brain buffer intracellular Ca2+ loads following kainate receptor activation using fluorescent indicators of [Ca2+]i and [Na+]i. Stimulation of cultured forebrain neurones with 100 μm kainate produced a rapid increase in [Ca2+]i that displayed a variable rate of recovery. Kainate also increased [Na+]i with a response that was slightly slower in onset and markedly slower in recovery. The recovery of [Ca2+]i to baseline was not very sensitive to the [Na+]i. The magnitude of the increase in [Na+]i in response to kainate did not correlate well with the [Ca2+]i recovery time, and experimental manipulations that altered [Na+]i did not have a large impact on the rate of recovery of [Ca2+]i. The recovery of [Ca2+]i to baseline was accelerated by the mitochondrial Na+‐Ca2+ exchange inhibitor CGP‐37157, suggesting that the recovery rate is influenced by release of Ca2+ from a mitochondrial pool and also that variation in the recovery rate is related to the extent of mitochondrial Ca2+ loading. Kainate did not alter the mitochondrial membrane potential. These studies reveal that mitochondria have a central role in buffering neuronal [Ca2+]i changes mediated by non‐N‐methyl‐D‐aspartate (NMDA) glutamate receptors, and that the variation in recovery times following kainate receptor activation reflects a variable degree of mitochondrial Ca2+ loading. However, unlike NMDA receptor‐mediated Ca2+ loads, kainate receptor activation has minimal effects on mitochondrial function.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

The role of intracellular Na⁺ and mitochondria in buffering of kainate‐induced intracellular free Ca²⁺ changes in rat forebrain neurones

Hoyt

Stout

Cardman

et al. 1998

The Journal of Physiology

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“…Neuronal survival is intimately linked to mitochondrial homeostasis. Mitochondria supply the central nervous system with energy (ATP), as well as regulating calcium within the cell (Khodorov et al, 1996). Several therapeutic interventions that target stabilizing mitochondria have shown promising results by reducing overall neuronal tissue damage as well as enhancing neurological outcome following TBI (Verweij et al, 1997;Sullivan et al, 1999;Sullivan et al, 2004;Hino et al, 2005;Xiong et al, 2005;Clark et al, 2007).…”

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confidence: 99%

Early Mitochondrial Dysfunction after Cortical Contusion Injury

Gilmer

Roberts

Joy³

et al. 2009

Journal of Neurotrauma

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Following traumatic brain injury, mitochondria sustain structural and functional impairment, which contributes to secondary damage that can continue for days after the initial injury. The present study investigated mitochondrial bioenergetic changes in the rat neocortex at 1 and 3 h after mild, moderate, and severe injuries. Brains from young adult Sprague-Dawley rats were harvested from the injured and contralateral cortex to assess possible changes in mitochondrial respiration abilities following a unilateral cortical contusion injury. Differential centrifugation was used to isolate synaptic and extrasynaptic mitochondria from cortical tissue. Bioenergetics was assessed using a Clark-type electrode and results were graphed as a function of injury severity and time postinjury. Respiration was significantly affected by all injury severity levels compared to uninjured tissue. Complex 1-and complex 2-driven respirations were affected proportionally to the severity of the injury, indicating that damage to mitochondria may occur on a gradient. Total oxygen utilization, respiratory control ratio, ATP production, and maximal respiration capabilities were all significantly decreased in the injured cortex at both 1 and 3 h post-trauma. Although mitochondria displayed bioenergetic deficits at 1 h following injury, damage was not exacerbated by 3 h. This study stresses the importance of early therapeutic intervention and suggests a window of approximately 1-3 h before greater dysfunction occurs.

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“…Thus, mitochondrial membrane potential can be regarded as a factor contributing to intracellular Ca 2+ reg ulation in neurons, which definitely occurs during activa tion of Glu receptors. Khodorov et al [26] showed that antimycin, an inhibitor of the 3rd complex of the electron transport chain, combined with the inhibitor of ATP syn thase, oligomycin, significantly inhibits Ca 2+ uptake into mitochondria. The latest data show that Ca 2+ uptake into mitochondria depends on the degree of their association with cytoskeleton.…”

Section: Toxic Action Of Glutamate Causes Accumulation Of Calcium In mentioning

confidence: 99%

Role of Mitochondria in the Mechanisms of Glutamate Toxicity

Isaev

Andreeva

Stel'mashuk

et al. 2005

Biochemistry (Moscow)

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Current data on glutamate-induced functional and morphological changes in mitochondria correlating with or being a result of their membrane potential changes are reviewed. The important role of Ca2+, Na+, and H+ in the potentiation of such changes is considered. It is assumed that glutamate-induced loss of mitochondrial potential is mediated by Ca2+ overload resulting in the induction of nonspecific permeability of the inner mitochondrial membrane.

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Dominant role of mitochondria in protection against a delayed neuronal Ca²⁺ overload induced by endogenous excitatory amino acids following a glutamate pulse

Cited by 49 publications

References 12 publications

The role of intracellular Na⁺ and mitochondria in buffering of kainate‐induced intracellular free Ca²⁺ changes in rat forebrain neurones

The role of intracellular Na⁺ and mitochondria in buffering of kainate‐induced intracellular free Ca²⁺ changes in rat forebrain neurones

Early Mitochondrial Dysfunction after Cortical Contusion Injury

Role of Mitochondria in the Mechanisms of Glutamate Toxicity

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Dominant role of mitochondria in protection against a delayed neuronal Ca2+ overload induced by endogenous excitatory amino acids following a glutamate pulse

Cited by 49 publications

References 12 publications

The role of intracellular Na+ and mitochondria in buffering of kainate‐induced intracellular free Ca2+ changes in rat forebrain neurones

The role of intracellular Na+ and mitochondria in buffering of kainate‐induced intracellular free Ca2+ changes in rat forebrain neurones

Early Mitochondrial Dysfunction after Cortical Contusion Injury

Role of Mitochondria in the Mechanisms of Glutamate Toxicity

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Dominant role of mitochondria in protection against a delayed neuronal Ca²⁺ overload induced by endogenous excitatory amino acids following a glutamate pulse

The role of intracellular Na⁺ and mitochondria in buffering of kainate‐induced intracellular free Ca²⁺ changes in rat forebrain neurones

The role of intracellular Na⁺ and mitochondria in buffering of kainate‐induced intracellular free Ca²⁺ changes in rat forebrain neurones