Neuron-Specific Inactivation of the Hypoxia Inducible Factor 1  Increases Brain Injury in a Mouse Model of Transient Focal Cerebral Ischemia

Baranova, Oxana V.; Miranda, Luís Felipe José Ravic de; Pichiule, Paola; Dragatsis, Ioannis; Johnson, Randall S.; Chávez, Juan C.

doi:10.1523/jneurosci.0449-07.2007

Cited by 324 publications

(356 citation statements)

References 55 publications

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“…27 When ischemia was applied for a longer time frame (90 minutes), however, the infarct damage was maximal within 24 hours after stroke. 27 More typically, a delayed increase in stroke volume is much more subtle or absent in rodent models 13,28,29 ; however, a notable increase in infarct growth may be observed when neuroprotective mechanisms are impaired in the brain, an illustration of the tenuous nature of cell viability in the penumbra. 28,29 Factors such as the presence of edema, peri-infarct depolarizations, 30 -32 inflammatory changes, [33][34][35] or the amount of collateral blood flow likely determine the fate of the penumbra.…”

Section: An Introduction To the Adaptive And Pathological Roles Of Asmentioning

confidence: 99%

“…In addition, expression and release of neuroprotective or harmful substances in response to ischemia are also likely determinants of cell death. 13,29,35 Given that astrocytes modulate blood flow, contribute to water homeostasis, participate in inflammatory responses, maintain ion homeostasis, and release a number of substances that may be either neuroprotective or harmful, they undoubtedly contribute to determining the viability of this vulnerable tissue.…”

Section: An Introduction To the Adaptive And Pathological Roles Of Asmentioning

confidence: 99%

“…Loss of activity of the transcription factor hypoxia-inducible factor-1 (HIF-1) specifically in neurons enhances infarct growth 24 -96 hours after stroke onset. 29 HIF-1 is expressed at low levels when oxygen availability is not limited, but its protein abundance is markedly induced during hypoxia. Once stabilized, HIF-1 translocates to the nucleus and induces a large number of targets that increase adaptive responses, such as glycolytic enzymes, neuroprotectants (erythropoietin [EPO] and adrenomedullin), and factors that encourage angiogenesis (vascular endothelial growth factor [VEGF]).…”

Section: An Introduction To the Adaptive And Pathological Roles Of Asmentioning

confidence: 99%

“…Once stabilized, HIF-1 translocates to the nucleus and induces a large number of targets that increase adaptive responses, such as glycolytic enzymes, neuroprotectants (erythropoietin [EPO] and adrenomedullin), and factors that encourage angiogenesis (vascular endothelial growth factor [VEGF]). 29,38 Thus, at least in neurons, HIF-1 has an adaptive function that impedes growth of stroke volume during this delayed time frame. In neuronastrocyte cocultures, however, HIF-1 activity in astrocytes has the opposite effect on neuronal viability.…”

Section: An Introduction To the Adaptive And Pathological Roles Of Asmentioning

confidence: 99%

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Targeting Astrocytes for Stroke Therapy

2010

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Summary: Stroke remains a major health problem and is a leading cause of death and disability. Past research and neurotherapeutic clinical trials have targeted the molecular mechanisms of neuronal cell death during stroke, but this approach has uniformly failed to reduce stroke-induced damage or to improve functional recovery. Beyond the intrinsic molecular mechanisms inducing neuronal death during ischemia, survival and function of astrocytes is absolutely required for neuronal survival and for functional recovery after stroke. Many functions of astrocytes likely improve neuronal viability during stroke. For example, uptake of glutamate and release of neurotrophins enhances neuronal viability during ischemia. Under certain conditions, however, astrocyte function may compromise neuronal viability. For example, astrocytes may produce inflammatory cytokines or toxic mediators, or may release glutamate. The only clinical neurotherapeutic trial for stroke that specifically targeted astrocyte function focused on reducing release of S-100␤ from astrocytes, which becomes a neurotoxin when present at high levels. Recent work also suggests that astrocytes, beyond their influence on cell survival, also contribute to angiogenesis, neuronal plasticity, and functional recovery in the several days to weeks after stroke. If these delayed functions of astrocytes could be targeted for enhancing stroke recovery, it could contribute importantly to improving stroke recovery. This review focuses on both the positive and the negative influences of astrocytes during stroke, especially as they may be targeted for translation to human trials.

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Section: An Introduction To the Adaptive And Pathological Roles Of Asmentioning

confidence: 99%

Section: An Introduction To the Adaptive And Pathological Roles Of Asmentioning

confidence: 99%

Section: An Introduction To the Adaptive And Pathological Roles Of Asmentioning

confidence: 99%

Section: An Introduction To the Adaptive And Pathological Roles Of Asmentioning

confidence: 99%

See 2 more Smart Citations

Targeting Astrocytes for Stroke Therapy

2010

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“…Expression can be further limited to specific cells in a given region by combining lentivirus and cre-lox systems or by altering the promoter of the shRNA [72,73]. For example, by injecting a virus with shRNA containing a premature stop codon that is floxed into Cre-CaMKIIα mice, a neuron specific knockdown can be achieved [74].…”

Section: Alternative Approaches For the Generation Of Rodent Models Omentioning

confidence: 99%

Alternative Approaches to Modeling Hereditary Dystonias

Fremont

Khodakhah

2012

Neurotherapeutics

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The role of ferroptosis as a regulator of oxidative stress in the pathogenesis of ischemic stroke

Delgado‐Martín,

Martínez‐Ruiz

2024

FEBS Letters

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Ferroptosis is a unique form of cell death that was first described in 2012 and plays a significant role in various diseases, including neurodegenerative conditions. It depends on a dysregulation of cellular iron metabolism, which increases free, redox‐active, iron that can trigger Fenton reactions, generating hydroxyl radicals that damage cells through oxidative stress and lipid peroxidation. Lipid peroxides, resulting mainly from unsaturated fatty acids, damage cells by disrupting membrane integrity and propagating cell death signals. Moreover, lipid peroxide degradation products can further affect cellular components such as DNA, proteins, and amines. In ischemic stroke, where blood flow to the brain is restricted, there is increased iron absorption, oxidative stress, and compromised blood–brain barrier integrity. Imbalances in iron‐transport and ‐storage proteins increase lipid oxidation and contribute to neuronal damage, thus pointing to the possibility of brain cells, especially neurons, dying from ferroptosis. Here, we review the evidence showing a role of ferroptosis in ischemic stroke, both in recent studies directly assessing this type of cell death, as well as in previous studies showing evidence that can now be revisited with our new knowledge on ferroptosis mechanisms. We also review the efforts made to target ferroptosis in ischemic stroke as a possible treatment to mitigate cellular damage and death.

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Neuron-Specific Inactivation of the Hypoxia Inducible Factor 1 Increases Brain Injury in a Mouse Model of Transient Focal Cerebral Ischemia

Cited by 324 publications

References 55 publications

Targeting Astrocytes for Stroke Therapy

Targeting Astrocytes for Stroke Therapy

Alternative Approaches to Modeling Hereditary Dystonias

The role of ferroptosis as a regulator of oxidative stress in the pathogenesis of ischemic stroke

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