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Query: UMLS:C0022116 (
ischemia
)
91,303
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The experiments strongly suggested that the reason why Purkinje cells die so easily after global brain
ischemia
relates to deficiencies in aldolase C and
EAAT4
that allow them to survive pathologically intense synaptic input from the inferior olive after the restoration of blood flow. This conclusion is based on: (a) the remarkably tight correspondence between the regional absence of aldolase C and
EAAT4
in Purkinje cells and the patterned loss of Purkinje cells after a bout of global brain
ischemia
; (b) the necessity of the olivocerebellar pathway for the ischemic death of Purkinje cells; and (c) the build-up of pathologically synchronous and high-frequency burst activity within the inferior olive during recovery from
ischemia
. Indeed, the correspondence between the absence of aldolase C and
EAAT4
to sensitivity to
ischemia
could be demonstrated for zones of Purkinje cells as small as two neurons. A second finding was that Purkinje cells are not uniformly sensitive to transient
ischemia
, since they die most frequently in zones where aldolase C and
EAAT4
are absent. One implication of the experiment is that factors beyond the unique synaptic and membrane properties of Purkinje cells play an important role in determining this neuron's high sensitivity to
ischemia
. The data strongly imply that two properties of Purkinje cells that make them susceptible to ischemic death are their reduced capability to sequester glutamate and reduced ability to generate energy during anoxia. The patterned death of Purkinje cells is sufficient to induce a form of audiogenic myoclonus, as determined with a neurotoxic dose of ibogaine. Ibogaine-induced myoclonus is recognized behaviorally as a reduced ability to habituate to a startle stimulus and resembles the myoclonic jerk of rats during recovery from a prolonged bout of global brain
ischemia
. Commonalities of
ischemia
and ibogaine-induced neurodegeneration are the intricately striped Purkinje cell loss in the posterior lobe and a nearly complete deafferentation of the lateral aspect of the fastigial nucleus from the cerebellar cortex, in particular the dorsolateral protuberance. Thus, the data point strongly to a cerebellar contribution to audiogenic myoclonus. Single-neuron electrophysiology experiments in monkeys have demonstrated that the evoked activity in the deep cerebellar nuclei occurs too late to initiate the startle response (60) and electromyography of the postischemic myoclonus of rats corroborates this view (see Chapter 31) (20). However, the nearly complete loss of GABAergic terminals in the dorsolateral protuberance after Purkinje cell death would be expected to dramatically increase its tonic firing and the background excitation of the brain-stem structures that it innervates. The fastigial nucleus innervates a large number of autonomic and motor structures in the brainstem and diencephalon, including the ventrolateral nucleus of the thalamus and the gigantocellular reticular nucleus in the medulla--structures that have been implicated in human posthypoxic myoclonus (6, 7). We propose that the posthypoxic myoclonic jerk of rats is, at least in part, due to disinhibition of the fastigial nucleus produced by patterned Purkinje cell death in the vermis. The argument is as follows: the loss of GABAergic inhibition in the fastigial nucleus after
ischemia
leads to diaschisis of the motor thalamus and reticular formation which, in turn, is responsible for enhanced motor excitability and myoclonus. That the audiogenic myoclonus after global brain
ischemia
in the rat gradually resolves over a period of 2 to 3 weeks is consistent with this view, as restoration of background excitability after CNS damage in rats has been documented to occur within this time-frame (61). Our view brings together the physiologic finding that posthypoxic myoclonus appears to originate in the sensory-motor cortices and/or reticular formation with the consistent anatomical finding of Purkinje cell loss after
ischemia
, and explains the puzzle of Marsden's unique cases of myoclonus associated with coeliac disease (1). Moreover, our argument is consistent with findings both in rats (62, 63) and humans (64) that damage to the vermis impairs the long-term habituation of the startle reflex. It remains to be determined whether the pathologically enhanced startle responses after vermal damage resemble brain-stem reticular or cortical myoclonus at the electrophysiologic level of analysis. What is the purpose of the regional expression of aldolase C and
EAAT4
in Purkinje cells? The close correspondence between the spatial distribution of aldolase C and the parasagittal anatomy of the cerebellum (48) has led to the view that aldolase C may help specify connectivity during development. While the present experiments do not address this issue, they underscore the fact that aldolase plays a fundamental role in metabolism. Because Purkinje cells have a repressed expression of aldolase A (31), whatever role the absence of aldolase C may play during development comes at the price of metabolic frailty later in adulthood. From another point of view, aldolase C and
EAAT4
appear to confer upon Purkinje cells the ability to survive their own climbing fiber. Indeed, climbing fibers form a distributed synapse that synchronously releases glutamate (or aspartate) at all levels of the dendritic tree simultaneously (65, 66). Such synchronous activation triggers calcium influx throughout the Purkinje cell dendrites at a magnitude that is unparalleled in the nervous system (12), and, thus, places an extraordinarily high metabolic demand on the Purkinje cell. The apparently reduced level of aldolase in a subpopulation of Purkinje cells provides the condition for energy failure and death during anoxia so long as the climbing fibers are intact or when climbing fiber activation is pharmacologically enhanced under normoxic conditions, such as after ibogaine (53-56). Lastly, the argument that diaschisis produced by patterned cerebellar degeneration leads to thalamo-cortical and reticular hyperexcitability agrees with C. David Marsden and his colleagues' bold demonstration of an inhibitory influence of cerebellar cortex on motor cortex in humans (67). Our anatomic data indicate that the spatially distinct zones of Purkinje cells, which are killed by global brain
ischemia
, may be the origin of such inhibition.
...
PMID:Why do Purkinje cells die so easily after global brain ischemia? Aldolase C, EAAT4, and the cerebellar contribution to posthypoxic myoclonus. 1196 59
The solute carrier family 1 (SLC1) includes five high-affinity glutamate transporters, EAAC1, GLT-1, GLAST,
EAAT4
and EAAT5 (SLC1A1, SLC1A2, SLC1A3, SLC1A6, and SLC1A7, respectively) as well as the two neutral amino acid transporters, ASCT1 and ASCT2 (SLC1A4 and ALC1A5, respectively). Although each of these transporters have similar predicted structures, they exhibit distinct functional properties which are variations of a common transport mechanism. The high-affinity glutamate transporters mediate transport of l-Glu, l-Asp and d-Asp, accompanied by the cotransport of 3 Na(+) and 1 H(+), and the countertransport of 1 K(+), whereas ASC transporters mediate Na(+)-dependent exchange of small neutral amino acids such as Ala, Ser, Cys and Thr. The unique coupling of the glutamate transporters allows uphill transport of glutamate into cells against a concentration gradient. This feature plays a crucial role in protecting neurons against glutamate excitotoxicity in the central nervous system. During pathological conditions, such as brain
ischemia
(e.g. after a stroke), however, glutamate exit can occur due to "reversed glutamate transport", which is caused by a reversal of the electrochemical gradients of the coupling ions. Selective inhibition of the neuronal glutamate transporter EAAC1 (SLC1A1) may be of therapeutic interest to block glutamate release from neurons during
ischemia
. On the other hand, upregulation of the glial glutamate transporter GLT1 (SLC1A2) may help protect motor neurons in patients with amyotrophic lateral sclerosis (ALS), since loss of function of GLT1 has been associated with the pathogenesis of certain forms of ALS.
...
PMID:The glutamate/neutral amino acid transporter family SLC1: molecular, physiological and pharmacological aspects. 1453 Sep 74
The serum and glucocorticoid inducible kinase (SGK) 1 is expressed in brain tissue and upregulated by
ischemia
, neuronal excitation, and dehydration. The present study has been performed to elucidate the expression of SGK1 in cerebellar Purkinje cells and to explore whether it influences the colocalized glutamate transporter
EAAT4
. Intense SGK1 staining was observed in Purkinje cells following 48h of water deprivation. The kinase activates glutamate induced current (I(GLU)) in Xenopus oocytes heterologously expressing
EAAT4
, an effect mimicked by its isoforms SGK2, 3 and PKB. I(GLU) was decreased by the ubiquitin ligase Nedd4-2, an effect partially but not completely reversed by additional coexpression of the SGK kinase isoforms or PKB. According to immunohistochemistry
EAAT4
protein abundance in the cell membrane was enhanced by SGK1 and decreased by Nedd4-2. In conclusion, SGK1 expression is upregulated by
ischemia
, excitation, and dehydration in cerebellar Purkinje cells. The upregulation of SGK1 may serve to stimulate
EAAT4
and thus to reduce neuroexcitotoxicity.
...
PMID:Stimulation of the EAAT4 glutamate transporter by SGK protein kinase isoforms and PKB. 1550 48
Cerebellar Purkinje cells represent a group of neurons highly vulnerable to
ischemia
. Excitotoxicity is thought to be an important pathophysiological mechanism in Purkinje cell death following
ischemia
. The glutamate transporter is the only mechanism for the removal of glutamate from the extracellular fluid in the brain. Therefore, glutamate transporters are believed to play a critical role in protecting Purkinje cells from
ischemia
-induced damage. Two distinct glutamate transporters, GLAST and
EAAT4
, are expressed most abundantly in the cerebellar cortex. GLAST is expressed in Bergmann glia, whereas
EAAT4
is concentrated in the perisynaptic regions of Purkinje cell spines. However, the in vivo functional significance of these glial and neuronal glutamate transporters in postischemic Purkinje cell death is largely unknown. To clarify the role of these glutamate transporters in the protection of Purkinje cells after global brain
ischemia
, we evaluated Purkinje cell loss after cardiac arrest in mice lacking GLAST or
EAAT4
. We found that Purkinje cells with low
EAAT4
expression were selectively lost after cardiac arrest in GLAST mutant mice. This result demonstrates that GLAST plays a role in preventing excitotoxic cerebellar damage after
ischemia
in concert with
EAAT4
.
...
PMID:Glutamate transporters GLAST and EAAT4 regulate postischemic Purkinje cell death: an in vivo study using a cardiac arrest model in mice lacking GLAST or EAAT4. 1664 73
The glutamate transporters EAAT3 and
EAAT4
are expressed in neurons. They contribute to the cellular uptake of glutamate and aspartate and thus to the clearance of the excitatory transmitters from the extracellular space. During
ischemia
, extracellular accumulation of glutamate may trigger excitotoxicity. Energy depletion leads to activation of the AMP-activated protein kinase (AMPK), a kinase enhancing energy production and limiting energy expenditure. The present study thus explored the possibility that AMPK regulates EAAT3 and/or
EAAT4
. To this end, EAAT3 or
EAAT4
were expressed in Xenopus oocytes with or without AMPK and electrogenic glutamate transport determined by dual electrode voltage clamp. In EAAT3- and in
EAAT4
-expressing oocytes glutamate generated a current (I(g)), which was half maximal (K(M)) at 74 microM (EAAT3) or at 4 microM (
EAAT4
) glutamate. Co-expression of constitutively active (gammaR70Q)AMPK or of wild type AMPK did not affect K(M) but significantly decreased the maximal I(g) in both EAAT3- (by 34%) and
EAAT4
- (by 49%) expressing oocytes. Co-expression of the inactive mutant (alphaK45R)AMPK [alpha1(K45R)beta1gamma1] did not appreciably affect I(g). According to confocal microscopy and chemiluminescence co-expression of (gammaR70Q)AMPK or of wild type AMPK reduced the membrane abundance of EAAT3 and
EAAT4
. The observations show that AMPK down-regulates Na(+)-coupled glutamate transport.
...
PMID:Down-regulation of Na+-coupled glutamate transporter EAAT3 and EAAT4 by AMP-activated protein kinase. 2021 75
The solute carrier family 1 (SLC1) consists of two neutral amino acid transporters and five high-affinity excitatory amino acid transporters (EAAT1-5). EAATs are expressed in glial cells (EAAT1/GLAST and EAAT2/GLT-1), neurons (EAAT3/EAAC1 and
EAAT4
), and the retina (EAAT5), where they precisely regulate extracellular glutamate levels at both synaptic and extrasynaptic sites. EAATs play essential roles in the maintenance of normal excitatory synaptic transmission, protection of neurons from the excitotoxic action of excessive glutamate, and regulation of glutamatemediated neuroplasticity. Therefore, dysfunction of EAATs can cause abnormal excitatory synaptic transmission, neuronal excitotoxicity, and the exaggeration of neuroplasticity-based events. EAAT dysfunction has been implicated in a variety of neurodegenerative and neurological diseases, including amyotrophic lateral sclerosis, Parkinson's disease, Alzheimer's disease,
ischemia
, and epilepsy. Recent evidence suggests that abnormalities of EAATs contribute to the pathogenesis of psychiatric diseases and pathological pain. The present review will briefly discuss novel findings on the roles of EAATs in the pathogenesis of psychiatric diseases such as schizophrenia, mood disorders, and drug dependence/ addiction, and pathological pain, as well as the potential of EAATs as therapeutic targets.
...
PMID:SLC1 glutamate transporters and diseases: psychiatric diseases and pathological pain. 2387 50
Janus kinase-3 (JAK3), a tyrosine kinase, is expressed in a variety of tissues, including the brain and is involved in the signaling of cytokine receptors. JAK3 participates in numerous functions, such as cell survival and proliferation, neuroprotection, apoptosis and the cellular response to hypoxia and
ischemia
-reperfusion. This kinase further contributes to the signaling of hematopoietic cell cytokine receptors, activation of dendritic cells, maturation, and immune suppression as well as to cell volume regulation. Recently, JAK3 has been demonstrated to be an important regulator of transport processes across the plasma membrane. Either directly or indirectly JAK3 affects the expression of transport proteins, including various ion channels, a number of cellular carriers and the Na+/K+ pump. More specifically, JAK3 is involved in the regulation of various potassium, sodium, and chloride ion channels, a wide variety of Na+-coupled cellular carriers including the high-affinity Na+ coupled glucose transporter SGLT1, the excitatory amino acid transporters EAAT1, EAAT2, EAAT3 and
EAAT4
, the peptide transporters PepT1 and PepT2, CreaT1 and theNa+/K+-ATPase. Via these transporters this kinase plays a role in various physiological and pathophysiological processes. Additional research is needed to investigate the effects of JAK3 on other cellular transporters and the underlying mechanisms.
...
PMID:Regulation of Ion Channels, Cellular Carriers and Na(+)/K(+)/ATPase by Janus Kinase 3. 2816 62
