Excitotoxicity can occur from substances produced within the body (
endogenous excitotoxins). Glutamate is a prime example of an excitotoxin in the brain, and it is also the major excitatory neurotransmitter in the central nervous system of mammals. During normal conditions, glutamate
concentration can be increased up to 1
mM in the
synaptic cleft, which is rapidly decreased in the lapse of milliseconds. When the glutamate concentration around the synaptic cleft cannot be decreased or reaches higher levels, the neuron kills itself by a process called
apoptosis. This pathologic phenomenon can also occur after
brain injury and
spinal cord injury. Within minutes after spinal cord injury, damaged neural cells within the lesion site spill glutamate into the extracellular space where glutamate can stimulate presynaptic glutamate receptors to enhance the release of additional glutamate.
Brain trauma or
stroke can cause
ischemia, in which
blood flow is reduced to inadequate levels. Ischemia is followed by accumulation of glutamate and
aspartate in the
extracellular fluid, causing cell death, which is aggravated by lack of
oxygen and
glucose. The
biochemical cascade resulting from ischemia and involving excitotoxicity is called the
ischemic cascade. Because of the events resulting from ischemia and glutamate receptor activation, a deep
chemical coma may be induced in patients with brain injury to reduce the metabolic rate of the brain (its need for oxygen and glucose) and save energy to be used to remove glutamate
actively. (The main aim in induced comas is to reduce the
intracranial pressure, not brain
metabolism). Increased extracellular glutamate levels leads to the activation of Ca2+ permeable NMDA receptors on myelin sheaths and
oligodendrocytes, leaving oligodendrocytes susceptible to Ca2+ influxes and subsequent excitotoxicity. One of the damaging results of excess calcium in the cytosol is initiating apoptosis through cleaved
caspase processing. which is suggested to be involved in depression. Inadequate
ATP production resulting from brain trauma can eliminate
electrochemical gradients of certain ions.
Glutamate transporters require the maintenance of these ion gradients to remove glutamate from the extracellular space. The loss of ion gradients results in not only the halting of glutamate uptake, but also in the reversal of the transporters. The Na+-glutamate transporters on neurons and astrocytes can reverse their glutamate transport and start secreting glutamate at a concentration capable of inducing excitotoxicity. This results in a buildup of glutamate and further damaging activation of glutamate receptors. On the
molecular level, calcium influx is not the only factor responsible for apoptosis induced by excitoxicity. Recently, it has been noted that extrasynaptic NMDA receptor activation, triggered by both glutamate exposure or hypoxic/ischemic conditions, activate a
CREB (
cAMP response element binding)
protein shut-off, which in turn caused loss of
mitochondrial membrane potential and apoptosis. On the other hand, activation of synaptic NMDA receptors activated only the CREB
pathway, which activates
BDNF (brain-derived neurotrophic factor), not activating apoptosis.
Exogenous excitotoxins Exogenous excitotoxins refer to neurotoxins that also act at postsynaptic cells but are not normally found in the body. These toxins may enter the body of an organism from the environment through wounds, food intake, aerial dispersion etc. Common excitotoxins include glutamate analogs that mimic the action of glutamate at glutamate receptors, including AMPA and NMDA receptors.
BMAA The L-alanine derivative β-methylamino-L-alanine (
BMAA) has long been identified as a
neurotoxin which was first associated with the
amyotrophic lateral sclerosis/
parkinsonism–
dementia complex (
Lytico-bodig disease) in the
Chamorro people of Guam. The widespread occurrence of BMAA can be attributed to
cyanobacteria which produce BMAA as a result of complex reactions under nitrogen stress. Following research, excitotoxicity appears to be the likely mode of action for BMAA which acts as a
glutamate agonist, activating
AMPA and
NMDA receptors and causing damage to cells even at relatively low concentrations of 10 μM. The subsequent uncontrolled influx of Ca2+ then leads to the pathophysiology described above. Further evidence of the role of BMAA as an excitotoxin is rooted in the ability of NMDA antagonists like MK801 to block the action of BMAA. A considerable portion of the research relating to the toxicity of BMAA has been conducted on
rodents. A study published in 2016 with
green monkeys (Chlorocebus sabaeus) in St. Kitts, which are homozygous for the apoE4 (APOE-ε4) allele (a condition which in humans is a risk factor for Alzheimer's disease), found that orally administered BMAA developed hallmark histopathology features of Alzheimer's Disease including amyloid beta plaques and neurofibrillary tangle accumulation. Subjects in the trial fed smaller doses of BMAA were found to have correlative decreases in these pathology features. This study demonstrates that BMAA, an environmental toxin, can trigger neurodegenerative disease as a result of a gene/environment interaction. While BMAA has been detected in brain tissue of deceased ALS/PDC patients, further insight is required to trace neurodegenerative pathology in humans to BMAA. == See also ==