Increased calcium influx secondary to glutamate induced excitotoxicity initiates and potentiates devastating pathological changes following ischemic stroke. Pertussis toxin (PTx), a Gprotein blocker, is known to suppress intracellular calcium accumulation. We hypothesize that PTx can protect against stroke by blocking calcium influx. In a permanent middle cerebral artery occlusion model, PTx (1000 ng) was given intraperitoneally 30 min after inducing stroke. Magnetic Resonance Imaging of perfusion and T2-weighted brain scans were obtained to evaluate cerebral blood flow (CBF) and infarct volume. Primary neuronal culture was used to test glutamate induced excitotoxicity and calcium influx. We established a non-linear exponential curve model to minimize variations in animal cerebrovasculature. A reduction of 40-60% in relative CBF was a critical window where infarct volume started to increase as rCBF reduced. PTx showed maximal effects in reducing infarct volume at this window. In vitro studies further demonstrated PTx increased neuronal cell survival by decreasing glutamate-induced calcium influx into neurons and preventing neurons from apoptosis. PTx salvages the ischemic penumbra by blocking calcium influx. This provides us a new mechanism upon which experimental therapies can be explored to treat ischemic stroke.
We have reported earlier that pertussis toxin (PTx) attenuates the motor deficits in experimental autoimmune encephalomyelitis (EAE), an animal model for human multiple sclerosis. PTx protects neurons from inflammatory insults. Vascular endothelial growth factor (VEGF) is also neuroprotective. However, the effect of PTx on VEGF has never been studied. We investigated whether PTx modulates neuronal VEGF expression and how it affects the pathogenesis of EAE. EAE was induced by injecting myelin oligodendrocyte glycoprotein 35-55 peptides with adjuvants into C57BL/6 mice. Clinical scores of EAE were evaluated daily for 19 days. Brain and spinal cord samples were collected and assessed for inflammation and demyelination. VEGF, NeuN for neurons, and Caspase-3 for apoptosis were stained for localization using immunohistochemistry techniques, followed by western blot analysis for quantification. Primary neurons were cultured to assess the direct effect of PTx on neuronal VEGF expression. PTx treatment increases neuronal VEGF expression by up to ∼75% in vitro and ∼60% in vivo, preventing neurons from apoptosis. This leads to resolution in inflammation and remyelination and amendment in motor deficits. Our findings suggest that upregulation of endogenous neuronal VEGF by PTx protects motor deficits in EAE and it is a potential therapeutic option for multiple sclerosis.
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