Urokinase-type plasminogen activator receptor modulates epileptogenesis in mouse model of temporal lobe epilepsy.

Mutation in Plaur gene encoding urokinase-type plasminogen activator receptor (uPAR) results in epilepsy and autistic phenotype in mice. In humans, a single nucleotide polymorphism in PLAUR gene represents a risk for autism spectrum disorders. Importantly, the expression of uPAR is elevated in the brain after various epileptogenic insults like traumatic brain injury and status epilepticus. So far, the consequences of altered uPAR expression on brain networks are poorly known. We tested a hypothesis that uPAR regulates post-injury neuronal reorganization and consequent functional outcome, particularly epileptogenesis. Epileptogenesis was induced by intrahippocampal injection of kainate in adult male wild type (Wt) or uPAR knockout (uPAR-/-) mice, and animals were monitored with continuous (24/7) video-electroencephalogram for 30 days. The severity of status epilepticus did not differ between the genotypes. The spontaneous electrographic seizures which developed were, however, longer and their behavioral manifestations were more severe in uPAR-/- than Wt mice. The more severe epilepsy phenotype in uPAR-/- mice was associated with delayed but augmented inflammatory response and more severe neurodegeneration in the hippocampus. Also, the distribution of newly born cells in the dentate gyrus was more scattered, and the recovery of hippocampal blood vessel length from status epilepticus-induced damage was compromised in uPAR-/- mice as compared to Wt mice. Our data demonstrate that a deficiency in uPAR represents a mechanisms which results in the development of a more severe epilepsy phenotype and progressive brain pathology after status epilepticus. We suggest that uPAR represents a rational target for disease-modifying treatments after epileptogenic brain insults.

Endothelin receptors A and B are expressed in distinct cellular compartments of rat hippocampus following global ischemia: an immunocytochemical study.

OBJECTIVES: The syntheses of endothelin receptors A and B were previously shown to be upregulated in rat dorsal hippocampus after traumatic brain injury. Here we characterize endothelin receptor A and endothelin receptor B cellular distribution in hippocampus after permanent global brain ischemia and their possible association to nerve cell injury. METHODS: Twenty-minute global ischemia was induced using the Pulsinelli's four-vessel occlusion in conjunction with systemic hypovolemia in male rats. Endothelin receptor A and endothelin receptor B immunoreactivities from sham-operated and ischemic rats were assessed qualitatively in dentate gyrus, Cornu Ammonis, and hilus regions of the hippocampus. Quantitative immunoreactivity measurements were also obtained by optical densitometry. RESULTS: In sham-operated control hippocampus, endothelin receptor A immunoreactivity was absent in nerve cell bodies but strongly expressed in the mossy fiber pathway (axons of dentate gyrus granule cells). After ischemia endothelin receptor A immunoreactivity in the same regions was reduced by 40-50% from control. In contrast, endothelin receptor B immunoreactivity in control hippocampus was widely distributed in pyramidal neurons, granule cells and glial cells, this immunoreactivity increasing by approximately 25-30% after ischemia. DISCUSSION: Endothelin receptor A's marked decrease in mossy fibers after ischemia may contribute to glutamate release from mossy fiber terminals, thus enhancing excitotoxic effects on their Cornu Ammonis synaptic targets. Additionally, endothelin receptor B increased expression in neurons and glia could be related to a more generalized activation of survival mechanisms involving elements of the neurovascular unit.