It is well documented that neurons exposed to high concentrations of excitatory amino acids, such as glutamate and aspartate, degenerate and die. The clearance of these amino acids from the synaptic cleft depends mainly on their transport by high‐affinity sodium‐dependent carriers. Using microdialysis in vivo and HPLC analysis, we have studied the effect of the administration of inhibitors of the glutamate transporter (l‐trans‐pyrrolidine‐2,4‐dicarboxylate and dihydrokainate) on the extracellular concentration of endogenous amino acids in the rat striatum. In addition, we have analyzed whether the changes observed in the concentration of glutamate and aspartate were injurious to striatal cells. Neuronal damage was assessed by biochemical determination of choline acetyltransferase and glutamate decarboxylase activities, 7 days after the microdialysis procedure. In other experiments, pyrrolidine dicarboxylate and dihydrokainate, as well as two other inhibitors of the glutamate carrier, dl‐threo‐β‐hydroxyaspartate and l‐aspartate‐β‐hydroxamate, were microinjected into the striatum, and neuronal damage was assessed, both biochemically and histologically, 7 or 14 days after the injection. Dihydrokainate and pyrrolidine dicarboxylate produced a similar remarkable increase in the concentration of extracellular aspartate and glutamate. However, the former induced also notable elevations in the concentration of other amino acids. Clear neuronal damage was observed only after dihydrokainate administration, which was partially prevented by intraperitoneal injection of (+)‐5‐methyl‐10,11‐dihydro‐5H‐dibenzo[a,d]cyclohepten‐5,10‐imine maleate or by intrastriatal coinjection of 2,3‐dihydroxy‐6‐nitro‐7‐sulfamoylbenzo(f)quinoxaline. No cell damage was observed with the other three glutamate carrier inhibitors used. It is concluded that an increased extracellular glutamate level in vivo due to dysfunction of its transporter is not sufficient for inducing neuronal damage. The neurotoxic effects of dihydrokainate could be explained by direct activation of glutamate postsynaptic receptors, an effect not shared by the other inhibitors used.
Senescent cells accumulate in various tissues and organs with aging altering surrounding tissue due to an active secretome, and at least in mice their elimination extends healthy lifespan and ameliorates several chronic diseases. Whether all cell types senesce, including post-mitotic cells, has been poorly described mainly because cellular senescence was defined as a permanent cell cycle arrest. Nevertheless, neurons with features of senescence have been described in old rodent and human brains. In this study we characterized an in vitro model useful to study the molecular basis of senescence of primary rat cortical cells that recapitulates senescent features described in brain aging. We found that in long-term cultures, rat primary cortical neurons displayed features of cellular senescence before glial cells did, and developed a functional senescence-associated secretory phenotype able to induce paracrine premature senescence of mouse embryonic fibroblasts but proliferation of rat glial cells. Functional autophagy seems to prevent neuronal senescence, as we observed an autophagic flux reduction in senescent neurons both in vitro and in vivo, and autophagy impairment induced cortical cell senescence while autophagy stimulation inhibited it. Our findings suggest that aging-associated dysfunctional autophagy contributes to senescence transition also in neuronal cells.
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