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ePoster
VULNERABILITY OF NEUROPEPTIDE Y–EXPRESSING INTERNEURONS IN ADULTHOOD FOLLOWING NEONATAL MONOSODIUM GLUTAMATE–INDUCED EXCITOTOXICITY
Rubén Castro-Torresand 8 co-authors
University Center of Biological and Agricultural Sciences (CUCBA)
FENS Forum 2026 (2026)
Barcelona, Spain
Presenter and authors
Presenter
Rubén Castro-Torres
University Center of Biological and Agricultural Sciences (CUCBA)
Co-authors
Osvaldo Jair Magdaleno-Alvarez; Ana Navarro; Antoni Parcerisas; Ester Verdaguer; Mónica E. Ureña-Guerrero; Jose L. Castañeda-Cabral; Antoni Camins; Carme Auladell
Abstract
Excitotoxicity, resulting from excessive glutamatergic stimulation, is a primary mechanism of neuronal damage within the central nervous system. Neuropeptide Y (NPY), a 36–amino acid neuropeptide, acts as a key endogenous modulator with anticonvulsant effects, particularly within the hippocampal region. Interneurons expressing this peptide (NPY⁺ INs) play an essential role in regulating excitability in the dentate gyrus; however, they may be especially vulnerable to early-life brain insults.
The study aimed to investigate the role of NPY in modulating excitotoxic damage and to analyze the long-term impact of neonatal excitotoxicity on these specific interneuron populations in adulthood. An experimental model of early-life excitotoxicity was established using male rats treated with monosodium glutamate (MSG; 4 g/kg, administered subcutaneously) on postnatal days 1, 3, 5, and 7. At 60 days of age (adulthood), IN-NPY⁺ interneuron counts (cells/µm²) were obtained in the hilus of the dentate gyrus by immunohistochemistry for NPY protein, comparing MSG-treated (n = 4) and control (n = 4) groups. Quantitative analysis revealed a significant reduction in NPY+ IN density in the hilus animals exposed to MSG during the neonatal period compared to control group. The results indicate that neonatal excitotoxic insults result in a persistent alteration of inhibitory mechanisms in the hippocampus. The loss of IN-NPY⁺ interneurons represents a vulnerability factor for the control of neuronal excitability, linking early-life seizures and damage to long-term neurological dysfunction. Reduced of IN-NPY+ increases neuronal excitability and may contribute to an increase of seizure susceptibility in adulthood following neonatal excitotoxic and seizure damage.
The study aimed to investigate the role of NPY in modulating excitotoxic damage and to analyze the long-term impact of neonatal excitotoxicity on these specific interneuron populations in adulthood. An experimental model of early-life excitotoxicity was established using male rats treated with monosodium glutamate (MSG; 4 g/kg, administered subcutaneously) on postnatal days 1, 3, 5, and 7. At 60 days of age (adulthood), IN-NPY⁺ interneuron counts (cells/µm²) were obtained in the hilus of the dentate gyrus by immunohistochemistry for NPY protein, comparing MSG-treated (n = 4) and control (n = 4) groups. Quantitative analysis revealed a significant reduction in NPY+ IN density in the hilus animals exposed to MSG during the neonatal period compared to control group. The results indicate that neonatal excitotoxic insults result in a persistent alteration of inhibitory mechanisms in the hippocampus. The loss of IN-NPY⁺ interneurons represents a vulnerability factor for the control of neuronal excitability, linking early-life seizures and damage to long-term neurological dysfunction. Reduced of IN-NPY+ increases neuronal excitability and may contribute to an increase of seizure susceptibility in adulthood following neonatal excitotoxic and seizure damage.