Evaluation of the effects of a hydrogen sulfide donor on neural plasticity.

  1. Conesa-Bakkali, Ryan
  2. Vega-Blanco, Ángela
  3. González-Morán, Daniel
  4. El Kharoubi-Zamudio, Naym
  5. Sola-García, Alejandro
  6. Cáliz-Molina, María Ángeles
  7. López-Fernández, Raúl
  8. Martín-Montalvo, Alejandro
  9. Espadas, Isabel
Revista:
Biosaia: Revista de los másteres de Biotecnología Sanitaria y Biotecnología Ambiental, Industrial y Alimentaria

ISSN: 2254-3821

Año de publicación: 2023

Número: 12

Tipo: Artículo

Otras publicaciones en: Biosaia: Revista de los másteres de Biotecnología Sanitaria y Biotecnología Ambiental, Industrial y Alimentaria

Resumen

The aging brain can exhibit significant modifications related with a progressive atrophy. Previous studies have shown that this atrophy may result from a combination of dendritic regression and neuronal death (1). Age-related memory and cognitive decline have been shown to coincide frequently with morphological changes which affect the neural plasticity and number of dendritic spines in the brains of both humans and animals (2). Furthermore, many neuropathologic conditions and neurodegenerative diseases exhibit abnormalities in dendritic tree structure. Animal studies have shown that even mild prolonged stress has been observed to induce the shrinkage of dendritic fields and the loss of dendritic spines (3).Recent evidence suggest that H2S is a gasotransmitter with neuroprotective properties. In addition, a few sulfur donors have shown beneficial therapeutic effects in experimental models of neurodegenerative diseases (4). Moreover, previous research in our lab suggests that a pharmacological treatment aimed at increasing intracellular H2S improves physical and metabolic health in mice. Nonetheless, the specific properties of these compounds maintaining neuron homeostasis and plasticity remain unknown.Here we aim to investigate whether modulation of intracellular H2S by a pharmacological intervention can improve neuronal plasticity in terms of morphological changes at the level of dendritic arborization and dendritic spine density. To this purpose, we will perform analyses in murine primary neuron cultures that will be treated with increasing concentrations of drug “δ”. Experimental conditions will be: untreated (0, vehicle solution), 10 μM, 50 μM, and 100 μM. Cells will be maintained for 12-14 days in culture, and will be treated with compound “δ” for 48 hours. Then cells will be fixed and MAP2 immunocytochemistry analyses will be performed. Photos will be taken under a fluorescence microscope and analyzed using software ImageJ to determine the percentage of arborized area and the dendritic spine density. The results will provide us with an insight into the potential of drug “δ” as a neuroprotective agent to prevent age-related loss of neuroplasticity.

Referencias bibliográficas

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