Morfología neuronal en el trastorno del espectro autista / Neuronal morphology in autism spectrum disorder

RESUMEN: El trastorno del espectro autista (TEA) abarca un grupo de trastornos multifactoriales del neurodesarrollo caracterizados por una comunicación e interacción social deteriorada y por comportamientos repetitivos y estereotipados. Múltiples estudios han revelado que en el TEA existen disfunciones sinápticas, en la cual la morfología y función neuronal son sustratos importantes en esta patogenia. En esta revisión comentamos los datos disponibles a nivel de anormalidades neuronales en el TEA, enfatizando la morfología de las dendritas, espinas dendríticas y citoesquelo de actina. Las dendritas y espinas dendríticas, ricas en actina, forman la parte postsináptica de la mayoría de las sinapsis excitadoras. En el TEA, los datos obtenidos apuntan a una desregulación en el crecimiento y desarrollo dendrítico, así como una alteración en la densidad de las espinas dendríticas. Lo anterior, se ve acompañado de alteraciones en la remodelación y composición del citoesqueleto neuronal. Para comprender mejor la fisiopatología del TEA, es necesario mayor información sobre cómo los cambios morfofuncionales de los actores que participan en la sinapsis impactan en los circuitos y el comportamiento.

SUMMARY: Autism Spectrum Disorder (ASD) is a group of multifactorial neurodevelopmental disorders, characterized by impaired communication and social interaction skills, and by repetitive and stereotyped behaviors. Multiple studies report that there are synaptic dysfunctions in ASD, in which important substrates such as morphology and neuronal function are involved in this pathogenesis. In this review we discuss the data available at the level of neuronal abnormalities in ASD, and emphasize the morphological aspects of dendrites, dendritic spines, and actin cytoskeleton. Actin-rich dendrites and dendritic spines shape the postsynaptic part of the most excitatory synapses. In ASD, the data points to a dysregulation in dendritic growth and development, as well as an alteration in the density of dendritic spines. This is accompanied by alterations in the remodeling and composition of the neuronal cytoskeleton. In order to better understand the pathophysiology of ASD, further information is needed on how the elements of synaptic morphofunctional changes impact circuits and behavior.

Dendritic spine changes in medial prefrontal cortex of male diabetic rats using golgi-impregnation method

Neuropathy is one of the major complications contributing to morbidity in patients with diabetes mellitus. The effect of diabetes on brain has not been studied so much and no gross abnormality has been found in the central nervous system of patients with diabetic neuropathy. This study was conducted to evaluate the time-dependent structural changes in medial prefrontal cortex of male diabetic rats using Golgi-impregnation method. Male Wistar rats were randomly divided into the control and diabetic groups. For induction of diabetes, a single dose of streptozotocin [60 mg/kg] was injected intraperitoneally. At the end of the first and second months, the rats were transcardially perfused with a solution of phosphate buffer containing paraformaldehyde and Golgi-impregnated method was used to evaluate the changes of dendritic spines in medial prefrontal cortex. There was a significant reduction in the mean density of pyramidal neuron dendritic spines in the layers II and III of medial prefrontal cortex only after 2 months in the diabetic group compared to age-matched controls [P<0.05]. Diabetes induces a reduction in the spine density of apical dendrites of medial prefrontal cortex only in two-month diabetic rats