RESUMO
Neonatal handling reduces the stress response in adulthood due to a feedback mechanism. The present study analyzed the effects of repeated neonatal environmental intervention (daily handling during the first 10 days after birth) on neuron-, astroglial cell density, and cellular proliferation of the hippocampal (CA1, CA2, and CA3) pyramidal cell layers in female rats. Pups were divided into two groups, nonhandled and handled, which were submitted to repeated handling sessions between postnatal days 1 and 10. Histological and immunohistochemical procedures were used to determine changes in neuron density, astroglial cell density, and cellular proliferation. We found an increase in neuron density in each pyramidal cell layer of the hippocampus (CA1, CA2, and CA3) in female rats (11 and 90 day old) that were handled during the neonatal period. Furthermore, we found an increase in astroglial cell density in both hemispheres of the brain in the handled group. Finally, we observed an increase in cellular proliferation in both hippocampi (CA1, CA2, and CA3) of the brain in female pups (11 days old) handled during the neonatal period. This study demonstrates that an early-life environmental intervention may induce morphological changes in a structure involved with several functions, including the stress response. The results of the current study suggest that neonatal handling may influence the animals' responses to environmental adversities later in life.
Assuntos
Astrócitos/fisiologia , Proliferação de Células , Ambiente Controlado , Hipocampo/citologia , Hipocampo/crescimento & desenvolvimento , Neurogênese/fisiologia , Neurônios/fisiologia , Animais , Animais Recém-Nascidos , Astrócitos/citologia , Contagem de Células , Feminino , Masculino , Neurônios/citologia , Gravidez , Ratos , Ratos WistarRESUMO
No sistema nervoso, a sinapse é a estrutura que permite a um neurônio passar um sinal elétrico ou químico a outro neurônio ou outra célula (muscular ou glandular). A palavra sinapse vem de "synaptein", palavra que Sir Charles Scott Sherrington e seus colegas acunharam do grego "syn" (junto) e "haptein"(afivelar). As sinapses podem ser separadas entre elétricas e químicas, porém a maior parte da transmissão sináptica é realizada através das sinapses químicas. Apesar das sinapses químicas terem uma resposta mais lenta que as elétricas, elas possuem a vantagem da amplificação do sinal gerada através de uma cascata de segundos mensageiros. As sinapses químicas podem ser excitatórias ou inibitórias e são caracterizadas por um terminal pré-sináptico (onde estão presentes as vesículas que contêm os neurotransmissores) em contato com um terminal pós-sináptico (onde estão presentes os receptores ionotrópicos e metabotrópicos para esses neurotransmissores) separados pela fenda sináptica. As sinapses típicas acontecem sobre axônios (axo-axônicas), sobre dendritos (axo-dendríticas), sobre o soma de outro neurônio (axo-somáticas) e sobre os espinhos dendríticos...
In the nervous system, the synapse is the structure that allows a neuron pass an electrical or chemical signal to another neuron or another cell (muscle or glandular). The word synapse comes from "synaptein" that Sir Charles Scott Sherrington and his colleagues minted from the Greek "syn" (together) and "haptein"(buckling). Most part of the synaptic transmission is performed through chemical synapses. Chemical synapses have a slower response than the electric ones; they have the advantage of amplifying the signal generated through a cascade of second messengers. Chemical synapses can be excitatory or inhibitory and are characterized by a presynaptic terminal (where there are vesicles that contain the neurotransmitters) in contact with a postsynaptic terminal (where there are the ionotropic and metabotropic receptors) separated by the synaptic cleft. Synapses can occur on axons (axo-axonal), on dendrites (axodendritic), on soma (axo-somatic) and on dendritic spines...
Assuntos
Receptores de Neurotransmissores , Transmissão SinápticaRESUMO
A comunicação entre neurônios é passível de constantes modificações, até mesmo no encéfalo adulto. Esta capacidade de circuitos neuronais fortalecerem ou enfraquecerem suas interações sinápticas específicas (fenômeno conhecido como plasticidade sináptica) pode ocorrer de acordo com as diferentes demandas ambientais, o que favorece a noção de que alterações dinâmicas na comunicação entre neurônios estão na base da flexibilidade comportamental (i.e., processos de aprendizagem e memória). Nas últimas décadas, o avanço das neurociências tem permitido uma melhor compreensão a respeito da plasticidade sináptica, especialmente a plasticidade de sinapses glutamatérgicas, cujos processos moleculares de modificação sináptica parecem estar entre os mais comuns de todo o sistema desse progresso na ciência básica tem contribuído para uma melhor compreensão acerca dos processos patológicos envolvendo as sinapses glutamatérgicas, como a doença de Alzheimer. Além disso, a crescente compreensão sobre o funcionamento da comunicação glutamatérgica tem ajudado a esclarecer como as sinapses, em geral, teriam se originado e evoluído na escala filogenética do reino animal (Metazoa)...
Communication between neurons is subject to constant changes, even in the adult brain. This ability of neural circuits to strengthen or weaken their specific synaptic interactions (a phenomenon known assynaptic plasticity) may occur according to different environmental demands, which favors the idea that dynamic changes in the communication between neurons underlie behavioral flexibility (i.e., learning and memory processes). In recent decades, advances in neuroscience has allowed a better understanding of synaptic plasticity, specially the plasticity of glutamatergic synapses, whose molecular processes of synaptic change appear to be among the most common throughout the central nervous system.Much of this progress in basic science has contributed to a better understanding of pathological processes involving the glutamatergic synapses, such as Alzheimer's disease. Furthermore, the growing understanding about the physiology of glutamatergic communication has helped explain how synapses, in general, would have originated and evolved in the phylogenetic scale of the Metazoa...
Assuntos
N-Metilaspartato , Plasticidade Neuronal , Ácido GlutâmicoRESUMO
Chronic hyperglycemia increases oxidative stress status and has been associated with neurological complications in diabetic individuals. This study compared the antioxidant properties of red wine or resveratrol in different brain areas of diabetic and non-diabetic rats, and investigated the effect of them on hippocampal cell proliferation in hippocampal dentate gyrus of diabetic rats. Streptozotocin-induced diabetic and control rats were treated with red wine (4 mL/kg), resveratrol (20 mg/kg), or saline, by oral gavage, for 21 days. Lipid peroxidation (TBARS), catalase and superoxide dismutase were measured to evaluate the oxidative stress and the BrdU-positive cells were assessed to measure changes in cellular proliferation. In diabetic animals, resveratrol showed antioxidant property in the hippocampus and in the striatum, while red wine had an antioxidant effect only in the hippocampus. Neither red wine nor resveratrol reversed the lower hippocampal cell proliferation in diabetic rats. Daily doses of red wine or resveratrol have an antioxidant effect in rats depending on the brain area and the glycemic status.