O controle da neurogênese pelos astrócitos no sistema nervoso central

Astrocytes control neurogenesis in the central nervous system.O controle da neurogênese pelos astrócitos no sistema nervoso central

Efeitos in vitro do ácido retinóico em células de glioblastoma.

Malignant gliomas are highly invasive, rapidly proliferating tumors and present a poor prognosis. In this study, we investigated the potential effects of the retinoic acid (RA) on a high proliferative glioblastoma cell line, GL-15. The exposure to a single dose of t-RA reduces the cell growth, induces a transitory stage of the cell differentiation, and it finally leads to the apoptotic cell death depending on the RA concentration range and the time of exposure. We found that the GL-15 cells express constitutively the RARs isotypes a, b and g, and that RARa1/2, RARb2, and RARg2 expressions are induced by t-RA. These results suggest that the ratio of RAR isoforms may be a crucial element for inducing either efficient differentiaton or apoptotic effects in those cells. Furthermore, they suggest that the use of ligands specific to each receptor isotype might be relevant for further glioma therapies.Os gliomas malignos são tumores muito infiltrantes, cujas células proliferam rapidamente, e apresentam um prognóstico muito reservado. Neste estudo, investigamos o efeito em potencial do ácido retinóico (AR) sobre a linhagem de células de glioblastoma multiforme humano GL-15. A exposição a uma única dose de AR (1-10 mM) inibiu a proliferação celular, induziu uma diferenciação transitória e, finalmente, conduziu estas células à apoptose. Observamos que as células GL-15 expressam os isotipos dos RARs a, b e g, e que as isoformas RARa1/2, RARb2 e RARg2 são induzidas pelo AR. Estes resultados sugerem que a relação entre a expressão das diferentes isoformas de RARs pode ser um elemento fundamental para a indução seja de uma diferenciação completa, seja de apoptose das células de glioblastoma, e que o uso de ligantes específicos a cada isotipo de receptor pode vir a ser um elemento importante para terapias futuras de gliomas

Contribution of gap junctional communication between tumor cells and astroglia to the invasion of the brain parenchyma by human glioblastomas

BACKGROUND: Gliomas are "intraparenchymally metastatic" tumors, invading the brain in a non-destructive way that suggests cooperation between glioma cells and their environment. Recent studies using an engineered rodent C6 tumor cell line have pointed to mechanisms of invasion that involved gap junctional communication (GJC), with connexin 43 as a substrate. We explored whether this concept may have clinical relevance by analyzing the participation of GJC in human glioblastoma invasion. RESULTS: Three complementary in vitro assays were used: (i) seeding on collagen IV, to analyze homocellular interactions between tumor cells (ii) co-cultures with astrocytes, to study glioblastoma/astrocytes relationships and (iii) implantation into organotypic brain slice cultures, that mimic the three-dimensional parenchymal environment. Carbenoxolone, a potent blocker of GJC, inhibited cell migration in the two latter models. It paradoxically increased it in the first one. These results showed that homocellular interaction between tumor cells supports intercellular adhesion, whereas heterocellular glioblastoma/astrocytes interactions through functional GJC conversely support tumor cell migration. As demonstrated for the rodent cell line, connexin 43 may be responsible for this heterocellular functional coupling. Its levels of expression, high in astrocytes, correlated positively with invasiveness in biopsied tumors. CONCLUSIONS: our results underscore the potential clinical relevance of the concept put forward by other authors based on experiments with a rodent cell line, that glioblastoma cells use astrocytes as a substrate for their migration by subverting communication through connexin 43-dependent gap junctions

Cytotoxicity effect of alkaloidal extract from Prosopis juliflora Sw. D.C. (Algaroba) pods on glial cells

A Prosopis juliflora é amplamente utilizada na alimentação humana e de várias espécies animais, especialmente bovinos. Quadros de intoxicação por esta planta, nesta espécie, têm sido relatados, principalmente quando a mesma é oferecida como única fonte alimentar, desencadeando uma doença de sintomatologia nervosa. Neste estudo, objetivou-se avaliar os efeitos in vitro da fração de alcalóides totais (FA) extraída das vagens da Prosopis juliflora utilizando cultura primária de astrócitos obtidos do córtex cerebral de ratos como modelo de estudo. A avaliação da atividade mitocondrial pelo teste do MTT demonstrou a citotoxicidade em 30 µg/ml da FA após 24 h. As concentrações de 0,3 e 3 µg/ml da FA induziram um aumento da atividade mitocondrial, indicando reatividade celular. Testes imunocitoquímicos para a GFAP, principal proteína de citoesqueleto de astrócitos, revelaram alterações morfológicas nas células após tratamento com 0,3 e 3 µg/ml da FA por 72 h. Tais resultados são consoantes à análise desta proteína por westernblot, quando as culturas foram tratadas com 0,3 e 3 µg/ml da FA por 72 h, demonstrando interferências na regulação da expressão da GFAP. A expressão de vimentina não foi significativamente alterada em nenhuma das concentrações testadas. Estes resultados sugerem que os alcalóides da P. juliflora induzem a reatividade astrocitária, o que pode estar envolvido nos efeitos neurotóxicos providos pelo consumo desta planta.Prosopis juliflora is largely used for feeding cattle and humans. Neurological signals have been reported in cattle due to intoxication with this plant. In this study, an alkaloidal fraction (AF) obtained from P. juliflora pods was tested on astrocyte primary cultures. Astrocytes display physiological functions essential to development, homeostasis and detoxification in the central nervous system (CNS). These cells are known for their role on energetic support and immune response in the CNS. Concentrations between 0.03 to 30 µg/ml AF were assayed for 24 - 72 h. The mitochondrial activity, assayed by MTT test, showed cytotoxicity at 30 µg/ml AF after 24 h. At concentrations ranging between 0.3 - 3 µg/ml, the AF induced an increase on mitochondrial activity, indicating cell reactivity. Immunocytochemistry assay for GFAP cytoskeletal protein, revealed alterations on cell morphology after treatment with 0.3 - 3 µg/ml AF for 72 h. This result corroborates with western blot analysis when cells treated with 0.3 - 3 µg/ml AF for 72 h showed GFAP upregulation. The vimentin expression was not significantly altered in all tested concentrations. These results suggest that alkaloids induce astrocyte reactivity and might be involved in the neurotoxic effects induced by P. juliflora consumption

Role of laminin bioavailability in the astroglial permissivity for neuritic outgrowth

The mechanisms involved in the failure of an adult brain to regenerate post-lesion remain poorly understood. The reactive gliosis which occurs after an injury to the CNS and leads to the glial scar has been considered as one of the major impediments to neurite outgrowth and axonal regeneration. A glial scar consists mainly of reactive, hypertrophic astrocytes. These reactive cells acquire new properties, leading to A non-permissive support for neurons. Astrogial reactivity is mainly characteriized by a high overexpression of the major component of the gliofilaments, the glial fibrillary acidic protein (GFAP). This GFAP overexpression is related to the astroglial morphological response to injury. We hypothesized that modulation of GFAP synthesis, reversing the hypertrophic phenotype, might also reverse the blockage of neuritic outgrowth observed after a lesion. In this article, we review findings of our group, confirming our hypothesis in a model of lesioned neuron-astrocyte cocultures. We demonstrate that permissivity for neuritic outgrowth is related to phenotypic changes induced in reactive astrocytes transfected by antisense GFAP-mRNA. We also found that this permissivity was related to a neuron-regulated extracellular laminin bioavailability

Envelhecimento do cérebro: reflexões sobre interações neuro-gliais

Aging begins at maturity and is characterized by increasing deviations from an ideal functional state. One major reason for this is thought to be oxydatif stress. The brain is particularly susceptible to oxidative damage. Besides neurons, glial cells, a major family of neural cells, are directly involved in vital brain functions and particularly in the brain antioxidant defence. This review brings insights into the potentialities of these glial cells to protect neurons and into their contribution to the brain aging process.O envelhecimento começa na maturidade e se caracteriza pelos crescentes desvios do estado funcional ideal. Supõe-se que o principal motivo dessas mudanças seja o estresse oxidativo. O cérebro é extremamente susceptível a danos oxidativos. Além dos neurônios, as células gliais, a principal família das células neurais, estão diretamente envolvidas com as funções vitais do cérebro, especialmente na defesa antioxidante do cérebro. Este trabalho aborda aspectos relativos ao potencial que as células gliais têm para proteger os neurônios e sua contribuição para o processo de envelhecimento do cérebro

ETUDE DE LA CROISSANCE CELLULAIRE, DE LA DIFFERENTIATION ET DE L'APOPTOSE INDUITS PAR L'ACIDE RETINOIQUE ET DES RETINOIDES DE SYNTHESE DANS DES LIGNEES TUMORALES HUMAINES GLIOMATEUSES

PARIS12-CRETEIL BU Multidisc. (940282102) / SudocSudocFranceF