Emı́lia Madarász scite author profile

In addition to being the major inhibitory neurotransmitter, gamma-aminobutyric acid (GABA) is thought to play a morphogenetic role in embryonic development. During the last decade, considerable progress has been made in elucidating the molecular mechanisms involved in GABA synthesis and biological action. The present review is an attempt to summarise recent results on the ontogeny of the different components of embryonic GABA signalling with an emphasis on the synthesis of GABA by different molecular forms of glutamic acid decarboxylase (GAD).

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Retinoic acid induced neural differentiation in a neuroectodermal cell line immortalized by p53 deficiency

Schlett

Madarász

1997

J. Neurosci. Res.

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Neuroepithelial cell lines were established from cerebral vesicles of 9‐day‐old mouse embryos lacking functional p53 genes (Livingstone et al: Cell 70:923–935, 1992). All‐trans retinoic acid (RA) induced bulk formation of neurons both in several p53‐deficient neuroepithelial cell lines and in wild‐type neural cells derived from early embryonic (E9–E12) forebrain vesicles. Forty‐eight‐hour treatment with 10−6 MRA was necessary and sufficient to initiate neuron formation by p53‐/‐‐progenitors, but neuronal characteristics appeared with a delay of 3–4 days. The first appearance of cells with astroglial features followed that of neurons with a further delay of 4–5 days. The establishment of neuronal phenotypes involved minimally three rounds of cell cycle. Future neurons were sorted out from substrate‐attached cells and were characterized by a specific rearrangement of nestin‐immunoreactive filaments. The formation of neuronal phenotypes was not synchronized within the RA‐treated cell populations. The data indicate that RA, which promotes the initiation of neural differentiation, cannot function as a direct regulator of cell‐fate decisions made by neural progenitor cells. J. Neurosci. Res. 47:405–415, 1997. © 1997 Wiley‐Liss, Inc.

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Exponential Distribution of Locomotion Activity in Cell Cultures

et al. 1998

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In vitro velocities of several cell types have been measured using computer controlled video microscopy, which allowed to record the cells' trajectories over several days. On the basis of our large data sets we show that the locomotion activity displays a universal exponential distribution. Thus, motion resulting from complex cellular processes can be well described by an unexpected, but very simple distribution function. A simple phenomenological model based on the interaction of various cellular processes and finite ATP production rate is proposed to explain these experimental results.Comment: 4 pages, 3 figure

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Astroglia‐derived retinoic acid is a key factor in glia‐induced neurogenesis

Környei

Gócza

Rühl³

et al. 2007

FASEB j.

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Astroglial cells are essential components of the neurogenic niches within the central nervous system. Emerging evidence suggests that they are among the key regulators of postnatal neurogenesis. Although astrocytes have been demonstrated to possess the potential to instruct stem cells to adopt a neuronal fate, little is known about the nature of the glia-derived instructive signals. Here we propose that all-trans retinoic acid, one of the most powerful morphogenic molecules regulating neuronal cell fate commitment, may be one of the glia-derived factors directing astroglia-induced neurogenesis. According to data obtained from several complementary approaches, we show that cultured astrocytes express the key enzyme mRNAs of retinoic acid biosynthesis and actively produce all-trans retinoic acid. We show that blockage of retinoic acid signaling by the pan-RAR antagonist AGN193109 prevents glia-induced neuron formation by noncommitted stem cells. Therefore, we provide strong in vitro evidence for retinoic acid action in astroglia-induced neuronal differentiation.

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Uptake and bio-reactivity of polystyrene nanoparticles is affected by surface modifications, ageing and LPS adsorption: in vitro studies on neural tissue cells

Kumarasamy

Kenesei

et al. 2015

Nanoscale

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Because of their capacity of crossing an intact blood-brain barrier and reaching the brain through an injured barrier or via the nasal epithelium, nanoparticles have been considered as vehicles to deliver drugs and as contrast materials for brain imaging. The potential neurotoxicity of nanoparticles, however, is not fully explored. Using particles with a biologically inert polystyrene core material, we investigated the role of the chemical composition of particle surfaces in the in vitro interaction with different neural cell types. PS NPs within a size-range of 45-70 nm influenced the metabolic activity of cells depending on the cell-type, but caused toxicity only at extremely high particle concentrations. Neurons did not internalize particles, while microglial cells ingested a large amount of carboxylated but almost no PEGylated NPs. PEGylation reduced the protein adsorption, toxicity and cellular uptake of NPs. After storage (shelf-life >6 months), the toxicity and cellular uptake of NPs increased. The altered biological activity of "aged" NPs was due to particle aggregation and due to the adsorption of bioactive compounds on NP surfaces. Aggregation by increasing the size and sedimentation velocity of NPs results in increased cell-targeted NP doses. The ready endotoxin adsorption which cannot be prevented by PEG coating, can render the particles toxic. The age-dependent changes in otherwise harmless NPs could be the important sources for variability in the effects of NPs, and could explain the contradictory data obtained with "identical" NPs.

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