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Dissociated Cultures (dissociated + culture)

Distribution by Scientific Domains
Life Sciences83%

Selected Abstracts

Differential expression and localization of neuronal intermediate filament proteins within newly developing neurites in dissociated cultures of Xenopus laevis embryonic spinal cord

CYTOSKELETON, Issue 1 2001
Jayanthi Undamatla
Abstract The molecular subunit composition of neurofilaments (NFs) progressively changes during axon development. In developing Xenopus laevis spinal cord, peripherin emerges at the earliest stages of neurite outgrowth. NF-M and XNIF (an ,-internexin-like protein) appear later, as axons continue to elongate, and NF-L is expressed after axons contact muscle. Because NFs are the most abundant component of the vertebrate axonal cytoskeleton, we must understand why these changes occur before we can fully comprehend how the cytoskeleton regulates axon growth and morphology. Knowing where these proteins are localized within developing neurites and how their expression changes with cell contact is essential for this understanding. Thus, we examined by immunofluorescence the expression and localization of these NF subunits within dissociated cultures of newly differentiating spinal cord neurons. In young neurites, peripherin was most abundant in distal neuritic segments, especially near branch points and extending into the central domain of the growth cone. In contrast, XNIF and NF-M were usually either absent from very young neurites or exhibited a proximal to distal gradient of decreasing intensity. In older neurites, XNIF and NF-M expression increased, whereas that of peripherin declined. All three of these proteins became more evenly distributed along the neurites, with some branches staining more intensely than others. At 24 h, NF-L appeared, and in 48-h cultures, its expression, along with that of NF-M, was greater in neurites contacting muscle cells, arguing that the upregulation of these two subunits is dependent on contact with target cells. Moreover, this contact had no effect on XNIF or peripherin expression. Our findings are consistent with a model in which peripherin plays an important structural role in growth cones, XNIF and NF-M help consolidate the intermediate filament cytoskeleton beginning in the proximal neurite, and increased levels of NF-L and NF-M help further solidify the cytoskeleton of axons that successfully reach their targets. Cell Motil. Cytoskeleton 49:16,32, 2001. © 2001 Wiley-Liss, Inc. [source]

The generation of rhythmic activity in dissociated cultures of rat spinal cord

EUROPEAN JOURNAL OF NEUROSCIENCE, Issue 2 2001
Jürg Streit
Abstract Locomotion in vertebrates is controlled by central pattern generators in the spinal cord. The roles of specific network architecture and neuronal properties in rhythm generation by such spinal networks are not fully understood. We have used multisite recording from dissociated cultures of embryonic rat spinal cord grown on multielectrode arrays to investigate the patterns of spontaneous activity in randomised spinal networks. We were able to induce similar patterns of rhythmic activity in dissociated cultures as in slice cultures, although not with the same reliability and not always with the same protocols. The most reliable rhythmic activity was induced when a partial disinhibition of the network was combined with an increase in neuronal excitability, suggesting that both recurrent synaptic excitation and neuronal excitability contribute to rhythmogenesis. During rhythmic activity, bursts started at several sites and propagated in variable ways. However, the predominant propagation patterns were independent of the protocol used to induce rhythmic activity. When synaptic transmission was blocked by CNQX, APV, strychnine and bicuculline, asynchronous low-rate activity persisted at ,,50% of the electrodes and ,,70% of the sites of burst initiation. Following the bursts, the activity in the interval was transiently suppressed below the level of intrinsic activity. The degree of suppression was proportional to the amount of activity in the preceding burst. From these findings we conclude that rhythmic activity in spinal cultures is controlled by the interplay of intrinsic neuronal activity and recurrent excitation in neuronal networks without the need for a specific architecture. [source]

Neural Signal Manager: a collection of classical and innovative tools for multi-channel spike train analysis

INTERNATIONAL JOURNAL OF ADAPTIVE CONTROL AND SIGNAL PROCESSING, Issue 11 2009
Antonio Novellino
Abstract Recent developments in the neuroengineering field and the widespread use of the micro electrode arrays (MEAs) for electrophysiological investigations made available new approaches for studying the dynamics of dissociated neuronal networks as well as acute/organotypic slices maintained ex vivo. Importantly, the extraction of relevant parameters from these neural populations is likely to involve long-term measurements, lasting from a few hours to entire days. The processing of huge amounts of electrophysiological data, in terms of computational time and automation of the procedures, is actually one of the major bottlenecks for both in vivo and in vitro recordings. In this paper we present a collection of algorithms implemented within a new software package, named the Neural Signal Manager (NSM), aimed at analyzing a huge quantity of data recorded by means of MEAs in a fast and efficient way. The NSM offers different approaches for both spike and burst analysis, and integrates state-of-the-art statistical algorithms, such as the inter-spike interval histogram or the post stimulus time histogram, with some recent ones, such as the burst detection and its related statistics. In order to show the potentialities of the software, the application of the developed algorithms to a set of spontaneous activity recordings from dissociated cultures at different ages is presented in the Results section. Copyright © 2008 John Wiley & Sons, Ltd. [source]

Dorsally derived BMP4 inhibits the induction of spinal cord oligodendrocyte precursors

JOURNAL OF NEUROCHEMISTRY, Issue 2002
R. H. Miller
During development oligodendrocyte precursors arise in a distinct domain of the ventral ventricular zone in the spinal cord that they share with motor neurons. The localized appearance of oligodendrocyte and motor neuron precursors is the result of local inductive signals including sonic hedgehog (Shh). Previous studies suggested that inhibitory signals from dorsal spinal cord act to sharpen the boundaries of the Shh induced region. Here we show that the dorsal spinal cord contains BMP4 during the developmental period when oligodendrocyte precursors first appear. In dissociated cultures of embryonic spinal cord cells, BMP4 competitively blocks the induction of oligodendrocyte precursors by Shh. Similarly, in embryonic slice preparations addition of BMP4 inhibited the appearance of oligodendrocyte precursors in the ventral spinal cord while addition of Shh enhanced their appearance. In vivo, transplantation of a BMP4 coated bead adjacent to the dorsal spinal cord inhibited ventral oligodendrogenesis while transplantation of a Shh coated bead enhanced ventral oligodendrogenesis. These data suggest that the initial localization of oligodendrocytes in the ventral spinal cord reflects the neutralization of dorsally-derived BMP4 inhibition by locally supplied Shh. [source]