Studying subcellular detail in fixed astrocytes: Dissociation of morphologically intact glial cells (DIMIGs)

Studying the distribution of astrocytic antigens is particularly hard when they are localized in their fine, peripheral astrocyte processes (PAPs), since these processes often have a diameter comparable to vesicles and small organelles. The most appropriate technique is immunoelectron microscopy, wh...

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Main Authors: Julia eHaseleu, Enrico eAnlauf, Sandra eBlaess, Elmar eEndl, Amin eDerouiche
Format: Article
Language:English
Published: Frontiers Media S.A. 2013-05-01
Series:Frontiers in Cellular Neuroscience
Subjects:
Online Access:http://journal.frontiersin.org/Journal/10.3389/fncel.2013.00054/full
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spelling doaj-a14b1957565447af803fb93edd9fe72c2020-11-24T23:51:04ZengFrontiers Media S.A.Frontiers in Cellular Neuroscience1662-51022013-05-01710.3389/fncel.2013.0005446446Studying subcellular detail in fixed astrocytes: Dissociation of morphologically intact glial cells (DIMIGs)Julia eHaseleu0Enrico eAnlauf1Enrico eAnlauf2Sandra eBlaess3Elmar eEndl4Amin eDerouiche5Amin eDerouiche6Amin eDerouiche7University of BonnUniversity of FrankfurtUniversity of FrankfurtUniversity of BonnUniversity of BonnUniversity of FrankfurtUniversity of BonnUniversity of FrankfurtStudying the distribution of astrocytic antigens is particularly hard when they are localized in their fine, peripheral astrocyte processes (PAPs), since these processes often have a diameter comparable to vesicles and small organelles. The most appropriate technique is immunoelectron microscopy, which is, however, a time-consuming procedure. Even in high resolution light microscopy, antigen localization is difficult to detect due to the small dimensions of these processes, and overlay from antigen in surrounding non-glial cells. Yet, PAPs frequently display antigens related to motility and glia-synaptic interaction. Here, we describe the dissociation of morphologically intact glial cells (DIMIGs), permitting unambiguous antigen localization using epifluorescence microscopy. Astrocytes are dissociated from juvenile (p13-15) mouse cortex by applying papain treatment and cytospin centrifugation to attach the cells to a slide. The cells and their complete processes including the PAPs is thus projected in 2D. The entire procedure takes 2½-3 hours. We show by morphometry that the diameter of DIMIGs, including the PAPs is similar to that of astrocytes in situ. In contrast to cell culture, results derived from this procedure allow for direct conclusions relating to (i) the presence of an antigen in cortical astrocytes, (ii) subcellular antigen distribution, in particular when localized in the PAPs. The detailed resolution is shown in an exemplary study of the organization of the astrocytic cytoskeleton components actin, ezrin, tubulin, and GFAP. The distribution of connexin 43 in relation to a single astrocyte’s process tree is also investigated.http://journal.frontiersin.org/Journal/10.3389/fncel.2013.00054/fullConnexin 43Tubulingap junctionActinsynapseEzrin
collection DOAJ
language English
format Article
sources DOAJ
author Julia eHaseleu
Enrico eAnlauf
Enrico eAnlauf
Sandra eBlaess
Elmar eEndl
Amin eDerouiche
Amin eDerouiche
Amin eDerouiche
spellingShingle Julia eHaseleu
Enrico eAnlauf
Enrico eAnlauf
Sandra eBlaess
Elmar eEndl
Amin eDerouiche
Amin eDerouiche
Amin eDerouiche
Studying subcellular detail in fixed astrocytes: Dissociation of morphologically intact glial cells (DIMIGs)
Frontiers in Cellular Neuroscience
Connexin 43
Tubulin
gap junction
Actin
synapse
Ezrin
author_facet Julia eHaseleu
Enrico eAnlauf
Enrico eAnlauf
Sandra eBlaess
Elmar eEndl
Amin eDerouiche
Amin eDerouiche
Amin eDerouiche
author_sort Julia eHaseleu
title Studying subcellular detail in fixed astrocytes: Dissociation of morphologically intact glial cells (DIMIGs)
title_short Studying subcellular detail in fixed astrocytes: Dissociation of morphologically intact glial cells (DIMIGs)
title_full Studying subcellular detail in fixed astrocytes: Dissociation of morphologically intact glial cells (DIMIGs)
title_fullStr Studying subcellular detail in fixed astrocytes: Dissociation of morphologically intact glial cells (DIMIGs)
title_full_unstemmed Studying subcellular detail in fixed astrocytes: Dissociation of morphologically intact glial cells (DIMIGs)
title_sort studying subcellular detail in fixed astrocytes: dissociation of morphologically intact glial cells (dimigs)
publisher Frontiers Media S.A.
series Frontiers in Cellular Neuroscience
issn 1662-5102
publishDate 2013-05-01
description Studying the distribution of astrocytic antigens is particularly hard when they are localized in their fine, peripheral astrocyte processes (PAPs), since these processes often have a diameter comparable to vesicles and small organelles. The most appropriate technique is immunoelectron microscopy, which is, however, a time-consuming procedure. Even in high resolution light microscopy, antigen localization is difficult to detect due to the small dimensions of these processes, and overlay from antigen in surrounding non-glial cells. Yet, PAPs frequently display antigens related to motility and glia-synaptic interaction. Here, we describe the dissociation of morphologically intact glial cells (DIMIGs), permitting unambiguous antigen localization using epifluorescence microscopy. Astrocytes are dissociated from juvenile (p13-15) mouse cortex by applying papain treatment and cytospin centrifugation to attach the cells to a slide. The cells and their complete processes including the PAPs is thus projected in 2D. The entire procedure takes 2½-3 hours. We show by morphometry that the diameter of DIMIGs, including the PAPs is similar to that of astrocytes in situ. In contrast to cell culture, results derived from this procedure allow for direct conclusions relating to (i) the presence of an antigen in cortical astrocytes, (ii) subcellular antigen distribution, in particular when localized in the PAPs. The detailed resolution is shown in an exemplary study of the organization of the astrocytic cytoskeleton components actin, ezrin, tubulin, and GFAP. The distribution of connexin 43 in relation to a single astrocyte’s process tree is also investigated.
topic Connexin 43
Tubulin
gap junction
Actin
synapse
Ezrin
url http://journal.frontiersin.org/Journal/10.3389/fncel.2013.00054/full
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