Charakterisierung spannungsabhängiger Kaliumkanäle an glialen Vorläuferzellen der Maus

Schmidt, Kathrin

16 October 1998

Das Membranstrommuster von Oligodendrozyten verändert sich während der Entwicklung dieser zellen sehr stark. Während die Membranleitfähigkeit von Oligodendrozyten-Vorläuferzellen von auswärts rektifizierenden Kaliumkanälen geprägt ist, exprimieren reife Oligodendrozyten passive, nicht spannungsabhängige Kaliumkanäle. Die Aktivität dieser Kanäle beeinflußt die Proliferation und Differenzierung dieser Zellen. In der vorliegenden Arbeit wurde die Expression von spannungsaktivierbaren Kaliumkanälen des Kv1-Typs (Shaker-Typ) in kultivierten Oligodendrozyten-Vorläuferzellen anhand der Transkriptexpression, der Expression von Kv1-Proteinen und der elektrophysiologischen und pharmakologischen Analyse der Membranströme untersucht. Auf mRNA Ebene wurden unterschiediche Kombinationen von Kv1.1, Kv1.4; Kv1.5 und Kv1.6 Transkripten gefunden. Ebenfalls wurde in einigen Zellen eine signifikante Menge an Kv1.2 und Kv1.3 Transkripten gefunden. Die Heterogenität der Transkriptexpression konnte nicht mit Unterschieden in den elektrophysiologischen Eigenschaften korrelliert werden. Die Expression der Kv1 Proteine wurde mit Hilfe von immunozytochemischen Färbungen mit spezifischen polyklonalen Antikörpern gegen die Kanäle Kv1.1 bis Kv1.6 untersucht. Alle Oligodendrozyten-Vorläuferzellen exprimierten die Kanäle Kv1.4 (85% der Zellen), Kv1.5 (99 %) und Kv1.6 (99 %), Kv1.1 Proteine wurden von 10 % der Zellen gebildet. Um den funktionellen Beitrag der Kv1 Kanäle zum Gesamtzellstrom zu bestimmen, wurde die Stromaktivierung und -inaktivierung sowie die Sensitivität der Ströme gegen die spezifischen Kaliumkanalblocker getestet. Dabei wurden durch TEA (1-100 mM), 4-AP (0,125-1 mM) und Chinidin (5-100 mM) jeweils ein großer Teil der Ströme gehemmt, durch CTX, DTX und MCDP wurde die Kanalaktivität nicht beeinflußt. Um den Beitrag der Kanalproteine Kv1.4 bzw. Kv1.1 zu den elektrophysiologischen Eigenschaften des Gesamtzellstromes zu testen, wurden an einzelnen Oligodendrozyten-Vorläuferzellen kombinierte elektrophysiologische Untersuchungen und immunozytochemische Färbungen durchgeführt. Dabei konnten keine signifikanten Unterschiede zwischen Kv1./Kv1.4 positiven und Kv1.1/Kv1.4 negativen Zellen festgestellt werden. Aus den Untersuchungen ergeben sich folgende Schlußfolgerungen: Oligodendrozyten exprimieren eine Vielzahl unterschiedlicher Kv1 Transkripte.Die überwiegende Mehrzahl der Oligodendrozyten-Vorläuferzellen exprimieren die Kv1 Proteine Kv1.4, Kv1.5 und Kv1.6.Der Gesamtzellstrom kann vorwiegend durch Kv1.5 Kanäle oder durch eine Kombination von Kv1.4/Kv1.6 Kanälen sowie durch Mitglieder anderer Familien spannungsabhängiger Kaliumkanäle getragen werden. Um zu untersuchen, ob spannungsabhängige Kaliumkanäle durch die Aktivierung von inhibitorischen Neurotransmitterrezeptoren beeinflußt werden, wurden kultivierte Körnerzellen als Modellsystem verwendet, da diese eine hohe Dichte an Kv Kanälen sowie an GABA Rezeptoren exprimieren. Im "cell-attached" Modus der Patch-Clamp-Technik wurde die Reaktion von einzelnen auswärts rektifizierenden Kaliumkanälen während der GABA-Antwort untersucht. Mit diesem Ansatz konnte gezeigt werden, daß die Öffnungswahrscheinlichkeit dieser Kanäle während der Reaktion der Zelle auf GABA stark zurückgeht. Da Oligodendrozyten-Vorläuferzellen ebenfalls GABAA-Rezeptoren exprimieren, ist anzunehmen, daß deren Aktivierung über einen analogen Mechanismus zur Blockierung von Kaliumkanälen führt. / The membrane current pattern of oligodendrocytes changes dramatically during cell development. In oligodendrocyte precursor cells the membrane conductance is dominated by outwardly rectifying potassium channels, mature oligodendrocytes on the other hand express passive, not voltage-gated potassium channels. The activity of these channels influences the proliferation and differentiation of the cells. In the present work the expression of outwardly-rectifying potassium channels of the Kv1-type (Shaker-type) was analysed in oligodendrocyte precursor cells in culture. Expression of Kv1 transcripts, Kv1 proteins as well as electrophysiological and pharmacological properties of these channels were tested. Different combinations of Kv1.1, Kv1.4, Kv1.5 and Kv1.6 transcripts were detected at mRNA level. In some cells also a significant amount of Kv1.2 and Kv1.3 transcripts was found. The heterogeneity of transcript expression could not be correlated with differences in electrophysiological properties. The expression of Kv1 channel proteins was analysed using immunocytochemical stainings with specific monoclonal antibodies against the channel molecules Kv1.1 to Kv1.6. All oligodendrocyte precursor cells expressed the channel molecules Kv1.4 (85 % of the cells), Kv1.5 (99 %) and Kv1.6 (99 %), Kv1.1 proteins were detected in 10 % of the cells. To find out the functional contribution of Kv1 channels to the whole-cell current of the cells the activation and inactivation characteristics as well as the sensitivity of the potassium current to different potassium channel specific antagonists was tested. Parts of the current were inhibited by TEA (1-100 mM), 4-AP (0,125-1 mM) and Chinidin (5-100 mM), CTX, DTX and MCDP had no effect on the channel activity. To isolate the contribution of the channel molecules Kv1.1 and Kv1.4 the electrophysiological properties of the whole cell current electrophysiological analysis of single cells using whole-cell patch-clamp technique and immunocytochemical stainings were combined. With this method no significant differences between Kv1.1/Kv1.4-positive and Kv1.1/Kv1.4 negative cells could be detected. From these findings the following conclusions could be drawn: Oligodendrocyte precursors express various different Kv1 transcripts.The majority of oligodendrocyte precursor cells expresses the Kv1 proteins Kv1.4, Kv1.5 and Kv1.6.The total current (whole-cell current) most likely is carried through Kv1.5 channels or a combination of Kv1.4/Kv1.6 channels and probably another type of voltage-gated potassium channels. To find out if voltage-gated potassium channels are related to the activation of inhibitory neurotransmitter receptors a model system of cultured granule cells was used. This cell type was selected because they are known to express a high density of Kv channels as well as GABAA receptors as well. The activity of single outwardly rectifying potassium channels was detected using the cell-attached mode of patch-clamp technique. With this method it could be demonstrated that the open probability of voltage-gated potassium channels is markedly decreased during GABAA response. It could be concluded that the activation of GABAA receptors on oligodendrocyte precursor cells leads to the inhibition of potassium channels in the same way as in cultured granule cells.

Oligodendrozyten

Kaliumkanal

Elektrophysiologie

Immunozytochemie

oligodendrocytes

potassium channel

electrophysiology

immunocytochemistry

590 Tiere (Zoologie)

32 Biologie

WE 5460

WW 4290

ddc:590

Synergistic Effect of Titanium Alloy and Collagen Type I on Cell Adhesion, Proliferation and Differentiation of Osteoblast-Like Cells

Röhlecke, Cora, Witt, Martin, Kasper, Michael, Schulze, E., Wolf, C., Hofer, A., Funk, Richard H. W.

04 March 2014

A number of studies have demonstrated the pivotal role of collagen in modulating cell growth and differentiation. In bone, where the extracellular matrix is composed of approximately 85% type I collagen, cellular interaction with matrix components has been shown to be important in the regulation of the osteoblast phenotype. Preservation or enhancement of normal osteoblast function and appositional bone formation after implant placement represents a strategy that can be useful for the purpose of improving osseointegration. In order to further improve biocompatibility, we combined two known favorable compounds, namely the titanium alloy, Ti6A14V, with type I collagen. We assessed the in vitro behavior of primary osteoblasts grown on both fibrillar collagen-coated and tropocollagen-coated Ti6A14V in comparison with uncoated titanium alloy, using an improved adsorption procedure. As parameters of biocompatibility, a variety of processes, including cell attachment, spreading, cytoskeletal organization, focal contact formation, proliferation and expression of a differentiated phenotype, were investigated. Our results demonstrated for the first time that in comparison to uncoated titanium alloy, collagen-coated alloy enhanced spreading and resulted in a more rapid formation of focal adhesions and their associated stress fibers. Growing on collagen-coated Ti6A14V, osteoblasts had a higher proliferative capacity and the intracellular expression of osteopontin was upregulated compared to uncoated titanium alloy. Type I collagen-coated titanium alloy exhibits favorable effects on the initial adhesion and growth activities of osteoblasts, which is encouraging for its potential use as bone graft material. Moreover, collagen type I may serve as an excellent biocompatible carrier for osteotropic factors such as cell adhesion molecules (e.g. fibronectin) or bone-specific growth factors. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Immunozytochemie

Osteoblasten

Titanium

Kollagen-Typ-I

Fokale Adhäsion

Ratte

Titanium

Osteoblasts

Collagen type I

Focal adhesions

Immunocytochemistry

Rat

ddc:610

rvk:XA 10000

Synergistic Effect of Titanium Alloy and Collagen Type I on Cell Adhesion, Proliferation and Differentiation of Osteoblast-Like Cells

Röhlecke, Cora, Witt, Martin, Kasper, Michael, Schulze, E., Wolf, C., Hofer, A., Funk, Richard H. W.

January 2001

A number of studies have demonstrated the pivotal role of collagen in modulating cell growth and differentiation. In bone, where the extracellular matrix is composed of approximately 85% type I collagen, cellular interaction with matrix components has been shown to be important in the regulation of the osteoblast phenotype. Preservation or enhancement of normal osteoblast function and appositional bone formation after implant placement represents a strategy that can be useful for the purpose of improving osseointegration. In order to further improve biocompatibility, we combined two known favorable compounds, namely the titanium alloy, Ti6A14V, with type I collagen. We assessed the in vitro behavior of primary osteoblasts grown on both fibrillar collagen-coated and tropocollagen-coated Ti6A14V in comparison with uncoated titanium alloy, using an improved adsorption procedure. As parameters of biocompatibility, a variety of processes, including cell attachment, spreading, cytoskeletal organization, focal contact formation, proliferation and expression of a differentiated phenotype, were investigated. Our results demonstrated for the first time that in comparison to uncoated titanium alloy, collagen-coated alloy enhanced spreading and resulted in a more rapid formation of focal adhesions and their associated stress fibers. Growing on collagen-coated Ti6A14V, osteoblasts had a higher proliferative capacity and the intracellular expression of osteopontin was upregulated compared to uncoated titanium alloy. Type I collagen-coated titanium alloy exhibits favorable effects on the initial adhesion and growth activities of osteoblasts, which is encouraging for its potential use as bone graft material. Moreover, collagen type I may serve as an excellent biocompatible carrier for osteotropic factors such as cell adhesion molecules (e.g. fibronectin) or bone-specific growth factors. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/610

ddc:610