Elektrophysiologische Charakterisierung künstlicher Ionenkanäle in lebenden Zellen

Fidzinski, Pawel

03 May 2006

Durch Ausübung physiologischer Grundfunktionen spielen Ionenkanäle eine entscheidende Rolle für die reguläre Funktion von Zellen. Zum besseren Verständnis ihrer Struktur und Funktion sind Untersuchungen natürlicher und künstlicher Ionenkanäle wichtige Werkzeuge. Großes analytisches und therapeutisches Potential ist in der Untersuchung künstlicher Kanäle in lebenden Zellen vorhanden, was bisher wenig Beachtung fand. In der vorliegenden Arbeit wurde die Wirkung der künstlichen Ionenkanäle THF-gram, THF-gram-TBDPS sowie linked-gram-TBDPS auf elektrophysiologische Eigenschaften boviner Trabekelwerkszellen des Auges anhand von Patch-Clamp-Untersuchungen im Whole-Cell-Modus analysiert. Die Untersuchung brachte folgende Erkenntnisse: 1. Die Inkorporation aller drei Verbindungen war erfolgreich, was sich durch Anstieg der Stromdichte und Verschiebung des Umkehrpotentials zeigte. 2. Einbau von THF-gram und THF-gram-TBDPS war mit dem Überleben der Zellen vereinbar, während linked-gram-TBDPS aufgrund einer sehr potenten Antwort bereits bei sehr geringen Konzentrationen zum raschen Zelltod führte. 3. Eine Asymmetrie der Stromantwort zugunsten stärkerer Auswärtsströme wurde bei THF-gram und in schwächerer Ausprägung bei THF-gram-TBDPS festgestellt. Linked-gram-TBDPS zeigte keine derartige Asymmetrie. 4. Unter Verwendung von Cs+ als Ladungsträger war der beobachtete Anstieg der Stromdichte bei allen drei Verbindungen eindeutig stärker als unter physiologischen Bedingungen (Na+/K+). 5. Die dargestellten Erkenntnisse sind ein erster Schritt zur therapeutischen Anwendung von künstlichen Ionenkanälen. Eine Weiterentwicklung in Richtung höherer Selektivität und besserer Kontrolle ist jedoch genauso erforderlich wie die Klärung der klinischen Umsetzbarkeit. / Ion channels play a pivotal role for regular cell function. To better understand their structure and function, investigation of both natural and artificial ion channels is being performed to date. Investigation of artificial channels in living cells hides a big potential, however, little attention has been paid to this field so far. In this work, the effect of the artificial ion channels THF-gram, THF-gram-TBDPS and linked-gram-TBDPS on electrophysiological properties of bovine trabecular meshwork cells was investigated with the patch-clamp-technique. Following results were obtained: 1. Incorporation of all three compounds was successful, which was proven by increase of current density and cell depolarisation. 2. The cells survived after incorporation of THF-gram and THF-gram-TBDPS but not after linked-gram-TBDPS, which resulted in cell death at very low concentrations. 3. Larger outward currents were observed with THF-gram and, at a lower extent, with THF-gram-TBDPS. Linked-gram-TBDPS did not show such an asymmetry. 4. With Cs+ as charge carrier all three compunds showed a stronger increase of current density than under physiological conditions (Na+/K+). 5. The decribed results are a first step towards therapeutic application of artificial ion channels, however, further development towards higher selectivity and better control is as necessary as clarification of clinical feasibility.

künstliche Ionenkanäle

Patch-Clamp-Technik

Gramicidin A

Trabekelwerk des Auges

artificial ion channels

patch-clamp-technique

gramicidin A

trabecular meshwork

610 Medizin

33 Medizin

WE 5460

ddc:610

Engineering of Light-Gated Artificial Ion Channels

Steller, Laura Florentina

26 January 2007

The goal of this project is the development of artificial ion channels that can be actuated by light and thus controlled efficiently. Our artificial system is composed of two regions: the gate and the body part. The gate part is based on light-responsive azo groups while the body part is formed by calix[4]resorcinarene. Key of controlling mechanism is the conformational change between cis and trans isomers, which is translated into movement of the gate. Light-gated artificial ion channels are aimed at eliminating of the stochastic mechanism of artificial ion channels. Such a reversible photocontrol should be a powerful tool for using artificial ion channels as the basis for the development of new pharmaceuticals and drug delivery systems, as photoswitches, and in the field of microfluidics.

artificial ion channel

calixresorcinarene

light switchable gate

patch clamp

künstliche Ionenkanäle

Calixresorcinarene

photogesteuerter Verschluss

Patch Clamp

ddc:540

rvk:WE 5460

Ionenkanal

Patch-Clamp-Methode

Engineering of Light-Gated Artificial Ion Channels

Steller, Laura Florentina

18 December 2006

The goal of this project is the development of artificial ion channels that can be actuated by light and thus controlled efficiently. Our artificial system is composed of two regions: the gate and the body part. The gate part is based on light-responsive azo groups while the body part is formed by calix[4]resorcinarene. Key of controlling mechanism is the conformational change between cis and trans isomers, which is translated into movement of the gate. Light-gated artificial ion channels are aimed at eliminating of the stochastic mechanism of artificial ion channels. Such a reversible photocontrol should be a powerful tool for using artificial ion channels as the basis for the development of new pharmaceuticals and drug delivery systems, as photoswitches, and in the field of microfluidics.

info:eu-repo/classification/ddc/540

ddc:540

Ionenkanal; Patch-Clamp-Methode