New synthetic strategies to tethered bilayer lipid membranes

Tethered bilayer lipid membranes provide an efficient, stable and versatile platform for the investigation of integrated membrane proteins. However, the incorporation of large proteins, as well as of proteins with a large submembrane part is still a very critical issue and therefore, further optimisation of the system is necessary. The central element of a tBLM is a lipid bilayer. Its proximal leaflet is, at least to some extend, covalently attached to a solid support via a spacer group. The anchor lipid consists of three distinct parts, a lipid headgroup, a spacer group and an anchor. All parts together influence the final bilayer properties. In the frame of this work, the synthesis of new thiolipids for tBLMs on gold has been investigated. The aim was to obtain molecules with longer spacers in order to increase the submembrane space. The systems obtained have been characterized using SPR and EIS. The results obtained during this study are multiple. First, the synthesis of a previously synthesized architecture was successfully scaled up in an industrial lab using a new synthetic approach. The synthesis of large amounts is now feasible. Then, the synthesis of the new thiolipids was carried out taking into account the following requirements: the increase of the submembrane space by having longer ethyleneglycol spacers, the attachment of the molecules to a gold substrate via a thiol bond, and the tunability of the lateral mobility by changing the lipid headgroup. Three different synthetic strategies have been investigated. The polymeric approach did not prove to be successful, merely because of the broad molecular weight distribution. The synthesis of heterofunctionally protected oligoethyleneglycols allowed to obtain ethyleneglycol moieties with 6 and 8 units, but the tedious purification steps gave very low yields. Finally, the block by block synthesis using ethyleneglycol precursors proved to be an efficient and fast method to synthesize the target molecules. Indeed, these were obtained with very high yields, and the separation was very efficient. A whole family of new compounds was obtained, having 6, 8 and 14 ethyleneglycol units and with mono- or diphytanyl lipid headgroups. This new pathway is a very promising synthetic strategy that can be used further in the development of new compounds of the tether system. The formation of bilayers was investigated for the different thiolipids mainly by using EIS. The electrical properties of a bilayer define the quality of the membrane and allow the study of the functionality of proteins embedded in such a system. Despite multiple trials to improve the system using self assembly, Langmuir Blodgett transfer, and detergent mixed vesicles, the new polymer thiolipids did not show as high electrical properties as tBLMs reported in the literature. Nevertheless, it was possible to show that a bilayer could be obtained for the different spacer lengths. These bilayers could be formed using self assembly for the first monolayer, and two different methods for bilayer formation, namely vesicle fusion and solvent exchange. We could furthermore show functional incorporation of the ion carrier valinomycin: the selective transport of K+ ions could be demonstrated. For DPHL, it was even possible to show the functional incorporation of the ion channel gramicidin. The influence of the spacer length is translated into an increase of the spacer capacitance, which could correspond to an increase in the capacity of charge accumulation in the submembrane space. The different systems need to be further optimised to improve the electrical properties of the bilayer. Moreover, the incorporation of larger proteins, and proteins bearing submembrane parts needs to be investigated.

Ion channels in mixed tethered bilayer lipid membranes

Mixed tethered bilayer lipid membranes (tBLMs) are described based on the self-assembly of a monolayer on template stripped gold, of an archea analogue thiolipid, 2,3-di-o-phytanyl-sn-glycerol-1-tetraethylene glycol-D,L--lipoic acid ester lipid (DPTL), and a newly designed dilution molecule, tetraethylene glycol-D,L--lipoic acid ester (TEGL). The usage of spacer and addition of extra dilution molecules between the substrate and the bilayer is that this architecture provides an ionic reservoir underneath the membrane, avoiding direct contact of the embedded membrane proteins with the gold electrodes and increasing the lateral diffusion of the bilayer, thus allowing for the incorporation of complex channels proteins which are failed in non-diluted systems. The tBLM is completed by fusion of liposomes made from a mixture of 1,2-diphythanolyl-sn-glycero-3-phosphocholine (DPhyPC), cholesterol, and 1,2-diphytanoyl-sn-Glycero-3-phosphate (DPhyPG) in a molar ratio of 6:3:1. Varying the mixing ratio, the optimum mixing ratio was obtained at a dilution factor of DPTL and TEGL at 90%:10%. Only under these conditions, the mixed tBLM showed electrical properties, as shown by EIS, which are comparable to a BLM. With higher dilution factors, a defect-free lipid bilayer was not formed. Formation of bilayers have been characterized by different techniques, such as surface plasmon resonance (SPR), electrochemical impedance spectroscopy (EIS), atomic force microscopy (AFM), and quartz crystal microbalance (QCM). Different proteins such as hemolysin, melittin, gramicidin, M2, Maxi-K, nAChR and bacteriohodopsin are incorporated into these tBLMs as shown by SPR and EIS studies. Ionic conductivity at 0 V vs. Ag|AgCl, 3M KCl were measured by EIS measurements. Our results indicate that these proteins have been successfully incorporated into a very stable tBLM environment in a functionally active form. Therefore, we conclude that the mixed tBLMs have been successfully designed as a general platform for biosensing and screening purposes of membrane proteins.

Mechanismen und funktionelle Konsequenzen der Chlorid-Homöostase in unreifen Neuronen des Neocortex

GABA, der wichtigste inhibitorische Neurotransmitter im adulten Gehirn, bewirkt im unreifen Nervensystem eine Membrandepolarisation, vermutlich aufgrund der erhöhten intrazellulären Chloridkonzentration ([Cl-]i) in unreifen Nervenzellen. GABAerge Membrandepolarisationen sind essentiell für die korrekte Entwicklung des zentralen Nervensystems und die Entstehung kortikaler Netzwerkaktivität. Im Rahmen der vorliegenden Arbeit wurde mit Hilfe elektrophysiologischer und immunohistochemischer Methoden die Regulation der Chlorid-Homöostase in unreifen Neuronen des Neokortex untersucht. Die Experimente wurden an Cajal-Retzius (CR) Zellen, einem transienten Zelltyp der Marginalzone, in akuten Hirnschnittpräparaten neonataler Ratten (P0-P3) durchgeführt. Es konnte gezeigt werden, dass CR Zellen eine hohe native [Cl-]i von ~30 mM aufweisen. Die hohe [Cl-]i wurde ausschließlich durch Bumetanid sensitiven und Na+-abhängigen aktiven Cl--Transport aufrechterhalten, was auf eine Cl--Akkumulation durch den Kationen-Chlorid-Cotransporter NKCC1 schließen lässt. Diese pharmakologischen Hinweise konnten durch den Nachweis der Expression von NKCC1 in der gesamten Marginalzone, speziell in CR Zellen, bestätigt werden. Die Transportgeschwindigkeit der NKCC1-abhängigen Cl--Akkumulation war gering, was auf eine limitierte Transportkapazität schließen lässt. In Übereinstimmung mit diesem Befund konnte gezeigt werden, dass die Cl--Leitfähigkeit in CR Zellen äußerst klein ist, so dass die NKCC1-abhängige Cl--Akkumulation ausreichend war, um unter Ruhebedingungen eine hohe [Cl-]i zu gewährleisten. Aufgrund dieser hohen [Cl-]i waren GABAA-Rezeptor vermittelte Antworten in CR Zellen exzitatorisch. Die Kapazität des NKCC1-vermittelten Cl--Transportes in CR Zellen konnte durch höherfrequente Stimulation überschritten werden, was dazu führte, dass die [Cl-]i abnahm und GABAerge Antworten unter diesen Bedingungen inhibitorisch wurden. Die inhibitorische Wirkung von GABA in CR Zellen wurde überwiegend durch die Reduktion des Eingangswiderstandes der Zelle vermittelt und beruhte nicht auf einer Verschiebung der Aktionspotentialschwelle.