Louis Tiefenauer

Adhesion proteins for a tight neuron–electrode contact

The neural cell adhesion molecules axonin-1 and NgCAM have been genetically engineered and covalently immobilized on glass and silicon oxide surfaces in their correct orientation. Surfaces treated with these adhesion molecules were used as substrates for culturing dorsal root ganglion neurons. The cleft between the neuron cell membrane and the surface was determined using fluorescence interference contrast (FLIC) microscopy. For comparison, cell--material distances on laminin, RGDC, polylysine and amino-terminated surfaces were measured. When the neurons grow on axonin-1 the cell--surface distance is at a minimum (37 nm) probably because the glycocalyx hinders a closer contact. A selective treatment of extracellular electrodes with axonin-1 could be used to improve the cell-material contact and thus increase extracellularly recorded signals.

Biotinyl-estradiol derivatives in enzyme immunoassays: Structural requirements for optimal antibody binding

The use of the avidin/biotin complex in immunoassays is well documented. No comprehensive studies, however, are available on the structural requirements of the linkage between biotin and small molecules to get an optimal antigen-antibody interaction. We have synthesized seven different biotinylated estradiol derivatives. They were evaluated in an antibody- and in an antigen-immobilized enzyme immunoassay system. All three derivatives lacking a spacer group were useless for use in immunoassays, demonstrating the importance of a long distance between the biotin- and estradiol-moiety. In addition, the chemical structure of the linkage at the site of attachment to the steroid skeleton is very important for the antibody recognition: it may either be rigid but identical to that one used in the immunogen (6-carboxymethyloxime), or must be structurally flexible as exemplified by a 6-amido-linkage. A rigid structure (hydrazone) different from that of the immunogen absolutely prevents antibody binding.

ANTIGEN- VERSUS ANTIBODY-IMMOBILIZED ELISA PROCEDURES BASED ON A BIOTINYL-ESTRADIOL CONJUGATE

A biotinyl-6 alpha-estradiol derivative (Bio-E2) was synthesized and used as the key component in antigen- and antibody-immobilized ELISA techniques, and the relative merits of the two methods were compared. A precise and reproducible antigen-immobilization was achieved in avidin-coated microtiter plates with Bio-E2. This assay, when completed by the incubation with primary antibody and second antibody-peroxidase conjugate, has a very low detection limit (6 pg/ml estradiol) but required a long incubation time with primary antibody to reach equilibrium. At non-equilibrium conditions, using a high antibody concentration, the assay could be very fast and sensitive. In the antibody-immobilized assay, the Bio-E2 was added to compete with the estradiol present in the calibrator or sample and visualized with a streptavidin-peroxidase conjugate. The detection limit is higher (34 pg/ml), but the specificity was superior and the incubation time to reach equilibrium shorter as compared to the antigen-immobilized assay. Therefore, the antibody-immobilized assay appeared to be ideal for the classical ELISA technique, whereas the antigen-immobilized method seemed to be best suited for automated assay systems using antibody in excess.

Prevention of bridge binding in immunoassays: A general estradiol tracer structure

Iodinated estradiol tracers were synthesized with three different bridges connecting the radiolabelled moiety to the steroid core: Hemisuccinate, carboxymethyloxime and amide. Taking these iodinated tracers in combination with ten antibodies raised against estradiol-6-CMO-albumin, titers and slopes of calibration curves have been compared to the corresponding data using a 3H tracer. The data indicate that the tracer with the amide bridge is recognized similarly to the tritiated estradiol by all antibodies tested, whereas the two other iodinated tracers exhibit substantial bridge binding. The results suggest that the amide tracer structure can generally be used to improve the quality of estradiol antibodies suffering from bridge binding effects.

Immunoscintigraphic localization of inflammatory lesions: concept, radiolabelling and in vitro testing of a granulocyte specific antibody.

Current nuclear medicine techniques for the localization of inflammatory processes are based on injection of111In labelled autologous granulocytes which need to be isolated and radiolabelled in vitro before reinjection. A new technique is presented here that obviates the need for cell isolation by the direct intravenous injection of a granulocyte specific123I labelled monoclonal antibody. In this publication the basic parameters of the antibody granulocyte interaction are described. Antibody binding does not inhibit vital functions of the granulocytes, such as chemotaxis and superoxide generation. Scatchard analysis of binding data reveals an apparent affinity of the antibody for granulocytes of 6.8 × 109 1/mol and approximately 7.1 × 104 binding sites per cell. Due to the high specificity of the antibody, the only expected interference is from CEA producing tumors.

Integration and recording of a reconstituted voltage-gated sodium channel in planar lipid bilayers.

Functional assays for membrane proteins become increasingly important in biosciences. We demonstrate the integration of reconstituted bacterial voltage-gated sodium channels (NaChBac) into preformed free-standing lipid bilayers by using the nystatin-ergosterol method to promote proteoliposome fusion. Vesicle delivery and subsequent NaChBac activity were monitored, the orientation of the transferred ion channels was assessed measuring at both, positive and negative holding potentials and the channel specificity was demonstrated by adding the blocker nimodipine. A conductance of 120 pS per channel and an opening time in the range of seconds have been observed. Interestingly, we found that fusion of proteoliposomes into preformed free-standing bilayers is limited, if hydrophobically silanized silicon nitride membranes are used as the supporting material. In this case the diameter of the liposome had to be at least 20 times smaller compared to that of the pore to render fusion possible.

Prevention of bridge binding effects in haptenic immunoassay systems exemplified by an iodinated radioimmunoassay for melatonin

Antisera used in immunological assay systems for small molecular weight substances are routinely prepared by coupling the hapten to a carrier protein via a chemical linker. Often this bridge is partly recognized by the antibody, resulting in reduced sensitivity when an identically structured tracer (e.g. iodine-labelled) is used. Historically, the problem was solved by changing the linking structures in the tracer. An alternative way is exemplified by the development of a very sensitive and specific iodinated radioimmunoassay for melatonin. This new approach involves the design of a linkage identical in the tracer and the antigen that is both very short and closely resembling the structure of the analyte itself.

Charge transport effects in ferrocene–streptavidin multilayers immobilized on electrode surfaces

Abstract Streptavidin (SAv) has been modified by covalent coupling of ferrocene (Fc) electron-relay groups to lysine-residues of the protein backbone. Reagent ratios were varied to obtain conjugates with three to 16 Fc groups per SAv. Biotin was covalently attached to gold electrodes for the anchoring of the conjugate monolayers. A method was devised to produce in situ bisbiotin functionalities that efficiently cross-linked Fc 16 SAv to form multilayer electrode coatings. The electrochemical charge transport properties of the coatings were examined by cyclic voltammetry. The characteristic current density i E measuring the rate of charge transport was 1 mA cm −2 for one monolayer of Fc 16 SAv. It was found that the transport of electrochemical charge through the Fc-containing SAv system is a diffusion-like process, as evidenced by the proportionality of the peak current and the square root of sufficiently high scan rate, and the inverse dependence of i E on the number (thickness) of Fc 16 SAv layers.

Redox labelled avidin for enzyme sensor architectures.

Conjugates of avidin with ferrocene and with microperoxidase 8 have been used as electrochemically active molecular building blocks. Assemblies of the conjugates with biotinylated glucose oxidase or lactate oxidase on gold electrodes were tested as enzyme sensors for glucose and lactate. The electrochemical detection is based either on ferrocene-mediated oxidation of the substrate in oxygen-free solution, or on microperoxidase-catalysed reduction of H2O2 which is enzymatically produced from the substrate and molecular oxygen. Glucose and lactate were detectable with both detection principles in concentrations down to 1 or 0.1 mM, respectively. The molecular architecture concept allows quick adaptation of the sensors to other analytes, and it provides a platform for arrays of sensors with different selectivity.

Electrochemical rectification by redox-labeled bioconjugates: Molecular building blocks for the construction of biodiodes

In the present work, we describe the properties of a bifunctional redox-labeled bioconjugate at electrode surfaces mediating the electron transfer across the electrode-electrolyte interface. We show that the assembly of ferrocene-labeled streptavidin on biotinylated electrodes results in a reproducible unidirectional current flow in the presence of electron donors in solution. Such rectifying films were built up by spontaneous binding of tetrameric streptavidin molecules to biotin centers immobilized on the electrode surface. Due to the high affinity of biotin to streptavidin, such bifunctional films completely bind any biotinylated compounds. The charge transport between donors in solution and the Au electrode is mediated by the ferrocene moieties, allowing us to develop a molecular rectifier. Our experimental results suggest that such redox-labeled proteins with a high binding capacity constitute a promising alternative to organic compounds used in molecular electronics.