Goran Klenkar

Differential protein assembly on micropatterned surfaces with tailored molecular and surface multivalency.

Life is a thing taken for granted by most. However, it is the life-long quest of many to unravel the mysteries of it. Understanding and characterizing the incomprehensively complex molecular interaction networks within a biological organism, which defines that organism, is a vital prerequisite to understand life itself. Already, there has been a lot of research conducted and a large knowledge has been obtained about these pathways over, especially, the last century. We have seen the fruits of these labors in e.g. the development of medicines which have been able to cure or at least arrest many diseases and conditions. However, many diseases are still incurable (e.g. cancer) and a lot more work is still needed for understanding them fully and designing successful treatments. This work describes a generic analytical tool platform for aiding in more efficient (bio)molecular interaction mapping analyses; protein microarray chips. Microarray chips are surfaces with micrometer sized features with the possibility of studying the interactions of many (thousands to tens of thousands) (bio)molecules in parallel. This allows for a higher throughput of analyses to be performed at a reduced time and cost. Protein microarrays have been around for approximately a decade, following in the footsteps of the, so far, more successfully used DNA microarrays (developed in the 1990s). Microarrays of proteins are more difficult to produce because of the more complex nature of proteins as compared to DNA. In our work we have constructed model surfaces which allow for the stable, highly oriented, and functional immobilization of proteins in an array format. Our capture molecules are based on multivalent units of the chelator nitrilotriacetic acid (NTA), which is able to bind histidine-tagged proteins. Furthermore, we have explored an approach for studying lipid membrane bound systems, e.g. receptor-ligand interactions, in a parallelized, microarray format. The approach relies on the addressable, DNA-mediated adsorption of tagged lipid vesicles. In an analogous work we have used the protein microarray concept for the detection of four common narcotics (heroin, amphetamine, ecstasy, and cocaine). The detection is based on the displacement of loosely bound antibodies from surface array positions upon injection of a specific target analyte, i.e. a narcotic substance. The proof-of-concept chip can easily be expanded to monitor many more narcotic substances. In addition, we have also been able to simultaneously detect the explosive trinitrotoluene (TNT) along with the narcotics, showing that the chip is a versatile platform for the detection of virtually any type of harmful or illegal compound. This type of biosensor system is potentially envisaged to be used in the fight against crime, terrorism, drug abuse etc. Infrared reflection absorption spectroscopy together with ellipsometry has been used to characterize molecular layers used in the fabrication processes of the microarray features. Imaging surface plasmon resonance operating in the ellipsometric mode is subsequently used for functional evaluation of the microarrays using a well-defined receptor-ligand model system. This approach allows simultaneous and continuous monitoring of binding events taking place in multiple regions of interest on the microarray chip. A common characteristic of all the instrumentation used is that there is no requirement for labeling of the biomolecules to be detected, e.g. with fluorescent or radioactive probes. This feature allows for a flexible assay design and the use of more native proteins, without any time-consuming pretreatments.

Self-Assembled Monolayers Containing Terminal Mono-, Bis-, and Tris-nitrilotriacetic Acid Groups: Characterization and Application

We have undertaken a structural and functional study of self-assembled monolayers (SAMs) formed on gold from a series of alkylthiol compounds containing terminal multivalent chelators (MCHs) composed of mono-, bis-, and tris-nitrilotriacetic acid (NTA) moieties. SAMs were formed from single-component solutions of the mono-, bis-, and tris-NTA compounds, as well as from mixtures with a tri(ethylene glycol)-terminated alkylthiol (EG(3)). Contact angle goniometry, null ellipsometry, and infrared spectroscopy were used to explore the structural characteristics of the MCH SAMs. Ellipsometric measurements show that the amount of the MCH groups on surfaces increases with increasing mol % of the MCH thiols in the loading solution up to about 80 mol %. We also conclude that mixed SAMs, prepared in the solution composition regime 0-30 mol % of the MCH thiols, consist of a densely packed alkyl layer, an amorphous ethylene glycol layer, and an outermost layer of MCH groups exposed toward the ambient. Above 30 mol %, a significant degree of disorder is observed in the SAMs. Finally, functional evaluation of the three MCH SAMs prepared at 0-30 mol% reveals a consistent increase in binding strength with increasing multivalency. The tris-NTA SAM, in particular, is enabled for stable and functional immobilization of a His6-tagged extracellular receptor subunit, even at low chelator surface concentrations, which makes it suitable for applications when a low surface density of capturing sites is desirable, e.g., in kinetic analyses.

Addressable adsorption of lipid vesicles and subsequent protein interaction studies

We demonstrate a convenient chip platform for the addressable immobilization of protein-loaded vesicles on a microarray for parallelized, high-throughput analysis of lipid-protein systems. Self-sorting of the vesicles on the microarray was achieved through DNA bar coding of the vesicles and their hybridization to complementary strands, which are preimmobilized in defined array positions on the chip. Imaging surface plasmon resonance in ellipsometric mode was used to monitor vesicle immobilization, protein tethering, protein-protein interactions, and chip regeneration. The immobilization strategy proved highly specific and stable and presents a mild method for the anchoring of vesicles to predefined areas of a surface, while unspecific adsorption to both noncomplementary regions and background areas is nonexistent or, alternatively, undetectable. Furthermore, histidine-tagged receptors have been stably and functionally immobilized via bis-nitrilotriacetic acid chelators already present in the vesicle membranes. It was discovered though that online loading of proteins to immobilized vesicles leads to cross contamination of previously loaded vesicles and that it was necessary to load the vesicles offline in order to obtain pure protein populations on the vesicles. We have used this cross-binding effect to our benefit by coimmobilizing two receptor subunits in different ratios on the vesicle surface and successfully demonstrated ternary complex formation with their ligand. This approach is suitable for mechanistic studies of complex multicomponent analyses involving membrane-bound systems.