H. Engelkamp

A virus-based single-enzyme nanoreactor

Most enzyme studies are carried out in bulk aqueous solution, at the so-called ensemble level, but more recently studies have appeared in which enzyme activity is measured at the level of a single molecule, revealing previously unseen properties. To this end, enzymes have been chemically or physically anchored to a surface, which is often disadvantageous because it may lead to denaturation. In a natural environment, enzymes are present in a confined reaction space, which inspired us to develop a generic method to carry out single-enzyme experiments in the restricted spatial environment of a virus capsid. We report here the incorporation of individual horseradish peroxidase enzymes in the inner cavity of a virus, and describe single-molecule studies on their enzymatic behaviour. These show that the virus capsid is permeable for substrate and product and that this permeability can be altered by changing pH.

Macroscopic Hierarchical Surface Patterning of Porphyrin Trimers via Self-Assembly and Dewetting

The use of bottom-up approaches to construct patterned surfaces for technological applications is appealing, but to date is applicable to only relatively small areas (∼10 square micrometers). We constructed highly periodic patterns at macroscopic length scales, in the range of square millimeters, by combining self-assembly of disk-like porphyrin dyes with physical dewetting phenomena. The patterns consisted of equidistant 5-nanometer-wide lines spaced 0.5 to 1 micrometers apart, forming single porphyrin stacks containing millions of molecules, and were formed spontaneously upon drop-casting a solution of the molecules onto a mica surface. On glass, thicker lines are formed, which can be used to align liquid crystals in large domains of square millimeter size.

Molecular materials based on crown ether functionalized phthalocyanines

This micro-review presents an overview of molecular materials derived from phthalocyanines which are substituted with crown ether rings. These flat disk-like molecules can self-assemble into ordered, well-defined structures with or without the aid of alkali metal ions. Highly ordered assemblies of crown ether phthalocyanines are capable of transporting electrons and ions, which is of interest for sensor applications.

Photochemical Surface Patterning by the Thiol-Ene Reaction†

The immobilization of proteins on solid substrates while controlling the size and dimensions of the generated patterns is increasingly relevant in biotechnology. Site-specific immobilization and thus control over the orientation of proteins is particularly important because, as opposed to nonspecific adsorption, it generates homogeneous surface coverage and accessibility to the active site of the protein. Consequently, different types of bioorthogonal reactions have been developed to attach proteins site-specifically to surfaces and to control protein patterning. Herein, we report the photochemical coupling of olefins to thiols to generate a stable thioether bond for the covalent surface patterning of proteins and small molecules. This reaction has been applied previously in solution for carbohydrate and peptide coupling. The thiol-ene photoreaction proceeds at close to visible wavelengths (l = 365–405 nm) and in buffered aqueous solutions. As a result of its specificity for olefins, this photoreaction can be considered to be bioorthogonal, unlike other photochemical methods used previously for protein immobilization. To adopt the thiol-ene reaction for the immobilization of biomolecules, surfaces functionalized with thiols and biomolecules derivatized with olefins were prepared (Figure 1). Polyamidoamine (PAMAM) dendrimers were attached covalently to silicon oxide surfaces. An aminocaproic acid spacer was attached to the dendrimers to create distance from the surface. Cystamine was coupled to the spacer, and subsequent reduction of the disulfide yielded the desired thiolterminated surfaces. A liquid layer of terminal-olefinfunctionalized molecules dissolved in ethylene glycol was spread onto these wafers, which were then covered immediately with a photomask. Subsequent irradiation of the surfaces through the photomask led to patterning with adducts of covalently attached thioethers. To establish the method, we photochemically attached the biotin derivative 1 to a thiol-functionalized surface as described above (Figure 1). After the removal of unreacted biotin molecules, the surface was incubated with Cy5-labeled streptavidin (SAv) to produce a SAv-patterned surface. Fluorescence images of the resulting surface (Figure 1) demonstrated that lateral gradients and patterns with micrometer-sized features (5–100 mm) over areas of centimeters in width (Figure 1A) were readily accessible. Figure 1B,C and the fluorescence-intensity profile in Figure 1D show that the patterns have a well-defined shape and are homogeneous over large distances. When prolonged sonication (4 h) and stringent washing were carried our after irradiation, SAv patterns with similar fluorescence intensities were observed, whereas control experiments with biotin that lacked the olefin linker showed no distinctive SAv patterns. These results indicate that the covalent attachment of biotin to the surface occurs specifically through the proposed thiol-ene reaction and that the nonspecific adsorption of biotin is insignificant. Figure 1E shows that the amount of material immobilized can be modified by changing the irradiation time. The procedure reproducibly requires a short irradiation time of 60 s to yield sufficient surface coverage for fabricating dense SAv patterns. To obtain homogeneous fluorescence signals of the patterns, the starting concentration of the solution that is drop cast onto the surface is also important. When the solution of 1 was diluted (to 1 mm), the Cy5-fluorescence intensity decreased considerably. Further dilution (below 500 mm) resulted eventually in disrupted SAv patterns. The application of more concentrated solutions of 1 (> 20 mm) resulted in the saturation of the fluorescence intensity of the SAv patterns. This behavior corresponds well with the effects observed upon varying the irradiation time. Longer irradi[*] Dr. D. N sse, Dr. H. Schroeder, Dr. R. Wacker, Prof. Dr. C. M. Niemeyer Faculty of Chemistry Biological-Chemical Microstructuring Technical University of Dortmund Otto-Hahn-Strasse 6, 44227 Dortmund (Germany) Fax: (+49)231-755-7082 E-mail: christof.niemeyer@tu-dortmund.de

Selection of supramolecular chirality by application of rotational and magnetic forces

Many essential biological molecules exist only in one of two possible mirror-image structures, either because they possess a chiral unit or through their structure (helices, for example, are intrinsically chiral), but so far the origin of this homochirality has not been unraveled. Here we demonstrate that the handedness of helical supramolecular aggregates formed by achiral molecules can be directed by applying rotational, gravitational and orienting forces during the self-assembly process. In this system, supramolecular chirality is determined by the relative directions of rotation and magnetically tuned effective gravity, but the magnetic orientation of the aggregates is also essential. Applying these external forces only during the nucleation step of the aggregation is sufficient to achieve chiral selection. This result shows that an almost instantaneous chiral perturbation can be transferred and amplified in growing supramolecular self-assemblies, and provides evidence that a falsely chiral influence is able to induce absolute enantioselection.

A virus-based biocatalyst

Virus particles are probably the most precisely defined nanometre-sized objects that can be formed by protein self-assembly. Although their natural function is the storage and transport of genetic material, they have more recently been applied as scaffolds for mineralization and as containers for the encapsulation of inorganic compounds. The reproductive power of viruses has been used to develop versatile analytical methods, such as phage display, for the selection and identification of (bio)active compounds. To date, the combined use of self-assembly and reproduction has not been used for the construction of catalytic systems. Here we describe a self-assembled system based on a plant virus that has its coat protein genetically modified to provide it with a lipase enzyme. Using single-object and bulk catalytic studies, we prove that the virus-anchored lipase molecules are catalytically active. This anchored biocatalyst, unlike man-made supported catalysts, has the capability to reproduce itself in vivo, generating many independent catalytically active copies.

The enzyme mechanism of nitrite reductase studied at single-molecule level

A generic method is described for the fluorescence “readout” of the activity of single redox enzyme molecules based on Förster resonance energy transfer from a fluorescent label to the enzyme cofactor. The method is applied to the study of copper-containing nitrite reductase from Alcaligenes faecalis S-6 immobilized on a glass surface. The parameters extracted from the single-molecule fluorescence time traces can be connected to and agree with the macroscopic ensemble averaged kinetic constants. The rates of the electron transfer from the type 1 to the type 2 center and back during turnover exhibit a distribution related to disorder in the catalytic site. The described approach opens the door to single-molecule mechanistic studies of a wide range of redox enzymes and the precise investigation of their internal workings.

Preparation of Biomolecule Microstructures and Microarrays by Thiol–ene Photoimmobilization

A mild, fast and flexible method for photoimmobilization of biomolecules based on the light‐initiated thiol–ene reaction has been developed. After investigation and optimization of various surface materials, surface chemistries and reaction parameters, microstructures and microarrays of biotin, oligonucleotides, peptides, and MUC1 tandem repeat glycopeptides were prepared with this photoimmobilization method. Furthermore, MUC1 tandem repeat glycopeptide microarrays were successfully used to probe antibodies in mouse serum obtained from vaccinated mice. Dimensions of biomolecule microstructures were shown to be freely controllable through photolithographic techniques, and features down to 5 μm in size covering an area of up to 75×25 mm were created. Use of a confocal laser microscope with a UV laser as UV‐light source enabled further reduction of biotin feature size opening access to nanostructured biochips.

Single-biomolecule kinetics: the art of studying a single enzyme

The potential of single-enzyme studies to unravel the complex energy landscape of these polymeric catalysts is the next critical step in enzymology. From its inception in Rotmans emulsion experiments in the 1960s, the field of single-molecule enzymology has now advanced into the time-resolved age. Technological advances have enabled individual enzymatic turnover reactions to be observed with a millisecond time resolution. A number of initial studies have revealed the underlying static and dynamic disorder in the catalytic rates originating from conformational fluctuations. Although these experiments are still in their infancy, they may be able to relate the topography of the energy landscape to the biological function and regulation of enzymes. This review summarizes some of the experimental techniques and data-analysis methods that have been used to study individual enzyme molecules in search of a deeper understanding of their kinetics.

Shaping polymersomes into predictable morphologies via out-of-equilibrium self-assembly

Polymersomes are bilayer vesicles, self-assembled from amphiphilic block copolymers. They are versatile nanocapsules with adjustable properties, such as flexibility, permeability, size and functionality. However, so far no methodological approach to control their shape exists. Here we demonstrate a mechanistically fully understood procedure to precisely control polymersome shape via an out-of-equilibrium process. Carefully selecting osmotic pressure and permeability initiates controlled deflation, resulting in transient capsule shapes, followed by reinflation of the polymersomes. The shape transformation towards stomatocytes, bowl-shaped vesicles, was probed with magnetic birefringence, permitting us to stop the process at any intermediate shape in the phase diagram. Quantitative electron microscopy analysis of the different morphologies reveals that this shape transformation proceeds via a long-predicted hysteretic deflation–inflation trajectory, which can be understood in terms of bending energy. Because of the high degree of controllability and predictability, this study provides the design rules for accessing polymersomes with all possible different shapes.