Christian B. Rosen

Template-directed covalent conjugation of DNA to native antibodies, transferrin and other metal-binding proteins

DNA-protein conjugates are important in bioanalytical chemistry, molecular diagnostics and bionanotechnology, as the DNA provides a unique handle to identify, functionalize or otherwise manipulate proteins. To maintain protein activity, conjugation of a single DNA handle to a specific location on the protein is often needed. However, preparing such high-quality site-specific conjugates often requires genetically engineered proteins, which is a laborious and technically challenging approach. Here we demonstrate a simpler method to create site-selective DNA-protein conjugates. Using a guiding DNA strand modified with a metal-binding functionality, we directed a second DNA strand to the vicinity of a metal-binding site of His6-tagged or wild-type metal-binding proteins, such as serotransferrin, where it subsequently reacted with lysine residues at that site. This method, DNA-templated protein conjugation, facilitates the production of site-selective protein conjugates, and also conjugation to IgG1 antibodies via a histidine cluster in the constant domain.

Efficient colorimetric and fluorescent detection of fluoride in DMSO–water mixtures with arylaldoximes

Fluoride detection through hydrogen bonding or deprotonation is most commonly achieved using amide, urea or pyrrole derivatives. The sensor molecules are often complex constructs and several synthetic steps are required for their preparation. Here we report the discovery that simple arylaldoximes have remarkable properties as fluoride anion sensors, providing distinct colorimetric or fluorescent readouts, depending on the structure of the arylaldoxime. The oximes showed exceptional selectivity towards fluoride over other typical anions, and low detection limits for fluoride in both DMSO and DMSO-water mixtures were obtained.

Intracellular Delivery of a Planar DNA Origami Structure by the Transferrin-Receptor Internalization Pathway

DNA origami provides rapid access to easily functionalized, nanometer-sized structures making it an intriguing platform for the development of defined drug delivery and sensor systems. Low cellular uptake of DNA nanostructures is a major obstacle in the development of DNA-based delivery platforms. Herein, significant strong increase in cellular uptake in an established cancer cell line by modifying a planar DNA origami structure with the iron transport protein transferrin (Tf) is demonstrated. A variable number of Tf molecules are coupled to the origami structure using a DNA-directed, site-selective labeling technique to retain ligand functionality. A combination of confocal fluorescence microscopy and quantitative (qPCR) techniques shows up to 22-fold increased cytoplasmic uptake compared to unmodified structures and with an efficiency that correlates to the number of transferrin molecules on the origami surface.

Control of Self-Assembled 2D Nanostructures by Methylation of Guanine

Methylation of DNA nucleobases is an important control mechanism in biology applied, for example, in the regulation of gene expression. The effect of methylation on the intermolecular interactions between guanine molecules is studied through an interplay between scanning tunneling microscopy (STM) and density functional theory with empirical dispersion correction (DFT-D). The present STM and DFT-D results show that methylation of guanine can have subtle effects on the hydrogen-bond strength with a strong dependence on the position of methylation. It is demonstrated that the methylation of DNA nucleobases is a precise means to tune intermolecular interactions and consequently enables very specific recognition of DNA methylation by enzymes. This scheme is used to generate four different types of artificial 2D nanostructures from methylated guanine. For instance, a 2D guanine windmill motif that is stabilized by cooperative hydrogen bonding is revealed. It forms by self-assembly on a graphite surface under ambient conditions at the liquid-solid interface when the hydrogen-bonding donor at the N1 site of guanine is blocked by a methyl group.

Docking of Antibodies into Cavities in DNA Origami

Immobilized antibodies are extensively employed for medical diagnostics, such as in enzyme-linked immunosorbent assays. Despite their widespread use, the ability to control the orientation of immobilized antibodies on surfaces is very limited. Herein, we report a method for the covalent and orientation-selective immobilization of antibodies in designed cavities in 2D and 3D DNA origami structures. Two tris(NTA)-modified strands are inserted into the cavity to form NTA-metal complexes with histidine clusters on the Fc domain. Subsequent covalent linkage to the antibody was achieved by coupling to lysine residues. Atomic force microscopy (AFM) and transmission electron microscopy (TEM) confirmed the efficient immobilization of the antibodies in the origami structures. This increased control over the orientation of antibodies in nanostructures and on surfaces has the potential to direct the interactions between antibodies and targets and to provide more regular surface assemblies of antibodies.

DNA-Templated Introduction of an Aldehyde Handle in Proteins.

Many medical and biotechnological applications rely on protein labeling, but a key challenge is the production of homogeneous and site‐specific conjugates. This can rarely be achieved by simple residue‐specific random labeling, but generally requires genetic engineering. Using site‐selective DNA‐templated reductive amination, we created DNA–protein conjugates with control over labeling stoichiometry and without genetic engineering. A guiding DNA strand with a metal‐binding functionality facilitates site‐selectivity by directing the coupling of a second reactive DNA strand in the vicinity of a protein metal‐binding site. We demonstrate DNA‐templated reductive amination for His6‐tagged proteins and metal‐binding proteins, including IgG1 antibodies. We also used a cleavable linker between the DNA and the protein to remove the DNA and introduce a single aldehyde on the protein. This functions as a handle for further modifications with desired labels. In addition to directing the aldehyde positioning, the DNA provides a straightforward route for purification between reaction steps.

Small-Molecule Probes for Affinity-Guided Introduction of Biocompatible Handles on Metal-Binding Proteins

Protein conjugates of high heterogeneity may contain species with significantly different biological properties, and as a consequence, the focus on methods for production of conjugates of higher quality has increased. Here, we demonstrate an efficient and generic approach for the modification of metal-binding proteins with biocompatible chemical handles without the need for genetic modifications. Affinity-guided small-molecule probes are developed for direct conjugation to off-the-shelf proteins and for installing different chemical handles on the protein surface. While purification of protein conjugates obtained by small molecule conjugation is troublesome, the affinity motifs of the probes presented here allow for purification of the conjugates. The versatility of the probes is demonstrated by conjugation to several His-tagged and natural metal-binding proteins, including the efficient and area-selective conjugation to three therapeutically relevant antibodies.

DNA-Templated Synthesis

In DNA templated synthesis (DTS) the effective local concentration of two or more reactants tethered to oligonucleotide strands is regulated by direct hybridization of the strands or by hybridization to a common template, bringing the reactants in close proximity. This provides efficient DNA-programmed control of chemical reactions at low concentrations. Furthermore, the approach may leave a nucleic acid tag on the reaction product enabling identification by PCR and sequencing. The concept has been applied for a variety of purposes, where control and spatial directionality of chemical reactivity are important, such as for chemical ligation of nucleic acids, nucleic acid detection, construction of macromolecular nanostructures, multistep synthesis, drug discovery, and chemical reaction discovery. In this chapter a selection of pertinent contributions to the field DTS are reviewed.