Solid-Phase Synthesis and Purification of Protein-DNA Origami Nanostructures.

We present a facile method for the combined synthesis and purification of protein-decorated DNA origami nanostructures (DONs). DONs bearing reductively cleavable biotin groups in addition to ligands for ligation of recombinant proteins are bound to magnetic beads. Protein immobilization is conducted with a large protein excess to achieve high ligation yields. Subsequent to cleavage from the solid support, pure sample solutions are obtained which are suitable for direct AFM analysis of occupation patterns. We demonstrate the method's utility using three different orthogonal ligation methods, the "halo-based oligonucleotide binder" (HOB), a variant of Halo-tag, the "SpyTag/SpyCatcher" (ST/SC) system, and the enzymatic "ybbR tag" coupling. We find surprisingly low efficiency for ST/SC ligation, presumably due to electrostatic repulsion and steric hindrance, whereas the ybbR method, despite its ternary nature, shows good ligation yields. Our method is particularly useful for the development of novel ligation methods and the synthesis of mechanically fragile DONs that present protein patterns for surface-based cell assays.

"Molecular Activity Painting": Switch-like, Light-Controlled Perturbations inside Living Cells.

Acute subcellular protein targeting is a powerful tool to study biological networks. However, signaling at the plasma membrane is highly dynamic, making it difficult to study in space and time. In particular, sustained local control of molecular function is challenging owing to the lateral diffusion of plasma membrane targeted molecules. Herein we present "molecular activity painting" (MAP), a novel technology which combines photoactivatable chemically induced dimerization (pCID) with immobilized artificial receptors. The immobilization of artificial receptors by surface-immobilized antibodies blocks lateral diffusion, enabling rapid and stable "painting" of signaling molecules and their activity at the plasma membrane with micrometer precision. Using this method, we show that painting of the RhoA-myosin activator GEF-H1 induces patterned acto-myosin contraction inside living cells.

Designed DNA Surfaces for in Vitro Modulation of Natural Killer Cells.

Natural killer (NK) cells are at the junction of the innate and the adaptive immune response and play a very important role in host defense against viral infections and cancer. They have numerous cell surface receptors that activate or inhibit various intracellular signaling cascades that are then integrated to determine the functional activity of these cells. Here we present a surface-based approach that aims to tackle the largely unknown molecular mechanisms of signal integration. We use DNA microarrays containing capture oligonucleotides for the DNA-directed immobilization (DDI) of oligonucleotide-tagged αCD16 antibodies as ligands for NK cells. We demonstrate that the resulting surfaces can be gradually tuned in terms of ligand density to trigger the activation of living NK cells, as evidenced by degranulation, the release of cytokines, and intracellular Ca(2+) flux, measured at the level of single cells.

Multiscale Origami Structures as Interface for Cells.

A DNA-based platform was developed to address fundamental aspects of early stages of cell signaling in living cells. By site-directed sorting of differently encoded, protein-decorated DNA origami structures on DNA microarrays, we combine the advantages of the bottom-up self-assembly of protein-DNA nanostructures and top-down micropatterning of solid surfaces to create multiscale origami structures as interface for cells (MOSAIC). In a proof-of-principle, we use this technology to analyze the activation of epidermal growth factor (EGF) receptors in living MCF7 cells using DNA origami structures decorated on their surface with distinctive nanoscale arrangements of EGF ligand entities. MOSAIC holds the potential to present to adhered cells well-defined arrangements of ligands with full control over their number, stoichiometry, and precise nanoscale orientation. It therefore promises novel applications in the life sciences, which cannot be tackled by conventional technologies.