Parallel Functionalization of DNA Origami.

DNA origami enables the creation of large supramolecular structures, with precisely defined features at the nanoscale. The concept thus naturally lends itself to the concept of molecular patterning, i.e., the positioning of molecular moieties and functional features. Creation of nanoscale patterns was already disseminated by Rothemund in 2006, in which DNA hairpins were used to produce nanoscale patterns on the flat origami canvases (Rothemund PWK, Nature 440(7082):297-302, 2006). For this type of application, it is often desired to produce multiple different patterns using the same origami canvas by reusing existing origami staple strands, rather than ordering new, custom oligonucleotides for each unique pattern. This chapter presents a method where the enzyme terminal deoxynucleotidyl transferase (TdT) is used in a parallelized reaction to add functional moieties to the end of a selected pool of unmodified staple strand oligonucleotides, which are then incorporated at precisely defined positions in the DNA origami canvas. Introducing arrays of functional features using this enzymatic functionalization of origami staple strands offers a very high degree of flexibility, versatility, and ease of use and can often be obtained faster than custom synthesis. For small synthesis scales, typically employed during initial functional screening of many different molecular patterns, the method also offers a significant advantage in terms of cost. During the past years, we have utilized this to incorporate a large variety of molecules including bulky proteins (Sørensen RS, Okholm AH, Schaffert D, Kodal ALB, Gothelf KV, Kjems J, ACS Nano 7:8098-8104, 2013) in designed patterns from modified nucleotide triphosphate (NTP) building blocks (Jahn K, Tørring T, Voigt NV, Sørensen RS, Kodal ALB, Andersen ES, Bioconjug Chem 22:819-823, 2011). The near-quantitative yields obtained by enzymatic functionalization allow synthesis of a large set of oligonucleotides in a one-pot reaction from commercial starting materials without the need for individual post-purification. Based on the chosen subset of staple strand, it is possible to create any designed functionality, array, or pattern. Here we describe the process going from an idea/design of a DNA origami-specific molecular pattern to nucleotide synthesis and subsequent parallel functionalization of the DNA origami, assembly, and the final characterization.

The Role of Nanoscale Distribution of Fibronectin in the Adhesion of Staphylococcus aureus Studied by Protein Patterning and DNA-PAINT.

Staphylococcus aureus is a widespread and highly virulent pathogen that can cause superficial and invasive infections. Interactions between S. aureus surface receptors and the extracellular matrix protein fibronectin mediate the bacterial invasion of host cells and is implicated in the colonization of medical implant surfaces. In this study, we investigate the role of distribution of both fibronectin and cellular receptors on the adhesion of S. aureus to interfaces as a model for primary adhesion at tissue interfaces or biomaterials. We present fibronectin in patches of systematically varied size (100-1000 nm) in a background of protein and bacteria rejecting chemistry based on PLL-g-PEG and studied S. aureus adhesion under flow. We developed a single molecule imaging assay for localizing fibronectin binding receptors on the surface of S. aureus via the super-resolution DNA points accumulation for imaging in nanoscale topography (DNA-PAINT) technique. Our results indicate that S. aureus adhesion to fibronectin biointerfaces is regulated by the size of available ligand patterns, with an adhesion threshold of 300 nm and larger. DNA-PAINT was used to visualize fibronectin binding receptor organization in situ at ∼7 nm localization precision and with a surface density of 38-46 µm-2, revealing that the engagement of two or more receptors is required for strong S. aureus adhesion to fibronectin biointerfaces.

Extrusion of RNA from a DNA-Origami-Based Nanofactory.

Cells often spatially organize biomolecules to regulate biological interactions. Synthetic mimicry of complex spatial organization may provide a route to similar levels of control for artificial systems. As a proof-of-principle, we constructed an RNA-extruding nanofactory using a DNA-origami barrel with an outer diameter of 60 nm as a chassis for integrated rolling-circle transcription and processing of RNA through spatial organization of DNA templates, RNA polymerases, and RNA endonucleases. The incorporation efficiency of molecular components was quantified to be roughly 50% on designed sites within the DNA-origami chassis. Each integrated nanofactory with RNA-producing units, composed of DNA templates and RNA polymerases, produced 100 copies of target RNA in 30 min on average. Further integration of RNA endonucleases that cleave rolling-circle transcripts from concatemers into monomers resulted in 30% processing efficiency. Disabling spatial organization of molecular components on DNA origami resulted in suppression of RNA production as well as processing.

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.