A Simplified and Robust Activation Procedure of Glass Surfaces for Printing Proteins and Subcellular Micropatterning Experiments

High-throughput microcontact printing of proteins in microwell cell culture plates

Microcontact printing (MCP) is used to pattern a surface with a specific compound, allowing the spatially restricted response of cells to be assayed as they encounter a molecule of interest. MCP is a relatively low-cost and accessible technique that uses commercially available reagents and common cell culture equipment. However, it can be technically challenging, slow, and incompatible with microwell cell culture plates that are widely used for screening and other applications. Here, we describe a novel protocol using medical biopsy punches to transfer patterns into standard 96-well plates via polydimethylsiloxane (PDMS) cutouts. We demonstrate that this method can be used to deposit patterns of poly-D-lysine (PDL) into the microwells of glass-bottom plates. As a proof-of-concept, we show that cultured rodent glial cells preferentially grow and extend processes on the pattern. This method will allow larger scale MCP experiments in which different patterns, proteins, or other factors can be assayed in parallel.•Biopsy punches enable both cutting out small circular stamps and plunging them into tissue culture microwells to transfer proteins.•Compared to standard MCP, this method offers a more rapid workflow to pattern proteins onto substrates, and allows use of microwell plates that permits larger-scale experiments.

Surface-Patterned DNA Origami Rulers Reveal Nanoscale Distance Dependency of the Epidermal Growth Factor Receptor Activation

The nanoscale arrangement of ligands can have a major effect on the activation of membrane receptor proteins and thus cellular communication mechanisms. Here we report on the technological development and use of tailored DNA origami-based molecular rulers to fabricate "Multiscale Origami Structures As Interface for Cells" (MOSAIC), to enable the systematic investigation of the effect of the nanoscale spacing of epidermal growth factor (EGF) ligands on the activation of the EGF receptor (EGFR). MOSAIC-based analyses revealed that EGF distances of about 30-40 nm led to the highest response in EGFR activation of adherent MCF7 and Hela cells. Our study emphasizes the significance of DNA-based platforms for the detailed investigation of the molecular mechanisms of cellular signaling cascades.

Microcontact Printing of Biomolecules on Various Polymeric Substrates: Limitations and Applicability for Fluorescence Microscopy and Subcellular Micropatterning Assays

Polymeric materials play an emerging role in biosensing interfaces. Within this regard, polymers can serve as a superior surface for binding and printing of biomolecules. In this study, we characterized 11 different polymer foils [cyclic olefin polymer (COP), cyclic olefin copolymer (COC), polymethylmethacrylate (PMMA), DI-Acetate, Lumirror 4001, Melinex 506, Melinex ST 504, polyamide 6, polyethersulfone, polyether ether ketone, and polyimide] to test for the applicability for surface functionalization, biomolecule micropatterning, and fluorescence microscopy approaches. Pristine polymer foils were characterized via UV-vis spectroscopy. Functional groups were introduced by plasma activation and epoxysilane-coating. Polymer modification was evaluated by water contact angle measurement and X-ray photoelectron spectroscopy. Protein micropatterns were fabricated using microcontact printing. Functionalized substrates were characterized via fluorescence contrast measurements using epifluorescence and total internal reflection fluorescence microscopy. Results showed that all polymer substrates could be chemically modified with epoxide functional groups, as indicated by reduced water contact angles compared to untreated surfaces. However, transmission and refractive index measurements revealed differences in important optical parameters, which was further proved by fluorescence contrast measurements of printed biomolecules. COC, COP, and PMMA were identified as the most promising alternatives to commonly used glass coverslips, which also showed superior applicability in subcellular micropatterning experiments.