Bioorthogonal Photoreactive Surfaces for Single-Cell Analysis of Intercellular Communications.

Methods to construct single-cell pairs of heterogeneous cells attract attention because of their potential in cell biological and medical applications for analyzing individual intercellular communications such as immune and nerve synaptic interactions. Photoactivatable substrate surfaces for cell anchoring are promising tools to achieve single-cell pairing. However, conventional surfaces that photoactivate a single type of cell anchoring moiety restrict the combination of cell pair types and their applications.

Photoactivatable Materials for Versatile Single-Cell Patterning Based on the Photocaging of Cell-Anchoring Moieties through Lipid Self-Assembly.

Versatile methods for patterning multiple types of cells with single-cell resolution have become an increasingly important technology for cell analysis, cell-based device construction, and tissue engineering. Here, we present a photoactivatable material based on poly(ethylene glycol) (PEG)-lipids for patterning a variety of cells, regardless of their adhesion abilities. In this study, PEG-lipids bearing dual fatty acid chains were first shown to perfectly suppress cell anchoring on their coated substrate surfaces whereas those with single-chain lipids stably anchored cells through lipid-cell membrane interactions.

Photo-responsive materials with strong cell trapping ability for light-guided manipulation of nonadherent cells.

We report a photo-cleavable material for tight trapping of nonadherent cells to substrate surfaces. Model immunocytes were selectively trapped in a non-irradiated area as single cells after the projection of a light pattern and withstood high-speed laminar flow, achieving light-guided cell release from the substrates.

Reversible and Photoresponsive Immobilization of Nonadherent Cells by Spiropyran-Conjugated PEG-Lipids.

Spatiotemporal control of cell-material interactions contributes to our understanding of cell biology and the development of cell engineering. Here, we first report the reversible and spatio-selective immobilization of nonadherent cells through the use of photoswitchable polymeric materials. The substrate coated with spiropyran-conjugated poly(ethylene glycol) (PEG) lipids, which bind to cell membranes via the lipid moiety only in their merocyanine form, enabled rapid cell immobilization and release in an on-off manner by irradiation with ultraviolet and visible light, respectively.

Microfluidic preparation of anchored cell membrane sheets for in vitro analyses and manipulation of the cytoplasmic face.

Molecular networks on the cytoplasmic faces of cellular plasma membranes are critical research topics in biological sciences and medicinal chemistry. However, the selective permeability of the cell membrane restricts the researchers from accessing to the intact intracellular factors on the membrane from the outside. Here, a microfluidic method to prepare cell membrane sheets was developed as a promising tool for direct examination of the cytoplasmic faces of cell membranes.

Chemically-activatable alkyne-tagged probe for imaging microdomains in lipid bilayer membranes.

A chemically-activatable alkynyl steroid analogue probe has been synthesized for visualizing the lipid raft membrane domains by Raman microscopy. The Raman probe, in which ring A of its steroid backbone is replaced with an alkynyl group, was designed to enable activation of the alkyne signal through the Eschenmoser-Tanabe fragmentation reaction of the oxidized cholesterol precursor in lipid bilayer membranes. The alkynyl steroid analogue was observed to form liquid-ordered raft-like domains on a model giant-liposome system in a similar manner as cholesterol, and the large alkyne signal of the accumulated probe at 2120 cm was mapped on the microdomains with a Raman microscope.

Chemically Activatable Alkyne Tag for Low pH-Enhanced Molecular Labeling on Living Cells.

Stimuli-responsive "activatable" reactive tags are applicable to selective labeling of biomolecules in a defined area or environment in living systems, yielding new insights into cellular processes through molecular imaging and fishing. Here, we developed a chemically activatable alkyne tag that can be incorporated into biological molecules and labeled with azide-tagged functional molecules through the alkyne-azide cycloaddition "click" reaction after chemical activation. Formation of the alkyne tag from the precursor moiety was confirmed to proceed in physiological aqueous media and was particularly enhanced under mildly acidic pH.