Synthetic ion channels in biomembranes.

Ion transport across cell membranes is crucial in maintaining ion homeostasis in cells. Synthetic molecules that can mimic the functions of natural ion channel proteins would possess great potential as therapeutic agents by promoting apoptosis or interfering with autophagic processes through perturbing the intracellular pH or inducing oxidative and osmotic stresses. However, little is known about the underlying mechanisms in terms of direct correlation between ion transport and biological functions.

Nanohoops in membranes: confined supramolecular spaces within phospholipid bilayer membranes.

Nanohoops, an exciting class of fluorophores with supramolecular binding abilities, have the potential to become innovative tools within biological imaging and sensing. Given the biological importance of cell membranes, incorporation of macrocyclic materials with the dual capability of fluorescence emission and supramolecular complexation would be particularly interesting. A series of different-sized nanohoops-ethylene glycol-decorated []cyclo--pyrenylenes (CPYs) ( = 4-8)-were synthesised an alternate synthetic route which implements a stannylation-based precursor, producing purer material than the previous borylation approach, enabling the growth of single-crystals of the Pt-macrocycle.

A bioinspired bifunctional catalyst: an amphiphilic organometallic catalyst for ring-closing metathesis forming liquid droplets in aqueous media.

Inspired by phase-separated biopolymers with enzymatic activity, we developed an amphiphilic catalyst consisting of alternating hydrophilic oligo(ethylene glycol) and hydrophobic aromatic units bearing a Hoveyda-Grubbs catalyst center (MAHGII). MAHGII served as both a droplet-forming scaffold and a catalyst for ring-closing metathesis reactions, providing a new biomimetic system that promotes organic reactions in an aqueous environment.

Monitoring insulin fibrillation kinetics using chromatographic analysis.

Insulin is a small protein widely used to treat patients with diabetes and is a commonly used model for protein fibrillation studies. Under specific conditions, such as low pH and high temperature, insulin monomers aggregate to form fibrils. This aggregation is problematic for manufacturing and storage of insulin.

Dense and Acidic Organelle-Targeted Visualization in Living Cells: Application of Viscosity-Responsive Fluorescence Utilizing Restricted Access to Minimum Energy Conical Intersection.

Cell-imaging methods with functional fluorescent probes are an indispensable technique to evaluate physical parameters in cellular microenvironments. In particular, molecular rotors, which take advantage of the twisted intramolecular charge transfer (TICT) process, have helped evaluate microviscosity. However, the involvement of charge-separated species in the fluorescence process potentially limits the quantitative evaluation of viscosity.

Supramolecular Mechanosensitive Potassium Channel Formed by Fluorinated Amphiphilic Cyclophane.

Inspired by mechanosensitive potassium channels found in nature, we developed a fluorinated amphiphilic cyclophane composed of fluorinated rigid aromatic units connected via flexible hydrophilic octa(ethylene glycol) chains. Microscopic and emission spectroscopic studies revealed that the cyclophane could be incorporated into the hydrophobic layer of the lipid bilayer membranes and self-assembled to form a supramolecular transmembrane ion channel. Current recording measurements using cyclophane-containing planer lipid bilayer membranes successfully demonstrated an efficient transmembrane ion transport.

Supramolecular Transmembrane Ion Channels Formed by Multiblock Amphiphiles.

Transmembrane proteins located within biological membranes play a crucial role in a variety of important cellular processes, such as energy conversion and signal transduction. Among them, ion channel proteins that can transport specific ions across the biological membranes are particularly important for achieving precise control over those processes. Strikingly, approximately 20% of currently approved drugs are targeted to ion channel proteins within membranes.

Characterization of a novel type of carbonic anhydrase that acts without metal cofactors.

Background: Carbonic anhydrases (CAs) are universal metalloenzymes that catalyze the reversible conversion of carbon dioxide (CO) and bicarbonate (HCO). They are involved in various biological processes, including pH control, respiration, and photosynthesis. To date, eight evolutionarily unrelated classes of CA families (α, β, γ, δ, ζ, η, θ, and ι) have been identified.

Calcium-induced reversible assembly of phosphorylated amphiphile within lipid bilayer membranes.

Inspired by calcium-induced reversible assembly and disassembly of membrane proteins found in nature, here we developed a phosphorylated amphiphile (PA) that contains an oligo(phenylene-ethynylene) unit as a hydrophobic unit and a phosphate ester group as a hydrophilic calcium-binding unit. We demonstrated that PA can assemble and disassemble in a reversible manner in response to the sequential addition of calcium chloride and ethylene-diaminetetraacetic acid within the lipid bilayer membranes for the first time as a synthetic molecule.

Synthetic Ion Channel Formed by Multiblock Amphiphile with Anisotropic Dual-Stimuli-Responsiveness.

Transmembrane proteins within biological membranes exhibit varieties of important functions that are vital for many cellular activities, and the development of their synthetic mimetics allows for deep understanding in related biological events. Inspired by the structures and functions of natural ion channels that can respond to multiple stimuli in an anisotropic manner, we developed multiblock amphiphile in this study. When was incorporated into the lipid bilayer membranes, formed a supramolecular ion channel whose ion transport property was controllable by the polarity and amplitude of the applied voltage.

Imidazolinium-based Multiblock Amphiphile as Transmembrane Anion Transporter.

Transmembrane anion transport is an important biological process in maintaining cellular functions. Thus, synthetic anion transporters are widely developed for their biological applications. Imidazolinium was introduced as anion recognition site to a multiblock amphiphilic structure that consists of octa(ethylene glycol) and aromatic units.

Thermo-driven self-assembly of a PEG-containing amphiphile in a bilayer membrane.

Self-assembly of lipid molecules in a plasma membrane, namely lipid raft formation, is involved in various dynamic functions of cells. Inspired by the raft formation observed in the cells, here we studied thermally induced self-assembly of a synthetic amphiphile, bola-AkDPA, in a bilayer membrane. The synthetic amphiphile consists of a hydrophobic unit including fluorescent aromatic and aliphatic components and hydrophilic tetraethylene glycol chains attached at both ends of the hydrophobic unit.

A synthetic ion channel with anisotropic ligand response.

Biological membranes play pivotal roles in the cellular activities. Transmembrane proteins are the central molecules that conduct membrane-mediated biochemical functions such as signal transduction and substance transportation. Not only the molecular functions but also the supramolecular properties of the transmembrane proteins such as self-assembly, delocalization, orientation and signal response are essential for controlling cellular activities.

Reversible formation of multiple stimuli-responsive polymeric materials through processing control of trifunctional amphiphilic molecules.

A nonionic amphiphile consisting of thermo-responsive tetraethylene glycol chains, redox-responsive thiol groups, and photo-responsive anthracene units was developed. By combining the thermal and redox stimuli in water and bulk to control the assembling processes, two pairs of polymeric materials possessing contrasting responses to thermal treatment and photoirradiation were prepared.

Aromatic Fluorination of Multiblock Amphiphile Enhances Its Incorporation into Lipid Bilayer Membranes.

We designed multiblock amphiphiles and , which consist of perfluorinated and non-fluorinated hydrophobic units, respectively. Absorption spectroscopy revealed that both amphiphiles are molecularly dispersed in organic solvent, while they form aggregates under aqueous conditions. Furthermore, we investigated whether and can be incorporated into DOPC lipid bilayer membranes, and found that the maximum concentration of that can be incorporated into DOPC lipid bilayer membranes is 43 times higher than that of .

New Modified Deoxythymine with Dibranched Tetraethylene Glycol Stabilizes G-Quadruplex Structures.

Methods for stabilizing G-quadruplex formation is a promising therapeutic approach for cancer treatment and other biomedical applications because stable G-quadruplexes efficiently inhibit biological reactions. Oligo and polyethylene glycols are promising biocompatible compounds, and we have shown that linear oligoethylene glycols can stabilize G-quadruplexes. Here, we developed a new modified deoxythymine with dibranched or tribranched tetraethylene glycol (TEG) and incorporated these TEG-modified deoxythymines into a loop region that forms an antiparallel G-quadruplex.

Heat-Triggered Crystallization of Liquid Crystalline Macrocycles Allowing for Conductance Switching through Hysteretic Thermal Phase Transitions.

A polymesomorphic thermal phase-transition of a macrocyclic amphiphile consisting of aromatic groups and oligoethylene glycol (OEG) chains is reported. The macrocyclic amphiphile exists in a highly-ordered liquid crystal (LC) phase at room temperature. Upon heating, this macrocycle shows phase-transition from columnar-lamellar to nematic LC phases followed by crystallization before melting.

Localization of transmembrane multiblock amphiphilic molecules in phase-separated vesicles.

A series of triblock amphiphilic molecules bearing hydrophilic PEG chains at both ends of the long aromatic hydrophobic moieties were obtained serendipitously. The molecules involve linearly connected diarylethyne and diarylbutadiyne units, which show characteristic emissions upon excitation by UV light. These emissions showed red-shifts upon an increase in the solvent polarity, where the shifts are larger for the molecules with longer aromatic moieties.

Enzymatically cleavable traceless biotin tags for protein PEGylation and purification.

Here we report an example of a protein-PEG conjugate with a biotin tag cleavable by lipase-catalyzed hydrolysis. Very mild cleavage conditions, heterogeneous, easily separable catalysts, and traceless design make this method attractive for the preparation and purification of PEGylated proteins.