Diarylethene-Powered Light-Induced Folding of Supramolecular Polymers.

Helical folding of randomly coiled linear polymers is an essential organization process not only for biological polypeptides but also for synthetic functional polymers. Realization of this dynamic process in supramolecular polymers (SPs) is, however, a formidable challenge because of their inherent lability of main chains upon changing an external environment that can drive the folding process (e.g., solvent, concentration, and temperature). We herein report a photoinduced reversible folding/unfolding of rosette-based SPs driven by photoisomerization of a diarylethene (DAE). Temperature-controlled supramolecular polymerization of a barbiturate-functionalized DAE (open isomer) in nonpolar solvent results in the formation of intrinsically curved, but randomly coiled, SPs due to the presence of defects. Irradiation of the randomly coiled SPs with UV light causes efficient ring-closure reaction of the DAE moieties, which induces helical folding of the randomly coiled structures into helicoidal ones, as evidenced by atomic force microscopy and small-angle X-ray scattering. The helical folding is driven by internal structure ordering of the SP fiber that repairs the defects and interloop interaction occurring only for the resulting helicoidal structure. In contrast, direct supramolecular polymerization of the ring-closed DAE monomers by temperature control affords linearly extended ribbon-like SPs lacking intrinsic curvature that are thermodynamically less stable compared to the helicoidal SPs. The finding represents an important concept applicable to other SP systems; that is, postpolymerization (photo)reaction of preorganized kinetic structures can lead to more thermodynamically stable structures that are inaccessible directly through temperature-controlled protocols.

Structure of Ultrafine Bubbles and Their Effects on Protein and Lipid Membrane Structures Studied by Small- and Wide-Angle X-ray Scattering.

Ultrafine bubbles (UFBs) are defined as small gas-filled bubbles with a diameter smaller than 1 µm. UFBs are stable for several weeks in aqueous solutions due to their small size. Although the mechanism of the stability of UFBs remains under intensive investigation, industrial applications of UFBs have recently arisen in various fields such as agricultural and fishery industries and medical therapy. The relevance of ions (protons and hydroxide anions) in UFB solutions has been discussed; however, the mechanism underlying the behavior of UFBs is still ambiguous and there is little direct evidence of the effect of UFBs on biological materials. This study deals with gaseous UFBs in aqueous solutions. Using small- and wide-angle X-ray scattering, we have investigated the structures of UFBs (air-UFBs, O2-UFBs, and N2-UFBs) and their effect on protein and lipid membrane structures. X-ray scattering and modeling data suggest that UFBs present a dynamic diffusive boundary (interface) due to the continuous release and absorption of gas. UFBs were found to not affect the structures of proteins at all hierarchal structure levels (from quaternary to tertiary, to internal, to secondary), whereas they did influence the packing and fluctuation of the hydrocarbon chains in the liposomes but not their shapes.

Differential gene responses in endothelial cells exposed to a combination of shear stress and cyclic stretch.

We developed a compliant tube-type flow-loading apparatus that allows simultaneous application of physiological levels of shear stress and cyclic stretch to cultured cells and examined gene responses to a combination of the two forces. Human umbilical vein endothelial cells were exposed to shear stress and/or cyclic stretch for 24h, and changes in the mRNA levels of endothelin-1 (ET-1), a potent vasoconstrictor, and endothelial nitric oxide synthase (eNOS), which catalyzes the production of a potent vasodilator, NO, were determined by reverse transcriptase/PCR. Cyclic stretch (10%, 1 Hz) alone increased ET-1 mRNA levels approximately 1.6-fold, but had no effect on eNOS mRNA levels. A shear stress of 7 dynes/cm(2) and 15 dynes/cm(2) alone decreased ET-1 mRNA levels to around 83% and 61%, respectively, of the basal level, but increased the eNOS mRNA level to around 2.2-fold and 3.2-fold, respectively. When cyclic stretch and shear stress were applied simultaneously, ET-1 mRNA levels did not change significantly, but the eNOS mRNA level increased to a level equivalent to the increase in response to shear stress alone. These results indicate that the response of endothelial genes to shear stress or cyclic stretch depends on whether the two forces are applied separately or together.

Preferential Intercalation of Human Amyloid-ß Peptide into Interbilayer Region of Lipid-Raft Membrane in Macromolecular Crowding Environment.

This study focuses on the interaction of human amyloid ß-peptide (Aß) with a lipid-raft model membrane under macromolecular crowding conditions that mimic the intracellular environment. Aß is central to the development of Alzheimer's disease (AD) and has been studied extensively to determine the molecular mechanisms of Aß-induced cellular dysfunctions underlying the pathogenesis of AD. According to evidence from spectroscopic studies, ganglioside clusters are key to the fibrillization process of Aß. Gangliosides are a major component of glycosphingolipids and are acidic lipids of the central nervous system known to form so-called lipid rafts. In this study, the small unilamellar vesicle (SUV) membrane, composed of monosialogangliosides, cholesterol, and 1,2-dipalmitoyl- sn-glycero-3-phosphocholine, did not show any structural changes after the addition of Aß under noncrowding conditions. However, the addition of Aß under crowding conditions induced shape deformation and aggregation to SUV resulting in multilamellar stacking. The time evolution of the lamellar peak suggested the preferential cohesion or intercalation of the Aß peptide into the interbilayer region. This phenomenon was only observed at the gel (Lß) phase. These results suggest that an intracellular crowding environment promotes Aß-membrane interaction and a selective accumulation of Aß peptides into the interbilayer regions.

Self-folding of supramolecular polymers into bioinspired topology.

Folding one-dimensional polymer chains into well-defined topologies represents an important organization process for proteins, but replicating this process for supramolecular polymers remains a challenging task. We report supramolecular polymers that can fold into protein-like topologies. Our approach is based on curvature-forming supramolecular rosettes, which affords kinetic control over the extent of helical folding in the resulting supramolecular fibers by changing the cooling rate for polymerization. When using a slow cooling rate, we obtained misfolded fibers containing a minor amount of helical domains that folded on a time scale of days into unique topologies reminiscent of the protein tertiary structures. Thermodynamic analysis of fibers with varying degrees of folding revealed that the folding is accompanied by a large enthalpic gain. The self-folding proceeds via ordering of misfolded domains in the main chain using helical domains as templates, as fully misfolded fibers prepared by a fast cooling rate do not self-fold.

Crystal structure of the flexible tandem repeat domain of bacterial cellulose synthesis subunit C.

Bacterial cellulose (BC) is synthesized and exported through the cell membrane via a large protein complex (terminal complex) that consists of three or four subunits. BcsC is a little-studied subunit considered to export BC to the extracellular matrix. It is predicted to have two domains: a tetratrico peptide repeat (TPR) domain and a ß-barrelled outer membrane domain. Here we report the crystal structure of the N-terminal part of BcsC-TPR domain (Asp24-Arg272) derived from Enterobacter CJF-002. Unlike most TPR-containing proteins which have continuous TPR motifs, this structure has an extra α-helix between two clusters of TPR motifs. Five independent molecules in the crystal had three different conformations that varied at the hinge of the inserted α-helix. Such structural feature indicates that the inserted α-helix confers flexibility to the chain and changes the direction of the TPR super-helix, which was also suggested by structural analysis of BcsC-TPR (Asp24-Leu664) in solution by size exclusion chromatography-small-angle X-ray scattering. The flexibility at the α-helical hinge may play important role for exporting glucan chains.

Effect of protein-encapsulation on thermal structural stability of liposome composed of glycosphingolipid/cholesterol/phospholipid.

We have studied the thermal structural stability of liposomes encapsulating proteins by using synchrotron radiation small- and wide-angle X-ray scattering (SR-SWAXS). Liposomes are known to be effective drug-delivery systems (DDSs) because they can reduce drug toxicity due to biodegradability and biocompatibility and can offer promising carriers of various types of drugs. However, in spite of numerous studies of liposomes, physicochemical characteristics of liposomes entrapping proteins are rarely known. The liposome studied is characterized by the lipid composition (mixture of acidic glycosphingolipid (ganglioside)/cholesterol/phospholipid). Gangliosides are one of the major constituents of so-called lipid rafts playing the role of a platform of cell-signaling. We have found that the encapsulation of proteins elevates the thermal transition temperature of the liposome membrane and suppresses the deformation of its shape. The present results suggest that not only membrane proteins, but also water-soluble proteins affect liposome stability through the revalence between osmotic pressure and membrane elasticity. In addition, we have found the presence of the size-effect depending on the molar content of gangliosides in the liposome, indicating the ability of ganglioside molecule controlling both the size and effective surface charge of the liposome. The present results would have significance from two different points of view. One is the confinement effect of proteins within a limited space like cell, and the other is a stability of a new type of DDS using gangliosides. Due to the intrinsic properties, gangliosides are expected to be promising agents for targeting and long-circulation properties of liposomal DDSs.