Coordination‐Driven Folding and Assembly of a Short Peptide into a Protein‐like Two‐Nanometer‐Sized Channel

Short peptide helices have attracted attention as suitable building blocks for soft functional materials, but they are rarely seen in crystalline materials. A new artificial nanoassembly of short peptide helices in the crystalline state is presented in which peptide helices are arranged three‐dimensionally by metal coordination. The folding and assembly processes of a short peptide ligand containing the Gly‐Pro‐Pro sequence were induced by silver(I) coordination in aqueous alcohol, and gave rise to a single crystal composed of polyproline II helices. Crystallographic studies revealed that this material possesses two types of unique helical nanochannel; the larger channel measures more than 2 nm in diameter. Guest uptake properties were investigated by soaking the crystals in polar solutions of guest molecules; anions, organic chiral molecules, and bio‐oligomers are effectively encapsulated by this peptide‐folded porous crystal, with moderate to high chiral recognition for chiral molecules.     

Morphology‐Dependent Cell Imaging by Using a Self‐Assembled Diacetylene Peptide Amphiphile

Herein, a novel cationic peptide gemini amphiphile containing diacetylene motifs ( DA₂P ) is presented, which self‐assembles into novel tadpole‐ and bola‐shaped nanostructures at low concentrations and nanofibers at higher concentrations. Interestingly, the DA₂P assemblies can be polymerized into a fluorescent red phase but only during incubation with HeLa cells, most likely owing to the reorganization of the diacetylene chains of DA₂P upon interaction with the cell membrane. The red‐fluorescent polymerized DA₂P assemblies can serve as a novel cell imaging probe. However, only vesicles, tadpole‐ and bola‐shaped DA₂P assemblies can be translocated into HeLa cells, whereas the nanofiber‐like DA₂P assemblies are trapped by the cell membranes and do not enter the cells. Hence, morphology‐dependent cell imaging is observed.     

Molecular Logic Gates and Switches Based on 1,3,4‐Oxadiazoles Triggered by Metal Ions

Organic molecular devices for information processing applications are highly useful building blocks for constructing molecular‐level machines. The development of “intelligent” molecules capable of performing logic operations would enable molecular‐level devices and machines to be created. We designed a series of 2,5‐diaryl‐1,3,4‐oxadiazoles bearing a 2‐(para‐substituted)phenyl and a 5‐(o‐pyridyl) group (substituent X=NMe₂, OEt, Me, H, and Cl; 1 a – e ) that form a bidentate chelating environment for metal ions. These compounds showed fluorescence response profiles varying in both emission intensity and wavelength toward the tested metal ions Ni²⁺, Cu²⁺, Zn²⁺, Cd²⁺, Hg²⁺, and Pb²⁺ and the responses were dependent on the substituent X, with those of 1 d being the most substantial. The 1,3,4‐oxadiazole O or N atom and pyridine N atom were identified as metal‐chelating sites. The fluorescence responses of 1 d upon metal chelation were employed for developing truth tables for OR, NOR, INHIBIT, and EnNOR logic gates as well as “ON‐OFF‐ON” and “OFF‐ON‐OFF” fluorescent switches in a single 1,3,4‐oxadiazole molecular system.     

Ln3+‐Mediated Self‐Assembly of a Collagen Peptide into Luminescent Banded Helical Nanoropes

Design of biomimetic peptides to achieve the desired properties of natural collagen has much potential to build functional biomaterials. A collagen‐peptide/Ln³⁺ system has been constructed and self‐assembled to form helical nanoropes with a distinct periodic banding pattern characteristic of natural collagen. The fully reversible self‐assembly is specifically mediated by lanthanide ions, but not by other commonly used divalent metal ions. Lanthanide ions not only provide an external biocompatible stimulus of the assembly, but also play as a functional unit to endow the assembled materials with easily tunable photoluminescence. To our knowledge, this is the first report of collagen‐peptide‐based materials with exquisite nanorope structure and excellent photoluminescent features. These novel luminescent nanomaterials may have great potential in cell imaging, medical diagnostics, and luminescent scaffolds for cell cultivation.     

Self‐Assembly of a Tripod Aromatic Rod into Stacked Planar Networks

Threefold symmetric rigid‐core molecules with an internally grafted poly(ethylene oxide) (PEO) chain were synthesized, and their self‐assembled structures were characterized using differential scanning calorimetry, TEM, and 1D and 2D X‐ray scatterings in the solid state. The tripod compounds based on short PEO chains (n=8, 13, 17, 21), self‐assemble into 2D channel‐like network structures, whereas the compound with the longest PEO chain (n=34) forms a lamellar liquid crystalline phase. The interiors of the channel structures are filled with flexible PEO chains along the double‐walled aromatic circumference. In these channel‐like networks, three aromatic rods connected in the meta‐position to each other are superimposed in parallel to other adjacent molecules to form the double‐walled aromatic frameworks stacked perpendicular to the resulting channels. These are novel examples of supramolecular channel‐like structures developed using amphiphilic diblock molecules based on a threefold symmetric rigid scaffold.     

Direct Preparation of Metal Ions‐Doped Manganese Oxide by Cyclic Voltammetry

In this work, for the first time, copper ions(II) and cobalt ions(II) were successfully electrodepositioned into manganese oxide by cyclic voltammetry (CV), respectively. The results obtained from energy dispersive X‐ray analysis (EDX) testified that copper ions and cobalt ions were doped into manganese oxide, and the images, taken from scan electron spectroscopy (SEM) also proved that the morphology of the resultant MnO₂ was altered by the doped metal ions to some extent. Interestingly, specific capacitance, obtained by cyclic voltammograms (CVs), for the metal ions‐doped MnO₂ exhibited a higher value compared to the non‐doped MnO₂. Developing a novel and simple method to generate the metal ions‐doped MnO₂ to improve the characteristics of MnO₂ is the main contribution of this work.     

Effects of Divalent Metal Ions on Electrochemiluminescence Sensor with Ru(bpy)32+ Immobilized in Eastman‐AQ Membrane

Different effects of divalent metal ions on electrochemiluminescence (ECL) sensor with Ru(bpy)₃²⁺ immobilized in Eastman‐AQ membrane were investigated. Mg²⁺, Ca²⁺ and Fe²⁺ can elevate the ECL of Ru(bpy)₃²⁺/proline; while metal ions that underwent redox reactions on the electrode such as Mn²⁺ and Co²⁺ presented intensive quenching effects on Ru(bpy)₃²⁺ ECL. Also, the quenching effect of Mn²⁺ on the ECL sensor with Ru(bpy)₃²⁺ immobilized in Eastman‐AQ membrane enhanced to about 30‐folds compared with the case that Ru(bpy)₃²⁺ was dissolved in phosphate buffer, and the enhanced quenching effects of Mn²⁺ were studied.     

Direct Synthesis of a Covalently Self‐Assembled Peptide Nanogel from a Tyrosine‐Rich Peptide Monomer and Its Biomineralized Hybrids

There has been significant progress in the self‐assembly of biological materials, but the one‐step covalent peptide self‐assembly for well‐defined nanostructures is still in its infancy. Inspired by the biological functions of tyrosine, a covalently assembled fluorescent peptide nanogel is developed by a ruthenium‐mediated, one‐step photo‐crosslinking of tyrosine‐rich short peptides under the visible light within 6 minutes. The covalently assembled peptide nanogel is stable in various organic solvents and different pH levels, unlike those made from vulnerable non‐covalent assemblies. The semipermeable peptide nanogel with a high density of redox‐active tyrosine acts as a novel nano‐bioreactor, allowing the formation of uniform metal–peptide hybrids by selective biomineralization under UV irradiation. As such, this peptide nanogel could be useful in the design of novel nanohybrids and peptidosomes possessing functional nanomaterials.     

Four‐Shell Polyoxometalates Featuring High‐Nuclearity Ln26 Clusters: Structural Transformations of Nanoclusters into Frameworks Triggered by Transition‐Metal Ions

A series of polyoxometalates (POMs) that incorporate the highest‐nuclearity Ln clusters that have been observed in such structures to date (Ln₂₆ , Ln=La and Ce) are described, which exhibit giant multishell configurations (Ln⊂W₆⊂Ln₂₆⊂W₁₀₀). Their structures are remarkably different from known giant POMs that feature multiple Ln ions. In particular, the incorporated Ln–O clusters with a nuclearity of 26 are significantly larger than known high‐nuclearity (≤10) Ln–O clusters in POM chemistry. Furthermore, they also contain the largest number of La and Ce centers for any POM reported to date and represent a new kind of rare giant POMs with more than 100 W atoms. Interestingly, the La₂₆‐containing POM can undergo a single‐crystal to single‐crystal structural transformation in the presence of various transition‐metal ions, such as Cu²⁺, Co²⁺, and Ni²⁺, from an inorganic molecular nanocluster into an inorganic–organic hybrid extended framework that is built from POM building blocks with even higher‐nuclearity La₂₈ clusters bridged by transition‐metal complexes.     

pH‐Triggered Self‐Assembly of Cellulose Oligomers with Gelatin into a Double‐Network Hydrogel

Multicomponent systems for self‐assembled molecular gels provide huge opportunities to generate collective or new functions that are not inherent in individual single‐component gels. However, gelation tends to require careful and complicated procedures, because, among a myriad of kinetically trapped structures related to the degree of mixing of multiple components over a wide range of scales, from molecular level to macroscopic scale, a limited number of structures that exhibit the desired function need to be constructed. This study presents a simple method for the construction of double‐network (DN) hydrogels with improved stiffness composed of crystalline cellulose oligomers and gelatin. The pH‐triggered self‐assembly of cellulose oligomers leads to the formation of robust networks composed of crystalline nanofibers in the presence of dissolved gelatin, followed by cooling to allow for the formation of soft gelatin networks. The resultant DN hydrogels exhibit improved stiffness; the improvement in gel stiffness with double networking is comparable to that of previously reported DN hydrogels produced via a time‐consuming enzymatic reaction.     

Hemostatic Efficacy of Biological Self‐Assembling Peptide Nanofibers in a Rat Kidney Model

We evaluated the hemostatic efficacy of a biological self‐assembling peptide RADA16‐I in a rat kidney injury model. Adult male rats were randomized into five groups: sham operation (no renal excision), no hemostatic agent (control), commercially available gelatin sponge (Gelfoam), 1% RADA16‐I, and 2% RADA16‐I. After left partial nephrectomy, the anesthetized animal was anticoagulated using 300 IU · kg^?1 heparin, and the topical hemostatic agent was applied to the injury. Blood loss and mean arterial pressure (MAP) were recorded. As was the case for Gelfoam, 2% RADA16‐I produced marked hemostasis versus controls (p < 0.01). Blood loss with 1% and 2% RADA16‐I was significantly less than controls. The decline in MAP during surgery was less with 2% versus 1% RADA16‐I. RADA16‐I also resulted in less histological tissue responses than Gelfoam. These data suggest that RADA16‐I can stop hemorrhage, with only minimal tissue responses, in experimental renal injury.

     

Bioremediation of Heavy Metal Ions by Phosphate‐mineralization Bacteria and Its Mechanism

Bioremediation of heavy metal ions by phosphate‐mineralization bacteria (PMB), as a new green and en‐ vironmental method, relies on microbe‐inducing phosphate precipitation and can prevent heavy metal ions from transferring. The growth of PMB was investigated via four aspects respectively — the control of incubation time, pH value, environmental conditions, and heavy metal ions. At the same time, phosphate? mineralization precipitations and mechanism of four common kinds of heavy metal ions were analyzed. The experimental results indicated that PMB didn’t grow immediately in the first 5 hours, and they reached to the fastest reproduction rate after 13 hours. The pH value of PMB solution increased gradually from 7.0 to 8.6 when PM₀B grew, which plays an important role in the mineralization process. PMB could grow most rapidly at 30 °C, pH of 8 and low concentration of heavy metal ions. It showed that too high or too low temperature and pH, as well as high concentration of heavy metal ions, could inhibit the reproduction of PMB. Stable and large particles phosphate ‐ mineralization precipitation, whose particle size could be more than 10 microns, were obtained by the process that PMB induced substrate to decompose and thus mineralized heavy metal ions effectively.     

Biomimetic Polymers Responsive to a Biological Signaling Molecule: Nitric Oxide Triggered Reversible Self‐assembly of Single Macromolecular Chains into Nanoparticles

Novel nitric oxide (NO) responsive monomers (NAPMA and APUEMA) containing o‐phenylenediamine functional groups have been polymerized to form NO‐responsive macromolecular chains as truly biomimetic polymers. Upon exposure to NO—a ubiquitous cellular signaling molecule—the NAPMA‐ and APUEMA‐labeled thermoresponsive copolymers exhibited substantial changes in solubility, clearly characterized by tuneable LCST behavior, thereby inducing self‐assembly into nanoparticulate structures. Moreover, the NO‐triggered self‐assembly process in combination with environmentally sensitive fluorescence dyes could be employed to detect and image endogenous NO.     

Self‐assembly of p‐Aminothiophenol on Gold Surface: Application for Impedimetric and Potentiometric Sensing of Cobalt (II) Ions – A Comparative Study

Cobalt, despite an essential biological element, imposes threat to humans when exposed to high concentration or even to low concentration for long term which demands the development of highly sensitive and selective analytical methods for its trace analysis. In the present work, self‐assembly of p‐aminothiophenol (p‐ATP) on gold surface (Au?ATP SAM) was carried out and for the first time, applied as a platform for impedimetric and potentiometric sensing of Co²⁺. Au?ATP SAM was characterized using electrochemical techniques: cyclic voltammetry (CV) and electrochemical impedance spectroscopy (EIS), in the presence of two redox probes: [Fe(CN)₆]^3?/4? and [Ru(NH₃)₆]^2+/3+ to evaluate associated passivating behaviour. Au?ATP SAM completely blocked [Fe(CN)₆]^3?/4? as compared to [Ru(NH₃)₆]^2+/3+ which may be attributed to inner‐sphere and outer‐sphere ET mechanisms, respectively. Au?ATP SAM was found to exhibit excellent sensitivity towards Co²⁺ in a wider concentration range from 1.0×10^?12 M to 1.0×10^?5 M (r²=0.963) at pH 5.5 with a detection limit of 6.0×10^?13 M and superior selectivity. Further, carbon paste electrode (CPE) was prepared by incorporating p‐ATP bound gold nanoparticles and explored for potentiometric sensing of Co²⁺ which exhibited Nernstian slope of 29.2±0.2 mV/dec in linear concentration range of 1.0×10^?6 M–1.0×10^?1 M (r²=0.971) with a detection limit of 8.0×10^?7 M. The proposed sensors were successfully applied for estimation of Co²⁺ content in water samples.     

Use of an Octapeptide–Guanidiniocarbonylpyrrole Conjugate for the Formation of a Supramolecular β‐Helix that Self‐Assembles into pH‐Responsive Fibers

Peptides that adopt β‐helix structures are predominantly found in transmembrane protein domains or in the lipid bilayer of vesicles. Constructing a β‐helix structure in pure water has been considered difficult without the addition of membrane mimics. Herein, we report such an example; peptide 1 self‐assembles into a supramolecular β‐helix in pure water based on charge interactions between the individual peptides. Peptide 1 further showed intriguing transitions from small particles to helical fibers in a time‐dependent process. The fibers can be switched to vesicles by changing the pH value.