Excitons in two-dimensional (2D) materials are tightly bound and exhibit rich physics. So far, the optical excitations in 2D semiconductors are dominated by Wannier-Mott excitons, but molecular systems can host Frenkel excitons (FE) with unique properties. Here, we report a strong optical response in a class of monolayer molecular J-aggregates. The exciton exhibits giant oscillator strength and absorption (over 30% for monolayer) at resonance, as well as photoluminescence quantum yield in the range of 60–100%. We observe evidence of superradiance (including increased oscillator strength, bathochromic shift, reduced linewidth and lifetime) at room-temperature and more progressively towards low temperature. These unique properties only exist in monolayer owing to the large unscreened dipole interactions and suppression of charge-transfer processes. Finally, we demonstrate light-emitting devices with the monolayer J-aggregate. The intrinsic device speed could be beyond 30 GHz, which is promising for next-generation ultrafast on-chip optical communications.
We described the integration of the general reversibility of glycosyltransferase-catalyzed reactions, artificial glycosyl donors, and a high throughput colorimetric screen to enable the engineering of glycosyltransferases for combinatorial sugar nucleotide synthesis. The best engineered catalyst from this study, the OleD Loki variant, contained the mutations P67T/I112P/T113M/S132F/A242I compared with the OleD wild-type sequence. Evaluated against the parental sequence OleD TDP16 variant used for screening, the OleD Loki variant displayed maximum improvements in k cat /K m of >400-fold and >15-fold for formation of NDP-glucoses and UDP-sugars, respectively. This OleD Loki variant also demonstrated efficient turnover with five variant NDP acceptors and six variant 2-chloro-4-nitrophenyl glycoside donors to produce 30 distinct NDP-sugars. This study highlights a convenient strategy to rapidly optimize glycosyltransferase catalysts for the synthesis of complex sugar nucleotides and the practical synthesis of a unique set of sugar nucleotides.carbohydrate | enzyme | glycobiology | protein engineering T he lack of accessibility and availability of uncommon and uniquely functionalized sugar nucleotides (NDP-sugars) continues to restrict research focused upon understanding the regulation, biosynthesis, and/or role of glycosylated macromolecules and glycosylated small molecules in biology or therapeutic development (1-7). Although there are many reported chemical, enzymatic, and chemoenzymatic strategies for NDP-sugar synthesis, those that extend beyond the reach of common biological sugars (e.g., Dglucose, D-galactose, etc.) nearly all suffer from long reaction times (>16 h), relatively low yields, and difficulties associated with product purification and/or stability (3,4,8,9). Thus, the development of robust methods for sugar nucleotide synthesis directly compatible to the downstream biological processes to be studied may be advantageous.From a traditional viewpoint, NDP-sugars are used as donors by Leloir glycosyltransferases (sugar nucleotide-dependent enzymes) for formation of glycosidic bonds. However, many glycosyltransferase (GT)-catalyzed reactions are known to be readily reversible, enabling the "pirating" of unique sugars from natural products or alternative donors (resulting in generation of the respective sugar nucleotide) and one-pot sugar exchange reactions between unique natural products (4, 10-13). This general reaction feature, in conjunction with availability of highly permissive glycosyltransferases (14-18) and simple donors designed to fundamentally alter the reaction thermodynamics, recently enabled a unique platform for NDP-sugar synthesis and a high throughput colorimetric screen for NDP-sugar formation and utilization (19). While the prior platform proof-of-concept study highlighted the syntheses of 22 natural and nonnatural TDP/UDP-sugars from 11 distinct 2-chloro-4-nitrophenyl glycoside donors using a single GT catalyst (Fig. 1A) (19), the substrate specificity of the glycosyltransferase used ...
The natural all d- and/or unnatural all l-1,4- and 1,6-oligosaccharides were synthesized from furan alcohols using a palladium-catalyzed glycosylation reaction. The 1,4- and 1,6-alpha-manno-disaccharides were achieved in seven total steps starting from chiral furan alcohols. Similarly, 1,4- and 1,6-alpha-manno-trisaccharides were also synthesized in nine total steps. Key to the overall efficiency of this process was the use of highly diastereoselective palladium-catalyzed glycosylations, reductions, and dihydroxylations.
Digitoxin is a cardiac glycoside currently being investigated for potential use in oncology. While a number of structure-activity relationship studies have been conducted, an investigation of anticancer activity as a function of oligosaccharide chain length has not yet been performed. We generated mono-, di-, and tri-O-digitoxoside derivatives of digitoxin and compared their activity to the corresponding MeON-neoglycosides. Both classes of cardenolide derivatives display comparable oligosaccharide chain length-dependent cytotoxicity toward human cancer cell lines. Further investigation revealed that both classes of compounds induce caspase-9-mediated apoptosis in non-small cell lung cancer cells (NCI-H460). Since O-glycosides and MeON-neoglycosides share a similar mode of action, the convenience of MeON-neoglycosylation could be exploited in future SAR work to rapidly survey large numbers of carbohydrates to prioritize selected O-glycoside candidates for traditional synthesis.
Conducting metal nanowires can be assembled into thin films for flexible electronics and optoelectronics applications including transparent electrodes, nanocircuits, and electronic skin, however, the junction resistances and low aspect ratios still limit its performance. Herein we report high-quality silver nanofibers (AgNFs) synthesized by a gas-assistant solution spinning method. Compared with traditional Ag nanowires that usually have lengths below 100 μm, AgNFs are infinitely long and can be easily assembled into large-scale 2D and 3D flexible conductors with fused junctions between nanofibers. The AgNF networks showed high transparency, low sheet resistance (e. g, 6 Ω sq(-1) at ∼97% transparency), and high flexibility as transparent electrodes, whereas the 3D AgNF sponge could be used as a deformable and robust 3D conductor.
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