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1. A computational investigation of aromatic oligoamide foldamer binding to sugar molecules

   https://doi.org/10.1039/D5OB00908A  

   Horowitz, Samantha; Bryan, Taylor; Guzman, Joshua E; Radichel, Sarah; Pickell, Ella C; Golebiewski, Olivia; Zhong, Yulong; Miller, Daniel P; Gong, Bing (October 2025, Organic & Biomolecular Chemistry)

   Helical aromatic oligoamide foldamers (1a–c) with tunable lengths were computationally examined for their ability to bind selected sugars and sugar alcohols. These helices feature cylindrically shaped inner cavities lined with multiple inward-facing amide carbonyl oxygens acting as hydrogen-bond acceptors, enabling sugar binding via hydrogen bonding. Each of the helical foldamers has an overall dipole moment that increases with the length of the helix. The binding of a guest typically results in a reduction of the overall helix dipole moment within the complex, although there are several exceptions. The strength of host–guest interactions correlated positively with the number of hydrogen bonds formed. Longer helix 1c showed stronger interaction energies (up to −84.45 kcal mol−1), particularly with disaccharides, while shorter helix 1a bound sugars more weakly due to fewer established hydrogen bonds. The helical hosts exhibit structural adaptibility upon binding guests, with host distortion upon binding decreased with increasing helix length. Despite reduced binding energies, the complexes retained binding capability in aqueous environments, demonstrating their viability for aqueous-phase applications. This study underscores the critical roles of helical length and dipole alignment in optimizing sugar binding, providing a theoretical foundation for designing synthetic receptors for sugars and sugar alcohols based on aromatic oligoamide foldamers. 

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2. Enhanced Concanavalin A Binding to Preorganized Mannose Nanoarrays in Glycodendrimersomes Revealed Multivalent Interactions

   https://doi.org/10.1002/anie.202100400  

   Yu. Kostina, Nina; Söder, Dominik; Haraszti, Tamás; Xiao, Qi; Rahimi, Khosrow; Partridge, Benjamin E.; Klein, Michael L.; Percec, Virgil; Rodriguez‐Emmenegger, Cesar (March 2021, Angewandte Chemie International Edition)

   Abstract The effect of the two‐dimensional glycan display on glycan‐lectin recognition remains poorly understood despite the importance of these interactions in a plethora of cellular processes, in (patho)physiology, as well as its potential for advanced therapeutics. Faced with this challenge we utilized glycodendrimersomes, a type of synthetic vesicles whose membrane mimics the surface of a cell and offers a means to probe the carbohydrate biological activity. These single‐component vesicles were formed by the self‐assembly of sequence‐defined mannose‐Janus dendrimers, which serve as surrogates for glycolipids. Using atomic force microscopy and molecular modeling we demonstrated that even mannose, a monosaccharide, was capable of organizing the sugar moieties into periodic nanoarrays without the need of the formation of liquid‐ordered phases as assumed necessary for rafts. Kinetics studies of Concanavalin A binding revealed that those nanoarrays resulted in a new effective ligand yielding a ten‐fold increase in the kinetic and thermodynamic constant of association. 

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3. From Disorder to Icosahedral Symmetry: How Conformation-Switching Subunits Enable RNA Virus Assembly

   Li, S; Tresset, G; Zandi, R (August 2025, Science advances)

   Icosahedral capsids are ubiquitous among spherical viruses, yet their assem- bly pathways and governing interactions remain elusive. We present a molecular dynamics model that incorporates essential physical and biological interactions, including protein diffusion, genome flexibility, and a conformational switch that mimics allostery and activates the elastic properties of proteins upon binding. This switch makes the simulations computationally feasible and enables the assembly of icosahedral capsids around a flexible genome—overcoming long-standing lim- itations in previous models. Using this framework, we successfully reproduce the self-assembly of subunits around a flexible genome into icosahedral shells with numbers greater than one – most notably 3, the most common structure in na- ture – a feat that rigid-body models have so far failed to achieve. We systematically explore the range of morphologies formed with different genome architectures, in line with in vitro experiments using cowpea chlorotic mottle virus capsid proteins: viral RNAs with more complex structure form more complete and stable capsids than linear ones. These results provide a predictive framework for genome-guided assembly and capsid design. 

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4. Extrusion‐Based Printing of Nanostructured Fatty Acid Gels Incorporated in Hydrogels

   https://doi.org/10.1002/app.57328  

   Amirfattahi, Saba; Freeman, Cody J; Honaryar, Houman; Ghazali, Hanieh Sadat; Kim, Kyungtae; Niroobakhsh, Zahra (May 2025, Journal of Applied Polymer Science)

   ABSTRACT Soft materials with unique nanostructures such as lamellar, hexagonal, and cubic morphologies can replicate complex structures that have potential in various fields, including biomedical and industrial applications. However, a key challenge in advancing the broader applications of 3D printing for these nanostructured soft materials is insufficient mechanical properties that hinder their printability and compromise structural stability in the final product. In this study, the suitability of a fatty acid‐based lamellar gel is evaluated for direct extrusion‐based 3D printing. The lamellar gel with varying water content is integrated with a photocurable hydrogel to preserve the shape and stability of the final prints. Complex 2D and 3D design patterns are used to assess extrusion behavior, structural stability, and print precision under varying pressures. Small‐angle X‐ray Scattering (SAXS) measurements reveal the formation of lamellar nanostructures and confirm their retention after photocuring in various gels. Rheological analysis confirms that these gels exhibit key properties suitable for extrusion‐based 3D printing, such as shear‐thinning behavior. Additionally, tensile testing is conducted to evaluate the mechanical properties across cured print samples. This study underscores the potential of nanostructured gels as a robust and versatile platform, facilitating the development of materials engineered for various applications. 

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5. Excited-State Palladium-Catalyzed 1,2-Spin-Center Shift Enables Selective C-2 Reduction, Deuteration, and Iodination of Carbohydrates

   https://doi.org/10.1021/jacs.0c11209  

   Zhao, Gaoyuan; Yao, Wang; Mauro, Jaclyn N.; Ngai, Ming-Yu (January 2021, Journal of the American Chemical Society)

   null (Ed.)

   Excited-state catalysis, a process that involves one or more excited catalytic species, has emerged as a powerful tool in organic synthesis because it allows access to the excited-state reaction landscape for the discovery of novel chemical reactivity. Herein, we report the first excited-state palladium-catalyzed 1,2-spin-center shift reaction that enables site-selective functionalization of carbohydrates. The strategy features mild reaction conditions with high levels of regio- and stereoselectivity that tolerate a wide range of functional groups and complex molecular architectures. Mechanistic studies suggest a radical mechanism involving the formation of hybrid palladium species that undergoes a 1,2-spin-center shift followed by the reduction, deuteration, and iodination to afford functionalized 2-deoxy sugars. The new reactivity will provide a general approach for the rapid generation of natural and unnatural carbohydrates. 

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