Search for: All records

Amyloid peptides (AMYs) and antimicrobial peptides (AMPs) are considered as two distinct families of peptides. In this review, we examine recent developments in the potential interplay between AMYs and AMPs, as well as their pathological implications. 

Abstract Misfolding and aggregation of amyloid peptides into β‐structure‐rich fibrils represent pivotal pathological features in various neurodegenerative diseases, including Alzheimer's disease (AD), type II diabetes (T2D), and medullary thyroid carcinoma (MTC). The development of effective amyloid detectors and inhibitors for probing and preventing amyloid aggregation is crucial for diagnosing and treating debilitating diseases, yet it poses significant challenges. Here, an aggregation‐induced emission (AIE) molecule of ROF2 with multifaceted functionalities as an amyloid probe and a screening tool for amyloid inhibitors using different biophysical, cellular, and worm assays, are reported. As an amyloid probe, ROF2 outperformed ThT, demonstrating its superior sensing capability in monitoring, detecting, and distinguishing amyloid aggregates of different sequences (Amyloid‐β, human islet amyloid polypeptide, or human calcitonin) and sizes (monomers, oligomers, or fibrils). More importantly, the utilization of ROF2 as a screening molecule to identify and repurpose cardiovascular drugs as amyloid inhibitors is introduced. These drugs exhibit potent amyloid inhibition properties, effectively preventing amyloid aggregation and reducing amyloid‐induced cytotoxicity both in cells and nematode. The findings present a novel strategy to discovery AIE‐based amyloid probes and to be used to repurpose amyloid inhibitors, expanding diagnostic and therapeutic options for neurodegenerative diseases while addressing vascular congestion and amyloid aggregation risks. 

Polymer brushes have witnessed extensive utilization and progress, driven by their distinct attributes in surface modification, tethered group functionality, and tailored interactions at the nanoscale, enabling them for various scientific and industrial applications of coatings, sensors, switchable/responsive materials, nanolithography, and lab-on-a-chips. Despite the wealth of experimental investigations into polymer brushes, this review primarily focuses on computational studies of antifouling polymer brushes with a strong emphasis on achieving a molecular-level understanding and structurally designing antifouling polymer brushes. Computational exploration covers three realms of thermotical models, molecular simulations, and machine-learning approaches to elucidate the intricate relationship between composition, structure, and properties concerning polymer brushes in the context of nanotribology, surface hydration, and packing conformation. Upon acknowledging the challenges currently faced, we extend our perspectives toward future research directions by delineating potential avenues and unexplored territories. Our overarching objective is to advance our foundational comprehension and practical utilization of polymer brushes for antifouling applications, leveraging the synergy between computational methods and materials design to drive innovation in this crucial field. 

Misfolding and aggregation of amyloid peptides are critical pathological events in numerous protein misfolding diseases (PMDs), such as Alzheimer's disease (AD), type II diabetes (T2D), and medullary thyroid carcinoma (MTC). While developing effective amyloid detectors and inhibitors to probe and prevent amyloid aggregation is a crucial diagnostic and therapeutic strategy for treating debilitating diseases, it is important to recognize that amyloid detection and amyloid prevention are two distinct strategies for developing pharmaceutical drugs. Here, we reported novel fluorescent BO21 as a versatile “dual-function, multi-target” amyloid probe and inhibitor for detecting and preventing amyloid aggregates of different sequences (Aβ, hIAPP, or hCT) and sizes (monomers, oligomers, or fibrils). As an amyloid probe, BO21 demonstrated a higher sensitivity and binding affinity to oligomeric and fibrillar amyloids compared to ThT, resulting in up to 18–39 fold fluorescence enhancements. As an amyloid inhibitor, BO21 also demonstrated its strong amyloid inhibition property by effectively preventing amyloid aggregation, disaggregating preformed amyloid fibrils, and reducing amyloid-induced cytotoxicity. The findings of this study offer a new perspective for the discovery of dual-functional amyloid probes and inhibitors, which have the potential to greatly expand the diagnostic and therapeutic treatments available for PMDs. 

Antifreezing hydrogels are essential for materials design and practical applications, but their development and understanding have been challenging due to their high-water content. Current antifreezing hydrogels typically rely on organic solvents or the addition of antifreezing agents. In this study, we present a novel crosslinking strategy to fabricate antifreezing hydrogels without the need for additional antifreezing agents. We introduce a new crosslinker, PEGn-EGINA, which combines highly hydrophilic EGINA with polyethylene glycol (PEG) of varying molecular weights. Utilizing PEGn-EGINA as the crosslinker, we synthesize Agar/Polyacrylamide (Agar/PAAm) double-network hydrogels, alongside conventional MBAA-crosslinked hydrogels for comparison. The resulting PEGn-EGINA-crosslinked hydrogels exhibit inherent antifreezing properties and retain their mechanical integrity even at subzero temperatures for extended periods. Molecular dynamics (MD) simulations further reveal that the antifreezing behavior observed in the PEGn-EGINA-crosslinked hydrogels can be attributed to their highly hydrophilic and tightly crosslinked double-network structures. These structures enable strong bindings between water and the hydrogel network, thus effectively preventing the formation of ice crystals within the hydrogels. Notably, PEGn-EGINA-crosslinked hydrogels not only demonstrate superior mechanical performance compared to MBAA-crosslinked hydrogels, but also maintain their mechanical properties even in frozen conditions, making them suitable for a wide range of applications. This study presents a simple yet effective design concept for highlighting the role of novel crosslinker in enhancing antifreezing and mechanical properties, showcasing their potential for various applications that require both antifreezing capabilities and robust mechanical performance.