Neutrophil extracellular traps (NETs) consist of DNA released by terminally stimulated neutrophils. They fine-tune inflammation, kill pathogens, activate macrophages, contribute to airway mucus obstruction in cystic fibrosis, and facilitate tumor metastasis after dormancy. Neutrophil proteases such as elastase (NE) and cathepsin G (CG) attach to NETs and contribute to the diverse immune outcome.  https://www.selleckchem.com/products/sbfi-26.html  However, because of the lack of suitable tools, little spatiotemporal information on protease activities on NETs is available in a pathophysiological context to date. Here, we present H-NE and H-CG, two FRET-based reporters armed with a DNA minor groove binder, which monitor DNA-bound NE and CG activity, respectively. The probes revealed that only NE maintains its catalytic ability when localized to DNA. Further, we demonstrated elevated protease activity within the extracellular DNA of sputum from cystic fibrosis patients. Finally, H-NE showed NE activity at single-cell and free DNA resolution within mouse lung slices, a difficult to achieve task with available substrate-based reporters.The architecturally symmetrical and synthetically challenging marine natural products lomaiviticins A and B present alluring synthetic targets due to their molecular complexity, potent antitumor properties, and natural scarcity. Herein, we report the total synthesis of the fully glycosylated monomeric unit of lomaiviticin A, monolomaiviticin A. The retrosynthetically derived synthetic strategy relied on an intramolecular palladium-catalyzed coupling reaction to complete the tetracyclic aglycon scaffold and gold-promoted glycosylations to install the synthetically challenging α- and β-glycoside moieties of the target molecule. This accomplishment paves a path for the eventual total synthesis of lomaiviticins A and B and opens opportunities for biological investigations within this family of compounds.A method for the fabrication of flexible electrical circuits on polyaramid substrates is presented based on laser-induced carbonization followed by copper electroplating. Locally carbonized flexible sheets of polyaramid (Nomex), by laser radiation, create rough and highly porous microstructures that show a higher degree of graphitization than thermally carbonized Nomex sheets. The found recipe for laser-induced carbonization creates conductivities of up to ∼45 S cm-1, thereby exceeding that observed for thermally pyrolyzed materials (∼38 S cm-1) and laser carbon derived from Kapton using the same laser wavelength (∼35 S cm-1). The electrical conductivity of the carbonized tracks was further improved by electroplating with copper. To demonstrate the electrical performance, fabricated circuits were tested and improvement of the sheet resistance was determined. Copper films exhibit antimicrobial activity and were used to fabricate customized flexible antibacterial coatings. The integration of laser carbonization and electroplating technologies in a polyaramid substrate points to the development of customized circuit designs for smart textiles operating in high-temperature environments.The accumulation and deposition of fibrillar aggregates of α-synuclein (α-syn) into Lewy bodies are the major hallmarks of Parkinson's disease (PD) for which there is no cure yet. Disrupting preformed α-syn fibrils is considered one of the rational therapeutic strategies to combat PD. Experimental studies reported that epigallocatechin gallate (EGCG), a polyphenol extracted from green tea, can disrupt α-syn fibrils into benign amorphous aggregates. However, the molecular mechanism of action is poorly understood. Herein, we performed molecular dynamics simulations on a newly released Greek-key-like α-syn fibril with or without EGCG to investigate the influence of EGCG on α-syn fibril. Our simulations show that EGCG disrupts the local β-sheet structure, E46-K80 salt-bridge crucial for the stabilization of the Greek-key-like structure, and hydrophobic interactions stabilizing the inter-protofibril interface and destabilizes the global structure of the α-syn fibril. Interaction analyses reveal that hydrophobic and hydrogen-bonding interactions between EGCG and α-syn fibrils play important roles in the destabilization of the fibril. We find that the disruption of the E46-K80 salt-bridge closely correlates with the formation of hydrogen-bonds (H-bonds) between EGCG and E46/K80. Our results provide mechanistic insights into the disruption modes of α-syn fibril by EGCG, which may pave the way for designing drug candidates targeting α-syn fibrillization to treat PD.Self-assembly of amphiphilic peptide-based building blocks gives rise to a plethora of interesting nanostructures such as ribbons, fibers, and tubes. However, it remains a great challenge to employ peptide self-assembly to directly produce nanostructures with lower symmetry than these highly symmetric motifs. We report here our discovery that persistent and regular crescent nanostructures with a diameter of 28 ± 3 nm formed from a series of tetrapeptides with the general structure AdKSKSEX (Ad = adamantyl group, KS = lysine residue functionalized with an S-aroylthiooxime (SATO) group, E = glutamic acid residue, and X = variable amino acid residue). In the presence of cysteine, the biological signaling gas hydrogen sulfide (H2S) was released from the SATO units of the crescent nanostructures, termed peptide-H2S donor conjugates (PHDCs), reducing levels of reactive oxygen species (ROS) in macrophage cells. Additional in vitro studies showed that the crescent nanostructures alleviated cytotoxicity induced by phorbol 12-myristate-13-acetate more effectively than common H2S donors and a PHDC of a similar chemical structure, AdK S KSE, that formed short nanoworms instead of nanocrescents. Cell internalization studies indicated that nanocrescent-forming PHDCs were more effective in reducing ROS levels in macrophages because they entered into and remained in cells better than nanoworms, highlighting how nanostructure morphology can affect bioactivity in drug delivery.Oligo-deoxyadenylic acid (dA X ) forms a novel 12 triple-helix with β-1,3-d-glucan schizophyllan (SPG). We found that dA X meticulously selects the most suitable length of SPG to bind; for example, dA30 only complexes with a short SPG chain having 30, 60, or 90 main-chain glucoses, and they can be easily isolated with each other. This study demonstrated such a novel stoichiometric complex formation by using gel permeation chromatography coupled with multi-angle light scattering and synchrotron small-angle X-ray scattering. These oligo-DNA/polysaccharide complexes can be used as a tool for delivering therapeutic oligonucleotides to immunocytes that express the β-1,3-d-glucan receptors. The present study provides a robust platform technique to characterize them in terms of modern regulatory science of nanomedicines, which is requisite to transfer drug candidates into clinical trial. Our findings are important for characterizing these complexes as well as for providing a new insight into nucleotide and saccharide chemistry.