Development of a bis-pyrene phospholipid probe for fluorometric detection of phospholipase A inhibition.

In this work, we report the design, synthesis, and application of a bis-pyrene phospholipid probe for detection of phospholipase A action through changes in pyrene monomer and excimer fluorescence intensities. Continuous fluorometric assays enabled detection of the activities of multiple PLA enzymes as well as the decrease in catalysis by PLA from honey bee venom caused by the inhibitor p-bromo phenacylbromide. Thin-layer chromatography and mass spectrometry analysis were also used to validate probe hydrolysis by PLA.

Harnessing Clickable Acylated Glycerol Probes as Chemical Tools for Tracking Glycerolipid Metabolism.

We report the use of clickable monoacylglycerol (MAG) analogs as probes for the labeling of glycerolipids during lipid metabolism. Incorporation of azide tags onto the glycerol region was pursued to develop probes that would label glycerolipids, in which the click tag would not be removed through processes including acyl chain and headgroup remodeling. Analysis of clickable MAG probes containing acyl chains of different length resulted in widely variable cell imaging and cytotoxicity profiles.

Copper-responsive liposomes for triggered cargo release employing a picolinamide-lipid conjugate.

In this work, we report triggered content release from liposomes brought about by copper chelation to a synthetic lipid switch containing a picolinamide headgroup. Fluorescence-based dye-leakage assays showcase release of carboxyfluorescein dye cargo upon copper treatment and control of liposomal release based on copper abundance. Our results additionally show that this platform is selective for copper and is accompanied by significant changes to liposome properties upon treatment with this ion.

Metabolite-Responsive Liposomes Employing Synthetic Lipid Switches Driven by Molecular Recognition Principles.

The ability to exert control over lipid properties, including structure, charge, function, and self-assembly characteristics is a powerful tool that can be implemented to achieve a wide range of biomedical applications. Examples in this arena include the development of caged lipids for controlled activation of signaling properties, metabolic labeling strategies for tracking lipid biosynthesis, lipid activity probes for identifying cognate binding partners, approaches for membrane assembly, and liposome triggered release strategies. In this Account, we describe recent advancements in the latter area entailing the development of stimuli-responsive liposomes through programmable changes to lipid self-assembly properties, which can be harnessed to drive the release of encapsulated contents toward applications including drug delivery.

Zinc Triggered Release of Encapsulated Cargo from Liposomes via a Synthetic Lipid Switch.

Liposomes are effective nanocarriers due to their ability to encapsulate and deliver a wide variety of therapeutics. However, therapeutic potential would be improved by enhanced control over the release of drug cargo. Zinc ions provide exciting new targets for stimuli-responsive lipid design due to their overly abundant concentrations associated with diseased cells.

Demolish and Rebuild: Controlling Lipid Self-Assembly toward Triggered Release and Artificial Cells.

The ability to modulate the structures of lipid membranes, predicated on our nuanced understanding of the properties that drive and alter lipid self-assembly, has opened up many exciting biological applications. In this Perspective, we focus on two endeavors in which the same principles are invoked to achieve completely opposite results. On one hand, controlled liposome decomposition enables triggered release of encapsulated cargo through the development of synthetic lipid switches that perturb lipid packing in the presence of disease-associated stimuli.