Brewster angle microscopy (BAM) is a powerful technique that allows for real-time visualization of Langmuir monolayers. The lateral organization of these films can be investigated, including phase separation and the formation of domains, which may be of different sizes and shapes depending on the properties of the monolayer. Different molecules or small changes within a molecule such as the molecule's length or presence of a double bond can alter the monolayer's lateral organization that is usually undetected using surface pressure-area isotherms. The effect of such changes can be clearly observed using BAM in real-time, under full hydration, which is an experimental advantage in many cases. While previous BAM reviews focused more on selected compounds or compared the impact of structural variations on the lateral domain formation, this review provided a broader overview of BAM application using biological materials and systems including the visualization of amphiphilic molecules, proteins, drugs, extracts, DNA, and nanoparticles at the air-water interface.
Diacylglycerol (DAG) is a key signaling lipid and intermediate in lipid metabolism. Our knowledge of DAG distribution and dynamics in cell membranes is limited. Using live‐cell fluorescence microscopy we investigated the localization of yeast cytosolic‐facing pools of DAG in response to conditions where lipid homeostasis and DAG levels were known to be altered. Two main pools were monitored over time using DAG sensors. One pool was associated with vacuolar membranes and the other localized to sites of polarized growth. Dynamic changes in DAG distribution were observed during resumption of growth from stationary phase, when DAG is used to support phospholipid synthesis for membrane proliferation. Vacuolar membranes experienced constant morphological changes displaying DAG enriched microdomains coexisting with liquid‐disordered areas demarcated by Vph1. Formation of these domains was dependent on triacylglycerol (TAG) lipolysis. DAG domains and puncta were closely connected to lipid droplets. Lack of conversion of DAG to phosphatidate in growth conditions dependent on TAG mobilization, led to the accumulation of DAG in a vacuolar‐associated compartment, impacting the polarized distribution of DAG at budding sites. DAG polarization was also regulated by phosphatidylserine synthesis/traffic and sphingolipid synthesis in the Golgi.
Membrane organization has received substantial research interest since the degree of ordering in membrane regions is relevant in many biological processes. Here we relate the impact of varying cholesterol concentrations on native secretory vesicle fusion and the lateral domain organization of membrane extracts from these vesicles. Membranes of isolated cortical secretory vesicles were either depleted of cholesterol, had cholesterol loaded to excess of native levels, or were depleted of cholesterol but subsequently reloaded to restore native cholesterol levels. Lipid analyses confirmed cholesterol was the only species significantly altered by these treatments. Treated vesicles were characterized for their ability to undergo fusion. Cholesterol depletion resulted in a decrease of Ca2+ sensitivity and the extent of fusion, while cholesterol loading had no effect on fusion parameters. Membrane extracts were characterized in terms of lipid packing by surface pressure-area isotherms whereas the lateral membrane organization was analyzed by Brewster angle microscopy. While no differences in the isotherms were observed, imaging revealed drastic differences in domain size, shape and frequency between the various conditions. Cholesterol depletion induced larger but fewer domains, suggesting that domain coalescence into larger structures may disrupt the native temporal-spatial organization of the fusion machinery and thus inhibit vesicle docking, priming, and fusion. In contrast, adding excess cholesterol, or rescuing with exogenous cholesterol after sterol depletion, resulted in more but smaller domains. Therefore, cholesterol is an important membrane organizer in the process of Ca2+ triggered vesicular fusion, which can be related to specific physical effects on native membrane substructure.
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