Biochemistry

Glycerol-3-phosphate (G3P) is a conserved precursor of glycerolipids that also plays an important role in plant defense. Its levels and/or metabolism are also associated with many human disorders including insulin resistance, diabetes, obesity, and cancer, among others. In plants, G3P accumulates upon pathogen infection and is a critical component of systemic acquired resistance, which confers broad spectrum disease resistance against secondary infections. G3P also plays an important role in root-shoot-root signaling in soybean that regulates incompatible interactions with nitrogen-fixing bacteria. Thus, accurate quantification of G3P is key to drawing a valid conclusion regarding its role in diverse processes ranging from lipid biosynthesis to defense. G3P quantification is further compounded by its rapid degradation in extracts prepared at room temperature.

Here, we describe a simplified procedure for accurate quantitative analysis of G3P from plant tissues. G3P was extracted along with the internal standard ribitol, derivatized with N-Methyl-N-(trimethylsilyl)trifluoroacetamide (MSTFA) and analyzed by gas chromatography–coupled mass spectrometry using selective ion mode. This procedure is simple, economical, and efficient, and does not involve isotopic internal standards or multiple-step derivatizations.

The envelope of Gram-negative bacteria consists of an outer membrane (OM), a peptidoglycan cell wall, and an inner membrane (IM). The OM and IM have different components of proteins and lipids. Separating the IM and OM is a basic biochemical procedure to further study lipids and membrane proteins in different locations. Sucrose gradient ultracentrifugation of lysozyme/EDTA-treated total membrane is the most widely used method to separate the IM and OM of Gram-negative bacteria. However, EDTA is often harmful to protein structure and function. Here, we describe a relatively simple sucrose gradient ultracentrifugation method to separate the IM and OM of Escherichia coli. In this method, the cells are broken by a high-pressure microfluidizer, and the total cell membrane is collected by ultracentrifugation. The IM and OM are then separated on a sucrose gradient. Because EDTA is not used, this method is beneficial for subsequent membrane protein purification and functional study.

Redox status assessments are time-consuming, require a large volume of samples and great reagent amounts, and are not adequately described for methodological reproducibility. Here, the objective was to standardize redox balance determination, based on previously described spectrophotometric tests in pregnant rats, to improve precision, time dispensed, and the volume of samples and reagents, while maintaining accuracy and adequate cost benefits. This protocol summarizes oxidative stress markers, which focus on spectrophotometric tests for the assessment of thiobarbituric acid–reactive substances, reduced thiol groups, and hydrogen peroxide, as well as the antioxidant activity of superoxide dismutase, glutathione peroxidase, and catalase in washed erythrocyte and serum samples from full-term pregnant rats. For non-pregnant rats and other species, it is necessary to standardize these determinations, especially the sample volume. All measurements were normalized by the estimated protein concentrations in each sample. To establish optimum conditions for the reproducibility of the proposed methods, we describe all changes made in each assay’s steps based on the reference method reassessed for the new standardizations. Furthermore, the calculations of the concentrations or activities of each marker are presented. Thus, we demonstrate that the analysis of serum samples is easier and faster, but it is impossible to detect catalase activity. Furthermore, the proposed methods can be applied for redox balance determination, especially using smaller reagent amounts and lower sample volumes in lesser time without losing accuracy, as is required in obtaining samples during rat pregnancy.

Endosomal recycling is essential for the appropriate function of the endosome. During this process, endosomal coat complexes (i.e., retromer, and Mvp1) are recruited to the endosome, and deform its membrane to form recycling vesicles. To further analyze this, we developed a protocol for the immunoisolation of recycling vesicles from budding yeast. This method is a powerful way to characterize endosomal recycling pathways.

Several filamentous cyanobacteria like Nostoc differentiate specialized cells in response to changes in environmental factors, such as low light or nutrient starvation. These specialized cells are termed heterocysts and akinetes. Under conditions of nitrogen limitation, nitrogen-fixing heterocysts form in a semi-regular pattern and provide the filament with organic nitrogen compounds. Akinetes are spore-like dormant cells, which allow survival during adverse unfavorable conditions. Both cell types possess multilayered thick envelopes mainly composed of an outermost polysaccharide layer and inner layers of glycolipids, that are important for stress adaptation. To study these envelope glycolipids, a method for the isolation, separation and analysis of lipids from heterocysts and akinetes is essential. The present protocol describes a method involving the extraction of lipids from cyanobacteria using solvents and their separation and visualization on silica plates, to render analysis simple and easy. This protocol is relevant for studying mutants that are defective in glycolipid layer formation and for the comparison of glycolipid composition of heterocysts and akinetes under different environmental stresses.

Transbilayer movement of phospholipids in biological membranes is mediated by a diverse set of lipid transporters. Among them are scramblases that facilitate rapid bi-directional movement of lipids without metabolic energy input. In this protocol, we describe the incorporation of phospholipid scramblases into giant unilamellar vesicles (GUVs) formed from scramblase-containing large unilamellar vesicles by electroformation. We also describe how to analyze their activity using membrane-impermeant sodium dithionite, to bleach symmetrically incorporated fluorescent ATTO488-conjugated phospholipids. The fluorescence-based readout allows single vesicle tracking for a large number of settled/immobilized GUVs, and provides a well-defined experimental setup to directly characterize these lipid transporters at the molecular level.

Graphic abstract:

Giant unilamellar vesicles (GUVs) are formed by electroformation from large unilamellar vesicles (LUVs) containing phospholipid scramblases (purple) and trace amounts of a fluorescent lipid reporter (green).
The scramblase activity is analyzed by a fluorescence-based assay of single GUVs, using the membrane-impermeant quencher dithionite. Sizes not to scale. Modified from Mathiassen et al. (2021).

The ability to stain lipid stores in vivo allows for the facile assessment of metabolic status in individuals of a population following genetic and environmental manipulation or pharmacological treatment. In the animal model Caenorhabditis elegans, lipids are stored in and mobilized from intracellular lipid droplets in the intestinal and hypodermal tissues. The abundance, size, and distribution of these lipids can be readily assessed by two staining methods for neutral lipids: Oil Red O (ORO) and Nile Red (NR). ORO and NR can be used to quantitatively measure lipid droplet abundance, while ORO can also define tissue distribution and lipid droplet size. C. elegans are a useful animal model in studying pathways relating to aging, fat storage, and metabolism, as their transparent nature allows for easy microscopic assessment of lipid droplets. This is done by fixation and permeabilization, staining with NR or ORO, image capture on a microscope, and computational identification and quantification of lipid droplets in individuals within a cohort. To ensure reproducibility in lipid measurements, we provide a detailed protocol to measure intracellular lipid dynamics in C. elegans.

Graphic abstract:

Flow chart depicting the preparation of C. elegans for fat staining protocols.

G-protein coupled signaling pathways are organized into multi-protein complexes called signalosomes that are located within and on cellular membranes. We describe the use of silica nanoparticles coated with a unilamellar phospholipid bilayer (lipobeads) to reconstitute the activated photoreceptor G-protein α-subunit (Gtα*) with its cognate effector (phosphodiesterase-6; PDE6) for biochemical and structural studies of the activation mechanism regulating this GPCR signaling pathway. Lipobeads are prepared by resuspending dried-down phospholipid mixtures with monodisperse 70 nm silica particles, followed by extrusion through a 100 nm membrane filter. This uniform and supported liposomal preparation is easily sedimented, permitting the separation of soluble from membrane-associated proteins. Upon loading lipobeads with Gtα* and PDE6, we find that activation of PDE6 catalysis by Gtα* occurs much more efficiently than in the absence of membranes. Chemical cross-linking of membrane-confined proteins allows detection of changes in protein-protein interactions, resulting from G-protein activation of PDE6. The advantages of using lipobeads over partially purified membrane preparations or traditional liposomal preparations are generally applicable to the study of other membrane-confined signal transduction pathways.

Various methods have been developed to generate phosphoglyceride liposomes. Approaches resulting in homogeneous populations of unilamellar bilayer vesicles are generally preferred to mimic various cell membrane situations, as well as to optimize aqueous solute trapping efficiency using the least amount of lipid for biotechnological purposes. Most are time-consuming, often tedious, or require specialized equipment, and produce vesicles with limited shelf-life at room temperature or in cold storage. Herein, we describe a straightforward approach that avoids the preceding complications and streamlines the construction of unilamellar bilayer vesicles from 1-palmitoyl-2-oleoyl phosphatidylcholine (POPC)/dihexanoyl phosphatidylcholine (DHPC) bicelle mixtures at room temperature. The resulting vesicles are small (32-36 nm diameter), unilamellar, bilayer vesicles that are homogeneous, stable, and resistant to freeze-thaw alterations.

Graphic abstract:

Cryo-EM of POPC vesicles formed by dilution of 0.5 q-value POPC/DHPC bicelle mix.

The efficient ATP production in mitochondria relies on the highly specific organization of its double membrane. Notably, the inner mitochondrial membrane (IMM) displays a massive surface extension through its folding into cristae, along which concentrate respiratory complexes and oligomers of the ATP synthase. Evidence has accumulated to highlight the importance of a specific phospholipid composition of the IMM to support mitochondrial oxidative phosphorylation. Contribution of specific phospholipids to mitochondrial ATP production is classically studied by modulating the activity of enzymes involved in their synthesis, but the interconnection of phospholipid synthesis pathways often impedes the determination of the precise role of each phospholipid. Here, we describe a protocol to specifically enrich mitochondrial membranes with cardiolipin or phosphatidylcholine, as well as a fluorescence-based method to quantify phospholipid enrichment. This method, based on the fusion of lipid vesicles with isolated mitochondria, may further allow a precise evaluation of phospholipid contribution to mitochondrial functions.