Studies on seeds. II. Origin and degradation of lipid vesicles in pea and bean cotyledons

At least two kinds of lipid vesicles are present in pea and bean cotyledons which can be recognized at seed maturity on the basis of whether they do or do not interassociate into lipid vesicle sheets. Those that do interassociate into sheets are also characterized by (a) their association with plastids or plasma membranes during dormancy, and (b) the unique transformation into flattened saccules that they undergo during the first few days of seed germination. These interassociated (or composite) lipid vesicles have been found in only a few seeds and may be restricted to certain classes of plants and/or certain states of cellular development. Lipid vesicle-to-saccule transformation is predominantly confined to the germinating seed. However, some lipid vesicle-derived saccules are already present in some cells even before the seed reaches maturity. These partially transformed vesicles and saccules remain unchanged over dormancy, and then resume their transformation when the seed is germinated. This suggests that some stages of seed germination are already underway before the seed reaches maturity and are only resumed at seed germination. The lipid vesicles that do not interassociate into sheets (i.e., the simple lipid vesicles) are present in all tissues at all states of cellular development. These vesicles do not undergo any conspicuous structural changes during development.     

Lipid transfer proteins in the study of artificial and natural membranes

Summary Lipid transfer proteins, differing in their specificity for the transfer of lipids and for the surfaces on which they act, have been purified from various mammalian tissues and subsequently characterized. Several of their properties make them useful research tools. They have been used alone or with other techniques to study the distribution and mobility of phospholipids in artificial vesicles and in natural membranes, and have been used to create asymmetric phospholipid vesicles.Lipid transfer proteins are capable of altering the lipid composition of membranes by introducing new lipids or by depletion of existing lipids. Some of the transfer proteins can effect a net transfer of phospholipids, glycosphingolipids and cholesterol from one structure to another, whereas others appear to act primarily in promoting exchange. Some lipid transfer proteins are capable of introducing spin labeled and fluorescent lipid analogs into the outer surface of membranes. Because lipid transfer proteins do not seem to alter membrane lipid asymmetry or permeability of membranes, they are useful tools for studying the effect of lipid substitution on membrane-mediated transport processes and on various membrane-bound enzyme systems.Abbreviations PA phosphatidic acid - PC phosphatidylcholine - PE phosphatidylethanolamine - PI phosphatidylinositol - PG phosphatidylglycerol - PS phosphatidylserine - DPG diphosphatidylglycerol - SPH sphingomyelin - G_{m t} II³--N-Acetylneuraminosylgangliotetraglycosylceramide - GbOse₄Cer globotetraglycosylceramide Career Investigator of C.O.N.I.C.E.T. (Argentina)Career Investigator of the American Heart Association.     

Real-time Observation of Lipoplex Formation and Interaction with Anionic Bilayer Vesicles

A novel development has allowed for the direct observation of single, pairwise interactions of linear DNA with cationic vesicles and of DNA-cationic lipid complexes with anionic vesicles. A new cationic phospholipid derivative, l,2-dioleoyl-sn-glycero-3-ethylphosphocholine, was used to prepare giant bilayer vesicles and to form DNA-cationic lipid complexes (lipoplexes). The cationic vesicles were electrophoretically maneuvered into contact with DNA, and similarly, complexes were brought into contact with anionic phospholipid vesicles composed of dioleoylphosphatidylglycerol (DOPG; 100%), DOPG/dioleoylphosphatidylethanolamine (DOPE; 1:1) or DOPG/dioleoylphosphatidylcholine (DOPC; 1:1). Video fluorescence microscopy revealed that upon contact with phospholipid anionic vesicles, lipoplexes exhibited four different types of behavior: adhesion, vesicle rupture, membrane perforation (manifested as vesicle shrinkage and/or content loss), and expansion of DNA (which was always concomitant with membrane perforation.) In one instance, the lipoplex was injected into the target vesicle just prior to DNA expansion. In all other instances, the DNA expanded over the outer surface of the vesicle, and expansion was faster, the larger the area of vesicle over which it expanded. Given the likelihood of incorporation of cellular anionic lipids into lipoplexes, the expansion of the DNA could be important in DNA release during cell transfection. Upon contact with naked DNA, giant cationic vesicles usually ruptured and condensed the DNA into a small particle. Contact of cationic vesicles that were partially coated with DNA usually caused the DNA to wrap around the vesicle, leading to vesicle rupture, vesicle fusion (with other attached vesicles or lipid aggregates), or simply cessation of movement. These behaviors clearly indicated that both DNA and vesicles could be partly or fully covered by the other, thus modifying surface charges, which, among others, allowed adhesion of DNA-coated vesicles with uncoated vesicles and of lipid-coated DNA with uncoated DNA.     

Preparation of ready-to-use small unilamellar phospholipid vesicles by ultrasonication with a beaker resonator

Lipid vesicles are widely used as models to investigate the interactions of proteins, peptides, and small molecules with lipid bilayers. We present a sonication procedure for the preparation of well-defined and ready-to-use small unilamellar vesicles composed of phospholipids with the aid of a beaker resonator. This indirect but efficient sonication method does not require subsequent centrifugation or other purification steps, which distinguishes it from established sonication procedures. Vesicles produced by this method reveal a unimodal size distribution and are unilamellar, as demonstrated by dynamic light scattering and ³¹P nuclear magnetic resonance spectroscopy, respectively.     

ULTRASTRUCTURE OF THE PRAWN NERVE SHEATHS : Role of Fixative and Osmotic Pressure in Vesiculation of Thin Cytoplasmic Laminae

The sheaths from freshly teased nerve fibers of the prawn exhibit a positive radial birefringence, consistent with their EM appearance as highly organized laminated structures composed of numerous thin cytoplasmic sheets or laminae bordered by unit membranes and arranged concentrically around the axon. The closely apposed membranes in these sheaths are fragile and often break down into rows of vesicles during fixation. Desmosome-like attachment zones occur in many regions of the sheath. The membranes within these zones resist vesiculation and thereby provide a "control" region for relating the type of vesicles formed in the fragile portions of the sheaths to the specific fixation conditions. It is proposed that during fixation the production of artifactual vesicles is governed by an interplay of three factors: (a) direct chemical action of the fixative on the polar strata of adjacent unit membranes, (b) osmotic forces applied to membranes during fixation, and (c) the pre-existing natural relations between adjacent membranes. It is found that permanganate best preserves the continuity of the membranes but will still produce vesicles if the fixative exerts severe osmotic forces. These results support other reports (19) of the importance of comparing tissues fixed by complementary procedures so that systematic artifacts will not be described as characteristic of the natural state.     

Reorganization of the system of intermediate filaments and detection of the organization centers after centrifugation of cells attached to a substrate

Cultured pig kidney epithelial cells were centrifuged at 20,000 gav so that the centrifugation force was oriented parallel to the substrate, fixed and processed for indirect immunofluorescent staining with tubulin and vimentin antibodies. After a 2 hour centrifugation vimentin filaments aggregated in the centripetal parts of the cells (probably, because of their association with floating lipid vesicles). Microtubule-organizing centers were found near the centripetal poles of the nuclei, which migrated in the direction of the centrifugal force. The distribution of the cytoplasmic microtubules did not change during centrifugation. The staining of the cultures one hour after centrifugation revealed vimentin-containing spots with radiating intermediate filaments in most of the cells. These spots were localized near the cell nuclei; double immunofluorescent staining with tubulin and vimentin antibodies showed that their position was identical to that of the microtubule-organizing centers. Similar foci of vimentin filaments were seen in the cells after a 3-4 hour centrifugation. Probably, these structures participate in organizing the intermediate filament cytoskeleton in cells.     

Cytomembranes in first cleavage xenopus embryos

Summary The ultrastructure and interrelationships of the Golgi body, endoplasmic reticulum and lipid droplets have been studied in the first cleavage Xenopus embryos. Lipid droplets, usually spherical or sometimes multilobed, did not have a discernible limiting membrane, although some had an incomplete electron dense partition. The Golgi bodies and endoplasmic reticulum were seen continuous with lipid droplets and the profiles indicated a probable formation of these membranes from lipid droplet material. Rough endoplasmic reticulum (ER) mainly consisted of paired tubular cisternae and vesicles containing filamentous material that gave a fringed appearance. The relationships of paired cisternae with the Golgi body suggested a transformation of ER membranes into the Golgi body membranes. In addition, paired ER cisternae showed a close apposition with the limiting membrane of the yolk platelet. Lone ER cisternae that contained moderately electron dense material instead of filaments were also present and showed numerous associated vesicles near the Golgi body. The Golgi body showed several morphological forms including a single fenestrated cisterna, two to four flat or cup-shaped cisternae, or up to seven cisternae, some of which were dilated and similar to fringed ER in appearance. These forms could be different developmental stages of the organelle. Coated vesicles were seen continuous with the cisternae of the Golgi body. A probable route for the assembly of the cell surface material has been proposed.This work was supported by a grant from the Medical Research Council of Canada to one of us (E.J.S.).     

An electron microscopic study of the interaction in vitro of vimentin intermediate filaments with vesicles prepared from Ehrlich ascites tumor cell lipids

The interaction of intermediate filaments prepared from pure, delipidated vimentin with vesicles obtained from Ehrlich ascites tumor (EAT) cell lipids was studied employing sucrose density gradient centrifugation in combination with electron microscopy. In negative stain electron microscopy, preformed vimentin filaments were seen in lateral association with lipid vesicles; end-on contacts of filaments with liposomes were rarely detected. When the reaction of filaments with vesicles was carried out at 0 degree C, sucrose density gradient equilibrium centrifugation of the reaction products led to the banding of relatively light filament-vesicle meshworks in clear separation from free filaments and free vesicles. With certain vimentin and lipid preparations, occasionally partial breakdown of the filaments during centrifugation and banding of vesicle-free fragments in denser regions of the sucrose gradients was observed. However, when the reaction mixtures were incubated at 37 degrees C prior to sucrose gradient analysis, all filaments were released from vesicles and totally fragmented during centrifugation. Electron microscopy showed unraveling of the filament fragments into subfilament strands. Employing lipid vesicles labeled with [3H]cholesterol, a low but significant amount of radioactivity was found to be associated with the fragments in a non-vesicular form. Filament reconstitution experiments performed in the presence of EAT cell lipids revealed an inhibitory effect of vesicles on filament assembly, particularly at lower temperatures. The mechanical labilization of the filament structure by lipid vesicles might play a role in the redistribution of intermediate filaments in the course of certain cellular processes involving turnover and fragmentation of intracellular membrane systems.     

Circaannual changes in antioxidants and oxidative stress in the heart and liver in rats

Reactive oxygen species are formed in physiological and pathological conditions in mammalian tissues. Because of their high reactivity, they may interact with biomolecules, inducing oxidative injury. Increases in lipid peroxidation can result in oxidative damage to cellular membranes. Protection against oxidative damage is provided by enzymatic and non-enzymatic antioxidant defenses. Antioxidant enzyme activities and lipid peroxidation, as an index of oxidative stress injury, were evaluated in different seasons over one year in the heart and liver of rats, maintained on a 12 h light and dark cycle. Glutathione peroxidase and catalase activities, in both tissues, were maximal in the summer season. Lipid peroxidation in the heart was maximal in the spring as compared to the other seasons and it did not vary in the liver during the year. These findings suggest that any study of antioxidants or oxidative stress must take into account such seasonal variations for a more precise analysis of changes due to any pathological condition.     

The dependence of lipid asymmetry upon phosphatidylcholine acyl chain structure

Lipid asymmetry, the difference in inner and outer leaflet lipid composition, is an important feature of biomembranes. By utilizing our recently developed MβCD-catalyzed exchange method, the effect of lipid acyl chain structure upon the ability to form asymmetric membranes was investigated. Using this approach, SM was efficiently introduced into the outer leaflet of vesicles containing various phosphatidylcholines (PC), but whether the resulting vesicles were asymmetric (SM outside/PC inside) depended upon PC acyl chain structure. Vesicles exhibited asymmetry using PC with two monounsaturated chains of >14 carbons; PC with one saturated and one unsaturated chain; and PC with phytanoyl chains. Vesicles were most weakly asymmetric using PC with two 14 carbon monounsaturated chains or with two polyunsaturated chains. To define the origin of this behavior, transverse diffusion (flip-flop) of lipids in vesicles containing various PCs was compared. A correlation between asymmetry and transverse diffusion was observed, with slower transverse diffusion in vesicles containing PCs that supported lipid asymmetry. Thus, asymmetric vesicles can be prepared using a wide range of acyl chain structures, but fast transverse diffusion destroys lipid asymmetry. These properties may constrain acyl chain structure in asymmetric natural membranes to avoid short or overly polyunsaturated acyl chains.     

Isolation and purification of extracellular matrix vesicles from blood vessels.

Extracellular membrane-bound vesicles (called matrix vesicles) which occur in abundance in atherosclerotic blood vessels are believed to be associated with lipid accumulation and calcification. A technique has been developed to isolate them from experimental aneurysms in sheep in which they are known to be plentiful. The matrix vesicles were isolated by differential centrifugation following extraction by hypotonic salt solution. Most of the vesicles were pelleted at 30,000g and fell within the size range of matrix vesicles in situ in the aneurysmal wall. Preliminary characterization of the enzymatic activities indicates that many of these vesicles are formed from cell membranes rather than being derived from lysosomes, mitochondria or endoplasmic reticulum. Morphologically they are similar to matrix vesicles of other mineralizing tissues.     

HEPATIC INTRACELLULAR OSMIOPHILIC DROPLETS : Effect of Lipid Solvents during Tissue Preparation

Lipid solvent extraction of aldehyde-fixed hepatic tissue of rats caused disappearance of all intravascular and hepatocellular osmiophilic droplets normally present, thus indicating their lipid content. Intramitochondrial dense granules and osmiophilic droplets in lysosomes also disappeared after this treatment. Lipid solvents extracted 43.8 to 92.6% of the radioactivity from aldehyde-fixed rat liver with C¹⁴-labeled lipids. Only 0.7 to 5.8% of the radioactivity was extracted when the hepatic proteins were labeled. When tissue was fixed with OsO₄, the lipid solvents extracted only 0.7 to 7.2% of the radioactivity from lipid-labeled liver and only 0 to 0.7% when proteins were labeled. Thin layer chromatography of the lipid solvents used in extraction of formaldehyde-fixed tissue revealed that triglyceride, phospholipid, and cholesterol and other lipid classes had been removed. However, acetone extracted less phospholipids than did ethanol or methanol-chloroform. During fat absorption the number and size of osmiophilic droplets increased in the nongranular endoplasmic reticulum. In animals fasted up to 5 days, 250-A osmiophilic particles were still present in the Golgi vesicles, other cytoplasmic vesicles, and in the space of Disse. These were considered possibly to represent lipoprotein being synthesized in the liver cell and secreted into the blood.     

Preparation of Artificial Plasma Membrane Mimicking Vesicles with Lipid Asymmetry

Lipid asymmetry, the difference in lipid distribution across the lipid bilayer, is one of the most important features of eukaryotic cellular membranes. However, commonly used model membrane vesicles cannot provide control of lipid distribution between inner and outer leaflets. We recently developed methods to prepare asymmetric model membrane vesicles, but facile incorporation of a highly controlled level of cholesterol was not possible. In this study, using hydroxypropyl-α-cyclodextrin based lipid exchange, a simple method was devised to prepare large unilamellar model membrane vesicles that closely resemble mammalian plasma membranes in terms of their lipid composition and asymmetry (sphingomyelin (SM) and/or phosphatidylcholine (PC) outside/phosphatidylethanolamine (PE) and phosphatidylserine (PS) inside), and in which cholesterol content can be readily varied between 0 and 50 mol%. We call these model membranes “artificial plasma membrane mimicking” (“PMm”) vesicles. Asymmetry was confirmed by both chemical labeling and measurement of the amount of externally-exposed anionic lipid. These vesicles should be superior and more realistic model membranes for studies of lipid-lipid and lipid-protein interaction in a lipid environment that resembles that of mammalian plasma membranes.     

Formation of Folds and Vesicles by Dipalmitoylphosphatidylcholine Monolayers Spread in Excess

Lipid monolayers exist in several biological systems, including the stratum corneum of the skin, the fluid tear film of the eye, the Eustachian tube of the ear, and airway and alveolar pulmonary surfactants. In this paper, the monolayer-to-bilayer transition was studied using dipalmitoylphosphatidylcholine (DPPC) as the model. Depositing DPPC organic solvent solutions in excess at an air:buffer interface led to the formation of elongated structures which could be imaged on carbon grids by transmission electron microscopy. The structures appeared to be DPPC folds protruding into the sol. The structures were frequently ordered with respect to one another, suggesting that they arose during lateral compression due to excess DPPC and are characteristic of a type of monolayer collapse phase. In some cases, series of short folds in an extended line and series of vesicles in line or parallel to the folds were observed. This suggests the elongated folds are unstable and can resolve by forming vesicles. Fold formation occurred at defined lipid concentrations above which more vesicles were observed. Surfactant protein-A did not influence fold or vesicle formation but bound to the edges of these structures preferentially. It is concluded that DPPC monolayers can form bilayers spontaneously in the absence of surfactant apoproteins, other proteins or agents. Received: 18 May 2000/Revised: 20 November 2000     

Lipid extraction by methyl-tert-butyl ether for high-throughput lipidomics

Accurate profiling of lipidomes relies upon the quantitative and unbiased recovery of lipid species from analyzed cells, fluids, or tissues and is usually achieved by two-phase extraction with chloroform. We demonstrated that methyl-tert-butyl ether (MTBE) extraction allows faster and cleaner lipid recovery and is well suited for automated shotgun profiling. Because of MTBE's low density, lipid-containing organic phase forms the upper layer during phase separation, which simplifies its collection and minimizes dripping losses. Nonextractable matrix forms a dense pellet at the bottom of the extraction tube and is easily removed by centrifugation. Rigorous testing demonstrated that the MTBE protocol delivers similar or better recoveries of species of most all major lipid classes compared with the "gold-standard" Folch or Bligh and Dyer recipes.     

Microstructural polymorphism in bovine brain galactocerebroside and its two major subfractions.

Aqueous suspensions of either brain galactocerebrosides or its subfraction consisting of alpha-hydroxyacyl galactocerebrosides are mainly composed of vesicles or granular lipid with occasional multilamellar sheets. In aqueous media the other subfraction consisting of non-hydroxyacyl galactocerebrosides forms some helical structures, but most of the lipid remains as granules or vesicles. It is demonstrated that thermal cycling of non-hydroxyacyl galactocerebrosides in polar nonaqueous solvents can greatly enhance the degree of conversion to helical ribbons about 100 nm in diameter. These structures appear to be a stable dehydrated crystalline form of this lipid and are morphologically similar to helical microstructures produced by a few synthetic lipids. On the other hand, similar treatment of unfractionated bovine brain cerebroside and its alpha-hydroxy fatty acyl subfraction quantitatively produces straight needles that appear to be cochleate cylinders. While their dimensions depend on formation conditions, a typical suspension has uniform particles with diameters close to 100 nm and lengths variable from one to a few hundred micrometers. This is the first report demonstrating the quantitative formation of crystalline high axial ratio microstructures from complex mixtures of natural lipids. The different microstructures formed by the two components appear related to the various forms of lipid deposits occurring in lipid storage diseases. The similarity of these "synthetic" microstructures to biological structures in which they are found (such as myelin and intestinal brush border microvilli) strengthens the possibility that galactocerebrosides have a role in stabilizing cylindrical biological structures.     

Phospholipid exchange between bilayer membranes.

The mode of interaction of aqueous dispersions of phospholipid vesicles is investigated. The vesicles (average diameter 950 A) are prepared from total lipid extracts of Escherichia coli composed of phosphatidylethanolamine, phosphatidylglycerol and cardiolipin. One type of vesicle contains trans-delta 9-octadecenoate, the other type trans-delta 9-hexadecenoate as predominant acyl chain component. The vesicles show order in equilibrium disorder transitions at transition temperatures, Tt = 42 degrees C and Tt = 29 degrees C, respectively. A mixture of these vesicles is incubated at 45 degrees C and lipid transfer is studied as a function of time using the phase transition as an indicator. The system reveals the following properties: Lipids are transferred between the two vesicle types giving rise to a vesicle population where both lipid components are homogeneously mixed. Lipid transfer is asymmetric, i.e. trans-delta 9-hexadecenoate-containing lipid molecules appear more rapidly in the trans-delta 9-octadecenoate-containing vesicles than vice versa. At a given molar ratio of the two types of vesicles the rate of lipid transfer is independent of the total vesicle concentration. It is concluded that lipid exchange through the water phase by way of single molecules or micelles is the mode of communication of these negatively charged lipid vesicles.     

PHAGOCYTOSIS OF LATEX BEADS BY ACANTHAMOEBA CASTELLANII (NEFF) : III. Isolation of the Phagocytic Vesicles and Their Membranes

A method is described for the rapid and efficient isolation of phagocytic vesicles from large scale cultures of Acanthamoeba castellanii (Neff) that have been incubated with polystyrene latex beads. Cells were allowed to phagocytose latex beads for 30 min and then were homogenized, and the phagocytic vesicles were isolated by one centrifugation through several layers of sucrose. Identity and purity of the phagocytic vesicles were determined by electron microscopy, chemical analyses, and assays of acid phosphatase, α- and β-glucosidase, and reduced nicotinamide adenine dinucleotide dehydrogenase. When phagocytosis was allowed to occur for longer periods the phagocytic vesicles appeared to fuse with each other and perhaps with digestive vacuoles. The resultant vesicles which contained many beads were heavier than those which consisted of only one bead or a few beads with a closely applied membrane. Ultrasonication ruptured the isolated vesicles, and the membranes could then be isolated in 30–50% yield based on phospholipid analysis. These membranes were essentially free of acid hydrolases and, presumably, other soluble proteins, as was also indicated by their low ratio of protein to phospholipid. The membranes have been prepared both as closed vesicles and as open sheets.     

Micelle-vesicle transition of egg phosphatidylcholine and octyl glucoside

The dissolution and formation of egg phosphatidylcholine (PC) vesicles by the detergent octyl glucoside were examined systematically by using resonance energy transfer between fluorescent lipid probes, turbidity, and gel filtration chromatography. Resonance energy transfer was exquisitely sensitive to the intermolecular distance when the lipids were in the lamellar phase and to the transitions leading to mixed micelles. Turbidity measurements provided information about the aggregation of lipid and detergent. Several reversible discrete transitions between states of the PC-octyl glucoside system were observed by both methods during dissolution and vesicle formation. These states could be described as a series of equilibrium structures that took the forms of vesicles, open lamellar sheets, and mixed micelles. As detergent was added to an aqueous suspension of vesicles, the octyl glucoside partitioned into the vesicles with a partition coefficient of 63. This was accompanied by leakage of small molecules and vesicle swelling until the mole fraction of detergent in the vesicles was just under 50% (detergent:lipid ratio of 1:1). Near this point, a transition was observed by an increase in turbidity and release of large molecules like inulin, consistent with the opening of vesicles. Both a turbidity maximum and a sharp increase in fluorescence were observed at a detergent to lipid mole ratio of 2.1:1. This was interpreted as the lower boundary of a region where both lamellar sheets and micelles are at equilibrium. At a detergent:lipid ratio of 3.0:1, another sharp change in resonance energy transfer and clarification of the suspension were observed, demarcating the upper boundary of this two-phase region. This latter transition is commonly referred to as solubilization.(ABSTRACT TRUNCATED AT 250 WORDS)     

Breeding and post-breeding structure of the vas deferens of the long-toed salamander Ambystoma macrodactylum

The vas deferens of Ambystoma macrodactylum is composed of a peritoneal epithelium, connective tissue layer with fibroblasts, circular smooth muscle, capillaries, cells containing lipid, and a luminal epithelium composed of a single layer of cuboidal cells covered by a net of interconnected ciliated squamous cells. The cuboidal cells have abundant rough endoplasmic reticulum, mitochondria, and PAS + secretory vesicles. Squamous cells of breeding males consistently have tufts of ～100 cilia located at one end of the long axis of each cell. These cilia may help distribute secretory products. The squamous cells, absent in post-breeding males, are apparently sloughed into the lumen. Lipid vesicles are present throughout the cytoplasm of the cuboidal and squamous epithelial cells and are also in some cells of the connective tissue layer. These vesicles increase dramatically in number during the first 4 weeks after breeding and may serve as an energy pool for the next breeding season. Enzyme-histochemical tests for testosterone synthesis were negative. In addition to the accumulation of lipid and the loss of squamous cells in the vas deferens, after breeding PAS + vesicle production is terminated. These alterations appear to represent energy conservation strategies employed by the sperm-depleted vas deferens.