Ann E. Oliver

In vivo lipidomics using single-cell Raman spectroscopy

We describe a method for direct, quantitative, in vivo lipid profiling of oil-producing microalgae using single-cell laser-trapping Raman spectroscopy. This approach is demonstrated in the quantitative determination of the degree of unsaturation and transition temperatures of constituent lipids within microalgae. These properties are important markers for determining engine compatibility and performance metrics of algal biodiesel. We show that these factors can be directly measured from a single living microalgal cell held in place with an optical trap while simultaneously collecting Raman data. Cellular response to different growth conditions is monitored in real time. Our approach circumvents the need for lipid extraction and analysis that is both slow and invasive. Furthermore, this technique yields real-time chemical information in a label-free manner, thus eliminating the limitations of impermeability, toxicity, and specificity of the fluorescent probes common in currently used protocols. Although the single-cell Raman spectroscopy demonstrated here is focused on the study of the microalgal lipids with biofuel applications, the analytical capability and quantitation algorithms demonstrated are applicable to many different organisms and should prove useful for a diverse range of applications in lipidomics.

MEMBRANE PHASE TRANSITION OF INTACT HUMAN PLATELETS : CORRELATION WITH COLD-INDUCED ACTIVATION

Using Fourier transform infrared spectroscopy (FTIR), we have determined the phase transition temperature (Tm) of lipids in intact human platelets and have shown that it occurs between 15 and 18°C, the temperature at which cold activation of platelets has previously been reported (Zucker and Borrelli, 1954, Blood, 28:602–608; White and Krivit, 1967, Blood, 30:625–635). The temperature at which the platelets pass through Tm is highly correlated with initial platelet shape change. However, change continues after the cells have passed through the phase transition. Cold‐induced activation has previously prevented long‐term storage of platelets at 4°C. Antifreeze glycoproteins (AFGPs) isolated from polar fishes previously have been used to prevent ice crystal growth during freezing of tissues as well as leakage of solutes from liposomes as they were chilled through their Tm. We sought to determine if these AFGPs were able to stabilize platelets for long‐term storage at 4°C. Incubating platelets with antifreeze glycoproteins during long‐term storage and rapid rewarming to 37°C abrogated granule secretion associated with cold activation in a dose‐dependent manner. This work suggests that AFGPs may be a possible solute for use in long‐term low temperature storage of platelets.

Evidence for a physiological role for membrane rafts in human platelets.

We have investigated raft formation in human platelets in response to cell activation. Lipid phase separation and domain formation were detected using the fluorescent dye 1,1′‐dioctadecyl‐3,3,3′,3′‐tetramethyl‐indocarbocyanine perchlorate (diI‐C18) that preferentially partitions into gel‐like lipid domains. We showed that when human platelets are activated by cold and physiological agonists, rafts coalesce into visible aggregates. These events were disrupted by depletion of membrane cholesterol. Using Fourier transform infrared spectroscopy (FTIR), we measured a thermal phase transition at around 30°C in intact platelets, which we have assigned as the liquid‐ordered to the liquid‐disordered phase transition of rafts. Phase separation of the phospholipid and the sphingomyelin‐enriched rafts could be observed as two phase transitions at around 15 and 30°C, respectively. The higher transition, assigned to the rafts, was greatly enhanced with removal of membrane cholesterol. Detergent‐resistant membranes (DRMs) were enriched in cholesterol (50%) and sphingomyelin (20%). The multi‐functional platelet receptor CD36 selectively partitioned into DRMs, whereas the GPI‐linked protein CD55 and the major platelet integrin αIIbβ3a did not, which suggests that the clustering of proteins within rafts is a regulated process dependent on specific lipid protein interactions. We suggest that raft aggregation is a dynamic, reversible physiological event triggered by cell activation. J. Cell. Physiol. 190: 117–128, 2002.

Stabilization of Dry Mammalian Cells: Lessons from Nature

Abstract The Center for Biostabilization at UC Davis is attempting to stabilize mammalian cells in the dry state. We review here some of the lessons from nature that we have been applying to this enterprise, including the use of trehalose, a disaccharide found at high concentrations in many anhydrobiotic organisms, to stabilize biological structures, both in vitro and in vivo. Trehalose has useful properties for this purpose and in at least in one case—human blood platelets—introducing this sugar may be sufficient to achieve useful stabilization. Nucleated cells, however, are stabilized by trehalose only during the initial stages of dehydration. Introduction of a stress protein obtained from an anhydrobiotic organism, Artemia, improves the stability markedly, both during the dehydration event and following rehydration. Thus, it appears that the stabilization will require multiple adaptations, many of which we propose to apply from studies on anhydrobiosis.

Methods for dehydration-tolerance: Depression of the phase transition temperature in dry membranes and carbohydrate vitrification

Anhydrobiosis, or life without water, is the remarkable ability of certain types of plants and animals to survive almost total dehydration. This phenomenon requires a coordinated series of events within the cells of anhydrobiotes that protect their cellular components, particularly proteins and lipid membranes, from damage caused by the removal of water. Much of what is now understood about preserving biological samples during drying was learned by studying naturally desiccation-tolerant organisms and extended using model systems such as phospholipid vesicles. Most anhydrobiotic organisms accumulate disaccharides in their cells and tissues during the dehydration process. These carbohydrates, usually sucrose or trehalose, satisfy two criteria that appear to be necessary for protecting membranes during desiccation and during storage in the dry state. These requirements include: (1) depression of the gel-to-liquid crystalline phase transition temperature (T m ) in the dehydrated lipid to a temperature at or near that of the hydrated lipid, a process that appears to require a direct interaction between the carbohydrates and the lipid molecules of the membrane; and (2) formation of a carbohydrate glass with a relatively high glass transition temperature, leading to inhibition of fusion between the vesicles.

Looking beyond sugars: the role of amphiphilic solutes in preventing adventitious reactions in anhydrobiotes at low water contents

Plants and animals that can survive dehydration accumulate high concentrations of disaccharides in their cells and tissues during desiccation. These sugars are necessary both for the depression of the membrane phase transition temperature of the dry lipid and for the formation of a carbohydrate glass. In the past decade, however, it has become clear that certain types of adventitious enzymatic reactions are possible at low water contents, which along with free-radical mediated damage, can cause hydrolysis of lipids and loss of membrane barrier function. Disaccharides do not necessarily prevent these types of reactions, which suggests that other compounds might also be necessary for protecting organisms from this type of degradation during anhydrobiosis. Arbutin, one possible example, accumulates in large quantities in certain resurrection plants and has been shown to inhibit phospholipase A(2) activity at low water contents. The direct effect of arbutin on membranes under stress conditions depends on the membrane lipid composition. It can serve a protective function during desiccation- or freeze/thaw-induced stress in the presence of nonbilayer-forming lipids or a disruptive function in their absence. Other possible amphiphiles, including certain naturally occurring flavonols, may serve as anti-oxidants and some might have similar lipid composition-dependent effects. Such compounds, therefore, are likely to be localized near specific membranes, where they might provide the greatest benefit at the least liability to the organism.

Loading Human Mesenchymal Stem Cells with Trehalose by Fluid-Phase Endocytosis

Human mesenchymal stem cells (MSCs) have shown great promise in the area of tissue engineering. Regardless of their regenerative potential, however, they will not be useful on a large scale unless an improved and more stable form of cellular storage is developed. An ideal storage condition would be dehydrated cells, as this would allow room temperature storage and would not require refrigeration or freezing equipment. As a first step toward developing a method for storing MSCs in a desiccated state, we have characterized the ability of these cells to take up solutes from the extracellular milieu, as the introduction of protective solutes into the cytosol is a critical step in the dehydration process. Lucifer yellow (LYCH), a well-known probe in the study of fluid-phase endocytosis, indicated the uptake process was inhibited below 20°C. Fourier transfer infrared spectroscopy studies suggested that this inhibition is associated with the membrane physical state. In addition, fluorescence microscopy revealed ...

Lipid composition determines the effects of arbutin on the stability of membranes

Arbutin (hydroquinone-beta-D-glucopyranoside) is an abundant solute in the leaves of many freezing- or desiccation-tolerant plants. Its physiological role in plants, however, is not known. Here we show that arbutin protects isolated spinach (Spinacia oleracea L.) thylakoid membranes from freeze-thaw damage. During freezing of liposomes, the presence of only 20 mM arbutin led to complete leakage of a soluble marker from egg PC (EPC) liposomes. When the nonbilayer-forming chloroplast lipid monogalactosyldiacylglycerol (MGDG) was included in the membranes, this leakage was prevented. Inclusion of more than 15% MGDG into the membranes led to a strong destabilization of liposomes during freezing. Under these conditions arbutin became a cryoprotectant, as only 5 mM arbutin reduced leakage from 75% to 20%. The nonbilayer lipid egg phosphatidylethanolamine (EPE) had an effect similar to that of MGDG, but was much less effective, even at concentrations up to 80% in EPC membranes. Arbutin-induced leakage during freezing was accompanied by massive bilayer fusion in EPC and EPC/EPE membranes. Twenty percent MGDG in EPC bilayers completely inhibited the fusogenic effect of arbutin. The membrane surface probes merocyanine 540 and 2-(6-(7-nitrobenz-2-oxa-1, 3-diazol-4-yl)amino)hexanoyl-1-hexadecanoyl-sn-glycero-3-phosph ocholi ne (NBD-C(6)-HPC) revealed that arbutin reduced the ability of both probes to partition into the membranes. Steady-state anisotropy measurements with probes that localize at different positions in the membranes showed that headgroup mobility was increased in the presence of arbutin, whereas the mobility of the fatty acyl chains close to the glycerol backbone was reduced. This reduction, however, was not seen in membranes containing 20% MGDG. The effect of arbutin on lipid order was limited to the interfacial region of the membranes and was not evident in the hydrophobic core region. From these data we were able to derive a physical model of the perturbing or nonperturbing interactions of arbutin with lipid bilayers.

Effects of Temperature on Calcium-Sensitive Fluorescent Probes

The effect of temperature on the binding equilibria of calcium-sensing dyes has been extensively studied, but there are also important temperature-related changes in the photophysics of the dyes that have been largely ignored. We conducted a systematic study of thermal effects on five calcium-sensing dyes under calcium-saturated and calcium-free conditions. Quin-2, chlortetracycline, calcium green dextran, Indo-1, and Fura-2 all show temperature-dependent effects on fluorescence in all or part of the range tested (5-40 degrees C). Specifically, the intensity of the single-wavelength dyes increased at low temperature. The ratiometric dyes, because of variable effects at the two wavelengths, showed, in general, a reduction in the fluorescence ratio as temperature decreased. Changes in viscosity, pH, oxygen quenching, or fluorescence maxima could not fully explain the effects of temperature on fluorescence. The excited-state lifetimes of the dyes were determined, in both the presence and absence of calcium, using multifrequency phase-modulation fluorimetry. In most cases, low temperature led to prolonged fluorescence lifetimes. The increase in lifetimes at reduced temperature is probably largely responsible for the effects of temperature on the physical properties of the calcium-sensing dyes. Clearly, these temperature effects can influence reported calcium concentrations and must therefore be taken into consideration during any investigation involving variable temperatures.

The effects of chloroplast lipids on the stability of liposomes during freezing and drying

Chloroplast thylakoids contain four classes of lipids, monogalactosyldiacylglycerol (MGDG), digalactosyldiacylglycerol (DGDG), sulfoquinovosyldiacylglycerol (SQDG), and phosphatidylglycerol (cpPG). We have investigated the effects of these lipids on the stability of large unilamellar vesicles made from egg phosphatidylcholine (EPC), by substitution of different fractions of EPC in the membranes by the various chloroplast lipids. Damage to liposomes after freezing to - 18 degrees C was measured as carboxyfluorescein leakage or fusion between vesicles. The presence of all chloroplast lipids increased leakage. However, the maximum amount of leakage and the concentration dependence were dramatically different between the different lipids. Only SQDG induced vesicle fusion, while the non-bilayer lipid MGDG did not. The presence of MGDG in the membranes led to more leakage than the presence of another non-bilayer lipid, egg phosphatidylethanolamine (EPE). In EPE-containing liposomes, leakage was strongly associated with fusion. Combinations of different chloroplast lipids had an additive effect on leakage induced by freezing. Most of the leakage from galactolipid-containing vesicles occurred during the first 15 min of freezing at - 18 degrees C. After a 3 h incubation period, most leakage occurred between 0 degrees C and - 10 degrees C. Lowering the temperature to - 22 degrees C had only a small additional effect. Incubation of liposomes at - 10 degrees C in the presence of 2.5 M NaCl without ice crystallization, approximately the same concentration obtained by freezing to - 10 degrees C, resulted in very little leakage. Air drying of liposomes to low water contents resulted in massive leakage, both from pure EPC vesicles and from vesicles containing galactolipids. The latter vesicles showed more leakage at any given water content than EPC vesicles.