Oral secretions from herbivorous lepidopteran larvae exhibit ion channel-forming activities

Feeding insects introduce oral secretions (OS) into the wounded tissue of the attacked plant. Various OS-derived molecules must be involved in subsequent processes including the induction of plant defence reactions. Using the planar lipid bilayer membrane technique, isolated OS were analyzed with respect to their membrane activities. Transmembrane ion fluxes were generated by OS of eight different lepidopteran larvae, all of which form comparable ion channels in artificial membranes. Currents were characterized by long lasting open times and conductivities from 250pS up to 1100pS. Channels formed by Spodoptera exigua secretions showed a preference for cations over anions. OS also induced a transient increase of the cytosolic calcium concentration in soybean cells, determined by the aequorin technique. Known compounds of the OS, fatty-acid-glutamine conjugates, also interfered with the membrane but were unable to form stable channels. Since ion fluxes and depolarization are early responses upon insect feeding, OS-derived components may be involved in the elicitation process by direct interaction with the plant membranes.     

Surfactin and fengycin lipopeptides of Bacillus subtilis as elicitors of induced systemic resistance in plants

Multiple strains of Bacillus spp. were demonstrated to stimulate plant defence responses. However, very little is known about the nature of molecular determinants secreted by these Gram-positive bacteria that are responsible for the elicitation of the induced systemic resistance (ISR) phenomenon. This study shows that the lipopeptides surfactins and fengycins may be involved in this elicitation process. In bean, pure fengycins and surfactins provided a significant ISR-mediated protective effect on bean plants, similar to the one induced by living cells of the producing strain S499. Moreover, experiments conducted on bean and tomato plants showed that overexpression of both surfactin and fengycin biosynthetic genes in the naturally poor producer Bacillus subtilis strain 168 was associated with a significant increase in the potential of the derivatives to induce resistance. In tomato cells, key enzymes of the lipoxygenase pathway appeared to be activated in resistant plants following induction by lipopeptide overproducers. To our knowledge, such lipopeptides constitute a novel class of compounds from non-pathogenic bacteria that can be perceived by plant cells as signals to initiate defence mechanisms.     

Phospholipase D in hormonal and stress signaling

Phospholipase D (PLD) is a family of diverse enzymes that are differentially regulated by Ca(2+), polyphosphoinositides, free fatty acids, G-proteins, N-acylethanolamines, and membrane lipid environments. Two new types of PLDs were identified in the past year: one is activated by oleic acid and the other requires no cation for activity. The oleate-stimulated PLD is associated with the plasma membrane and binds to microtubules. The Ca(2+)-independent PLD contains a PX and a PH domain, but not the Ca(2+)/phospholipid-binding C2 domain found in most plant PLDs. The mechanism by which Ca(2+), phosphoinositides, and G proteins regulate certain PLDs is better understood. PLDs and their product phosphatidic acid are involved in various stress responses, including water deficits, salts, wounding, and elicitation. Increasing evidence supports a role of PLD in the abscisic acid signaling cascades.     

Phytoalexin Induction in French Bean : Intercellular Transmission of Elicitation in Cell Suspension Cultures and Hypocotyl Sections of Phaseolus vulgaris

Treatment of hypocotyl sections or cell suspension cultures of dwarf French bean (Phaseolus vulgaris L.) with an abiotic elicitor (denatured ribonuclease A) resulted in increased extractable activity of the enzyme l-phenylalanine ammonia-lyase. This induction could be transmitted from treated cells through a dialysis membrane to cells which were not in direct contact with the elicitor. In hypocotyl sections, induction of isoflavonoid phytoalexin accumulation was also transmitted across a dialysis membrane, although levels of insoluble, lignin-like phenolic material remained unchanged in elicitor-treated and control sections. In bean cell suspension cultures, the induction of phenylalanine ammonia-lyase in cells separated from ribonuclease-treated cells by a dialysis membrane was also accompanied by increases in the activities of chalcone synthase and chalcone isomerase, two enzymes previously implicated in the phytoalexin defense response. Such intercellular transmission of elicitation did not occur in experiments with cells treated with a biotic elicitor preparation heat-released from the cell walls of the bean pathogen Colletotrichum lindemuthianum. The results confirm and extend previous suggestions that a low molecular weight, diffusible factor of host plant origin is involved (in French bean) in the intercellular transmission of the elicitation response to abiotic elicitors.     

Lipid signaling

Various lipids are involved in mediating plant growth, development and responses to biotic and abiotic cues, and their production is regulated by lipid-signaling enzymes. Lipid-hydrolyzing enzymes play a pivotal role both in the production of lipid messengers and in other processes, such as cytoskeletal rearrangement, membrane trafficking, and degradation. Studies on the downstream targets and modes of action of lipid signals in plants are still in their early stages but distinguishing features of plant lipid-based signaling are being recognized. Phospholipase D enzymes and phosphatidic acid may play a broader role in lipid signaling in plants than in other systems.     

Lipid rafts in higher plant cells: purification and characterization of Triton X-100-insoluble microdomains from tobacco plasma membrane

A large body of evidence from the past decade supports the existence of functional microdomains in membranes of animal and yeast cells, which play important roles in protein sorting, signal transduction, or infection by pathogens. They are based on the dynamic clustering of sphingolipids and cholesterol or ergosterol and are characterized by their insolubility, at low temperature, in nonionic detergents. Here we show that similar microdomains also exist in plant plasma membrane isolated from both tobacco leaves and BY2 cells. Tobacco lipid rafts were found to be greatly enriched in a sphingolipid, identified as glycosylceramide, as well as in a mixture of stigmasterol, sitosterol, 24-methylcholesterol, and cholesterol. Phospho- and glycoglycerolipids of the plasma membrane were largely excluded from lipid rafts. Membrane proteins were separated by one- and two-dimensional gel electrophoresis and identified by tandem mass spectrometry or use of specific antibody. The data clearly indicate that tobacco microdomains are able to recruit a specific set of the plasma membrane proteins and exclude others. We demonstrate the recruitment of the NADPH oxidase after elicitation by cryptogein and the presence of the small G protein NtRac5, a negative regulator of NADPH oxidase, in lipid rafts.     

The plant defense elicitor cryptogein stimulates clathrin-mediated endocytosis correlated with reactive oxygen species production in bright yellow-2 tobacco cells

The plant defense elicitor cryptogein triggers well-known biochemical events of early signal transduction at the plasma membrane of tobacco (Nicotiana tabacum) cells, but microscopic observations of cell responses related to these early events were lacking. We determined that internalization of the lipophilic dye FM4-64, which is a marker of endocytosis, is stimulated a few minutes after addition of cryptogein to tobacco Bright Yellow-2 (BY-2) cells. This stimulation is specific to the signal transduction pathway elicited by cryptogein because a lipid transfer protein, which binds to the same receptor as cryptogein but without triggering signaling, does not increase endocytosis. To define the nature of the stimulated endocytosis, we quantified clathrin-coated pits (CCPs) forming on the plasma membrane of BY-2 cells. A transitory stimulation of this morphological event by cryptogein occurs within the first 15 min. In the presence of cryptogein, increases in both FM4-64 internalization and clathrin-mediated endocytosis are specifically blocked upon treatment with 5 microm tyrphostin A23, a receptor-mediated endocytosis inhibitor. The kinetics of the transient increase in CCPs at the plasma membrane coincides with that of transitory reactive oxygen species (ROS) production occurring within the first 15 min after elicitation. Moreover, in BY-2 cells expressing NtrbohD antisense cDNA, which are unable to produce ROS when treated with cryptogein, the CCP stimulation is inhibited. These results indicate that the very early endocytic process induced by cryptogein in tobacco is due, at least partly, to clathrin-mediated endocytosis and is dependent on ROS production by the NADPH oxidase NtrbohD.     

Fusogenic potential of sperm membrane lipids: nature's wisdom to accomplish targeted gene delivery

The membrane-membrane fusion during fertilization of oocyte by spermatozoa is believed to be mainly mediated by so called "fusion proteins". In the present study we have tried to demonstrate that beside the proteins, lipid components of membrane may play an important role in fusion of oocyte with spermatozoa. Conventional membrane-membrane fusion assays were used as means to demonstrate fusogenic potential of human sperm membrane lipids. The liposomes (spermatosomes) made of the lipids isolated from sperm membrane were found to undergo strong membrane-membrane fusion as evident from fluorescence dequenching and resonance energy transfer assays. Furthermore, the fusion of these liposomes with living cells (J774 A.1 macrophage cell line) was demonstrated to result in an effective transfer of a water-soluble fluorescent probe (calcein) to cytosol of the target cell. Lastly, the liposomes were demonstrated to behave like efficient vehicles for the in vivo cytosolic delivery of the antigens to target cells resulting in elicitation of antigen specific CD8(+) T cell responses.     

Catalysis of ACAT may be completed within the plane of the membrane: a working hypothesis.

Two ACAT sharing protein sequence homology near their C termini have been identified. Both proteins may span the endoplasmic reticulum (ER) membrane several times. There is good evidence implicating the role of ACAT1 in macrophage foam cell formation, and ACAT2 in intestinal cholesterol absorption. On the other hand, the functional roles of ACAT1 and ACAT2 in the VLDL or chylomicron assembly process are less clear. It is possible that both enzymes are able to form lipid droplets (which are present in the cytoplasm), and participate in lipoprotein assembly (which occurs in the ER lumen). To link the site of ACAT catalysis with its function, we propose that part of the ACAT catalytic site may reside within the lipid bilayer, allowing catalysis to be completed within the plane of the membrane. Cholesteryl esters (CE) produced in situ may burst into cytoplasmic lipid droplets, carrying phospholipid monolayers as their outer coats. In cells engaged in lipoprotein assembly and secretion, CE in the bilayer may be recognized by the specific protein microsomal triacylglycerol transfer protein (MTP), reaching out from the lumenal side of the membrane. MTP then lipidates the growing apolipoprotein B (apoB) chain with CE and TG during the early stages of apoB lipoprotein assembly.     

Histochemical Evidence for the Presence of Lysosome-like Particles in root Meristem Cells of Vicia faba

The lysosomes of animal cells, as defined by biochemists, areparticles limited by a lipid-protein membrane and which containhydrolytic enzymes; they are inert until the permeability ofthe limiting membrane has been altered. In addition, the lysosomesin animal cells have been demonstrated also by histochemicalprocedures. Acid phosphatase may be used as a marker for lysosomes,and can be demonstrated by a modified Gomori procedure. Thus,in controlled-temperature frozen sections of plant tissue, ithas been possible to demonstrate granules which are inactivefor acid phosphatase until subjected to agents that will disruptlipid-protein structures, namely freezing and thawing, formaldehydeand heat. Whether such particles are the lysosomes is discussed.     

Synthesis and turnover of non-polar lipids in yeast

In the yeast Saccharomyces cerevisiae as in other eukaryotic cells non-polar lipids form a reservoir of energy and building blocks for membrane lipid synthesis. The yeast non-polar lipids, triacylglycerol (TAG) and steryl ester (STE), are synthesized by enzymes with overlapping function. Recently, genes encoding these enzymes were identified and gene products were partially characterized. Once formed, TAG and STE are stored in so-called lipid particles/droplets. This compartment which is reminiscent of mammalian lipoproteins from the structural viewpoint is, however, not only a lipid depot but also an organelle actively contributing to lipid metabolism. Non-polar lipid degrading enzymes, TAG lipases and STE hydrolases, also occur in redundancy in the yeast. These proteins, which are components of the lipid particle surface membrane with the exception of one plasma membrane localized STE hydrolase, mobilize non-polar lipids upon requirement. In this review, we describe the coordinate pathways of non-polar lipid synthesis, storage and mobilization in yeast with special emphasis on the role of the different enzymes and organelles involved in these processes. Moreover, we will discuss non-polar lipid homeostasis and its newly discovered links to various cell biological processes in the yeast.     

Surface alterations in transformed epithelial and fibroblastic cells in culture: A disturbance of membrane degradation versus biosynthesis?

Fibroblasts which were transformed with oncogenic DNA or RNA viruses as well as by chemicals or spontaneously have, with very few exceptions, been shown to possess increased agglutinabilities with various plant agglutinins. This surface membrane alteration is now shown to hold true also for transformed epithelial cells and for tumors of epithelial origin as monitored by wheat germ agglutinin, Concanavalin A, phytohemagglutinin, Ricinus communis and Great Northern bean (GNB) agglutinin. An agglutinin from lentils did the opposite. It permitted the agglutination of normal liver cells but not that of hepatoma cells which led to the suggestion that some membrane glycoproteins or glycolipids may possibly be turned inside out while others are turned outside in (during the transformation process. Inhibition of protein synthesis in normal cells brought about the agglutinable membrane state in non-growing or resting cells but not in actively growing cells. Since this agglutinability could be inhibited by protease inhibitors and since proteolytic enzymes could bring about the agglutinable membrane state in growing normal cells, it was suggested that growing cells have as active a biosynthesis of membrane proteins as do non growing cells but that non-growing cells are actively catabolizing their membranes with proteases, much more so than non growing, stationary cells.     

Induction of competence for elicitation of defense responses in cucumber hypocotyls requires proteasome activity

The epidermal cells of hypocotyls from etiolated cucumber seedlings are not constitutively competent for elicitation of the rapid H2O2 defense response. However, elicitor competence developed while conditioning the surface-abraded seedlings by rotating them in buffer for 4 h. Competence development was greatly potentiated by inducers of systemic acquired resistance and suppressed by specific inhibitors of proteasome activity, clastolactacystin beta-lactone (LAC) and carboxybenzoyl-L-leucyl-L-leucyl-L-leucinal (LLL). In the freshly abraded seedlings, chitinase gene activation became evident approximately 4 h after elicitor addition. Accumulation of chitinase mRNA was enhanced upon conditioning prior to elicitation and was inhibited by LAC and LLL, indicating that the process which leads to H2O2 elicitation competence is also superimposed on the elicitation of chitinase mRNA. LAC and LLL caused an accumulation of ubiquitin-conjugated proteins and enhanced the expression of a proteasome alpha-subunit, suggesting that proteasome activity was specifically inhibited and that the effect observed on gene expression was not due to impaired gene induction in general. Together, our results suggest that the ubiquitin-proteasome system may play a crucial role in a process which switches the signaling pathway for diverse plant defense responses into a functional state, as is known for many basic cellular processes in both animals and yeast.     

Effects of Cerulenin upon the Syntheses of Lipid and Protein and upon the Formation of Respiratory Enzymes in Adapting, Lipid-Limited Saccharomyces cerevisiae

When bakers' yeast cells were grown anaerobically in a medium supplemented with Tween 80 and ergosterol, exposure during aeration to the fatty acid synthesis inhibitor, cerulenin, had little effect upon respiratory adaptation, the induction of enzymes of electron transport, or the in vivo incorporation of [(14)C]leucine into mitochondrial membranes. These lipid-supplemented cells were apparently able to undergo normal respiratory adaptation utilizing endogenous lipids alone. The level of cerulenin used (2 mug/ml) inhibited the in vivo incorporation of [(14)C]acetate into mitochondrial membrane lipids by 96%. If, however, the cells were deprived of exogenous lipid during anaerobic growth, subsequent exposure to cerulenin severely reduced their capacity to undergo respiratory adaptation, to form enzymes of electron transport, and to incorporate amino acid into both total cell and mitochondrial membrane proteins. This cerulenin-mediated inhibition of enzyme formation and of protein synthesis was nearly completely reversed by the addition of exogenous lipid during the aeration of the cells. In lipid-limited cells, chloramphenicol also had dramatic inhibitory effects, both alone (75%) and together with cerulenin (85%), upon total cell and mitochondrial membrane [(14)C]leucine incorporation. This marked chloramphenicol-mediated inhibition was also largely reversed by exogenous lipid. It is concluded that, in lipid-limited cells, either cerulenin or chloramphenicol may prevent the emergence of a pattern of lipids required for normal levels of protein synthetic activity. The effect of cerulenin upon the formation of mitochondrial inner membrane enzymes thus appears to reflect a nonspecific effect of this antilipogenic antibiotic upon total cell protein synthesis.     

Inhibition of elicitor-induced phytoalexin formation in cotton and soybean cells by citrate

Addition of an elicitor preparation from Verticillium dahliae to soybean or cotton cell suspension cultures induces the formation of the phytoalexins, glycelollin or sesquiterpene aldehydes, respectively. Recent work (PS Low, PF Heinstein 1986 Arch Biochem Biophys 249: 472-479) has shown that the induction of phytoalexin biosynthesis in these cells is preceded by rapid changes in the plant cell membrane which can be conveniently monitored by membrane associated fluorescent probes. Using this elicitation assay, we have found that citrate, a common metabolite of higher plants, acts as a potent inhibitor of elicitation when added prior to treatment with elicitor. The citrate concentration required to obtain a 50% inhibition of the elicitor-induced fluorescence transition in cultured cotton cells was found to be about 2 millimolar, while the concentration of citrate observed to inhibit elicitor-induced sesquiterpene aldehyde formation in the same cell suspensions was also 2 millimolar. Curiously, in the presence of elicitor, citrate at less than ID₅₀ concentrations increased cell mass accumulation significantly above control incubations without elicitor. A similar inhibition of glyceollin formation with an increase in cell mass accumulation was also observed upon addition of 1 to 5 millimolar citrate to soybean cell suspension cultures. The physiological significance of the inhibition by citrate of phytoalexin formation in plant cell suspensions was supported by the observation that a similar inhibition of sesquiterpene aldehyde formation occurs in cotton plantlets elicited by cold shock or V. dahliae stress. The specificity of citrate as an inhibitor of phytoalexin formation was demonstrated by data showing that other di- and tricarboxylic-hydroxy acids did not inhibit, with the exception of malate which inhibited phytoalexin formation in soybean cells with roughly half the potency of citrate. These experiments not only demonstrate that citrate can act as a specific inhibitor of elicitation, but they further confirm the validity of monitoring elicitation and its modulation with fluorescent probes.     

The plasma membrane lipid composition affects fusion between cells and model membranes

Investigations were carried out on the effect of plasma membrane lipid modifications on the fusogenic capacity of control and ras-transformed fibroblasts. The plasma membrane lipid composition was modified by treatment of cells with exogenous phospholipases C and D, sphingomyelinase and cyclodextrin. The used enzymes hydrolyzed definite membrane lipids thus inducing specific modifications of the lipid composition while cyclodextrin treatment reduced significantly the level of cholesterol. The cells with modified membranes were used for assessment of their fusogenic capacity with model membranes with a constant lipid composition. Treatment with phospholipases C and D stimulated the fusogenic potential of both cell lines whereas the specific reduction of either sphingomyelin or cholesterol induced the opposite effect. The results showed that all modifications of the plasma membrane lipid composition affected the fusogenic capacity irrespective of the initial differences in the membrane lipid composition of the two cell lines. These results support the notion that the lipid composition plays a significant role in the processes of membrane-membrane fusion. This role could be either direct or through modulation of the activity of specific proteins which regulate membrane fusion.     

Carbon Dioxide Hydration with Liposomes Entrapping Carbonic Anhydrase

Abstract

Liposomes entrapping enzymes behave as small membrane bioreactors which can be used in biotechnological and biomedical applications. Furthermore, liposomes loading enzymes are being used as model to mimic cellular and subcellular organel behaviour. This work deals with the study of the kinetic behaviour of carbonic anhydrase (CA) entrapped in lipid vesicle. CA is nearly ubiquitous, being present in many tissues of different species, in cells, subcellular particles and membranes. The carbonic anhydrase entrapment in liposomes, as a function of the lipid cocktail used, was studied preliminarily. Then kinetics of carbon dioxide hydration reaction, catalysed by CA entrapped in liposomes, has been studied.     

Flow cytometric analysis of steroidogenic organelles in differentiating granulosa cells.

Functional and structural changes accompany the differentiation of granulosa cells during follicular development. We used flow cytometry and fluorescent dyes to characterize two organelles important to the steroidogenic process. Mitochondria, which contain the rate-limiting enzyme responsible for cholesterol conversion to pregnenolone, and lipid droplets, which store cholesterol substrate, were probed in viable hen granulosa cells during differentiation. The fluorescent dye Dio3-C5 (DiO) was used to probe mitochondrial membrane potential, indicative of mitochondrial activity and/or number, during rapid granulosa cell differentiation in a hierarchy of individual developing hen preovulatory follicles (F6, smallest, to F1, largest). Cellular DiO fluorescence, granularity, and cell size were significantly elevated with increasing maturation state. Treatment with LH significantly increased DiO fluorescence in granulosa cells from F1 but not F3. The increased mitochondrial activity/number in granulosa cells that accompanies follicular maturation and is influenced by LH may reflect, at least in part, increased activity or amount of hormone-regulated mitochondrial enzymes controlling steroidogenesis. Flow spectrofluorometry and the metachromatic lipid dye, nile red, were used to probe lipid droplets in differentiating granulosa cells from F6 to F1. There was a dramatic increase in the fluorescence component related to lipid droplets with increasing stages of follicular maturation, suggesting recruitment of lipids into droplets during the differentiation of granulosa cells into hormone-responsive steroidogenic cells. The results demonstrate the dynamic nature of the granulosa cell morphology involved in steroidogenesis during follicular development.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential remodeling of the lipidome during cold acclimation in natural accessions of Arabidopsis thaliana

Freezing injury is a major factor limiting the geographical distribution of plant species and the growth and yield of crop plants. Plants from temperate climates are able to increase their freezing tolerance during exposure to low but non‐freezing temperatures in a process termed cold acclimation. Damage to cellular membranes is the major cause of freezing injury in plants, and membrane lipid composition is strongly modified during cold acclimation. Forward and reverse genetic approaches have been used to probe the role of specific lipid‐modifying enzymes in the freezing tolerance of plants. In the present paper we describe an alternative ecological genomics approach that relies on the natural genetic variation within a species. Arabidopsis thaliana has a wide geographical range throughout the Northern Hemisphere with significant natural variation in freezing tolerance that was used for a comparative analysis of the lipidomes of 15 Arabidopsis accessions using ultra‐performance liquid chromatography coupled to Fourier‐transform mass spectrometry, allowing the detection of 180 lipid species. After 14 days of cold acclimation at 4°C the plants from most accessions had accumulated massive amounts of storage lipids, with most of the changes in long‐chain unsaturated triacylglycerides, while the total amount of membrane lipids was only slightly changed. Nevertheless, major changes in the relative amounts of different membrane lipids were also evident. The relative abundance of several lipid species was highly correlated with the freezing tolerance of the accessions, allowing the identification of possible marker lipids for plant freezing tolerance.