Lipid Composition of Pea and Bean Leaves during Chloroplast Development

The changes in composition of the complex lipids were followed during the greening of dark-grown pea (Pisum sativum) and bean (Phaseolus vulgaris) seedlings. No significant changes in glycerolipid concentrations in the leaves were observed during the early stages of greening (0-8 hour for peas and 0-12 hour for beans). On further greening, there was an increase in the proportion of galactolipids and a decrease in the phospholipids. The fatty acid composition of the galactolipids remained constant during 24 hours of greening, but there was a slight increase in α-linolenic acid at 72 hours in the bean. The percentage of α-linolenic acid in the phospholipids and in sulfolipid showed a marked increase between 24 and 72 hours in the bean. Trans-δ³-hexadecenoic acid was the major fatty acid of phosphatidyl glycerol in bean leaves at 72 hours, but it was barely detectable at 24 hours. The lipid composition of greening leaves is discussed in relation to the fine structure and photochemical activity of the developing plastids.     

Alterations of the chlorophyll-protein pattern in chronically photoinhibited Chenopodium rubrum cells

When photoautotrophic Chenopodium rubrum L. culture cells were exposed to high photon flux densities for seven consecutive light periods a marked reduction in photochemical efficiency, chlorophyll (Chl) content and Chl a/b ratio occurred. These alterations were accompanied by distinct changes in the pigment and protein composition of the thylakoid membranes. In photosystem II (PSII) a reduction in the relative contents of proteins from the reaction center (D1 protein, D2 protein and Cyt b₅₅₉) and the inner antenna (CP43 and CP47) was observed. In agreement with the reduction in the Chl a/b ratio an increase in the relative content of the major light-harvesting complex of PSII (LHCII) could be demonstrated. The minor chlorophyll-proteins of PSII were only slightly affected but PSI (quantified as total complex) showed a reduction upon chronic photoinhibition. The changes in protein composition were accompanied by a drastic increase in the contents of lutein and the xanthophyll-cycle pigments and by a reduction in the β-carotene content. The effects on lutein and xanthophyll-cycle pigment content were most pronounced in stroma thylakoids. Here, an increase in LHCII (which harbours these pigments) was clearly detectable. Considering the pigment content of LHCII, the change in its apoprotein content was not large enough to explain the pigment changes.     

Diversity and Seasonal Changes of Uncultured Planctomycetales in River Biofilms

Cell counts of planctomycetes showed that there were high levels of these organisms in the summer and low levels in the winter in biofilms grown in situ in two polluted rivers, the Elbe River and the Spittelwasser River. In this study 16S rRNA-based methods were used to investigate if these changes were correlated with changes in the species composition. Planctomycete-specific clone libraries of the 16S rRNA genes found in both rivers showed that there were seven clusters, which were distantly related to the genera Pirellula, Planctomyces, and Gemmata. The majority of the sequences from the Spittelwasser River were affiliated with a cluster related to Pirellula, while the majority of the clones from the Elbe River fell into three clusters related to Planctomyces and one deeply branching cluster related to Pirellula. Some clusters also contained sequences derived from freshwater environments worldwide, and the similarities to our biofilm clones were as high as 99.8%, indicating the presence of globally distributed freshwater clusters of planctomycetes that have not been cultivated yet. Community fingerprints of planctomycete 16S rRNA genes were generated by temperature gradient gel electrophoresis from Elbe River biofilm samples collected monthly for 1 year. Sixteen bands were identified, and for the most part these bands represented organisms related to the genus Planctomyces. The fingerprints showed that there was strong seasonality of most bands and that there were clear differences in the summer and the winter. Thus, seasonal changes in the abundance of Planctomycetales in river biofilms were coupled to shifts in the community composition.     

Bilayer undulation dynamics in unilamellar phospholipid vesicles: Effect of temperature,cholesterol and trehalose

We report a combined dynamic light scattering (DLS) and neutron spin-echo (NSE) study on the local bilayer undulation dynamics of phospholipid vesicles composed of 1,2-dimyristoyl-glycero-3-phosphatidylcholine (DMPC) under the influence of temperature and the additives cholesterol and trehalose. The additives affect vesicle size and self-diffusion. Mechanical properties of the membrane and corresponding bilayer undulations are tuned by changing lipid headgroup or acyl chain properties through temperature or composition. On the local length scale, changes at the lipid headgroup influence the bilayer bending rigidity κ less than changes at the lipid acyl chain: We observe a bilayer softening around the main phase transition temperature T_m of the single lipid system, and stiffening when more cholesterol is added, in concordance with literature. Surprisingly, no effect on the mechanical properties of the vesicles is observed upon the addition of trehalose.     

Aging-dependent modification of lipid composition and lipid structural order parameter of hepatic mitochondria

The effect of aging on the lipid composition of hepatic mitochondria has been determined using a rigorously defined group of Fischer 344 rats with known survivorship data. The age groups studied included mature adults as controls (8.5-month, 100% survivorship); an intermediate aged group (17.5-month, 90% survivorship); and an aged group (29-month, 20% survivorship). Lipid extracts of mitochondria were prepared using chloroform-methanol (2:1, by volume) and total phospholipid-P_i, cholesterol (free and esterfied), and phospholipid composition were determined. In the aged animals, total phospholipid-P_i decreased significantly (P = 0.019) whereas cholesterol increased (P = 0.048) with a progressive aging-dependent increase in the molar ratio of cholesterol/phospholipid. The lower total phospholipid content of hepatic mitochondria from the aged 29-month animals was due primarily to decreases in the major phospholipids with the most notable decrease being in cardiolipin (approximately 39%). Steady-state fluorescence polarization using 1,6-diphenyl-1,3,5-hexatriene as the probe was used to estimate the lipid structural order parameter of hepatic mitochondria. There was a highly significant (P = 0.01) aging-dependent increase in the lipid structural order parameter which correlated well with the increased molar ratio of cholesterol/phospholipid in the hepatic mitochondria isolated from the aged animals. The data suggest alterations in mitochondrial membrane lipid-protein interactions in aging and are consistent with the hypothesis of impairment of membrane function in the aging process.     

Compromising human skin in vivo and ex vivo to study skin barrier repair

Ex vivo regenerated stratum corneum (SC) after tape-stripping can be used as a model to study the barrier function of compromised skin. Yet, details about how close the regenerated SC model mimics the lipid properties (e.g. lipid composition and lipid ordering) of the in vivo situation are not known. Here, we examined using a comprehensive ceramide analysis whether human ex vivo regenerated SC showed similar lipid properties as human in vivo regenerated SC. Both in vivo and ex vivo regenerated SC had an altered ceramide subclass composition, with increased percentages of sphingosine-based subclass and decreased percentages of phytosphingosine-based subclass ceramides, a reduced mean ceramide chain length, and a higher percentage of unsaturated ceramides. Overall, regenerated SC ex vivo showed more pronounced but similar changes compared to the in vivo response. One of the purposes of these models is to use them to mimic compromised skin of inflammatory skin diseases. The altered lipid properties in regenerated SC were comparable to those observed in several inflammatory skin diseases, which makes them a valuable model for the barrier properties in inflammatory skin diseases.     

Patterns of variation in the lipid class and fatty acid composition of Nannochloropsis oculata (Eustigmatophyceae) during batch culture

Changes in the lipid and fatty acyl compositions of the marine microalga Nannochloropsis oculata Droop were examined during a batch culture growth cycle. During the early phase of batch culture the cellular proportion of triacylglycerols (TAG) increased. This was in addition to the increases in TAG observed in many microalgal species in the stationary-phase. Concomitant increases in the relative proportions of both saturated and monounsaturated fatty acids and decreases in the proportion of polyunsaturated fatty acids in total lipid were also associated with this phase. The separated individual lipid classes were found to have characteristic fatty acyl compositions. The relative proportion of lipid per cell, the relative proportions of the individual lipid classes and the fatty acyl compositions of the individual classes were all subject to variability during the growth cycle. The changing total lipid fatty acyl composition of N. oculata was found to be determined by the proportion of the total lipid present as TAG. The data suggest that the changes observed in the fatty acyl composition of N. oculata are a result of the partitioning of photosynthetically fixed carbon between polar and neutral lipid class biosynthesis and fatty acyl desaturation and elongation pathways. The effect of such a partitioning of carbon is discussed in relation to the effects of environmental variables and growth phase upon the balance of lipid class and polyunsaturated fatty acids (PUFA) synthesis in marine microalgae.     

Changes in plasma membrane lipids, aquaporins and proton pump of broccoli roots, as an adaptation mechanism to salinity

Salinity stress is known to modify the plasma membrane lipid and protein composition of plant cells. In this work, we determined the effects of salt stress on the lipid composition of broccoli root plasma membrane vesicles and investigated how these changes could affect water transport via aquaporins. Brassica oleracea L. var. Italica plants treated with different levels of NaCl (0, 40 or 80 mM) showed significant differences in sterol and fatty acid levels. Salinity increased linoleic (18:2) and linolenic (18:3) acids and stigmasterol, but decreased palmitoleic (16:1) and oleic (18:1) acids and sitosterol. Also, the unsaturation index increased with salinity. Salinity increased the expression of aquaporins of the PIP1 and PIP2 subfamilies and the activity of the plasma membrane H⁺-ATPase. However, there was no effect of NaCl on water permeability (P_f) values of root plasma membrane vesicles, as determined by stopped-flow light scattering. The counteracting changes in lipid composition and aquaporin expression observed in NaCl-treated plants could allow to maintain the membrane permeability to water and a higher H⁺-ATPase activity, thereby helping to reduce partially the Na⁺ concentration in the cytoplasm of the cell while maintaining water uptake via cell-to-cell pathways. We propose that the modification of lipid composition could affect membrane stability and the abundance or activity of plasma membrane proteins such as aquaporins or H⁺-ATPase. This would provide a mechanism for controlling water permeability and for acclimation to salinity stress.     

Changes in the lipid composition of mussel (<Emphasis Type="Italic">Mytilus trossulus</Emphasis>) embryo cells during cryopreservation

The survival and the lipid composition of mussel (Mytilus trossulus) larval cells was analyzed before and after cryopreservation in two protective media. Cell survival and functional recovery were greatly improved when the conventional DMSO + trehalose were supplemented with a lipid extract from mature mollusks (Crenomytilus grayanus) + vitamins E and C. These additives also markedly influenced the fatty acid composition of the cells upon thawing, particularly as regards the share of monoenic acids and the unsaturation index. The probable causes of these effects are discussed.     

Relationship between Phospholipid Breakdown and Freezing Injury in a Cell Wall-Less Mutant of Chlamydomonas reinhardii

The effects of freezing and thawing on a cell wall-less mutant (CW15+) of Chlamydomonas reinhardii were investigated by monitoring enzyme release, cell viability, cell ultrastructure, and lipid composition. Cells suspended in Euglena gracilis medium were extremely susceptible to freezing injury, the median lethal temperature in the presence of extracellular ice being −5.3°C. Cell damage was associated with a release of intracellular enzymes and massive breakdown of cellular organization. Changes in phospholipid fatty acid composition consistent with either a peroxidation process or phospholipase A₂ activity were evident, but the time course of these changes showed clearly that alterations in phospholipid fatty acid composition were a secondary, pathological event and not the the primary cause of freeze-thaw injury in Chlamydomonas reinhardii CW15+.     

An Assessment of Growth Media Enrichment on Lipid Metabolome and the Concurrent Phenotypic Properties of Candida albicans

A critical question among the researchers working on fungal lipid biology is whether the use of an enriched growth medium can affect the lipid composition of a cell and, therefore, contribute to the observed phenotypes. One presumption is that enriched medias, such as YPD (yeast extract, peptone and dextrose), are likely to contain lipids, which may homogenize with the yeast lipids and play a role in masking the actual differences in the observed phenotypes or lead to an altered phenotype altogether. To address this issue, we compared the lipids of Candida albicans, our fungus of interest, grown in YPD or in a defined media such as YNB (yeast nitrogen base). Mass spectrometry-based lipid analyses showed differences in the levels of phospholipids, including phosphatidylinositol, phosphatidylglycerol, lyso-phospholipids; sphingolipids, such as mannosyldiinositolphosphorylceramide; and sterols, such as ergostatetraenol. Significant differences were observed in 70 lipid species between the cells grown in the two media, but the two growth conditions did not affect the morphological characteristics of C. albicans. The lipid profiles of the YNB- and YPD-grown C. albicans cells did vary, but these differences did not influence their response to the majority of the tested agents. Rather, the observed differences could be attributed to the slow growth rate of the Candida cells in YNB compared to YPD. Notably, the altered lipid changes between the two media did impact the susceptibility to some drugs. This data provided evidence that changes in media can lead to certain lipid alterations, which may affect specific pathways but, in general, do not affect the majority of the phenotypic properties of C. albicans. It was determined that either YNB or YPD may be suitable for the growth and lipid analysis of C. albicans, depending upon the experimental requirements, but additional precautions are necessary when correlating the phenotypes with the lipids.     

Influence of growth medium on surface and wall lipid of fungal spores

Conidiospores of Alternaria tenuis, Botrytis fabae, Neurospora crassa and sporangiospores of Rhizopus stolonifer from cultures on various media were shown by microelectrophoresis to have lipid on their surface. Analyses of lipid fractions obtained by sequential solvent extraction demonstrated that surface lipid forms a small but discrete layer different in composition from that within the wall. Free fatty acids, alkanes, triglycerides and other acyl lipids were identified by GC-MS. Phospholipids and sterols were absent. The qualitative and quantitative composition of both the surface and wall lipid fractions was dependent upon the growth medium used.     

Lipid and protein composition and thermotropic lipid phase transitions in fatty acid-homogeneous membranes of Acholeplasma laidlawii B

The membrane composition and lipid physical properties have been systematically investigated as a function of fatty acid composition for a series of Acholeplasma laidlawii B membrane preparations made homogeneous in various fatty acids by growing cells on single fatty acids and avidin, a potent fatty acid synthetic inhibitor. The membrane protein molecular weight distribution is essentially constant as a function of fatty acid composition, but the lipid/protein ratio varies over a 2-fold range when different fatty acid growth supplements are used. The membrane lipid head-group composition varies somewhat under these conditions, particularly in the ratio of the two major neutral glycolipids. Differential thermal analytical investigations of the thermotropic phase transitions of various combinations of membrane components suggest that these compositional changes are unlikely to result in qualitative changes in the nature of lipid-protein or lipid-lipid interactions, although lesser changes of a quantitative nature probably do occur. The total lipids of membranes made homogeneous in their lipid fatty acyl chain composition exhibit sharper than normal gel-to-liquid-crystalline phase transitions of which midpoint temperatures correlate very well with the phase transition temperatures of synthetic hydrated phosphatidylcholines with like acyl chains. Our results indicate that using avidin and suitable fatty acids to grow A. laidlawii B, it is possible to manipulate the position and the sharpness of the membrane lipid phase transition widely and independently without causing major modifications in other aspects of the membrane composition. This fact makes the fatty acid-homogeneous A. laidlawii B membrane a very useful biological membrane preparation in which to study lipid physical properties and their functional consequences.     

Comparison of the Lipid Composition of Oat Root and Coleoptile Plasma Membranes : Lack of Short-Term Change in Response to Auxin

The total lipid composition of plasma membranes (PM), isolated by the phase partitioning method from two different oat (Avena sativa L.) tissues, the root and coleoptile, was compared. In general, the PM lipid composition was not conserved between these two organs of the oat seedling. Oat roots contained 50 mole percent phospholipid, 25 mole percent glycolipid, and 25 mole percent free sterol, whereas comparable amounts in the coleoptile were 42, 39, and 19 mole percent, respectively. Individual lipid components within each lipid class also showed large variations between the two tissues. Maximum specific ATPase activity in the root PM was more than double the activity in the coleoptile. Treatment of coleoptile with auxin for 1 hour resulted in no detectable changes in PM lipids or extractable ATPase activity. Differences in the PM lipid composition between the two tissues that may define the limits of ATPase activity are discussed.     

Changes in Bacterioplankton Composition under Different Phytoplankton Regimens

The results of empirical studies have revealed links between phytoplankton and bacterioplankton, such as the frequent correlation between chlorophyll a and bulk bacterial abundance and production. Nevertheless, little is known about possible links at the level of specific taxonomic groups. To investigate this issue, seawater microcosm experiments were performed in the northwestern Mediterranean Sea. Turbulence was used as a noninvasive means to induce phytoplankton blooms dominated by different algae. Microcosms exposed to turbulence became dominated by diatoms, while small phytoflagellates gained importance under still conditions. Denaturing gradient gel electrophoresis (DGGE) of 16S rRNA gene fragments showed that changes in phytoplankton community composition were followed by shifts in bacterioplankton community composition, both as changes in the presence or absence of distinct bacterial phylotypes and as differences in the relative abundance of ubiquitous phylotypes. Sequencing of DGGE bands showed that four Roseobacter phylotypes were present in all microcosms. The microcosms with a higher proportion of phytoflagellates were characterized by four phylotypes of the Bacteroidetes phylum: two affiliated with the family Cryomorphaceae and two with the family Flavobacteriaceae. Two other Flavobacteriaceae phylotypes were characteristic of the diatom-dominated microcosms, together with one Alphaproteobacteria phylotype (Roseobacter) and one Gammaproteobacteria phylotype (Methylophaga). Phylogenetic analyses of published Bacteroidetes 16S rRNA gene sequences confirmed that members of the Flavobacteriaceae are remarkably responsive to phytoplankton blooms, indicating these bacteria could be particularly important in the processing of organic matter during such events. Our data suggest that quantitative and qualitative differences in phytoplankton species composition may lead to pronounced differences in bacterioplankton species composition.     

Nitrogen-Deprivation Elevates Lipid Levels in Symbiodinium spp. by Lipid Droplet Accumulation: Morphological and Compositional Analyses

Stable cnidarian-dinoflagellate (genus Symbiodinium) endosymbioses depend on the regulation of nutrient transport between Symbiodinium populations and their hosts. It has been previously shown that the host cytosol is a nitrogen-deficient environment for the intracellular Symbiodinium and may act to limit growth rates of symbionts during the symbiotic association. This study aimed to investigate the cell proliferation, as well as ultrastructural and lipid compositional changes, in free-living Symbiodinium spp. (clade B) upon nitrogen (N)-deprivation. The cell proliferation of the N-deprived cells decreased significantly. Furthermore, staining with a fluorescent probe, boron dipyrromethane 493/503 (BODIPY 493/503), indicated that lipid contents progressively accumulated in the N-deprived cells. Lipid analyses further showed that both triacylglycerol (TAG) and cholesterol ester (CE) were drastically enriched, with polyunsaturated fatty acids (PUFA; i.e., docosahexaenoic acid, heneicosapentaenoic acid, and oleic acid) became more abundant. Ultrastructural examinations showed that the increase in concentration of these lipid species was due to the accumulation of lipid droplets (LDs), a cellular feature that have previously shown to be pivotal in the maintenance of intact endosymbioses. Integrity of these stable LDs was maintained via electronegative repulsion and steric hindrance possibly provided by their surface proteins. Proteomic analyses of these LDs identified proteins putatively involved in lipid metabolism, signaling, stress response and energy metabolism. These results suggest that LDs production may be an adaptive response that enables Symbiodinium to maintain sufficient cellular energy stores for survival under the N-deprived conditions in the host cytoplasm.     

DHA-fluorescent probe is sensitive to membrane order and reveals molecular adaptation of DHA in ordered lipid microdomains

Docosahexaenoic acid (DHA) disrupts the size and order of plasma membrane lipid microdomains in vitro and in vivo. However, it is unknown how the highly disordered structure of DHA mechanistically adapts to increase the order of tightly packed lipid microdomains. Therefore, we studied a novel DHA-Bodipy fluorescent probe to address this issue. We first determined if the DHA-Bodipy probe localized to the plasma membrane of primary B and immortal EL4 cells. Image analysis revealed that DHA-Bodipy localized into the plasma membrane of primary B cells more efficiently than EL4 cells. We then determined if the probe detected changes in plasma membrane order. Quantitative analysis of time-lapse movies established that DHA-Bodipy was sensitive to membrane molecular order. This allowed us to investigate how DHA-Bodipy physically adapted to ordered lipid microdomains. To accomplish this, we employed steady-state and time-resolved fluorescence anisotropy measurements in lipid vesicles of varying composition. Similar to cell culture studies, the probe was highly sensitive to membrane order in lipid vesicles. Moreover, these experiments revealed, relative to controls, that upon incorporation into highly ordered microdomains, DHA-Bodipy underwent an increase in its fluorescence lifetime and molecular order. In addition, the probe displayed a significant reduction in its rotational diffusion compared to controls. Altogether, DHA-Bodipy was highly sensitive to membrane order and revealed for the first time that DHA, despite its flexibility, could become ordered with less rotational motion inside ordered lipid microdomains. Mechanistically, this explains how DHA acyl chains can increase order upon formation of lipid microdomains in vivo.     

Increased susceptibility of algal symbionts to photo-inhibition resulting from the perturbation of coral gastrodermal membrane trafficking

The stability of cnidarian-dinoflagellate endosymbioses is dependent upon communication between the host gastrodermal cell and the symbionts housed within it. Although the molecular mechanisms remain to be elucidated, existing evidence suggests that the establishment of these endosymbioses may involve the sorting of membrane proteins. The present study examined the role of host gastrodermal membranes in regulating symbiont (genus Symbiodinium) photosynthesis in the stony coral Euphyllia glabrescens. In comparison with the photosynthetic behavior of Symbiodinium in culture, the Symbiodinium populations within isolated symbiotic gastrodermal cells (SGCs) exhibited a significant degree of photo-inhibition, as determined by a decrease in the photochemical efficiency of photosystem II (F _v/F _m). This photo-inhibition coincided with increases in plasma membrane perturbation and oxidative activity in the SGCs. Membrane trafficking in SGCs was examined using the metabolism of a fluorescent lipid analog, N-[5-(5,7-dimethyl boron dipyrromethene difluoride)-1-pentanoyl]-D-erythro-Sphingosylphosphoryl-choline (BODIPY-Sphingomyelin or BODIPY-SM). Light irradiation altered both membrane distribution and trafficking of BODIPY-SM, resulting in metabolic changes. Cholesterol depletion of the SGC plasma membranes by methyl-??-cyclodextrin retarded BODIPY-SM degradation and further augmented Symbiodinium photo-inhibition. These results indicate that Symbiodinium photo-inhibition may be related to perturbation of the host gastrodermal membrane, providing evidence for the pivotal role of host membrane trafficking in the regulation of this environmentally important coral-dinoflagellate endosymbiosis.     

The quenching effect of blue light on halorhodopsin

A mutant of Halobacterium halobium which contains halorhodopsin was isolated from strain S₉. An absorbance change at 380 nm caused by steady orange light illumination (λ ?530 nm) was observed. This change depended upon the intensity of the actinic light. The bleached envelope vesicles and vesicles derived from nicotine-grown cells showed a small or no absorbance change at 380 nm, suggesting that the change stemmed from the photochemical intermediate of halorhodopsin (referred to as P-380). When blue light was superimposed on orange background illumination, the membrane potential (Δψ) of the envelope vesicles decreased. Δψ was determined from the tetraphenylphosphonium cation (TPP⁺) distribution by means of a TPP⁺ electrode. When blue light intensity was increased, both Δψ and the amount of P-380 were decreased. An equation was derived which showed that Δψ is proportional to the concentration of P-380 formed by illumination under the assumption that the ionic composition is not significantly changed upon illumination. This equation was checked experimentally from the following three points: The blue light effect, the relationship between Δψ and light intensity, and the effect of gramicidin. The data obtained accorded well with the theoretical relationship.     

Estimation of the content of lipids composing endothelial lipid droplets based on Raman imaging

Lipid droplets (LDs) are dynamic organelles involved in intracellular lipid metabolism, and the biogenesis of LDs in endothelium is triggered by the excess of lipids in the environment. In this paper we present the methodology aimed to define the composition of endothelial LDs formed upon stimulation with oleic acid (OA) in two models: endothelial cells cultured in vitro and in isolated blood vessel ex vivo. The biochemical composition of LDs was determined using Raman imaging, followed by the lipid unsaturation calibration analysis and modelling of spectral bands based on individual spectra of selected lipids. Among LDs formed in response to OA in vitro or ex vivo conditions there were two types of LDs; those with more unsaturated (average number of CC bonds equalled 1.40) or saturated (average number of CC bonds equalled 0.95) lipids. The modelling of endothelial LDs composition revealed the OA represented a major component of LDs (80.6–91.3%) with an important content of arachidonic acid (8.7–19.4%). In conclusion, endothelial LDs consist of exogenous oleic acid uptaken from the extracellular space, and the endogenous arachidonic acid released from plasma membranes.