Polyunsaturated fats,membrane lipids and animal longevity

Fatty acids are essential for life because they are essential components of cellular membranes. Lower animals can synthesize all four classes of fatty acids from non-lipid sources, but both omega-6 and omega-3 cannot be synthesized de novo by ‘higher’ animals and are therefore essential components of their diet. The relationship between normal variation in diet fatty acid composition and membrane fatty acid composition is little investigated. Studies in the rat show that, with respect to the general classes of fatty acids (saturated, monounsaturated and polyunsaturated) membrane fatty acid composition is homeostatically regulated despite diet variation. This is not the case for fatty acid composition of storage lipids, which responds to diet variation. Polyunsaturated fatty acids are important determinants of physical and chemical properties of membranes. They are the substrates for lipid peroxidation and it is possible to calculate a peroxidation index (PI) for a particular membrane composition. Membrane PI appears to be homeostatically regulated with respect to diet PI. Membrane fatty acid composition varies among species and membrane PI is inversely correlated to longevity in mammals, birds, bivalve molluscs, honeybees and the nematode Caenorhabditis elegans.     

Islet transplantation in experimental diabetes of the rat. XII. Effect on diabetic retinopathy. Morphological findings and morphometrical evaluation

Digest-preparations of rat retinal vasculature were examined with respect to single capillary alterations and diffuse changes in cellular composition. Retinas of streptozotocin-diabetic rats revealed single micro-aneurysms, degenerated capillaries, strand formation, microthromboses and further lesions, occurring sooner than previously described. A severe loss of pericytes and a slight increase in endothelial cell number resulting in an increase in E/P-ratio were observed, all effects becoming more pronounced with longer duration of diabetes. Syngeneic islet transplantation could prevent all of the described alterations if carried out soon after diabetes induction. If performed six months later it was able to almost restore the normal cellular composition while pathomorphological lesions could be arrested or reversed only partially.     

Role of membrane lipids and membrane fluidity in thermosensitivity and thermotolerance of mammalian cells

The role of membrane lipids and membrane fluidity in thermosensitivity of mammalian cells is not well understood. The limited experimental data in the literature have led to conflicting results. A detailed investigation of lipid composition and membrane fluidity of cellular membranes was undertaken to determine their relationship to cell survival after hyperthermia. Ehrlich ascites (EA) cells, mouse fibroblast LM cells, and HeLa S3 cells differed in thermosensitivity as expressed by a D0 of 3.1, 5.2, and 9.7 min, respectively, at 44 degrees C. No correlation with cellular thermosensitivity could be found with respect to the amount of cholesterol and to the cholesterol to phospholipid ratio in the particulate fraction of the cells. By growing the cells for some generations in different media, cholesterol and phospholipid content could be changed in the particulate fraction, but no difference in cell survival was observed. When mouse fibroblasts were grown for 24 hr in a serum-free medium supplemented with arachidonic acid (20:4), all subcellular membranes were about eight times richer in phospholipids containing polyunsaturated acyl (PUFA) chains and membrane fluidity was increased as measured by fluorescence polarization of diphenylhexatriene (DPH). The alterations resulted in a higher thermosensitivity. When mouse fibroblasts were made thermotolerant no change in cholesterol and phospholipid content could be found in the particulate fraction of the cells. The relative weights and the quality of the phospholipids as well as the fatty acid composition of the phospholipids appeared to be the same for normal and thermotolerant cells. Fluidity measurements in whole cells, isolated plasma membranes, and liposomes prepared from phospholipids extracted from the cells revealed no significant differences between normal and thermotolerant fibroblasts when assayed by fluorescence polarization (DPH) and electron spin resonance (5-nitroxystearate). It is concluded that the mechanism of thermal adaptation resulting in differences in lipid composition as reported in the literature differs from the mechanism of the acquisition of thermal tolerance. The lower heat sensitivity of thermotolerant cells, as initiated by a nonlethal triggering heat dose followed by an induction period at 37 degrees C, does not involve changes in lipid composition and membrane fluidity. However, a prompt and clear (also nonlethal) change in membrane fluidity by an increase in PUFA does result in an increased thermosensitivity, probably because of an indirect effect via the lipids in causing disfunctioning of proteins in the membrane and/or the cytoskeleton.     

Motion of spin-labeled fatty acids in murine macrophages. Relation to cellular phagocytic activity.

Macrophage membrane fluidity was investigated with respect to cellular phagocytic activity through the use of fatty acid spin labels. Spin-labeled fatty acid derivatives were incorporated into intact mouse peritoneal macrophages by exchange from bovine serum albumin. The electron spin resonance (ESR) spectra of the spin-labeled fatty acids in the macrophages showed a pronounced temperature dependence and a decrease in the hyperfine splittings (2 T11) of the spectra as the nitroxide radical was moved away from the polar head group of the fatty acid derivatives. Spin-labeled macrophages underwent a time- and temperature-dependent decay, which was inhibited by preincubating the cells with mercuric chloride, heating at 56 degrees C, or by fixing them with 0.25% glutaraldehyde. No correlation between the phagocytic activity of macrophages and membrane freedom of motion could be demonstrated. Treatment of macrophages with anti-macrophage serum or extended in vitro cultivation inhibited cellular phagocytic activity but exerted no effect on the motional freedom of the macrophage membrane. Enrichment of the fatty acid composition of the macrophage membrane with cis- or trans-unsaturated fatty acids had striking effects on cellular phagocytic activity, while no significant changes could be detected in the freedom of motion of incorporated fatty acid spin labels at the degree of specific enrichment achieved here. Thus no correlation between cellular phagocytic activity and lipid motion could be detected.     

Radiosensitivity of normal and polyunsaturated fatty acid supplemented fibroblasts after depletion of glutathione

Mouse fibroblast LM cells have been modified with respect to their phospholipid composition in all subcellular fractions, including the nuclear membrane. The content of polyunsaturated fatty acids (PUFA) was significantly increased but no difference in cell survival after X-irradiation could be observed between the normal and PUFA enriched cells. It is concluded that the radiosensitive PUFAs in the membranes are well protected against radiation damage. This protection of the PUFA cells could not be caused by vitamin E, because this membrane protector was not present in these fibroblasts. The content of glutathione (GSH) was about the same in the normal and the modified cells. Reduction of the cellular GSH content to less than 5 per cent of that for non-treated cells did not alter cellular survival after radiation of either normal or PUFA enriched cells under oxic or anoxic conditions. The radiosensitive lipids present in the membranes of the PUFA enriched cells proved to be vulnerable to radiation-induced lipid peroxidation when extracted from the cells and reconstituted into liposomes, indicating that the fatty acids per se are peroxidizable. It is concluded that the lipids in the membranes of mammalian cells are not the principal target in radiation-induced reproductive death, and that no generalization is permitted with respect to glutathione, as being the major hydrogen donating species in mammalian cells responsible for the repair of those target molecules responsible for cell survival after radiation.     

Effect of docosahexaenoic acid on membrane fluidity and function in intact cultured Y-79 retinoblastoma cells.

Considerable metabolic energy is expended in ensuring that membranes possess a characteristic fatty acid composition. The nature of the specific requirement of the retina for high levels of docosahexaenoic acid (DHA) is as yet undefined. Previous work has speculated that DHA is required to maintain the fluid nature and permeability necessary for optimal retinal function. Cultured Y-79 retinoblastoma cells were grown in serum-containing media with and without supplemental DHA. Resultant changes in membrane fluidity were assessed using fluorescent probes. No differences were observed in rotational probe mobility as assessed by fluorescence polarization despite a fourfold increase in cellular DHA content. Lateral probe mobility as assessed by pyrene eximer formation was significantly enhanced in DHA-supplemented cells. Both the DHA content and total fatty acid unsaturation index in retinoblastoma cells were directly correlated with membrane fluidity as reported by eximer formation (Pearson's rho = 0.96 and 0.92, respectively). DHA supplementation also resulted in a significant increase in cellular choline uptake. We speculate that the effect of DHA content on retinal function may be mediated by changes in membrane fluidity and associated enzyme and transport activities.     

Cell volume regulation in the nervous system

There is good evidence that the three main compartments of the brain, i.e. extracellular space, neurones and glial cells, change their volume during physiological and pathophysiological neuronal activity. However, there is strikingly little knowledge about the mechanisms underlying such alterations in cell volume. For this purpose, a better understanding of the electrophysiological behavior of the neurones and glial cells during volume changes is necessary. Examples are discussed for which changes in cell volume can be derived from the underlying changes in membrane permeabilities. Volume regulatory mechanisms in the brain have not been described under isotonic conditions. However, a rapid volume regulatory decrease is occurring in cultured glial cells during exposure to hypotonic solutions. In contrast, in these cells no volume regulatory increase was found during superfusion with hypertonic media. On the other hand, the entire brain is able to compensate chronic hypertonic perturbations within hours to days. Interestingly, not only ion fluxes induce cellular volume changes but, in turn, water movements can also influence ion fluxes in both neurones and glial cells. With respect to this it should be considered that volume regulatory membrane processes might not exclusively be activated by changes in transmembranal ion gradient, but also by changes of membrane surface shape. Future studies on cellular mechanisms of volume regulation in the brain should imply a combined use of recent techniques such as computerized video-imaging, radiotracer flux measurements and ion-sensitive microelectrodes in defined cell cultures. Optical monitoring and ion-sensitive microelectrodes should enable measurements of volume changes in identified cellular elements of intact nervous structures such as brain slices.     

Adaptive changes of chloroplast membrane lipid components under environmental factors

Review deals with some modern views of the membrane chloroplast lipid composition role in low-, high temperature and water stress adaptive reactions. It is shown that the transformed changes in membrane lipid composition determined the biochemical adaptive process due homeostasis support and preservation of the lipid bilayer fluidity, being necessary for their normal functioning in the changed environmental conditions. The aspects of long-term and short-term adaptive reactions in protein/lipid membrane complexes is discussed. The lipid sensor functions at genetically regulation of adaptive mechanisms is considered.     

Altered body morphology is caused by increased stearate levels in a mutant of Arabidopsis

A mutant of Arabidopsis thaliana, fab2 , in which a profound developmental phenotype, miniature growth, is caused by an increase in the level of the membrane fatty acid, stearate has been characterized. Miniature growth in fab2 results from changes in cell expansion and maturation processes. Leaf anatomy of fab2 is characterized by cell-specific changes in expansion growth, by a lack of differentiation in the cells of the leaf blade, and by the absence of air spaces. Leaves of fab2 lack the basipetal gradient in cellular development which is ubiquitous in higher plants. These cellular changes occur without distorting the chronology of development, or destroying the biological integrity of the organism. A second site suppressor mutation, shs , substantially restores both normal fatty acid composition and normal body size, causally linking the two phenotypes. Growth of the fab2 mutant at high temperature substantially corrects the miniature phenotype without altering the fatty acid composition, suggesting a role for membrane structure in the production of the aberrant morphology.     

Yeast Integral Membrane Proteins Apq12, Brl1, and Brr6 Form a Complex Important for Regulation of Membrane Homeostasis and Nuclear Pore Complex Biogenesis

Proper functioning of intracellular membranes is critical for many cellular processes. A key feature of membranes is their ability to adapt to changes in environmental conditions by adjusting their composition so as to maintain constant biophysical properties, including fluidity and flexibility. Similar changes in the biophysical properties of membranes likely occur when intracellular processes, such as vesicle formation and fusion, require dramatic changes in membrane curvature. Similar modifications must also be made when nuclear pore complexes (NPCs) are constructed within the existing nuclear membrane, as occurs during interphase in all eukaryotes. Here we report on the role of the essential nuclear envelope/endoplasmic reticulum (NE/ER) protein Brl1 in regulating the membrane composition of the NE/ER. We show that Brl1 and two other proteins characterized previously—Brr6, which is closely related to Brl1, and Apq12—function together and are required for lipid homeostasis. All three transmembrane proteins are localized to the NE and can be coprecipitated. As has been shown for mutations affecting Brr6 and Apq12, mutations in Brl1 lead to defects in lipid metabolism, increased sensitivity to drugs that inhibit enzymes involved in lipid synthesis, and strong genetic interactions with mutations affecting lipid metabolism. Mutations affecting Brl1 or Brr6 or the absence of Apq12 leads to hyperfluid membranes, because mutant cells are hypersensitive to agents that increase membrane fluidity. We suggest that the defects in nuclear pore complex biogenesis and mRNA export seen in these mutants are consequences of defects in maintaining the biophysical properties of the NE.     

Erythrocyte membrane fluidity and changes in plasma lipid composition: a possible relationship in childhood obesity

We have studied plasma lipid patterns and erythrocyte membrane fluidity in 60 obese children and 20 normal children. Plasma levels of total cholesterol and associated low-density lipoproteins were significantly increased in 20 obese patients with respect to controls. A significant decrease in membrane fluidity, measured as an increase in the fluorescence polarization value of the probe 1,6-diphenyl-1,3,5-hexatriene, associated with an increase in the cholesterol/protein ratio has been shown in obese patients. The study of the correlation between erythrocyte membrane fluidity and plasma cholesterol has indicated that significant changes in fluidity and membrane lipid composition also occur in erythrocytes of obese patients with normal plasma lipid levels. These findings confirm that the erythrocyte membrane responds very early to modifications of plasma lipoproteins and suggest that in childhood obesity a modified transfer of cholesterol from plasma to erythrocyte membrane may take place.     

Transport changes associated with growth control and malignant transformation.

We can distinguish two classes of membrane transport changes in cultured cells: (a) growth-rate contingent changes are those which occur in coordination with the onset of density-dependent inhibition of growth; (b) transformation-specific changes are those which occur when cells become transformed, and which can be detected even when normal and transformed cells are growing at the same rate. Growth-rate contingent changes include the density-dependent changes in phosphate, nucleoside, glucose, amino acid, and potassium transport. Only one transformation-specific transport change has been found in Rous-transformed chicken embryo fibroblasts: an increased rate of hexose transport. The variation in potassium transport are associated with variations in the number of ouabain binding sites in the membrane. The molecular basis for changes in the rate of hexose transport is unknown, although gross changes in membrane bilayer composition and "fluidity" seem not to be involved. In analyzing the regulation of hexose transport activity, we find that decreased cAMP may play a role in the transformation-specific increase in hexose transport, but that fibrinolytic activity is not necessary.     

The effect of varying sea salt concentration in the growth medium on the chemical composition of a purified membrane fraction fromPlanococcus citreus Migula

Membrane preparations were prepared from cells ofPlanococcus citreus grown in the presence of three final concentrations of sea salt in a basic growth medium. The concentration of salt in the medium affects the amount of membrane in the cell. The three preparations were subjected to chemical analysis and no significant changes in chemical composition were seen as the salt concentration in the medium was increased. Values for the various components generally were within normal ranges and were similar to those of non-halophiles rather than extreme halophiles. The protein levels were slightly higher and it is suggested that this may be advantageous in selectively maintaining the correct cellular ion balance. Atomic absorption analysis of the major cations associated with the membranes showed that divalent ions were present in a 2:1 ratio with 1971; Oliver and Colwell, 1973; Stern and Tietz, 1973; Kushwaha et al., 1974; Lanyi, 1974). However, changes in the overall membrane composition in mild halophiles in response to various concentrations of salt have received little attention, even though it has been known for some time (Salton and Freer, 1965) that the composition of a growth medium may alter the chemical composition of a bacterial membrane. This investigation was undertaken to determine whether any gross changes in composition occurred in membranes isolated from cells ofPlanococcus citreus Migula when it is grown in a basic medium supplemented with various amounts of sea salt.     

Effects of membrane lipids on ion channel structure and function

Biologic membranes are not simply inert physical barriers, but complex and dynamic environments that affect membrane protein structure and function. Residing within these environments, ion channels control the flux of ions across the membrane through conformational changes that allow transient ion flux through a central pore. These conformational changes may be modulated by changes in transmembrane electrochemical potential, the binding of small ligands or other proteins, or changes in the local lipid environment. Ion channels play fundamental roles in cellular function and, in higher eukaryotes, are the primary means of intercellular signaling, especially between excitable cells such as neurons. The focus of this review is to examine how the composition of the bilayer affects ion channel structure and function. This is an important consideration because the bilayer composition varies greatly in different cell types and in different organellar membranes. Even within a membrane, the lipid composition differs between the inner and outer leaflets, and the composition within a given leaflet is both heterogeneous and highly dynamic. Differential packing of lipids (and proteins) leads to the formation of microdomains, and lateral diffusion of these microdomains or "lipid rafts" serve as mobile platforms for the clustering and organization of bilayer constituents including ion channels. The structure and function of these channels are sensitive to specific chemical interactions with neighboring components of the membrane and also to the biophysical properties of their membrane microenvironment (e.g., fluidity, lateral pressure profile, and bilayer thickness). As specific examples, we have focused on the K+ ion channels and the ligand-gated nicotinicoid receptors, two classes of ion channels that have been well-characterized structurally and functionally. The responsiveness of these ion channels to changes in the lipid environment illustrate how ion channels, and more generally, any membrane protein, may be regulated via cellular control of membrane composition.     

Changes in mitochondrial mass,membrane potential,and cellular adenosine triphosphate content during the cell cycle of human leukemic (HL-60) cells

Oxidative phosphorylation within the inner mitochondrial membrane generates the majority of cellular adenosine triphosphate (ATP) required for normal physiological functions (including regulation of cell volume and solute concentration, maintenance of cellular architecture, and synthesis of essential macromolecules). Its efficient functioning depends on the maintenance of an electrochemical gradient and is tightly coupled to the energetic demands of the cell and/or tissue. Commitment to and completion of the cell division cycle are sensitive to changes in the availability of mitochondrially derived ATP, although the relationship between cell cycle and mitochondrial physiology is poorly understood. Using vital, mitochondrial-specific fluorochromes to differentiate between mitochondrial mass (10-N-nonyl acridine orange) and mitochondrial membrane potential (Rhodamine123), together with a quantification of total cellular ATP levels, it was possible to generate profiles of these mitochondrial characteristics in HL-60 cells at different stages of their cell cycle. The data suggest that the availability of ATP changes in a cell cycle-specific manner and cannot be predicted by changes in mitochondrial mass or membrane potential. Furthermore, transition points in the cell cycle where ATP availability is low with respect to the amount of functional inner mitochondrial membrane have been observed. We suggest that these cell cycle phase transitions are sensitive to inhibition of mitochondrial activity because the basal levels of available ATP at these points are nearer to a theoretical “minimal threshold” below which cell cycle progression is inhibited. J. Cell. Physiol. 180:91–96, 1999. © 1999 Wiley-Liss, Inc.     

Adaptive Lipid Packing and Bioactivity in Membrane Domains

Lateral compositional and physicochemical heterogeneity is a ubiquitous feature of cellular membranes on various length scales, from molecular assemblies to micrometric domains. Segregated lipid domains of increased local order, referred to as rafts, are believed to be prominent features in eukaryotic plasma membranes; however, their exact nature (i.e. size, lifetime, composition, homogeneity) in live cells remains difficult to define. Here we present evidence that both synthetic and natural plasma membranes assume a wide range of lipid packing states with varying levels of molecular order. These states may be adapted and specifically tuned by cells during active cellular processes, as we show for stimulated insulin secretion. Most importantly, these states regulate both the partitioning of molecules between coexisting domains and the bioactivity of their constituent molecules, which we demonstrate for the ligand binding activity of the glycosphingolipid receptor GM1. These results confirm the complexity and flexibility of lipid-mediated membrane organization and reveal mechanisms by which this flexibility could be functionalized by cells.     

Nonspecific depolarization of the plasma membrane potential induces cytoskeletal modifications of bovine corneal endothelial cells in culture

Modifications in the cell membrane potential have been suggested to affect signaling mechanisms participating in diverse cellular processes, many of which involve structural cellular alterations. In order to contribute some evidence in this respect, we explored the effects of several depolarizing procedures on the structure and monolayer organization of bovine corneal endothelial cells in culture. Visually confluent cell monolayers were incubated with or without the depolarizing agent, either in a saline solution or in culture medium for up to 30 min. Membrane potential was monitored by fluorescence microscopy using oxonol V. Fluorescent probes were employed for F-actin, microtubules, and vinculin. Depolarization of the plasma membrane, achieved via the incorporation of gramicidin D into confluent endothelial cells or by modifications of the extracellular saline composition, provoked an increment of oxonol fluorescence and changes in cell morphology, consisting mainly of modifications in the cytoskeletal organization. In some areas, noticeable intercellular spaces appear. The cytoskeleton modifications mainly consist of a marked redistribution of F-actin and microtubules, with accompanying changes in vinculin localization. The results suggest that the depolarization of the plasma membrane potential may participate in mechanisms involved in cytoskeleton organization and monolayer continuity in corneal endothelial cells in culture.     

Deoxycholic acid modulates cell death signaling through changes in mitochondrial membrane properties

Cytotoxic bile acids, such as deoxycholic acid (DCA), are responsible for hepatocyte cell death during intrahepatic cholestasis. The mechanisms responsible for this effect are unclear, and recent studies conflict, pointing to either a modulation of plasma membrane structure or mitochondrial-mediated toxicity through perturbation of mitochondrial outer membrane (MOM) properties. We conducted a comprehensive comparative study of the impact of cytotoxic and cytoprotective bile acids on the membrane structure of different cellular compartments. We show that DCA increases the plasma membrane fluidity of hepatocytes to a minor extent, and that this effect is not correlated with the incidence of apoptosis. Additionally, plasma membrane fluidity recovers to normal values over time suggesting the presence of cellular compensatory mechanisms for this perturbation. Colocalization experiments in living cells confirmed the presence of bile acids within mitochondrial membranes. Experiments with active isolated mitochondria revealed that physiologically active concentrations of DCA change MOM order in a concentration- and time-dependent manner, and that these changes preceded the mitochondrial permeability transition. Importantly, these effects are not observed on liposomes mimicking MOM lipid composition, suggesting that DCA apoptotic activity depends on features of mitochondrial membranes that are absent in protein-free mimetic liposomes, such as the double-membrane structure, lipid asymmetry, or mitochondrial protein environment. In contrast, the mechanism of action of cytoprotective bile acids is likely not associated with changes in cellular membrane structure.     

Studies on regenerating liver and hepatoma plasma membranes--I. Lipid and protein composition

1. Plasma membranes were isolated from normal liver, Morris hepatoma 7288C and regenerating liver, 6, 15, 24, and 48 hr after partial hepatectomy. 2. The cholesterol/phospholipid ratio was lower in regenerating liver 6 hr after partial hepatectomy (0.51) compared to the sham control (0.68), returning to normal after 15 hr. This was accompanied by a small increase in palmitic acid (16:0). There were no other changes in the lipid composition in regenerating hepatocytes in the first 48 hr after partial hepatectomy. 3. Analysis of lipid composition showed a higher cholesterol/phospholipid ratio in the hepatoma plasma membrane compared to normal liver accompanied by an increase in saturation of the fatty acyl groups of the phospholipids. There were also significant changes in the phospholipid classes. 4. There was no change in the two-dimensional electrophoretic profile of membrane proteins in the early stages of liver regeneration, however hepatoma membranes showed significant differences in protein profile. 5. These changes in the lipid composition of the hepatoma plasma membrane would have the effect of decreasing the average fluidity of the membrane and together with the changes in protein composition may be significant in the altered growth of the hepatoma. Changes in the lipid composition of the hepatocyte plasma membrane early in liver regeneration may reflect the onset of renewed cell division.