Fatty acid composition of mitochondrial membranes of pea germs exposed to insufficient watering and treated with organophosphorous plant growth regulator

The influence of insufficient watering and a melamine salt of bis(oxymethyl)-phosphonic acid (melaphen) on fatty acid composition of mitochondrial membrane of pea seedlings has been studied. It is shown that insufficient watering results in a 1.57-fold decrease in the ratio of unsaturated to saturated C₁₈ fatty acids and in a 3.04-fold decrease in the ratio of unsaturated to saturated C₂₀ fatty acids. The modification of fatty acid composition of mitochondrial membranes was associated with the alterations in their functional state: maximal rates of oxidation of NAD-dependent substrates and the rates of electron transport at the end of respiratory chain decreased. A preliminary treatment of the seeds with 3 × 10⁻⁹ M melaphen restored the maximal rates of oxidation of NAD-dependent substrates to the control values. We suggest that the alterations of the electron transport rates in respiratory chain in mitochondria are related to the physicochemical state of the membranes of these organelles, as the treatment with melaphen prevented the changes in fatty acid composition of the membranes of seedlings growing under the conditions of insufficient watering.     

Changes in the content and composition of lipid fatty acids in tobacco leaves and roots at low-temperature hardening

Changes in the fatty acid (FA) composition of leaf and root lipids of heat-loving tobacco (Nicotiana tabacum L., cv. Samsun) plants during low-temperature hardening (8°C for 6 days) were studied. Hardening could improve leaf but not root cold tolerance. As this took place, the relative content of polyunsaturated (18:2n-6 and 18:3n-3) FAs increased and the proportion of saturated and monounsaturated FAs decreased. In contrast, in the roots hardening slightly increased the concentration of saturated FAs (16:0 and 18:0) and reduced the level of unsaturated FAs (18:1n-9, 18:2n-6, and 18:3n-3). At the same time, root lipids contained much C_20–24 FAs, and their content increased during hardening. It was suggested that an increased FA saturation and elevated proportion of C_20–24 FAs in the root lipids resulting in the lower membrane fluidity could be a reason for incapability of heat-loving tobacco plant roots of hardening and plant death at the lowtemperature stress.     

Changes in the fatty acid composition of symbiotic dinoflagellates from the hermatypic coral <Emphasis Type="Italic">Echinopora lamellosa</Emphasis> during adaptation to the irradiance level

The composition of fatty acids (FAs) of symbiotic dinoflagellates isolated from the hermatypic coral Echinoporal lamellosa adapted to the irradiance of 95, 30, 8, and 2% PAR was studied. Polar lipids and triacylglycerols (TAG) differed between them in FA composition. Polar lipids were enriched in unsaturated FAs, whereas TAG, in saturated FAs. Light exerted a substantial influence on the FA composition in both polar lipids and TAG. The elevation of irradiance resulted in the accumulation of 16:0 acid in both lipid groups and 16:1(n-7) acid in TAG. It seems likely that de novo synthesis of 16:0 acid occurred actively in the cells of symbiotic dinoflagellates in high light. Since these processes are energy-consuming ones, they utilize excessive energy. When light intensity declined, 18:4(n-3) and 20:5(n-3) acids accumulated in polar lipids, which was accompanied by the increase in the content of chlorophyll a in the cells of zooxanthellae, whereas the levels of 22:6(n-3) and 20:4(n-6) acids reduced. Although the relative content of particular FAs varied substantially in dependence of irradiance, the balance between the sum of saturated and unsaturated FAs changed insignificantly. We concluded that the role of photoadaptation could not be limited only to changes in the degree of lipid unsaturation and membrane fluidity. It is supposed that light-induced changes in the FA composition reflect the interrelation between photosynthesis and FA biosynthesis.     

The role of free fatty acids in mitochondrial energetic metabolism in winter wheat seedlings

The effect of fatty acids (FAs) (C12–C24) on the functioning of winter wheat (Triticum aestivum L.) mitochondria was studied. Such fatty acids as C12:0, C16:0, and C18:0 and unsaturated FAs, such as C18:1 (n-9 cis), C18:1 (n-12 cis), C18:2 (n-9, 12), (18:3, n-3), and C22:1 (n-9 cis) caused efficient uncoupling of oxidative phosphorylation in mitochondria, i.e., an increase in the nonphosphorylating respiration rate and a decrease in the respiratory control value. It was established that C16:0 had the strongest uncoupling effect among all saturated FAs, and C18:3, among unsaturated FAs. The uncoupling effect of saturated FAs is provided by the ADP/ATP-antiporter, while plant uncoupling proteins play an important role in the uncoupling effect of unsaturated FAs. In addition, unsaturated, as well as saturated FAs might serve as oxidative substrates for mitochondria. It was concluded that the role of FAs in energetic metabolism of winter wheat seedlings consisted of uncoupling of oxidative phosphorylation and of serving as substrates for oxidation.     

Seasonal changes in the fatty acid composition of Pinus sylvestris needle lipids

The fatty acid (FA) composition of common pine (Pinus sylvestris L.) needle lipids was studied. It was shown that FA composition of needle lipids changed during the entire growth period (from March to October) under the influence of environmental factors (temperature, solar radiation) affecting the biosynthesis of chloroplast membrane lipids in pine needles. Among needle lipid FAs, unsaturated polymethylene-interrupted FAs (Δ5-UPIFA) were identified: pinolenic, skiadonic, coniferonic, and other); in March and April, their content attained 16.1 and 16.9% of total FAs; it decreased in June to 6.0% and increased again in September to 20.4%.     

Large fluxes of fatty acids from membranes to triacylglycerol and back during N-deprivation and recovery in Chlamydomonas

Microalgae accumulate triacylglycerol (TAG) during nutrient deprivation and break it down after nutrient resupply, and these processes involve dramatic shifts in cellular carbon allocation. Due to the importance of algae in the global carbon cycle, and the potential of algal lipids as feedstock for chemical and fuel production, these processes are of both ecophysiological and biotechnological importance. However, the metabolism of TAG is not well understood, particularly the contributions of fatty acids (FAs) from different membrane lipids to TAG accumulation and the fate of TAG FAs during degradation. Here, we used isotopic labeling time course experiments on Chlamydomonas reinhardtii to track FA synthesis and transfer between lipid pools during nitrogen (N)-deprivation and resupply. When cells were labeled before N-deprivation, total levels of label in cellular FAs were unchanged during subsequent N-deprivation and later resupply, despite large fluxes into and out of TAG and membrane lipid pools. Detailed analyses of FA levels and labeling revealed that about one-third of acyl chains accumulating in TAG during N-deprivation derive from preexisting membrane lipids, and in total, at least 45% of TAG FAs passed through membrane lipids at one point. Notably, most acyl chains in membrane lipids during recovery after N-resupply come from TAG. Fluxes of polyunsaturated FAs from plastidic membranes into TAG during N-deprivation were particularly noteworthy. These findings demonstrate a high degree of integration of TAG and membrane lipid metabolism and highlight a role for TAG in storage and supply of membrane lipid components.

In Chlamydomonas, about a third of triacylglycerol (TAG) made during nitrogen deprivation is derived from preexisting membranes, and most membranes made after resupply are derived from TAG.     

Fatty acid composition of lipids from the vacuolar membranes of the roots of root vegetables

The fatty acid (FA) composition of vacuolar membrane lipids from the storage tissues of parsnip (Pastinaca sativa L.), parsley (Petroselinum crispum L.), and carrot (Daucus carota L.) was studied by gasliquid chromatography, and possible pathways of the biosynthesis of these acids are considered. A high level of unsaturated FAs (up to 78% of the total FA amount) was characteristic of these membrane lipids with the predominance of linoleic acid, which content in vacuolar lipids of parsnip, parsley, and carrot was 53.5, 55.1, and 54.4%, respectively. A high content of hexadienoic acid (C16:2ω6) was characteristic of the vacuolar lipids of parsnip and parsley (8.0 and 4.6%. respectively); the content of α-linolenic acid in the vacuolar lipids of these plants was 4.4–7.3%. Palmitic acid predominated among the saturated FAs (18.0–20.4%).     

The Effect of Helminthosporic Root Rot on the Composition of Acyl Lipids of Wheat Seedlings

The changes of the molecular species composition of esterified fatty acids (FAs) of total and nonextractable lipids were determined in roots and etiolated shoots of 3- to 10-day-old wheat (Triticum aestivumL.) seedlings infected with the fungus Bipolaris sorokiniana, the agent of helminthosporic root rot. A novel technique of assessing the extent of the infection-induced deviation of FA composition, mol %, from the control value was developed. It consists in the quantitative determination of both the deviations in this composition and the extent of contribution of separate FA species to the deviations observed. The application of this technique has shown that, for the total lipids, the maximum of such a deviation, in accordance with the membrane theory of stress, directly coincided in time with the onset of a decrease in the dry matter content in both roots and shoots. In each of these, the deviation was primarily caused by the change in the content of those FA species that usually dominate in a specific group of membrane lipids prevailing in a given organ, viz., plastid glycolipids in shoots and extraplastidal membrane phospholipids in roots. In both cases, C₂₀–C₂₂FAs significantly contributed to the deviations observed. This fact seems to reflect an enhanced formation of epicuticular waxes rich in these FAs on the shoot and root surfaces as an adaptive response of plants to fungal infection. Nonextractable (annular) membrane lipids, because of their vital importance for the survival of plant cells, differed from the total lipids with a far greater stability of their quantitative FA composition under conditions of infection-induced metabolic disturbances.     

Substrate specificity of acyl-lipid Δ9-desaturase from <Emphasis Type="Italic">Prochlorothrix hollandica</Emphasis> cyanobacterium producing myristoleic acid

Chlorophyll b-containing cyanobacterium Prochlorothrix hollandica is characterized by a high content of esterified fatty acids (FA) with 14 and 16 carbon atoms in the membrane lipids. Depending on the conditions of cultivation, the relative amount of myristic (C_14:0) and myristoleic (C_14:1) acids can reach 35%, and palmitic (С_16:0) and palmitoleic (С_16:1) acids can reach 60% of the sum of all fatty acids in cells. Monounsaturated FAs are represented by C_14:1, and C_16:1 with an olefinic bond presumably located in the Δ⁹ position. We cloned the gene of acyl-lipid Δ9-desaturase, desC1, from Prochlorothrix hollandica and characterized its specificity to the length of the substrate using the heterologous expression in Escherichia coli cells adding C_14:0 or stearic (C_18:0) acids as exogenous substrates. The results show that DesC1 Δ⁹ desaturase generates olefinic bonds in the FAs with a length of 14 to 18 carbon atoms with an approximately equal efficiency. This indicates that the length of the FA chain in P. hollandica is determined by the activity of the FA synthase, and the chain is desaturated at the Δ⁹ position nonspecifically relatively to its length.     

Influence of abiotic factors on the content of fatty acids of Ulva Intestinalis

The composition of fatty acids (FAs) of a green alga (Ulva intestinalis) inhabiting small rivers of the Elton Lake basin has been investigated. It has been established that long-chain FAs with 16 and 18 carbon atoms are essential. We have investigated the composition variability of FAs of lipids of U. intestinalis depending on environmental factors: the level of mineralization, temperature, oxygen saturation, and acidity. It has been revealed that FA nonsaturation increases with an increase in mineralization. We assume that ω-6 and ω-3 desaturases participate in the adaptation of U. intestinalis to this factor.     

Fatty acid composition of the parasitic mite Varroa destructor and its host the worker prepupae of Apis mellifera

The present study analyzes the fatty acid (FA) profile of lipids isolated from Varroa destructor Anderson & Trueman, a parasitic mite of the honey bee (Apis mellifera L.), uninfected and infected worker prepupae of the Carnolian subspecies Apis mellifera carnica Pollmann, and bee bread fed to the worker brood. Significant differences are observed in the FA profiles of lipids isolated from parasites, hosts and bee bread. Parasitism by V. destructor (henceforth, varroosis) induces visible changes in the lipid profile of worker prepupae. In infected prepupae, the percentage of total saturated FAs is lower and the percentage of unsaturated FAs is higher than in uninfected insects. These differences result from significant changes in the percentages of FAs that are most abundant in the evaluated groups (i.e. C16:0, C18:1 9c, C18:2n‐6 and C18:3n‐3 FAs). In mites and in uninfected and infected prepupae, the predominant FAs are oleic acid (41.07 ± 2.26%, 42.79 ± 1.21% and 45 ± 0.20%, respectively) and palmitic acid (22.62 ± 0.87%, 39.48 ± 0.43% and 36.84 ± 0.22%, respectively). Highly significant differences in FA composition are noted between bee bread and worker brood. The results suggest specific mechanisms of FA uptake, accumulation and metabolism in the food chain of this parasitic association, beginning from the food processed by nurse bees for larval feeding, through host organisms (worker brood) to V. destructor mites.     

Fatty Acid Composition of Lipids from Leaves and Strobila of Cycas Revoluta (<Emphasis Type="Italic">Cycas revoluta</Emphasis>)

Fatty acid (FA) composition of lipids from leaves and differentiated fleshy strobila tissues and sporangia with spores of Cycas (Cycas revoluta Thumb.) after their step quantitative extraction from plant material was investigated. Quantitative content and qualitative composition of FAs of extractable and nonextractable leaf lipids were determined. It was established that flesh lipids of sporophylls are characterized by a high saturation level and contain a considerable proportion of saturated FAs with the usual chain length (C₁₂–C₁₈, 53–57%). At the same time, total amount of etherified FAs with a very long chain in lipids not extractable by the method of Zhukov and Vereshchagin exceeds several times that found in extractable lipids (~15 and ~4%, respectively). Neutral lipids of Cycas spores were represented by triacylglycerols, the lower-alkyl esters of FAs, free FAs, and sterol esters.     

Fatty acids of sponges from the Sea of Okhotsk

The fatty acid (FA) composition of Demospongiae species from the Sea of Okhotsk was studied. Fifteen sponge species were investigated for the first time, and the previously studied species Desmacella rosea and Myxilla incrustans were reexamined for their FA composition. Gas chromatography-mass spectrometry revealed 150 different fatty acids, of which 15 have not been identified in sponge lipids previously. The relative content of saturated FAs varied from 7.6 in Melonachora kobjakovae to 29.6% in Amphilectus digitata, with an average of 14.6% of total FAs. The relative content of monoenic FAs ranged from 12.8 in T. dirhaphis to 27.0% in Polymastia sp., with an average of 20.6% of total FAs. Non-methylen-interrupted, primarily unsaturated Δ5,9-FAs contributed a significantly to the amount of polyunsaturated fatty acids of sponges; this being a distinguishing feature of the FA composition of the investigated group of organisms.     

Oxaloacetate translocator in plant mitochondria

(1) Mitochondria were prepared from leaves of spinach, green and etiolated seedlings and roots of pea, potato tuber and rat liver and heart. In the case of leaf mitochondria, an improved isolation procedure resulted in high respiratory rates (460–510 nmol/mg protein per min) and good respiratory control ratio (6.8–9.8) with glycine as substrate. (2) In these mitochondria oxaloacetate transport was studied either by following the inhibitory effect of oxaloacetate on the respiration of NADH-linked substrates or by determining the consumption of [4-¹⁴C]oxaloacetate. (3) Studies of the competition by other carboxylates and effect of inhibitors on the oxaloacetate transport demonstrate that mitochondria from spinach leaves, green pea seedlings, etiolated pea seedlings and pea roots contain a specific translocator for oxaloacetate with a very high affinity to its substrate (K_m = 3–7 μM) and an even higher sensitivity to its competitive inhibitor phthalonate (K_i = 3–5 μM). The V_max values ranged from 150 to 180 nmol/mg protein per min for mitochondria from etiolated pea seedlings and pea roots and from 550 to 570 nmol/mg protein per min for mitochondria from spinach leaves and green pea seedlings. In mitochondria from potato tuber, the K_m was about one order of magnitude higher (V_max = 450 nmol/mg protein per min). In mitochondria from rat liver and rat heart, a specific translocator for oxaloacetate was not found. (4) The oxaloacetate translocator enables the functioning of a malate-oxaloacetate shuttle for the transfer of reducing equivalents across the inner mitochondrial membrane. (5) This malate-oxaloacetate shuttle appears to play a role in the photorespiratory cycle in catalyzing the transfer of reducing equivalents generated in the mitochondria during glycine oxydation to the peroxysomal compartment for the reduction of β-hydroxypyruvate. (6) Interaction between the mitochondrial and the chloroplastic malate oxaloacetate shuttles would make it possible for surplus-reducing equivalents, generated by photosynthetic electron transport, to be oxidized by mitochondrial electron transport.     

Role of the Transmembrane Potential in the Membrane Proton Leak

The molecular mechanism responsible for the regulation of the mitochondrial membrane proton conductance (G) is not clearly understood. This study investigates the role of the transmembrane potential (ΔΨ_m) using planar membranes, reconstituted with purified uncoupling proteins (UCP1 and UCP2) and/or unsaturated FA. We show that high ΔΨ_m (similar to ΔΨ_m in mitochondrial State IV) significantly activates the protonophoric function of UCPs in the presence of FA. The proton conductance increases nonlinearly with ΔΨ_m. The application of ΔΨ_m up to 220 mV leads to the overriding of the protein inhibition at a constant ATP concentration. Both, the exposure of FA-containing bilayers to high ΔΨ_m and the increase of FA membrane concentration bring about the significant exponential G_m increase, implying the contribution of FA in proton leak. Quantitative analysis of the energy barrier for the transport of FA anions in the presence and absence of protein suggests that FA⁻ remain exposed to membrane lipids while crossing the UCP-containing membrane. We believe this study shows that UCPs and FA decrease ΔΨ_m more effectively if it is sufficiently high. Thus, the tight regulation of proton conductance and/or FA concentration by ΔΨ_m may be key in mitochondrial respiration and metabolism.     

Fatty acid composition of lipids in the calluses of two pine species <Emphasis Type="Italic">Pinus sibirica</Emphasis> and <Emphasis Type="Italic">Pinus sylvestris</Emphasis>

The fatty acid (FA) composition of callus lipids in two pine species, Pinus sibirica Du Tour and P. sylvestris L. was studied. Callus lipids were characterized by a high content of unsaturated FAs: 81.7% in P. sibirica and 63.2% in P. sylvestris. Among them, oleic and linoleic acids predominated (22.9 and 34.0% of total FAs in P. sibirica and 17.6 and 27.8% in P. sylvestris, respectively). Callus lipids also contained Δ5-UPIFA (unsaturated polymethyle-interrupted FAs), where pinoleic and sciadonic acids predominated. A comparison of FAs in the lipids of P. sylvestris calluses derived from needle and needle photosynthesizing tissues of this pine species showed that callus lipids were characterized by a greater diversity of Δ5-UPIFA but a lower degree of FA unsaturation and he higher level of Δ5-UPIFA.     

On the Physiological Role of Anaerobically Synthesized Lipids in <Emphasis Type="Italic">Oryza sativa</Emphasis> Seedlings

The objective of this work was to elucidate a possible adaptive role of lipid biosynthesis and unsaturated fatty acids (FAs), esterified to lipids, as terminal acceptors of electrons, alternative to molecular oxygen, in the shoots of rice seedlings (Oryza sativa L.) under conditions of strict anoxia. Biosynthesis of lipids and their accumulation, as well as the reduction of double bonds in unsaturated FAs, were studied by electron microscopic observation of the accumulation of lipid bodies in the cytoplasm and by the biochemical analysis of FAs in shoot lipids before and after anaerobic incubation of the shoots. The experiments were carried out with intact coleoptiles after 5 and 8 days of anaerobic germination of seeds (primary anoxia) and with detached shoots, preliminarily grown in air and then subjected to anoxia in the presence of 2% glucose for 48 h (secondary anoxia). In these experiments, lipid bodies did not accumulate in the cytoplasm under anoxic conditions. Lipid bodies appeared only during 48-h anaerobic incubation of detached coleoptiles in the absence of exogenous glucose, when mitochondria degraded. There was no change either in the double bond index of FAs, or in the qualitative and quantitative composition of FAs during shoot anaerobic incubation. We conclude that neither lipids synthesized under anaerobic conditions nor esterified unsaturated FAs are involved in plant adaptation to anaerobiosis as terminal acceptors of electrons, alternative to molecular oxygen. Lipid biosynthesis under anoxic conditions, which was demonstrated for anoxia-tolerant seedlings of Oryza sativa and Echinochloa phyllopogon in experiments with radioactive precursors, ¹⁴C-acetate and ³H-glycerol, is only the manifestation of a turnover of saturated FAs and various classes of lipids, which stabilizes cell membranes under adverse conditions of strict anoxia.__________Translated from Fiziologiya Rastenii, Vol. 52, No. 4, 2005, pp. 540–548.Original Russian Text Copyright © 2005 by Generosova, Vartapetian.     

Fatty acid and nutritive quality of chia (Salvia hispanica L.) seeds and plant during growth

The fatty acid (FA) profile, chemical composition, gross energy and organic matter digestibility of chia (Salvia hispanica L.) have been determined in the seed and in the plant collected at five progressive morphological stages from early vegetative to budding stage. The FA analyses disclosed quantitative differences between the plant stages that were characterised by a high percentage of polyunsaturated fatty acids (PUFA), which made up from 752 to 623 g/kg of the total FA of the plant during the growth cycle. The α-linolenic acid (ALA, C_18:3n–3) decreased from 649 g/kg, at the early vegetative stage, to 499 g/kg of the total FA, at the budding stage, while all the other FAs increased with increasing growth stage. The chia seed FAs were also highly unsaturated, with their main components being ALA (641 g/kg of the total FA) and linoleic acid (LA, C_18:2n–6; 188 g/kg of the total FA).The evolution of the quality of chia is closely related to the ageing of the plant. The chia plant provides a forage with a good nutritive value when harvested at a stage before the shooting period. After this, the nutritional quality of the plant considerably decreases with an increase in the fibrous fractions and a dramatical decrease of the crude protein content.     

The Composition of fatty acids and aldehydes of the marine bryozoans <Emphasis Type="Italic">Berenicea meandrina</Emphasis> and <Emphasis Type="Italic">Dendrobeania flustroides</Emphasis> (Bryozoa: Gymnolaemata)

This study examines the composition of lipids, fatty acids, and fatty aldehydes in two marine bryozoan species, Berenicea meandrina and Dendrobeania flustroides, from the Sea of Okhotsk. The share of neutral lipids was up to 57.3% in D. flustroides and 54.9% in B. meandrina; the share of polar lipids was 33.2 and 40.4%, respectively. In all, 57 fatty acids (FA) and 9 aldehydes were identified in total lipids. The main FAs were 16:0, 18:0, 22:6n-3, and 20:5n-3. The content of branched saturated FA in bryozoans was on the average 6.4%. Three isomers of 16:1 (n-9, n-7, and n-5), five isomers of 18:1 (n-13, n-11, n-9, n-7, and n-5), four isomers of 20:1 (n-13, n-11, n-9, and n-7), as well as 22:1n-9 and 22:1n-13 were found; the presence of 7-methyl-6-hexadienoic acid (on the average, 3.0% of total FAs) was demonstrated. Non-methylene-inter-rupted FAs contributed 8.9 and 1.6% of the total FAs in D. flustroides and B. meandrina, respectively, and were identified as 20:2(5,11), 20:2(7,13), 20:3(5,11,14), 22:2(7,13), and 22:2(7,15). In B. meandrina, minor amounts of 24:0, 24:1, 25:0, 26:0, 24:4n-3, 26:3(5,9,19), and 28:3(5,9,19) were found, suggesting sponge biofouling on some bryozoan colonies. Aldehydes (branched saturated and unsaturated C_16–19 homologues) did not exceed 10.3 and 1.9% of the total FAs in D. flustroides and B. meandrina, respectively. The presence of the FA markers that are characteristic of microalgae, protozoans, and detritus in bryozoan lipids agrees well with data on polytrophic feeding of these bryozoans.