Lipid and Fatty Acid Composition of the Marine Brown Alga Dictyopteris membranacea

Glycerolipids and fatty acids of D. membranacea (Dic-tyotales)were analysed. The betaine lipid DGTA and the glycolipids MGOG,DGDG and SQDG were major components. The phospholipids PE, PG,PI and PHEG were present in minor amounts only. This lipid pattern,which is characterised by the presence of DGTA and the absenceof PC, has been found exclusively in brown algae belonging tothe orders Dictyotales, Durvillaeales and Fucales. Major fattyacids were 16:0, 18:1, 18:2, 18:3, 18:4 and 20:4 acids. MGDGwas the most unsaturated lipid with high levels of 18:4 acid.SQDG showed the highest degree of saturation containing a considerableproportion of 16:0 acid. DGTA contained 14 : 0,18:1,18:2 and20:4 as major fatty acids. Among phospholipids, PE and PHEGhad a very similar pattern which was enriched in 20:4 acid.Analysis of the positional distribution of fatty acids revealedthat DGTA and MGDG were almost exclusivly of the "euka-ryotic"type, whereas SQDG was predominantly of the "prokaryotic" type.For the first time, molecular species of selected lipids havebeen analysed in a brown alga. In DGTA, 14:0/18:1, 14:0/18:2and 14:0/20:4 were the main molecular species. In MGDG the highlyunsaturated erl8:3/18:4, 18:4/18:4 and 18:4/20:5 were predominant. (Received March 31, 1997; Accepted July 4, 1997)     

Effect of Growth Temperature on Fatty Acid Composition of Ten Thermus Strains

The fatty acid composition of Thermus spp., including T. aquaticus ATCC 25104, T. thermophilus DSM 579, T. flavus DSM 674, and seven wild strains was examined. Organisms were tested at a minimum of either 35, 40, or 45°C and at an optimum of 60 or 70°C. Total fatty acid content per dry weight of cells varied between 1.2 and 3.7%, and the quantity of fatty acids was higher at the high temperature range in the majority of strains. At the optimum temperature, strains could be assigned to three chemotaxonomic groups with reference to the ratio of iso C_15:0/iso C_17:0. In six of the strains the ratio of iso C_15:0/iso C_17:0 remained unchanged at the minimum temperature, whereas in four strains the ratio was reversed. The proportion of the C_15:0 and C_17:0 isobranched acids was decreased and the proportion of anteisobranched fatty acids, namely anteiso C_15:0, anteiso C_17:0, and anteiso C_17:1, was increased at the lower temperature range. Some changes were seen in the levels of the n-C_16:0 and iso C_16:0 acids, but these were strain specific.     

The Effect of Temperature on the Lipid Composition of the Green Alga Botryococcus

The lipid composition of the green alga Botryococcus was studied at three different cultivation temperatures: suboptimal (18°C), optimal (25°C), and supraoptimal (32°C). Cultivation at the supraoptimal temperature was found to considerably inhibit the synthesis of nearly all intracellular lipids, except for triacylglycerides, and to influence their fatty acid composition. In particular, the content of trienoic fatty acids was significantly lower at the supraoptimal than at the optimal cultivation temperature. At the same time, the fatty acid composition of the extracellular lipids of the alga virtually did not depend on cultivation temperature.     

Effect of Monochromatic Light on Proton Efflux of the Blue-Green Alga Anabaena variabilis

Light-induced proton efflux of Anabaena variabilis was found to be biphasic, the second phase being inhibited by the ATPase inhibitor nitrofen (2,4-dichloro-1-[4-nitrophenoxy]benzene). The first, fast phase was triggered by monochromatic light of 707 nanometers, whereas the second, slower phase was not. With 707 nanometers, light, respiratory O₂ uptake was inhibited. Using light composed of two wavelengths (616 and 707 nanometers) a marked enhancement of both O₂ evolution as well as the second phase of proton efflux was observed. The first phase was not enhanced. Thus, phase II is driven by both photosystems. As concluded from the action spectrum phase I is markedly determined by photosystem-I activity. Altogether the data show that two different mechanisms of light-induced proton efflux exist on the cytoplasmic membrane of Anabaena, the slower one being dependent on ATP and linear photosynthetic electron flow.     

Effect of Temperature on the Fatty Acid Composition of Thermus aquaticus

Thermus aquaticus contains four major fatty acids, iso-C(15) (28%), iso-C(16) (9%), normal-C(16) (13%), and iso-C(17) (48%), when grown at 70 C, as determined by gas chromatography and mass spectrometry. Small amounts of iso-C(12), normal-C(12:1), iso-C(13), normal-C(14), iso-C(14), and normal-C(15:1) were also detected. A change in growth temperature (50 to 75 C at 5-C intervals) affects a shift in the proportions of some of the fatty acids. The proportions of the monoenoic and branched-C(17) fatty acids decreased and the proportions of the higher-melting iso-C(16) and normal-C(16) fatty acids increased. Cells grown at 75 C contained 70% more total fatty acids than cells grown at 50 C. The largest increases, in absolute amounts, were in the content of iso-C(16) and normal-C(16) fatty acids, with only a 1.6-fold increase in the major iso-C(15) and iso-C(17) fatty acids. There was a 2.5-fold decrease in normal-C(15:1) and at least a 24-fold decrease in anteiso-C(17), which is present at 50 and 55 C but not at higher temperatures. There was no difference in proportion or amount of fatty acids between exponential and stationary-phase cells grown at 70 C. When cells were grown on glutamate instead of yeast-extract and tryptone at 70 C, the total fatty acid content remained constant, but there was an increase in the proportions of iso-C(16) and normal-C(16) fatty acids concomitant with a decrease in the proportions of the iso-C(15) and iso-C(17) fatty acids.     

Influences of Culture Temperature on the Growth, Lipid Content and Fatty Acid Composition of Aurantiochytrium sp. Strain mh0186

The growth, lipid content, and fatty acid composition of Aurantiochytrium sp. strain mh0186 at different temperatures were investigated. Strain mh0186 grew well at 15–30°C, but weakly at 10°C. The biomass at 15–30°C was significantly higher than at 10 and 35°C, and the total lipid at 15–35°C was significantly higher than that at 10°C. The amount of DHA in the total fatty acid was highest at 10°C and decreased in response to temperature increase. The content of DHA (mg/g-dry cell weight) at 15–30°C were significantly higher than those at 35°C and those at 15–25°C were significantly higher than those at 10 and 35°C. The DHA yield at 15–35°C was significantly higher than those at 10 and 35°C. Unsaturation of fatty acid was regulated by temperature and was enhanced in response to temperature decrease. The ratio of DHA to DPA varied at different temperatures.     

Effect of Low Temperature upon Lipid and Fatty Acid Composition of Roots and Leaves of Winter Rape Plants

When winter rape plants were transferred from favourable temperature conditions (25/20°C day/night temperature) to 5°C, the frost resistance of the leaves was increased whereas the frost tolerance of the roots remained unaffected. This permitted an analysis of the changes in lipid and fatty acid composition both as related to functioning of the plant at low temperature alone (roots) and as related to adaptation to freezing and functioning at low temperature (leaves). — Transfer of the plants to 5°C lead to an increase in the level of linolenic acid in roots and leaves. This increase was most evident in the phosphatidyl choline and ethanolamine fractions of the leaves, and in the neutral lipids and in an unidentified phospholipid from the roots. It was concluded that upon transfer of the plants to 5°C a general and non-specific increase in linolenic acid level contributed to functioning of the rape plants at low temperature; and that parallel but minor increases in linolenic acid level of digalactosyl diglyceride, phosphatidyl inositol and the unknown phospholipid in roots and leaves could only contribute to low-temperature functioning in specific membrane enzyme locations. Combined adaptation of the leaves to freezing tolerance and low-temperature functioning was correlated with a higher level of phosphatidyl choline and ethanolamine, predominantly esterified with linolenic acid.     

Effect of Temperature on Fatty Acid Composition of a White Thermus Strain

A white Thermus sp. strain, NCIMB 11245, showed high levels of anteiso C_17:0, anteiso C_17:1, normal C_16:1, and iso C_16:0 with low levels of iso C_15:0 + iso C_17:0 in comparison to yellow-pigmented strains. The fatty acid composition may be associated with precursor metabolism or the absence of carotene pigmentation.     

Effects of Growth Pressure and Temperature on Fatty Acid Composition of a Barotolerant Deep-Sea Bacterium

The effects of pressure and temperature on the fatty acid composition in a barotolerant deep-sea bacterium that had branched-chain fatty acids were examined. The major fatty acids of the strain at atmospheric pressure were iso-C_15:0, C_16:1, iso-C_17:0, and iso-C_17:1. As the growth pressure increased, the proportion of unsaturated fatty acid increased because of an increase in the proportion of iso-C_17:1. On the other hand, as the growth temperature decreased, the proportion of unsaturated fatty acid increased because of the increase in the proportion of C_16:1 and C_18:1.     

Fatty Acid and Polar Lipid Composition in the Classification of Kurthia

Strains of Kurthia zopfii were degraded by acid methanolysis and the non-hydroxylated fatty acid esters so released were examined by gas liquid chromatography. The major fatty acid types were straight-chain, anteiso - and iso -methyl branched-chain acids. Monounsaturated fatty acids were not detected. The major fatty acid in five of the six strains examined consisted of 12-methyltetra-decanoic ( anteiso -C₁₅) acid. The other strain possessed major amounts of both 13-methyltetradecanoic ( iso -C₁₅) and anteiso -C₁₅ acids. Polar lipids of all the strains were examined by two-dimensional thin-layer chromatography. All possessed a very simple polar lipid composition consisting of diphosphatidylglycerol, phosphatidylglycerol and phosphatidylethanolamine.     

The Effect of Temperature on the Fatty Acid Composition of Tetrahymena pyriformis WH-14

SYNOPSIS. A reduction in the growth temperature of Tetrahymena pyriformis strain WH-14 from 35 C to 15 C resulted in distinct alterations in the fatty acid composition of the glycerophospholipids. The proportion of normal saturated acids declined from 26 to 19%; palmitoleic acid increased by 6%, and the composition of the polyunsaturated fatty acids increased in 18:2 Δ^6,11(n) and decreased in 18:2 Δ^9,12(n) and 18:3 Δ^6,9,12(n). The unsaturation index (the average number of double bonds/100 molecules) did not change with a shift in temperature.
Two biosynthetic pathways exist in Tetrahymena for the formation of unsaturated fatty acids. The observed changes in fatty acid composition that accompany a lowering of the environmental temperature can be accounted for by a reduction in the accumulation of products of the fatty acid pathway leading to the formation of γ-linolenic acid [16:0(n) → 18:0(n) → 18:1 Δ⁹(n) → 18:2 Δ^9,12(n) → 18:3 Δ^6,9,12(n)] and an increase in the components of the pathway leading to the formation of 18:2 Δ^6,11(n) [16:0(n) → 16:1 Δ⁹(n) → 18:1 Δ¹¹(n) → 18:2 Δ^6,11(n)]. The data suggest that the regulatory mechanism in Tetrahymena differs from that found in some bacteria where a simple substitution of unsaturated fatty acids for saturated fatty acids occurs at low culture temperatures.     

Effect of Growth Temperature on the Fatty Acid Composition of the Leaf Lipids in Atriplex lentiformis (Torr.) Wats

Plants of Atriplex lentiformis had more saturated leaf lipids when grown at 43 C day/30 C night as compared to 23/18 C temperatures. In monogalactosyl diglyceride, the major change was the presence of hexadecatrienoic acid (16:3) at low but not high growth temperatures. In other lipids investigated, the major change was a decrease in linolenic acid (18:3) and increases in the more saturated fatty acids at high growth temperatures. Growth temperatures had little effect on the relative proportions of the galacto- and sulfolipids in the leaf. The increased lipid saturation is correlated with the greater thermostability of the photosynthetic apparatus at high growth temperatures in A. lentiformis but any cause and effect relationship is uncertain.     

不同生态条件对绿色巴夫藻生长与脂肪酸组成的影响

研究不同温度、盐度、光照条件对绿色巴夫藻生长和脂肪酸组成的影响。实验结果表明:绿色巴夫藻的适温范围在5—30℃之间,最适为25℃;该藻为低盐度种类,在试验范围内都能生长,其最适盐度为6‰;生长较适宜的光照强度为3000—5000lx。巴夫藻的主要脂肪酸为C14∶0、C16∶0、C16∶1(n-7)、C18∶1(n-9)、C18∶3(n-3)、C18∶4(n-3)、C22∶6(n-3),其中在20℃时C22∶6(n-3)的含量达到最高,且PUFA(n-3)的含量也较高;在低盐度条件下有利于PUFA(n-3)的合成,盐度为6‰时C20∶5(n-3)的含量最高为总脂的6.02%,在盐度为15‰时C22∶6(n-3)的含量达到最高(总脂的17.79%);光照强度对C22∶6(n-3)的影响不大,在3000lx时C20∶5(n-3)的含量较高。结果表明低光照强度下利于PUFA(n-3)的合成,且C22∶6(n-3)的含量较高。     

Effect of Temperature and Salinity Stress on Growth and Lipid Composition of Shewanella gelidimarina

The maximum growth temperature, the optimal growth temperature, and the estimated normal physiological range for growth of Shewanella gelidimarina are functions of water activity (a_w), which can be manipulated by changing the concentration of sodium chloride. The growth temperatures at the boundaries of the normal physiological range for growth were characterized by increased variability in fatty acid composition. Under hyper- and hypoosmotic stress conditions at an a_w of 0.993 (1.0% [wt/vol] NaCl) and at an a_w of 0.977 (4.0% [wt/vol] NaCl) the proportion of certain fatty acids (monounsaturated and branched-chain fatty acids) was highly regulated and was inversely related to the growth rate over the entire temperature range. The physical states of lipids extracted from samples grown at stressful a_w values at the boundaries of the normal physiological range exhibited no abrupt gel-liquid phase transitions when the lipids were analyzed as liposomes. Lipid packing and adaptational fatty acid composition responses are clearly influenced by differences in the temperature-salinity regime, which are reflected in overall cell function characteristics, such as the growth rate and the normal physiological range for growth.     

Effects of pH and Temperature on the Fatty Acid Composition of Bacillus acidocaldarius

The fatty acid composition of lipid extracts from cells of Bacillus acidocaldarius grown at temperatures of 50 to 70 C and pH values of 2 to 5 was determined by gas chromatography of the methyl esters. The most abundant fatty acids are 11-cyclohexylundecanoic and 13-cyclohexyltridecanoic, followed by anteiso- and iso-heptadecanoic; unsaturated acids are absent. Highly aerated cultures produce more of the iso and anteiso acids and less of the cyclohexyl acids. The effects of temperature and pH are interdependent; at lower pH, increasing temperature raises the proportion of the iso and anteiso acids, but at higher pH the effect of increasing temperature is reversed and the proportion of the cyclohexyl acids is increased.     

Effect of Temperature on the Fatty Acid Composition of the Extreme Thermophiles, Bacillus caldolyticus and Bacillus caldotenax

Gas chromatographic analysis of extracts from Bacillus caldolyticus and Bacillus caldotenax grown at 60, 70, or 80 C showed that both contain branched-chain fatty acids as major constituents at all temperatures tested. With increasing temperature, a decrease of i-C15 and an increase of i-C17 fatty acids were observed in both strains, as well as a decrease of i-C16 fatty acids corresponding to an increase of n-C16 fatty acids. The most obvious difference was that the shifts observed with B. caldolyticus occurred mainly upon raising the temperature to 10 C above, and in B. caldotenax upon lowering the temperature to 20 C below, the optimal growth temperature.     

Fatty Acid Composition of Escherichia coli as a Possible Controlling Factor of the Minimal Growth Temperature.

Shaw, Maxwell K. (University of California, Davis), and John L. Ingraham. Fatty acid composition of Escherichia coli as a possible controlling factor of the minimal growth temperature. J. Bacteriol. 90:141-146. 1965.-If Escherichia coli ML30 is shifted from 37 to 10 C during exponential growth in glucose minimal medium, a 4.5-hr lag results. During this lag, the proportion of unsaturated fatty acids increases in the cellular lipids. However, the adjustment of the fatty acid composition does not appear to be prerequisite to growth at 10 C. If shifts are made to 10 C into minimal medium containing glucose after starvation for glucose at 37 C for 0.5 and 16 hr, the lag periods at 10 C are 4.5 and 6 hr, respectively. Withholding glucose during the lag periods does not affect the duration of the lag periods, but no change in fatty acid composition occurs if glucose is not present. Supplementing the medium with glucose after the lag period permits immediate growth at 10 C; however, the fatty acid composition is still typical of cells grown at 37 C. It is concluded that the fatty acid composition of cells does not determine the minimal temperature of growth.     

Effect of Temperature on the Fatty Acid Composition and Yield of Evening Primrose (Oenothera lamarckiana) Seeds

The oil content and yield of evening primrose (Oenothera lamarckianaL.) seeds decreased significantly at high temperatures (32 ?C)compared with lower ones (25 ?C and below), under controlledgrowing conditions. Moreover, the fatty acid composition ofthe seed oils was also affected by the temperature regime. Higheroleic acid levels and lower linoleic and -linolenic acid (GLA)levels were characteristic of the seeds developed at highertemperatures. The opposite trend was observed at lower temperatures.In field experiments, seeds of O. lamarckiana plants sown inautumn contained lower oleic acid levels, and higher linoleicacid and GLA levels than seeds of spring plantings. This effectwas also demonstrated for seeds developed on the same stem inflorescenceunder increasing temperatures during the season in the field.Changes in fatty acid composition during various stages of seeddevelopment were observed. Key words: Evening primrose, oil, fatty acids, Oenothera spp., gamma linolenic acid