Effect of Substrate on the Fatty Acid Composition of Hydrocarbon- and Ketone-utilizing Microorganisms

The fatty acid pattern in hydrocarbon- and ketone-utilizing bacteria after growth on various substrates was examined. The fatty acid composition of one hydrocarbon-utilizing organism (Mycobacterium sp. strain OFS) was investigated in detail after growth on n-alkanes, 1-alkenes, ketones, and n-alcohols. n-Alkanes shorter than C₁₃ or longer than C₁₇ were not incorporated into cellular fatty acids without some degradation. Strain OFS incorporated C₁₄ to C₁₇ 1-alkenes into cellular fatty acids as the ω-monoenoic fatty acid. Methyl ketones were incorporated into strain OFS after removal of one- or two-carbon fragments from the carbonyl end of the molecule. An organism isolated by enrichment on methyl ketones was incapable of n-alkane utilization but could grow on, although not incorporate, ketones or long chain n-alcohols into cellular fatty acids.     

Effect of Substrate on the Fatty Acid Composition of Hydrocarbon-Utilizing Filamentous Fungi

A methionyl-specific dipeptidase from Streptococcus pneumoniae has been described. This enzyme and the pneumococcal tripeptidase have been shown to be intracellular, soluble, and constitutive. In addition to their function in cleavage of peptide nutrients, these peptidases may play a role in protein synthesis and turnover.     

Fatty Acid Metabolism in Microorganisms

The production of pimelic acid from azelaic acid by microorganisms was studied. About 100 strains of bacteria which were able to utilize azelaic acid as a sole carbon source were isolated from soil and other natural materials. Among these bacteria, several strains produced a large quantity of an organic acid (pimelic acid) from azelaic acid in their culture fluids during the cultivation. The acid was isolated from the culture fluid of strain A133 in crystalline form. The crystal was identified as pimelic acid by physicochemical and biological methods.

From the results of investigations on the morphological and physiological characters, the bacterial strain A133 was assumed to be Micrococcus sp.     

Fatty Acid Metabolism in Microorganisms

During the investigation on the metabolism of azelaic acid by Micrococcus sp., it was found that the bacterium produced a large amount of keto acid (α-ketoglutaric acid) under the restricted condition for nitrogen source. The acid was identified as α-ketoglutaric acid by physico-chemical and biological methods. The mechanism of the production of α-ketoglutaric acid from azelaic acid was investigated. From the result, it was suggested that α-ketoglutaric acid production proceeded thrpugh the further oxidation of acetic acid produced from azelaic acid and that the production might be functioned by TCA cycle enzymes of the bacterium. Similarly, α-ketoglutaric acid was found to be produced remarkably from other various fatty acids.     

Effects of Microorganisms on the Peroxidation of Lipid and Fatty Acid Composition of Fermented Fish Meal

Fermentation of waste fish treated with Aspergillus oryzae, Aspergillus sojae K, and Saccharomyces cerevisiae IFO 2114 were studied independently and combined. Three microorganisms decreased the POV, MDA, and COY of fish meal at different rates. The optimum conditions for fermentation with the combination of three microorganisms was found at 30°C for 20–hr fermentation. Almost no difference was observed in the chemical composition or amino acid spectra of the protein hydrolysates of the fermented and nonfermented fish meal. On the quantity of water-soluble amino acids, the highest increase was in glutamate among others, but histidine was decreased by the combination of the three microorganisms. With A. oryzae, the highest increase was in phenylalanine and with A. sojae K in threonine. A great change was observed in some fatty acids content. Myristic acid (14:0) was decreased while the highest increase occurred in the linoleic acid (18: 2) content by fermentation with the combination of three microorganisms. The same phenomenum was observed with A. oryzae and A. sojae K. S. cerevisiae has a weaker effect than A. oryzae and A. sojae K in fermentation of waste fish.     

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.     

Calculation of Biodiesel Fuel Characteristics Based on the Fatty Acid Composition of the Lipids of Some Biotechnologically Important Microorganisms

The interdependences between the structure of fatty acid and biofuel characteristics obtained from these fatty acids were briefly reviewed. The fatty acid compositions of the lipids of yeasts and phototrophic microorganisms were analyzed. The main parameters of the biodiesel (iodine value, cetane number, and kinematic viscosity) that can be made from the lipids of these microorganisms were calculated based on the data and compared to the current standards. The lipids of the yeast Rhodosporidium toruloides VKPM Y-3349 were shown to be the most suitable for biofuel production due to the composition and content of fatty acid. The possibilities of a decrease in the prime cost of microbial lipids (along with plant oils) that would make them competitive raw material for biofuel production were considered.     

培养条件对青枯雷尔氏菌脂肪酸组成的影响

应用气相色谱技术测定不同温度、培养时间、pH值等培养条件下青枯雷尔氏菌(Ralstonia solanacearum)脂肪酸的结果表明: 青枯雷尔氏菌强致病力菌株Rs-J.1.4-010704-01v的脂肪酸种类有14~34种, 主要特征脂肪酸为C16:1ω7c/C15:0 ISO 2OH(10.644 min), C16:0(10.950 min), C18:1ω7c(14.177 min), 所占总百分比含量为总脂肪酸的55.66%~75.69%; 该菌脂肪酸的种类与含量随着培养条件的改变而发生变化,     

Effect of Dietary Mono- and Polyunsaturated Fatty Acids on the Fatty Acid Composition of Pigs' Adipose Tissues

In two experiments with growing-finishing pigs six different dietary fats were added to a conventional diet (control - C) to study the effects of dietary monounsaturated (MUFA) and polyunsaturated fatty acids (PUFA) on the fatty acid composition of backfat and kidney fat at similar amounts of double bonds in feed (Exp. 1:7% pork fat - PF, 4.95% olive oil - OO, 3.17% soybean oil - SO) or a constant amount of 5% of processed fats (Exp. 2: partially hydrogenated fat - SAT, fractionated pork fats: olein - OLE, stearin - STE). Compared with the control, PUFA were only slightly increased in backfat of pigs fed PF, OLE, STE or OO, although dietary PUFA intake was up to 70% higher. With SO PUFA were significantly increased in adipose tissues, predominantly at the expense of MUFA. Consequently, a non-linear relationship was found between PUFA intake and proportion in backfat. MUFA were incorporated at the expense of SFA, therefore, adipose tissues of OO fed animals were lowest in SFA. Despite comparable amounts of double bonds in feed (Exp. 1), the degree of unsaturation measured as fat score (sum of double bonds) was in the order SO > OO > PF > C. In contrast, the proportion of SFA was C > PF = SO > OO. Regarding the decisive role of SFA for fat consistency it may be concluded that MUFA should also be considered in feeding recommendations for pigs. Furthermore, in case of a high dietary supply of MUFA, a simple index of double bonds might not be sufficiently conclusive to judge pig fat quality.     

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.     

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.     

Effect of Aromatic Compounds on Cellular Fatty Acid Composition of Rhodococcus opacus

In cells of Rhodococcus opacus GM-14, GM-29, and 1CP, the contents of branched (10-methyl) fatty acids increased from 3% to 15 to 34% of the total fatty acids when the cells were grown on benzene, phenol, 4-chlorophenol, chlorobenzene, or toluene as the sole source of carbon and energy, in comparison with cells grown on fructose. In addition, the content of trans-hexadecenoic acid increased from 5% to 8 to 18% with phenol or chlorophenol as the carbon source. The 10-methyl branched fatty acid content of R. opacus GM-14 cells increased in a dose-related manner following exposure to phenol or toluene when toluene was not utilized as the growth substrate. The results suggest that 10-methyl branched fatty acids may participate in the adaptation of R. opacus to lipophilic aromatic compounds.     

Effects of Chain-length of Alkane Substrate on Fatty Acid Composition and Biosynthetic Pathway in Some Candida Yeasts

Cellular fatty acid compositions of Candida tropicalis pK 233 and Candida lipolytica NRRL Y -6795 and the time-course changes during yeast growth were studied using individual n-alkanes of various chain lengths (from C₁₁ to C₁₈) and a mixture of n-alkanes (C₁₁ to C₁₈) as a sole carbon source. Observed relationships of the chain-length of n-alkane substrate to time-course changes and final patterns of the fatty acid compositions of these yeasts, especially those of the cells grown on odd-carbon alkanes, indicated that “intact incorporation mechanism,” that is, accumulation of the fatty acid having the same chain-length as that of the alkane substrate used was predominant in the yeasts cultivated on a longer alkane such as n-heptadecane and n-octadecane. On the other hand, “chain elongation pathway” and “de novo synthesis pathway” following β-oxidation of substrate were simultaneously operative in the cells growing on a relatively shorter alkane such as undecane and dodecane.     

Effect of γ Irradiation on the Fatty Acid Composition of Soybean and Soybean Oil

Food irradiation is a form of food processing to extend the shelf life and reduce spoilage of food. We examined the effects of γ radiation on the fatty acid composition, lipid peroxidation level, and antioxidative activity of soybean and soybean oil which both contain a large amount of unsaturated fatty acids. Irradiation at 10 to 80 kGy under aerobic conditions did not markedly change the fatty acid composition of soybean. While 10-kGy irradiation did not markedly affect the fatty acid composition of soybean oil under either aerobic or anaerobic conditions, 40-kGy irradiation considerably altered the fatty acid composition of soybean oil under aerobic conditions, but not under anaerobic conditions. Moreover, 40-kGy irradiation produced a significant amount of trans fatty acids under aerobic conditions, but not under anaerobic conditions. Irradiating soybean oil induced lipid peroxidation and reduced the radical scavenging activity under aerobic conditions, but had no effect under anaerobic conditions. These results indicate that the fatty acid composition of soybean was not markedly affected by radiation at 10 kGy, and that anaerobic conditions reduced the degradation of soybean oil that occurred with high doses of γ radiation.     

Fatty Acid Composition of Spirochaeta stenostrepta

The fatty acid composition of Spirochaeta stenostrepta consists primarily of saturated, branch-chained fatty acids. Iso-C(15), anteiso-C(15), iso-C(17), and anteiso-C(17) represent 66% of the total fatty acids.     

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.     

Fatty Acid Composition of Hydrocarbon-Assimilating Yeast

As a part of extensive program on microbial utilization of hydrocarbons, lipid components of Candida petrophillum SD-14 grown on n-alkanes and glucose as carbon sources were studied. In any carbon source, cellular fatty acids of the yeast contained palmitic, palmitoleic, stearic, oleic and linoleic acids as major components.

When n-tridecane was fed to the yeast, fatty acids with odd- and even-number of carbon atoms were produced in almost identical quantity. Another yeast, Torulopsis petrophillum SD-77, also gave a very similar fatty acid pattern by n-tridecane substrate. These phenomena indicate the existence of C₂ addition and β-oxidation of the fatty acid formed in the yeasts.

In the cases of n-tridecane, n-hexadecane and glucose as substrate, about a half of SD-14’s lipid was phospholipid, which consisted of phosphatidyl ethanolamine and phosphatidyl choline principally. Free alcohol and wax were not detected in any case.     

伞形霉属3个种的脂肪酸组成初探

伞形霉属是重要的产油真菌,本研究分析了具棱伞形霉(Umbelopsis angularis)、长白伞形霉(U.changbaiensis)和葡酒色伞形霉(U. vinacea) 36个菌株的脂肪酸组成。研究结果共检测到26种脂肪酸,链长12～20碳。特征性脂肪酸为18∶3 cis 6,12,14(十八碳三烯酸)、18∶2 cis 9,12/18∶0a(亚油酸/硬脂酸)、18∶1(w 8)/18∶1 cis 9 (w 9)(顺-10-油酸/油酸)和16∶0(十六烷酸) 4种,累计百分比为92.92%。脂肪酸/菌体生物量比值范围为0.40%～2.18%。结果表明具棱伞形霉、长白伞形霉和葡酒色伞形霉富含长链不饱和脂肪酸和重要功能性脂肪酸,具有潜在的开发价值。     

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。