Conversion of C14-Labeled Substrates to Volatile Fatty Acids by the Rumen Microbiota

The fermentation of uniformly labeled glucose-C¹⁴, glucose-1-C¹⁴, -2-C¹⁴, and -6-C¹⁴, xylose-1-C¹⁴, cellulose-1-C¹⁴, -2-C¹⁴, and -6-C¹⁴, and lactate-2-C¹⁴ by rumen fluids from cows fed all-hay, hay and concentrate (50:50), and all-concentrate diets was investigated. The results obtained suggested that the Embden-Meyerhof glycolytic pathway is the major pathway of hexose utilization, that the major pathway of xylose fermentation involves hexose synthesis, and that the contributions of the nonrandomizing (acrylate) pathway of propionate formation during glucose, xylose, and cellulose fermentations are 4.5, 8.0, and 10.5%, and 24.6, 25.8, and 17.2%, respectively, by rumen fluids from the cows fed all-hay and all-concentrate rations.     

发酵法生产多不饱和脂肪酸

简要介绍微生物产多不饱和脂肪酸的生化研究现状,着重从高产菌株的筛选、工程菌株的构建、发酵条件及产业化现状等方面论述微生物发酵生产多不饱和脂肪酸的主要研究进展;概述多不饱和脂肪酸的提取制备技术,并对发酵法生产多不饱和脂肪酸研究目标和发展前景提出了建议.     

Volatile Fatty Acid Requirements of Cellulolytic Rumen Bacteria

A gas chromatographic method was developed which could separate the isomers isovaleric and 2-methylbutyric acid. Subsequent analyses revealed that most commercially available samples of these acids were cross-contaminated; however, one sample of each acid was found to be pure by this criterion. The growth response of seven strains of cellulolytic rumen bacteria (three strains of Bacteroides succinogenes, three strains of Ruminococcus flavefaciens, and one strain of R. albus) to additions of isobutyric, isovaleric, 2-methylbutyric, valeric, and combinations of valeric and a branched-chain acid was determined. Strains of B. succinogenes required a combination of valeric plus either isobutyric or 2-methylbutyric acid. Isovaleric acid was completely inactive. Either isobutyric or 2-methylbutyric acid was required for the growth of R. albus 7. Strain C-94 of R. flavefaciens grew slowly in the presence of any one of the three branched-chain acids, but a combination of isobutyric and 2-methylbutyric acids appeared to satisfy this organism's growth requirements. None of the individual acids or mixtures of straight- and branched-chain acids allowed growth of R. flavefaciens strain C1a which would approach the response obtained from the total mixture of acids. Further work indicated that all three branched-chain acids were required for optimal growth by this strain, although isovaleric acid only influenced the rate of maximal growth. Either 2-methylbutyric or isovaleric acid allowed growth of nearly the same magnitude as that of the positive control for R. flavefaciens B34b. The presence of acetic acid had little influence on the rate or extent of growth of any of the strains except R. albus 7, for which the extent of growth was markedly increased. Determination of the quantitative fatty acid requirements for the three B. succinogenes strains indicated that 0.1 μmole of valeric per ml and 0.05 μmole of 2-methylbutyric per ml permitted maximal growth. However, with isobutyric acid as the branched-chain component, strains A3c and B21a required 0.1 μmole/ml in contrast to S-85 which exhibited optimal growth at the 0.05 μmole/ml level. By use of mixtures of isobutyric and 2-methylbutyric acids, good growth of C-94 was obtained at concentrations of 0.1 and 0.01 μmole/ml, respectively. About 0.3 μmole/ml of each acid was required for satisfactory growth of C1a.     

Characterization of the Cricket Hindgut Microbiota with Fluorescently Labeled rRNA-Targeted Oligonucleotide Probes

Most cricket hindgut microorganisms (60 to 80%) were detected with a universal fluorescent rRNA-targeted probe and found to be eubacteria. Group-specific probes showed that the hindguts of five different cricket species harbor similar bacterial groups, although in different proportions, and that different diets shifted the structure of the hindgut microbial community. The Bacteroides-Prevotella probe, of the eight eubacterial probes tested, stained the largest percentage of cells in all crickets.     

酶法水解油脂生产脂肪酸的研究

豆油和猪油用解脂假丝酵母脂肪酶水解,酶解产物的酸值分别达到196和194.酶解条件是:豆油酶量100单位/克油,猪油酶量250单位/克油,豆油:水=1:1,猪油:水=0.6:0.4,豆油温度40℃,猪油温度42℃,摇床转速180r/min,水解时间36h,酶解过程中加20%NaOH溶液1%.这样的条件适合脂肪酸生产.     

Volatile Acid Production by Clostridium sporogenes under Controlled Culture Conditions

S ummary . Clostridium sporogenes , grown under controlled culture conditions in a complex medium, starts to produce volatile acids at the end of the logarithmic growth phase when sporulation begins. Since, however, the amount and type of acids depend on the nature of the medium used, it is doubtful whether the volatile acid pattern can be used for identification and classification of proteolytic Clostridia without controlling culture conditions.     

发酵法生产脂肪酸的研究

用毛霉菌做出发菌株 ,经紫外线及硫酸二乙酯等物理化学方法诱变育种 ,筛选出利用葡萄糖生产γ 亚麻酸的菌株 ,并对其发酵条件进行了研究。菌体产率 3 5 %～ 40 % ;脂质含量 2 5 %以上 ,脂质中γ 亚麻酸含量 1 3 %～ 1 4% ,所产脂质脂肪酸组成与天然月见草油基本一致 ,从而解决了天然月见草油资源不足以及γ 亚麻酸含量较低的问题。     

Anaerobic Degradation of Uric Acid by Gut Bacteria of Termites

A study was done of anaerobic degradation of uric acid (UA) by representative strains of uricolytic bacteria isolated from guts of Reticulitermes flavipes termites. Streptococcus strain UAD-1 degraded UA incompletely, secreting a fluorescent compound into the medium, unless formate (or a formicogenic compound) was present as a cosubstrate. Formate functioned as a reductant, and its oxidation to CO₂ by formate dehydrogenase provided 2H⁺ + 2e⁻ needed to drive uricolysis to completion. Uricolysis by Streptococcus UAD-1 thus corresponded to the following equation: 1UA + 1formate → 4CO₂ + 1acetate + 4NH₃. Urea did not appear to be an intermediate in CO₂ and NH₃ formation during uricolysis by strain UAD-1. Formate dehydrogenase and uricolytic activities of strain UAD-1 were inducible by growth of cells on UA. Bacteroides termitidis strain UAD-50 degraded UA as follows: 1UA → 3.5 CO₂ + 0.75acetate + 4NH₃. Exogenous formate was neither required for nor stimulatory to uricolysis by strain UAD-50. Studies of UA catabolism by Citrobacter strains were limited, because only small amounts of UA were metabolized by cells in liquid medium. Uricolytic activity of such bacteria in situ could be important to the carbon, nitrogen, and energy economy of R. flavipes.     

胆汁酸和肠道菌群相互作用对非酒精性脂肪性肝病的影响

近年来,大量研究发现胆汁酸与肠道菌群相互作用对非酒精性脂肪性肝病的发生和发展有重要影响。胆汁酸主要在肝脏中合成,分泌进入肠道后不仅可以促进脂类物质的消化和吸收,还具有重要的生理信号和代谢调节作用,其能通过参与能量代谢和炎症反应影响非酒精性脂肪性肝病的进程。肠道菌群的代谢产物(如胆汁酸、短链脂肪酸、内生性乙醇和三甲胺等)对宿主的代谢表型、免疫稳态、炎症反应和病程进展等都有重要调节作用。本文主要综述了胆汁酸的合成、转运代谢与肠道菌群结构变化之间的互相作用和对话交流机制,揭示了肠道菌群结构紊乱和胆汁酸代谢异常对非酒精性脂肪性肝病的推动作用,以期为临床上治疗非酒精性脂肪性肝病提供全新的策略和方法。     

Rates of Production of Individual Volatile Fatty Acids in the Rumen of Lactating Cows

The rumen fermentation rates in individual lactating cows were measured in four different experiments. The results disclosed that the amounts and proportions of volatile acids formed could vary widely. In one case, a marked difference in the proportions of the acids produced arose within the experiment and correlated with a difference in the proportion of methane formed.

The average rate of production per day was 10.5 moles butyric acid, 12.8 moles propionic acid, and 40 moles acetic acid. Manometric estimations of rate gave lower results than those obtained by the zero-time method, due to delay after sampling and to failure of the acids to liberate stoichiometric quantities of carbon dioxide.

For those experiments in which zero-time rates were estimated, the average specific absorption rates, i.e., the amount absorbed per hour per micromole of acid in the rumen, were 0.37 for butyric acid, 0.38 for propionic acid, and 0.26 for acetic acid.

The carbon dioxide, acids, and microbial cells produced in the rumen fermentation are estimated to account for about 90% of the carbon found in the milk and respiratory CO₂ of the cows. The carbon dioxide from the fermentation was about 27% of the carbon dioxide exhaled.

     

Hydrogen Profiles and Localization of Methanogenic Activities in the Highly Compartmentalized Hindgut of Soil-Feeding Higher Termites (Cubitermes spp.)

It has been shown that the coexistence of methanogenesis and reductive acetogenesis in the hindgut of the wood-feeding termite Reticulitermes flavipes is based largely on the radial distribution of the respective microbial populations and relatively high hydrogen partial pressures in the gut lumen. Using Clark-type microelectrodes, we showed that the situation in Cubitermes orthognathus and other soil-feeding members of the subfamily Termitinae is different and much more complex. All major compartments of agarose-embedded hindguts were anoxic at the gut center, and high H₂ partial pressures (1 to 10 kPa) in the alkaline anterior region rendered the mixed segment and the third proctodeal segment (P3) significant sources of H₂. Posterior to the P3 segment, however, H₂ concentrations were generally below the detection limit (<100 Pa). All hindgut compartments turned into efficient hydrogen sinks when external H₂ was supplied, but methane was formed mainly in the P3/4a and P4b compartments, and in the latter only when H₂ or formate was added. Addition of H₂ to the gas headspace stimulated CH₄ emission of living termites, indicating that endogenous H₂ production limits methanogenesis also in vivo. At the low H₂ partial pressures in the posterior hindgut, methanogens would most likely outcompete homoacetogens for this electron donor. This might explain the apparent predominance of methanogenesis over reductive acetogenesis in the hindgut of soil-feeding termites, although the presence of homoacetogens in the anterior, highly alkaline region cannot yet be excluded. In addition, the direct contact of anterior and posterior hindgut compartments in situ permits a cross-epithelial transfer of H₂ or formate, which would not only fuel methanogenesis in these compartments, but would also create favorable microniches for reductive acetogenesis. In situ rates and spatial distribution of H₂-dependent acetogenic activities are addressed in a companion paper (A. Tholen and A. Brune, Appl. Environ. Microbiol. 65:4497–4505, 1999).     

Enhancement of Polyunsaturated Fatty Acid Production by Tn5 Transposon in Shewanella baltica

Transposon Tn5 mutagenesis was used to generate random mutations in Shewanella baltica MAC1, a polyunsaturated fatty acid (PUFA)-producing bacterium. Three mutants produced 3–5 times more eicosapentaenoic acid (EPA 20:5 n−3) compared to the wild type at 10°C. One of the mutants produced 0.3 mg EPA g⁻¹ when grown at high temperature (30°C). Moreover, 2 mg docosahexaenoic acid (DHA 22:6 n−3) g⁻¹ was produced by S. baltica mutants at 4°C. Sequencing of insertion mutation(s) showed 96% homology to trimethylamine N-oxide (TMAO) reductase gene and 85% homology to rRNA operons of E. coli. Tn5 transposon mutagenesis therefore is a suitable technique to increase PUFA formation in bacteria.     

Production of Acetic Acid and Other Volatile Compounds by Leuconostoc citrovorum and Leuconostoc dextranicum

Single-strain milk cultures of Leuconostoc dextranicum are capable of reducing added acetaldehyde, propionaldehyde, and butanone to the corresponding alcohols at 30 C. L. dextranicum and L. citrovorum reduced propionaldehyde to n-propanol quantitatively in 30 hr, and the reduction of this compound paralleled culture growth. Under unagitated conditions, these organisms produced large amounts of acetic acid and ethyl alcohol. The yield of acetic acid increased when cultures were agitated during growth. This increase in acetic acid production was accompanied by a 20- to 70-fold decrease in ethyl alcohol. The addition of acetaldehyde to the fermentation caused a reduction in the final concentration of acetic acid.     

Improving Fatty Acid Availability for Bio-Hydrocarbon Production in Escherichia coli by Metabolic Engineering

Previous studies have demonstrated the feasibility of producing fatty-acid-derived hydrocarbons in Escherichia coli. However, product titers and yields remain low. In this work, we demonstrate new methods for improving fatty acid production by modifying central carbon metabolism and storing fatty acids in triacylglycerol. Based on suggestions from a computational model, we deleted seven genes involved in aerobic respiration, mixed-acid fermentation, and glyoxylate bypass (in the order of cyoA, nuoA, ndh, adhE, dld, pta, and iclR) to modify the central carbon metabolic/regulatory networks. These gene deletions led to increased total fatty acids, which were the highest in the mutants containing five or six gene knockouts. Additionally, when two key enzymes in the fatty acid biosynthesis pathway were over-expressed, we observed further increase in strain △cyoA△adhE△nuoA△ndh△pta△dld, leading to 202 mg/g dry cell weight of total fatty acids, ~250% of that in the wild-type strain. Meanwhile, we successfully introduced a triacylglycerol biosynthesis pathway into E. coli through heterologous expression of wax ester synthase/acyl-coenzyme:diacylglycerol acyltransferase (WS/DGAT) enzymes. The added pathway improved both the amount and fuel quality of the fatty acids. These new metabolic engineering strategies are providing promising directions for future investigation.     

Effects of Time and Growth Media on Short-Chain Fatty Acid Production by Bacteroides fragilis

Gas-liquid chromatography was used to monitor the evolution of short chain fatty acids by Bacteroides fragilis in five media. Acetic and succinic acids, the prominent end products encountered, were readily detected within 24 h. Propionic, isobutyric, butyric, isovaleric, and lactic acids were usually recorded in more limited quantities. Maximum rates of bacterial multiplication, glucose catabolism, and end-product production coincided with the first 24 h in carbohydrate-supplemented media. Extended incubation (672 h) favored substantial succinate increases in three of five media. These observations suggest that incubation time and composition of the medium are important determinants in short chain fatty acid production by B. fragilis.     

Localization and In Situ Activities of Homoacetogenic Bacteria in the Highly Compartmentalized Hindgut of Soil-Feeding Higher Termites (Cubitermes spp.)

Methanogenesis and homoacetogenesis occur simultaneously in the hindguts of almost all termites, but the reasons for the apparent predominance of methanogenesis over homoacetogenesis in the hindgut of the humivorous species is not known. We found that in gut homogenates of soil-feeding Cubitermes spp., methanogens outcompete homoacetogens for endogenous reductant. The rates of methanogenesis were always significantly higher than those of reductive acetogenesis, whereas the stimulation of acetogenesis by the addition of exogenous H₂ or formate was more pronounced than that of methanogenesis. In a companion paper, we reported that the anterior gut regions of Cubitermes spp. accumulated hydrogen to high partial pressures, whereas H₂ was always below the detection limit (<100 Pa) in the posterior hindgut, and that all hindgut compartments turned into efficient H₂ sinks when external H₂ was provided (D. Schmitt-Wagner and A. Brune, Appl. Environ. Microbiol. 65:4490–4496, 1999). Using a microinjection technique, we found that only the posterior gut sections P3/4a and P4b, which harbored methanogenic activities, formed labeled acetate from H¹⁴CO₃⁻. Enumeration of methanogenic and homoacetogenic populations in the different gut sections confirmed the coexistence of both metabolic groups in the same compartments. However, the in situ rates of acetogenesis were strongly hydrogen limited; in the P4b section, no activity was detected unless external H₂ was added. Endogenous rates of reductive acetogenesis in isolated guts were about 10-fold lower than the in vivo rates of methanogenesis, but were almost equal when exogenous H₂ was supplied. We conclude that the homoacetogenic populations in the posterior hindgut are supported by either substrates other than H₂ or by a cross-epithelial H₂ transfer from the anterior gut regions, which may create microniches favorable for H₂-dependent acetogenesis.     

Production of Tricarboxylic Acid Anhydrides from Fatty Acids by a Lipase-producing Strain of Pseudomonas cepacia

A lipase-producing strain of Pseudomonas cepacia isolated from a soil sample was found to produce five compounds when oleic acid was added to the culture medium as lipase inducer. The five compounds were isolated by solvent extraction, silicagel column chromatography and preparative HPLC, and their structural elucidation was performed by mass spectrometry, and infrared and nuclear magnetic resonance spectroscopies. The products were identified as dec-3-ene-1,3,4-tricarboxylic acid 3,4-anhydride (product 1 ), undec-3-ene-1,3,4-tricarboxylic acid 3,4-anhydride (product 2 ), dodec-3-ene-I,3,4-tricarboxylic acid 3,4-anhydride (product 3 ), dodec-3,8-diene-1,3,4-tricarboxylic acid 3,4-anhydride (product 4 ) and dodec-3,6-diene-I,3,4-tricarboxylic acid 3,4-anhydride (product 5 ). Accumulation of these compounds in the culture medium started after oleic acid consumption and followed a pattern similar to that found for cell growth and for lipase production. The five compounds were radioactively labeled when [U- 14 C]oleic acid was supplied to the culture medium, thus showing that they were produced by transformation of the acid. When isolated from cultures containing [1,2- 13 C]acetic acid and oleic acid as the sole sources of carbon, the compounds showed to contain the 13 C isotope only in the first five atoms of carbon of the molecule. Several long chain fatty acids also acted as precursors of these compounds, with maximal yields for chain lengths between 11 and 18 atoms of carbon. None of the five compounds acted as lipase inducer when added to the culture medium instead of oleic acid. The compounds showed moderate antibacterial and antifungal activities when tested in solid media bioassays.     

Production of Tricarboxylic Acid Anhydrides from Fatty Acids by a Lipase-producing Strain of Pseudomonas cepacia

A lipase-producing strain of Pseudomonas cepacia isolated from a soil sample was found to produce five compounds when oleic acid was added to the culture medium as lipase inducer. The five compounds were isolated by solvent extraction, silicagel column chromatography and preparative HPLC, and their structural elucidation was performed by mass spectrometry, and infrared and nuclear magnetic resonance spectroscopies. The products were identified as dec-3-ene-1,3,4-tricarboxylic acid 3,4-anhydride (product 1 ), undec-3-ene-1,3,4-tricarboxylic acid 3,4-anhydride (product 2 ), dodec-3-ene-I,3,4-tricarboxylic acid 3,4-anhydride (product 3 ), dodec-3,8-diene-1,3,4-tricarboxylic acid 3,4-anhydride (product 4 ) and dodec-3,6-diene-I,3,4-tricarboxylic acid 3,4-anhydride (product 5 ). Accumulation of these compounds in the culture medium started after oleic acid consumption and followed a pattern similar to that found for cell growth and for lipase production. The five compounds were radioactively labeled when [U- 14 C]oleic acid was supplied to the culture medium, thus showing that they were produced by transformation of the acid. When isolated from cultures containing [1,2- 13 C]acetic acid and oleic acid as the sole sources of carbon, the compounds showed to contain the 13 C isotope only in the first five atoms of carbon of the molecule. Several long chain fatty acids also acted as precursors of these compounds, with maximal yields for chain lengths between 11 and 18 atoms of carbon. None of the five compounds acted as lipase inducer when added to the culture medium instead of oleic acid. The compounds showed moderate antibacterial and antifungal activities when tested in solid media bioassays.