A novel isolate of <Emphasis Type="Italic">Clostridium butyricum</Emphasis> for efficient butyric acid production by xylose fermentation

Bacterial fermentation of lignocellulose has been regarded as a sustainable approach to butyric acid production. However, the yield of butyric acid is hindered by the conversion efficiency of hydrolysate xylose. A mesophilic alkaline-tolerant strain designated as Clostridium butyricum B10 was isolated by xylose fermentation with acetic and butyric acids as the principal liquid products. To enhance butyric acid production, performance of the strain in batch fermentation was evaluated with various temperatures (20–47 °C), initial pH (5.0–10.0), and xylose concentration (6–20 g/L). The results showed that the optimal temperature, initial pH, and xylose concentration for butyric acid production were 37 °C, 9.0, and 8.00 g/L, respectively. Under the optimal condition, the yield and specific yield of butyric acid reached about 2.58 g/L and 0.36 g/g xylose, respectively, with 75.00% butyric acid in the total volatile fatty acids. As renewable energy, hydrogen was also collected from the xylose fermentation with a yield of about 73.86 mmol/L. The kinetics of growth and product formation indicated that the maximal cell growth rate (μ _m ) and the specific butyric acid yield were 0.1466 h^?1 and 3.6274 g/g cell (dry weight), respectively. The better performance in xylose fermentation showed C. butyricum B10 a potential application in efficient butyric acid production from lignocellulose.     

Growth and pectate-lyase activity of the ruminal bacterium Lachnospira multiparus in the presence of short-chain organic acids

AIMS: Acetic, propionic, butyric and lactic acids are end products of feed fermentation by rumen microbes. The effects of these short chain acids on growth and pectate-lyase (PL) activity of Lachnospira multiparus were studied. METHODS AND RESULTS: The bacterial strain used was L. multiparus D32. Acids were tested between 50 and 300 mmol l(-1). Growth and PL activity were measured by the increase in total protein content and by the increase in absorbance at 235 nm in the reaction medium respectively. With the exception of lactic acid, all acids decreased bacterial growth rates; generally, these effects were more pronounced at higher concentrations and with acids of longer chains. PL activity was inhibited by all the acids except by butyric acid at 50 and 100 mmol l(-1). Enzyme inhibition increased with the concentrations of the acids and lactic acid was the most inhibitory. CONCLUSIONS: High concentrations of short chain acids can differentially inhibit the growth rate and the PL activity of L. multiparus. SIGNIFICANCE AND IMPACT OF THE STUDY: Products of fermentation generated by the ruminal microbiota could modify the degradation of pectic substances by this bacterium.     

Regulation of acetate kinase and butyrate kinase by acids in Clostridium acetobutylicum

Abstract The effects of acetic acid and butyric acid on acetate kinase, butyrate kinase and acetoacetate decarboxylase levels are studied. It is shown that acetate kinase biosynthesis is regulated by acetic acid whereas butyric acid has no effect. Acetate kinase specific activity is found to be maximal at the beginning of the fermentation, and decreases as acetic acid concentration increases in the medium. Butyrate kinase is not regulated by the end-product acids; its specific activity is constant during the fermentation. In the presence of acetic acid, acetoacetate decarboxylase biosynthesis represents a 4-fold increase in activity over a culture without acetate and a 1.7-fold increase over that obtained in presence of butyrate. The technique of fermentation used allows us to show that bacterial growth and solventogenesis may occur simultaneously.     

Effects of butyric and acetic acids on acetone-butanol formation by Clostridium acetobutylicum

The actions of butyric and acetic acids on acetone-butanol fermentation are investigated. Production of butyric and acetic acids are controlled by the extracellular concentrations of both acids: acetic acid added to the medium inhibits its own formation but has no effect on butyric acid formation, and added butyric acid inhibits its own formation but not that of acetic acid. The ratio of end metabolites depends upon acetic and butyric acid quantities excreted during the fermentation. In contrast to acetic acid, which specifically increases acetone formation, butyric acid increases both acetone and butanol formations. Acetate and butyrate kinase activities were also examined. Both increase at the start of fermentation and decrease when solvents appear in the medium. Coenzyme A transferase activity is weak in the acidogenic phase and markedly increases in the solvent phase. Acetic and butyric acids appear to be co-substrates. On the basis of these results, a mechanism of acetic and butyric acid pathways, coupled to solvent formation by C. acetobutylicum glucose fermentation is proposed.     

Effects of extractive fermentation on butyric acid production byClostridium acetobutylicum

Summary The addition of an oleyl alcohol extractant to a batch fermentation of glucose byClostridium acetobutylicum resulted in a concentration profile that was distinctly different from the non-extractive control fermentation. The concentration of butyric acid increased and subsequently decreased in the control fermentation. The concentration of butyric acid increased but did not subsequently decrease in the oleyl alcohol extractive fermentation. The production of butyric acid was found to have been prolonged into the solventogenic phase in the oleyl alcohol extractive fermentation. Butyric acid was continually replenished from glucose while it was being converted to butanol. Supplementation of exogenous acetic and butyric acids, the metabolic uncoupler carbonyl cyanide 3-chlorophenylhydrazone, or decanol to the oleyl alcohol extractive fermentation helped to reinstate the normal butyric acid concentration profile. These findings are discussed with respect to the effects of these additives on the pH ofC. acetobutylicum and its importance with regard to the production of butyric acid.     

Biocatalytic reduction of short‐chain carboxylic acids into their corresponding alcohols with syngas fermentation

Short‐chain carboxylic acids generated by various mixed‐ or pure‐culture fermentation processes have been considered valuable precursors for production of bioalcohols. While conversion of carboxylic acids into alcohols is routinely performed with catalytic hydrogenation or with strong chemical reducing agents, here, a biological conversion route was explored. The potential of carboxydotrophic bacteria, such as Clostridium ljungdahlii and Clostridium ragsdalei, as biocatalysts for conversion of short‐chain carboxylic acids into alcohols, using syngas as a source of electrons and energy is demonstrated. Acetic acid, propionic acid, n‐butyric acid, isobutyric acid, n‐valeric acid, and n‐caproic acid were converted into their corresponding alcohols. Furthermore, biomass yields and fermentation stoichiometry from the experimental data were modeled to determine how much metabolic energy C. ljungdahlii generated during syngas fermentation. An ATP yield of 0.4–0.5 mol of ATP per mol CO consumed was calculated in the presence of hydrogen. The ratio of protons pumped across the cell membrane versus electrons transferred from ferredoxin to NAD⁺ via the Rnf complex is suggested to be 1.0. Based on these results, we provide suggestions how n‐butyric acid to n‐butanol conversion via syngas fermentation can be further improved. Biotechnol. Bioeng. 2013; 110: 1066–1077. © 2012 Wiley Periodicals, Inc.     

Activity and identity of fermenting microorganisms in full-scale biological nutrient removing wastewater treatment plants

Hydrolysis and fermentation are of key importance in biological nutrient removal (BNR) wastewater treatment plants as they provide polyphosphate-accumulating organisms and denitrifying bacteria with carbon and energy sources (e.g. short chain fatty acids). Little information, however, exists about the microbiology of the microorganisms involved in hydrolysis and fermentation. In this study, fermentation of monosaccharides was found to be a universal process taking place in all full-scale BNR plants investigated, where glucose and other monosaccharides were consumed and fermented during anaerobic conditions. The removal rates of glucose were in the range of 0.05–0.32 mmol gVSS⁻¹ h⁻¹ and only slightly lower than glucose removal under aerobic conditions. The main fermentation products detected were (in descending order) propionic acid, lactic acid, acetic acid and formic acid. The fermentation was diverse, consisting of at least three fermentation metabolisms, including lactic acid (homolactic), mixed acid and propionic acid fermentations. Possible existence of alcohol and/or butyric acid fermentations could not be excluded. Fermentation organisms in Aalborg East treatment plant were identified by using microautoradiography combined with fluorescence in situ hybridization. All microorganisms involved in monosaccharide fermentation belonged to either Gram-positive Firmicutes or Actinobacteria . Most of them were related either to Streptococcus , hybridizing to the oligonucleotide probe Str, or to uncultured Actinobacteria with a phenotype of polyphosphate-accumulating organisms. The fermenting bacteria were widespread in the nine full-scale BNR plants investigated and constituted 3–21% of the total bacterial biovolume.     

Anaerobic digestion: microbial and biochemical aspects of volatile acid production

Summary The production of organic acids has been tested with bacterial flora selected from a municipal sludge digestor. In order to elucidate the basic mechanisms by which glucose is converted to volatile fatty acids, the examination of non-methanogenic bacteria was attempted. Both lactate-producers and lactate-utilizers were found among these bacteria. When mixed isolates were used as the inoculum, the accumulation of lactic acid and its further conversion to propionic and butyric acids was demonstrated at a carbon conversion rate of about 0.75. It is therefore suggested that this metabolic sequence may occur as a normal process in acidogenic fermentation, which is the first step in anaerobic digestion.     

Solvent production byClostridium pasteurianum in media of high sugar content

Summary The fermentation end products ofClostridium pasteurianum ATCC 6013 are normally acetic and butyric acids. When grown in media of high sugar content however, significant quantities of solvents (acetone, butanol and ethanol) were produced. Solvent production was not stimulated by added acetic and butyric acids, nor was the effect due to a low water activity of the mediumper se.     

Improvements of metabolites tolerance in <Emphasis Type="Italic">Clostridium acetobutylicum</Emphasis> by micronutrient zinc supplementation

Micronutrient zinc is of great importance for acetone-butanol-ethanol (ABE) fermentation by Clostridium acetobutylicum. The effect of zinc supplementation on toxic metabolites (formic, acetic, butyric acid and butanol) tolerance during ABE fermentation was investigated under various stress-shock conditions without pH control. Great improvements on cell growth, glucose utilization and butanol production were achieved. In the presence of 0.45 g/L formic acid, zinc contributed to 11.28 g/L butanol produced from 55.24 g/L glucose compared to only 5.27 g/L butanol from 29.49 g/L glucose in the control without zinc supplementation. More importantly, relatively higher levels of 7.5 g/L acetic acid, 5.5 g/L butyric acid and 18 g/L butanol could be tolerated by C. acetobutylicum with zinc supplementation while no fermentation was observed under the same stress-shock condition respectively, suggesting that the acids and butanol tolerance in C. acetobutylicum could be significantly facilitated by pleiotropic regulation of micronutrient zinc. Thus, this paper provides an efficient bioprocess engineering strategy for improving stress tolerance in Clostridium species.     

Ethyl esterification of long-chain unsaturated fatty acids derived from grape must by yeast during alcoholic fermentation

The composition of total fatty acid ethyl ester (FAEE) in yeast cells and the liquid phase separated from grape must during alcoholic fermentation at different temperatures was investigated by using the solid-phase extraction method. Thirteen FAEE from butyric to linolenic acids were detected during fermentation. Significant amounts of long-chain unsaturated FAEE, including linoleic and linolenic acids derived from grape material, had already accumulated in the yeast cells by day 3 during fermentation.     

Modulation of Acetone-Butanol-Ethanol Fermentation by Carbon Monoxide and Organic Acids

Metabolic modulation of acetone-butanol-ethanol fermentation by Clostridium acetobutylicum with carbon monoxide (CO) and organic acids is described. CO, which is a known inhibitor of hydrogenase, was found to be effective in the concentration range of dissolved CO corresponding to a CO partial pressure of 0.1 to 0.2 atm. Metabolic modulation by CO was particularly effective when organic acids such as acetic and butyric acids were added to the fermentation as electron sinks. The uptake of organic acids was enhanced, and increases in butyric acid uptake by 50 to 200% over control were observed. Hydrogen production could be reduced by 50% and the ratio of solvents could be controlled by CO modulation and organic acid addition. Acetone production could be eliminated if desired. Butanol yield could be increased by 10 to 15%. Total solvent yield could be increased 1 to 3% and the electron efficiency to acetone-butanol-ethanol solvents could be increased from 73 to 78% for controls to 80 to 85% for CO- and organic acid-modulated fermentations. Based on these results, the dynamic nature of electron flow in this fermentation has been elucidated and mechanisms for metabolic control have been hypothesized.     

Characterization of anaerobic microbial culture with high acidogenic activity

The mixed cultures which were used were isolated from municipal sludge digesters, and the production of organic acids (acetic, propionic, butyric, etc.) from carbohydrates was tested. The behavior of the reference population (culture R) obtained directly from the sewage treatment plant, is compared to that obtained after three months in a plug-flow reactor (Gradostat fermentor) without pH control (culture A) and after six months with pH control (culture B). For culture B, the specific rate of acid production is related to the cell growth rate by (1/X)r_p= 17 µ + 1.6 with a maximal acid concentration of 40 g/liter. The batch culture yields are improved from 0.36g/g for the initial culture (R) to 0.72 g/g for culture B after six months in continuous culture, and 0.8 g/g in plug-flow continuous culture. The productivity of organic acids reaches 1.7 g/liter·hr. It is suggested that the acidogenic fermentation, the first step of methanogenesis, is a potential process to produce acetic, propionic, and butyric acids.     

The effect of applying lactic bacteria at ensilage on the chemical and microbiological composition of vetch, wheat and alfalfa silages

The effect of applying a commercial lactic acid bacterial inoculant, at 5.6 × 10⁴ cfu/g fresh material, to vetch, wheat, direct-cut and wilted alfalfa silages has been studied under laboratory conditions, and on wheat also under farm conditions. Dry matter losses in the inoculated vetch and alfalfa silages were smaller than in the control silages, due to improved fermentation in the former as indicated by a faster and larger pH decrease and by a faster and larger lactic acid build-up. Volatile fatty acid analysis also indicated more efficient fermentation patterns in the inoculated vetch and alfalfa silages with less ethanol, acetic and butyric acids compared with the respective control silages. The inoculant suppressed enterobacteria and clostridia in the inoculated direct-cut alfalfa silage. The inoculant did not have a great effect on the wheat silages.     

Effects of hybrid,kernel maturity,and storage period on the bacterial community in high-moisture and rehydrated corn grain silages

This study evaluated changes in the bacterial community in high-moisture and rehydrated corn grain silage, and their correlation with fermentation quality attributes in distinct corn hybrids, the storage period, and kernel maturity at plant harvest. Most silages achieved good fermentation (pH < 4.2). Rehydrated corn had a higher pH across all storage periods evaluated and increased dry matter losses. Leuconostoc and Lactococcus were the dominant genera in fresh material, while Lactobacillus and Acetobacter were prevalent in silages. Clostridium and Enterococcus prevailed in rehydrated corn after 120 days storage, and Clostridium was highly and positively correlated with acetone, butyric acid, and 2,3-butanediol contents. The storage period and kernel maturity were the most important factors responsible for changes in the bacterial community of silages. Results confirmed the existence of a specific bacterial microbiome that was unique for each maturity and storage time. Variations in these factors also affected the fermentation quality through influencing the bacterial community.     

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.

     

接种固定化粪菌和培养基种类对体外结肠菌群发酵的影响

目的研究三种模拟结肠发酵培养基和粪菌固定化对体外结肠发酵体系菌群构成的影响,为建立高度模拟结肠体外结肠发酵提供参考。方法采集健康女性成人粪便,粪便制备悬液或用结冷胶-黄原胶固定化粪菌接种于模拟结肠发酵反应器,分别用三种培养基按0.07 m L/h稀释率进行连续发酵10 d,用末端限制性片段长度多态性(T-RFLP)与高通量测序技术分析菌群多样性,并分析发酵液短链脂肪酸含量。结果 T-RFLP分析显示,培养基类型主要影响粪菌固定体系菌群α多样性达到稳定的时间和多样性。β多样性分析显示,第10天时培养基Ⅲ悬液培养和培养基I固定化培养系统的菌群构成与粪便菌群最相近。而培养基Ⅲ在第10天达到较高而稳定的丁酸浓度。结论由于比粪菌固定培养更易操作,培养基Ⅲ悬液培养适于模拟人结肠发酵。     

On-line extraction of volatile fatty acids in acidogenic chemostat culture using a supported liquid membrane

An on-line extraction of volatile fatty acids (acetic and butyric acids) from acidogenic fermentation in chemostat cultures using a supported liquid membrane (SLM) was investigated in order to overcome end-product inhibition. By using SLM, the high-cell-density retaining dilution rate of the chemostat could be increased, thus enhancing the microbial acidogenesis. To further understand this phenomenon, the growth and extraction kinetics were studied. The effect of substrate concentration was found to obey the Haldane equation. Regarding the inhibition by volatile fatty acids, it turned out that undissociated butyric acid rather than acetic acid severely inhibited the growth, corresponding to non-competitive kinetics. The extraction rates of the acids were proportional to their undissociated concentration as well as to the SLM area/broth volume, and butyric acid extraction was easier than that of acetic acid.     

Evaluation of native potential probiotic bacteria using an in vitro ruminal fermentation system

Rumen microbiota provides an important source of protein to grazing animals and produces volatile fatty acids (VFA), the main energy source for ruminants generated by fibre fermentation. Probiotics can be used to modulate rumen fermentation, and native microbiota is a source of potentially useful microorganisms. In this work, ruminal bacterial strains were isolated and subsequently identified, and their potential to modify fermentation patterns with wheat straw, microcrystalline cellulose and oat xylan as substrates was assessed by in vitro gas production and VFA fermentation patterns. Four of the isolates were identified as Pseudobutyrivibrio ruminis and two corresponded to new members of the Lachnospiraceae family. The addition of one P. ruminis (strain 50C) and one Lachnospiraceae (strain 21C) to the fermentation system which used wheat straw as the substrate significantly increased total VFA concentration without altering the total gas produced in one case and showed a decrease in total gas production in the other. All bacterial strains induced higher butyric acid concentrations with the three substrates (up to 31 mM in the case of Lachnospiraceae 21C incubated with oat xylan and 25 mM in microcrystalline cellulose fermenters to which P. ruminis 50C had been added) compared to the control, which had concentrations of <1 mM. Analysis of the fermentation products suggested that the addition of probiotics to the fermentation system had the potential to induce metabolic shifts that would result in better energy yields. These results show that native bacteria have promising features as fermentation modulators, thereby justifying further research to assess their use as probiotics for ruminants.     

Factors influencing cell fatty acid composition and A40926 antibiotic complex production in <Emphasis Type="Italic">Nonomuraea</Emphasis> sp. ATCC 39727

A40926 is a glycopeptide antibiotic complex consisting of several structurally related factors. It is produced by fermentation of Nonomuraea sp. ATCC 39727 and the complex components differ in the structure of the fatty acid moiety linked to the aminoglucuronic acid unit. In previous work, we observed that the production of single factors in glycopeptide antibiotic complexes could be selectively enhanced by the addition of suitable precursors to the culture medium. In this contribution, we examine the effects of branched amino acid addition to fermentation of Nonomuraea sp. in a chemically defined minimal medium. The changes in the composition of cell fatty acids correlate to the fatty acid distribution within the A40926 complex in diverse cultivation conditions. Nonomuraea sp. prefers isobutyric, butyric and propionic acids as initiators of fatty acid biosynthesis. The relative amount of the produced fatty acids is significantly influenced by the availability of intermediates or final products from the amino acid catabolic pathways. Antibiotic complex composition closely reflects the cell fatty acid pattern, in agreement with the assumption that the antibiotic fatty acid moieties are synthesized by shortening the chain of cell fatty acids.