Enhancement of phase separation by the addition of de-emulsifiers to three-phase (diesel oil/biocatalyst/aqueous phase) emulsion in diesel biodesulfurization

Ethanol, added as a de-emulsifier to separate oil and biocatalyst (or bacterial cells) from a three-phase (oil/biocatalyst/aqueous phase) emulsion, formed in diesel biodesulfurization employing Gordonia nitida, improved oil recovery by centrifugation from about 50% in its absence to almost 100% at 3% (v/v). The biocatalyst recovered with ethanol addition showed similar specific growth rates (0.03 h^–1) and dibenzothiophene desulfurization rates (6–7.2 mol l^–1 h^–1) to those (0.03 h^–1 and 7.1 mol l^–1, respectively) of the biocatalyst recovered with no ethanol addition. The desulfurization activity significantly increased as the number of the repeated recovery and reuse of the biocatalyst.     

The acetoin assimilation pathway of Pseudomonas putida KT2440 is regulated by overlapping global regulatory elements that respond to nutritional cues

Many microorganisms produce and excrete acetoin (3-hydroxy-2-butanone) when growing in environments that contain glucose or other fermentable carbon sources. This excreted compound can then be assimilated by other bacterial species such as pseudomonads. This work shows that acetoin is not a preferred carbon source of Pseudomonas putida, and that the induction of genes required for its assimilation is down-modulated by different, independent, global regulatory systems when succinate, glucose or components of the LB medium are also present. The expression of the acetoin degradation genes was found to rely on the RpoN alternative sigma factor and to be modulated by the Crc/Hfq, Cyo and PTS^Ntr regulatory elements, with the impact of the latter three varying according to the carbon source present in addition to acetoin. Pyruvate, a poor carbon source for P. putida, did not repress acetoin assimilation. Indeed, the presence of acetoin significantly improved growth on pyruvate, revealing these compounds to have a synergistic effect. This would provide a clear competitive advantage to P. putida when growing in environments in which all the preferred carbon sources have been depleted and pyruvate and acetoin remain as leftovers from the fermentation of sugars by other microorganisms.     

Fermentation of Xylan,Corn Fiber,or Sugars to Acetoin and Butanediol by Bacillus polymyxa Strains

Bacillus polymyxa can produce levo-butanediol, a potential biogradable anti-freeze, and ethanol, a fuel additive, using starch-based fermentations. To explore use of less expensive biomass fermentation substrates, we screened B. polymyxa strains for good growth on xylans. During aerobic growth on glucose, six selected xylanolytic strains produced mainly acetoin and butanediol plus lesser amounts of acetaldehyde and ethanol. Undesirable acetoin formation was eliminated by anaerobic growth on glucose, but substrate usage, butanediol, and other fermentation products were greatly reduced. High xylanase activity occurred with growth on xylans or corn fiber, and about 50–65% of oatspelt xylan and 25–35% of the corn fiber were used during aerobic growth, but unexpectedly no butanediol and only small levels of acetoin were produced. Aerobic growth on arabinose, arabinose plus glucose, or xylose plus glucose resulted in both acetoin and butanediol formation. Little or no butanediol was made from xylose alone. Growth on an acid hydrolysate of corn fiber that contained a mixture of these sugars resulted in the formation of acetoin, acetaldehyde, and ethanol, but very little butanediol. The data suggest B. polymyxa is limited in conversion of xylan-rich biomass sources or their hydrolysates to butanediol. This limitation might be overcome by using better cultivation conditions and/or genetically engineered strains.     

Isolation and identification of an acetoin high production bacterium that can reverse transform 2,3-butanediol to acetoin at the decline phase of fermentation

Acetoin (3-hydroxy-2-butanone), a very popular food spice is now used in many industries (pharmaceuticals, chemicals, paint, etc.). In this study, an acetoin high producing strain, numbered as JNA-310, was newly isolated and identified as Bacillus subtilis which is safe on food industry, based on its physiological, biological tests and 16S rDNA sequence analysis. When glucose was used as carbon source in fermentation, the fermentation characterizations of this strain were analyzed, and a new phenomenon of reverse transforming 2,3-butanediol which was synthesized from glucose in the fermentation broth to acetoin was detected. Before 96 h, glucose which was mainly transformed to 2,3-butanediol and acetoin was totally consumed, and the yield of the two products were 41.7 and 21.0 g/l respectively. Acetoin was only a by product in the fermentation broth at prophase of fermentation. At the end of fermentation, the yield of acetoin was greatly improved and the yield of 2,3-butanediol was declined and the yield of them were about 42.2 and 15.8 g/l, respectively. The results indicated that 2,3-butanediol was reversely transformed to acetoin.     

Fermentative production of chiral acetoin by wild-type Bacillus strains

Abstract

In recent years, there have been many studies on producing acetoin by microbial fermentation, while only a few studies have focused on chiral acetoin biosynthesis. The weight assignment method was first applied to balance the chiral purity (expressed as the enantiomeric excess value) and the titer of acetoin. Bacillus sp. H-18W, a thermophile, was selected from seven Bacillus strains for chiral acetoin production. To lower the cost of the fermentation medium, soybean meal was used as a feedstock. Four kinds of frequently used commercial proteinases with different active sites were tested for the hydrolyzation of the soybean meal, and the combination of the acidic proteinase and the neutral proteinase showed the best results. In a fermentation medium containing 100?g L^?1 glucose and 200?g L^?1 hydrolysate, Bacillus sp. H-18W produced 21.84?g L^?1 acetoin with an ee value of 96.25% at 60?h. This is the first report of using a thermophilic strain to produce chiral acetoin by microbial fermentation. Thermophilic fermentation can reduce the risk of bacterial contamination and can save cooling water. Using soybean meal hydrolysate and glucose as feedstocks, this work provides an economical and alternative method for the production of chiral pure acetoin.     

Enhanced production of acetoin and butanediol in recombinant Enterobacter aerogenes carrying Vitreoscilla hemoglobin gene

Microbial production of butanediol and acetoin has received increasing interest because of their diverse potential practical uses. Although both products are fermentative in nature, their optimal production requires a low level of oxygen. In this study, the use of a recombinant oxygen uptake system on production of these metabolites was investigated. Enterobacter aerogenes was transformed with a pUC8-based plasmid carrying the gene (vgb) encoding Vitreoscilla (bacterial) hemoglobin (VHb). The presence of vgb and production of VHb by this strain resulted in an increase in viability from 72 to 96 h in culture, but no overall increase in cell mass. Accumulation of the fermentation products acetoin and butanediol were enhanced (up to 83%) by the presence of vgb/VHb. This vgb/VHb related effect appears to be due to an increase of flux through the acetoin/butanediol pathway, but not at the expense of acid production.     

Enzymatic regulation of glucose catabolism by Lactobacillus plantarum in response to pH shifts in a chemostat

Summary The influence of medium pH on the regulation of glucose catabolism by Lactobacillus plantarum 8014 was examined in anaerobic chemostat cultures. When L. plantarum was grown in a chemostat at pH 5.5, and the pH shifted to pH 7.5, acetate was produced in addition to lactate and acetoin. After the shift, acetate kinase and NAD-dependent lactate dehydrogenase activities increased while the acetoin dehydrogenase and alpha-acetolactate synthase activities decreased. The high acetate kinase activity together with low acetoin dehydrogenase and alpha-acetolactate synthase activities may explain why L. plantarum made more acetate at the expense of acetoin in response to alkaline conditions.Offprint requests to: T.J. Montville     

pH-mediated regulation of pyruvate catabolism inLactobacillus plantarum chemostat cultures

Summary While the ability of lactobacilli to catabolize pyruvate to a variety of industrially important catabolites is well known, the mechanisms which regulate pyruvate distribution among alternative catabolic pathways is unclear. This paper demonstrates that environmental acidity regulates the catabolic activities ofLactobacillus plantarum cells in chemostat cultures.L. plantarum cells grown in medium containing 100 mM exogenous pyruvate, diverted pyruvate away from lactate to acetoin. Pyruvate uptake and acetoin generation increased under acidic conditions; on a molar basis, pyruvate utilization increased twice as fast as acetoin production, reflecting the 21 stoichiometry of pyruvate incorporation into acetoin. Lactate production increased under alkaline conditions when glucose was fermented to provide endogenous pyruvate. Acetate was formed only at pH 7.5 and 8.0, although acetoin production decreased at elevated pH values. These data indicate thatL. plantarum adjusts to changes in environmental pH by altering its distribution of pyruvate among various catabolites.     

Diacetyl production and growth of Lactobacillus rhamnosus on multiple substrates

Lactobacillus rhamnosus is a heterolactic acid bacterium, which can be used to produce flavour compounds like diacetyl and acetoin. Various startegies have been applied to improve the growth rate and diacetyl yield. The use of multiple substrates affected growth as well as the yield of diacetyl. Growth on a medium containing glucose demonstrated a diauxic growth profile, with the second phase of growth being on the product, lactic acid. L. rhamnosus also grew on a medium containing citrate. Growth on medium containing glucose+citrate demonstrated simultaneous utilization of carbon sources. L. rhamnosus did not grow in a medium containing acetate and also did not co-metabolize it with glucose. Maximum specific growth rate ( _max) was found to increase in the case of simultaneous utilization of glucose+citrate (0.38 h^–1) as compared to glucose as the sole carbon source (0.28 h^–1). The yields of diacetyl were also found to increase for glucose + pyruvate and glucose + citrate (0.10 and 0.05 g g^–1 of glucose, respectively) as compared to glucose alone (0.01 g g^–1 of glucose). The productivity of diacetyl on medium containing glucose and citrate was double that of a medium containing only citrate, although the yields were comparable.     

Effect of deletion of 2,3-butanediol dehydrogenase gene (bdhA) on acetoin production of Bacillus subtilis

The present work aims to block 2,3-butanediol synthesis in acetoin fermentation of Bacillus subtilis. First, we constructed a recombinant strain BS168D by deleting the 2,3-butanediol dehydrogenase gene bdhA of the B. subtilis168, and there was almost no 2,3-butanediol production in 20?g/L of glucose media. The acetoin yield of BS168D reached 6.61?g/L, which was about 1.5 times higher than that of the control B. subtilis168 (4.47?g/L). Then, when the glucose concentration was increased to 100?g/L, the acetoin yield reached 24.6?g/L, but 2.4?g/L of 2,3-butanediol was detected at the end of fermentation. The analysis of 2,3-butanediol chiral structure indicated that the main 2,3-butanediol production of BS168D was meso-2,3-butanediol, and the bdhA gene was only responsible for (2R,3R)-2,3-butanediol synthesis. Therefore, we speculated that there may exit another pathway relating to the meso-2,3-butanediol synthesis in the B. subtilis. In addition, the results of low oxygen condition fermentation showed that deletion of bdhA gene successfully blocked the reversible transformation between acetoin and 2,3-butanediol and eliminated the effect of dissolved oxygen on the transformation.     

Effect of varying citrate levels on C4 compound formation and on enzyme levels in Leuconostoc mesenteroides subsp. cremoris grown in continuous culture

Summary The effects of citrate on diacetyl, acetoin and 2,3-butylene glycol (2,3-BG) production by Leuconostoc mesenteroides subsp. cremoris grown in continuous culture at pH 5.2 were studied. In glucose alone end-product production agreed with the theoretical stoichiometry. In the presence of citrate, lactate and acetate production was higher than the theoretical stoichiometry from glucose. Lactate production was constant when the initial citrate concentration was increased whereas ethanol production strongly decreased. In the absence of citrate, citrate lyase (CL) exhibited weak activity. Diacetyl reductase (DR) and acetoin reductase (AR) exhibited basal activity. When varying citrate concentrations ranging from 10 to 75 mm were added to glucose broth, DR, AR, lactate dehydrogenase, NADH oxidase and alcohol dehydrogenase decreased as the initial citrate concentration increased suggesting that they were partly repressed by citrate. In contrast, CL increased and the specific citrate utilization rate also increased in the same way, indicating no saturation of the first step of citrate metabolism. Acetate kinase (AK) was slightly higher in the presence of citrate and increased when the initial citrate concentration increased. This result was correlated with an increase of acetate from the acetyl phosphate pathway. More ATP was produced in the presence of citrate, which could explain the increase in biomass formation. Citrate bioconversion into diacetyl, acetoin and 2,3-BG increased as the initial citrate increased. Correspondence to: C. Diviès     

Escherichia coli aceE variants coding pyruvate dehydrogenase improve the generation of pyruvate-derived acetoin

Several chromosomally expressed AceE variants were constructed in Escherichia coli ΔldhA ΔpoxB ΔppsA and compared using glucose as the sole carbon source. These variants were examined in shake flask cultures for growth rate, pyruvate accumulation, and acetoin production via heterologous expression of the budA and budB genes from Enterobacter cloacae ssp. dissolvens. The best acetoin-producing strains were subsequently studied in controlled batch culture at the one-liter scale. PDH variant strains attained up to four-fold greater acetoin than the strain expressing the wild-type PDH. In a repeated batch process, the H106V PDH variant strain attained over 43 g/L of pyruvate-derived products, acetoin (38.5 g/L) and 2R,3R-butanediol (5.0 g/L), corresponding to an effective concentration of 59 g/L considering the dilution. The acetoin yield from glucose was 0.29 g/g with a volumetric productivity of 0.9 g/L·h (0.34 g/g and 1.0 g/L·h total products). The results demonstrate a new tool in pathway engineering, the modification of a key metabolic enzyme to improve the formation of a product via a kinetically slow, introduced pathway. Direct modification of the pathway enzyme offers an alternative to promoter engineering in cases where the promoter is involved in a complex regulatory network.     

Diacetyl and acetoin production from whey permeate using engineered <Emphasis Type="Italic">Lactobacillus casei</Emphasis>

The capability of Lactobacillus casei to produce the flavor-related compounds diacetyl and acetoin from whey permeate has been examined by a metabolic engineering approach. An L. casei strain in which the ilvBN genes from Lactococcus lactis, encoding acetohydroxyacid synthase, were expressed from the lactose operon was mutated in the lactate dehydrogenase gene (ldh) and in the pdhC gene, which codes for the E2 subunit of the pyruvate dehydrogenase complex. The introduction of these mutations resulted in an increased capacity to synthesize diacetyl/acetoin from lactose in whey permeate (1,400 mg/l at pH 5.5). The results showed that L. casei can be manipulated to synthesize added-value metabolites from dairy industry by-products.     

Artificial consortium that produces riboflavin regulates distribution of acetoin and 2,3‐butanediol by Paenibacillus polymyxa CJX518

The introduction of an NADH/NAD⁺ regeneration system can regulate the distribution between acetoin and 2,3‐butanediol. NADH regeneration can also enhance butanol production in coculture fermentation. In this work, a novel artificial consortium of Paenibacillus polymyxa CJX518 and recombinant Escherichia coli LS02T that produces riboflavin (VB₂) was used to regulate the NADH/NAD⁺ ratio and, consequently, the distribution of acetoin and 2,3‐butanediol by P. polymyxa. Compared with a pure culture of P. polymyxa, the level of acetoin was increased 76.7% in the P. polymyxa and recombinant E. coli coculture. Meanwhile, the maximum production and yield of acetoin in an artificial consortium with fed‐batch fermentation were 57.2 g/L and 0.4 g/g glucose, respectively. Additionally, the VB₂ production of recombinant E. coli could maintain a relatively low NADH/NAD⁺ ratio by changing NADH dehydrogenase activity. It was also found that 2,3‐butanediol dehydrogenase activity was enhanced and improved acetoin production by the addition of exogenous VB₂ or by being in the artificial consortium that produces VB₂. These results illustrate that the coculture of P. polymyxa and recombinant E. coli has enormous potential to improve acetoin production. It was also a novel strategy to regulate the NADH/NAD⁺ ratio to improve the acetoin production of P. polymyxa.     

Fermentation of cinnamate by a mesophilic strict anaerobe,Acetivibrio multivorans sp. nov.

A cinnamate-fermenting bacterium (strain PeC1) was isolated in pure culture from anoxic sludge of an oil refinery wastewater treatment facility. It was a mesophilic gram-negative non-sporing actively motile rod. It did not reduce nitrate, sulfte, or other sulfur compounds as electron acceptors. It fermented cinnamate to 3-phenylpropionate, benzoate, and acetate; crotonate to butyrate and acetate; pyruvate to lactate and acetate; acetoin to ethanol and acetate; and carbohydrates to ethanol, formate, and acetate. The DNA base ratio of the strain was 44 mol% guanine plus cytosine. It is described as a new species of the genus Acetivibrio, A. multivorans sp. nov.     

Production of Acetylacetoin by Bacterial Fermentation

Bacillus sp. YUF-4 did not produce acetylacetoin with general culture media, such as bouillon medium containing glucose or acetoin. When diacetyl was added to a medium cultured for 18–20 h in the presence of glucose or acetoin, AAC was produced as culture continued. AAC was assayed by GLC with a Carbowax 20M capillary column. The AAC produced was purified by several steps: the final HPLC using a Shodex E411 column was effective. The yield of AAC was 346 mg per liter of the medium (7.5% recovery) and the purity was 97%. AAC was identified by ¹H-NMR and ¹³C-NMR.     

Acetoin production in growing Leuconostoc mesenteroides

Leuconostoc mesenteroides NCDO 518, provided with oxygen and pyruvate, preferentially used oxygen as accessory electron acceptor and converted pyruvate to acetoin. With glucose, 5.6 mM, as sole energy source only small amounts of acetoin were formed (0.08–0.21 mM). With glucose, 5.6 mM, and pyruvate, 20 mM, substantial amounts of acetoin were produced in growing, aerated cultures at pH 5 (2.8 mM, equivalent to 0.5 mol [mol glucose fermented]^–1). On exhaustion of glucose, growth ceased but metabolism of pyruvate continued with the formation of acetate and a little acetoin. In aerated cultures at pH 6 the general pattern was similar to that at pH 5 but less acetoin (0.6 mM) was formed during the growth phase and, after the exhaustion of glucose, pyruvate was converted very slowly to acetate only. Leuc. mesenteroides did not grow with pyruvate as sole energy source.     

Acetoin production in Leuconostoc mesenteroides NCDO 518

Abstract Cell suspensions of Leuconostoc mesenteroides NCDO 518 converted pyruvate to acetoin and a small amount of lactate and acetate. Acetoin was not produced from mixtures of pyruvate and glucose unless the ratio of pyruvate to glucose was greater than 2:1. In the presence of glucose, external pyruvate was first used as an electron acceptor, being reduced to lactate, and was converted to acetoin only after the exhaustion of glucose. Use of added pyruvate as an electron acceptor suppressed ethanol formation and the products of glucose fermentation were then lactate and acetate; 2 mol of pyruvate per mol of glucose were required to completely suppress ethanol formation. It is suggested that acetoin is produced by heterofermentative organisms when available pyruvate is in excess of that required for reoxidation of all NADH produced during glucose fermentation.     

Carbon assimilation and extracellular antigens of some yeast-like fungi

Many yeast-like fungi assimilated n-hexadecane, butylamine and putrescine as sole carbon sources. Methanol was not assimilated. This points to a physiological similarity to endomycetous, hydrocarbon-utilizing yeasts. Stephanoascus ciferrii assimilated uric acid, adenine and allantoin as sole source of carbon and nitrogen. All strains of Geotrichum candidum and many other yeast-like fungi assimilated acetoin and butan-2,3-diol. Assimilation tests for adenine, uric acid, allantoin, acetoin and butan-2,3-diol were found to be suitable for taxonomic purposes.Extracellular antigens immunologically related to those produced by Geotrichum candidum were detected in the cell-free culture liquids of several yeast-like fungi. The extracellular antigen excreted by Stephanoascus ciferrii was species-specific.