Generation of Antitumor Active Neutral Medium-Sized α-Glycan in Apple Vinegar Fermentation

The physiologically active substances in apple vinegar have not yet been chemically characterized. We studied the biological functions of apple vinegar produced from crushed apples, and found that the constituent neutral medium-sized α-glycan (NMαG) acts as an antitumor agent against experimental mouse tumors. NMαG is a homoglycan composed of glucose having a molecular weight of about 10,000 and a branched structure bearing α (1-4,6) linkages.

In this study, we clarified the origin of NMαG in apple vinegar by examination of its content in alcohol and acetic acid fermentation products sequentially. We found that NMαG appeared in acetic acid fermentation, but not in alcohol fermentation. Furthermore we investigated NMαG origin using acetic acid fermentation from alcohol fortifiied apple without alcohol fermentation and from raw material with varying amounts of pomace. The results indicate that NMαG originated in the apple fruit body and that its production requires both fermentation processes.     

High strength vinegar fermentation by Acetobacter pasteurianus via enhancing alcohol respiratory chain

Seeking high strength vinegar fermentation by acetic acid bacteria (AAB) is still the mission of vinegar producers. AAB alcohol respiratory chain, located on intracellular membrane, is directly responsible for vinegar fermentation. In the semi-continuous vinegar fermentation by Acetobacter pasteurianus CICIM B7003, acetification rate showed positive correlation with the activity of the enzymes in alcohol respiratory chain. Aiming at achieving high strength fermentation process, a series of trials were designed to raise the activity of AAB alcohol respiratory chain. Finally, acetification was enhanced by adding some precursors (ferrous ions and β-hydroxybenzoic acid) of alcohol respiration associated factors and increasing aeration rate (0.14 vvm). As final result, average acetification rate has been raised to 2.29 ± 0.02 g/L/h, which was 28.7% higher than the original level. Simultaneously, it was found that the oxidization of alcohol into acetic acid in AAB cells was improved by well balancing of three factors: enzyme activity in alcohol respiratory chain, precursor of ubiquinone biosynthesis, and aeration rate.     

用生料制备功能性双歧醋生产工艺的实验室研究

目的将双歧杆菌、醋酸菌、酵母菌和粉碎的制醋原料及麸曲共同发酵,通过生料制醋的方法来制备功能性双歧醋。方法将粉碎的玉米与麸曲、酵母液、麸皮和水搅拌均匀,使其经过液态糖化和酒精发酵后,接入醋酸菌和双歧杆菌(二者比例为1∶1),同时加入辅料,进行醋酸发酵,当检测到醋酸酸度为5.0%~7.5%时,加入食盐终止发酵,经过过滤,除菌澄清得到功能性双歧醋。结果双歧醋的最终醋酸度为3.2%,外观红棕色,光泽度好,清澈透明,无沉淀和悬浮物。总菌数:醋酸菌为3.3×1011/m l,双歧杆菌为1.9×107/m l;活菌数:醋酸菌为1.7×1011/m l,双歧杆菌为6.8×106/m l;大肠菌群数3个/100 m l;致病菌:不得检出。结论双歧杆菌及其代谢物可以在双歧醋中存活,生料固态发酵制备双歧醋的方法可行。     

巴氏醋杆菌高酸度醋发酵过程的能量代谢分析

【目的】初步分析了Acetobacter pasteurianus CICIM B7003-02在醋酸发酵过程中的能量代谢状况, 通过强化细胞能量代谢水平以提升菌株高酸发酵的产酸强度。【方法】探明A. pasteurianus CICIM B7003-02在高酸度醋发酵的不同阶段中三羧酸循环底物含量、乙醇呼吸链酶活及能量代谢酶基因的转录水平等代谢特点, 分析用于醋酸发酵的产能代谢途径及其作用。【结果】发现A. pasteurianus CICIM B7003-02在醋酸发酵初期, 主要通过苹果酸/琥珀酸回补偶联有氧呼吸途径产能。进入醋酸快速积累阶段, 乙醇呼吸链为主要供能代谢途径。发酵后期苹果酸/琥珀酸回补途径配合乙醇呼吸链供能。基于上述研究, 采取添加琥珀酸和苹果酸强化细胞产能, 促进高酸度醋发酵强度。【结论】能量供给影响醋杆菌耐酸能力和醋酸生产能力。确定乙醇呼吸链为醋酸发酵的主要供能系统。强化细胞产能手段可达到提高醋酸发酵强度的目的。     

耐乙酸乳杆菌的筛选及其产乳酸特性

【背景】耐受乙酸的乳酸菌是传统谷物醋醋酸发酵过程中产生乳酸及其风味衍生物的重要功能微生物。【目的】从镇江香醋醋醅中分离鉴定具有耐乙酸特性的乳酸菌,并评价不同条件下该菌株的产乳酸能力。【方法】利用4%(体积比)乙酸含量的MRS培养基分离耐乙酸乳酸菌;对其进行16S rRNA基因鉴定、基因组测序、形态观察以及生理生化特性研究;考察不同乙酸浓度、葡萄糖浓度、发酵温度和时间对菌株产乳酸能力的影响。【结果】分离得到一株可耐受6%乙酸的乳杆菌Lactobacillus sp. JN500903;在厌氧静置、接种量5%、乙酸浓度5%、葡萄糖浓度40 g/L、发酵温度37°C、发酵时间10 d条件下,该菌株乳酸产量为16.1 g/L。【结论】乳杆菌JN500903能够耐受6%乙酸浓度,具有在酸性环境下合成乳酸的能力,有一定的应用潜力。     

Aerobic submerged fermentation by acetic acid bacteria for vinegar production: Process and biotechnological aspects

Strictly aerobic acetic acid bacteria (AAB) have a long history of use in fermentation processes, and the conversion of ethanol to acetic acid for the production of vinegar is the most well-known application.At the industrial scale, vinegar is mainly produced by submerged fermentation, which refers to an aerobic process in which the ethanol in beverages such as spirits, wine or cider is oxidized to acetic acid by AAB. Submerged fermentation requires robust AAB strains that are able to oxidize ethanol under selective conditions to produce high-titer acetic acid. Currently submerged fermentation is conducted by unselected AAB cultures, which are derived from previous acetification stocks and maintained by repeated cultivation cycles.In this work, submerged fermentation for vinegar production is discussed with regard to advances in process optimization and parameters (oxygen availability, acetic acid content and temperature) that influence AAB activity. Furthermore, the potential impact arising from the use of selected AAB is described.Overcoming the acetification constraints is a main goal in order to facilitate innovation in submerged fermentation and to create new industry-challenging perspectives.     

Acetobacter senegalensis isolated from mango fruits: Its polyphasic characterization and adaptation to protect against stressors in the industrial production of vinegar: A review

It has been more than a decade since Acetobacter senegalensis was isolated, identified and described as a thermotolerant strain of acetic acid bacteria. It was isolated from mango fruits in Senegal and used for industrial vinegar production in developing countries, mainly in sub-Saharan Africa. The strain was tested during several spirit vinegar fermentation processes at relatively high temperatures in accordance with African acclimation. The upstream fermentation process had significant stress factors, which are highlighted in this review so that the fermentation process can be better controlled. Due to its high industrial potential, this strain was extensively investigated by diverse industrial microbiologists worldwide; they concentrated on its microbiological, physiological and genomic features. A research group based in Belgium proposed an important project for the investigation of the whole-genome sequence of A. senegalensis. It would use a 454-pyrosequencing technique to determine and corroborate features that could give this strain significant diverse bio-industrial applications. For instance, its application in cocoa bean fermentation has made it a more suitable acetic acid bacterium for the making of chocolate than Acetobacter pasteurianus. Therefore, in this paper, we present a review that summarizes the current research on A. senegalensis at its microbial and genomic levels and also its specific bio-industrial applications, which can provide economic opportunities for African agribusiness. This review summarizes the physiological and genomic characteristics of Acetobacter senegalensis, a thermotolerant strain isolated from mango fruits and intended to be used in industrial vinegar fermentation processes. It also explores other bio-industrial applications such as cocoa fermentation. Vinegar fermentation is usually performed with mesophilic strains in temperate regions of the world. Developing countries, such as Senegal, import vinegar or make ‘fake’ vinegar by diluting acetic acid obtained from petrochemicals. The use of a thermotolerant Acetobacter senegalensis strain as a solid functional starter culture, as well as the design of a new adapted bioreactor, has significantly contributed to food security and the creation of small- to medium-sized enterprises that produce mango vinegar in West Africa.     

Optically Active Bis-β-keto Sulfonium Ylid

Particulate alcohol dehydrogenase of acetic acid bacteria that is mainly participated in vinegar fermentation was purified to homogeneous state from Gluconobacter suboxydans IFO 12528. Solubilization of enzyme from the bacterial membrane fraction by Triton X-100 and subsequent fractionation on DEAE-Sephadex A-50 and hydroxylapatite was successful in enzyme purification. A cytochrome c-like component was tightly bound to the dehydrogenase protein and existed as an enzyme-cytochrome complex. It was also confirmed that the alcohol dehydrogenase is not a cytochrome component itself. The molecular weight of the enzyme was determined to be 150,000, and gel electrophoresis showed the presence of three subunits having a molecular weight of 85,000, 49,000 and 14,400. The smallest subunit was corresponded to the cytochrome c-like component. Ethanol was oxidized in the presence of dyes in vitro but NAD or NADP were not required as hydrogen acceptor. Unlike NAD- linked alcohol dehydrogenase in yeast or liver and other primary alcohol dehydrogenases in methanol utilizing bacteria, the enzyme from the acetic acid bacteria showed its optimum pH at fairly acidic pH.     

醋酸菌耐酸机理及其群体感应研究新进展

醋酸菌(acetic acid bacteria,AAB)是一类严格好氧的革兰氏阴性细菌,因其乙醇氧化生成醋酸能力强、高耐醋酸等特性而成为食醋发酵的主要工业菌种。醋酸菌的耐酸性对于高酸度食醋生产具有重要意义。随着醋酸菌的蛋白组学及基因组学研究的深入,其糖代谢、蛋白质代谢、脂代谢及应激响应等分子机制或过程也得到更多的阐释;葡糖醋杆菌中有关群体感应系统的研究报道则为从信号通路角度探索醋酸菌的耐酸机制提供了新的思路,进而对于高耐酸醋酸菌的选育以及醋酸发酵工艺的优化具重要的参考意义。本文在简介蛋白组、基因组研究的基础上,着重综述醋酸菌群体感应的研究进展。     

Isolation and Identification of Acetic Acid Bacteria for Submerged Acetic Acid Fermentation at High Temperature

Industrial vinegar production by submerged acetic acid fermentation has been carried out using Acetobacter strains at about 30°C. To obtain strains suitable for acetic acid fermentation at higher temperature, about 1,100 strains of acetic acid bacteria were isolated from vinegar mash, soils in vinegar factories and fruits, and their activities to oxidize ethanol at high temperature were examined. One of these strains, No. 1023, identified as Acetobacter aceti, retained full activity to produce acetic acid in continuous submerged culture at 35°C and produced 45% of activity at 38°C, while the usual strain of A. aceti completely lost its activity at 35°C. Thus the use of this strain may reduce the cooling costs of industrial vinegar production.     

Energy metabolism of a unique acetic acid bacterium, Asaia bogorensis, that lacks ethanol oxidation activity

Acetic acid bacteria (AAB) are known as a vinegar producer on account of their ability to accumulate a high concentration of acetic acid due to oxidative fermentation linking the ethanol oxidation respiratory chain. Reactions in oxidative fermentation cause poor growth because a large amount of the carbon source is oxidized incompletely and the harmful oxidized products are accumulated almost stoichiometrically in the culture medium during growth, but a newly identified AAB, Asaia, has shown unusual properties, including scanty acetic acid production and rapid growth, as compared with known AAB as Acetobacter, Gluconobacter, and Gluconacetobacter. To understand these unique properties of Asaia in more detail, the respiratory chain and energetics of this strain were investigated. It was found that Asaia lacks quinoprotein alcohol dehydrogenase, but has other sugar and sugar alcohol-oxidizing enzymes specific to the respiratory chain of Gluconobacter, especially quinoprotein glycerol dehydrogenase. It was also found that Asaia has a cyanide-sensitive cytochrome bo(3)-type ubiquinol oxidase as sole terminal oxidase in the respiratory chain, and that it exhibits a higher H(+)/O ratio.     

Fermentation effects of oligosaccharides of Radix Ophiopogonis on alloxan-induced diabetes in mice

In this study, oligosaccharides extracted from Ophiopogon japonicus vinegar (OOV) by alcoholic and acetic acid fermentation with water extracts from Radix Ophiopogon and oligosaccharides extracted from Radix Ophiopogonis (OOJ) were investigated. Characterization of the extracts indicated that OOV are proteoglycans, whereas OOJ are not. Moreover, compared with OOJ, monosaccharide compositions of OOV only include fructose and galactose and not glucose. MALDI-TOF-mass spectrometric results showed that the molecular weight of OOV was smaller after fermentation. Changes in the characteristics of OOV would inevitably lead to changes in its hypoglycemic properties. The OOV inhibition activity against α-glucosidase was stronger than that of OOJ. The inhibition activity became stronger with higher dosages of OOV. The hypoglycemic effect of OOV on alloxan-induced diabetic mice was stronger than that of OOJ. More important, the ability of OOV to reduce damage on islets in diabetic mice was stronger than that of OOJ. Overall, alcoholic and acetic acid fermentation improved the hypoglycemic activity of OOJ.     

Differentiation of Synthetic from Biogenic Raw Materials in Various Foods with a Liquid Scintillation Counter

By estimating the ¹⁴C content of many acetic acid samples prepared from vinegars, Worcester sauces, ketchups and pickles with a liquid scintillation counter, it was proved that synthetic acetic acid mixed with biogenic one could be discriminated with considerable accuracy. It was also found that several products obtained from the open market contained synthetic acetic acid though they were represented to have been prepared exclusively from fermentation vinegar.     

New developments in oxidative fermentation

Oxidative fermentations have been well established for a long time, especially in vinegar and in L-sorbose production. Recently, information on the enzyme systems involved in these oxidative fermentations has accumulated and new developments are possible based on these findings. We have recently isolated several thermotolerant acetic acid bacteria, which also seem to be useful for new developments in oxidative fermentation. Two different types of membrane-bound enzymes, quinoproteins and flavoproteins, are involved in oxidative fermentation, and sometimes work with the same substrate but produce different oxidation products. Recently, there have been new developments in two different oxidative fermentations, D-gluconate and D-sorbitol oxidations. Flavoproteins, D-gluconate dehydrogenase, and D-sorbitol dehydrogenase were isolated almost 2 decades ago, while the enzyme involved in the same oxidation reaction for D-gluconate and D-sorbitol has been recently isolated and shown to be a quinoprotein. Thus, these flavoproteins and a quinoprotein have been re-assessed for the oxidation reaction. Flavoprotein D-gluconate dehydrogenase and D-sorbitol dehydrogenase were shown to produce 2-keto- D-gluconate and D-fructose, respectively, whereas the quinoprotein was shown to produce 5-keto- D-gluconate and L-sorbose from D-gluconate and D-sorbitol, respectively. In addition to the quinoproteins described above, a new quinoprotein for quinate oxidation has been recently isolated from Gluconobacter strains. The quinate dehydrogenase is also a membrane-bound quinoprotein that produces 3-dehydroquinate. This enzyme can be useful for the production of shikimate, which is a convenient salvage synthesis system for many antibiotics, herbicides, and aromatic amino acids synthesis. In order to reduce energy costs of oxidative fermentation in industry, several thermotolerant acetic acid bacteria that can grow up to 40 degrees C have been isolated. Of such isolated strains, some thermotolerant Acetobacter species were found to be useful for vinegar fermentation at a high temperature such 38-40 degrees C, where mesophilic strains showed no growth. They oxidized higher concentrations of ethanol up to 9% without any appreciable lag time, while alcohol oxidation with mesophilic strains was delayed or became almost impossible under such conditions. Several useful Gluconobacter species of thermotolerant acetic acid bacteria are also found, especially L-erythrulose-producing strains and cyclic alcohol-oxidizing strains. Gluconobacter frateurii CHM 43 is able to rapidly oxidize meso-erythritol at 37 degrees C leading to the accumulation of L-erythrulose, which may replace dihydroxyacetone in cosmetics. G. frateuriiCHM 9 is able to oxidize cyclic alcohols to their corresponding cyclic ketones or aliphatic ketones, which are known to be useful for preparing many different physiologically active compounds such as oxidized steroids or oxidized bicyclic ketones. The enzymes involved in these meso-erythritol and cyclic alcohol oxidations have been purified and shown to be a similar type of membrane-bound quinoproteins, consisting of a high molecular weight single peptide. This is completely different from another quinoprotein, alcohol dehydrogenase of acetic acid bacteria, which consists of three subunits including hemoproteins.     

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.     

比较基因组学解析谷物醋醋醅中巴氏醋杆菌和欧洲驹形杆菌的功能差异

【目的】基于比较基因组分析,探究镇江香醋醋醅中不同醋酸菌的功能差异。【方法】利用分离培养技术结合16SrRNA基因全长测序获得不同分类地位的醋酸菌;应用比较基因组学结合发酵性能实现不同醋酸菌生长和代谢的差异比较。【结果】巴氏醋杆菌和欧洲驹形杆菌为镇江香醋醋醅中的主要醋酸菌。其中,欧洲驹形杆菌的GC含量更高、基因组更大。功能注释结果表明巴氏醋杆菌和欧洲驹形杆菌的碳水化合物、氨基酸相关基因数量及种类差异较大,欧洲驹形杆菌的碳水化合物活性酶数量更多。相比巴氏醋杆菌,欧洲驹形杆菌中富集的功能差异基因主要参与磷酸戊糖途径、脂肪酸生物合成、果糖和甘露糖代谢等代谢途径。验证结果表明欧洲驹形杆菌可通过产生更多的乙醇脱氢酶、乙醛脱氢酶和大量的ATP,并改变细胞膜脂肪酸组成来提高乙醇的转化率。【结论】明确了巴氏醋杆菌和欧洲驹形杆菌基因之间的差异。欧洲驹形杆菌通过更多的能量积累、更高的乙醇转化相关酶酶活力和细胞膜脂肪酸组成的改变,来改善胞内微环境以适应高酸环境。本研究得到的结果可加深对不同醋酸菌耐酸机制的理解。     

Characterization of acetic acid bacteria in traditional acetic acid fermentation of rice vinegar (komesu) and unpolished rice vinegar (kurosu) produced in Japan

Bacterial strains were isolated from samples of Japanese rice vinegar (komesu) and unpolished rice vinegar (kurosu) fermented by the traditional static method. Fermentations have never been inoculated with a pure culture since they were started in 1907. A total of 178 isolates were divided into groups A and B on the basis of enterobacterial repetitive intergenic consensus-PCR and random amplified polymorphic DNA fingerprinting analyses. The 16S ribosomal DNA sequences of strains belonging to each group showed similarities of more than 99% with Acetobacter pasteurianus. Group A strains overwhelmingly dominated all stages of fermentation of both types of vinegar. Our results indicate that appropriate strains of acetic acid bacteria have spontaneously established almost pure cultures during nearly a century of komesu and kurosu fermentation.     

Characterization by plasmid profile analysis of acetic acid bacteria from wine, spirit and cider acetators for industrial vinegar production

The fermentation in industrial high acid submerged fermenters of wine, spirit or cider into vinegar was investigated by direct analysis of the plasmid patterns of the acetic acid bacteria involved. The strains were different in all samples. One strain from a red wine acetator was isolated by the double layer agar technique and proved to be the main fermenting organism. After inoculation of an acetator with this strain, the initiation of acidification was accelerated. Inoculation with spirit vinegar organisms led to immediate acidification. The spirit vinegar organisms were outnumbered after 12 d by fortuitously-occurring, highly adapted red wine vinegar bacteria. Over-oxidation was due to physiological regulation, a genetical change by plasmid loss or occurrence of new organisms was not observed.