Direct fermentation of 2-keto-L-gulonic acid in recombinant Gluconobacter oxydans

We isolated Gluconobacter oxydans T-100 that had an activity to produce 2-KLGA from D-sorbitol; however, the yield of 2-KLGA was quite insufficient. Therefore, enzymes involved in the biosynthesis of L-sorbosone and 2-KLGA, L-sorbose dehydrogenase (SDH) and L-sorbosone dehydrogenase (SNDH), respectively, were purified from G. oxydans T-100. A genomic library of G. oxydans T-100 was screened to clone both genes for SDH and SNDH based on their amino acid sequences. SNDH and SDH were encoded in sequential open reading frames with 1497 and 1596 nucleotides, respectively, which were verified by the expression in Escherichia coli. The amino acid sequence of SDH and SNDH showed close similarity with E. coli choline dehydrogenase (CDH) and betaine-aldehyde dehydrogenase (BADH), respectively, which cooperatively play a key role for conferring osmotic tolerance. Because the yield of 2-KLGA by G. oxydans introduced with the genes for SDH and SNDH were insufficient, replacement of the promoter with that of Escherichia coli tufB1 in combination with chemical mutagenesis by N-methyl-N'-nitro-N-nitrosoguanidine resulted in improvement of the production level.     

Cloning and nucleotide sequencing of the membrane-bound L-sorbosone dehydrogenase gene of Acetobacter liquefaciens IFO 12258 and its expression in Gluconobacter oxydans.

Cloning and expression of the gene encoding Acetobacter liquefaciens IFO 12258 membrane-bound L-sorbosone dehydrogenase (SNDH) were studied. A genomic library of A. liquefaciens IFO 12258 was constructed with the mobilizable cosmid vector pVK102 (mob+) in Escherichia coli S17-1 (Tra+). The library was transferred by conjugal mating into Gluconobacter oxydans OX4, a mutant of G. oxydans IFO 3293 that accumulates L-sorbosone in the presence of L-sorbose. The transconjugants were screened for SNDH activity by performing a direct expression assay. One clone harboring plasmid p7A6 converted L-sorbosone to 2-keto-L-gulonic acid (2KGA) more rapidly than its host did and also converted L-sorbose to 2KGA with no accumulation of L-sorbosone. The insert (25 kb) of p7A6 was shortened to a 3.1-kb fragment, in which one open reading frame (1,347 bp) was found and was shown to encode a polypeptide with a molecular weight of 48,222. The SNDH gene was introduced into the 2KGA-producing strain G. oxydans IFO 3293 and its derivatives, which contained membrane-bound L-sorbose dehydrogenase. The cloned SNDH was correctly located in the membrane of the host. The membrane fraction of the clone exhibited almost stoichiometric formation of 2KGA from L-sorbosone and L-sorbose. Resting cells of the clones produced 2KGA very efficiently from L-sorbosone and L-sorbose, but not from D-sorbitol; the conversion yield from L-sorbosone was improved from approximately 25 to 83%, whereas the yield from L-sorbose was increased from 68 to 81%. Under fermentation conditions, cloning did not obviously improve the yield of 2KGA from L-sorbose.     

利用山梨糖脱氢酶活性筛选氧化葡糖杆菌PQQ合成基因簇

【目的】利用山梨糖脱氢酶醌酶活性从氧化葡糖杆菌H24中分离PQQ生物合成基因簇。【方法】利用ptsG位点整合sdh基因的大肠杆菌JM109作为宿主菌构建了氧化葡糖杆菌H24的基因组DNA文库。通过山梨糖脱氢酶活性检测,从文库中筛选具有PQQ合成能力的单菌落并进行亚克隆。【结果】从氧化葡糖杆菌H24的基因组文库中筛选得到一株具有山梨糖脱氢酶活性的单菌落,亚克隆后序列分析显示插入片段全长5400bp,对应5个编码框(pqqABCDE),与其他细菌PQQ生物合成基因簇有很高的序列同源性。【结论】利用山梨糖脱氢酶醌酶活性成功从氧化葡糖杆菌H24中分离克隆得到了PQQ生物合成基因簇pqqABCDE。     

Membrane-bound pyrroloquinoline quinone-dependent dehydrogenase in Gluconobacter oxydans M5, responsible for production of 6-(2-hydroxyethyl) amino-6-deoxy-L-sorbose

A membrane-bound protein purified from Gluconobacter oxydans M5 was confirmed to be a pyrroloquinoline quinone-dependent D-sorbitol dehydrogenase. Gene disruption and complementation experiments demonstrated that this enzyme is responsible for the oxidation of 1-(2-hydroxyethyl) amino-1-deoxy-D-sorbitol (1NSL) to 6-(2-hydroxyethyl) amino-6-deoxy-L-sorbose (6NSE), which is the precursor of an antidiabetic drug, miglitol.     

氧化葡糖杆菌sndh-sdh基因簇的克隆表达

目的:从氧化葡糖杆菌H763中克隆sndh-sdh基因簇,在大肠杆菌和氧化葡糖杆菌621H中分别表达山梨酮脱氢酶-山梨糖脱氢酶(SNDH-SDH),并检测其活性。方法与结果:以氧化葡糖杆菌H763基因组DNA为模板,PCR扩增包括启动子、结构基因及终止序列在内的sndh-sdh基因簇,回收3533 bp的扩增产物,连入pMD18T载体,转化至大肠杆菌DH5α中表达;以山梨糖或木糖为底物,DCIP法检测菌体裂解液,DCIP检测液颜色由蓝绿色变为黄色,表明大肠杆菌表达产物具有脱氢酶活性。构建pBBR1MCS2-sndh-sdh载体,通过接合转移导入氧化葡糖杆菌621H,重组葡糖杆菌在以山梨醇或山梨糖为底物的培养基中培养,采用薄层层析检测法检测其培养上清中的代谢产物,层析板上显示了2-酮基-L-古龙酸斑点。结论:重组大肠杆菌DH5α和氧化葡糖杆菌621H中均表达了有脱氢酶活性的SNDH-SDH。     

Optimized synthesis of L-sorbose by C(5)-dehydrogenation of D-sorbitol with Gluconobacter oxydans

The optimization of L-sorbose synthesis by regiospecific dehydrogenation of D-sorbitol using Gluconobacter oxydans is reported. The current L-sorbose production processes that are based on G. oxydans and other bacterial strains are suboptimal as to yield and rate of L-sorbose synthesis. One reason for these problems is the toxicity that is induced by the substrate D-sorbitol when used in concentrations of >10% (w/v). This phenomenon significantly limits the potentials of L-sorbose production from an industrial point of view. The goal of this study was to develop a fast production process that yields L-sorbose in stoichiometric amounts starting from D-sorbitol concentrations that exceed 10% (w/v). A gradual improvement of the inoculum build-up procedure, culture medium composition, and process parameters ultimately led to a theoretically maximal L-sorbose productivity (200 g L(-1) of L-sorbose from 200 g L(-1) of D-sorbitol in 28 h of fermentation) using a Gluconobacter oxydans mutant strain that was selected under conditions of substrate inhibition. Because the D-sorbitol/L‐sorbose bioconversion is used to mass-produce vitamin C, the procedure reported here will contribute to a more efficient and more economic synthesis of vitamin C.     

Coenzyme specificity of enzymes in the oxidative pentose phosphate pathway of Gluconobacter oxydans

The coenzyme specificity of enzymes in the oxidative pentose phosphate pathway of Gluconobacter oxydans was investigated. By investigation of the activities of glucose-6-phosphate dehydrogenase (G6PDH) and 6-phosphogluconate dehydrogenase (6PGDH) in the soluble fraction of G. oxydans, and cloning and expression of genes in Escherichia coli, it was found that both G6PDH and 6PGDH have NAD/NADP dual coenzyme specificities. It was suggested that the pentose phosphate pathway is responsible for NADH regeneration in G. oxydans.     

Gluconobacter oxydans: its biotechnological applications

Gluconobacter oxydans is a gram-negative bacterium belonging to the family Acetobacteraceae. G. oxydans is an obligate aerobe, having a respiratory type of metabolism using oxygen as the terminal electron acceptor. Gluconobacter strains flourish in sugary niches e.g. ripe grapes, apples, dates, garden soil, baker's soil, honeybees, fruit, cider, beer, wine. Gluconobacter strains are non-pathogenic towards man and other animals but are capable of causing bacterial rot of apples and pears accompanied by various shades of browning. Several soluble and particulate polyol dehydrogenases have been described. The organism brings about the incomplete oxidation of sugars, alcohols and acids. Incomplete oxidation leads to nearly quantitative yields of the oxidation products making G. oxydans important for industrial use. Gluconobacter strains can be used industrially to produce L-sorbose from D-sorbitol; D-gluconic acid, 5-keto- and 2-ketogluconic acids from D-glucose; and dihydroxyacetone from glycerol. It is primarily known as a ketogenic bacterium due to 2,5-diketogluconic acid formation from D-glucose. Extensive fermentation studies have been performed to characterize its direct glucose oxidation, sorbitol oxidation, and glycerol oxidation. The enzymes involved have been purified and characterized, and molecular studies have been performed to understand these processes at the molecular level. Its possible application in biosensor technology has also been worked out. Several workers have explained its basic and applied aspects. In the present paper, its different biotechnological applications, basic biochemistry and molecular biology studies are reviewed.     

Stepwise metabolic engineering of Gluconobacter oxydans WSH-003 for the direct production of 2-keto-l-gulonic acid from d-sorbitol

2-Keto-l-gulonic acid (2-KLG), the direct precursor of vitamin C, is currently produced by a two-step fermentation route from d-sorbitol. However, this route involves three bacteria, making the mix-culture system complicated and redundant. Thus, replacement of the conventional two-step fermentation process with a one-step process could be revolutionary in vitamin C industry. In this study, different combinations of five l-sorbose dehydrogenases (SDH) and two l-sorbosone dehydrogenases (SNDH) from Ketogulonicigenium vulgare WSH-001 were introduced into Gluconobacter oxydans WSH-003, an industrial strain used for the conversion of d-sorbitol to l-sorbose. The optimum combination produced 4.9 g/L of 2-KLG. In addition, 10 different linker peptides were used for the fusion expression of SDH and SNDH in G. oxydans. The best recombinant strain (G. oxydans/pGUC-k0203-GS-k0095) produced 32.4 g/L of 2-KLG after 168 h. Furthermore, biosynthesis of pyrroloquinoline quinine (PQQ), a cofactor of those dehydrogenases, was enhanced to improve 2-KLG production. With the stepwise metabolic engineering of G. oxydans, the final 2-KLG production was improved to 39.2 g/L, which was 8.0-fold higher than that obtained using independent expression of the dehydrogenases. These results bring us closer to the final one-step industrial-scale production of vitamin C.     

Construction of a vector plasmid for use in Gluconobacter oxydans

A host vector system in Gluconobacter oxydans was constructed. An Acetobacter-Escherichia coli shuttle vector was introduced with the efficiency of 10(4) transformants/microg of DNA. Next, aiming for a self-cloning vector, we found a cryptic plasmid (which we named pAG5) of 5648 bp in G. oxydans strain IFO 3171, and sequenced the nucleotides. The plasmid seemed to have only one open reading flame (ORF) for a possible replication protein. Shuttle vectors of Gluconobacter-E. coli were constructed with the plasmid pAG5 and an E. coli vector, pUC18.     

Sequence analysis of the Gluconobacter oxydans RecA protein and construction of a recA-deficient mutant.

The deduced amino acid sequence of Gluconobacter oxydans RecA protein shows 75.2, 69.4, and 66.2% homology with those from Aquaspirillum magnetotacticum, Escherichia coli, and Pseudomonas aeruginosa, respectively. The amino acid residues essential for function of the recombinase, protease, and ATPase in E. coli recA protein are conserved in G. oxydans. Of 24 amino acid residues believed to be the ATP binding domain of E. coli RecA, 17 are found to be identical in G. oxydans RecA. Interestingly, nucleotide sequence alignment between the SOS box of G. orphans recA gene and those from different microorganisms revealed that all the DNA sequences examined have dyad symmetry that can form a stem-loop structure. A G. oxydans recA-deficient mutant (LCC96) was created by allelic exchange using the cloned recA gene that had been insertionally inactivated by a kanamycin-resistance cassette. Such replacement of the wild-type recA with a kanamycin resistance gene in the chromosome was further verified by Southern hybridization. Phenotypically, the recA-deficient mutant is significantly more sensitive to UV irradiation than the wild-type strain, suggesting that the recA gene of G. oxydans ATCC9324 plays a role in repairing DNA damage caused by UV irradiation. Moreover, the mutant strain is much more plasmid transformable than its parent strain, illustrating that G. oxydans LCC96 could be used as a host to take up the recombinant plasmid for gene manipulation.     

Biochemical characterization and sequence analysis of the gluconate:NADP 5-oxidoreductase gene from Gluconobacter oxydans.

Gluconate:NADP 5-oxidoreductase (GNO) from the acetic acid bacterium Gluconobacter oxydans subsp. oxydans DSM3503 was purified to homogeneity. This enzyme is involved in the nonphosphorylative, ketogenic oxidation of glucose and oxidizes gluconate to 5-ketogluconate. GNO was localized in the cytoplasm, had an isoelectric point of 4.3, and showed an apparent molecular weight of 75,000. In sodium dodecyl sulfate gel electrophoresis, a single band appeared corresponding to a molecular weight of 33,000, which indicated that the enzyme was composed of two identical subunits. The pH optimum of gluconate oxidation was pH 10, and apparent Km values were 20.6 mM for the substrate gluconate and 73 microM for the cosubstrate NADP. The enzyme was almost inactive with NAD as a cofactor and was very specific for the substrates gluconate and 5-ketogluconate. D-Glucose, D-sorbitol, and D-mannitol were not oxidized, and 2-ketogluconate and L-sorbose were not reduced. Only D-fructose was accepted, with a rate that was 10% of the rate of 5-ketogluconate reduction. The gno gene encoding GNO was identified by hybridization with a gene probe complementary to the DNA sequence encoding the first 20 N-terminal amino acids of the enzyme. The gno gene was cloned on a 3.4-kb DNA fragment and expressed in Escherichia coli. Sequencing of the gene revealed an open reading frame of 771 bp, encoding a protein of 257 amino acids with a predicted relative molecular mass of 27.3 kDa. Plasmid-encoded gno was functionally expressed, with 6.04 U/mg of cell-free protein in E. coli and with 6.80 U/mg of cell-free protein in G. oxydans, which corresponded to 85-fold overexpression of the G. oxydans wild-type GNO activity. Multiple sequence alignments showed that GNO was affiliated with the group II alcohol dehydrogenases, or short-chain dehydrogenases, which display a typical pattern of six strictly conserved amino acid residues.     

葡萄糖酸氧化杆菌木糖醇脱氢酶基因的克隆与表达

【目的】获得葡萄糖酸氧化杆菌(Gluconobacter oxydans CGMCC 1.637)的木糖醇脱氢酶基因,研究其酶学性质及碳源特别是D-阿拉伯醇和木糖醇对该酶活性的影响。【方法】通过已报道序列的木糖醇脱氢酶的保守区设计引物,用聚合酶链式反应(polymerase chain reaction,PCR)扩增获得目的基因片段。根据获得的片段序列设计引物克隆目的基因的5’和3’片段,将所获得的片段拼接,获得完整的木糖醇脱氢酶基因。通过构建工程菌获得重组蛋白,并利用氧化还原反应测定重组酶的活性。用含不同碳源的培养基培养G.oxydans CGMCC 1.637,并测定其破胞上清液木糖醇脱氢酶氧化木糖醇的活性;用不同碳源培养的G.oxydans CGMCC 1.637转化木酮糖,用高效液相色谱法测定木糖醇的产量。【结果】获得一个新的798bp的木糖醇脱氢酶基因,所编码的木糖醇脱氢酶含265个氨基酸,属于短链脱氢酶家族。酶学性质研究发现,该木糖醇脱氢酶催化木糖醇氧化的最适合条件为35℃、pH 10.0,最高活性为23.27 U/mg,催化木酮糖还原为木糖醇的最适条件为30℃、pH 6.0。最高活性为255.55 U/mg;该木糖醇脱氢酶的对木糖醇的Km和Vmax分别为78.97 mmol/L和40.17 U/mg。碳源诱导实验表明,d-山梨醇对G.oxydans CGMCC 1.637木糖醇脱氢酶的活性有明显的促进作用,而葡萄糖、果糖、木糖、木糖醇、D-阿拉伯醇对木糖醇脱氢酶活性有明显的抑制作用。而在转化实验中,用d-甘露糖培养的G.oxydans CGMCC 1.637的转化能力明显高于其他碳源培养的G.oxydans CGMCC 1.637的转化能力,其中,用阿拉伯醇培养的G.oxydans CGMCC 1.637的转化能力最低,仅为对照的35%。【结论】克隆自G.oxydans CGMCC 1.637的木糖醇脱氢酶基因是一个新的基因,用阿拉伯醇培养的G.oxydans CGMCC 1.637破胞液木糖醇脱氢酶活性低;且阿拉伯醇对G.oxydans CGMCC 1.637木酮糖的还原能力具有抑制作用。     

5-keto-D-gluconate production is catalyzed by a quinoprotein glycerol dehydrogenase,major polyol dehydrogenase,in gluconobacter species

Acetic acid bacteria, especially Gluconobacter species, have been known to catalyze the extensive oxidation of sugar alcohols (polyols) such as D-mannitol, glycerol, D-sorbitol, and so on. Gluconobacter species also oxidize sugars and sugar acids and uniquely accumulate two different keto-D-gluconates, 2-keto-D-gluconate and 5-keto-D-gluconate, in the culture medium by the oxidation of D-gluconate. However, there are still many controversies regarding their enzyme systems, especially on D-sorbitol and also D-gluconate oxidations. Recently, pyrroloquinoline quinone-dependent quinoprotein D-arabitol dehydrogenase and D-sorbitol dehydrogenase have been purified from G. suboxydans, both of which have similar and broad substrate specificity towards several different polyols. In this study, both quinoproteins were shown to be identical based on their immuno-cross-reactivity and also on gene disruption and were suggested to be the same as the previously isolated glycerol dehydrogenase (EC 1.1.99.22). Thus, glycerol dehydrogenase is the major polyol dehydrogenase involved in the oxidation of almost all sugar alcohols in Gluconobacter sp. In addition, the so-called quinoprotein glycerol dehydrogenase was also uniquely shown to oxidize D-gluconate, which was completely different from flavoprotein D-gluconate dehydrogenase (EC 1.1.99.3), which is involved in the production of 2-keto-D-gluconate. The gene disruption experiment and the reconstitution system of the purified enzyme in this study clearly showed that the production of 5-keto-D-gluconate in G. suboxydans is solely dependent on the quinoprotein glycerol dehydrogenase.     

Cloning of the xylitol dehydrogenase gene from Gluconobacter oxydans and improved production of xylitol from D-arabitol

Xylitol dehydrogenase (XDH) was purified from the cytoplasmic fraction of Gluconobacter oxydans ATCC 621. The purified enzyme reduced D-xylulose to xylitol in the presence of NADH with an optimum pH of around 5.0. Based on the determined NH2-terminal amino acid sequence, the gene encoding xdh was cloned, and its identity was confirmed by expression in Escherichia coli. The xdh gene encodes a polypeptide composed of 262 amino acid residues, with an estimated molecular mass of 27.8 kDa. The deduced amino acid sequence suggested that the enzyme belongs to the short-chain dehydrogenase/reductase family. Expression plasmids for the xdh gene were constructed and used to produce recombinant strains of G. oxydans that had up to 11-fold greater XDH activity than the wild-type strain. When used in the production of xylitol from D-arabitol under controlled aeration and pH conditions, the strain harboring the xdh expression plasmids produced 57 g/l xylitol from 225 g/l D-arabitol, whereas the control strain produced 27 g/l xylitol. These results demonstrated that increasing XDH activity in G. oxydans improved xylitol productivity.     

Molecular cloning and functional expression of d-arabitol dehydrogenase gene from Gluconobacter oxydans in Escherichia coli

A NADP-dependent d-arabitol dehydrogenase gene was cloned from Gluconobacter oxydans CGMCC 1.110 and functionally expressed in Escherichia coli. With d-arabitol as sole carbon source, E. coli transformants grew rapidly in minimal medium, and produced d-xylulose. The enzymatic properties of the 29kDa enzyme were documented. The DNA sequence surrounding the gene suggested that it is part of an operon with several components of a sugar alcohol transporter system, and the d-arabitol dehydrogenase gene belongs to the short-chain dehydrogenase family.     

Membrane-bound D-sorbitol dehydrogenase of Gluconobacter suboxydans IFO 3255--enzymatic and genetic characterization

Gluconobacter strains effectively produce L-sorbose from D-sorbitol because of strong activity of the D-sorbitol dehydrogenase (SLDH). L-sorbose is one of the important intermediates in the industrial vitamin C production process. Two kinds of membrane-bound SLDHs, which consist of three subunits, were reportedly found in Gluconobacter strains [Agric. Biol. Chem. 46 (1982) 135,FEMS Microbiol. Lett. 125 (1995) 45]. We purified a one-subunit-type SLDH (80 kDa) from the membrane fraction of Gluconobacter suboxydans IFO 3255 solubilized with Triton X-100 in the presence of D-sorbitol, but the cofactor could not be identified from the purified enzyme. The SLDH was active on mannitol, glycerol and other sugar alcohols as well as on D-sorbitol to produce respective keto-aldoses. Then, the SLDH gene (sldA) was cloned and sequenced. It encodes the polypeptide of 740 residues, which contains a signal sequence of 24 residues. SLDH had 35-37% identity to those of membrane-bound quinoprotein glucose dehydrogenases (GDHs) from Escherichia coli, Gluconobacter oxydans and Acinetobacter calcoaceticus except the N-terminal hydrophobic region of GDH. Additionally, the sldB gene located just upstream of sldA was found to encode the polypeptide consisting of 126 very hydrophobic residues that is similar to the one-sixth N-terminal region of the GDH. Development of the SLDH activity in E. coli required co-expression of the sldA and sldB genes and the presence of PQQ. The sldA gene disruptant showed undetectable oxidation activities on D-sorbitol in growing culture, and resting-cell reaction (pH 4.5 and 7); in addition, they showed undetectable activities on D-mannitol and glycerol. The disruption of the sldB gene by a gene cassette with a downward promoter to express the sldA gene resulted in formation of a larger size of the SLDH protein and in undetectable oxidation of the polyols. In conclusion, the SLDH of the strain 3255 functions as the main polyol dehydrogenase in vivo. The sldB polypeptide possibly has a chaperone-like function to process the SLDH polypeptide into a mature and active form.     

Molecular cloning and functional expression of D-sorbitol dehydrogenase from Gluconobacter suboxydans IF03255, which requires pyrroloquinoline quinone and hydrophobic protein SldB for activity development in E. coli

The sldA gene that encodes the D-sorbitol dehydrogenase (SLDH) from Gluconobacter suboxydans IFO 3255 was cloned and sequenced. It encodes a polypeptide of 740 residues, which contains a signal sequence of 24 residues. SLDH had 35-37% identity to the membrane-bound quinoprotein glucose dehydrogenases (GDHs) from E. coli, Gluconobacter oxydans, and Acinetobacter calcoaceticus except the N-terminal hydrophobic region of GDH. Additionally, the sldB gene located just upstream of sldA was found to encode a polypeptide consisting of 126 very hydrophobic residues that is similar in sequence to the one-sixth N-terminal region of the GDH. For the development of the SLDH activity in E. coli, co-expression of the sldA and sldB genes and the presence of pyrrloquinolone quinone as a co-factor were required.     

Transaldolase/glucose-6-phosphate isomerase bifunctional enzyme and ribulokinase as factors to increase xylitol production from D-arabitol in Gluconobacter oxydans

Xylitol production from D-arabitol by the membrane and soluble fractions of Gluconobacter oxydans was investigated. Two proteins in the soluble fraction were found to have the ability to increase xylitol production. Both of these xylitol-increasing factors were purified, and on the basis of their NH(2)-terminal amino acid sequences the genes encoding both of the factors were cloned. Expression of the cloned genes in Escherichia coli showed that one of the xylitol-increasing factors is the bifunctional enzyme transaldolase/glucose-6-phosphate isomerase, and the other is ribulokinase. Using membrane and soluble fractions of G. oxydans, 3.8 g/l of xylitol were produced from 10 g/l D-arabitol after incubation for 40 h, and addition of purified recombinant transaldolase/glucose-6-phosphate isomerase or ribulokinase increased xylitol to 5.4 g/l respectively, confirming the identity of the xylitol-increasing factors.     

混合培养中巨大芽孢杆菌对氧化葡萄糖酸杆菌的作用

为查明维生素Ｃ二步发酵混合培养中巨大芽孢杆菌与氧化葡萄糖酸杆菌间的关系,通过生长曲线测定、静息细胞实验及摇瓶发酵实验研究了巨大芽孢杆菌对氧化葡萄糖酸杆菌生长和产生２－酮基－Ｌ－古龙酸作用的影响;采用超滤分离、凝胶层析及聚丙烯酰胺凝胶电泳技术对巨大芽孢杆菌胞外液中具有促进氧化葡萄糖酸杆菌产酸作用的活性物质进行了分离和纯化。结果表明,大菌胞内液和胞外液均可促进小菌生长,大菌胞外液中具有该作用的组分分子