High Rate Production in Static Culture of Bacterial Cellulose from Sucrose by a Newly Isolated Acetobacter Strain

For the industrial production of bacterial cellulose from sucrose in static cultures, the possibility of a high rate of cellulose production was investigated. An Acetobacter strain, S-35, which had been isolated from a grape, was selected from 1500 isolates. This strain was found to produce a large amount of cellulose from either glucose or fructose. Using this strain, high cellulose production rates of 3.3g/liter/d or 40g/m²/d from sucrose were seen in static culture.     

Production of cellulose from glucose by Acetobacter xylinum

Acetobacter xylinum 1FO 13693 was selected as the best cellulose-producing bacterium among 41 strains belonging to the genus Acetobacter and Agrobacterium. Cellulose was found to be produced at the liquid surface in static liquid cultivation. The rate of cellulose production depended proportionally on the surface-area of the culture medium and was unaffected by the depth and volume of the medium. The optimum pH for cellulose production was 4.0 to 6.0. Glucose, fructose and glycerol were preferred carbon sources for cellulose production. The yield of cellulose, relative to the glucose consumed, decreased with an increase in initial glucose concentration, and gluconic acid accumulated at a high initial glucose concentration. The decrease in cellulose yield could be due to some glucose being metabolized to gluconic acid. However, the accumulated gluconic acid did not affect cellulose production. The culture conditions of the bacterium for cellulose production were optimized. The maximum production rate of cellulose was 36 g/d·m², with a yield of 100% for added glucose under the optimal conditions.     

Utilization of agro-industrial orange peel and sugar beet pulp wastes for fungal endo- polygalacturonase production

The pectinase enzymes are involved in several industrial applications, and industrial waste is one of the largest environmental pollutants, so this study aims to Endo-polygalacturonase (endo-PG) producing using Aspergillus niger AUMC 4156, Penicillium oxalicum AUMC 4153 and P. variotii AUMC 4149 by using some agro-industrial wastes (dried orange peel and sugar beet pulp) as a sole raw carbon source for degradation these waste in the process of urban wastes disposal. The fermentation process was carried out as a submerged culture technique under both shaken and static culture conditions. A. niger AUMC 4156 was the most promising producer of endo-PG under static conditions while P. oxalicum AUMC 4153 was the highest producer of endo-PG under shaken conditions. Sugar beet pulp proved to be the most preferable to orange peel as the only source of carbon in both shaken and static cultures. The medium that encompassing orange peel as a single carbon source afforded the highest protein content with all tested fungal strains in stirred and static cultures in comparison with sugar beet pulp. The highest activity of endo-polygalacuronase that produced using A. niger AUMC 4156 and P. oxalicum AUMC 4153 was achieved by using sugar beet pulp at 3% concentration under static cultures, meanwhile maximal enzyme activity produced by both fungal strains required 2% sugar beet pulp under shaken cultures. Sugar beet pulp showed promised potential as a good inducer for endo-polygalacturoase production, and enzymes production depended on fungal strains, culture medium, and submerged fermentation conditions.     

Characterization of Cellulose Production by a Gluconacetobacter xylinus Strain from Kombucha

The aims of this work were to characterize and improve cellulose production by a Gluconoacetobacter xylinus strain isolated from Kombucha and determine the purity and some structural features of the cellulose from this strain. Cellulose yield in tea medium with both black tea and green tea and in Hestrin and Schramm (HS) medium under both static and agitated cultures was compared. In the tea medium, the highest cellulose yield was obtained with green tea (~0.20 g/L) rather than black tea (~0.14 g/L). Yield in HS was higher (~0.28 g/L) but did not differ between static and agitated incubation. ¹H-NMR and ¹³C-NMR spectroscopy indicated that the cellulose is pure (free of acetan) and has high crystallinity, respectively. Cellulose yield was improved by changing the type and level of carbon and nitrogen source in the HS medium. A high yield of ~2.64 g/L was obtained with mannitol at 20 g/L and corn steep liquor at 40 g/L in combination. In the tea medium, tea at a level of 3 g/L gave the highest cellulose yield and the addition of 3 g/L of tea to the HS medium increased cellulose yield to 3.34 g/L. In conclusion, the G. xylinus strain from Kombucha had different cellulose-producing characteristics than previous strains isolated from fruit. Cellulose was produced in a pure form and showed high potential applicability. Our studies extensively characterized cellulose production from a G. xylinus strain from Kombucha for the first time, indicating both similarities and differences to strains from different sources.     

Isolation and Screening of Alkaline Lipase-producing Fungi from Brazilian Savanna Soil

Summary Fifty-nine lipase-producing fungal strains were isolated from Brazilian savanna soil by employing enrichment culture tecniques. An agar plate medium containing bile salts and olive oil emulsion was employed for isolating and growing fungi in primary screening assay. Twenty-one strains were selected by the ratio of the lipolytic halo radius and the colonies radius. Eleven strains were considered good producers under conditions of submerged liquid fermentation (shaken cultures) and solid-state fermentation. The most productive strain, identified as Colletotrichum gloesporioides, produced 27,700 U/l of lipase under optimized conditions and the crude lipase preparation was capable of hydrolysing a broad range of substrates including lard, natural oils and tributyrin.     

Engineered cell-to-cell signalling within growing bacterial cellulose pellicles

Bacterial cellulose is a strong and flexible biomaterial produced at high yields by Acetobacter species and has applications in health care, biotechnology and electronics. Naturally, bacterial cellulose grows as a large unstructured polymer network around the bacteria that produce it, and tools to enable these bacteria to respond to different locations are required to grow more complex structured materials. Here, we introduce engineered cell-to-cell communication into a bacterial cellulose-producing strain of Komagataeibacter rhaeticus to enable different cells to detect their proximity within growing material and trigger differential gene expression in response. Using synthetic biology tools, we engineer Sender and Receiver strains of K. rhaeticus to produce and respond to the diffusible signalling molecule, acyl-homoserine lactone. We demonstrate that communication can occur both within and between growing pellicles and use this in a boundary detection experiment, where spliced and joined pellicles sense and reveal their original boundary. This work sets the basis for synthetic cell-to-cell communication within bacterial cellulose and is an important step forward for pattern formation within engineered living materials.     

Increased production of bacterial cellulose as starting point for scaled-up applications

Bacterial cellulose is composed of an ultrafine nanofiber network and well-ordered structure; therefore, it offers several advantages when used as native polymer or in composite systems.

In this study, a pool of 34 acetic acid bacteria strains belonging to Komagataeibacter xylinus were screened for their ability to produce bacterial cellulose. Bacterial cellulose layers of different thickness were observed for all the culture strains. A high-producing strain, which secreted more than 23 g/L of bacterial cellulose on the isolation broth during 10 days of static cultivation, was selected and tested in optimized culture conditions. In static conditions, the increase of cellulose yield and the reduction of by-products such as gluconic acid were observed. Dried bacterial cellulose obtained in the optimized broth was characterized to determine its microstructural, thermal, and mechanical properties. All the findings of this study support the use of bacterial cellulose produced by the selected strain for biomedical and food applications.

     

Production of bacterial cellulose by<Emphasis Type="Italic">Gluconacetobacter hansenii</Emphasis> PJK isolated from rotten apple

A cellulose-producing strain isolated from rotten apples was identified asGluconace-tobacter hansenii based on its physiological properties and the 16S rDNA complete sequencing method, and specifically namedGluconacetobacter hansenii PJK. The amount of bacterial cellulose (BC) produced byG. hansenii PJK in a shaking incubator was 1.5 times higher than that produced in a static culture. The addition of ethanol to the medium during cultivation enhanced the productivity of bacterial cellulose, plus the supplementation of 1% ethanol into the culture medium made the produced BC aggregate into a big lump and thus protected the bacterial-cellulose-producingG. hansenii PJK cells in the shear stress field from being converted into noncellulose-producing (Cel) mutants. Cells subcultured three times in a medium containing ethanol retained their ability to produce BC without any loss in the production yield.     

Synthesis of 20α- and 20β-Amino-3,5-pregnadiene Derivatives and Antimicrobial Activity

Cellulose production by Acetobacter strains is enhanced by the addition of a small amount of cellulose to the production culture. The effect of an endo-β-1, 4-glucanase from Bacillus subtilis on the cellulose production by Acebohacter xylinum BPR2001 was examined by adding various amounts of the purified glucanase to the culture. The addition of a small amount of this glucanase enhanced cellulose production. Furthermore, it reduced the amount of a polysaccharide called acetan produced. However, an active-site mutant enzyme of the glucanase, which showed no enzyme activity but still had cellulose-binding ability, had no effect on cellulose production. It was concluded, therefore, that the endoglucanase activity itself, but not the cellulose-binding ability, was essential for the enhancement of cellulose production. The structural properties of the cellulose produced in the presence of the endoglucanase were found to be almost identical to those of native bacterial cellulose.     

Formation of Highly Twisted Ribbons in a Carboxymethylcellulase Gene-Disrupted Strain of a Cellulose-Producing Bacterium

Cellulases are enzymes that normally digest cellulose; however, some are known to play essential roles in cellulose biosynthesis. Although some endogenous cellulases of plants and cellulose-producing bacteria are reportedly involved in cellulose production, their functions in cellulose production are unknown. In this study, we demonstrated that disruption of the cellulase (carboxymethylcellulase) gene causes irregular packing of de novo-synthesized fibrils in Gluconacetobacter xylinus, a cellulose-producing bacterium. Cellulose production was remarkably reduced and small amounts of particulate material were accumulated in the culture of a cmcax-disrupted G. xylinus strain (F2-2). The particulate material was shown to contain cellulose by both solid-state ¹³C nuclear magnetic resonance analysis and Fourier transform infrared spectroscopy analysis. Electron microscopy revealed that the cellulose fibrils produced by the F2-2 cells were highly twisted compared with those produced by control cells. This hypertwisting of the fibrils may reduce cellulose synthesis in the F2-2 strains.     

Enhancement of cellulose pellicle production by constitutively expressing vitreoscilla hemoglobin in Acetobacter xylinum

Vitreoscilla hemoglobin (VHb) gene driven by the constitutive bla promoter was expressed in the cellulose-producing Acetobacter xylinum. The expressed VHb was biochemically active and could enhance cell growth in a shaken culture containing cellulase. VHb-expressing A. xylinum (VHb+) exhibited a specific growth rate 50% higher than that of the host strain (VHb-). Probably because of its faster growth rate, the size of tentacled cellulose beads produced by VHb+ was about 20% of that produced by VHb- after 2 days cultivation in a shake-flask. When cultured statically, the amount of cellulose pellicle produced by VHb+ could be 2-fold that produced by VHb-. Cellulose pellicle concentration of 11 g/L was obtained for VHb+, whereas 6 g/L was obtained for VHb- after 6 days of microaerobic incubation.     

一株产纤维素酶细菌的筛选、鉴定及产酶条件优化

目的：筛选1株产纤维素酶的细菌。方法：通过对从腐烂朽木及其附近土壤中得到的样品进行富集培养、分离纯化得到16株纤维素分解菌,经刚果红染色鉴定和液体发酵培养后对其进行了菌种初步鉴定及产酶条件的初步优化。结果：获得1株纤维素酶分泌量较高的细菌LT3。结论：LT3为革兰氏阳性菌,菌体成杆状,经发酵优化培养后,较适产酶条件为甘蔗渣20g/L,pH7.0、30℃培养120h,CMC酶活为71.17U/mL,滤纸酶活为33.37U/mL。通过克隆其16S rDNA序列,对其进行系统进化分析,鉴定为蜡状芽孢杆菌。     

Adaptive mutation related to cellulose producibility in <Emphasis Type="Italic">Komagataeibacter medellinensis</Emphasis> (<Emphasis Type="Italic">Gluconacetobacter xylinus</Emphasis>) NBRC 3288

Gluconacetobacter xylinus (formerly Acetobacter xylinum and presently Komagataeibacter medellinensis) is known to produce cellulose as a stable pellicle. However, it is also well known to lose this ability very easily. We investigated the on and off mechanisms of cellulose producibility in two independent cellulose-producing strains, R1 and R2. Both these strains were isolated through a repetitive static culture of a non-cellulose-producing K. medellinensis NBRC 3288 parental strain. Two cellulose synthase operons, types I and II, of this strain are truncated by the frameshift mutation in the bcsBI gene and transposon insertion in the bcsCII gene, respectively. The draft genome sequencing of R1 and R2 strains revealed that in both strains the bcsBI gene was restored by deletion of a nucleotide in its C-rich region. This result suggests that the mutations in the bcsBI gene are responsible for the on and off mechanism of cellulose producibility. When we looked at the genomic DNA sequences of other Komagataeibacter species, several non-cellulose-producing strains were found to contain similar defects in the type I and/or type II cellulose synthase operons. Furthermore, the phylogenetic relationship among cellulose synthase genes conserved in other bacterial species was analyzed. We observed that the cellulose genes in the Komagataeibacter shared sequence similarities with the γ-proteobacterial species but not with the α-proteobacteria and that the type I and type II operons could be diverged from a same ancestor in Komagataeibacter.     

A Host–Vector System for a Cellulose-Producing Acetobacter Strain

An indigenous plasmid, named pAH4, was detected in a cellulose-producing Acetobacter strain. This plasmid, consisting of 4002 bp, contained an AT-rich region and encoded several open reading frames, as deduced by the complete nucleotide sequence. One of the putative open reading frames showed homology with replication proteins of other plasmids. A shuttle vector of Escherichia coli and this strain was constructed by connecting pAH4 to pUC18. Electroporation of the shuttle vector into the strain yielded 1.7 × 10⁵ ampicillin resistant transformants per μg DNA. The shuttle plasmid was very stably maintained in the strain.     

Development and production of cholesterol-lowering <Emphasis Type="Italic">Monascus</Emphasis>-nata complex

This study develops a new foodstuff, the Monascus-nata complex, which combines the functions of cholesterol-lowering monacolin k and bacterial dietary-fibre. Two Monascus strains, M. ruber and M. pilosus were fermented within cubical bacterial cellulose, nata de coco, obtained from Acetobacter fermented coconut juice, in a conditioned medium. The production levels and stability of monacolin k in the cultured Monascus-nata complex were determined to develop optimal fermentation conditions. The results indicated that a medium that comprised 5% glucose and 1.5% ammonium phosphate at pH 6.0–7.0 produced the most monacolin k (157 mg/l) for Monascus pilosus NCHU M-35. However, monosodium glutamate (MSG) and 0.001% ZnSO₄ inhibited the intracellular accumulation of monacolin k. Monacolin k within the Monascus-nata complex was relatively resistant to washing and changes of pH, but thermal processing and freezing storage markedly reduced the amount present. This novel Monascus-nata complex is potentially a healthy foodstuff.     

Modulation of glycolysis induction in primary cultures of rabbit kidney proximal tubule cells: the role of shaking,glucose and insulin.

We have assessed the impact of increasing oxygen availability on cellular phenotype expression of rabbit proximal tubule cells in primary culture developed with variable glucose and/or insulin contents. To mitigate hypoxia at the cell/medium interface, cells were shaken for the whole culture duration and their expressed phenotype was compared with those expressed by static cultures. O₂ and CO₂ tensions were kept constant in the incubator atmosphere. Glycolysis and gluconeogenesis pathways, detoxication system, and mitochondrial, apical and basolateral membrane marker enzyme activities were assessed. This study showed that the induction of glycolysis which appear in primary cultures of proximal tubule cells may be partially prevented by continuously shaking the cultures. This effect was more marked in the presence of glucose, suggesting better substrate oxidation in shaken cultures.     

一株东方醋酸杆菌分离与其促进果蝇生长发育

【目的】分离与鉴定黑腹果蝇体内醋酸杆菌,并研究其对宿主生长发育的促进作用。【方法】利用醋酸杆菌选择性培养基分离果蝇肠道醋酸杆菌;通过革兰氏染色和16S rRNA基因比对鉴定菌种;肠道定植实验验证共生关系;发育历期和生长速率实验检测其促进果蝇生长作用;免疫荧光染色技术检测肠道细胞增殖;RT-PCR法检测促生长的分子标志物和相关的信号通路。【结果】菌株为东方醋酸杆菌(Acetobacter orientalis),可以持续地定植在果蝇肠道及其培养基中,并且明显促进果蝇的生长。东方醋酸杆菌通过胰岛素信号通路增加肠分裂细胞的数量和促进蜕皮激素的分泌。【结论】东方醋酸杆菌是果蝇的一种共生菌,对果蝇肠道结构和机体发育具有重要的作用。     

Factors affecting the yield and properties of bacterial cellulose

Acetobacter xylinum E₂₅ has been applied in our studies in order to find optimal culture conditions for effective bacterial cellulose (BC) production. The strain displays significantly higher stability in BC production under stationary culture conditions. In contrast, intensive agitation and aeration appear to drastically reduce cellulose synthesis since such conditions induced formation of spontaneous cellulose nonproducing mutants (Cel−), which dominated in the culture. Mutation frequency strictly depends on the medium composition in agitated cultures. Enrichment of the standard SH and Yamanaka media with 1% ethanol significantly enhanced BC production in stationary cultures. Horizontal fermentors equipped with rotating discs or rollers were successfully applied in order to improve culture conditions. Relatively slow rotation velocity (4 rpm) and large surface area enabling effective cell attachment are optimal parameters for cellulose production. Physical properties of BC samples synthesized either in stationary cultures or in a horizontal fermentor revealed that cellulose from stationary cultures demonstrated a much higher value of Young's modulus, but a much lower value of water-holding capacity. Journal of Industrial Microbiology & Biotechnology (2002) 29, 189–195 doi:10.1038/sj.jim.7000303 Received 01 March 2002/ Accepted in revised form 18 July 2002     

Effective cellulose production by a coculture of Gluconacetobacter xylinus and Lactobacillus mali

A microbial colony that contained a marked amount of cellulose was isolated from vineyard soil. The colony was formed by the associated growth of two bacterial strains: a cellulose-producing acetic acid bacterium (st-60-12) and a lactic acid bacterium (st-20). The 16S rDNA-based taxonomy indicated that st-60-12 belonged to Gluconacetobacter xylinus and st-20 was closely related to Lactobacillus mali. Cocultivation of the two organisms in corn steep liquor/sucrose liquid medium resulted in a threefold higher cellulose yield when compared to the st-60-12 monoculture. A similar enhancement was observed in a coculture with various L. mali strains but not with other Lactobacillus spp. The enhancement of cellulose production was most remarkable when sucrose was supplied as the substrate. L. mali mutants for exocellular polysaccharide (EPS) production were defective in promoting cellulose production, but the addition of EPS to the monoculture of st-60-12 did not affect cellulose productivity. Scanning electron microscopic observation of the coculture revealed frequent association between the st-60-12 and L. mali cells. These results indicate that cell–cell interaction assisted by the EPS-producing L. mali promotes cellulose production in st-60-12.The nucleotide sequences of 16S rDNA that are reported in this paper were submitted to GenBank/EMBL/DDBJ under the accession numbers AB016864 (st-20) and AB016865 (st-60-12).     

Correlation of actinomycin X2 to the lipid profile in static and shaken cultures of Streptomyces nasri strain YG62

Streptomyces nasri strain YG62 produces a broad-spectrum antibiotic designated actinomycin X2. The influence of static and shaken incubation on the production of actinomycin X2 and lipid profiles of S. nasri strain YG62 was investigated. It was found that shaken incubation was superior to the static process for both actinomycin X2 (2-fold) and total lipids (1.6-fold). Triglyceride and phospholipid levels paralleled the actinomycin X2 production with an increase in the triglyceride (2.8-fold) and phospholipid (1.2-fold) concentrations in the shaken culture over the static incubation. Analysis of fatty acid patterns revealed the occurrence of a wide range of fatty acids (C10-C22). The mean percentage of total saturated fatty acids in shaken culture was higher than those of the static culture. The mean percentage of mono-unsaturated fatty acids was almost the same in both cultures. The mean percentage of the total polyunsaturated fatty acids in the static culture was slightly higher than that of the shaken culture. The polyunsaturated/saturated fatty acid ratio (P/S) was higher in the static culture compared with the shaken culture. A positive correlation was recorded between triglycerides, phospholipids and actinomycin X2. A negative correlation on the other hand, was found between fatty acids and actinomycin X2.