Relationship between Sulfaguanidine Resistance and Increased Cellulose Production in Acetobacter xylinum BPR3001E

The mechanism of the increased cell growth and cellulose production of Acetobacter xylinum subsp. sucrofermentans BPR3001E, a sulfaguanidine (SG)-resistant mutant, was investigated. We found that adding p-aminobenzoic acid (PABA) to cultures of the parent strain, BPR2001, led to increased levels of intracellular adenosine-related purine compounds and increased cellulose production. Furthermore, adding ATP increased the cellulose production by permeabilized BPR2001 cells. On the other hand, the intracellular levels of PABA and adenosine-related purine compounds in BPR3001E cells were higher than those in BPR2001 cells. These results suggest that SG resistance increases enhance cellulose production through increased levels of intracellular high-energy compounds caused by increased PABA biosynthesis, reflecting the promoted supply of cellulose precursors.     

Features of bacterial cellulose synthesis in a mutant generated by disruption of the diguanylate cyclase 1 gene of <Emphasis Type="Italic">Acetobacter xylinum</Emphasis> BPR 2001

The diguanylate cyclase 1 (DGC1) (dgc1) gene in Acetobacter xylinum BPR 2001—a bacterial cellulose (BC) producer—was cloned and sequenced, and a DGC1 gene-disrupted mutant, strain DD, was constructed. The production and structural characteristics of the BC formed by DD were compared with those of the parental strain BPR 2001. BC production by DD was almost the same as that by BPR 2001 in static cultivation and in shake flask cultivation. However, in a jar fermentor DD produced about 36% more BC than the parental strain. DD produced suspended particle materials that cannot aggregate owing to their random structural characteristics in static cultivation; more uniformly dispersed BC pellicles and smaller BC pellets are produced on average in a jar fermentor, as reflected by the higher BC production by DD than by the parental strain in a jar fermentor. Micrographs of BC produced by DD revealed that the width of cellulose ribbons assemblies decreased as a result of differences in the ultrastructure and mechanism of formation of BC between the two strains. These results reveal that disruption of the dgc1 gene, which catalyzes synthesis of c-di-GMP (an effector of BC synthase), is not fatal for BC synthesis, although it affects BC structure.     

Resistin and RELM-alpha gene expression in white adipose tissue of lactating mice

An ORF2 gene located upstream of the cellulose synthase (bcs) operon of Acetobacter xylinum BPR2001 was disrupted and a mutant (M2-2) was constructed. In static cultivation, the parent strain produced a tough, colorless, and insoluble cellulose pellicle, whereas M2-2 culture produced a thin, yellow, and fragile pellicle. The results of X-ray diffraction and 13C solid-state NMR indicated that the product of M2-2 is a mixture of cellulose I, cellulose II, and amorphous cellulose. The cellulose I to cellulose II ratio of the mixture was evaluated from the signal areas of C6 to be about 1:2. Electron microscopy revealed that the product of M2-2 included ribbon-like cellulose and irregularly shaped particles attached to the ribbons. On the other hand, the mutant complemented with plasmid pSA-ORF2/k containing the ORF2 gene and BPR2001 produced only cellulose I. These results indicate that the ORF2 gene is involved in the production and crystallization of cellulose I microfibrils by this microorganism.     

Screening of Bacterial Cellulose-producing Acetobacter Strains Suitable for Agitated Culture

Extensive screening for cellulose-producing Acetobacter strains suitable for agitated culture was done by developing the screening conditions. A total of 2096 strains were isolated; isolation from fruits was particularly efficient. The cellulose productivities of 412 isolates were estimated by culturing in two different media under both shaken and static conditions. No correlation between the amounts of cellulose accumulated in shaken and static cultures was observed. Higher cellulose accumulation was obtained in the shaken cultures using a corn steep liquor/fructose-based medium than a conventional yeast extract/peptone/glucose-based one. Many isolates showed higher cellulose accumulation than well-known cellulose-producing strains. The producer that yielded the highest cellulose accumulation in shaken culture was selected and named Acetobacter sp. BPR 2001. Using this strain, cellulose was produced in a jar fermentor.     

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.     

Breeding of a 5-Fluorouridine-resistant Mutant with Increased Cellulose Production from Acetobacter xylinum subsp. nonacetoxidans

UDP-glucose (UDP-G), the direct precursor of cellulose, is known to be produced from UTP and glucose-1-phosphate. In an attempt to increase UTP biosynthesis, 5-fluorouridine (5-FUR: a pyrimidine analog)-resistant mutants were obtained using Acetobacter xylinum subsp. nonacetoxidans 757 as the parent strain. One of the 5-FUR-resistant mutants, FUR-35, showed about 40% higher cellulose productivion compared to the parent strain. Intracellular levels of UTP and UDP-G in FUR-35 was found to be higher than those in the parent strain. The carbamyl phosphate synthetase II (CPS) activity of FUR-35 was higher than that of the parent strain and the feedback inhibition of CPS by UTP in FUR-35 had been released compared with that in the parent strain. These results suggest that the increased cellulose production of FUR-35 was attributable to its higher of intracellular UDP-G level resulting from increased UTP biosynthesis.     

Role of water-soluble polysaccharides in bacterial cellulose production

Acetobacter xylinum BPR2001 produces water-insoluble bacterial cellulose (BC) and a water-soluble polysaccharide called acetan in corn steep liquor-fructose medium. Acetobacter xylinum EP1, which is incapable of acetan production was derived by disrupting the aceA gene of BPR2001. The BC production by EP1 (2.88 g/L) was lower than that by BPR2001 (4.6 g/L) in baffled-flask culture. When purified acetan or agar was added to the medium from the start of cultivation, the BC production by EP1 was enhanced and the final BC yield of EP1 was almost the same as that of BPR2001. A similar improvement of BC production by EP1 by the addition of agar was also confirmed by cultivation in a 50-L airlift reactor. From these results, the role of acetan in BC production is associated with the increase in the viscosity of the culture medium which may hinder coagulation of BC and cells in the culture, thereby accelerating the growth of BPR2001 and BC production by BPR2001.     

Intermediatry steps in Acetobacter xylinum cellulose synthesis: studies with whole cells and cell-free preparations of the wild type and a celluloseless mutant.

Intermediatry steps in cellulose synthesis in Acetobacter xylinum were studied with resting cells and particulate-membranous preparations of the wild-type strain and of a celluloseless mutant. Exogenously supplied [1-14C]glucose was rapidly converted by resting cells of both types into glucose 6-phosphate, glucose 1-phosphate, and uridine glucose 5'-diphosphate (UDP)-glucose and incorporated into lipid-, water-, and alkali-soluble cellular fractions. The decrease in the level of labeled hexose-phosphates and UDP-glucose upon depletion of the exogenous substrate was accounted for by a continuous incorporation of [14C]glucose into cellulose in the wild type and into the above-mentioned cellular components in the mutant. [14C]glucose retained in the alkali- and water-soluble fractions of pulse-labeled wild-type cells was quantitatively chased into cellulose. Sonic extracts of both strains catalyzed the transfer of glucose from UDP-glucose into lipid-, water-, and alkali-soluble materials, as well as into an alkali-insoluble cellulosic beta-1,4-glucan. The results strongly support the sequence glucose leads to glucose 6-phosphate leads to glucose 1-phosphate leads to UDP-glucose leads to cellulose and indicate that lipid- and protein-linked cellodextrins may function as intermediates between UDP-glucose and cellulose in A. xylinum.     

Biosynthesis and function of trehalose inEctothiorhodospira halochloris

Trehalose-6-phosphate synthase, catalyzing the reaction between UDP-glucose and glucose 6-phosphate and forming trehalose 6-phosphate, was isolated and partially purified (30-fold) from the phototrophic, haloalkaliphilic bacteriumEctothiorhodospira halochloris. The activity is stabilized by 20mM MgCl₂, 50mM NaCe and 2M glycine betaine. The molecular weight was 63000.The enriched enzyme had a MgCl₂ optimum at 3–6mM, a pH optimum at 7.5 (in Tris-HCl buffer) and a temperature optimum at 50°C. The K_m-values were 1.5×10^–3M for UDP-glucose and 2×10^–3M for glucose 6-phosphate. The enzyme showed a salinity dependence with optimal concentrations between 100 and 300mM salt. Higher concentrations of salt resulted in a decrease in activity. In the presence of inhibitory salt concentrations the compatible solute glycine betaine had a protective effect with a maximum between 0.5 and 2.0M.     

CugP Is a Novel Ubiquitous Non-GalU-Type Bacterial UDP-Glucose Pyrophosphorylase Found in Cyanobacteria

UDP-glucose pyrophosphorylase synthesizes UDP-glucose from UTP and glucose 1-phosphate and exists in almost all species. Most bacteria possess a GalU-type UDP-glucose pyrophosphorylase, whereas many cyanobacteria species do not. In certain cyanobacteria, UDP-glucose is used as a substrate for synthesis of exopolysaccharide cellulose in spite of the absence of GalU-type UDP-glucose pyrophosphorylase. Therefore, there should be an uncharacterized UDP-glucose pyrophosphorylase in cyanobacteria. Here, we show that all cyanobacteria possess a non-GalU-type bacterial UDP-glucose pyrophosphorylase, i.e., CugP, a novel family in the nucleotide triphosphate transferase superfamily. The expressed recombinant Synechocystis sp. strain PCC 6803 CugP had pyrophosphorylase activity that was highly specific for UTP and glucose 1-phosphate. The fact that the CugP gene cannot be deleted completely in Synechocystis sp. PCC 6803 suggests its central role as the substrate supplier for galactolipid synthesis. Galactolipids are major constituents of the photosynthetic thylakoid membrane and important for photosynthetic activity. Based on phylogenetic analysis, this CugP-type UDP-glucose pyrophosphorylase may have recently been horizontally transferred to certain noncyanobacteria.     

Effects of acetan on production of bacterial cellulose by Acetobacter xylinum

Acetan is a water-soluble polysaccharide produced by a bacterial cellulose (BC) producer, Acetobacter xylinum. An acetan-nonproducing mutant, EP1, was generated from wild-type A. xylinum BPR2001 by the disruption of aceA, which may act to catalyze the first step of the acetan biosynthetic pathway in this bacterium. EP1 produced less BC than the wild-type strain. However, when EP1 was cultured in a medium containing acetan, BC production was stimulated and the final yield of BC was equivalent to that of BPR2001. The culture broth containing acetan was more viscous and the free cell number was higher than that of the broth without the polysaccharide, so acetan may hinder the coagulation of BC in the broth. The addition of 1.5 g/l agar also increased BC production; we concluded that acetan and BC syntheses were not directly related on the genetic level.     

Utilization of the buffering capacity of corn steep liquor in bacterial cellulose production by Acetobacter xylinum

Acetobacter xylinum BPR2001 produces water-insoluble bacterial cellulose (BC). Using a pH sensor for the accurate control of pH, which is one of the most critical factors for efficient BC production, is difficult especially in a baffled shake-flask and an airlift reactor. The buffering capacity of corn steep liquor (CSL) was estimated by measuring (buffering capacity) values in advance and was used to maintain the pH within the optimal range during the production of BC. When CSL was added to either a shake-flask, a stirred-tank reactor or an airlift reactor, BC production was almost the same as that in cultivations where pH was controlled manually or by a pH sensor.     

Enhancement of crystallinity of cellulose produced by <Emphasis Type="Italic">Escherichia coli</Emphasis> through heterologous expression of <Emphasis Type="Italic">bcsD</Emphasis> gene from <Emphasis Type="Italic">Gluconacetobacter xylinus</Emphasis>

Objectives

To evaluate the crystallinity index of the cellulose produced by Escherichia coli Nissle 1917 after heterologous expression of the cellulose synthase subunit D (bcsD) gene of Gluconacetobacter xylinus BPR2001.

Results

The bcsD gene of G. xylinus BPR2001 was expressed in E. coli and its protein product was visualized using SDS-PAGE. FTIR analysis showed that the crystallinity index of the cellulose produced by the recombinants was 0.84, which is 17% more than that of the wild type strain. The increased crystallinity index was also confirmed by X-ray diffraction analysis. The cellulose content was not changed significantly after over-expressing the bcsD.

Conclusion

The bcsD gene can improve the crystalline structure of the bacterial cellulose but there is not any significant difference between the amounts of cellulose produced by the recombinant and wild type E. coli Nissle 1917.

     

Regulatory aspects of glycosaminoglycan biosynthesis

The control of glycosaminoglycan biosynthesis was investigated by studying the kinetic and regulatory properties of some enzymes involved in the formation of UDP-sugar precursors: UDP-N-acetylglucosamine 4'-epimerase, catalyzing the interconversion of hexosamine precursors and UDP-glucose dehydrogenase and UDP-glucose 4'-epimerase, utilizing UDP-glucose for the formation of uronic acid and galactose precursors. The study was carried out in tissues with different glycosaminoglycan production: bovine cornea, producing both chondroitin sulfate and keratan sulfate, and newborn-pig epiphysial-plate cartilage, producing mostly chondroitin sulfate. The biosynthesis of hexosamine precursors appeared to be regulated by the value of the NAD/NADH ratio. This control mechanism regulated also the activities of both UDP-glucose dehydrogenase and UDP-glucose 4'-epimerase and, therefore, it could correlate the biosynthesis of glycosaminoglycan precursors with the redox activity of the cell. At the level of UDP-glucose utilization two other control mechanisms were demonstrated: the different affinities of UDP-glucose dehydrogenase and UDP-glucose 4'-epimerase for UDP-glucose in tissues with different glycosaminoglycan production and the cellular concentration of UDP-xylose. This sugar-nucleotide inhibited UDP-glucose dehydrogenase, but did not affect the UDP-glucose 4'-epimerase activity; therefore, and increase of its cellular concentration may result in a decreased chondroitin sulfate synthesis and in an increased keratan sulfate formation.     

Production of bacterial cellulose by Acetobacter xylinumwith an air-lift reactor

Bacterial cellulose was produced by Acetobacter xylinum subsp. surcrofermentans BPR2001 in a 50 liter air-lift reactor using fructose as the main carbon source. When air was supplied, the production of the cellulose was only 2.3 g/l in 80 h but when O -fortified air was supplied, the cellulose concentration increased to 5.63 g/l in 28 h and the productivity of the cellulose in an air-lift reactor with O -fortified air supply was comparable to that in a mechanically agitated jar fermenter.     

Novel characteristics of UDP-glucose dehydrogenase activities in maize: non-involvement of alcohol dehydrogenases in cell wall polysaccharide biosynthesis

UDP-glucose dehydrogenase (UDPGDH) activity was detected in extracts of maize cell-cultures and developing leaves. The reaction product was confirmed as UDP-glucuronate. Leaf extracts from null mutants defective in one or both of the ethanol dehydrogenase genes, ADH1 and ADH2, had similar UDPGDH activities to wild-type, showing that UDPGDH activity is not primarily due to ADH proteins. The mutants showed no defect in their wall matrix pentose:galactose ratios, or matrix:cellulose ratio, showing that ADHs were not required for normal wall biosynthesis. The majority of maize leaf UDPGDH activity had K _m (for UDP-glucose) 0.5–1.0 mM; there was also a minor activity with an unusually high K _m of >50 mM. In extracts of cultured cells, kinetic data indicated at least three UDPGDHs, with K _m values (for UDP-glucose) of roughly 0.027, 2.8 and >50 mM (designated enzymes E_L, E_M and E_H respectively). E_M was the single major contributor to extractable UDPGDH activity when assayed at 0.6–9.0 mM UDP-Glc. Most studies, in other plant species, had reported only E_L-like isoforms. Ethanol (100 mM) partially inhibited UDPGDH activity assayed at low, but not high, UDP-glucose concentrations, supporting the conclusion that at least E_H activity is not due to ADH. At 30 μM UDP-glucose, 20–150 μM UDP-xylose inhibited UDPGDH activity, whereas 5–15 μM UDP-xylose promoted it. In conclusion, several very different UDPGDH isoenzymes contribute to UDP-glucuronate and hence wall matrix biosynthesis in maize, but ADHs are not responsible for these activities.     

Existence of Cerebroside-like Lipid in Rice Oil

A particulate enzyme fraction capable of catalyzing the transfer of glucose from UDP-glucose to β-glucan was prepared from the mycelium and protoplasts of Pyricularia oryzae P₂. An assay method for the β-glucan synthase was developed. About 80% of the β-glucan synthase activity was found in the pellet obtained on centrifugation at 28,000 × g for 30min. The particulate enzyme preparation showed β-glucan and glycogen synthase activities, in a ratio of 7:3. The optimum temperature and pH of the enzyme were found to be 20°C and 7.0, respectively. The glucan synthase activity increased 5.7-fold in 5 hr after the onset of protoplast regeneration.     

Increased cellulose production by heterologous expression of bcsA and B genes from Gluconacetobacterxylinus in E. coli Nissle 1917

Bioprocess and Biosystems Engineering - Based on cellulose biosynthesis pathway of Gluconacetobacterxylinus BPR2001 and E. coli Nissle 1917, bcsA and bcsB genes have been selected and...     

Isolation and Structure Elucidation of α Substance-IB,a Hexapeptide Inducing Sexual Agglutination in Saccharomyces cerevisiae

Cellulose triacetate prepared from bacterial cellulose of Acetobacter xylinum subsp. sucrofermentans BPR3001A showed a higher degree of polymerization and higher mechanical strength than that from the cotton linter. The fine fibrils of bacterial cellulose required only a short time for acetylation which preserved the high degree of polymerization.     

Recent progress in cellulose biosynthesis

Cellulose comprises the major polymer of the plant cell wall. It consists of a set of parallel chains composed of glucans and these chains are highly oriented to form a structure known as a microfibril. The orientation of the microfibrils controls the extension of the direction of the plant cell. Extensive studies on the cellulose biosynthesis have been carried out for over three decades, and recently (1996) genes for cellulose biosynthesis in plants (CesA) were isolated. In the year 2002, a specific primer for cellulose biosynthesis reaction has been discovered and cellulose synthetic activity has been also confirmed by recombinant protein derived from the plant CesA gene. Furthermore, other proteins involved in cellulose biosynthesis besides CesA proteins were also proposed at the same time. One of these proteins, Korrigan cellulase, was suggested to act by removing sitosterol from the primer for biosynthesis reaction of cellulose. A membrane-bound sucrose synthase was also suggested to provide UDP-glucose as a substrate for cellulose biosynthesis. On the basis of these results, a new pathway for cellulose biosynthesis was proposed. Now, the research field of cellulose biosynthesis is facing a major turning point. Electronic Publication