Pyrrolnitrin Production by an Enterobacter agglomerans Strain with a Broad Spectrum of Antagonistic Activity Towards Fungal and Bacterial Phytopathogens

Strain IC1270 of Enterobacter agglomerans has been previously described as a producer of a complex of chitinolytic enzymes and as an antagonist of many fungal phytopathogens [Chernin et al. (1995) Appl. Env. Microbiol. 61:1720–1726]. Here we show that this strain also produces an antibiotic that was purified by TLC and HPLC and identified by UV, IR, MS, and NMR analyses as pyrrolnitrin [3-chloro-4-(2′-nitro-3′-chlorophenyl)pyrrole]. The purified antibiotic is efficient against many phytopathogenic bacteria and fungi in vitro. This is the first piece of evidence showing that pyrrolnitrin can be produced by bacteria other than Pseudomonas and that one bacterial strain can simultaneously produce chitinolytic enzymes and pyrrolnitrin. The possible role of a combination of chitinases and pyrrolnitrin in antagonism is discussed.     

Biodegradation of Chlorpyrifos by Enterobacter Strain B-14 and Its Use in Bioremediation of Contaminated Soils

Six chlorpyrifos-degrading bacteria were isolated from an Australian soil and compared by biochemical and molecular methods. The isolates were indistinguishable, and one (strain B-14) was selected for further analysis. This strain showed greatest similarity to members of the order Enterobacteriales and was closest to members of the Enterobacter asburiae group. The ability of the strain to mineralize chlorpyrifos was investigated under different culture conditions, and the strain utilized chlorpyrifos as the sole source of carbon and phosphorus. Studies with ring or uniformly labeled [¹⁴C]chlorpyrifos in liquid culture demonstrated that the isolate hydrolyzed chlorpyrifos to diethylthiophospshate (DETP) and 3, 5, 6-trichloro-2-pyridinol, and utilized DETP for growth and energy. The isolate was found to possess mono- and diphosphatase activities along with a phosphotriesterase activity. Addition of other sources of carbon (glucose and succinate) resulted in slowing down of the initial rate of degradation of chlorpyrifos. The isolate degraded the DETP-containing organophosphates parathion, diazinon, coumaphos, and isazofos when provided as the sole source of carbon and phosphorus, but not fenamiphos, fonofos, ethoprop, and cadusafos, which have different side chains. Studies of the molecular basis of degradation suggested that the degrading ability could be polygenic and chromosome based. Further studies revealed that the strain possessed a novel phosphotriesterase enzyme system, as the gene coding for this enzyme had a different sequence from the widely studied organophosphate-degrading gene (opd). The addition of strain B-14 (10⁶ cells g⁻¹) to soil with a low indigenous population of chlorpyrifos-degrading bacteria treated with 35 mg of chlorpyrifos kg⁻¹ resulted in a higher degradation rate than was observed in noninoculated soils. These results highlight the potential of this bacterium to be used in the cleanup of contaminated pesticide waste in the environment.     

Proteomic Analysis of Anti-Cancerous Scopularide Production by a Marine Microascus brevicaulis Strain and Its UV Mutant

The marine fungus Microascus brevicaulis strain LF580 is a non-model secondary metabolite producer with high yields of the two secondary metabolites scopularides A and B, which exhibit distinct activities against tumour cell lines. A mutant strain was obtained using UV mutagenesis, showing faster growth and differences in pellet formation besides higher production levels. Here, we show the first proteome study of a marine fungus. Comparative proteomics were applied to gain deeper understanding of the regulation of production and of the physiology of the wild type strain and its mutant. For this purpose, an optimised protein extraction protocol was established. In total, 4759 proteins were identified. The central metabolic pathway of strain LF580 was mapped using the KEGG pathway analysis and GO annotation. Employing iTRAQ labelling, 318 proteins were shown to be significantly regulated in the mutant strain: 189 were down- and 129 upregulated. Proteomics are a powerful tool for the understanding of regulatory aspects: The differences on proteome level could be attributed to limited nutrient availability in the wild type strain due to a strong pellet formation. This information can be applied for optimisation on strain and process level. The linkage between nutrient limitation and pellet formation in the non-model fungus M. brevicaulis is in consensus with the knowledge on model organisms like Aspergillus niger and Penicillium chrysogenum.     

Structure of the exopolysaccharide produced by Enterobacter amnigenus

The bacterial species Enterobacter amnigenus was isolated from sugar beets harvested in Finland. It produced an exopolysaccharide rich in l-fucose, which gave viscous water solutions. Its primary structure was determined mainly by NMR spectroscopy and ESIMS of oligosaccharides and a polysaccharide with decreased molecular weight, obtained by Smith degradation of the O-deacetylated native polymer [carbohydrate structure: see text]     

Plasmid-associated Bacteriocin Production by a Lactobacillus plantarum Strain

A Lactobacillus plantarum strain, LTF154, isolated from a fermented sausage, produces a bacteriocin, designated plantacin 154. Plantacin 154 was stable to heat treatment, and its activity was sensitive to proteolytic enzymes. The molecular mass, as indicated by activity detection after SDS-PAGE, was estimated to be 3.0 kDa or less. A plasmid-curing experiment and transformation analysis indicated that a 9.5-MDa plasmid, pLP1542, may be involved in the production of plantacin 154.     

Pectin Lyase Production by a Penicillium italicum Strain

Growth and concomitant production of an extracellular pectin lyase (PL) [poly(methoxylgalactosiduronate) endolyase; EC 4.2.2.10] were investigated in a group of 16 fungi grown in liquid medium containing pectin as a supplementary carbon source. Culture filtrates of both Penicillium italicum (CECT 2294) and P. expansum (CECT 2275) showed the highest PL activity and contained polygalacturonase but not pectinesterase activity. The effect of the inoculum size, the carbon source (sucrose and glucose syrup), and the presence of pectin on the production of PL by P. italicum was studied. The presence of 2.6 mM glycerophosphate in the culture medium enhanced the appearance of PL but was not inhibitory for the in vitro activity. However, glycerol inhibited the enzyme nearly 50% at such a concentration.     

Production of 2,3-butanediol by newly isolated Enterobacter cloacae

Enterobacter cloacae NRRL B-23289 was isolated from local decaying wood/corn soil samples while screening for microorganisms for conversion of l-arabinose to fuel ethanol. The major product of fermentation by the bacterium was meso-2,3-butanediol (2,3-BD). In a typical fermentation, a BD yield of 0.4 g/g arabinose was obtained with a corresponding productivity of 0.63 g/l per hour at an initial arabinose concentration of 50 g/l. The effects of initial arabinose concentration, temperature, pH, agitation, various monosaccharides, and multiple sugar mixtures on 2,3-BD production were investigated. BD productivity, yield, and byproduct formation were influenced significantly within these parameters. The bacterium utilized sugars from acid plus enzyme saccharified corn fiber and produced BD (0.35 g/g available sugars). It also produced BD from dilute acid pretreated corn fiber by simultaneous saccharification and fermentation (0.34 g/g theoretical sugars). Received: 17 December 1998 / Revision received: 9 March 1999 / Accepted: 20 March 1999     

Genetic Engineering of Enterobacter asburiae Strain JDR-1 for Efficient Production of Ethanol from Hemicellulose Hydrolysates

Dilute acid pretreatment is an established method for hydrolyzing the methylglucuronoxylans of hemicellulose to release fermentable xylose. In addition to xylose, this process releases the aldouronate methylglucuronoxylose, which cannot be metabolized by current ethanologenic biocatalysts. Enterobacter asburiae JDR-1, isolated from colonized wood, was found to efficiently ferment both methylglucuronoxylose and xylose in acid hydrolysates of sweet gum xylan, producing predominantly ethanol and acetate. Transformation of E. asburiae JDR-1 with pLOI555 or pLOI297, each containing the PET operon containing pyruvate decarboxylase (pdc) and alcohol dehydrogenase B (adhB) genes derived from Zymomonas mobilis, replaced mixed-acid fermentation with homoethanol fermentation. Deletion of the pyruvate formate lyase (pflB) gene further increased the ethanol yield, resulting in a stable E. asburiae E1(pLOI555) strain that efficiently utilized both xylose and methylglucuronoxylose in dilute acid hydrolysates of sweet gum xylan. Ethanol was produced from xylan hydrolysate by E. asburiae E1(pLOI555) with a yield that was 99% of the theoretical maximum yield and at a rate of 0.11 g ethanol/g (dry weight) cells/h, which was 1.57 times the yield and 1.48 times the rate obtained with the ethanologenic strain Escherichia coli KO11. This engineered derivative of E. asburiae JDR-1 that is able to ferment the predominant hexoses and pentoses derived from both hemicellulose and cellulose fractions is a promising subject for development as an ethanologenic biocatalyst for production of fuels and chemicals from agricultural residues and energy crops.Lignocellulosic resources, including forest and agricultural residues and evolving energy crops, offer benign alternatives to petroleum-based resources for production of fuels and chemicals. As renewable resources, these lignocellulosic materials are expected to decrease dependence on exhaustible supplies of petroleum and mitigate the net release of carbon dioxide into the atmosphere. The development of economically acceptable bioconversion processes requires pretreatments that release the maximal quantities of hexoses (predominantly glucose released from cellulose) and pentoses (arabinose and xylose) from hemicelluloses and also requires microbial biocatalysts that efficiently convert these compounds to a single targeted product.As one of three main components of lignocellulosics, hemicellulose contains polysaccharides comprised of pentoses, hexoses and sugar acids that account for 20 to 35% of the total biomass from different sources (21). Methylglucuronoxylans (MeGAX_n), consisting of long chains of as many as 70 β-xylopyranose residues linked by β-1,4-glycosidic bonds (25), are the predominant components in the hemicellulose fractions of agricultural residues and energy crops, including corn stover, sugarcane bagasse, poplar, and switchgrass (7, 18, 23, 24). In hardwood and softwood xylans, a 4-O-methylglucuronic acid is attached at the 2′ position of every sixth to eighth xylose residue (12, 15). Dilute acid hydrolysis is commonly used to make the monosaccharides comprising hemicellulose accessible for fermentation (7, 22). However, the α-1,2 glucuronosyl linkage in xylan is resistant to dilute acid hydrolysis, which results in the release of methylglucuronoxylose (MeGAX) along with xylose and other monosaccharides. MeGAX is not fermented by bacterial biocatalysts currently used to convert hemicellulose to ethanol, such as Escherichia coli KO11 (2, 6). In sweet gum xylan, as much as 27% of the carbohydrate may be in this unfermentable fraction after dilute acid pretreatment (2, 20). Complete utilization of all hemicellulosic sugars can improve the efficiency of conversion of lignocellulosic materials to fuel ethanol and other value-added products.Our previous research on the processing of hemicelluloses for fermentation led to isolation of Enterobacter asburiae strain JDR-1. This isolate performed mixed-acid fermentation of the principal hexoses and pentoses that can be derived from cellulose and hemicellulose fractions of lignocellulosic biomass and exhibited a novel metabolic potential based on its ability to ferment MeGAX and xylose to ethanol and acetate as major fermentation products from sweet gum MeGAX_n hydrolysates generated by dilute acid pretreatment (2). This strain has been genetically modified to produce d-(−)-lactate as the predominant product from acid hydrolysates of MeGAX_n (3).In this study, the PET operon containing the pdc, adhA, and adhB genes from Zymomonas mobilis (10, 11) was incorporated into a pflB E. asburiae JDR-1 isolate by plasmid transformation to construct homoethanologenic strains. The resulting recombinant strains were compared with E. asburiae wild-type strain JDR-1 and the ethanologenic strain E. coli KO11 to evaluate their efficiencies of production of ethanol from dilute acid hydrolysates of sweet gum MeGAX_n.     

Synthesis of Polygalacturonate Trans-eliminase and Polygalacturonase by a Strain of Enterobacter cloacae Isolated from Ponded Sitka Spruce

During the ponding of Sitka spruce in lake water there was a change from a diverse, aerobic flora (16 species) to a restricted, facultatively anaerobic flora (1 or 2 species). This change corresponded with a marked increase in the degradation of pectin and a concomitant increase in the permeability of the wood to preservatives. A strain of Enterobacter cloacae (NCPPB 2909) isolated during ponding, synthesized an extracellular and intracellular polygalacturonase (PG) and an intracellular polygalacturonate trans-eliminase (PGTE). Both PG and PGTE were growth–linked; extracellular PG was produced initially and then replaced by intracellular PG and PGTE. A change in the pH value of the medium did not alter the relative synthesis of enzyme. Reduced oxygen tension retarded growth but had no effect on enzyme activities. PG and PGTE of E. cloacae were shown to have specific ion requirements and when tap-water was used in the preparation of a medium growth did not occur. The results are discussed in relation to an artificial system of sprinkling water, seeded with known species of bacteria, on to spruce wood in order to control the rate of pectin degradation and thus the permeability of the wood to preservatives.     

Simultaneous Cellulose Degradation and Electricity Production by Enterobacter cloacae in a Microbial Fuel Cell

Electricity can be directly generated by bacteria in microbial fuel cells (MFCs) from many different biodegradable substrates. When cellulose is used as the substrate, electricity generation requires a microbial community with both cellulolytic and exoelectrogenic activities. Cellulose degradation with electricity production by a pure culture has not been previously demonstrated without addition of an exogenous mediator. Using a specially designed U-tube MFC, we enriched a consortium of exoelectrogenic bacteria capable of using cellulose as the sole electron donor. After 19 dilution-to-extinction serial transfers of the consortium, 16S rRNA gene-based community analysis using denaturing gradient gel electrophoresis and band sequencing revealed that the dominant bacterium was Enterobacter cloacae. An isolate designated E. cloacae FR from the enrichment was found to be 100% identical to E. cloacae ATCC 13047^T based on a partial 16S rRNA sequence. In polarization tests using the U-tube MFC and cellulose as a substrate, strain FR produced 4.9 ± 0.01 mW/m², compared to 5.4 ± 0.3 mW/m² for strain ATCC 13047^T. These results demonstrate for the first time that it is possible to generate electricity from cellulose using a single bacterial strain without exogenous mediators.Exoelectrogenic microorganisms can release electrons to electron acceptors outside the cell, such as iron oxides or carbon anodes in microbial fuel cells (MFCs). Members of many genera, including Rhodoferax (6), Shewanella (13, 14), Pseudomonas (29), Aeromonas (28), Geobacter (2), Geopsychrobacter (10), Desulfuromonas (1), Desulfobulbus (9), Clostridium (27), Geothrix (3), Ochrobactrum (40), and Rhodopseudomonas (38), have been shown to produce electricity in an MFC. These bacteria have been grown on simple soluble substrates, such as glucose or acetate, that can be directly taken into the cell and used for energy production.Cellulose is the most abundant biopolymer in the world, and there is great interest in using this material as a substrate in an MFC. However, use of a particulate substrate in an MFC has not been well investigated. Cellulose must first be hydrolyzed to a soluble substrate that can be taken up by the cell. In previous MFC tests this has required the use of enzymes to hydrolyze the cellulose into sugars or the use of cocultures or mixed cultures (32, 33, 35). For example, Ren et al. (32) used a coculture of the cellulose fermentor Clostridium cellulolyticum and the exoelectrogen Geobacter sulfurreducens to generate electricity in an MFC fed with cellulose. Analysis of the anode microbial communities in other studies of cellulose-fed MFCs showed that Clostridium spp. (in a biofilm) and Comamonadaceae (in suspension) were predominant when rumen contents were used as an inoculum (35), while a rice paddy soil inoculum (12) converged to a Rhizobiales-dominated anode community (more than 30% of the population). To date, it has not been demonstrated that a single microbe can both degrade cellulose and generate current.Conventional methods of isolating exoelectrogenic microorganisms are based primarily on identifying microorganisms that can respire using soluble or insoluble metal oxides in agar plates (20-22). However, not all dissimilatory metal oxide-reducing bacteria are capable of producing electricity in an MFC, and not all bacteria that produce current in an MFC can grow using metal oxides (5, 34). Therefore, these methods may miss important electrochemically active strains of microorganisms. A new method to isolate exoelectrogenic microorganisms was recently developed (40); this method is based on dilution to extinction and a specially designed U-tube MFC that enriches exoelectrogenic bacteria on the anode. Using this method, a bacterium that could produce electricity in an MFC but not respire using iron was isolated (40).The main objective of this study was to isolate a bacterium capable of producing current from particulate cellulose. A cellulose-degrading consortium was diluted and serially transferred into U-tube MFCs using cellulose as the sole electron donor. Community analysis demonstrated the predominance of a single bacterium, which was isolated and compared to a culture collection strain for generation of current in an MFC.     

Production of Oxalic Acid by a Strain of Agaricus campestris

A strain of the common mushroom Agaricus campestris was grown on a mixture of composted sawdust and CaCO₃. On incubation for 47 days, the organism produced 20.5 g of oxalic acid per 100 g of initial dry compost solids.     

Effects of Formate on Fermentative Hydrogen Production by Enterobacter aerogenes

This paper describes the effects of formate on fermentative hydrogen production by Enterobacter aerogenes by way of batch culture. When 20 mM formate was added to pH 6.3 and pH 5.8 E. aerogenes glucose cultures (formate culture) at the beginning of cultivation, hydrogen evolution through both glucose consumption and decomposition of the extrinsic formate occurred together, while hydrogen evolution occurred only through glucose consumption in the control cultures. The hydrogen evolution rates in the formate cultures were faster than in the control cultures, although cell growth and glucose consumption rates in the formate cultures were slower than the control cultures’. The decomposition rate of the extrinsic formate in the pH 5.8 formate culture was faster than in the pH 6.3 fomiate culture. The hydrogen yield from glucose in the pH 6.3 formate culture increased due to the increasing amount of the nicotinamide adenine dinucleotide for hydrogen production.     

Production of High-Viscosity Whey-Glucose Broths by a Xanthomonas campestris Strain

Acclimation of a sandy soil to an air-natural gas mixture stimulated the biological oxidation of chloroform to carbon dioxide. Acetylene and methane inhibited chloroform oxidation. Chloroform oxidation continued up to 31 days in the absence of methane. Chloroform oxidation rates increased at chloroform concentrations up to 5 mug g of soil.     

一株产透明质酸酶的菌株鉴定及酶学性质研究

透明质酸酶可用于药物渗透剂、动物皮革松散及低分子量的透明质酸制备.实验室前期筛选了一株具有较高透明质酸降解能力的菌株,本研究对其进行了 16S rRNA基因和生理生化反应鉴定,鉴定为弗氏柠檬酸杆菌,但弗氏柠檬酸杆菌来源的透明质酸酶的功能还未见报道.因而,以透明质酸为底物研究其酶学性质,结果表明:该酶最适pH值为5.5,在pH值4.0～8.0下处理1 h可以保持60％以上酶活力;最适温度为50℃,在50℃和60℃下处理1h后剩余60％以上的酶活力.该酶和人源透明质酸酶最适pH相似,但其耐热性更高.因此,本研究挖掘到了新颖的透明质酸酶的资源,并为其开发利用提供了参考价值.     

Complete Fermentation of Xylose and Methylglucuronoxylose Derived from Methylglucuronoxylan by Enterobacter asburiae Strain JDR-1

Acid pretreatment is commonly used to release pentoses from the hemicellulose fraction of cellulosic biomass for bioconversion. The predominant pentose in the hemicellulose fraction of hardwoods and crop residues is xylose in the polysaccharide methylglucuronoxylan, in which as many as one in six of the β-1,4-linked xylopyranose residues is substituted with α-1,2-linked 4-O-methylglucuronopyranose. Resistance of the α-1,2-methylglucuronosyl linkages to acid hydrolysis results in release of the aldobiuronate 4-O-methylglucuronoxylose, which is not fermented by bacterial biocatalysts currently used for bioconversion of hemicellulose. Enterobacter asburiae strain JDR-1, isolated from colonized hardwood (sweetgum), efficiently ferments both methylglucuronoxylose and xylose, producing predominantly ethanol and acetate. ¹³C-nuclear magnetic resonance studies defined the Embden-Meyerhof pathway for metabolism of glucose and the pentose phosphate pathway for xylose metabolism. Rates of substrate utilization, product formation, and molar growth yields indicated methylglucuronoxylose is transported into the cell and hydrolyzed to release methanol, xylose, and hexauronate. Enterobacter asburiae strain JDR-1 is the first microorganism described that ferments methylglucuronoxylose generated along with xylose during the acid-mediated saccharification of hemicellulose. Genetic definition of the methylglucuronoxylose utilization pathway may allow metabolic engineering of established gram-negative bacterial biocatalysts for complete bioconversion of acid hydrolysates of methylglucuronoxylan. Alternatively, Enterobacter asburiae strain JDR-1 may be engineered for the efficient conversion of acid hydrolysates of hemicellulose to biofuels and chemical feedstocks.     

Fermentative Production of Thymidine by a Metabolically Engineered Escherichia coli Strain

Thymidine is an important precursor in the production of various antiviral drugs, including azidothymidine for the treatment of AIDS. Since thymidine-containing nucleotides are synthesized only by the de novo pathway during DNA synthesis, it is not easy to produce a large amount of thymidine biologically. In order to develop a host strain to produce thymidine, thymidine phosphorylase, thymidine kinase, and uridine phosphorylase genes were deleted from an Escherichia coli BL21 strain to develop BLdtu. Since the genes coding for the enzymes related to the nucleotide salvage pathway were disrupted, BLdtu was unable to utilize thymidine or thymine, and thymidine degradation activity was completely abrogated. We additionally expressed T4 thymidylate synthase, T4 nucleotide diphosphate reductase, bacteriophage PBS2 TMP phosphohydrolase, E. coli dCTP deaminase, and E. coli uridine kinase in the BLdtu strain to develop a thymidine-producing strain (BLdtu24). BLdtu24 produced 649.3 mg liter⁻¹ of thymidine in a 7-liter batch fermenter for 24 h, and neither thymine nor uridine was detected. However, the dUTP/dTTP ratio was increased in BLdtu24, which could lead to increased double-strand breakages and eventually to cell deaths during fermentation. To enhance thymidine production and to prevent cell deaths during fermentation, we disrupted a gene (encoding uracil-DNA N-glycosylase) involved in DNA excision repair to suppress the consumption of dTTP and developed BLdtug24. Compared with the thymidine production in BLdtu24, the thymidine production in BLdtug24 was increased by ∼1.2-fold (740.3 mg liter⁻¹). Here, we show that a thymidine-producing strain with a relatively high yield can be developed using a metabolic engineering approach.Thymidine, which is composed of 2-deoxyribose and a thymine base, is a commercially useful precursor in the chemical synthesis of various antiviral drugs, including stavudine and zidovudine (azidothymidine), the active ingredient in a formulation for the treatment of AIDS (18, 19). Because thymidine is required only in DNA synthesis, intracellular thymidine levels are very low and are tightly controlled (40). For the production of precursors for antiviral drugs, thymidine is either biologically produced in a low yield by a few modified microorganisms or chemically synthesized through a very costly process (17, 33, 48, 49). Thus, there is a need for developing a more efficient strain for thymidine production on a large scale.In nature, there are two distinct pathways for dTTP synthesis, the salvage and de novo pathways. The salvage pathway enables the cells to utilize preformed nucleobases and nucleosides for nucleotide synthesis, using thymidine phosphorylase (deoA), uridine phosphorylase (udp), and thymidine kinase (tdk) (Fig. ​(Fig.1)1) (40).Open in a separate windowFIG. 1.Thymidine biosynthetic pathway. The steps engineered in this study are indicated by the bold arrows and lines. Components of the catabolism are as follows: pyrA, carbamoylphosphate synthase; pyrBI, aspartate-carbamoyl transferase; pyrC, dihydroorotase; pyrD, dihydroorotate oxidase; pyrE, orotate phosphoribosyltransferase; pyrF, OMP decarboxylase; pyrG, CTP synthetase; pyrH, UMP kinase; TMPase, TMP phosphohydrolase; nrd, nucleotide diphosphate reductase; tdΔI, T4 thymidylate synthase (intron deleted); thyA, thymidylate synthase; dcd, dCTP deaminase; udk, uridine kinase; deoA, thymidine phosphorylase; tdk, thymidine kinase; udp, uridine phosphorylase; dut, deoxyribonucleotide triphosphatase; ndk, nucleotide diphosphate kinase; tmk, TMP kinase; ung, uracil-DNA N-glycosylase; upp, uracil phosphoribosyl-transferase; cdd, cytidine deaminase; codA, cytosine deaminase.As the name indicates, the de novo pathway enables the cells to synthesize nucleobases de novo. The de novo pathway leading to thymidine biosynthesis starts with the condensation of aspartate and carbamoylphosphate, synthesized by carbamoylphosphate synthase (pyrA) (41). This condensation reaction is catalyzed by aspartate-carbamoyl transferase (pyrBI) to produce carbamoyl aspartate, which undergoes several reactions to produce UMP, the common precursor for the synthesis of the pyrimidine ribonucleoside and deoxynucleosides (Fig. ​(Fig.1)1) (39-41). For thymidine biosynthesis, UMP is converted to UDP in a reaction catalyzed by UMP kinase (pyrH), and UDP is converted to dUDP by ribonucleoside diphosphate reductase (nrdAB), which is regulated by NTP effectors through binding to specific allosteric sites on ribonucleotide diphosphate reductase (nrdA). Escherichia coli can synthesize dUMP from both dCDP and dUDP. The major pathway involves phosphorylation of dCDP to dCTP, deamination of dCTP to dUTP, and hydrolysis of dUTP to dUMP. Only 20 to 30% of the cellular dUMP is supplied by hydrolysis of dUTP (29, 37). The deamination of dCTP (dcd) is located at a branch point in the pyrimidine metabolic pathway. Because of its importance, dcd is regulated by a positive homotropic cooperativity toward dCTP and by a feedback inhibition by dTTP (29, 31, 40).Deoxyuridine triphosphatase (dUTPase [dut]) is a pyrophosphatase that contains zinc ions (42). dUTPase catalyzes the hydrolysis of dUTP to PP_i and dUMP, a substrate for thymidylate synthase (thyA). Generally, the intracellular concentration of dUTP is <10 nmol per 1 g dry cell weight (DCW), and that of dTTP exceeds 500 nmol per 1 g DCW (5, 39, 52). The intracellular dUTP-to-dTTP ratio is increased in dut-deficient mutants, leading to an increased frequency of misincorporation of uracil for thymine in DNA (34). This incorporation is transient only because uracil is removed from DNA via a subsequent excision repair initiated by uracil-DNA N-glycosylase, which is encoded by ung (15, 50). Attempted repair of deoxyuridine residues from DNA without adequate dTTP available to complete the repair reaction can result in multiple single-strand breaks, eventually leading to double-strand breaks (15). Indeed, single- and double-strand breaks accumulate in thymidine-deprived cells (16). In such cells, the loss of uracil glycosylase activity should decrease DNA breaks arising from attempted repair and thereby decrease the toxicity of thymidine depletion.The synthesis of dTMP from dUMP involves the transfer of a methylene group and two reducing equivalents from 5,10-methylenetetrahydrofolate to dUMP, catalyzed by the dimeric enzyme thymidylate synthase (thyA). Even though ThyA catalyzes the committed step for de novo synthesis of dTTP, neither the activity of the enzyme nor the expression of the thyA gene seems to be regulated (2, 3).The general strategy used for the development of a thymidine-overproducing strain involves the alleviation of control mechanisms in key pathways. Several different microorganisms have been modified for thymidine production, including E. coli, Brevibacterium helvolum, and Corynebacterium ammoniagenes, by classical mutagenesis methods, and they were selected based on their capacity to grow on toxic thymidine analogues (30, 33, 48, 49). In these studies, feedback inhibition-resistant variants of thymidine biosynthetic enzymes were obtained by random mutation, and high-producing variants were selected. The most optimum B. helvolum strain obtained by this procedure produced 500 mg liter⁻¹ of thymidine by batch fermentation (33). However, engineered B. helvolum and E. coli mutants also produced thymine, deoxyuridine, and uracil, which are unfavorable for thymidine production since it increases costs during the purification process (30, 33, 48, 49). Furthermore, these thymidine-producing strains have residual thymidine degradation activities, resulting in decreased productivities.Thus, we tried to develop a more efficient thymidine-producing strain by enhancing the de novo pathway leading to thymidine biosynthesis and by disrupting the thymidine salvage pathway. The strategy reported here is based on disrupting genes which encode enzymes involved in thymidine degradation and on expressing foreign genes in the de novo pathway leading to thymidine biosynthesis which encode enzymes that are expected to be less sensitive to feedback inhibition by thymidine than the original enzymes in the host strain. The T4 ribonucleotide diphosphate reductase (nrdAB) operon, T4 thioredoxin (nrdC), T4 thymidylate synthase (td), and PBS2 TMP phosphohydrolase (TMPase) were expressed in an E. coli mutant strain which was modified to block the salvage pathway (deoA, tdk, and udp). In order to increase the influx of dUMP, E. coli dCTP deaminase (dcd), deoxyuridine triphosphatase (dut), and uridine kinase (udk) were expressed with phage-derived genes. We found that the dUTP/dTTP ratio was increased by increasing the level of dUTP in our mutant, leading to the frequent misincorporation of dUTP in DNA. In order to prevent frequent temporary DNA breaks and gaps by excision repair caused by the increased intracellular dUTP/dTTP ratio, uracil-DNA N-glycosylase (ung) was additionally disrupted.     

Production of High-Viscosity Whey Broths by a Lactose-Utilizing Xanthomonas campestris Strain

Xanthomonas campestris BB-1L was isolated by enrichment and selection by serial passage in a lactose-minimal medium. When BB-1L was subsequently grown in medium containing only 4% whey and 0.05% yeast extract, the lactose was consumed and broth viscosities greater than 500 cps at a 12 s⁻¹ shear rate were produced. Prolonged maintenance in whey resulted in the loss of the ability of BB-1L to produce viscous broths in whey, indicating a reversion to preferential growth on whey protein, like the parent strain.     

Production of Two Extracellular Alkaline Phosphatases by a Psychrophilic Arthrobacter Strain

We surveyed our collection of psychrophilic bacteria to determine the types of phosphatases they produce and whether any had heat-labile activities with potential applications. Assays at different temperatures showed that the activity from one isolate was optimal at 45(deg)C and decreased dramatically above 55(deg)C. This isolate, D10, had the rod-coccus morphological cycle and cell wall amino acids associated with members of the Arthrobacter genus. Interestingly, we found that this strain made two extracellular phosphatases that could be separated by ammonium sulfate fractionation and migration during polyacrylamide gel electrophoresis. One enzyme, designated D10A, hydrolyzed both X-phos (5-bromo-4-chloro-3-indolyl phosphate) and para-nitrophenyl phosphate as substrates and had activity over a broad pH range of 7 to 11. The second enzyme, D10B, lacked activity against X-phos and had a narrow pH range of about 8 to 9. In addition, the D10B enzyme required calcium for activity. The levels of activity of both enzymes decreased for cells grown in media containing more than 100 (mu)M P(infi). These results not only demonstrate the existence of different enzymes from one Arthrobacter strain but also suggest ways in which other studies may have missed phosphatases with unknown requirements.     

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.