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Applied Microbiology and Biotechnology (v.59, #4-5)
Engineering an indene bioconversion process for the production of cis-aminoindanol: a model system for the production of chiral synthons by X. O'Brien; J. Parker; P. Lessard; A. Sinskey (pp. 389-399).
Cis-aminoindanol, a key chiral precursor to the HIV protease inhibitor CRIXIVAN, can be derived from indene oxidation products of (2R) stereochemistry. A number of different microorganisms, notably strains of the genera Pseudomonas and Rhodococcus, have been isolated that catalyze the oxygenation of indene to indandiol with greater stereospecificity than is achievable through traditional chemical synthesis. The yield and ultimate optical purity of indandiol produced in such biocatalytic processes is influenced by the intrinsic stereospecificity of the oxygenase(s), enantioselective dehydrogenation, and the loss of substrate to alternate, undesirable metabolites. Metabolic engineering of any indene bioconversion system for the commercial-scale production of cis-aminoindanol must account for these influences, as well as pathway fluxes and enzyme regulation, to optimize the formation of oxygenated precursors with useful stereochemistry. As such, the process by which bacterial systems carry out the bioconversion of indene to indandiol serves as a model for biological production of industrially relevant chiral synthons.
The biotechnological production of sorbitol by M. Silveira; R. Jonas (pp. 400-408).
Sorbitol, a polyol found in many fruits, is of increasing industrial interest as a sweetener, humectant, texturizer and softener. At present, it is produced chemically. The bacterium Zymomonas mobilis is able to produce sorbitol and gluconic acid from fructose and glucose, respectively. This is possible in a one-step reaction via a glucose-fructose oxidoreductase so far only known from Z. mobilis. The possibilities for the industrial production of sorbitol by Z. mobilis are discussed, and compared with the current chemical production method as well as other microbiological processes.
Microbial alkaline pectinases and their industrial applications: a review by G. Hoondal; R. Tiwari; R. Tewari; N. Dahiya; Q. Beg (pp. 409-418).
The biotechnological potential of pectinolytic enzymes from microorganisms has drawn a great deal of attention from various researchers worldwide as likely biological catalysts in a variety of industrial processes. Alkaline pectinases are among the most important industrial enzymes and are of great significance in the current biotechnological arena with wide-ranging applications in textile processing, degumming of plant bast fibers, treatment of pectic wastewaters, paper making, and coffee and tea fermentations. The present review features the potential applications and uses of microbial alkaline pectinases, the nature of pectin, and the vast range of pectinolytic enzymes that function to mineralize pectic substances present in the environment. It also emphasizes the environmentally friendly applications of microbial alkaline pectinases thereby revealing their underestimated potential. The review intends to explore the potential of these enzymes and to encourage new alkaline pectinase-based industrial technology.
Protein serine/threonine kinases in signal transduction for secondary metabolism and morphogenesis in Streptomyces by T. Umeyama; P.-C. Lee; S. Horinouchi (pp. 419-425).
A number of proteins in the Gram-positive bacterial genus Streptomyces are phosphorylated on their serine/threonine and tyrosine residues in response to developmental phases. AfsR is one of these proteins and acts as a transcriptional factor in both the regulation of secondary metabolism in Streptomyces coelicolor A3(2) and morphological differentiation in Streptomyces griseus. In S. coelicolor A3(2), AfsR is phosphorylated on its serine and threonine residues by more than three protein kinases whose kinase activity is enhanced by means of autophosphorylation on their serine and threonine residues. The degree of autophosphorylation of AfsK is regulated by KbpA which, by binding directly to the kinase domain of AfsK, inhibits its autophosphorylation. Phosphorylation of AfsR enhances its DNA-binding activity and causes it to bind the promoter elements, including –35, of afsS, thus resulting in activation of afsS transcription. ATPase activity of AfsR is essential for this transcriptional activation, probably because the energy available from ATP hydrolysis is required for the isomerization of the closed complex between AfsR and RNA polymerase to a transcriptionally competent open complex. afsS, encoding a 63-amino-acid protein, then activates transcription of actII-ORF4, a pathway-specific transcriptional activator in the actinorhodin biosynthetic gene cluster, in an as yet unknown way. Distribution of the afsK-afsR systems in a wide variety of Streptomyces species and the presence of many phosphorylated proteins in a given Streptomyces strain suggest that the signal transduction via not only two-component regulatory systems but also serine/threonine kinases generally regulates secondary metabolism and morphogenesis in this genus.
On the safety of Aspergillus niger – a review by E. Schuster; N. Dunn-Coleman; J. Frisvad; P. van Dijck (pp. 426-435).
Aspergillus niger is one of the most important microorganisms used in biotechnology. It has been in use already for many decades to produce extracellular (food) enzymes and citric acid. In fact, citric acid and many A. niger enzymes are considered GRAS by the United States Food and Drug Administration. In addition, A. niger is used for biotransformations and waste treatment. In the last two decades, A. niger has been developed as an important transformation host to over-express food enzymes. Being pre-dated by older names, the name A. niger has been conserved for economical and information retrieval reasons and there is a taxonomical consensus based on molecular data that the only other common species closely related to A. niger in the Aspergillus series Nigri is A. tubingensis. A. niger, like other filamentous fungi, should be treated carefully to avoid the formation of spore dust. However, compared with other filamentous fungi, it does not stand out as a particular problem concerning allergy or mycopathology. A few medical cases, e.g. lung infections, have been reported, but always in severely immunocompromised patients. In tropical areas, ear infections (otomycosis) do occur due to A. niger invasion of the outer ear canal but this may be caused by mechanical damage of the skin barrier. A. niger strains produce a series of secondary metabolites, but it is only ochratoxin A that can be regarded as a mycotoxin in the strict sense of the word. Only 3–10% of the strains examined for ochratoxin A production have tested positive under favourable conditions. New and unknown isolates should be checked for ochratoxin A production before they are developed as production organisms. It is concluded, with these restrictions, that A. niger is a safe production organism.
Fermentation performance and intracellular metabolite patterns in laboratory and industrial xylose-fermenting Saccharomyces cerevisiae by J. Zaldivar; A. Borges; B. Johansson; H. Smits; S. Villas-Bôas; J. Nielsen; L. Olsson (pp. 436-442).
Heterologous genes for xylose utilization were introduced into an industrial Saccharomyces cerevisiae, strain A, with the aim of producing fuel ethanol from lignocellulosic feedstocks. Two transformants, A4 and A6, were evaluated by comparing the performance in 4-l anaerobic batch cultivations to both the parent strain and a laboratory xylose-utilizing strain: S. cerevisiae TMB 3001. During growth in a minimal medium containing a mixture of glucose and xylose (50 g/l each), glucose was preferentially consumed. During the first growth phase on glucose, the specific growth rates were 0.26, 0.32, 0.27 and 0.30 h–1 for strains TMB 3001, A (parental strain), A4, and A6, respectively. The specific ethanol productivities were 0.04, 0.13, 0.04 and 0.03 g/g.per hour, for TMB 3001, A, A4 and A6, respectively. The specific xylose consumption rates were 0.06, 0.21 and 0.14 g/g.per hour, respectively for strains TMB 3001, A4 and A6. Xylose consumption resulted mainly in the formation of xylitol, with biomass and ethanol being minor products. The metabolite profile of intermediates in the pentose phosphate pathway and key glycolytic intermediates were determined during growth on glucose and xylose, respectively. The metabolite pattern differed depending on whether glucose or xylose was utilized. The levels of intracellular metabolites were higher in the industrial strains than in the laboratory strain during growth on xylose.
The influence of bark on the fermentation of Douglas-fir whitewood pre-hydrolysates by J. Robinson; J. Keating; A. Boussaid; S. Mansfield; J. Saddler (pp. 443-448).
Douglas-fir (Pseudotsuga menziesii) whitewood was supplemented with increasing concentrations of bark (0–30%) and was pretreated using SO2-catalysed steam explosion. The presence of bark in the feedstock resulted in the decreased recovery of total sugars, furfural and 5-hydroxymethylfurfural in the resultant pre-hydrolysate. No detrimental impact on monomer sugar recovery was observed. The concentration of lipophilic extractives present in the pre-hydrolysate increased with increasing bark loading, to a maximum of 0.43 g l–1. The water-soluble pre-hydrolysates were fermented by Saccharomyces cerevisiae to determine the impact of bark on sugar consumption and ethanol production. Despite the inclusion of bark, fermentation of all pre-hydrolysates resulted in the complete consumption of hexose sugars within 48 h. Ethanol yields were greater than 0.43 g g–1 for all pre-hydrolysates regardless of bark content, indicating that, up to a content of 30%, bark had a negligible impact on the fermentation of the pre-hydrolysates to ethanol.
P450camr, a cytochrome P450 catalysing the stereospecific 6-endo-hydroxylation of (1R)-(+)-camphor by G. Grogan; G. Roberts; S. Parsons; N. Turner; S. Flitsch (pp. 449-454).
Rhodococcus sp. NCIMB 9784 accumulated 6-endo-hydroxycamphor 3 when grown on (1R)-(+)-camphor 1 as sole carbon source. The structure of 3 has been unambiguously assigned for the first time using X-ray crystallography. A soluble cytochrome P450 hydroxylase, induced by growth on (1R)-(+)-camphor and designated P450camr, has been isolated from the bacterium Rhodococcus sp. NCIMB 9784. Using authentic 6-endo hydroxycamphor as standard, a cell-free system consisting of pure P450camr and putidaredoxin and putidaredoxin reductase from Pseudomonas putida confirmed that the enzyme hydroxylates (1R)-(+)-camphor specifically in the 6-endo position, in contrast to the 5-exo hydroxylation catalysed by the well-studied P450cam from P. putida. P450camr has a molecular mass of approximately 44 kDa, and a pI of 4.8.
Clostridium thermocellum cellulase CelT, a family 9 endoglucanase without an Ig-like domain or family 3c carbohydrate-binding module by J. Kurokawa; E. Hemjinda; T. Arai; T. Kimura; K. Sakka; K. Ohmiya (pp. 455-461).
The celT gene of Clostridium thermocellum strain F1 was found downstream of the mannanase gene man26B [Kurokawa J et al. (2001) Biosci Biotechnol Biochem 65:548–554] in pKS305. The open reading frame of celT consists of 1,833 nucleotides encoding a protein of 611 amino acids with a predicted molecular weight of 68,510. The mature form of CelT consists of a family 9 cellulase domain and a dockerin domain responsible for cellulosome assembly, but lacks a family 3c carbohydrate-binding module (CBM) and an immunoglobulin (Ig)-like domain, which are often found with family 9 catalytic domains. CelT devoid of the dockerin domain (CelTΔdoc) was constructed and purified from a recombinant Escherichia coli, and its enzyme properties were examined. CelTΔdoc showed strong activity toward carboxymethylcellulose (CMC) and barley β-glucan, and low activity toward xylan. The V max and K m values were 137 µmol min–1 mg–1 and 16.7 mg/ml, respectively, for CMC. Immunological analysis indicated that CelT is a catalytic component of the C. thermocellum F1 cellulosome. This is the first report describing the characterization of a family 9 cellulase without an Ig-like domain or family 3c CBM.
Expression of two kinds of recombinant glutamate dehydrogenase from Aeropyrum pernix with different N-terminal sequence length in Escherichia coli by I. Helianti; Y. Morita; Y. Murakami; K. Yokoyama; E. Tamiya (pp. 462-466).
Two recombinant Aeropyrum pernix glutamate dehydrogenase (GDH) enzymes with different length N-termini were cloned and expressed in Escherichia coli: sGDH begins with the amino acid sequence of the extracted native enzyme (M-Q-P-T-D-P-L-E-E), whereas lGDH begins with the sequence of the predicted ORF (M-E-V-L-A-L-Q-P-T-D) and is longer than sGDH by five amino acids (M-E-V-L-A). Purified recombinant lGDH was more stable than sGDH, indicating that the N-terminal extension, containing mostly hydrophobic residues, affected the overall stability of recombinant lGDH. This stabilising effect of extending the N-terminal sequence on an oligomeric enzyme such as GDH is novel; factors affecting stabilisation have previously only been discussed in the context of the contribution of internal amino acids.
A food-grade cloning vector for lactic acid bacteria based on the nisin immunity gene nisI by T. Takala; P. Saris (pp. 467-471).
A new food-grade cloning vector for lactic acid bacteria was constructed using the nisin immunity gene nisI as a selection marker. The food-grade plasmid, pLEB590, was constructed entirely of lactococcal DNA: the pSH71 replicon, the nisI gene, and the constitutive promoter P45 for nisI expression. Electroporation into Lactococcus lactis MG1614 with 60 international units (IU) nisin/ml selection yielded approximately 105 transformants/µg DNA. MG1614 carrying pLEB590 was shown to be able to grow in medium containing a maximum of 250 IU nisin/ml. Plasmid pLEB590 was succesfully transformed into an industrial L. lactis cheese starter carrying multiple cryptic plasmids. Suitability for molecular cloning was confirmed by cloning and expressing the proline iminopeptidase gene pepI from Lactobacillus helveticus in L. lactis and Lb. plantarum. These results show that the food-grade expression system reported in this paper has potential for expression of foreign genes in lactic acid bacteria in order to construct improved starter bacteria for food applications.
Glycerol and arabitol production by an intergeneric hybrid, PB2, obtained by protoplast fusion between Saccharomyces cerevisiae and Torulaspora delbrueckii by M. Lucca; J. Spencer; L. de Figueroa (pp. 472-476).
An intergeneric osmotolerant hybrid yeast, PB2, was used together with the parental strains to study glycerol and arabitol production in batch culture. This fusion product was previously obtained by protoplast fusion between Torulaspora delbrueckii and Saccharomyces cerevisiae. Polyols and biomass production were determined in batch culture under aerobic conditions. Under the conditions tested, using PB2 hybrid and both parental strains, the best results were obtained with the hybrid. Arabitol reached a final concentration of 70 g/l and glycerol was increased to up to 50 g/l.
In vivo evolution of the Aeromonas punctata polyhydroxyalkanoate (PHA) synthase: isolation and characterization of modified PHA synthases with enhanced activity by A. Amara; A. Steinbüchel; B. Rehm (pp. 477-482).
In vivo random mutagenesis of the polyhydroxyalkanoate (PHA) synthase gene from Aeromonas punctata was performed employing the mutator strain Escherichia coli XL1-Red. About 200,000 mutants were screened on Nile red-containing medium and five mutants with enhanced fluorescence were selected. Four of these mutants exhibited enhanced in vivo and in vitro PHA synthase activity. Mutant M1, which carried the single mutation F518I, showed a five-fold increase in specific PHA synthase activity, whereas the corresponding mediated PHA accumulation increased by 20%, as compared with the wild-type PHA synthase. Mutant M2, which carried the single mutation V214G, showed a two-fold increase in specific PHA synthase activity and PHA accumulation only increased by 7%. Overall, the in vitro activities of the overproducing mutants ranged from 1.1- to 5-fold more than the wild-type activity, whereas the amounts of accumulated PHA ranged over 107–126% of that of the wild type. Moreover, all mutants mediated synthesis of PHAs with an increased weight average molar mass, but the molar fractions of 3-hydroxybutyrate and 3-hydroxyhexanoate remained almost constant. In vivo random mutagenesis proved to be a versatile tool to isolate mutants exerting improved properties with respect to PHA biosynthesis.
Cloning, functional expression and biochemical characterization of a stereoselective alcohol dehydrogenase from Pseudomonas fluorescens DSM50106 by P. Hildebrandt; A. Musidlowska; U. Bornscheuer; J. Altenbuchner (pp. 483-487).
Sequencing of a genomic library prepared from Pseudomonas fluorescens DSM 50106 identified an orf showing 29% identity to a C α-dehydrogenase of Pseudomonas paucimobilis and high homology to several sequences with unknown functions derived from genome projects. The corresponding gene adhF1 encodes a dehydrogenase of 296 amino acids with a calculated molecular mass of 31.997 kDa. The gene was functionally expressed in E. coli using a rhamnose inducible expression system. The resulting recombinant enzyme was active in the pH range 6–10 (best pH 8) and at 5–25 °C. This dehydrogenase converts cyclic ketones to the corresponding alcohols utilizing the cofactor NADH. The highest activity was found for cyclohexanone. The enzyme also exhibits high stereoselectivity in the desymmetrization of the prochiral ketone acetophenone, producing optically pure (R)-α-phenyl ethanol (>99%ee) at high conversion (95%).
Inhibition of lotic biofilms by Diclofenac by M. Paje; U. Kuhlicke; M. Winkler; T. Neu (pp. 488-492).
Diclofenac, a common drug, was subjected to degradation studies using river biofilms grown in rotating annular reactors. Degradation of diclofenac was possible after acclimatisation as confirmed by liquid chromatography-mass spectrometry analyses. Adapted biofilms showed that degradation down to 10–25% of the initial concentration could be achieved within 4 days. In situ observation by confocal laser scanning microscopy, however, revealed slow biofilm development in the presence of diclofenac compared with control experiments grown in river water only. This was substantiated by low cell counts and isolation of fewer kinds of microorganisms from diclofenac-grown biofilms. Fluorescent in situ hybridisation analyses confirmed the presence of various bacterial groups, especially those belonging to the Cytophaga-Flavobacterium and γ-Proteobacteria groups, in the biofilms. Quantification of image data indicated a negative effect of diclofenac on the growth of bacteria and algae. This is the first report on degradation of diclofenac by lotic biofilms.
Biosynthesis of citric and isocitric acids from ethanol by mutant Yarrowia lipolytica N 1 under continuous cultivation by T. Finogenova; S. Kamzolova; E. Dedyukhina; N. Shishkanova; A. Il'chenko; I. Morgunov; O. Chernyavskaya; A. Sokolov (pp. 493-500).
The effect of ethanol, zinc, and iron (Fe2+ and Fe3+) concentration and of oxygen supply on cell growth and the production of citric acid (CA) and isocitric acid (ICA) from ethanol by mutant Yarrowia lipolytica N 1 was studied under continuous cultivation. The following peculiarities of Y. lipolytica metabolism were found: (1) intensive CA production occurred under yeast growth limitation by nitrogen; (2) inhibition of yeast growth by ethanol was accompanied by significant alterations in fatty acid composition of lipids; (3) the production of CA and ICA from ethanol required high concentrations of zinc and iron ions; (4) the intracellular iron concentration determined whether CA or ICA was predominantly formed; (5) the cell's requirement for oxygen depended on the intracellular iron concentration. The events taking place in the production of CA and ICA were evaluated through the activities of enzyme systems involved in the metabolism of ethanol and CA in this strain.
Genetic and physiological analysis of branched-chain alcohols and isoamyl acetate production in Saccharomyces cerevisiae by H. Yoshimoto; T. Fukushige; T. Yonezawa; H. Sone (pp. 501-508).
Branched-chain alcohols, such as isoamyl alcohol and isobutanol, and isoamyl acetate are important flavor components of yeast-fermented alcoholic beverages. Analysis of a null mutant of the BAT2 gene encoding cytosolic branched-chain amino acid aminotransferase, and a transformant with multi-copy plasmids containing the BAT2 gene showed that the BAT2 gene product plays an important role in the production of branched-chain alcohols and isoamyl acetate. Fermentation tests using the bat2 null mutant transformed with multi-copy plasmids carrying the ATF1 gene, which encodes alcohol acetyltransferase, indicated that modified expression of BAT2 and ATF1 genes could significantly alter the proportion of branched-chain alcohols and isoamyl acetate synthesized. Furthermore, fermentation tests using different ratios of nitrogen source and RNA blot analyses demonstrated that transcription of L-leucine biosynthetic (LEU) and BAT genes is co-regulated by nitrogen source, that production of isoamyl alcohol depends on this transcription, and that ATF transcription increased with increased concentrations of nitrogen source. Our data suggest that changes in isoamyl alcohol production by nitrogen source are due to transcriptional co-regulation of LEU and BAT genes, and that production of isoamyl acetate is dependent on isoamyl alcohol production and ATF transcription.
A physiological and enzymatic study of Debaryomyces hansenii growth on xylose- and oxygen-limited chemostats by A. Nobre; L. Duarte; J. Roseiro; F. Gírio (pp. 509-516).
The effect of changing growth rate and oxygen transfer rate (OTR) on Debaryomyces hansenii physiology was studied using xylose-limited and oxygen-limited chemostat cultures, respectively, and complemented with enzymatic assays. Under xylose-limited chemostat (oxygen-excess), neither ethanol nor xylitol was produced over the entire range of dilution rate (D). The maximal volumetric biomass productivity was 2.5 g l–1 h–1 at D =0.25 h–1 and cell yield was constant at all values of D. The respiratory rates and xylose consumption rate increased linearly with growth rate but, above 0.17 h–1, oxygen consumption rate had a steeper increase compared to carbon dioxide production rate. Enzymatic analysis of xylose metabolism suggests that internal fluxes are redirected as a function of growth rate. For values of D up to 0.17 h–1, the xylose reductase (XR) titre is lower than the xylitol dehydrogenase (XDH) titre, whereas above 0.17 h–1 XR activity is about twice that of XDH and the NADPH-producing enzymes sharply increase their titres indicating an internal metabolic flux shift to meet higher NADPH metabolic requirements. Moreover, the enzymes around the pyruvate node also exhibited different patterns if D was above or below 0.17 h–1. Under oxygen-limited chemostat (xylose-excess) the metabolism changed drastically and, due to oxidative phosphorylation limitation, cell yield decreased to 0.16 g g–1 for an OTR of 1.4 mmol l–1 h–1 and xylitol became the major extracellular product along with minor amounts of glycerol. The enzymatic analysis revealed that isocitrate dehydrogenase is not regulated by oxygen, whereas XR, XDH and the NADPH-producing enzymes changed their levels according to oxygen availability.
Characterization of a bioflocculant produced by the marine myxobacterium Nannocystis sp. NU-2 by J. Zhang; Z. Liu; S. Wang; P. Jiang (pp. 517-522).
The marine myxobacterium strain NU-2, which can grow on high concentrations (up to 7%) of NaCl, was isolated from a salt soil sample collected from the coast of the Huanghai Sea, China. Morphological properties and 16S rDNA sequence analysis indicated that the isolate is a novel species related to the genus Nannocystis. Nannocystis sp. NU-2 produced a new kind of flocculating substance in a starch medium with a yield of 14.8 g l–1. The NU-2 flocculant was composed of 40.3% proteins and 56.5% polysaccharides, of which glucose, mannose and glucuronic acid were the principal constituents in the relative proportions of 5:4:1. The flocculation activity of the NU-2 flocculant depends strongly on cations such as Fe3+ and Al3+. When a 30 mg l–1 FeCl3 solution is present in kaolin clay suspension, 30 mg l–1of the flocculant produced a high flocculating activity value of 90%, which remained unchanged over an extensive pH range (pH 2.0–13.0). The flocculant was tested for its ability to bleach dyeing liquors, and the bleaching activities were 98.2% for acid red in 100 mg l–1of the flocculant and 99.0% for direct emerald blue in 50 mg l–1of the flocculant under test conditions. Use of the flocculant to bleach basic pink and cation emerald blue liquors was not effective.
Comparison of green fluorescent protein expression in two industrial Escherichia coli strains, BL21 and W3110, under co-expression of bacterial hemoglobin by D. Kang; Y. Kim; H. Cha (pp. 523-528).
Vitreoscilla hemoglobin (VHb) has been successfully used to enhance production of foreign proteins in several microorganisms including Escherichia coli. We compared the expression of an oxygen-dependent foreign protein, green fluorescent protein (GFP) under co-expression of VHb in two typical industrial E. coli strains, BL21 (a B derivative) and W3110 (a K12 derivative), which have different metabolic properties. We employed the nar oxygen-dependent promoter for self-tuning regulation of VHb expression due to the natural transition of dissolved oxygen (DO) level during culture. We observed several interesting and differing behaviors in cultures of the two strains. VHb co-expression showed a positive influence on expression, and even on solubility, of GFP in both strains; while strain BL21 had the higher GFP expression level, W3110 showed higher solubility of expressed GFP. GFP expression in strain BL21 was very largely affected by variation of aeration environments, but W3110 was not significantly impacted. We surmised that this arose from different oxygen utilization abilities and indeed the two strains showed different patterns of oxygen uptake rate. Interestingly, the VHb co-expressing W3110 strain exhibited a peculiar increasing pattern of GFP expression during the late culture period even under low aeration conditions and this enhancement was more obvious in large-scale cultures. Therefore, this strain could be successfully employed in practical large-scale production cultures where DO levels tend to be limited.
Construction of a stable microbial community with high cellulose-degradation ability by S. Haruta; Z. Cui; Z. Huang; M. Li; M. Ishii; Y. Igarashi (pp. 529-534).
We bred a microbial community capable of degrading rice straw with high efficiency. The microbial community degraded more than 60% of rice straw within 4 days at 50 °C. The high stability of the community's degradation ability was demonstrated by its tolerance of being subcultured several times in medium with/without cellulosic material, being heated to 95 °C, and freezing at –80 °C. The community degraded both nonsterilized and sterilized substrate; and its degradation ability was not affected by pH changes in the medium (initial pH 5–9). PCR-denaturing gradient gel electrophoresis (DGGE) analyses based on 16S rDNA fragments showed that the community structure remained constant after multiple subcultures extending over 2 years. DNA sequence analyses of DGGE bands indicated the coexistence of both aerobic and anaerobic bacteria in the community.
Biodegradation of monohalogenated alkanes by soil NH3-oxidizing bacteria by K. Duddleston; D. Arp; P. Bottomley (pp. 535-539).
Although cooxidative biodegradation of monohalogenated hydrocarbons has been well studied in the model NH3-oxidizing bacterium, Nitrosomonas europaea, virtually no information exists about cooxidation of these compounds by native populations of NH3-oxidizing bacteria. To address this subject, nitrifying activity was stimulated to 125–400 nmol NO3 – produced g–1 soil h–1 by first incubating a Ca(OH)2-amended, silt loam soil (pH 7.0±0.2) at field capacity (270 g H2O kg–1 soil) with 10 µmol NH4 + g–1 soil for 14 days, followed by another 10 days of incubation in a shaken slurry (2:1 water:soil, v/w) with periodic pH adjustment and maintenance of 10 mM NH4 +. These slurries actively degraded both methyl bromide (MeBr) and ethyl chloride (EtCl) at maximum rates of 20–30 nmol ml–1 h–1 that could be sustained for approximately 12 h. Although the MeBr degradation rates were linear for the first 10–12 h of incubation, they could not be sustained regardless of NH4 + level and declined to zero over 20 h of incubation. The transformation capacity of the slurry enrichments (~1 µmol MeBr ml–1 soil slurry) was similar to the value measured previously in cell suspensions of N. europaea with similar NH3-oxidizing activity. Several MeBr-degrading characteristics of the nitrifying enrichments were found to be similar to those documented in the literature for MeBr-degrading methanotrophs and facultatively methylotrophic bacteria.
Enhanced transformation of polycyclic aromatic hydrocarbons using a combined Fenton's reagent, microbial treatment and surfactants by N. Nadarajah; J. Van Hamme; J. Pannu; A. Singh; O. Ward (pp. 540-544).
The potential for using Fenton's reagent (H2O2 + Fe2+) as an advanced oxidation pretreatment process to enhance microbial transformation of two model polycyclic aromatic hydrocarbons, anthracene and benzo[a]pyrene, in an aqueous system was evaluated. Fenton's reagent at a concentration of 0.5% H2O2 and 10 mM Fe2+ (molar ratio, 15:1) was most effective in transforming anthracene at pH 4. Application of non-ionic surfactants during Fenton's pre-treatment was found to be more effective in the transformation of both anthracene and benzo[a]pyrene. The extent of removal of substrates by a combined Fenton's–biotreatment was 2–4 times higher than with Fenton's treatment or biotreatment alone. In a chemical–biological treatment train, 48 h of Fenton's pre-treatment in the presence of a non-ionic surfactant, followed by 7 days of biological treatment resulted in 80–85% removal of PAHs (100 ppm).
Cloning and characterization of a FAD-monooxygenase gene (cadA) involved in degradation of chloranilic acid (2,5-dichloro-3,6-dihydroxybenzo-1,4-quinone) in Pseudomonas putida TQ07 by L. Treviño-Quintanilla; L. Galán-Wong; B. Rodríguez-Uribe; G. Soberón-Chávez (pp. 545-550).
A bacterium culture was isolated on the basis of its ability to degrade chloranilic acid, and was later identified as Pseudomonas putida (TQ07). Several transposon insertion mutants unable to degrade chloranilic acid were selected. The characterization of the site of insertion of one of these mutants led to the identification of the cadA gene encoding an enzyme with significant homology with FAD-monooxygenases involved in the degradation of aromatic and chloroaromatic compounds. The finding that, after replacing the mutant allele with the wild-type one, the strain recovered the wild-type pattern of "halo" formation (a zone of clearing color on agar plates around TQ07 colonies that degrade chloranilic acid) and degradation of chloranilic acid, unequivocally assigned cadA a function in the metabolism of this compound. We also found that most of the transposon insertion mutants unable to degrade chloranilic acid are clustered in a 10-kb region of the P. putida genome that is encoded in a megaplasmid or in an unstable chromosomal region.
Biostimulation and bioaugmentation for on-site treatment of weathered diesel fuel in Arctic soil by E. Thomassin-Lacroix; M. Eriksson; K. Reimer; W. Mohn (pp. 551-556).
Bioremediation of weathered diesel fuel in Arctic soil at low temperature was studied both on-site in small-scale biopiles and in laboratory microcosms. The field study site was on Ellesmere Island (82°30'N, 62°20'W). Biostimulation was by fertilization with phosphorous and nitrogen. Bioaugmentation was with an enrichment culture originating from the field site. In biopiles, total petroleum hydrocarbons (TPH) were reduced from 2.9 to 0.5 mg/g of dry soil over a period of 65 days. In microcosms at 7 °C, TPH were reduced from 2.4 to 0.5 mg/g of dry soil over a period of 90 days. Inoculation had no effect on hydrocarbon removal in biopiles or in microcosms. Maximum TPH removal rates in the biopiles were approximately 90 µg of TPH g–1 of soil day–1, occurring during the first 14 days when ambient temperature ranged from 0 to 10 °C. The fate of three phylotypes present in the inoculum was monitored using most-probable-number PCR, targeting 16S rRNA genes. Populations of all three phylotypes increased more than 100-fold during incubation of both uninoculated and inoculated biopiles. The inoculum increased the initial populations of the phylotypes but did not significantly affect their final populations. Thus, biostimulation on site enriched populations that were also selected in laboratory enrichment cultures.
Oxygen-limited autotrophic nitrification/denitrification by ammonia oxidisers enables upward motion towards more favourable conditions by S. Philips; S. Wyffels; R. Sprengers; W. Verstraete (pp. 557-566).
The hypothesis is formulated that in case of oxygen limitation in the sediment, nitrifiers switch from nitrification to oxygen-limited autotrophic nitrification-denitrification (OLAND) in order to survive and maintain activity. During OLAND, ammonium is oxidised using nitrite as e-acceptor to form dinitrogen gas. As an additional advantage they benefit from the gaseous N2 formed as a means of transport. In this way, the nitrifiers can move out of the sediment and rise through the water column towards more favourable conditions. At the surface, the bacteria could take up oxygen, and recommence nitrification. In order to test this hypothesis, nitrifying sediment with an overlaying water column was simulated in lab-scale columns. Nitrogen transformations and material transport through the water column were followed after addition of different forms of nitrogen under oxygen-limited conditions. 15N-labelling experiments showed a large contribution of OLAND to the observed nitrogen deficits. Nitrifier enumerations, fluorescent in situ hybridisation and 16S rRNA gene analysis revealed increased populations of ammonia oxidising nitrifiers in the upper water layers. The results presented support the proposed hypothesis of transport using OLAND. Nitrifying activity in the sediment immediately recovered almost completely from prolonged oxygen-limited incubation when oxygen concentrations were increased.
Optimization of nutrient supply in a downflow gas-phase biofilter packed with an inert carrier by Ó. Prado; J. Mendoza; M. Veiga; C. Kennes (pp. 567-573).
Several methodologies were tested to supply nutrients to a downflow biofilter packed with perlite and used to treat toluene-polluted air. Despite the presence of an inorganic carrier, elimination capacities of up to around 60 g/m3 per hour could be maintained when a basal medium, containing nitrogen, phosphorus and potassium, was supplied once every fortnight or even once a month rather than once a week. Experimental results also indicated that the addition of vitamins or trace minerals to the basal aqueous medium hardly improved biofilter performance. Furthermore, the nutrient supply could be combined with a biomass control strategy, using air sparging, without any adverse effect on biofilter performance compared to supplying nutrients alone, and limiting the accumulation of excess biomass on the packing material. The performance of the biofilter was not significantly affected by temperature fluctuations between 25 and 33 °C.
Effect of dispersing oil phase on the biodegradability of a solid alkane dissolved in non-biodegradable oil by K. Hori; Y. Matsuzaki; Y. Tanji; H. Unno (pp. 574-579).
Acinetobacter sp. CR was grown on a model oil, which consisted of an inert oil matrix of pristane with n-heneicosane dissolved in it as the sole carbon source, in a stirred-tank bioreactor. This bacterium takes up substrates from the oil phase by direct contact with the oil phase. A previously established mathematical model was applied to reveal the effect of agitation conditions on the growth and n-alkane degradation kinetics of the bacterium. Higher impeller speed resulted in both lower microbial growth and lower n-alkane degradation rate of the bacterium, although it increased the specific surface area of the oil, which was measured by a previously developed device. This result was due to the decreased number of cells adhering to the oil surface, i.e., intense agitation inhibited the adhesion of cells to the oil surface. The addition of a surfactant below a critical micelle concentration (CMC) inhibited the degradation of n-heneicosane dissolved in pristane, although the biodegradability of the substrate recovered gradually with the increase in the dose of surfactant over CMC. The results suggest that efforts to increase the specific surface area of the oil phase have the undesirable result of inhibiting oil degradation when the dominant microbial degraders take up substrates in oil by direct contact with the oil.
Solubilization of polyaromatic hydrocarbons by recombinant bioemulsifier AlnA by A. Toren; E. Ron; R. Bekerman; E. Rosenberg (pp. 580-584).
AlnA is the protein responsible for the emulsifying and solubilizing activity of the Acinetobacter radioresistens KA53 bioemulsifier alasan. AlnA was produced in Escherichia coli, purified to homogeneity and then used to measure the enhanced solubility of 12 polyaromatic hydrocarbons (PAHs). The amount of PAH solubilized was directly proportional to AlnA concentration. The ratio of PAH solubilized by 40 µg/ml AlnA compared to that soluble in the aqueous buffer varied greatly, from 4 (fluorene) to 81 (hexylbenzylcyclosilane). Calculations of moles PAH solubilized per mole AlnA yielded values from 4.3 (hexylphenylbenzene) to 55.8 (1,10-phenanthrolene). There was no obvious relationship between the amount of PAH solubilized and its molecular weight or intrinsic solubility. Native gel electrophoresis indicated that AlnA formed hexamers in the presence of PAHs. With molar ratios of fluorene to AlnA of 0.75 or less, only the monomer was observed, whereas at ratios of 7.5 or higher, only the hexamer was detected. At an intermediate molar ratio of 2.6, both monomer and hexamer appeared. The data indicate that PAHs are initially solubilized by binding to the monomeric form of AlnA, and as the amount bound increases above one molecule PAH per AlnA, the protein aggregates to form a specific oligomer of 5–8 monomers which allows for the binding and solubilization of more PAH.
Population dynamics of free-floating and attached bacteria in a styrene-degrading biotrickling filter analyzed by denaturing gradient gel electrophoresis by O. Tresse; M.-J. Lorrain; D. Rho (pp. 585-590).
Population dynamics was studied in a 52-l biotrickling filter (BTF) operated for 182 days and used to clean air contaminated with styrene vapors. In the BTF, biomass grew either as free-floating (planktonic) or attached (sessile) microorganisms. PCR-amplified 16S rDNA fragments from planktonic and sessile cells within the bioreactor were analyzed using denaturing gradient gel electrophoresis (DGGE). The results indicated that the complexity of biofilm community was always more pronounced than the complexity of the planktonic cell community. Notably, Rhodococcus erythropolis was identified, based on DNA sequence analysis, as one of the biofilm-specific strains. It was also shown that the inoculum, even when enriched with styrene-degrading bacteria, was not adapted to the growth conditions imposed by the BTF. After a 35-day microbial acclimation period, the DGGE analysis also showed less variation in the banding pattern representing the microbial complexity of the biofilm. In addition, the phylogenic fingerprinting method used demonstrated similar banding profiles in the biofilm along the filter bed.
The influence of lignin content and temperature on the biodegradation of lignocellulose in composting conditions by M. Vikman; S. Karjomaa; A. Kapanen; K. Wallenius; M. Itävaara (pp. 591-598).
The aim of this research was to study the influence of lignin content and composting temperature on the biodegradation of lignin-containing pulp and paper products in a controlled composting test (European standard prEN 14046). Lignin reduced the biodegradation of the samples, and there was a linear correlation between the lignin content and the biodegradation of pulp and paper products at 58°C. The influence of incubation temperature (35, 50 and 58°C) on biodegradation was studied using bleached kraft paper containing 0.2 wt% lignin and mechanical pulp (stone-ground wood) containing 24–27 wt% lignin. Mechanical pulp biodegraded better at lower temperatures, while kraft paper biodegraded well at all three temperatures. Microbial activity was evaluated by measuring CO2 evolution and the change in ATP content, and fungal biomass by measuring the ergosterol content during the composting experiments. Kraft paper strongly increased microbial activity during the controlled composting test, but the activity returned to the background level at the end of the composting test. The proportion of sample carbon converted to microbial biomass carbon was considerably higher at lower incubation temperatures. Changes in microbial community structure during biodegradation of mechanical pulp and kraft paper at 50°C were studied by the PCR-based technique denaturing gradient gel electrophoresis. Changes in the microbial community were observed during the intensive degradation phase of kraft paper.
Adaptation of the white-rot basidiomycete Panus tigrinus for transformation of high concentrations of chlorophenols by A. Leontievsky; N. Myasoedova; L. Golovleva; M. Sedarati; C. Evans (pp. 599-604).
During feed-batch cultivation of the white-rot fungus Panus tigrinus in a 5-l bioreactor on N-limited medium, 100, 200, 500, 1,000 and 2,000 mg 2,4,6-trichlorophenol (2,4,6-TCP) l–1 were added sequentially after 90% removal of the previous portion of the toxicant. The addition of 500 mg 2,4,6-TCP l–1 without preliminary adaptation killed the culture. The addition of 300 mg 2,4,6-TCP l–1 without prior adaptation resulted in its slower removal than removal of 2,000 mg 2,4,6-TCP l–1 by this adapted culture. After adaptation of P. tigrinus to 2,4,6-TCP in a 72-l bioreactor, the mixture of 2,4-dichlorophenol, 2,4,6-TCP, and pentachlorophenol, each at 500 mg l–1, was totally removed over 3 weeks. No lignin peroxidase activity was found in the course of cultivation of the fungus. Laccase activity was suppressed by addition of 2,4,6-TCP. Mn-peroxidase was found to be responsible for transformation of the chlorophenols. As final products of the process, several newly formed aromatic polymers, both chlorinated and non-chlorinated, were found in the culture liquid.
Kinetics of soluble microbial product formation in substrate-sufficient batch culture of activated sludge by Y. Liu; J.-L. Rols (pp. 605-608).
The kinetics of soluble microbial product (SMP) formation under substrate-sufficient conditions appear to exhibit different patterns from substrate-limited cultures. However, energy spilling-associated SMP formation is not taken into account in the existing kinetic models and classification of SMP. Based on the concepts of growth yield and energy uncoupling, a kinetic model describing energy spilling-associated SMP formation in relation to the ratio of initial substrate concentration to initial biomass concentration (S 0/X 0) was developed for substrate-sufficient batch culture of activated sludge, and was verified by experimental data. The specific rate of energy spilling-associated SMP formation showed an increasing trend with the S 0/X 0 ratio up to its maximum value. The SMP productivity coefficient (α p/e) was defined from the model on the basis of energy spilling-associated substrate consumption. Results revealed that less than 5% of energy spilling-associated substrate consumption was converted into SMP.