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Applied Microbiology and Biotechnology (v.71, #1)
In situ product recovery (ISPR) by crystallization: basic principles, design, and potential applications in whole-cell biocatalysis by Evelyn M. Buque-Taboada; Adrie J. J. Straathof; Joseph J. Heijnen; Luuk A. M. van der Wielen (pp. 1-12).
The removal of inhibiting or degrading product from a bioreactor as soon as the product is formed is an important issue in industrial bioprocess development. In this review, the potential of crystallization as an in situ product removal (ISPR) technique for the biocatalytic production of crystalline compounds is discussed. The emphasis of this review is on the current status of crystalline product formation by metabolically active cells for application in fine-chemicals production. Examples of relevant biocatalytic conversions are summarized, and some basic process options are discussed. Furthermore, a case study is presented in which two conceptual process designs are compared. In one process, product formation and crystallization are integrated by applying ISPR, whereas a second, nonintegrated process is based on a known conventional process equivalent for the production of 6R-dihydro-oxoisophorone. The comparison indicates that employing ISPR leads to significant advantages over the nonintegrated case in terms of increased productivity and yield with a corresponding decrease in the number of downstream processing steps, as well as in the quantity of waste streams. This leads to an economically more interesting process alternative. Finally, a general outlook on the various research aspects of ISPR by crystallization is given.
Lipids as renewable resources: current state of chemical and biotechnological conversion and diversification by J. O. Metzger; U. Bornscheuer (pp. 13-22).
Oils and fats are the most important renewable raw materials of the chemical industry. They make available fatty acids in such purity that they may be used for chemical conversions and for the synthesis of chemically pure compounds. Oleic acid (1) from “new sunflower,” linoleic acid (2) from soybean, linolenic acid (3) from linseed, erucic acid (4) from rape seed, and ricinoleic acid (5) from castor oil are most important for chemical transformations offering in addition to the carboxy group one or more C-C-double bonds. New plant oils containing fatty acids with new and interesting functionalities such as petroselinic acid (6) from Coriandrum sativum, calendic acid (7) from Calendula officinalis, α-eleostearic acid (8) from tung oil, santalbic acid (9) from Santalum album (Linn.), and vernolic acid (10) from Vernonia galamensis are becoming industrially available. The basic oleochemicals are free fatty acids, methyl esters, fatty alcohols, and fatty amines as well as glycerol as a by-product. Their interesting new industrial applications are the usage as environmentally friendly industrial fluids and lubricants, insulating fluid for electric utilities such as transformers and additive to asphalt. Modern methods of synthetic organic chemistry including enzymatic and microbial transformations were applied extensively to fatty compounds for the selective functionalization of the alkyl chain. Syntheses of long-chain diacids, ω-hydroxy fatty acids, and ω-unsaturated fatty acids as base chemicals derived from vegetable oils were developed. Interesting applications were opened by the epoxidation of C-C-double bonds giving the possibility of photochemically initiated cationic curing and access to polyetherpolyols. Enantiomerically pure fatty acids as part of the chiral pool of nature can be used for the synthesis of nonracemic building blocks.
Bioconversion of red seaweed galactans: a focus on bacterial agarases and carrageenases by Gurvan Michel; Pi Nyval-Collen; Tristan Barbeyron; Mirjam Czjzek; William Helbert (pp. 23-33).
Agars and carrageenans are 1,3-α-1,4-β-galactans from the cell walls of red algae, substituted by zero (agarose), one (κ-), two (ι-), or three (λ-carrageenan) sulfate groups per disaccharidic monomer. Agars, κ-, and ι-carrageenans auto-associate into crystalline fibers and are well known for their gelling properties, used in a variety of laboratory and industrial applications. These sulfated galactans constitute a crucial carbon source for a number of marine bacteria. These microorganisms secrete glycoside hydrolases specific for these polyanionic, insoluble polysaccharides, agarases and carrageenases. This article reviews the microorganisms involved in the degradation of agars and carrageenans, in their environmental and taxonomic diversity. We also present an overview on the biochemistry of the different families of galactanases. The structure–function relationships of the family GH16 β-agarases and κ-caraggeenases and of the family GH82 ι-carrageenases are discussed in more details. In particular, we examine how the active site topologies of these glycoside hydrolases influence their mode of action in heterogeneous phase. Finally, we discuss the next challenges in the basic and applied field of the galactans of red algae and of their related degrading microorganisms.
Novel polysaccharide–protein-based amphipathic formulations by Horacio Bach; David L. Gutnick (pp. 34-38).
Previous results showed that the cell-surface esterase from Acinetobacter venetianus RAG-1 enhances the emulsification properties of the polymeric bioemulsifier emulsan and its deproteinated derivative apoemulsan (Bach H, Berdichevsky Y, Gutnick D (2003) An exocellular protein from the oil-degrading microbe Acinetobacter venetianus RAG-1 enhances the emulsifying activity of the polymeric bioemulsifier emulsan. Appl Environ Microbiol 69:2608–2615). Here we show that in the presence of the his-tagged recombinant esterase from RAG-1, 18 different polysaccharides from microbial, plant, insect and synthetic sources formed hexadecane-in-water emulsions. Emulsifying activities were distributed over a 13-fold range from over 4800 U/mg protein/mg polysaccharide in the case of apoemulsan to 370 U/mg protein/mg polysaccharide in the case of alginic acid. The stability of the emulsions ranged between 95 and 58%. Emulsions formed in the presence of seven of the polysaccharides exhibited stabilities of over 80%. The esterase from A. calcoaceticus BD4, which shows sequence homology to the RAG-1 esterase, was inactive in emulsification enhancement. The sequence of the RAG-1 esterase was shown to contain two conserved peptide sequences previously shown to be implicated in carbohydrate/polysaccharide binding. A hypothetical model illustrating a possible mode of interaction between the esterase, the apoemulsan and the oil droplet is presented. The complex is presumed to generate a series of “coated” oil droplets which are restricted in their ability to coalesce resulting in a relatively stable emulsion.
Practical applications of high-affinity, albumin-binding proteins from a group G streptococcal isolate by Emily M. Coyle; Levi L. Blazer; Abby A. White; Jennifer L. Hess; Michael D. P. Boyle (pp. 39-45).
Binding proteins that have high affinities for mammalian plasma proteins that are expressed on the surface of bacteria have proven valuable for the purification and detection of several biologically important molecules from human and animal plasma or serum. In this study, we have isolated a high affinity albumin-binding molecule from a group G streptococcal isolate of bovine origin and have demonstrated that the isolated protein can be biotinylated without loss of binding activity and can be used as a tracer for quantification of human serum albumin (HSA). The binding protein can be immobilized and used as a selective capture reagent in a competitive ELISA format using a biotinylated HSA tracer. In this assay format, the sensitivity of detection for 50% inhibition of binding of HSA was less than 1 μg/ml. When attached to the bacterial surface, this binding protein can be used to deplete albumin from human plasma, as analyzed by surface-enhanced laser desorption ionization time of flight mass spectrometry.
Expression of alanine:glyoxylate aminotransferase gene from Saccharomyces cerevisiae in Ashbya gossypii by Tatsuya Kato; Enoch Y. Park (pp. 46-52).
Two plasmids containing an autonomously replicating sequence from Saccharomyces cerevisiae were constructed. Using these vectors, the AGX1 gene encoding alanine:glyoxylate aminotransferase (AGT) from S. cerevisiae, which converts glyoxylate into glycine but is not present in Ashbya gossypii, was expressed in A. gossypii. Geneticin-resistant transformants with the plasmid having the kanamycin resistance gene under the control of the translation elongation factor 1 α (TEF) promoter and terminator from A. gossypii were obtained with a transformation efficiency of approximately 10–20 transformants per microgram of plasmid DNA. The specific AGT activities of A. gossypii pYPKTPAT carrying the AGX1 gene in glucose- and rapeseed-oil-containing media were 40 and 160 mU mg−1 of wet mycelial weight, respectively. The riboflavin concentrations of A. gossypii pYPKTPAT carrying AGX1 gene in glucose- and rapeseed-oil-containing media were 20 and 150 mg l−1, respectively. In the presence of 50 mM glyoxylate, the riboflavin concentration and the specific riboflavin concentration of A. gossypii pYPKTPAT were 2- and 1.3-fold those of A. gossypii pYPKT without the AGX1 gene.
Combinatorial biosynthesis of flavones and flavonols in Escherichia coli by Ikuo Miyahisa; Nobutaka Funa; Yasuo Ohnishi; Stefan Martens; Takaya Moriguchi; Sueharu Horinouchi (pp. 53-58).
(2S)-Flavanones (naringenin and pinocembrin) are key intermediates in the flavonoid biosynthetic pathway in plants. Recombinant Escherichia coli cells containing four genes for a phenylalanine ammonia-lyase, cinnamate/coumarate:CoA ligase, chalcone synthase, and chalcone isomerase, in addition to the acetyl-CoA carboxylase, have been established for efficient production of (2S)-naringenin from tyrosine and (2S)-pinocembrin from phenylalanine. Further introduction of the flavone synthase I gene from Petroselinum crispum under the control of the T7 promoter and the synthetic ribosome-binding sequence in pACYCDuet-1 caused the E. coli cells to produce flavones: apigenin (13 mg/l) from tyrosine and chrysin (9.4 mg/l) from phenylalanine. Introduction into the E. coli cells of the flavanone 3β-hydroxylase and flavonol synthase genes from the plant Citrus species led to production of flavonols: kaempferol (15.1 mg/l) from tyrosine and galangin (1.1 mg/l) from phenylalanine. The combinatorial biosynthesis of the flavones and flavonols in E. coli is promising for the construction of a library of various flavonoid compounds and un-natural flavonoids in bacteria.
Use of reporter transposons for tagging and detection of Mycobacterium sp. strain 1B in PAH-contaminated soil by C. E. Dandie; R. H. Bentham; S. M. Thomas (pp. 59-66).
An environmental Mycobacterium able to degrade phenanthrene, pyrene and fluoranthene was transformed with an IS1096-based transposon marker system. Electroporation and subsequent delivery of the transposon enabled formation of constitutive lacZ transformants, with similar growth rates on pyrene and R2A media to the parental strain. A semi-selective medium was developed to recover and detect colonies of the transformed strain after inoculation into polycyclic aromatic hydrocarbon-contaminated soil. Microcosm experiments involving inoculation of the tagged Mycobacterium strain into a historically PAH-contaminated soil indicated survival when an appropriate carbon source was available. The results reported show that transposon systems developed for clinical mycobacterial isolates are also applicable for use in environmental isolates. The results also show that inoculated Mycobacterium strains could survive for at least 100 days at 106–107 cfu g−1 in the PAH-contaminated soil tested here.
Genetic organization of a plasmid from an industrial wastewater bioreactor by Michael Bramucci; Mario Chen; Vasantha Nagarajan (pp. 67-74).
Pseudomonas strain CT14 was isolated from activated sludge. Strain CT14 contained a 55, 216 bp plasmid that was characterized by sequence analysis. The plasmid had a modular structure with 51 open reading frames (ORFs) that were distributed between two clearly demarcated domains. Domain I primarily contained genes for plasmid-related functions and a novel origin of replication. Domain II bore evidence of extensive transposition and recombination. Domain II contained several genes from a meta-cleavage pathway for aromatic rings. These genes appeared to have been recruited from different hosts. This observation suggests that sequencing pCT14 may have revealed an intermediate stage in the evolution of a new assemblage of meta-cleavage pathway genes.
Screening for candidate genes involved in tolerance to organic solvents in yeast by Ken Matsui; Takashi Hirayama; Kouichi Kuroda; Katsuhiko Shirahige; Toshihiko Ashikari; Mitsuyoshi Ueda (pp. 75-79).
Saccharomyces cerevisiae mutant strain, KK-211, isolated from serial culture in medium containing isooctane showed an extremely higher tolerance to the hydrophobic organic-solvents, which are toxic to yeast cells compared to the wild-type parent strain, DY-1. To detect genes that are related to this tolerance, a DNA microarray analysis was performed using mRNAs isolated from strains DY-1 and KK-211. Fourteen genes were identified as being related to the tolerance. The expression of 12 genes including ICT1, YNL190W, and PRY3, was induced while the expression of two genes including PHO84 was repressed in strain KK-211. Two genes, ICT1 and YNL190W showed the same profile in the DNA microarray analysis and a differential display-polymerase chain reaction analysis. But, there is no detectable difference in the expression profile of KK-211 cells cultured with or without isooctane. The results suggest that change in expression levels of multiple genes that confer the modification function of the cell surface, not by a single gene, might be required for yeast cell tolerance to organic solvents.
Occurrence and expression of tricarboxylate synthases in Ralstonia eutropha by Christian Ewering; Christian O. Brämer; Nadine Bruland; Axel Bethke; Alexander Steinbüchel (pp. 80-89).
2-Methylcitrate synthase (2-MCS1) and citrate synthase (CS) of Ralstonia eutropha strain H16 were separated by affinity chromatography and analyzed for their substrate specificities. 2-MCS1 used not only the primary substrate propionyl-CoA but also acetyl-CoA and, at a low rate, even butyryl-CoA and valeryl-CoA for condensation with oxaloacetate. The K M values for propionyl-CoA and acetyl-CoA were 0.061 or 0.35 mM, respectively. This enzyme is therefore a competitor for acetyl-CoA during biosynthesis of poly(3-hydroxybutyrate) (PHB) and has to be taken into account if metabolic fluxes are calculated for PHB biosynthesis. In contrast, CS could not use propionyl-CoA as a substrate. The gene-encoding CS (cisY) of R. eutropha was cloned and encodes for a protein consisting of 433 amino acids with a calculated molecular weight of 48,600 Da; it is not truncated in the N-terminal region. Furthermore, a gene encoding a second functionally active 2-methylcitrate synthase (2-MCS2, prpC2) was identified in the genome of R. eutropha. The latter was localized in a gene cluster with genes for an NAD(H)-dependent malate dehydrogenase and a putative citrate lyase. RT-PCR analysis of R. eutropha growing on different carbon sources revealed the transcription of prpC2. In addition, cells of recombinant Escherichia coli strains harboring prpC2 of R. eutropha exhibited high 2-MCS activity of 0.544 U mg−1. A prpC2 knockout mutant of R. eutropha exhibited an identical phenotype as the wild type if grown on different media. 2-MCS2 seems to be dispensable, and a function could not be revealed for this enzyme.
Patterns of metabolites produced from the fluoroquinolone enrofloxacin by basidiomycetes indigenous to agricultural sites by H.- G. Wetzstein; J. Schneider; W. Karl (pp. 90-100).
Supernatants of mycelial cultures of seven basidiomycetous fungi indigenous to agricultural sites were evaluated for metabolites generated from the veterinary fluoroquinolone enrofloxacin (EFL) by employing high–performance liquid chromatography/high–resolution electrospray ionization mass spectrometry. From exact masses, molecular formulae were derived, and the most probable chemical structures were deduced. Patterns of major metabolites were surprisingly similar but differed greatly from that provided by Gloeophyllum striatum due to the absence of monohydroxylated EFL congeners and a greater variety of metabolites with a modified piperazine moiety. The structures of three metabolites were elucidated by 1H–nuclear magnetic resonance spectroscopy. Of 61 compounds detected, 48 were new, while 13 were known from a pattern of 87 EFL metabolites identified for G. striatum. Ethylpiperazine moieties carrying oxido, hydroxy, oxo, and acetoxy groups, or showing partial degradation, were linked to the unmodified, oxidatively decarboxylated, or multiply hydroxylated core of EFL and to isatin– and anthranilic acid–type EFL congeners. Cleavage of the fluoro–aromatic bond was observed for two, 14CO2 formation for six species. Metabolites with a hydroxylated aromatic part implied subsequent ring cleavage to be brought about by the formation of potentially four oxidizable ortho–aminophenol– and one catechol–type intermediates. EFL degradation appears to be a common activity among basidiomycetes.
Outlines of an “exploding” network of metabolites generated from the fluoroquinolone enrofloxacin by the brown rot fungus Gloeophyllum striatum by W. Karl; J. Schneider; H.-G. Wetzstein (pp. 101-113).
Degradation of the veterinary fluoroquinolone antibiotic enrofloxacin (EFL) was studied with three strains of Gloeophyllum, basidiomycetous fungi thought to produce extracellular hydroxyl radicals. Metabolites generated in a mineral medium were analyzed by combined high-performance liquid chromatography/high-resolution electrospray ionization mass spectrometry. Their origin was inferred from peak doublets representing 12C and 14C isotopomers detected at a defined proportion. From each exact molecular mass, the molecular formula was derived for which the most probable chemical structure was postulated, using for guidance 18 known EFL metabolites. All supernatants provided similar metabolite patterns, with the most comprehensive consisting of 87 compounds. These metabolites belonged to five families headed by EFL, its oxidatively decarboxylated or defluorinated congeners, an isatin-, and an anthranilic acid-type derivative. Metabolites hydroxylated in the aromatic part suggested the formation of three catechols and two oxidizable ortho-aminophenol-type compounds. After oxidation to the respective ortho-quinones or ortho-quinone imines and oxidative ring cleavage at one of three alternative sites, the formation of various cis,cis-muconic acid-type derivatives is likely, one of which could be detected. Anthranilic acid-type compounds provided two additional sites for ortho-aminophenol formation and aromatic ring cleavage. An “exploding” network of diverse EFL congeners produced by Gloeophyllum suggests the broad utility of our model for studying biodegradation.
Molecular breeding of white rot fungus Pleurotus ostreatus by homologous expression of its versatile peroxidase MnP2 by Takahisa Tsukihara; Yoichi Honda; Takahito Watanabe; Takashi Watanabe (pp. 114-120).
Using a DNA-mediated transformation technique, a molecular breeding approach to isolate Pleurotus ostreatus strains with enhanced productivity of its versatile peroxidase MnP2 was conducted. A recombinant mnp2 construct under the control of P. ostreatus sdi1 expression signals was introduced into the wild-type P. ostreatus strain by cotransformation with a carboxin-resistant marker plasmid. A total of 32 transformants containing the recombinant mnp2 sequence were isolated in a screening with specific amplification by PCR. Productivity of MnP2 in the recombinants was evaluated by the decolorization ability of Poly R-478 on agar plates in the absence of Mn2+. Recombinant P. ostreatus strains with elevated manganese peroxidase (MnP) productivity were successfully isolated. One of the recombinants, TM2-10, was demonstrated to secrete recombinant MnP2 predominantly on a synthetic medium containing 15 mM ammonium oxalate, which was confirmed by reverse transcription PCR (RT-PCR) and isozyme profile analysis using anion-exchange chromatography. The benzo[a]pyrene-removing activity by fungal treatment was also analyzed using the isolated recombinant strains.
Use of fluorescence spectroscopy to differentiate yeast and bacterial cells by Hemant Bhatta; Ewa M. Goldys; Robert P. Learmonth (pp. 121-126).
This study focuses on the characterization of bacterial and yeast species through their autofluorescence spectra. Lactic acid bacteria (Lactobacillus sp.), and yeast (Saccharomyces sp.) were cultured under controlled conditions and studied for variations in their autofluorescence, particularly in the area representative of tryptophan residues of proteins. The emission and excitation spectra clearly reveal that bacterial and yeast species can be differentiated by their intrinsic fluorescence with UV excitation. The possibility of differentiation between different strains of Saccharomyces yeast was also studied, with clear differences observed for selected strains. The study shows that fluorescence can be successfully used to differentiate between yeast and bacteria and between different yeast species, through the identification of spectroscopic fingerprints, without the need for fluorescent staining.