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Applied Microbiology and Biotechnology (v.91, #1)
Features and applications of bacterial sialidases by Seonghun Kim; Doo-Byoung Oh; Hyun Ah Kang; Ohsuk Kwon (pp. 1-15).
Sialidases, or neuraminidases (EC 3.2.1.18), belong to a class of glycosyl hydrolases that release terminal N-acylneuraminate residues from the glycans of glycoproteins, glycolipids, and polysaccharides. In bacteria, sialidases can be used to scavenge sialic acids as a nutrient from various sialylated substrates or to recognize sialic acids exposed on the surface of the host cell. Despite the fact that bacterial sialidases share many structural features, their biochemical properties, especially their linkage and substrate specificities, vary widely. Bacterial sialidases can catalyze the hydrolysis of terminal sialic acids linked by the α(2,3)-, α(2,6)-, or α(2,8)-linkage to a diverse range of substrates. In addition, some of these enzymes can catalyze the transfer of sialic acids from sialoglycans to asialoglycoconjugates via a transglycosylation reaction mechanism. Thus, some bacterial sialidases have been applied to synthesize complex sialyloligosaccharides through chemoenzymatic approaches and to analyze the glycan structure. In this review article, the biochemical features of bacterial sialidases and their potential applications in regioselective hydrolysis reactions as well as sialylation by transglycosylation for the synthesis of sialylated complex glycans are discussed.
Keywords: Sialidase; In vitro trans-sialylation; Sialoglycoconjugate; Chemoenzymatic synthesis; Sialic acid; Regioselectivity
Biotechnological production of polyamines by Bacteria: recent achievements and future perspectives by Jens Schneider; Volker F. Wendisch (pp. 17-30).
In Bacteria, the pathways of polyamine biosynthesis start with the amino acids l-lysine, l-ornithine, l-arginine, or l-aspartic acid. Some of these polyamines are of special interest due to their use in the production of engineering plastics (e.g., polyamides) or as curing agents in polymer applications. At present, the polyamines for industrial use are mainly synthesized on chemical routes. However, since a commercial market for polyamines as well as an industry for the fermentative production of amino acid exist, and since bacterial strains overproducing the polyamine precursors l-lysine, l-ornithine, and l-arginine are known, it was envisioned to engineer these amino acid-producing strains for polyamine production. Only recently, researchers have investigated the potential of amino acid-producing strains of Corynebacterium glutamicum and Escherichia coli for polyamine production. This mini-review illustrates the current knowledge of polyamine metabolism in Bacteria, including anabolism, catabolism, uptake, and excretion. The recent advances in engineering the industrial model bacteria C. glutamicum and E. coli for efficient production of the most promising polyamines, putrescine (1,4-diaminobutane), and cadaverine (1,5-diaminopentane), are discussed in more detail.
Keywords: Corynebacterium glutamicum ; Escherichia coli ; Polyamines; Polyamides; Polymer; Cadaverine; Putrescine; 1,5-diaminopentane; 1,4-diaminobutane
Best practices in heterotrophic high-cell-density microalgal processes: achievements, potential and possible limitations by Fabian Bumbak; Stella Cook; Vilém Zachleder; Silas Hauser; Karin Kovar (pp. 31-46).
Microalgae of numerous heterotrophic genera (obligate or facultative) exhibit considerable metabolic versatility and flexibility but are currently underexploited in the biotechnological manufacturing of known plant-derived compounds, novel high-value biomolecules or enriched biomass. Highly efficient production of microalgal biomass without the need for light is now feasible in inexpensive, well-defined mineral medium, typically supplemented with glucose. Cell densities of more than 100 g l−1 cell dry weight have been achieved with Chlorella, Crypthecodinium and Galdieria species while controlling the addition of organic sources of carbon and energy in fedbatch mode. The ability of microalgae to adapt their metabolism to varying culture conditions provides opportunities to modify, control and thereby maximise the formation of targeted compounds with non-recombinant microalgae. This review outlines the critical aspects of cultivation technology and current best practices in the heterotrophic high-cell-density cultivation of microalgae. The primary topics include (1) the characteristics of microalgae that make them suitable for heterotrophic cultivation, (2) the appropriate chemical composition of mineral growth media, (3) the different strategies for fedbatch cultivations and (4) the principles behind the customisation of biomass composition. The review confirms that, although fundamental knowledge is now available, the development of efficient, economically feasible large-scale bioprocesses remains an obstacle to the commercialisation of this promising technology.
Keywords: Microalgae; Heterotrophic growth; High-cell-density culture; Fedbatch process; Substrate limitation; Stirred tank bioreactor
Bacterial cysteine desulfurases: versatile key players in biosynthetic pathways of sulfur-containing biofactors by Ryota Hidese; Hisaaki Mihara; Nobuyoshi Esaki (pp. 47-61).
Cysteine desulfurases are pyridoxal 5′-phosphate-dependent homodimeric enzymes that catalyze the conversion of L-cysteine to L-alanine and sulfane sulfur via the formation of a protein-bound cysteine persulfide intermediate on a conserved cysteine residue. The enzymes are capable of donating the persulfide sulfur atoms to a variety of biosynthetic pathways for sulfur-containing biofactors, such as iron–sulfur clusters, thiamin, transfer RNA thionucleosides, biotin, and lipoic acid. The enormous advances in biochemical and structural studies of these biosynthetic pathways over the past decades provide an opportunity for detailed understanding of the nature of the excellent sulfur transfer mechanism of cysteine desulfurases.
Keywords: Cysteine desulfurase; Sulfur transfer; Sulfur-containing biofactors; Biosynthetic pathways; A persulfide intermediate
Small RNAs as regulators of primary and secondary metabolism in Pseudomonas species by Elisabeth Sonnleitner; Dieter Haas (pp. 63-79).
Small RNAs (sRNAs) exert important functions in pseudomonads. Classical sRNAs comprise the 4.5S, 6S, 10Sa and 10Sb RNAs, which are known in enteric bacteria as part of the signal recognition particle, a regulatory component of RNA polymerase, transfer–messenger RNA (tmRNA) and the RNA component of RNase P, respectively. Their homologues in pseudomonads are presumed to have analogous functions. Other sRNAs of pseudomonads generally have little or no sequence similarity with sRNAs of enteric bacteria. Numerous sRNAs repress or activate the translation of target mRNAs by a base-pairing mechanism. Examples of this group in Pseudomonas aeruginosa are the iron-repressible PrrF1 and PrrF2 sRNAs, which repress the translation of genes encoding iron-containing proteins, and PhrS, an anaerobically inducible sRNA, which activates the expression of PqsR, a regulator of the Pseudomonas quinolone signal. Other sRNAs sequester RNA-binding proteins that act as translational repressors. Examples of this group in P. aeruginosa include RsmY and RsmZ, which are central regulatory elements in the GacS/GacA signal transduction pathway, and CrcZ, which is a key regulator in the CbrA/CbrB signal transduction pathway. These pathways largely control the extracellular activities (including virulence traits) and the selection of the energetically most favourable carbon sources, respectively, in pseudomonads.
Keywords: Small RNA; Pseudomonas ; Virulence; Carbon catabolite repression; Secondary metabolism; Quorum sensing
Influence of the hydromechanical stress and temperature on growth and antibody fragment production with Bacillus megaterium by Svenja Lüders; Florian David; Miriam Steinwand; Eva Jordan; Michael Hust; Stefan Dübel; Ezequiel Franco-Lara (pp. 81-90).
Bacillus megaterium was used for production of the lysozyme-specific recombinant scFv D1.3 antibody fragment. Key process parameters like the temperature and the hydromechanical stress play a very important role for significant product formation during process development or scale-up. In this study, the influence of these two variables on growth and recombinant antibody fragment production in a 2-L lab-scale bioreactor system was investigated using a central composite design. Especially a significant influence of the hydromechanical stress on antibody fragment production was detected in batch cultivations. While volumetric power inputs of about 0.5 kW/m3 (agitation rates around 500 min−1) are usually employed in batch cultivations, in this work maximal product concentration was found at a volumetric power input of about 0.06 kW/m3 (agitation rate around 250 min−1) and at a high cultivation temperature of 41 °C. The influence of the two process variables at single-cell level was estimated using flow cytometry too. The characterization was done by estimating the membrane potential giving a hint on bioprocess productivity and secretion capability: the best production was obtained through big cells with low specific membrane potential, which grew at low volumetric power inputs and high cultivation temperatures.
Keywords: Single-chain antibody fragment; Volumetric power input; Flow cytometry; Membrane potential
Control of the heparosan N-deacetylation leads to an improved bioengineered heparin by Zhenyu Wang; Bo Yang; Zhenqing Zhang; Mellisa Ly; Majde Takieddin; Shaker Mousa; Jian Liu; Jonathan S. Dordick; Robert J. Linhardt (pp. 91-99).
The production of the anticoagulant drug heparin from non-animal sources has a number of advantages over the current commercial production of heparin. These advantages include better source material availability, improved quality control, and reduced concerns about animal virus or prion impurities. A bioengineered heparin would have to be chemically and biologically equivalent to be substituted for animal-sourced heparin as a pharmaceutical. In an effort to produce bioengineered heparin that more closely resembles pharmaceutical heparin, we have investigated a key step in the process involving the N-deacetylation of heparosan. The extent of N-deacetylation directly affects the N-acetyl/N-sulfo ratio in bioengineered heparin and also impacts its molecular weight. Previous studies have demonstrated that the presence and quantity of N-acetylglucosamine in the nascent glycosaminoglycan chain, serving as the substrate for the subsequent enzymatic modifications (C5 epimerization and O-sulfonation), can impact the action of these enzymes and, thus, the content and distribution of iduronic acid and O-sulfo groups. In this study, we control the N-deacetylation of heparosan to produce a bioengineered heparin with an N-acetyl/N-sulfo ratio and molecular weight that is similar to animal-sourced pharmaceutical heparin. The structural composition and anticoagulant activity of the resultant bioengineered heparin was extensively characterized and compared to pharmaceutical heparin obtained from porcine intestinal mucosa.
Keywords: Heparin; Heparosan; Porcine intestine; Deacetylation
Production of 1,3-propanediol by Clostridium butyricum growing on biodiesel-derived crude glycerol through a non-sterilized fermentation process by Afroditi Chatzifragkou; Seraphim Papanikolaou; David Dietz; Agapi I. Doulgeraki; George-John E. Nychas; An-Ping Zeng (pp. 101-112).
The aim of the present study was to investigate the production of 1,3-propanediol (PDO) under non-sterile fermentation conditions by employing the strain Clostridium butyricum VPI 1718. A series of batch cultures were performed by utilizing biodiesel-derived crude glycerol feedstocks of different origins as the sole carbon source, in various initial concentrations. The strain presented similarities in terms of PDO production when cultivated on crude glycerol of various origins, with final concentrations ranging between 11.1 and 11.5 g/L. Moreover, PDO fermentation was successfully concluded regardless of the initial crude glycerol concentration imposed (from 20 to 80 g/L), accompanied by sufficient PDO production yields (0.52–0.55 g per gram of glycerol consumed). During fed-batch operation under non-sterile culture conditions, 67.9 g/L of PDO were finally produced, with a yield of 0.55 g/g. Additionally, the sustainability of the bioprocess during a continuous operation was tested; indeed, the system was able to run at steady state for 16 days, during which PDO effluent level was 13.9 g/L. Furthermore, possible existence of a microbial community inside the chemostat was evaluated by operating a polymerase chain reaction-denaturing gradient gel electrophoresis (PCR-DGGE) analysis, and DGGE results revealed the presence of only one band corresponding to that of C. butyricum VPI 1718. Finally, non-sterile continuous cultures were carried out at different dilution rates (D), with inlet glycerol concentration at 80 g/L. Maximum PDO production was achieved at low D values (0.02 h−1) corresponding to 30.1 g/L, while the elaboration of kinetic data from continuous cultures revealed the stability of the bioprocess proposed, with global PDO production yield corresponding to 0.52 g/g.
Keywords: Clostridium butyricum ; 1,3-Propanediol; Crude glycerol; Non-sterile fermentation
Unexpected property of ectoine synthase and its application for synthesis of the engineered compatible solute ADPC by Elisabeth M. H. J. Witt; Noel W. Davies; Erwin A. Galinski (pp. 113-122).
A new cyclic amino acid was detected in a deletion mutant of the moderately halophilic bacterium Halomonas elongata deficient in ectoine synthesis. Using mass spectroscopy (MS) and nuclear magnetic resonance (NMR) techniques, the substance was identified as 5-amino-3,4-dihydro-2H-pyrrole-2-carboxylate (ADPC). We were able to demonstrate that ADPC is the product of a side reaction of lone ectoine synthase (EC 4.2.1.108), which forms ADPC by cyclic condensation of glutamine. This reaction was shown to be reversible. Subsequently, a number of ectoine derivatives, in particular 4,5-dihydro-2-methylimidazole-4-carboxylate (DHMICA) and homoectoine, were also shown to be cleaved by ectoine synthase, which is classified as a hydro-lyase. This study thus reports for the first time that ectoine synthase accepts more than one substrate and is a reversible enzyme able to catalyze both the intramolecular condensation into and the hydrolytic cleavage of cyclic amino acid derivatives. As ADPC supports growth of bacteria under salt stress conditions and stabilizes enzymes against freeze-thaw denaturation, it displays typical properties of compatible solutes. As ADPC has not yet been described as a natural compound, it is presented here as the first man-made compatible solute created through genetic engineering.
Keywords: Halomonas elongata ; Ectoine synthase; ADPC; Genetic engineering; Cyclic amino acid derivatives; Compatible solute
How is the reactivity of laccase affected by single-point mutations? Engineering laccase for improved activity towards sterically demanding substrates by Carlo Galli; Patrizia Gentili; Claude Jolivalt; Catherine Madzak; Raffaella Vadalà (pp. 123-131).
In spite of its broad specificity among phenols, Trametes versicolor laccase hardly succeeds in oxidizing hindered substrates. To improve the oxidation ability of this laccase towards bulky phenolic substrates, we designed a series of single-point mutants on the basis of the amino-acid layout inside the reducing substrate active site known from the crystal structure of the enzyme. Site-directed mutagenesis has addressed four phenylalanine residues in key positions 162, 265, 332, and 337 at the entrance of the binding pocket, as these residues appeared instrumental for docking of the substrate. These phenylalanines were replaced by smaller-sized but still apolar alanines. A double mutant F162A/F332A was also designed. Measurement of the oxidation efficiency towards encumbered phenols has shown that mutant F162A was more efficient than the wild-type laccase. The double mutant F162A/F332A led to 98% consumption of bisphenol A in only 5 h and was more efficient than the single mutants in the aerobic oxidation of this bulky substrate. In contrast, lack of appropriate hydrophobic interactions with the substrate possibly depresses the oxidation outcome with mutants F265A and F332A. One explanation for the lack of reactivity of mutant F337A, supported by literature reports, is that this residue is part of the second coordination shell of T1 Cu. A mutation at this position thus leads to a drastic coordination shell destabilization. Thermal stability of the mutants and their resistance in a mixed water–dioxane solvent have also been investigated.
Keywords: Laccase; Site-directed mutagenesis; Steric hindrance; Active site; Oxidation reactivity
Hydrophobin signal sequence mediates efficient secretion of recombinant proteins in Pichia pastoris by Kirsten Kottmeier; Kai Ostermann; Thomas Bley; Gerhard Rödel (pp. 133-141).
Pichia pastoris is an important eukaryotic organism for the expression, processing, and secretion of recombinant proteins. Here, the secretion of enhanced green fluorescent protein (EGFP) in P. pastoris by using three novel secretion signals originating from the HFBI and HFBII class 2 hydrophobins of Trichoderma reesei was investigated. EGFP was fused to the carboxyl terminus of hydrophobin secretion signals and expressed under the control of the constitutive GAP promoter. In every case, recombinant EGFP entered the secretory pathway of P. pastoris. SDS-polyacrylamide gel electrophoresis, Western blot analysis of the cells' supernatant, and fluorescence measurements on single-cell level via flow cytometry confirmed the efficient secretion of EGFP mediated by the novel secretion sequences. In conclusion, the data clearly show that the secretion sequences derived from HFBI and HFBII of T. reesei have the potential to achieve an efficient secretion of heterologous proteins in P. pastoris. Due to the small size of the hydrophobin-derived secretion signals, their coding sequence can be easily introduced to the gene of interest by PCR.
Keywords: Secretion; Hydrophobin; Pichia pastoris ; Signal sequence; Recombinant proteins; EGFP
Investigation of phosphorylation status of OdhI protein during penicillin- and Tween 40-triggered glutamate overproduction by Corynebacterium glutamicum by Jongpill Kim; Takashi Hirasawa; Masaki Saito; Chikara Furusawa; Hiroshi Shimizu (pp. 143-151).
Glutamate overproduction by Corynebacterium glutamicum is triggered by treatment with penicillin or Tween 40 and is accompanied by a decrease in 2-oxoglutarate dehydrogenase complex (ODHC) activity. We have reported that de novo synthesis of OdhI, which inhibits ODHC activity by interacting specifically with the E1o subunit of ODHC (OdhA), is induced by penicillin, and that odhI overexpression induces glutamate overproduction in the absence of any triggers for glutamate overproduction. In this study, to determine the function of OdhI in glutamate overproduction by C. glutamicum, changes in OdhI levels and phosphorylation status during penicillin- and Tween 40-induced glutamate overproduction were examined by western blot. The synthesis of both unphosphorylated and phosphorylated OdhI was increased by addition of Tween 40 or penicillin and the levels of unphosphorylated OdhI, which can inhibit ODHC activity, was significantly higher than those of phosphorylated OdhI, which is unable to inhibit ODHC activity. Meanwhile, the OdhA levels were maintained throughout the culture. These results indicate that OdhI synthesis is induced by additions of penicillin and Tween 40 and most synthesized OdhI is unphosphorylated, resulting in the decrease in ODHC activity and glutamate overproduction. Similarly, in the odhI-overexpressing strain, both unphosphorylated and phosphorylated OdhI were synthesized, while the levels of OdhA were nearly constant throughout culture. Our results suggest that high level of unphosphorylated OdhI regulates glutamate overproduction by C. glutamicum.
Keywords: Corynebacterium glutamicum ; Glutamate production; Penicillin; Tween 40; OdhI; Phosphorylation
The antibacterial activity of biogenic silver and its mode of action by Liesje Sintubin; Bart De Gusseme; Paul Van der Meeren; Benny F. G. Pycke; Willy Verstraete; Nico Boon (pp. 153-162).
In a previous study, biogenic silver nanoparticles were produced by Lactobacillus fermentum which served as a matrix preventing aggregation. In this study the antibacterial activity of this biogenic silver was compared to ionic silver and chemically produced nanosilver. The minimal inhibitory concentration (MIC) was tested on Gram-positive and Gram-negative bacteria and was comparable for biogenic silver and ionic silver ranging from 12.5 to 50 mg/L. In contrast, chemically produced nanosilver had a much higher MIC of at least 500 mg/L, due to aggregation upon application. The minimal bactericidal concentration (MBC) in drinking water varied from 0.1 to 0.5 mg/L for biogenic silver and ionic silver, but for chemically produced nanosilver concentrations, up to 12.5 mg/L was needed. The presence of salts and organic matter decreased the antimicrobial activity of all types of silver resulting in a higher MBC and a slower inactivation of the bacteria. The mode of action of biogenic silver was mainly attributed to the release of silver ions due to the high concentration of free silver ions measured and the resemblance in performance between biogenic silver and ionic silver. Radical formation by biogenic silver and direct contact were found to contribute little to the antibacterial activity. In conclusion, biogenic nanosilver exhibited equal antimicrobial activity compared to ionic silver and can be a valuable alternative for chemically produced nanosilver.
Keywords: Biocide; Nanoparticles; Green chemistry; Biological synthesis; Drinking water; Disinfectant
Sequence and transcriptional analysis of the genes responsible for curdlan biosynthesis in Agrobacterium sp. ATCC 31749 under simulated dissolved oxygen gradients conditions by Hong-Tao Zhang; Xiao-Bei Zhan; Zhi-Yong Zheng; Jian-Rong Wu; Xiao-Bin Yu; Yun Jiang; Chi-Chung Lin (pp. 163-175).
Expression at the mRNA level of ten selected genes in Agrobacterium sp. ATCC 31749 under various dissolved oxygen (DO) levels during curdlan fermentation related to electron transfer chain (ETC), tricarboxylic acid (TCA) cycle, peptidoglycan/lipopolysaccharide biosynthesis, and uridine diphosphate (UDP)-glucose biosynthesis were determined by qRT-PCR. Experiments were performed at DO levels of 30%, 50%, and 75%, as well as under low-oxygen conditions. The effect of high cell density on transcriptional response of the above genes under low oxygen was also studied. Besides cytochrome d (cyd A), the transcription levels of all the other genes were increased at higher DO and reached maximum at 50% DO. Under 75% DO, the transcriptional levels of all the genes were repressed. In addition, transcription levels of icd, sdh, cyo A, and fix N genes did not exhibit significant fluctuation with high cell density culture under low oxygen. These results suggested a mechanism for DO regulation of curdlan synthesis through regulation of transcriptional levels of ETCs, TCA, and UDP-glucose synthesis genes during curdlan fermentation. To our knowledge, this is the first report that DO concentration apparently regulates curdlan biosynthesis in Agrobacterium sp. ATCC 31749 providing essential lead for the optimization of the fermentation at the industrial scale.
Keywords: Agrobacterium sp.; Curdlan productivity; Dissolve oxygen; TCA cycle; Aerobic and anaerobic metabolism; Transcriptomics
A method to generate recombinant Salmonella typhi Ty21a strains expressing multiple heterologous genes using an improved recombineering strategy by Bin Yu; Mei Yang; Ho Yin Bosco Wong; Rory M. Watt; Erwei Song; Bo-Jian Zheng; Kwok-Yung Yuen; Jian-Dong Huang (pp. 177-188).
Live attenuated Salmonella enterica serovar Typhi Ty21a (Ty21a) is an important vaccine strain used in clinical studies for typhoid fever and as a vaccine vector for the expression of heterologous antigens. To facilitate the use of Ty21a in such studies, it is desirable to develop improved strategies that enable the stable chromosomal integration and expression of multiple heterologous antigens. The phage λ Red homologous recombination system has previously been used in various gram-negative bacteria species to mediate the accurate replacement of regions of chromosomal DNA with PCR-generated ‘targeting cassettes’ that contain flanking regions of shared homologous DNA sequence. However, the efficiency of λ Red-mediated recombineering in Ty21a is far lower than in Escherichia coli and other Salmonella typhimurium strains. Here, we describe an improved strategy for recombineering-based methods in Ty21a. Our reliable and efficient method involves the use of linear DNA-targeting cassettes that contain relatively long flanking ‘arms’ of sequence (ca. 1,000 bp) homologous to the chromosomal target. This enables multiple gene-targeting procedures to be performed on a single Ty21a chromosome in a straightforward, sequential manner. Using this strategy, we inserted three different influenza antigen expression cassettes as well as a green fluorescent protein gene reporter into four different loci on the Ty21a chromosome, with high efficiency and accuracy. Fluorescent microscopy and Western blotting analysis confirmed that strong inducible expression of all four heterologous genes could be achieved. In summary, we have developed an efficient, robust, and versatile method that may be used to construct recombinant Ty21a antigen-expressing strains.
Keywords: Recombineering Salmonella vaccine
Comprehensive analysis of Salmonella sequence polymorphisms and development of a LDR-UA assay for the detection and characterization of selected serotypes by Andrea Lauri; Bianca Castiglioni; Paola Mariani (pp. 189-210).
Salmonella is a major cause of food-borne disease, and Salmonella enterica subspecies I includes the most clinically relevant serotypes. Salmonella serotype determination is important for the disease etiology assessment and contamination source tracking. This task will be facilitated by the disclosure of Salmonella serotype sequence polymorphisms, here annotated in seven genes (sefA, safA, safC, bigA, invA, fimA, and phsB) from 139 S. enterica strains, of which 109 belonging to 44 serotypes of subsp. I. One hundred nineteen polymorphic sites were scored and associated to single serotypes or to serotype groups belonging to S. enterica subsp. I. A diagnostic tool was constructed based on the Ligation Detection Reaction—Universal Array (LDR-UA) for the detection of polymorphic sites uniquely associated to serotypes of primary interest (Salmonella Hadar, Salmonella Infantis, Salmonella Enteritidis, Salmonella Typhimurium, Salmonella Gallinarum, Salmonella Virchow, and Salmonella Paratyphi B). The implementation of promiscuous probes allowed the diagnosis of ten further serotypes that could be associated to a unique hybridization pattern. Finally, the sensitivity and applicability of the tool was tested on target DNA dilutions and with controlled meat contamination, allowing the detection of one Salmonella CFU in 25 g of meat.
Keywords: Salmonella; Diagnostics; Food safety; Ligation detection reaction; Universal array
Biodegradation of sulfamethoxazole by individual and mixed bacteria by Simone Larcher; Viviane Yargeau (pp. 211-218).
Antibiotic compounds, like sulfamethoxazole (SMX), have become a concern in the aquatic environment due to the potential development of antibacterial resistances. Due to excretion and disposal, SMX has been frequently detected in wastewaters and surface waters. SMX removal in conventional wastewater treatment plants (WWTPs) ranges from 0% to 90%, and there are opposing results regarding its biodegradability at lab scale. The objective of this research was to determine the ability of pure cultures of individual and mixed consortia of bacteria (Bacillus subtilis, Pseudomonas aeruginosa, Pseudomonas putida, Rhodococcus equi, Rhodococcus erythropolis, Rhodococcus rhodocrous, and Rhodococcus zopfii) known to exist in WWTP activated sludge to remove SMX. Results showed that R. equi alone had the greatest ability to remove SMX leading to 29% removal (with glucose) and the formation of a metabolite. Degradation pathways and metabolite structures have been proposed based on the potential enzymes produced by R. equi. When R. equi was mixed with other microorganisms, a positive synergistic effect was not observed and the maximum SMX removal achieved was 5%. This indicates that pure culture results cannot be extrapolated to mixed culture conditions, and the methodology developed here to study the biodegradability of compounds under controlled mixed culture conditions offers an alternative to conventional studies using pure bacterial cultures or inocula from activated sludge sources consisting of unknown and variable microbial populations.
Keywords: Sulfamethoxazole (SMX); Antibiotics; Biodegradation; R. equi ; Mixed cultures