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Applied Microbiology and Biotechnology (v.97, #9)
The roots—a short history of industrial microbiology and biotechnology by Klaus Buchholz; John Collins (pp. 3747-3762).
Early biotechnology (BT) had its roots in fascinating discoveries, such as yeast as living matter being responsible for the fermentation of beer and wine. Serious controversies arose between vitalists and chemists, resulting in the reversal of theories and paradigms, but prompting continuing research and progress. Pasteur’s work led to the establishment of the science of microbiology by developing pure monoculture in sterile medium, and together with the work of Robert Koch to the recognition that a single pathogenic organism is the causative agent for a particular disease. Pasteur also achieved innovations for industrial processes of high economic relevance, including beer, wine and alcohol. Several decades later Buchner, disproved the hypothesis that processes in living cells required a metaphysical ‘vis vitalis’ in addition to pure chemical laws. Enzymes were shown to be the chemical basis of bioconversions. Studies on the formation of products in microbial fermentations, resulted in the manufacture of citric acid, and chemical components required for explosives particularly in war time, acetone and butanol, and further products through fermentation. The requirements for penicillin during the Second World War lead to the industrial manufacture of penicillin, and to the era of antibiotics with further antibiotics, like streptomycin, becoming available. This was followed by a new class of high value-added products, mainly secondary metabolites, e.g. steroids obtained by biotransformation. By the mid-twentieth century, biotechnology was becoming an accepted specialty with courses being established in the life sciences departments of several universities. Starting in the 1970s and 1980s, BT gained the attention of governmental agencies in Germany, the UK, Japan, the USA, and others as a field of innovative potential and economic growth, leading to expansion of the field. Basic research in Biochemistry and Molecular Biology dramatically widened the field of life sciences and at the same time unified them considerably by the study of genes and their relatedness throughout the evolutionary process. The scope of accessible products and services expanded significantly. Economic input accelerated research and development, by encouraging and financing the development of new methods, tools, machines and the foundation of new companies. The discipline of ‘New Biotechnology’ became one of the lead sciences. Although biotechnology has historical roots, it continues to influence diverse industrial fields of activity, including food, feed and other commodities, for example polymer manufacture, biofuels and energy production, providing services such as environmental protection, and the development and production of many of the most effective drugs. The understanding of biology down to the molecular level opens the way to create novel products and efficient environmentally acceptable methods for their production.
Keywords: Biotechnology; History; Fermentation theories; Industrial microbiology; Genetic techniques; Biotech companies
Lysine biosynthesis in microbes: relevance as drug target and prospects for β-lactam antibiotics production by Felicitas Fazius; Christoph Zaehle; Matthias Brock (pp. 3763-3772).
Plants as well as pro- and eukaryotic microorganisms are able to synthesise lysine via de novo synthesis. While plants and bacteria, with some exceptions, rely on variations of the meso-diaminopimelate pathway for lysine biosynthesis, fungi exclusively use the α-aminoadipate pathway. Although bacteria and fungi are, in principle, both suitable as lysine producers, current industrial fermentations rely on the use of bacteria. In contrast, fungi are important producers of β-lactam antibiotics such as penicillins or cephalosporins. The synthesis of these antibiotics strictly depends on α-aminoadipate deriving from lysine biosynthesis. Interestingly, despite the resulting industrial importance of the fungal α-aminoadipate pathway, biochemical reactions leading to α-aminoadipate formation have only been studied on a limited number of fungal species. In this respect, just recently an essential isomerisation reaction required for the formation of α-aminoadipate has been elucidated in detail. This review summarises biochemical pathways leading to lysine production, discusses the suitability of interrupting lysine biosynthesis as target for new antibacterial and antifungal compounds and emphasises on biochemical reactions involved in the formation of α-aminoadipate in fungi as an essential intermediate for both, lysine and β-lactam antibiotics production.
Keywords: meso-diaminopimelate; α-aminioadipate; Peptidoglycan; Antibiotics; Aconitase; Homoaconitase
New insights on nucleoside 2′-deoxyribosyltransferases: a versatile Biocatalyst for one-pot one-step synthesis of nucleoside analogs by A. Fresco-Taboada; I. de la Mata; M. Arroyo; J. Fernández-Lucas (pp. 3773-3785).
In recent years, glycosiltransferases have arisen as standard biocatalysts for the enzymatic synthesis of a wide variety of natural and non-natural nucleosides. Such enzymatic synthesis of nucleoside analogs catalyzed by nucleoside phosphorylases and 2′-deoxyribosyltransferases (NDTs) has demonstrated to be an efficient alternative to the traditional multistep chemical methods, since chemical glycosylation reactions include several protection–deprotection steps. This minireview exhaustively covers literature reports on this topic with the final aim of presenting NDTs as an efficient option to nucleoside phosphorylases for the synthesis of natural and non-natural nucleosides. Detailed comments about structure and catalytic mechanism of described NDTs, as well as their possible biological role, substrate specificity, and advances in detection of new enzyme specificities towards different non-natural nucleoside synthesis are included. In addition, optimization of enzymatic transglycosylation reactions and their application in the synthesis of natural and non-natural nucleosides have been described. Finally, immobilization of NDTs is shown as a practical procedure which leads to the preparation of very interesting biocatalysts applicable to industrial nucleoside synthesis.
Keywords: 2′-Deoxyribosyltransferases; Nucleoside synthesis; Immobilization; Biocatalysis
Hosting the plant cells in vitro: recent trends in bioreactors by Milen I. Georgiev; Regine Eibl; Jian-Jiang Zhong (pp. 3787-3800).
Biotechnological production of high-value metabolites and therapeutic proteins by plant in vitro systems has been considered as an attractive alternative of classical technologies. Numerous proof-of-concept studies have illustrated the feasibility of scaling up plant in vitro system-based processes while keeping their biosynthetic potential. Moreover, several commercial processes have been established so far. Though the progress on the field is still limited, in the recent years several bioreactor configurations has been developed (e.g., so-called single-use bioreactors) and successfully adapted for growing plant cells in vitro. This review highlights recent progress and limitations in the bioreactors for plant cells and outlines future perspectives for wider industrialization of plant in vitro systems as “green cell factories” for sustainable production of value-added molecules.
Keywords: Bioreactor design; Differentiated plant in vitro systems; Culture mode; Plant cell culture; Signal transduction engineering; Single-use bioreactors
Development of biological soil disinfestations in Japan by Noriaki Momma; Yuso Kobara; Seiji Uematsu; Nobuhiro Kita; Akinori Shinmura (pp. 3801-3809).
Biological soil disinfestations (BSDs) were developed separately in Japan and in The Netherlands as an alternative to chemical fumigations. In Japan, it was developed based on the knowledge of irrigated paddy rice and upland crop rotation system that was rather tolerant of soil-borne disease development. The methods consist of application of easily decomposable organic matter, irrigation, and covering the soil surface with plastic film, thereby inducing anaerobic (reductive) soil conditions and suppressing many soil-borne pests including fungi, bacteria, nematodes, and weeds. The methods are widely used by organic farmers in the area where residences and agricultural fields are intermingled. To note one advantage of these methods, maintenance of soil suppressiveness to Fusarium wilt of tomato was suggested, while soil treated with chloropicrin became conducive to the disease. Suppression of soil-borne fungal pathogens by BSDs might be attributed to anaerobicity and high temperature, organic acids generated, and metal ions released into soil water. Contributions of respective factors to suppression of respective pathogens might be diverse. Presumably, these factors might vary on the fungal community structure in BSD-treated soil. These factors also work in paddy fields. Therefore, the BSDs developed in Japan are probably a method to raise the efficacy of paddy–upland rotation through intensive organic matter application and through maintenance of a strongly anaerobic (reductive) soil condition.
Keywords: Biological soil disinfestation; Anaerobic soil disinfestation; Fusarium wilt; Ferrous ion; Organic acids
Optimisation of signal peptide for recombinant protein secretion in bacterial hosts by Kheng Oon Low; Nor Muhammad Mahadi; Rosli Md. Illias (pp. 3811-3826).
Escherichia coli—the powerhouse for recombinant protein production—is rapidly gaining status as a reliable and efficient host for secretory expression. An improved understanding of protein translocation processes and its mechanisms has inspired and accelerated the development of new tools and applications in this field and, in particular, a more efficient secretion signal. Several important characteristics and requirements are summarised for the design of a more efficient signal peptide for the production of recombinant proteins in E. coli. General approaches and strategies to optimise the signal peptide, including the selection and modification of the signal peptide components, are included. Several challenges in the secretory production of recombinant proteins are discussed, and research approaches designed to meet these challenges are proposed.
Keywords: Signal peptide; Recombinant protein; Mutation; Secretory production; Sec system; Escherichia coli
Bacterial metabolism of environmental arsenic—mechanisms and biotechnological applications by Martin C. Kruger; Philippe N. Bertin; Hermann J. Heipieper; Florence Arsène-Ploetze (pp. 3827-3841).
Arsenic causes threats for environmental and human health in numerous places around the world mainly due to its carcinogenic potential at low doses. Removing arsenic from contaminated sites is hampered by the occurrence of several oxidation states with different physicochemical properties. The actual state of arsenic strongly depends on its environment whereby microorganisms play important roles in its geochemical cycle. Due to its toxicity, nearly all organisms possess metabolic mechanisms to resist its hazardous effects, mainly by active extrusion, but also by extracellular precipitation, chelation, and intracellular sequestration. Some microbes are even able to actively use various arsenic compounds in their metabolism, either as an electron donor or as a terminal electron acceptor for anaerobic respiration. Some microorganisms can also methylate inorganic arsenic, probably as a resistance mechanism, or demethylate organic arsenicals. Bioavailability of arsenic in water and sediments is strongly influenced by such microbial activities. Therefore, understanding microbial reactions to arsenic is of importance for the development of technologies for improved bioremediation of arsenic-contaminated waters and environments. This review gives an overview of the current knowledge on bacterial interactions with arsenic and on biotechnologies for its detoxification and removal.
Keywords: Arsenic tolerance; Genomics; Bioreporter; Bioremediation
Selection method of pH conditions to establish Pseudomonas taetrolens physiological states and lactobionic acid production by Saúl Alonso; Manuel Rendueles; Mario Díaz (pp. 3843-3854).
Microbial physiological responses resulting from inappropriate bioprocessing conditions may have a marked impact on process performance within any fermentation system. The influence of different pH-control strategies on physiological status, microbial growth and lactobionic acid production from whey by Pseudomonas taetrolens during bioreactor cultivations has been investigated for the first time in this work. Both cellular behaviour and bioconversion efficiency from P. taetrolens were found to be negatively influenced by pH-control modes carried out at values lower than 6.0 and higher than 7.0. Production schemes were also influenced by the operational pH employed, with asynchronous production from damaged and metabolically active subpopulations at pH values lower than 6.0. Moreover, P. taetrolens showed reduced cellular proliferation and a subsequent delay in the onset of the production phase under acidic conditions (pH < 6.0). Unlike cultivations performed at 6.5, both pH-shift and pH-stat cultivation strategies performed at pH values lower than 6.0 resulted in decreased lactobionic acid production. Whereas the cellular response showed a stress-induced physiological response under acidic conditions, healthy functional cells were predominant at medium operational pH values (6.5–7.0). P. taetrolens thus displayed a robust physiological status at initial pH value of 6.5, resulting in an enhanced bioconversion yield and lactobionic acid productivity (7- and 4-fold higher compared to those attained at initial pH values of 4.5 and 5.0, respectively). These results have shown that pH-control modes strongly affected both the physiological response of cells and the biological performance of P. taetrolens, providing key information for bio-production of lactobionic acid on an industrial scale.
Keywords: Flow cytometry; pH-control strategy; Lactobionic acid; Bioprocessing conditions; Pseudomonas taetrolens ; Physiological status
Production and characterization of a CD25-specific scFv-Fc antibody secreted from Pichia pastoris by Lin Wan; Shengyun Zhu; Jian Zhu; Hao Yang; Shengfu Li; Youping Li; Jingqiu Cheng; Xiaofeng Lu (pp. 3855-3863).
Antibodies against CD25 would be novel tools for the diagnosis and treatment of adult T cell leukemia lymphoma (ATLL) and many other immune disorders. In our previous work, we successfully produced the single-chain fragment of a variable antibody against CD25, the Dmab(scFv) antibody, using Pichia pastoris. Here, we describe a novel form of an antibody against CD25, the Dmab(scFv)-Fc antibody, also produced by P. pastoris. To construct the Dmab(scFv)-Fc antibody, the Dmab(scFv) antibody was genetically fused to the Fc fragment of a human IgG1 antibody. A fusion gene encoding Dmab(scFv)-Fc antibody was cloned into the pPIC9K plasmid and expressed at high levels, 60–70 mg/l, by P. pastoris under optimized conditions. The Dmab(scFv)-Fc antibody was similar to the Dmab(scFv) antibody in its binding specificity but different in its molecular form and Fc-mediated effector functions. The Dmab(scFv)-Fc antibody and the Dmab(scFv) antibody both bound to CD25-positive MJ cells but not to CD25-negative K562 cells. The Dmab(scFv)-Fc antibody existed as a dimer whereas the Dmab(scFv) antibody was a monomer because it lacks the Fc fragment. The Dmab(scFv)-Fc antibody enhanced the antibody-dependent cellular cytotoxicity of CD25-positive cancer cells, whereas the Dmab(scFv) antibody was inactive in the antibody-dependent cellular cytotoxicity assays. In addition, compared to the Dmab(scFv) antibody, the Dmab(scFv)-Fc antibody showed stronger immunosuppressive activity in the Con A-stimulated lymphocyte proliferation system and in the mixed lymphocyte reaction system. These results demonstrate that the Dmab(scFv)-Fc antibody produced in P. pastoris is functional, and therefore it might be developed as a novel diagnostic and therapeutic tool for ATLL and other immune disorders.
Keywords: Immunotherapy; Single-chain variable fragment; Antibody engineering; CD25; P. pastoris
A chemo-enzymatic route to synthesize (S)-γ-valerolactone from levulinic acid by Katharina Götz; Andreas Liese; Marion Ansorge-Schumacher; Lutz Hilterhaus (pp. 3865-3873).
Levulinic acid is a feasible platform chemical derived from acid-catalyzed hydrolysis of lignocellulose. The conversion of this substrate to (S)-γ-valerolactone ((S)-GVL) was investigated in a chemo-enzymatic reaction sequence that benefits from mild reaction conditions and excellent enantiomeric excess of the desired (S)-GVL. For that purpose, levulinic acid was chemically esterified over the ion exchange resin Amberlyst 15 to yield ethyl levulinate (LaOEt). The keto ester was successfully reduced by (S)-specific carbonyl reductase from Candida parapsilosis (CPCR2) in a substrate-coupled cofactor regeneration system utilizing isopropanol as cosubstrate. In classical batch experiments, a maximum conversion of 95 % was achieved using a 20-fold excess of isopropanol. Continuous reduction of LaOEt was carried out for 24 h, and a productivity of more than 5 mg (S)-ethyl-4-hydroxypentanoate (4HPOEt) per μg CPCR2 was achieved. Afterwards (S)-4HPOEt (>99%ee) was substituted to lipase-catalyzed lactonization using immobilized lipase B from Candida antarctica to yield (S)-GVL in 90 % overall yield and >99%ee.
Keywords: Technical levulinic acid; Chemo-enzymatic reaction sequence; Asymmetric reduction; CPCR2; Enantioselective
α-Synuclein and β-synuclein enhance secretion protein production in baculovirus expression vector system by Chao-Yi Teng; Shou-Lin Chang; Meng-Feng Tsai; Tzong-Yuan Wu (pp. 3875-3884).
The baculovirus expression vector system (BEVS) is widely used as a tool for expressing of recombinant proteins in insect cells or larvae. However, the expression level of secretion pathway proteins is often lower than that of cytosolic and nucleus proteins. Thus, we attempted to improve production of secreted proteins by using a secretory alkaline phosphatase-EGFP fusion protein (SEFP)-based bi-cistronic baculovirus vector to identify chaperones that have potential on boosting secreted protein production. As co-expressed SEFP with a chaperone, calreticulin (CALR), it was found that the secreted SEFP enzyme activity can be boosted up to twofold. This result demonstrated the SEFP-based bi-cistronic approach can be used to identify the genes that can enhance secretion protein production in BEVS. Thus, the chaperone activity of α-synuclein (α-syn) and β-synuclein (β-syn) was evaluated in cells co-expressed with SEFP and compared that with CALR by analyzing localization, alkaline phosphatase enzyme activity, and mRNA expression levels of SEFP. Our results showed that SEFP enzyme activity from cells co-expressed with both synuclein proteins can be enhanced up to 2.3-fold and this increment was better than that caused by CALR. Moreover, this enhancement might arise from the transcription enhancement or higher RNA stability. By this novel approach, we provided evidences that α- and β-syn can enhance secretion proteins production in BEVS.
Keywords: Baculovirus; Calreticulin; α-Synuclein; β-Synuclein; Secreted proteins
Three antimycobacterial metabolites identified from a marine-derived Streptomyces sp. MS100061 by Caixia Chen; Jian Wang; Hui Guo; Weiyuan Hou; Na Yang; Biao Ren; Mei Liu; Huanqin Dai; Xueting Liu; Fuhang Song; Lixin Zhang (pp. 3885-3892).
In the course of a screening program for bioactive compounds from a marine natural product library, a newly isolated Actinomycetes strain, designated as MS100061, exhibited strong anti-Mycobacterium bovis Bacillus Calmette–Guérin (BCG) activity. The strain belongs to the genus Streptomyces according to its morphological and 16S rDNA phylogenetic analysis. Bioassay-guided isolation resulted in a new spirotetronate, lobophorin G (1), together with two known compounds, lobophorins A (2) and B (3). The structures were elucidated by extensive spectroscopic methods and comparison with literatures. Compounds 1–3 were subjected to anti-BCG, antituberculosis, and antibacterial screening and exhibited potent anti-BCG activity with minimum inhibitory concentration (MIC) values of 1.56, 1.56, and 0.78 μg/ml, respectively, and moderate anti-Mycobacterium tuberculosis H37Rv activity with MIC values of 32, 32, and 16 μg/ml, respectively. The MIC values of compounds 1–3 against Bacillus subtilis were 3.125, 12.5, and 1.56 μg/ml, respectively, indicating great potential for antibacterial drugs. In addition, this is the first report of the anti-BCG and antituberculosis activities of lobophorins.
Keywords: Marine Streptomyces ; Lobophorins; Anti-BCG; Antituberculosis
High cell density cultivation of a recombinant E. coli strain expressing a key enzyme in bioengineered heparin production by Odile Francesca Restaino; Ujjwal Bhaskar; Priscilla Paul; Lingyun Li; Mario De Rosa; Jonathan S. Dordick; Robert J. Linhardt (pp. 3893-3900).
A bioengineered heparin, as a replacement for animal-derived heparin, is under development that relies on the fermentative production of heparosan by Escherichia coli K5 and its subsequent chemoenzymatic modification using biosynthetic enzymes. A critical enzyme in this pathway is the mammalian 6-O-sulfotransferase (6-OST-1) which specifically sulfonates the glucosamine residue in a heparin precursor. This mammalian enzyme, previously cloned and expressed in E. coli, is required in kilogram amounts if an industrial process for bioengineered heparin is to be established. In this study, high cell density cultivation techniques were exploited to obtain recombinant 6-OST-1. Physiological studies were performed in shake flasks to establish optimized growth and production conditions. Induction strategies were tested in fed-batch experiments to improve yield and productivity. High cell density cultivation in 7-l culture, together with a coupled inducer strategy using isopropyl β-d-1-thiogalactopyranoside and galactose, afforded 482 mg l−1 of enzyme with a biomass yield of 16.2 mg gcdw −1 and a productivity of 10.5 mg l−1 h−1.
Keywords: Bioengineered heparin; High cell density cultivations; Heparosan; Sulfotransferase
Reduced by-product formation and modified oxygen availability improve itaconic acid production in Aspergillus niger by An Li; Nina Pfelzer; Robbert Zuijderwijk; Anja Brickwedde; Cora van Zeijl; Peter Punt (pp. 3901-3911).
Aspergillus niger has an extraordinary potential to produce organic acids as proven by its application in industrial citric acid production. Previously, it was shown that expression of the cis-aconitate decarboxylase gene (cadA) from Aspergillus terreus converted A. niger into an itaconic acid producer (Li et al., Fungal Genet Bio 48: 602–611, 2011). After some initial steps in production optimization in the previous research (Li et al., BMC biotechnol 12: 57, 2012), this research aims at modifying host strains and fermentation conditions to further improve itaconic acid production. Expression of two previously identified A. terreus genes encoding putative organic acid transporters (mttA, mfsA) increased itaconic acid production in an A. niger cis-aconitate decarboxylase expressing strain. Surprisingly, the production did not increase further when both transporters were expressed together. Meanwhile, oxalic acid was accumulated as a by-product in the culture of mfsA transformants. In order to further increase itaconic acid production and eliminate by-product formation, the non-acidifying strain D15#26 and the oxaloacetate acetylhydrolase (oahA) deletion strain AB 1.13 ∆oahA #76 have been analyzed for itaconic acid production. Whereas cadA expression in AB 1.13 ∆oahA #76 resulted in higher itaconic acid production than strain CAD 10.1, this was not the case in strain D15#26. As expected, oxalic acid production was eliminated in both strains. In a further attempt to increase itaconic acid levels, an improved basal citric acid-producing strain, N201, was used for cadA expression. A selected transformant (N201CAD) produced more itaconic acid than strain CAD 10.1, derived from A. niger strain AB1.13. Subsequently, we have focused on the influence of dissolved oxygen (D.O.) on itaconic acid production. Interestingly, reduced D.O. levels (10–25 %) increased itaconic acid production using strain N201 CAD. Similar results were obtained in strain AB 1.13 CAD + HBD2.5 (HBD 2.5) which overexpressed a fungal hemoglobin domain. Our results showed that overexpression of the hemoglobin domain increased itaconic acid production in A. niger at lower D.O. levels. Evidently, the lower levels of D.O. have a positive influence on itaconic acid production in A. niger strains.
Keywords: Aspergillus niger ; Itaconic acid; Transporters; By-product; Dissolved oxygen (D.O.)
Construction and characterization of a recombinant human beta defensin 2 fusion protein targeting the epidermal growth factor receptor: in vitro study by Minjing Zhang; Zhuangwei Qiu; Yinyu Li; Yan Yang; Qihao Zhang; Qi Xiang; Zhijian Su; Yadong Huang (pp. 3913-3923).
The HER2/neu proto-oncogene encodes a 185-kDa trans-membrane glycoprotein kinase with extensive homology to the epidermal growth factor receptor and plays a key role in the transformation and growth of malignant tumors. To date, two antibody drugs targeting HER2/neu have been developed successfully. In order to reduce the cost and the time of clinical treatment, we produced a fusion protein composed of human beta defensin 2 (hBD2) and anti-HER2/neu single-chain variable fragment (scFv 4D5), which is capable of specifically targeting, significantly inhibiting, and promptly killing HER2/neu-positive cancer cells. The recombinant protein was expressed in Escherichia coli using the small ubiquitin-related modifier (SUMO) as the molecular chaperone, and the optimal expression level reached to 40.2 % of the total supernatant protein. After purifying by Ni-NTA affinity chromatography, the fusion protein was cleaved with a SUMO-specific protease to obtain hBD2–4D5, which was further purified by Ni-NTA affinity chromatography. The purity of hBD2–4D5 was higher than 95 %, and the yield was 19 ± 2 mg/L in flask fermentation. The cell number count and flow cytometry results showed that hBD2–4D5 exerted cytotoxic and anti-proliferative effects on HER2/neu-positive breast cancer cell line, SKBR-3. The results of scanning electron microscope and transmission electron microscope observation indicated that hBD2–4D5 could induce intracellular ultrastructure changes and cell necrosis by disrupting the cell membrane. Immunofluorescence analysis showed that hBD2–4D5 could bind to SKBR-3 cells and further be internalized into the cytoplasm. Moreover, hBD2–4D5 could also mediate apoptosis of SKBR-3 cells by up-regulating the ratio of Bax to Bcl-2.
Keywords: HER2/neu; hBD2; Single-chain variable fragment; Fusion protein; Cancer cell targeting; Cytotoxicity
Characterization of a family 5 glycoside hydrolase isolated from the outer membrane of cellulolytic Cytophaga hutchinsonii by Yongtao Zhu; Hong Zhou; Yanlin Bi; Weixin Zhang; Guanjun Chen; Weifeng Liu (pp. 3925-3937).
Cytophaga hutchinsonii is an abundant aerobic cellulolytic bacterium that rapidly digests crystalline cellulose in a contact-dependent manner. The different roles of various predicted glycoside hydrolases and the detailed mechanism used by C. hutchinsonii in cellulose digestion are, however, not known. In this study, an endoglucanase belonging to glycoside hydrolase family 5 (GH5) named as ChCel5A was isolated from the outer membrane of C. hutchinsonii. The catalytic domain of ChCel5A exhibited typical endoglucanase activity and was capable of hydrolyzing insoluble cellulose with cellobiose and cellotriose as the predominant digestion products. Site-directed mutagenesis identified two aromatic amino acids in ChCle5A, W61 and W308, that dramatically decreased its hydrolytic activity toward filter paper while causing only a slight decrease in carboxymethylcellulase (CMCase) activity. Disruption of chu_1107 encoding ChCel5A caused no drastic effect on the growth parameters on cellulose for the resulting mutant strain with negligible reduction in the specific CMCase activities for intact cells. The demonstration of targeted gene inactivation capability for C. hutchinsonii has provided an opportunity to improve understanding of the details of the mechanism underlying its efficient utilization of cellulose.
Keywords: Cytophaga hutchinsonii ; Cellulase; Gene inactivation; Mutagenesis
Modulating heterologous protein production in yeast: the applicability of truncated auxotrophic markers by Ali Kazemi Seresht; Per Nørgaard; Eva Akke Palmqvist; Asser Sloth Andersen; Lisbeth Olsson (pp. 3939-3948).
The use of auxotrophic Saccharomyces cerevisiae strains for improved production of a heterologous protein was examined. Two different marker genes were investigated, encoding key enzymes in the metabolic pathways for amino acid (LEU2) and pyrimidine (URA3) biosynthesis, respectively. Expression plasmids, carrying the partly defective selection markers LEU2d and URA3d, were constructed. Two CEN.PK-derived strains were chosen and insulin analogue precursor was selected as a model protein. Different truncations of the LEU2 and URA3 promoters were used as the mean to titrate the plasmid copy number and thus the recombinant gene dosage in order to improve insulin productivity. Experiments were initially carried out in batch mode to examine the stability of yeast transformants and to select high yielding mutants. Next, chemostat cultivations were run at high cell density to address industrial applicability and long-term expression stability of the transformants. We found that the choice of auxotrophic marker is crucial for developing a yeast expression system with stable heterologous protein production. The incremental truncation of the URA3 promoter led to higher plasmid copy numbers and IAP yields, whereas the truncation of the LEU2 promoter caused low plasmid stability. We show that the modification of the level of the recombinant gene dosage by varying the degree of promoter truncation can be a strong tool for optimization of productivity. The application of the URA3d-based expression systems showed a high potential for industrial protein production and for further academic studies.
Keywords: Promoter truncation; URA3d ; LEU2d ; Human insulin; Plasmid copy number; High cell density cultivation
Biochemical and structural characterization of recombinant short-chain NAD(H)-dependent dehydrogenase/reductase from Sulfolobus acidocaldarius highly enantioselective on diaryl diketone benzil by Angela Pennacchio; Vincenzo Sannino; Giosuè Sorrentino; Mosè Rossi; Carlo A. Raia; Luciana Esposito (pp. 3949-3964).
The gene encoding a novel alcohol dehydrogenase that belongs to the short-chain dehydrogenases/reductases superfamily was identified in the aerobic thermoacidophilic crenarchaeon Sulfolobus acidocaldarius strain DSM 639. The saadh2 gene was heterologously overexpressed in Escherichia coli, and the resulting protein (SaADH2) was purified to homogeneity and both biochemically and structurally characterized. The crystal structure of the SaADH2 NADH-bound form reveals that the enzyme is a tetramer consisting of identical 27,024-Da subunits, each composed of 255 amino acids. The enzyme has remarkable thermophilicity and thermal stability, displaying activity at temperatures up to 80 °C and a 30-min half-inactivation temperature of ∼88 °C. It also shows good tolerance to common organic solvents and a strict requirement for NAD(H) as the coenzyme. SaADH2 displays a preference for the reduction of alicyclic, bicyclic and aromatic ketones and α-ketoesters, but is poorly active on aliphatic, cyclic and aromatic alcohols, showing no activity on aldehydes. Interestingly, the enzyme catalyses the asymmetric reduction of benzil to (R)-benzoin with both excellent conversion (98 %) and optical purity (98 %) by way of an efficient in situ NADH-recycling system involving a second thermophilic ADH. The crystal structure of the binary complex SaADH2–NADH, determined at 1.75 Å resolution, reveals details of the active site providing hints on the structural basis of the enzyme enantioselectivity.
Keywords: Archaea; Sulfolobus acidocaldarius ; Short-chain dehydrogenases/reductases; Crystal structure; Bioreduction; Benzil
Functional and structural studies of a novel cold-adapted esterase from an Arctic intertidal metagenomic library by Juan Fu; Hanna-Kirsti S. Leiros; Donatella de Pascale; Kenneth A. Johnson; Hans-Matti Blencke; Bjarne Landfald (pp. 3965-3978).
A novel cold-adapted lipolytic enzyme gene, est97, was identified from a high Arctic intertidal zone sediment metagenomic library. The deduced amino acid sequence of Est97 showed low similarity with other lipolytic enzymes, the maximum being 30 % identity with a putative lipase from Vibrio caribbenthicus. Common features of lipolytic enzymes, such as the GXSXG sequence motif, were detected. The gene product was over-expressed in Escherichia coli and purified. The recombinant Est97 (rEst97) hydrolysed various ρ-nitrophenyl esters with the best substrate being ρ-nitrophenyl hexanoate (K m and k cat of 39 μM and 25.8 s−1, respectively). This esterase activity of rEst97 was optimal at 35 °C and pH 7.5 and the enzyme was unstable at temperatures above 25 °C. The apparent melting temperature, as determined by differential scanning calorimetry was 39 °C, substantiating Est97 as a cold-adapted esterase. The crystal structure of rEst97 was determined by the single wavelength anomalous dispersion method to 1.6 Å resolution. The protein was found to have a typical α/β-hydrolase fold with Ser144-His226-Asp197 as the catalytic triad. A suggested, relatively short lid domain of rEst97 is composed of residues 80–114, which form an α-helix and a disordered loop. The cold adaptation features seem primarily related to a high number of methionine and glycine residues and flexible loops in the high-resolution structures.
Keywords: Esterase; Cold adapted; Metagenomic; Crystal structure; Thermolabile
Improving the affinity and activity of CYP101D2 for hydrophobic substrates by Stephen G. Bell; Wen Yang; Alison Dale; Weihong Zhou; Luet-Lok Wong (pp. 3979-3990).
CYP101D2 is a cytochrome P450 monooxygenase from Novosphingobium aromaticivorans which is closely related to CYP101A1 (P450cam) from Pseudomonas putida. Both enzymes selectively hydroxylate camphor to 5-exo-hydroxycamphor, and the residues that line the active sites of both enzymes are similar including the pre-eminent Tyr96 residue. However, Met98 and Leu253 in CYP101D2 replace Phe98 and Val247 in CYP101A1, and camphor binding only results in a maximal change in the spin state to 40 % high-spin. Substitutions at Tyr96, Met98 and Leu253 in CYP101D2 reduced both the spin state shift on camphor binding and the camphor oxidation activity. The Tyr96Ala mutant increased the affinity of CYP101D2 for hydrocarbon substrates including adamantane, cyclooctane, hexane and 2-methylpentane. The monooxygenase activity of the Tyr96Ala variant towards alkane substrates was also enhanced compared with the wild-type enzyme. The crystal structure of the substrate-free form of this variant shows the enzyme in an open conformation (PDB: 4DXY), similar to that observed with the wild-type enzyme (PDB: 3NV5), with the side chain of Ala96 pointing away from the heme. Despite this, the binding and activity data suggest that this residue plays an important role in substrate binding, evidencing that the enzyme probably undergoes catalysis in a more closed conformation, similar to those observed in the crystal structures of CYP101A1 (PDB: 2CPP) and CYP101D1 (PDB: 3LXI).
Keywords: Cytochrome P450 monooxygenase; Biocatalysis; Novosphingobium aromaticivorans ; C–H bond activation; Protein engineering
Design, expression, and characterization of a novel targeted plectasin against methicillin-resistant Staphylococcus aureus by Ruoyu Mao; Da Teng; Xiumin Wang; Di Xi; Yong Zhang; Xiaoyuan Hu; Yalin Yang; Jianhua Wang (pp. 3991-4002).
A novel specifically targeted antimicrobial peptide (STAMP) that was especially effective against methicillin-resistant Staphylococcus aureus (MRSA) was designed by fusing the AgrD1 pheromone to the N-terminal end of plectasin. This STAMP was named Agplectasin, and its gene was synthesized and expressed in Pichia pastoris X-33 via pPICZαA. The highest amount of total secreted protein reached 1,285.5 mg/l at 108 h during the 120-h induction. The recombinant Agplectasin (rAgP) was purified by cation exchange chromatography and hydrophobic exchange chromatography; its yield reached 150 mg/l with 94 % purity. The rAgP exhibited strong bactericidal activity against S. aureus but not Staphylococcus epidermidis or other types of tested bacteria. A bactericidal kinetics assay showed that the rAgP killed over 99.9 % of tested S. aureus (ATCC 25923 and ATCC 43300) in both Mueller–Hinton medium and human blood within 10 h when treated with 4× minimal inhibitory concentration. The rAgP caused only approximately 1 % hemolysis of human blood cells, even when the concentration reached 512 μg/ml, making it potentially feasible as a clinical injection agent. In addition, it maintained a high activity over a wide range of pH values (2.0–10.0) and demonstrated a high thermal stability at 100 °C for 1 h. These results suggested that this STAMP has the potential to eliminate MRSA strains without disrupting the normal flora.
Keywords: Agplectasin; STAMP; Plectasin; MRSA; Pichia pastoris
Mutant firefly luciferases with improved specific activity and dATP discrimination constructed by yeast cell surface engineering by Tatsuya Fushimi; Natsuko Miura; Hideya Shintani; Hiroyuki Tsunoda; Kouichi Kuroda; Mitsuyoshi Ueda (pp. 4003-4011).
Pyrosequencing system utilizing luciferase is one of the next-generation DNA sequencing systems. However, there is a crucial problem with the current pyrosequencing system: luciferase cannot discriminate between ATP and dATP completely, and dATPαS must be used as the dATP analogue. dATPαS is expensive and has low activity for the enzyme. If luciferase can clearly recognize the difference between ATP and dATP, dATP could be used instead of the expensive dATPαS in the pyrosequencing system. We attempted to prepare a novel luciferase with improved specific activity and dATP discrimination with the molecular display method. First, we selected two amino acid residues, Ser440 and Ser456, as target residues for mutation from the whole sequence of Photinus pyralis luciferase; we comprehensively mutated these two amino acids. A mutant luciferase library was constructed using yeast cell surface engineering. Through three step-wide screenings with individual conditions, we easily and speedily isolated three candidate mutants from 1,152 candidates and analyzed the properties of these mutants. Consequently, we succeeded in obtaining interesting mutant luciferases with improved specific activity and dATP discrimination more conveniently than with other methods.
Keywords: Firefly luciferase; Molecular display; Yeast cell surface engineering; Specific activity; dATP discrimination; Protein library
Effect of sterol composition on the activity of the yeast G-protein-coupled receptor Ste2 by Sanae Morioka; Tomohiro Shigemori; Keisuke Hara; Hironobu Morisaka; Kouichi Kuroda; Mitsuyoshi Ueda (pp. 4013-4020).
The main sterol of the human cell membrane is cholesterol, whereas in yeast it is ergosterol. In this study, we constructed a cholesterol-producing yeast strain by disrupting the genes related to ergosterol synthesis and inserting the genes related to cholesterol synthesis. The total sterols of the mutant yeast were extracted and the sterol composition was analyzed by GC-MS. We confirmed that cholesterol was produced instead of ergosterol in yeast and subsequently examined the activity of the yeast G-protein-coupled receptor (GPCR) Ste2p. Ste2p signaling was assessed in wild type (WT) with ergosterol and the cholesterol-producing yeast instead of ergosterol to determine whether sterol composition affects the activity of the yeast GPCR. Our results demonstrated that Ste2p could transduce a signal even in the cholesterol-rich membrane, but the maximum signal intensity was weaker than that transduced in the ergosterol-rich original (WT) membrane. This result indicates that sterol composition affects the activity of yeast GPCRs, and thus, this provides new insight into GPCR-mediated transduction using yeast for future fundamental and applied studies on GPCRs from yeast to other organisms.
Keywords: Sterol; Cholesterol; Ergosterol; Plasma membrane; GPCR; Ste2p
Development and validation of qualitative SYBR®Green Real-Time PCR for detection and discrimination of Listeria spp. and Listeria monocytogenes by Elodie Barbau-Piednoir; Nadine Botteldoorn; Marc Yde; Jacques Mahillon; Nancy H. Roosens (pp. 4021-4037).
A combination of four qualitative SYBR®Green qPCR screening assays targeting two levels of discrimination: Listeria genus (except Listeria grayi) and Listeria monocytogenes, is presented. These assays have been developed to be run simultaneously using the same polymerase chain reaction (PCR) programme. The paper also proposes a new validation procedure to specifically validate qPCR assays applied to food microbiology according to two guidelines: the ISO 22118 norm and the “Definition of minimum performance requirements for analytical methods of GMO testing”. The developed assays target the iap, prs and hlyA genes that belong to or neighbour the virulence cluster of Listeria spp. The selected primers were designed to amplify short fragments (60 to 103 bp) in order to obtain optimal PCR efficiency (between 97 and 107 % efficiency). The limit of detection of the SYBR®Green qPCR assays is two to five copies of target genes per qPCR reaction. These assays are highly accurate (98.08 and 100 % accuracy for the Listeria spp. and L. monocytogenes assays, respectively).
Keywords: Real-time PCR; SYBR®Green; Foodborne pathogens; Detection; Listeria ; qPCR validation
TG1 integrase-based system for site-specific gene integration into bacterial genomes by Tetsurou Muroi; Takaaki Kokuzawa; Yoshihiko Kihara; Ryuichi Kobayashi; Nobutaka Hirano; Hideo Takahashi; Mitsuru Haruki (pp. 4039-4048).
Serine-type phage integrases catalyze unidirectional site-specific recombination between the attachment sites, attP and attB, in the phage and host bacterial genomes, respectively; these integrases and DNA target sites function efficiently when transferred into heterologous cells. We previously developed an in vivo site-specific genomic integration system based on actinophage TG1 integrase that introduces ∼2-kbp DNA into an att site inserted into a heterologous Escherichia coli genome. Here, we analyzed the TG1 integrase-mediated integrations of att site-containing ∼10-kbp DNA into the corresponding att site pre-inserted into various genomic locations; moreover, we developed a system that introduces ∼10-kbp DNA into the genome with an efficiency of ∼104 transformants/μg DNA. Integrations of attB-containing DNA into an attP-containing genome were more efficient than integrations of attP-containing DNA into an attB-containing genome, and integrations targeting attP inserted near the replication origin, oriC, and the E. coli “centromere” analogue, migS, were more efficient than those targeting attP within other regions of the genome. Because the genomic region proximal to the oriC and migS sites is located at the extreme poles of the cell during chromosomal segregation, the oriC–migS region may be more exposed to the cytosol than are other regions of the E. coli chromosome. Thus, accessibility of pre-inserted attP to attB-containing incoming DNA may be crucial for the integration efficiency by serine-type integrases in heterologous cells. These results may be beneficial to the development of serine-type integrases-based genomic integration systems for various bacterial species.
Keywords: Serine-type phage integrase; Site-specific recombination; Microbial genome engineering
Exploration of BAC versus plasmid expression vectors in recombinant CHO cells by Alexander Mader; Bernhard Prewein; Katalin Zboray; Emilio Casanova; Renate Kunert (pp. 4049-4054).
Vector engineering approaches are commonly used to increase recombinant protein production in mammalian cells, and among various concepts, bacterial artificial chromosomes (BAC) have been proposed to serve as open chromatin regions to omit chromosome positional effects. For proof of concept, we developed stable recombinant Chinese hamster ovary (CHO) cell lines using different expression vector systems: the plasmid vectors contained the identical expression cassette as the BAC constructs. Two anti-HIV1 antibody derivates served as model proteins (3D6scFc and 2F5scFc) for generation of four stable recombinant CHO cell lines. The BAC-derived clones showed three to four times higher specific productivity, and therefore, gene copy numbers and transcript level were quantified. The active chromatin region provided with the BAC environment significantly improved transcription evidenced with both model proteins. Specific transcription was approximately six times higher from BAC-based vectors compared to the corresponding plasmid vectors for both single-chain fragment crystallizable (scFc) proteins. Our accurate investigations elucidated also differences between translational activities related to the protein of choice. 3D6scFc expressed specifically three to four times more product than 2F5scFc indicating that the product by itself also contributes to enhanced productivity. This study indicated comparable increase of transcription level for both scFc proteins when using the BAC system, but translation, maturation, and secretion of individual proteins seem to be protein specific.
Keywords: BAC; CHO; Antibody expression; gcn; Transcript level
Development of a novel recombinant strain Zygosacharomyces rouxii JL2011 for 1,3-propanediol production from glucose by Zheng Ma; Yalin Bian; Xuping Shentu; Xiaoping Yu (pp. 4055-4064).
1,3-propanediol (1,3-PDO) is one of the most important industrial chemicals due to its highly desired properties and its wide applications as a key component of the emerging polymer industry. Biotechnology route has been one of the most interesting methods for 1,3-PDO production, whereas, the dha genes were essential to 1,3-PDO biosynthesis. In this study, we cloned and placed the dha cassettes under the control of a glyceraldehyde 3-phosphate dehydrogenase gene promoter pGAP and homologous ZrFPS1 gene promoter pZrfps1; these two promoters were further integrated into the chromosome of Z. rouxii JL2011 to generate recombinant strain JL2011-GZ and JL2011-ZZ, respectively. The results showed that the two strains could produce 1,3-PDO from glucose with a final yield of 6.9 and 10.3 g/l, respectively. The engineered strain JL2011-ZZ showed a 2.3- and 1.5-fold increase in the specific activities and final concentration of 1,3-PDO, respectively, with respect to JL2011-GZ. Batch fermentation with aerobic/micro-aerobic combined strategy of JL2011-ZZ resulted a titer of 17.1 g/l and a yield from glucose of 8.6 %. These results demonstrated that JL2011-ZZ would be a potential strain for 1,3-PDO production from glucose.
Keywords: 1,3-propanediol; Zygosacharomyces rouxii ; Promoter pZrfps1 ; Quantitative real-time PCR
Biodegradation of the neonicotinoid insecticide thiamethoxam by the nitrogen-fixing and plant-growth-promoting rhizobacterium Ensifer adhaerens strain TMX-23 by Guang-can Zhou; Ying Wang; Shan Zhai; Feng Ge; Zhong-hua Liu; Yi-jun Dai; Sheng Yuan; Jun-yi Hou (pp. 4065-4074).
Thiamethoxam (THIA), a second generation neonicotinoid insecticide in the thianicotinyl subclass, is used worldwide. Environmental studies revealed that microbial degradation is the major mode of removal of this pesticide from soil. However, microbial transformation of THIA is poorly understood. In the present study, we isolated a bacterium able to degrade THIA from rhizosphere soil. The bacterium was identified as Ensifer adhaerens by its morphology and 16S ribosomal DNA sequence analysis. High-performance liquid chromatography and mass spectrometry analysis suggested that the major metabolic pathway of THIA in E. adhaerens TMX-23 involves the transformation of its N-nitroimino group (=N–NO2) to N-nitrosoimino (=N–NO) and urea (=O) metabolites. E. adhaerens TMX-23 is a nitrogen-fixing bacterium harboring two types of nifH genes in its genome, one of which is 98 % identical to the nifH gene in the cyanobacterium Calothrix sp. MCC-3A. E. adhaerens TMX-23 released various plant-growth-promoting substances including indole-3-acetic acid, exopolysaccharides, ammonia, HCN, and siderophores. Inoculation of E. adhaerens TMX-23 onto soybean seeds (Glycine max L.) with NaCl at 50, 100, or 154 mmol/L increased the seed germination rate by 14, 21, and 30 %, respectively. THIA at 10 mg/L had beneficial effects on E. adhaerens TMX-23, enhancing growth of the bacterium and its production of salicylic acid, an important plant phytohormone associated with plant defense responses against abiotic stress. The nitrogen-fixing and plant-growth-promoting rhizobacterium E. adhaerens TMX-23, which is able to degrade THIA, has the potential for bioaugmentation as well as to promote growth of field crops in THIA-contaminated soil.
Keywords: Ensifer adhaerens ; Nitrogen fixation; Nitro reduction; Plant-growth-promoting rhizobacterium; Thiamethoxam
Quantitative analysis of growth and volatile fatty acid production by the anaerobic ruminal bacterium Megasphaera elsdenii T81 by P. J. Weimer; G. N. Moen (pp. 4075-4081).
Megasphaera elsdenii T81 grew on either dl-lactate or d-glucose at similar rates (0.85 h−1) but displayed major differences in the fermentation of these substrates. Lactate was fermented at up to 210-mM concentration to yield acetic, propionic, butyric, and valeric acids. The bacterium was able to grow at much higher concentrations of d-glucose (500 mM), but never removed more than 80 mM of glucose from the medium, and nearly 60 % the glucose removed was sequestered as intracellular glycogen, with low yields of even-carbon acids (acetate, butyrate, caproate). In the presence of both substrates, glucose was not used until lactate was nearly exhausted, even by cells pregrown on glucose. Glucose-grown cultures maintained only low extracellular concentrations of acetate, and addition of exogenous acetate increased yields of butyrate, but not caproate. By contrast, exogenous acetate had little effect on lactate fermentation. At pH 6.6, growth rate was halved by exogenous addition of 60 mM propionate, 69 mM butyrate, 44 mM valerate, or 33 mM caproate; at pH 5.9, these values were reduced to 49, 49, 18, and 22 mM, respectively. The results are consistent with this species’ role as an effective ruminal lactate consumer and suggest that this organism may be useful for industrial production of volatile fatty acids from lactate if product tolerance could be improved. The poor fermentation of glucose and sensitivity to caproate suggests that this strain is not practical for industrial caproate production.
Keywords: Lactate; Glucose; Megasphaera elsdenii ; Volatile fatty acids
Aspartate protects Lactobacillus casei against acid stress by Chongde Wu; Juan Zhang; Guocheng Du; Jian Chen (pp. 4083-4093).
The aim of this study was to investigate the effect of aspartate on the acid tolerance of L. casei. Acid stress induced the accumulation of intracellular aspartate in L. casei, and the acid-resistant mutant exhibited 32.5 % higher amount of aspartate than that of the parental strain at pH 4.3. Exogenous aspartate improved the growth performance and acid tolerance of Lactobacillus casei during acid stress. When cultivated in the presence of 50 mM aspartate, the biomass of cells increased 65.8 % compared with the control (without aspartate addition). In addition, cells grown at pH 4.3 with aspartate addition were challenged at pH 3.3 for 3 h, and the survival rate increased 42.26-fold. Analysis of the physiological data showed that the aspartate-supplemented cells exhibited higher intracellular pH (pHi), intracellular NH4 + content, H+-ATPase activity, and intracellular ATP pool. In addition, higher contents of intermediates involved in glycolysis and tricarboxylic acid cycle were observed in cells in the presence of aspartate. The increased contents of many amino acids including aspartate, arginine, leucine, isoleucine, and valine in aspartate-added cells may contribute to the regulation of pHi. Transcriptional analysis showed that the expression of argG and argH increased during acid stress, and the addition of aspartate induced 1.46- and 3.06-fold higher expressions of argG and argH, respectively, compared with the control. Results presented in this manuscript suggested that aspartate may protect L. casei against acid stress, and it may be used as a potential protectant during the production of probiotics.
Keywords: Acid stress; Lactobacillus casei ; Aspartate accumulation; Stress response; Amino acid metabolism
Isolation and characterization of Pseudomonas sp. strain capable of degrading diethylstilbestrol by Weiwei Zhang; Zongliang Niu; Chunyang Liao; Lingxin Chen (pp. 4095-4104).
Since diethylstilbestrol (DES) interrupts endocrine systems and generates reproductive abnormalities in both wildlife and human beings, methods to remove DES from the environments are urgently recommended. In this study, bacterial strain J51 was isolated and tested to effectively degrade DES. J51 was identified as Pseudomonas sp. based on its nucleotide sequence of 16S rRNA. The quinoprotein alcohol dehydrogenase and isocitrate lyase were identified to be involved in DES degradation by MALDI–TOF–TOF MS/MS analysis. In the presence of 40 mg/l DES, increase of the genes encoding quinoprotein alcohol dehydrogenase and isocitrate lyase in both RNA and protein levels was determined. The HPLC/MS analysis showed that DES was hydrolyzed to a major degrading metabolite DES-4-semiquinone. It was the first time to demonstrate the characteristics of DES degradation by specific bacterial strain and the higher degradation efficiency indicated the potential application of Pseudomonas sp. strain J51 in the treatment of DES-contaminated freshwater and seawater environments.
Keywords: Diethylstilbestrol; Pseudomonas sp.; Degradation; Metabolite; Cytotoxicity
An innovative tool reveals interaction mechanisms among yeast populations under oenological conditions by P. E. Renault; W. Albertin; M. Bely (pp. 4105-4119).
Alcoholic fermentation of grape must is a complex process, involving several yeast genera and species. The early stages in fermentation are dominated by non-Saccharomyces yeasts that are gradually replaced by the Saccharomyces cerevisiae species, which takes over the fermentation. Quantitative studies have reported the influence of non-Saccharomyces yeast species on wine quality and evaluated their biotechnological interest. The industrial yeast market, which, until recently, exclusively focused on S. cerevisiae, now offers S. cerevisiae/non-Saccharomyces (including Torulaspora delbrueckii) multi-starters. The development of these new mixed industrial starters requires a better understanding of the interaction mechanisms between yeast populations in order to optimize the aromatic impact of the non-Saccharomyces yeast while ensuring complete alcoholic fermentation thanks to S. cerevisiae. For this purpose, a new double-compartment fermentor was designed with the following characteristics: (1) physical separation of two yeast populations, (2) homogeneity of the culture medium in both compartments, (3) fermentation kinetics monitored by weight loss due to CO2 release, and (4) independent monitoring of growth kinetics in the two compartments. This tool was used to compare mixed inoculations of S. cerevisiae/T. delbrueckii with and without physical separation. Our results revealed that physical contact/proximity between S. cerevisiae and T. delbrueckii induced rapid death of T. delbrueckii, a phenomenon previously described and attributed to a cell–cell contact mechanism. In contrast, when physically separated from S. cerevisiae, T. delbrueckii maintained its viability and its metabolic activity had a marked impact on S. cerevisiae growth and viability. The double fermentor is thus a powerful tool for studying yeast interactions. Our findings shed new light on interaction mechanisms described in microorganism populations.
Keywords: Saccharomyces cerevisiae ; Torulaspora delbrueckii ; Wine fermentation; Cell–cell contact; Quorum sensing
The improved l-tryptophan production in recombinant Escherichia coli by expressing the polyhydroxybutyrate synthesis pathway by Pengfei Gu; Junhua Kang; Fan Yang; Qian Wang; Quanfeng Liang; Qingsheng Qi (pp. 4121-4127).
Polyhydroxybutyrate (PHB), the best known polyhydroxyalkanoates (PHA) has been believed to change intracellular metabolic flow and oxidation/reduction state, as well as enhance stress resistance of the host. In this study, a PHB biosynthesis pathway, which contains phaCAB operon genes from Ralstonia eutropha, was introduced into an l-tryptophan producing Escherichia coli strain GPT1002. The expression of the PHB biosynthesis genes resulted in PHB accumulation inside the cells and improved the l-tryptophan production. Quantitative real-time PCR analysis showed that the transcription of tryptophan operon genes in GPT2000 increased by 1.9 to 4.3 times compared with the control, indicating that PHB biosynthesis in engineered E. coli changed the physiological state of the host. Xylose was added into the medium as co-substrate to enhance the precursor supply for PHB biosynthesis. The addition of xylose improved both extracellular l-tryptophan production and intracellular PHB accumulation. Moreover, we obtained 14.4 g l−1 l-tryptophan production and 9.7 % PHB (w/w) accumulation in GPT2000 via fed-batch cultivation.
Keywords: E. coli ; l-tryptophan; PHB; Metabolic engineering
Reproducibility, fidelity, and discriminant validity of linear RNA amplification for microarray-based identification of major human enteric viruses by Haifeng Chen; Xuemei Chen; Yuan Hu; Huijun Yan (pp. 4129-4139).
Human enteric viruses are inherently a group of viruses that confer similar or overlapping clinical symptoms and pose a challenge for correct etiological diagnosis. DNA microarray technology has emerged to be of major interest to detect broad range of viral pathogens including enteric viruses. However, this approach requires a relative large amount of target nucleic acid for hybridization analysis. This feature limits its further applicability. To address this challenge, we evaluated a novel single primer linear isothermal amplification (Ribo-SPIA) procedure for preparation of single-stranded cDNA (sscDNA) from minute amount of starting RNA for microarray-based simultaneous detection and identification of three major human enteric viruses including hepatitis A virus, norovirus, and coxsachievirus B2. We performed a series of tests using different amounts of input RNA ranging from 30 ng to 55 pg to assess amplification yield, reproducibility, analytical sensitivity, and fidelity. We demonstrated that as little as 55 pg of viral RNA could produce adequate material by Ribo-SPIA to enable successful identification by microarray analysis without compromising detection specificity. Pairwise comparison of technical replicates hybridized to the microarrays by regression analysis showed excellent reproducibility in the appropriate sensitivity range. We also showed that the use of sscDNA as labeled targets offered increased microarray detection accuracy over complementary RNA generated by traditional T7 in vitro transcription amplification method.
Keywords: Human enteric viruses; DNA microarray; Linear RNA amplification; Single-stranded cDNA
The starch-binding domain as a tool for recombinant protein purification by D. Guillén; S. Moreno-Mendieta; P. Aguilera; S. Sánchez; A. Farres; R. Rodríguez-Sanoja (pp. 4141-4148).
Recombinant protein purification with affinity tags is a widely employed technique. One of the most common tags used for protein purification is the histidine tag (Histag). In this work, we use a tandem starch-binding domain (SBDtag) as a tag for protein purification. Four proteins from different sources were fused to the SBDtag, and the resulting fusion proteins were purified by affinity chromatography using the Histag or the SBDtag. The results showed that the SBDtag is superior to the Histag for protein purification. The efficient adsorption of the fusion proteins to raw corn starch was also demonstrated, and two fusions were selected to test purification directly using raw starch from rice, corn, potato, and barley. The two fusion proteins were successfully recovered from crude bacterial extract using raw starch, thus demonstrating that the SBDtag can be used as an efficient affinity tag for recombinant protein purification on an inexpensive matrix.
Keywords: Starch-binding domain; Purification tag; Affinity tag; Fusion protein; Protein immobilization
Response surface methodology to design a selective enrichment broth for rapid detection of Salmonella spp. by SYBR Green Ι real-time PCR by Qiaoyan Zhang; Tingting Chen; Shengli Yang; Xiaofu Wang; Hui Guo (pp. 4149-4158).
In order to meet dominant growth of Salmonella spp. in a composed system of five pathogens for accurate detection, designing an appropriate selective enrichment broth was clearly needed. First, we built a high-throughput assay procedure based on SYBR Green Ι real-time PCR, which possessed the necessary specificity for Salmonella spp., a good linear standard curve with typical R 2 value (0.9984) and high amplification efficiency (99.0 %). Further, for the larger target biomass in the mixed microflora, acarbose, LiCl and bile salt were selected to optimize their concentrations using response surface methodology (RSM). A central composite design was employed to collect the data and fit the response. A quadratic polynomial model was derived by computer simulation. Statistical analysis was carried out to explore the action and interaction of the variables on the response. In the end, a novel broth (Sal-5) was formulated to allow the efficient enrichment of Salmonella spp. and inhibit the growth of other tested strains. A detection platform was developed, including selective enrichment in Sal-5, DNA extraction by the boiling lysis method and real-time PCR test based on SYBR Green Ι. This work could extend the application of RSM and real-time PCR in the design of other selective enrichment media for common pathogens.
Keywords: Response surface methodology; Selective enrichment broth; SYBR Green Ι real-time PCR; Salmonella spp.; Inhibitor; Acarbose
Two-day detection of infectious enteric and non-enteric adenoviruses by improved ICC-qPCR by Leslie Ogorzaly; Henry-Michel Cauchie; Christian Penny; Aline Perrin; Christophe Gantzer; Isabelle Bertrand (pp. 4159-4166).
In order to provide a more suitable response to public health concerns, we improved the detection of infectious human adenoviruses in water by optimising the commonly used integrated cell culture–PCR method. Risk evaluation studies seek for rapid detection of infectious adenoviruses, including the enteric types 40 and 41 that are considered as the second most common agents of gastroenteritis in children next to rotaviruses. The here-employed 293A cell line used for infectious status assessment showed its ability to multiply adenoviruses including type 41. Two modifications were moreover applied to the workflow for viral detection. The first occurred at the nucleic acid extraction step performed directly on all infected cells, while the second was the application of real-time quantitative PCR as detection tool. All adaptations led to a 3-day reduction of the response delay and an improved sensitivity especially for the enteric adenoviral types. The infectious status of laboratory strain types 2 and 41 was demonstrated by a more than 2-log10 increase in genome quantity. These conclusions were confirmed and reinforced by the analysis of water samples applying the improved assay. Naturally occurring infectious adenoviruses were detected in wastewater and river water, within 2 days. Types belonging to the species human adenoviruses C and type 31 were observed, but the most frequently identified type was 41 (71 % of identified sequences, n = 34). This highlights the usefulness of our method for a wide range of types, and especially for the most prevalent and public health-relevant enteric adenoviruses.
Keywords: Human adenoviruses; Type 41; ICC-qPCR; HEK 293A; Infectivity
Improvement on the modified Lowry method against interference of divalent cations in soluble protein measurement by Yue-xiao Shen; Kang Xiao; Peng Liang; Yi-wei Ma; Xia Huang (pp. 4167-4178).
This paper systematically investigated the interference of calcium and magnesium in protein measurement with a modified Lowry method first proposed by Frølund et al. (Appl Microbiol Biotechnol 43:755–761, 1995). This interference has in the past been largely ignored resulting in variable and unreliable results when applied to natural water matrices. We discovered significant formation of calcium and magnesium precipitates that lead to a decline in light absorbance at 750 nm during protein determination. Underestimation of protein concentration (sometimes even yielding negative concentrations) and low experiment reproducibility were demonstrated at high concentrations of divalent cations (e.g., [Ca2+] over 1 mmol L−1). To eliminate interference from calcium and magnesium, two pretreatment strategies were established based on cation exchange and dialysis. These pretreatments were convenient and were found to be highly effective in removing calcium and magnesium in protein samples. By using the modified Lowry method with these pretreatments, proteins in standard solutions and in wastewater samples were successfully quantified with good reliability and reproducibility. In addition, we demonstrated that simultaneous quantification of humic substances with the modified Lowry method was not affected by the two pretreatments. These approaches are expected to be applicable to protein and humic substance determination in different research fields, in cases where the modified Lowry method is sensitive to divalent cation concentrations.
Keywords: Cation exchange; Dialysis; Divalent cations; The modified Lowry method; Interference
Variation in microbial population during composting of agro-industrial waste by Luísa Coelho; Mário Reis; Lídia Dionísio (pp. 4179-4186).
Two compost piles were prepared, using two ventilation systems: forced ventilation and ventilation through mechanical turning. The material to compost was a mixture of orange waste, olive pomace, and grass clippings (2:1:1 v/v). During the composting period (375 days), samples were periodically taken from both piles, and the enumeration of fungi, actinomycetes, and heterotrophic bacteria was carried out. All studied microorganisms were incubated at 25 and 55 °C after inoculation in appropriate growth media. Fungi were dominant in the early stages of both composting processes; heterotrophic bacteria proliferated mainly during the thermophilic stage, and actinomycetes were more abundant in the final stage of the composting process. Our results showed that the physical and chemical parameters: temperature, pH, moisture, and aeration influenced the variation of the microbial population along the composting process. This study demonstrated that composting of these types of wastes, despite the prolonged mesophilic stage, provided an expected microbial variation.
Keywords: Fungi; Actinomycetes; Heterotrophic bacteria; Compost
Decolorization of azo dyes by marine Shewanella strains under saline conditions by Guangfei Liu; Jiti Zhou; Xianming Meng; Shiang Q. Fu; Jing Wang; Ruofei Jin; Hong Lv (pp. 4187-4197).
Azo dye decolorization was studied with Shewanella strains under saline conditions. Growing cells of Shewanella algae and Shewanella marisflavi isolated from marine environments demonstrated better azo dye decolorization capacities than the other three strains from non-saline sources. Cell suspensions of S. algae and S. marisflavi could decolorize single or mixed azo dyes with different structures. Decolorization kinetics were described with Michaelis–Menton equation, which indicated better decolorization performance of S. algae over S. marisflavi. Lactate and formate were identified as efficient electron donors for amaranth decolorization by the two strains. S. algae and S. marisflavi could decolorize amaranth at up to 100 g L−1 NaCl or Na2SO4. However, extremely low concentration of NaNO3 exerted strong inhibition on decolorization. Both strains could remove the color and COD of textile effluent during sequential anaerobic–aerobic incubation. Lower concentrations of NaCl (20–30 g L−1) stimulated the activities of azoreductase, laccase, and NADH-DCIP reductase. The decolorization intermediates were identified by high-performance liquid chromatography and Fourier transform infrared spectroscopy. Decolorization metabolites of amaranth were less toxic than original dye. These findings improved our knowledge of azo-dye-decolorizing Shewanella species and provided efficient candidates for the treatment of dye-polluted saline wastewaters.
Keywords: Azo dye; Decolorization; Saline; Shewanella algae ; Shewanella marisflavi
Dynamics of metabolically active bacterial communities involved in PAH and toxicity elimination from oil-contaminated sludge during anoxic/oxic oscillations by I. Vitte; R. Duran; G. Hernandez-Raquet; J. Mounier; R. Jézéquel; V. Bellet; P. Balaguer; P. Caumette; C. Cravo-Laureau (pp. 4199-4211).
The kinetics of polycyclic aromatic hydrocarbons (PAH) elimination from a contaminated sludge were determined in bioreactors under different conditions: continuously oxic, anoxic, and anoxic/oxic oscillations. The dynamics of metabolically active bacterial communities and their involvement in PAH degradation were followed by T-RFLP targeting 16S rRNA and ring hydroxylating dioxygenase (RHD) transcripts, respectively. PAH degradation was related to toxicity elimination using an aryl hydrocarbon receptor-responsive reporter cell line. Oxygen supply was identified as the main factor affecting the structure of bacterial communities and PAH removal. PAH-degrading bacterial communities were stable throughout the experiment in all conditions according to the presence of RHD transcripts, indicating that bacterial communities were well adapted to the presence of pollutants. Oxic and anoxic/oxic oscillating conditions showed similar levels of PAH removal at the end of the experiment despite several anoxic periods in oscillating conditions. These results highlight the role of dioxygenase activity after oxygen addition. Nevertheless, the higher toxicity elimination observed under oxic conditions suggests that some metabolites or other unidentified active compounds persisted under oscillating and anoxic conditions. Our results emphasize the importance of using complementary biological, chemical and toxicological approaches to implement efficient bioremediation strategies.
Keywords: Anoxic/oxic oscillations; RHD gene; PAH degradation; AhR activity; Metabolically active bacteria; Oily sludge
Influence of aeration intensity on mature aerobic granules in sequencing batch reactor by Da-Wen Gao; Lin Liu; Hong Liang (pp. 4213-4219).
Aeration intensity is well known as an important factor in the formation of aerobic granules. In this research, two identical lab-scale sequencing batch reactors with aeration intensity of 0.8 (R1) and 0.2 m3/h (R2) were operated to investigate the characteristics and kinetics of matured aerobic granules. Results showed that both aeration intensity conditions induced granulation, but they showed different effects on the characteristics of aerobic granules. Compared with the low aeration intensity (R2), the aerobic granules under the higher aeration intensity (R1) had better physical characteristics and settling ability. However, the observed biomass yield (Y obs) in R1 [0.673 kg mixed liquor volatile suspended solids (MLVSS)/kg chemical oxygen demand (COD)] was lower than R2 (0.749 kg MLVSS/kg COD). In addition, the maximum specific COD removal rates (q max) and apparent half rate constant (K) of mature aerobic granular sludge under the two aeration intensities were at a similar level. Therefore, the matured aerobic granule system does not require to be operated in a higher aeration intensity, which will reduce the energy consumption.
Keywords: Aerobic granule; Aeration intensity; Dissolved oxygen; Biodegradation; Wastewater treatment
Characterization of rhizosphere prokaryotic diversity in a horizontal subsurface flow constructed wetland using a PCR cloning-sequencing based approach by Moez Bouali; Eric Pelletier; Sébastien Chaussonnerie; Denis Le Paslier; Amina Bakhrouf; Abdelghani Sghir (pp. 4221-4231).
Performance of biological wastewater treatment systems may be related to the composition and activity of microbial populations they contain. However, little information is known regarding microbial community inhabiting these ecosystems. The purpose of this study was to investigate archaeal and bacterial diversity, using cultivation-independent molecular techniques, in a constructed wetland receiving domestic wastewater. Two 16S rRNA gene libraries were constructed using total genomic DNA and amplified by PCR using primers specific for archaeal and bacterial domains. A high microbial diversity was detected. The Proteobacteria phylum is the most abundant and diversified phylogenetic group representing 31.3 % of the OTUs, followed by the Bacteroidetes (14.8 %), Planctomycetales (13.8 %), Actinobacteria (12 %), and Chloroflexi (8.2 %). Sequences affiliated with minor phylogenetic divisions such as the TM7, Nitrospira, OP10, and BRC1 are represented by <6 % of total OTUs. The Archaea domain was represented by the Thaumarchaeota phylum dominated by the Candidatus Nitrososphaera genus.
Keywords: Microbial diversity; Thaumarchaeota ; Wastewater treatment; Constructed wetland
Erratum to: Design, expression, and characterization of a novel targeted plectasin against methicillin-resistant Staphylococcus aureus
by Ruoyu Mao; Da Teng; Xiumin Wang; Di Xi; Yong Zhang; Xiaoyuan Hu; Yalin Yang; Jianhua Wang (pp. 4233-4234).