Maotai-flavor liquor, a famous traditional Chinese drink, is distilled from fermented sorghum in the southern province of China. Moreover, it is of interest as one of the few examples of liquor distilled from the product of a fermentation using a wild microflora starter. Daqu is the starter of this fermentation process. Daqu is a mixture of two components: milled wheat and a complex microbial community. The composition and the effects of this microbial group are largely unknown. In this study, we have analysed the constituents of the microbial community and the development of microorganisms in the industrial Daqu preparation and ripening process. More than 200 colonies were isolated and characterized. The isolates were discriminated by phenotypic and conventional biochemical taxonomic methods. The results revealed the presence of bacteria, moulds and yeasts. Bacteria consist of Bacillus, Acetobacter, Lactobacillus, and Clostridium, among which Bacillus strains were found to be predominant. Moulds consisted of Aspergillus, Mucor, Rhizopus, Monascus and Trichoderma, and Aspergillus strains were found to be predominant in the six different biotypes. Yeasts comprised Saccharomyces, Hansenula, Candida, Pichia, and Torulaspora. The most frequently isolated yeasts belonged to the genus Saccharomyces. The microbial diversity shift showed that the microbial genera changed with increasing ripening time. Knowledge of the microbial diversity in Daqu provides a basis for microflora management and understanding of the role of microbes in the Daqu production process, and the contribution of Daqu performed as a starter culture to Maotai-flavor liquor.
The epothilones are highly promising prospective anticancer agents that are produced by the myxobacterium Sorangium cellulosum. We mutated the epothilone producing S. cellulosum strain So0157-2 to improve the production of epothilones. For evaluation in high-throughput of a large number of mutants, we developed a simple microtiter method for primary screening. Using the classical UV-mutation method plus selection pressures, the production capacity was increased about 0.5 approximately 2.5 times the starting strain. The mutants with higher production and different phenotypes were further subjected to recursive protoplast fusions and the fusants products were screened under multi-selection pressure. Furthermore, the production was greatly increased by the genome shuffling. For epothilone B, the production of one fusant was increased about 130 times compared to the starting strain, increasing from 0.8 mg l(-1) to 104 mg l(-1).
Metabolic engineering of microbial strains for the production of flavonoids of industrial interest has attracted great attention due to its promising advantages over traditional extraction approaches, such as independence of plantation, facile downstream separation, and ease of process and quality control. However, most of the constructed microbial production systems suffer from low production titers, low yields and low productivities, restricting their commercial applications. One important reason of the inefficient production is that the expression conditions and the detailed functions of the flavonoid pathway enzymes are not well understood. In this review, we have collected the biochemical properties, structural details, and genetic information of the enzymes in the flavonoid biosynthetic pathway as a guide for the expression and analysis of these enzymes in microbial systems. Additionally, we have summarized the engineering approaches used in improving the performances of these enzymes in recombinant microorganisms. Major challenges and future directions on the flavonoid pathway are also discussed.
Wall teichoic acids (WTAs) are charged glycopolymers containing phosphodiester-linked polyol units and represent one of the major components of Gram-positive cell envelope. WTAs have important physiological functions in cell division, gene transfer, surface adhesion, drug resistance, and biofilm formation, and are critical virulence factors and vital determinants in mediating cell interaction with and tolerance to environmental factors. Here we first briefly introduce WTA structure, biosynthesis and its regulation, and then summarize in detail four major physiological roles played by WTAs, i.e. WTA-mediated resistance to antimicrobials, virulence to mammalian cells, interaction with bacteriolytic enzymes, and regulation of cell metabolism. We also review the applications of WTAs in these fields that are closely related to the human society, including antibacterial drug discovery targeting WTA biosynthesis, development of vaccines and antibodies regarding WTA-mediated pathogenicity, specific and sensitive detection of pathogens in food using WTAs as a surface epitope, and regulation of WTA-related pathways for efficient microbial production of useful compounds. We also point out major problems remaining in these fields, and discuss some possible directions in the future exploration of WTA physiology and applications.
Recovery of recombinant proteins
from the Escherichia
coli cytoplasm depends on cell disruption by mechanical,
chemical, and/or enzymatic methods, which usually cause incomplete
cell breakage or protein denaturation. Controllable autolytic E. coli strains have been designed to facilitate
the purification of recombinant proteins; however, these strains suffer
from low recovery yield, slow cell lysis, or extensive strain engineering.
Herein, we report an improved, highly efficient programmable autolytic E. coli platform, in which cell lysis is initiated
upon the induced expression of T4 lysozyme with N-terminal fusion
of a cell-penetrating peptide. Through the engineering of the peptide
sequence and copy number, and by incorporating the fusion lytic gene
into the E. coli genome, more than
99.97% of cells could be lysed within 30 min of induction regardless
of cell age. We further tested the expression and release of a recombinant
enzyme lysostaphin (Lst) and demonstrated that 4 h induction of the
lytic gene after 3 h of Lst expression resulted in 98.97% cell lysis.
Lst obtained from this system had the same yield, yet 1.63-fold higher
activity, compared with that obtained from cells lysed by freeze–thawing
and sonication. This autolytic platform shows potential for use in
large-scale microbial production of proteins and other biopolymers.
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