1.Cryptomycota: the missing link.
Krishna BOLLA ; Elizabeth Jane ASHFORTH
Protein & Cell 2012;3(3):161-162
Biological Evolution
;
Chitin
;
chemistry
;
metabolism
;
Fungi
;
classification
;
genetics
;
metabolism
;
Phylogeny
2.Genetic engineering and enzyme research in lignocellulosic ethanol production.
Protein & Cell 2011;2(10):776-777
Bacteria
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enzymology
;
genetics
;
Bacterial Proteins
;
chemistry
;
genetics
;
Biofuels
;
Enzyme Stability
;
Enzymes
;
chemistry
;
genetics
;
Ethanol
;
chemical synthesis
;
Fermentation
;
Lignin
;
chemistry
;
Protein Engineering
4.Engineering of a genome-reduced host: practical application of synthetic biology in the overproduction of desired secondary metabolites.
Hong GAO ; Ying ZHUO ; Elizabeth ASHFORTH ; Lixin ZHANG
Protein & Cell 2010;1(7):621-626
Synthetic biology aims to design and build new biological systems with desirable properties, providing the foundation for the biosynthesis of secondary metabolites. The most prominent representation of synthetic biology has been used in microbial engineering by recombinant DNA technology. However, there are advantages of using a deleted host, and therefore an increasing number of biotechnology studies follow similar strategies to dissect cellular networks and construct genome-reduced microbes. This review will give an overview of the strategies used for constructing and engineering reduced-genome factories by synthetic biology to improve production of secondary metabolites.
Biosynthetic Pathways
;
genetics
;
Cephamycins
;
biosynthesis
;
Epoxy Compounds
;
metabolism
;
Escherichia coli
;
genetics
;
metabolism
;
Gene Deletion
;
Gene Regulatory Networks
;
Genetic Engineering
;
methods
;
Genetics, Microbial
;
Genome
;
Sesquiterpenes
;
metabolism
;
Streptomyces
;
genetics
;
metabolism
;
Streptomycin
;
biosynthesis
;
Synthetic Biology