Optimize flavonoid production through metabolic engineering.Flavonoids flavonoids, n.pl common plant pigment compounds that act as antioxidants, enhance the effects of vitamin C, and strengthen connective tissue around capillaries. are plant polyphenols most commonly known for their antioxidant activity. The flavonoid pathway leads to the formation of phenolic phe·no·lic adj. Of, relating to, containing, or derived from phenol. n. Any of various synthetic thermosetting resins, obtained by the reaction of phenols with simple aldehydes and used as adhesives. compounds that have several biological functions. Scientists at the State University of New York (body) State University of New York - (SUNY) The public university system of New York State, USA, with campuses throughout the state. at Buffalo have developed novel production platforms for the biosynthesis Biosynthesis The synthesis of more complex molecules from simpler ones in cells by a series of reactions mediated by enzymes. The overall economy and survival of the cell is governed by the interplay between the energy gained from the breakdown of compounds of natural flavonoid molecules--isoflavones, flavanones, flavones, flavonols, catechins and anthocyanins--using well-characterized microbial microbial pertaining to or emanating from a microbe. microbial digestion the breakdown of organic material, especially feedstuffs, by microbial organisms. species, such as Escherichia coli and Saccharomyces Saccharomyces: see yeast. cerevisiae. The novel production methodologies under development will allow flavonoid compounds to be produced at a significantly lower cost and at higher purity. This is because production through microbial platforms is easier. Microorganisms are easier to grow than plants in a controlled environment. This approach relies on renewable carbon sources as a feeding source--glucose. It is more economical since there are lower energy requirements as microorganisms grow at room temperature. There is no reliance on toxic catalysts and organic solvents. The scientists can provide novel flavonoids that can be used in various food applications, such as functional foods with improved antioxidant properties. Since some flavonoids, such as anthocyanins and deoxyanthocyanins, are natural colorants, their efficient and economical production through microbial synthesis will allow their use as alternatives to synthetic dyes, which may have adverse health effects. It is important to note that some anthocyanins, unlike other natural dyes, have some unique coloration properties, such as blue and purple coloration, which are among the highly sought natural colors in the food industry. The critical issue that the researchers are still working on is improving production yields to make the processes even more competitive and amenable to large-scale production. In addition, the scientists use their microbial strains to produce not only natural flavonoids but also non-natural derivatives that have unusual chemistry and properties. The researchers believe that both the natural compounds (some of which are extremely rare in nature, such as deoxyanthocyanins) and the non-naturals can have applications not only in the food but also in the pharmaceutical industry. In particular, the researchers are exploring the use of these compounds in the treatment of obesity and type II diabetes Type II diabetes Type II diabetes is the most common form of diabetes and usually appears in middle aged adults. It is often associated with obesity and may be delayed or controlled with diet and exercise. Mentioned in: Diabetic Ketoacidosis . They have already accumulated some evidence demonstrating the beneficial effect of some of the compounds in the treatment of these two chronic diseases. The researchers' data demonstrate that yeast is a better biocatalyst bi·o·cat·a·lyst n. A substance, especially an enzyme, that initiates or modifies the rate of a chemical reaction in a living body; a biochemical catalyst. bi for flavonoid biosynthesis, displaying in some cases a 10-fold higher production yield compared to prokaryotic pro·kar·y·ote also pro·car·y·ote n. An organism of the kingdom Monera (or Prokaryotae), comprising the bacteria and cyanobacteria, characterized by the absence of a distinct, membrane-bound nucleus or membrane-bound organelles, and by DNA that E. coli. The scientists have optimized flavonoid biosynthesis in E. coli by increasing the intracellular pool of malonyl-CoA through various metabolic and protein engineering approaches. Malonyl-CoA is a coenzyme A derivative which plays a key role in chain elongation in fatty acid biosynthesis and polyketide biosynthesis. Using the constructed recombinant strains, the scientists also have achieved the biosynthesis of two novel, unnatural flavonoid compounds with fluro and amino groups introduced at the 4' position of the B phenyl phenyl (fĕn`əl), C6H5, organic free radical or alkyl group derived from benzene by removing one hydrogen atom. ring. The research is ongoing. Further information. Mattheos Koffas, Department of Chemical and Biological Engineering, The State University of New York at Buffalo, 904 Furnas Hall, Buffalo, NY 14260; phone: 716-645-2911; fax: 716-645-3822; email: mkoffas@buffalo.edu. |
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