October 18th, 2011
SBE’s Metabolic Engineering Symposium Showcases Science and Business of Bio-based ProductsBy Drew McUsic | 30421Comments (1)SBE%27s+Metabolic+Engineering+Symposium+Showcases+Science+and+Business+of+Bio-based+Products2011-10-18+21%3A57%3A13Drew+McUsichttp%3A%2F%2Fchenected.aiche.org%2F%3Fp%3D30421
This post is presented by SBE, the Society for Biological Engineering—a global organization of leading engineers and scientists dedicated to advancing the integration of biology with engineering. The Society for Biological Engineering (SBE) Symposium on “20 Years of Metabolic Engineering: Foundation of a Bio-Based Economy” celebrated the rapidly growing field of metabolic engineering in an exciting forum consisting of esteemed speakers from industry, government, and academia, followed by an open group discussion. MIT’s Gregory Stephanopoulos, widely considered to be one of the fathers of metabolic engineering since his 1991 publication (hence "20 years"), chaired the symposium, introduced the conceptual basis, and briefly stated the rationale for why the field has such enormous implications for present day challenges in materials, chemicals, and renewable biofuels production. [caption id="attachment_30455" align="alignright" width="225" caption="Stephanopoulos kicks off the symposium"][/caption] Metabolic engineering is the principle that living organisms (usually bacteria or other simple, single-celled organisms) can be modified to produce desirable products such as polymers and fuels. Most commonly, this modification is performed by altering existing metabolic pathways or introducing new ones through genetic manipulation. The metabolic engineer (often a chemical engineer by training) is concerned with this network level of metabolic pathways rather than single chemical reactions. Sang Yup Lee of KAIST introduced some key concepts of metabolic engineering, including the measurement and optimization of molecules as they move through microorganisms. This "flux" is important because it ultimately determines the efficiency, or "yield", of the end product. Sang Yup repeatedly used the phrase "kill off" to describe what metabolic engineers must do to many of the naturally existing pathways in E. coli, which are designed to degrade, inhibit, and reabsorb the very product they've been engineered to spit out. From naturally existing products such as polysaccharides and peptides to products traditionally derived from petroleum such as synthetic polymers and fuels, there seems to be no limit to what can be manufactured through metabolic engineering in an academic context. Sang Yup gave teasers into the possibilities of engineered sugars that have double the yield of sugarcane but won't affect sugar prices for consumers, and redesigned E. coli that can internalize metal particles and synthesize quantum dots for use in cutting edge qLED TVs.