THE METABOLIC PATHWAY ENGINEERING HANDBOOK Tools and Applications 77651.indb 1 6/2/09 6:36:39 PM The Metabolic Pathway Engineering Handbook, 1st Edition The Metabolic Pathway Engineering Handbook: Fundamentals The Metabolic Pathway Engineering Handbook: Tools and Applications 77651.indb 2 6/2/09 6:36:39 PM THE METABOLIC PATHWAY ENGINEERING HANDBOOK Tools and Applications Edited by Christina D. Smolke 77651.indb 3 6/2/09 6:36:40 PM CRC Press Taylor & Francis Group 6000 Broken Sound Parkway NW, Suite 300 Boca Raton, FL 33487-2742 © 2010 by Taylor & Francis Group, LLC CRC Press is an imprint of Taylor & Francis Group, an Informa business No claim to original U.S. Government works Printed in the United States of America on acid-free paper 10 9 8 7 6 5 4 3 2 1 International Standard Book Number-13: 978-1-4200-7765-0 (Hardcover) This book contains information obtained from authentic and highly regarded sources. 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Title. [DNLM: 1. Genetic Engineering--methods. 2. DNA--metabolism. 3. Genetic Techniques. 4. RNA--metabolism. QU 450 M587 2010] TP248.6.M48 2010 660.6’5--dc22 2008045948 Visit the Taylor & Francis Web site at http://www.taylorandfrancis.com and the CRC Press Web site at http://www.crcpress.com 77651.indb 4 6/2/09 6:36:40 PM Contents Introduction ..................................................................................................ix Editor .............................................................................................................xv Contributors ...............................................................................................xvii SEcTIon I Evolutionary Tools in Metabolic Engineering Claudia Schmidt-Dannert 1 Evolutionary Engineering of Industrially Important Microbial Phenotypes .....................................................................................1-1 Stephen S. Fong 2 Improving Protein Functions by Directed Evolution ................................... 2-1 Nikhil u. Nair and Huimin Zhao 3 Engineering DNA and RNA Regulatory Regions through Random Mutagenesis and Screening ............................................................................3-1 Ichiro Matsumura, Sean A. Lynch, and Justin P. Gallivan 4 Evolving Pathways and Genomes for the Production of Natural and Novel Compounds ..........................................................................................4-1 Ethan T. Johnson and Claudia Schmidt-Dannert 5 Models Predicting Optimized Strategies for Protein Evolution ...................5-1 Jonathan J. Silberg and Peter Q. Nguyen SEcTIon II Gene Expression Tools for Metabolic Pathway Engineering Christina D. Smolke 6 Low-Copy Number Plasmids as Artificial Chromosomes ............................6-1 Kristala L. Jones Prather 7 Chromosomal Engineering Strategies ............................................................7-1 Kenan C. Murphy v 77651.indb 5 6/2/09 6:36:40 PM vi Contents 8 Regulating Gene Expression through Engineered RNA Technologies ...................................................................................................8-1 Maung Nyan Win and Christina D. Smolke 9 Tools Designed to Regulate Translational Efficiency ................................... 9-1 Claes Gustafsson 10 Metabolic Engineering of the Secretory Processing Pathway in Eukaryotes.................................................................................................10-1 Mohak Mhatre, Maira P. Pellegrini, and Michael J. Betenbaugh 11 Engineering Multifunctional Enzyme Systems for Optimized Metabolite Transfer between Sequential Conversion Steps .........................11-1 Robert J. Conrado, Thomas J. Mansell, and Matthew P. DeLisa 12 Practical Pathway Engineering—Demonstration in Integrating Tools ...........................................................................................12-1 Sung Kuk Lee and Jay D. Keasling SEcTIon III Application of Emerging Technologies to Metabolic Engineering Jay D. Keasling 13 Genome-Wide Technologies: DNA Microarrays, Phenotypic Microarrays, and Proteomics .......................................................................13-1 Seh Hee Jang, Mee-Jung Han, Sang Yup Lee, Jong Hyun Choi, and Xiao Xia Xia 14 Monitoring and Measuring the Metabolome ...............................................14-1 Maria Rowena N. Monton and Tomoyoshi Soga SEcTIon IV Future Prospects in Metabolic Engineering Bernhard ø. Palsson and Sang Yup Lee 15 Systems Biology, Genome-Scale Models, and Metabolic Engineering ..................................................................................15-1 Sang Yup Lee, Hyun uk Kim, Hongseok Yun, Seung Bum Sohn, Jin Sik Kim, Bernhard ø. Palsson, Markus J. Herrgård, and Vasiliy A. Portnoy 16 Cell-Free Systems for Metabolic Engineering ..............................................16-1 Kara A. Calhoun and James R. Swartz 17 In Silico Models for Metabolic Systems Engineering ...................................17-1 Kumar Selvarajoo, Satya Nanda Vel Arjunan, and Masaru Tomita 77651.indb 6 6/2/09 6:36:41 PM Contents vii SEcTIon V Tools for Experimentally Determining Flux through Pathways Ralf Takors 18 GC–MS for Metabolic Flux Analysis ............................................................18-1 Christoph Wittmann 19 Tools for Measuring Intermediate and Product Formation ........................19-1 Marco Oldiges 20 Use of AEX-HPLC-ESI-MS for 13C-Labeling Based Metabolic Flux Analysis in Saccharomyces cerevisiae and Penicillium chrysogenum .........20-1 Wouter A. van Winden, Roelco J. Kleijn, Walter M. van Gulik, and Joseph J. Heijnen SEcTIon VI Future Applications of Metabolic Engineering Brian F. Pfleger 21 Energy and Cofactor Issues in Fermentation and Oxyfunctionalization Processes ...................................................................21-1 Bruno Bühler, Lars M. Blank, Birgitta E. Ebert, Katja Bühler, and Andreas Schmid 22 Microbial Biosynthesis of Fine Chemicals: An Emerging Technology .............................................................................22-1 Zachary L. Fowler and Mattheos Koffas 23 Applications of Metabolic Engineering for Natural Drug Discovery .............................................................................................23-1 Yi Tang, Suzanne Ma, and Wladyslaw A. Wojcicki 24 Metabolic Engineering for Alternative Fuels ...............................................24-1 Yandi Dharmadi and Ramon Gonzalez Index .............................................................................................................I–1 77651.indb 7 6/2/09 6:36:41 PM 77651.indb 8 6/2/09 6:36:41 PM Introduction Progression of Biological Synthesis Methods toward commercial Relevance The advent of recombinant DNA in the 1970s brought transformative technologies for the synthesis and manipulation of artificial genetic material. The ability to amplify, cut, and piece together fragments of DNA outside of a cell and to get (or transform) that DNA into a cell of interest resulted in a set of molec- ular cloning tools that enabled the field of genetic engineering. In genetic engineering, foreign DNA that encodes for new or altered functions or traits is inserted into an organism of interest. Many early applications of recombinant DNA technology focused on heterologous protein production in microbial hosts. The first medicine made through recombinant DNA technology that was approved by the United States Federal Drug Administration was the synthesis of synthetic “human” insulin in Escherichia coli. This was an important early application of recombinant DNA technology, as the success of producing a safe and effective synthetic hormone in a bacteria led to the widespread acceptance of the technology and significant resources and funding to be directed to its support and advancement. As the technologies in support of synthesizing and manipulating artificial DNA matured and advanced, so did the applications to which they were applied. The early successful applications of recom- binant DNA technology resulted in alternative routes to the synthesis of medicines, such as insulin, human growth factor, and erythropoietin, vaccines, and even genetically modified organisms, includ- ing crops that exhibit more desirable traits. Technologies were developed for the manipulation of artifi- cial DNA in both prokaryotic and eukaryotic host organisms, including mammalian and plant cells. In addition, inspired by the diversity of natural products, chemicals, and materials synthesized by biologi- cal systems that are observed in the natural world, researchers began to look beyond applications that were limited to the synthesis of a single heterologous protein product in a cellular host to more com- plicated engineering feats. In particular, these new applications focused on the manipulation of sets or combinations of proteins, or enzymes, that acted in conjunction in a cell, within metabolic pathways, to convert energy and precursor chemicals into desired natural and non-natural products. The production of chemicals, materials, and energy through biology presents an alternative to tra- ditional chemical synthesis routes. While the development of chemical synthesis methods for the production of valuable chemicals and small molecule pharmaceuticals is a more mature field and has demonstrated significant successes, many chemicals remain difficult to be synthesized through such strategies, particularly those with many chiral centers. Biological catalysts, or enzymes, have dem- onstrated remarkable adeptness at the synthesis of very complex molecules. In addition, cellular bio- synthesis strategies offer several advantages over traditional chemical synthesis strategies in that the former is often conducted under less harsh conditions, thereby enabling “green” synthesis strategies that are associated with the production of fewer toxic by-products. In addition, cellular biosynthesis ix 77651.indb 9 6/2/09 6:36:41 PM