Recombinant gene expression is the fastest growing area in the study of molecular biology. By the time the Human Genome Project is completed (~2002), several thousand sequences will be known, but the purpose of the resultant expression products will remain a mystery. Gene discovery requires efficient expression systems for determining the structure and function of gene products. Gene Expression Systems covers a variety of promoters and host organisms that researchers can tailor to their specific needs.
While the choices of microbial and eukaryotic expression systems for production of recombinant proteins are many, most researchers in academic and industrial settings do not have ready access to pertinent biological and technical information since it is normally scattered throughout the scientific literature. This book closes the gap by providing information on the general biology of the host organism, a description of the expression platform, a methodological section -- with strains, genetic elements, vectors and special methods, where applicable -- as well as examples of proteins produced with the respective platform. The systems thus described are well balanced by the inclusion of three prokaryotes (two Gram-negatives and one Gram-positive), four yeasts, two filamentous fungi and two higher eukaryotic cell systems -- mammalian and plant cells. Throughout, the book provides valuable practical and theoretical information on the criteria and schemes for selecting the appropriate expression platform, the possibility and practicality of a universal expression vector, and on comparative industrial-scale fermentation, with the production of a recombinant Hepatitis B vaccine chosen as an industrial example. With a foreword by Herbert P. Schweizer, Colorado State University, USA: "As a whole, this book is a valuable and overdue resource for a varied audience. It is a practical guide for academic and industrial researchers who are confronted with the design of the most suitable expression platform for their favorite protein for technical or pharmaceutical purposes. In addition, the book is also a valuable study resource for professors and students in the fields of applied biology and biotechnology."
Gene Expression Systems: Using Nature for the Art of Expression offers detailed information on a wide variety of gene expression systems from an array of organisms. It describes several different types of expression systems including transient, stable, viral, and transgenic systems. Each chapter is written by a leader in the field. The book includes timelines and examples for each expression system, and provides an overview of the future of recombinant protein expression. Provides detailed information on expression systems Covers a variety of promoters and host organisms enabling researchers to tailor protocols to their specific needs Includes timelines and examples Compares pros and cons of each method
1. Expression strategy (Michael Dyson) 2. Protein expression in Escherichia coli (Rosalind Kim) 3. Expression engineering of synthetic antibodies using ribosome display (Matthew DeLisa and Lydia M. Contreras Martinez) 4. Refolding proteins from inclusion bodies (Renaud Vincentelli) 5. Selection of protein variants with improved expression using GFP-derived folding and solubility reporters (Geoffrey Waldo and Stéphanie Cabantous) 6. Protein expression in the wheat germ cell-free system (Yaeta Endo and Tatsuya Sawasaki) 7. Saccharomyces cerevisiae ; A microbial eukaryotic expression system (Christine Lang) 8. Expression of proteins in Pichia pastoris (Geoff and Joan Lin-Cereghino and Wilson Leung) 9. Improved baculovirus expression vectors (Linda King, Richard Hitchman and Robert Possee) 10. Transient transfection of insect cells for rapid expression screening and protein production (Robert Novy et al.) 11. Generation of stable CHO cell lines for protein expression (Zhijian Lu et al.) 12. Transient expression in HEK293-EBNA1 cells (Yves Durocher, Roseanne Tom and Louis Bisson) 13. Nisin- and subtilin-controlled gene expression systems for Gram-positive bacteria (Oscar Kuipers and Jan Kok) 14. Protein expression using lentiviral vectors (Bernard Massie, Renald Gilbert and Sophie Broussau) 15. Expression in mammalian cells using BacMam viruses (Yu-Chen Hu and Hsiao-Ping Lee) List of suppliers;Index
Recombinant Protein Expression, Part B, Volume 660 in the Methods in Enzymology series, highlights new advances in the field with this new volume presenting interesting chapters on Multiplexed analysis protein: Protein interactions of polypeptides translated in Leishmania cell-free system, MultiBac system and its applications, performance and recent, Production of antibodies in Shuffle, Designing hybrid-promoter architectures by engineering cis-acting DNA sites to enhance transcription in yeast, Designing hybrid-promoter architectures by engineering cis-acting DNA sites to deregulate transcription in yeast, Antibody or protein-based vaccine production in plants, Cell-free protein synthesis, Plant-based expression of biologic drugs, and much more. Additional sections cover the Use of native mass spectrometry to guide detergent-based rescue of non-native oligomerization by recombinant proteins, Advancing overexpression and purification of recombinant proteins by pilot optimization through tandem affinity-buffer exchange chromatography online with native mass spectrometry, Method for High-Efficiency Fed-batch cultures of recombinant Escherichia coli, Method to transfer Chinese hamster ovary (CHO) shake flask experiments to the ambr® 250, and Expression of recombinant antibodies in Leishmania tarentolae. Provides the authority and expertise of leading contributors from an international board of authors Presents the latest release in the Methods in Enzymology serial Updated release includes the latest information on Recombinant Protein Expression
With the advent of recombinant DNA technology, expressing heterologous proteins in microorganisms rapidly became the method of choice for their production at laboratory and industrial scale. Bacteria, yeasts and other hosts can be grown to high biomass levels efficiently and inexpensively. Obtaining high yields of recombinant proteins from this material was only feasible thanks to constant research on microbial genetics and physiology that led to novel strains, plasmids and cultivation strategies. Despite the spectacular expansion of the field, there is still much room for progress. Improving the levels of expression and the solubility of a recombinant protein can be quite challenging. Accumulation of the product in the cell can lead to stress responses which affect cell growth. Buildup of insoluble and biologically inactive aggregates (inclusion bodies) lowers the yield of production. This is particularly true for obtaining membrane proteins or high-molecular weight and multi-domain proteins. Also, obtaining eukaryotic proteins in a prokaryotic background (for example, plant or animal proteins in bacteria) results in a product that lack post-translational modifications, often required for functionality. Changing to a eukaryotic host (yeasts or filamentous fungi) may not be a proper solution since the pattern of sugar modifications is different than in higher eukaryotes. Still, many advances in the last couple of decades have provided to researchers a wide variety of strategies to maximize the production of their recombinant protein of choice. Everything starts with the careful selection of the host. Be it bacteria or yeast, a broad list of strains is available for overcoming codon use bias, incorrect disulfide bond formation, protein toxicity and lack of post-translational modifications. Also, a huge catalog of plasmids allows choosing for different fusion partners for improving solubility, protein secretion, chaperone co-expression, antibiotic resistance and promoter strength. Next, controlling culture conditions like temperature, inducer and media composition can bolster recombinant protein production. With this Research Topic, we aim to provide an encyclopedic account of the existing approaches to the expression of recombinant proteins in microorganisms, highlight recent discoveries and analyze the future prospects of this exciting and ever-growing field.
Examines the ways design teams can take a more creative approach to the design and expression of both active and passive environmental control systems. Case Studies from around the world, including many award-winning buildings.
Advances in protein expression technologies have mushroomed in recent years. In this book current and emerging expression technologies are reviewed. Reviews of the molecular genetics of expression systems in various organisms are presented. Topics covered include: Expression of extremophilic proteins; expression in E. coli, Bacillus spp., Saccharomyces cerevisiae, and methylotrophic yeasts; insect cell expression and the baculovirus system; and Chinese Hamster Ovary (CHO) cell lines for large-scale protein production. Also covered are two emerging expression systems, Methylobacterium extorquens AM1 and Caulobacter crescentus.
This reference is a "must-read": It explains how an effective and economically viable enzymatic process in industry is developed and presents numerous successful examples which underline the efficiency of biocatalysis.
While we have known for centuries that facial expressions can reveal what people are thinking and feeling, it is only recently that the face has been studied scientifically for what it can tell us about internal states, social behavior, and psychopathology. Today's widely available, sophisticated measuring systems have allowed us to conduct a wealth of new research on facial behavior that has contributed enormously to our understanding of the relationship between facial expression and human psychology. The chapters in this volume present the state-of-the-art in this research. They address key topics and questions, such as the dynamic and morphological differences between voluntary and involuntary expressions, the relationship between what people show on their faces and what they say they feel, whether it is possible to use facial behavior to draw distinctions among psychiatric populations, and how far research on automating facial measurement has progressed. The book also includes follow-up commentary on all of the original research presented and a concluding integration and critique of all the contributions made by Paul Ekman. As an essential reference for all those working in the area of facial analysis and expression, this volume will be indispensable for a wide range of professionals and students in the fields of psychology, psychiatry, and behavioral medicine.
