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Author: Isoken Omosefe Airen
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
We set out to develop and apply a high-throughput cell-free protein synthesis (CFPS) platform that provides functional genomics information for a wide variety of open reading frames (ORFs). We then used this information to improve CFPS yields by 4- to 5-fold, depending on the protein product. With the increasing number of completed genome sequences and ongoing sequencing projects, the post-genomic era has ushered in the promise of complete understanding of biological systems. For such a task, the most important set of information is inarguably the knowledge of the function of each gene product. To lead this endeavor of discerning the properties and functions of the entirety of an organism's genes and gene products, the field of functional genomics has emerged. Functional genomics focuses on dynamic cellular aspects, such as gene transcription, translation, and protein-protein interactions, in attempts to understand the relationship between an organism's genome and its phenotype. Thus, the ultimate goal of such studies is to provide a more complete picture of how biological function arises from the hereditary information of a living system. However, despite this clear interest in analyzing the expression and function of gene products, the development of techniques to address the high-throughput needs of functional genomics has been challenging, given the large diversity of protein functions and physiochemical properties, such as molecular weight and hydrophobicity, as well as the varying expression levels of proteins within a cell. In light of these challenges, we developed a sequential CFPS platform, which is capable of characterizing a variety of diverse proteins in the context of the dynamic metabolic networks that exist in vivo. The first round of expression is directed by PCR-generated expression templates (ETs) and creates an array of cell extracts that are individually enriched with a single target gene product. This round of CFPS is terminated by the selective degradation of the linear DNA templates, and a subsequent round of protein expression is initiated by the addition of a plasmid ET for a reporter protein. The array is then screened to identify gene products that enhanced or inhibited the expression and folding of the reporter. With such a method, we expect that the observations will expand our knowledge of both cell-free and in vivo metabolism, as well as identify key factors and reactions that could potentially lead to improved in vitro transcription, translation and protein folding. CFPS systems offer attractive alternatives to conventional fermentation processes used for protein production. Although improvements in CFPS energetics and reaction conditions have greatly enhanced in vitro protein synthesis, we believe that there are still other issues limiting the productivity of the technology. For this reason, identifying targets that could further improve CFPS is desirable. To validate the developed sequential CFPS protocol, we conducted a genome-wide survey of the well-studied bacterium Escherichia coli (E. coli) to identify soluble gene products that influence the in vitro metabolism. With this method, we identified 139 gene products (79 positive and 60 negative effectors) that influenced the cell-free transcription, translation, and protein folding of our three reporter proteins, as well as the energy metabolism and RNA and protein stability in the CFPS system. Encouragingly, most of the observed effects were consistent with the accepted in vivo metabolic functions of the gene products. However, many were not and required subsequent assays and in-depth literature searches to suggest hypotheses for the in vitro activities of the identified gene products. In many cases, the observations illuminated principles and influences that are unknown, lesser known, or secondary functions that were not expected to influence the CFPS performance. The information from the genome-wide survey was then used to guide modifications of the CFPS system to improve the productivity and duration of in vitro protein synthesis, as well as the efficiency of protein folding. First, fifteen positive effectors were produced and supplemented into the expression reactions in various combinations of the effectors in order to identify cooperative interactions that further enhance system performance. Next, we constructed and evaluated four mutant E. coli strains with chromosomal deletions in non-essential genes that encode negative effectors identified by the genomic survey. We also re-optimized the small molecule metabolite environment in the CFPS reactions. Thus, in the improved in vitro expression system, energy generation, translation initiation and elongation, and protein folding were enhanced; the reaction pH was stabilized; the supplies of specific molecular substrates that are essential for protein synthesis were replenished; and mRNA transcripts were stabilized. With this new system, the total, soluble, and active yields of the several diverse proteins were enhanced by 300 to 400%. The functional genomic analysis of E. coli has greatly broadened our understanding of the biology of the organism. And with the use of species-independent translational leaders that can facilitate cell-free expression (Mureev et al., 2009), our sequential CFPS platform can be used for similar genome-wide surveys of most organisms. In this way, the vast wealth of information available in the sequenced genomes will be utilized, and our knowledge of these biological systems will be significantly improved. Furthermore, the forward, or targeted, metabolic engineering strategy that was used to enhance our CFPS system can be applied to the development and/or improvement of most organism-based in vitro protein expression platforms. These targeted metabolic changes will lead to more rapid and more significant enhancements than traditional improvement strategies, as well as bring us closer to a complete understanding of the biological systems.
Author: Isoken Omosefe Airen
Publisher:
ISBN:
Category :
Languages : en
Pages :
Get Book Here
Book Description
We set out to develop and apply a high-throughput cell-free protein synthesis (CFPS) platform that provides functional genomics information for a wide variety of open reading frames (ORFs). We then used this information to improve CFPS yields by 4- to 5-fold, depending on the protein product. With the increasing number of completed genome sequences and ongoing sequencing projects, the post-genomic era has ushered in the promise of complete understanding of biological systems. For such a task, the most important set of information is inarguably the knowledge of the function of each gene product. To lead this endeavor of discerning the properties and functions of the entirety of an organism's genes and gene products, the field of functional genomics has emerged. Functional genomics focuses on dynamic cellular aspects, such as gene transcription, translation, and protein-protein interactions, in attempts to understand the relationship between an organism's genome and its phenotype. Thus, the ultimate goal of such studies is to provide a more complete picture of how biological function arises from the hereditary information of a living system. However, despite this clear interest in analyzing the expression and function of gene products, the development of techniques to address the high-throughput needs of functional genomics has been challenging, given the large diversity of protein functions and physiochemical properties, such as molecular weight and hydrophobicity, as well as the varying expression levels of proteins within a cell. In light of these challenges, we developed a sequential CFPS platform, which is capable of characterizing a variety of diverse proteins in the context of the dynamic metabolic networks that exist in vivo. The first round of expression is directed by PCR-generated expression templates (ETs) and creates an array of cell extracts that are individually enriched with a single target gene product. This round of CFPS is terminated by the selective degradation of the linear DNA templates, and a subsequent round of protein expression is initiated by the addition of a plasmid ET for a reporter protein. The array is then screened to identify gene products that enhanced or inhibited the expression and folding of the reporter. With such a method, we expect that the observations will expand our knowledge of both cell-free and in vivo metabolism, as well as identify key factors and reactions that could potentially lead to improved in vitro transcription, translation and protein folding. CFPS systems offer attractive alternatives to conventional fermentation processes used for protein production. Although improvements in CFPS energetics and reaction conditions have greatly enhanced in vitro protein synthesis, we believe that there are still other issues limiting the productivity of the technology. For this reason, identifying targets that could further improve CFPS is desirable. To validate the developed sequential CFPS protocol, we conducted a genome-wide survey of the well-studied bacterium Escherichia coli (E. coli) to identify soluble gene products that influence the in vitro metabolism. With this method, we identified 139 gene products (79 positive and 60 negative effectors) that influenced the cell-free transcription, translation, and protein folding of our three reporter proteins, as well as the energy metabolism and RNA and protein stability in the CFPS system. Encouragingly, most of the observed effects were consistent with the accepted in vivo metabolic functions of the gene products. However, many were not and required subsequent assays and in-depth literature searches to suggest hypotheses for the in vitro activities of the identified gene products. In many cases, the observations illuminated principles and influences that are unknown, lesser known, or secondary functions that were not expected to influence the CFPS performance. The information from the genome-wide survey was then used to guide modifications of the CFPS system to improve the productivity and duration of in vitro protein synthesis, as well as the efficiency of protein folding. First, fifteen positive effectors were produced and supplemented into the expression reactions in various combinations of the effectors in order to identify cooperative interactions that further enhance system performance. Next, we constructed and evaluated four mutant E. coli strains with chromosomal deletions in non-essential genes that encode negative effectors identified by the genomic survey. We also re-optimized the small molecule metabolite environment in the CFPS reactions. Thus, in the improved in vitro expression system, energy generation, translation initiation and elongation, and protein folding were enhanced; the reaction pH was stabilized; the supplies of specific molecular substrates that are essential for protein synthesis were replenished; and mRNA transcripts were stabilized. With this new system, the total, soluble, and active yields of the several diverse proteins were enhanced by 300 to 400%. The functional genomic analysis of E. coli has greatly broadened our understanding of the biology of the organism. And with the use of species-independent translational leaders that can facilitate cell-free expression (Mureev et al., 2009), our sequential CFPS platform can be used for similar genome-wide surveys of most organisms. In this way, the vast wealth of information available in the sequenced genomes will be utilized, and our knowledge of these biological systems will be significantly improved. Furthermore, the forward, or targeted, metabolic engineering strategy that was used to enhance our CFPS system can be applied to the development and/or improvement of most organism-based in vitro protein expression platforms. These targeted metabolic changes will lead to more rapid and more significant enhancements than traditional improvement strategies, as well as bring us closer to a complete understanding of the biological systems.
Author: James R. Swartz
Publisher: Springer Science & Business Media
ISBN: 3642593372
Category : Science
Languages : en
Pages : 213
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Book Description
Cell-free protein synthesis is coming of age! Motivated by an escalating need for efficient protein synthesis and empowered by readily accessible cell-free protein synthesis kits, the technology is expanding both in the range of feasible proteins and in the ways that proteins can be labeled and modified. This volume follows "Cell-Free Translation Systems", edited by Professor Alexander S. Spirin in 2002. Since then, an impressive collection of new work has emerged that demonstrates a substantial expansion of capability. In this volume, we show that proteins now can be efficiently produced using PCR products as DNA templates and that even membrane proteins and proteins with multiple disulfide proteins are obtained at high yields. Many additional advances are also presented. It is an exciting time for protein synthesis technology.
Author: Alexander S. Spirin
Publisher: John Wiley & Sons
ISBN: 9783527316496
Category : Science
Languages : en
Pages : 272
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Book Description
With its detailed description of membrane protein expression, high-throughput and genomic-scale expression studies, both on the analytical and the preparative scale, this book covers the latest advances in the field. The step-by-step protocols and practical examples given for each method constitute practical advice for beginners and experts alike.
Author: Kirill Alexandrov
Publisher: Humana
ISBN: 9781493962549
Category : Science
Languages : en
Pages : 0
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Book Description
Cell-free protein expression promises to narrow the technological gap between DNA and protein technologies and provide a platform for broad application of synthetic biology principles in the Life Sciences. It is a rapid and high throughput methodology for the conversion of DNA encoded genetic information into protein-mediated biochemical activities. Cell-Free Protein Synthesis: Methods and Protocols brings together the key opinion leaders of cell-free technology development and provides case studies and detailed protocols for the application of cell-free methodology. Chapters cover the main directions in the development of cell-free technologies including several recently developed cell-free systems, as well as a number of applications of cell-free systems ranging from discovery of biofuel enzymes to in vitro assembly of viruses. Written in the successful Methods in Molecular Biology series format, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible protocols, and notes on troubleshooting and avoiding known pitfalls. Authoritative and easily accessible, Cell-Free Protein Synthesis: Methods and Protocols seeks to serve a wide variety of scientists with its well-honed methodologies.
Author: National Research Council
Publisher: National Academies Press
ISBN: 0309180716
Category : Science
Languages : en
Pages : 102
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Book Description
The U.S. Department of Energy (DOE) promotes scientific and technological innovation to advance the national, economic, and energy security of the United States. Recognizing the potential of microorganisms to offer new energy alternatives and remediate environmental contamination, DOE initiated the Genomes to Life program, now called Genomics: GTL, in 2000. The program aims to develop a predictive understanding of microbial systems that can be used to engineer systems for bioenergy production and environmental remediation, and to understand carbon cycling and sequestration. This report provides an evaluation of the program and its infrastructure plan. Overall, the report finds that GTL's research has resulted in and promises to deliver many more scientific advancements that contribute to the achievement of DOE's goals. However, the DOE's current plan for building four independent facilities for protein production, molecular imaging, proteome analysis, and systems biology sequentially may not be the most cost-effective, efficient, and scientifically optimal way to provide this infrastructure. As an alternative, the report suggests constructing up to four institute-like facilities, each of which integrates the capabilities of all four of the originally planned facility types and focuses on one or two of DOE's mission goals. The alternative infrastructure plan could have an especially high ratio of scientific benefit to cost because the need for technology will be directly tied to the biology goals of the program.
Author: Sukanta Mondal
Publisher: Academic Press
ISBN: 0128206128
Category : Science
Languages : en
Pages : 340
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Book Description
Advances in Animal Genomics provides an outstanding collection of integrated strategies involving traditional and modern - omics (structural, functional, comparative and epigenomics) approaches and genomics-assisted breeding methods which animal biotechnologists can utilize to dissect and decode the molecular and gene regulatory networks involved in the complex quantitative yield and stress tolerance traits in livestock. Written by international experts on animal genomics, this book explores the recent advances in high-throughput, next-generation whole genome and transcriptome sequencing, array-based genotyping, and modern bioinformatics approaches which have enabled to produce huge genomic and transcriptomic resources globally on a genome-wide scale. This book is an important resource for researchers, students, educators and professionals in agriculture, veterinary and biotechnology sciences that enables them to solve problems regarding sustainable development with the help of current innovative biotechnologies. Integrates basic and advanced concepts of animal biotechnology and presents future developments Describes current high-throughput next-generation whole genome and transcriptome sequencing, array-based genotyping, and modern bioinformatics approaches for sustainable livestock production Illustrates integrated strategies to dissect and decode the molecular and gene regulatory networks involved in complex quantitative yield and stress tolerance traits in livestock Ensures readers will gain a strong grasp of biotechnology for sustainable livestock production with its well-illustrated discussion
Author: National Research Council
Publisher: National Academies Press
ISBN: 0309038405
Category : Science
Languages : en
Pages : 128
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Book Description
There is growing enthusiasm in the scientific community about the prospect of mapping and sequencing the human genome, a monumental project that will have far-reaching consequences for medicine, biology, technology, and other fields. But how will such an effort be organized and funded? How will we develop the new technologies that are needed? What new legal, social, and ethical questions will be raised? Mapping and Sequencing the Human Genome is a blueprint for this proposed project. The authors offer a highly readable explanation of the technical aspects of genetic mapping and sequencing, and they recommend specific interim and long-range research goals, organizational strategies, and funding levels. They also outline some of the legal and social questions that might arise and urge their early consideration by policymakers.
Author: Haig H. Kazazian
Publisher: FT Press
ISBN:
Category : Business planning
Languages : en
Pages : 287
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Book Description
Annotation What we now know about mobile DNA--and the substantial roles it plays in humans, animals, and plants. & bull; & bull;Mobile DNA accounts for more than half of our genome: This book explains the important role it plays in shaping evolutionary change. & bull;A rich, thorough, and accessible introduction for all serious students, practitioners, and researchers in human and medical genetics, molecular biology, or evolutionary biology. & bull;By one of the field's leading researchers, Dr. Haig Kazazian. This book thoroughly reviews our current scientific understanding of the significant role that mobile genetic elements play in the evolution and function of genomes and organisms--from plants and animals to humans. Highly regarded geneticist Haig Kazazian offers an accessible intellectual history of the field's research strategies and concerns, explaining how advances opened up new questions, and how new tools and capabilities have encouraged progress in the field. Kazazian introduces the key strategies and approaches taken in leading laboratories (including his own) to gain greater insight into the large proportion of our genome that derives from mobile genetic elements, including viruses, plasmids, and transposons. He also presents intriguing insights into long-term research strategies that may lead to an even deeper understanding.
Author: Bruce R. Korf
Publisher: John Wiley & Sons
ISBN: 1118537661
Category : Medical
Languages : en
Pages : 280
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Book Description
This fourth edition of the best-selling textbook, Human Genetics and Genomics, clearly explains the key principles needed by medical and health sciences students, from the basis of molecular genetics, to clinical applications used in the treatment of both rare and common conditions. A newly expanded Part 1, Basic Principles of Human Genetics, focuses on introducing the reader to key concepts such as Mendelian principles, DNA replication and gene expression. Part 2, Genetics and Genomics in Medical Practice, uses case scenarios to help you engage with current genetic practice. Now featuring full-color diagrams, Human Genetics and Genomics has been rigorously updated to reflect today’s genetics teaching, and includes updated discussion of genetic risk assessment, “single gene” disorders and therapeutics. Key learning features include: Clinical snapshots to help relate science to practice 'Hot topics' boxes that focus on the latest developments in testing, assessment and treatment 'Ethical issues' boxes to prompt further thought and discussion on the implications of genetic developments 'Sources of information' boxes to assist with the practicalities of clinical research and information provision Self-assessment review questions in each chapter Accompanied by the Wiley E-Text digital edition (included in the price of the book), Human Genetics and Genomics is also fully supported by a suite of online resources at www.korfgenetics.com, including: Factsheets on 100 genetic disorders, ideal for study and exam preparation Interactive Multiple Choice Questions (MCQs) with feedback on all answers Links to online resources for further study Figures from the book available as PowerPoint slides, ideal for teaching purposes The perfect companion to the genetics component of both problem-based learning and integrated medical courses, Human Genetics and Genomics presents the ideal balance between the bio-molecular basis of genetics and clinical cases, and provides an invaluable overview for anyone wishing to engage with this fast-moving discipline.
Author: Mousumi Debnath
Publisher: Springer Science & Business Media
ISBN: 9048132614
Category : Medical
Languages : en
Pages : 527
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Book Description
A rapid development in diverse areas of molecular biology and genetic engineering resulted in emergence of variety of tools. These tools are not only applicable to basic researches being carried out world over, but also exploited for precise detection of abnormal conditions in plants, animals and human body. Although a basic researcher is well versed with few techniques used by him/her in the laboratory, they may not be well acquainted with methodologies, which can be used to work out some of their own research problems. The picture is more blurred when the molecular diagnostic tools are to be used by physicians, scientists and technicians working in diagnostic laboratories in hospitals, industry and academic institutions. Since many of them are not trained in basics of these methods, they come across several gray areas in understanding of these tools. The accurate application of molecular diagnostic tools demands in depth understanding of the methodology for precise detection of the abnormal condition of living body. To meet the requirements of a good book on molecular diagnostics of students, physicians, scientists working in agricultural, veterinary, medical and pharmaceutical sciences, it needs to expose the reader lucidly to: Give basic science behind commonly used tools in diagnostics Expose the readers to detailed applications of these tools and Make them aware the availability of such diagnostic tools The book will attract additional audience of pathologists, medical microbiologists, pharmaceutical sciences, agricultural scientists and veterinary doctors if the following topics are incorporated at appropriate places in Unit II or separately as a part of Unit-III in the book. Molecular diagnosis of diseases in agricultural crops Molecular diagnosis of veterinary diseases. Molecular epidemiology, which helps to differentiate various epidemic strains and sources of disease outbreaks. Even in different units of the same hospital, the infections could be by different strains of the same species and the information becomes valuable for infection control strategies. Drug resistance is a growing problem for bacterial, fungal and parasitic microbes and the molecular biology tools can help to detect the drug resistance genes without the cultivation and in vitro sensitivity testing. Molecular diagnostics offers faster help in the selection of the proper antibiotic for the treatment of tuberculosis, which is a major problem of the in the developing world. The conventional culture and drug sensitivity testing of tuberculosis bacilli is laborious and time consuming, whereas molecular diagnosis offers rapid drug resistant gene detection even from direct clinical samples. The same approach for HIV, malaria and many more diseases needs to be considered. Molecular diagnostics in the detection of diseases during foetal life is an upcoming area in the foetal medicine in case of genetic abnormalities and infectious like TORCH complex etc. The book will be equally useful to students, scientists and professionals working in the field of molecular diagnostics.
