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Protein folding: Diverse methods yield clues
August 07, 2009Rice University physicists have written the next chapter in an innovative approach for studying the forces that shape proteins -- the biochemical workhorses of all living things.
New research featured on the cover of today's issue of the Journal of Physical Chemistry illustrates the value of studying proteins with a new method that uses the tools of nanotechnology to grab a single molecule and pull it apart. The new method helps scientists measure the forces that hold proteins together. The new study contrasted the findings from Rice's method with a different approach that relies on chemical reactions.
Over the past decades, scientists have discovered that misfolded proteins play an important but mysterious role in diseases like Alzheimer's and Parkinson's. As a result, more laboratories like Kiang's are studying how proteins fold and misfold in the hopes of finding clues that could lead to new treatments.
Kiang's team specializes in studying the forces that hold protein strands together. Her group uses atomic force microscopes (AFM), which operate much like phonograph players. The AFM has a needle that's suspended from one end of a cantilevered arm. The needle bobs up and down on the arm, randomly grabbing and lifting proteins. By measuring exactly how much force it takes to pull the strands apart, Kiang's group can learn important clues about the protein's behavior.
Kiang's work was recognized in Small Times magazine's 2007 "Best of Small Tech Awards," but it's not the only way to study protein folding. Other groups use chemicals to determine how much energy it takes to unfold proteins, and Kiang's latest paper looks at similarities and differences between the two methods.
"The chemical denaturant method gives very accurate information about the folded and unfolded state of the protein, and our method gives important information about what happens in between," Kiang said.
Proteins are the workhorses of biology. Each protein is a string of amino acids that are attached end to end, like a strand of pearls. The order of the amino acids comes from DNA blueprints, but the order itself doesn't tell scientists what the protein is designed to do. That's because each protein folds in upon itself shortly after its made, much like a strand of pearls curls up as it's dropped into someone's palm.
Unlike the pearls, which might fall this way or that depending upon how they're dropped, proteins fold the same way every time. That's important, because when they misfold, they cannot function properly and in some cases can make people sick.
"This is fundamental research, but it is very important," Kiang said. "We need to answer to these fundamental questions in order to better understand how protein folds correctly, which affects people's health."
Rice University
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Lectures On Statistical Physics And Protein Folding by Kerson Huang (Author) This book introduces an approach to protein folding from the point of view of kinetic theory. There is an abundance of data on protein folding, but few proposals are available on the mechanism driving the process. Here, presented for the first time, are suggestions on possible research directions, as developed by the author in collaboration with C C Lin. The first half of this invaluable book contains a concise but relatively complete review of relevant topics in statistical mechanics and kinetic theory. It includes standard topics such as thermodynamics, the Maxwell–Boltzmann distribution, and ensemble theory. Special discussions include the dynamics of phase transitions, and Brownian motion as an illustration of stochastic processes. The second half develops topics in... |
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Protein Folding, Misfolding and Aggregation: Classical Themes and Novel Approaches (RSC Biomolecular Sciences) by Victor Muñoz (Editor) This unique book covers all the modern approaches and the many advances experienced in the field during the last 10 years. There is much emphasis on computational methods and studies of protein aggregation which have really flourished in the last decade. It includes chapters in the areas that have witnessed major developments and written by top experts including: computer simulations of folding, fast folding, single molecule spectroscopy, protein design, aggregation studies (both computational and experimental). |
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Protein Folding by Thomas E. Creighton (Author) The phenomenon of protein folding has become the focus of intense scientific inquiry. Researchers have realised the importance of understanding how proteins adopt their folding conformations, and are developing experimental techniques to attack this problem. , Protein Folding is a report on the current state of this crucial area of research-the 4y experiments, techniques, and implications of recent findings on modem biotechnology and biomedicine. Its authors are the world's leading investigators in this field, including: R M. Richards, Department of Molecular Biophysics and Biochemistry, Yale University - Janet M Thornton, Biomolecular Structure and Modelling Unit, University College,. . London, UK - Peter L Privokv, Institute of Protein Research, Academy of Sciences, Moscow - Martin... |
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Protein Folding Kinetics: Biophysical Methods by Bengt Nölting (Author) Protein Folding Kinetics - Biophysical Methods (2nd Edition) gives a deep insight into the principles and concepts of the kinetic and structural resolution of fast chemical and biophysical reactions of proteins with emphasis on protein-folding reactions. The study of fast protein-folding reactions and the understanding of the folding paradox have significantly advanced due to the recent development of new biophysical methods which allow not only kinetic resolution in the sub-millisecond time scale but also structural resolution with unprecedented precision. Pathways and structures of early and late folding events and the transition state structures of fast- and ultrafast-folding proteins can now be studied in far more detail. Important techniques include biophysical, chemical, molecular... |
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Protein Structure Prediction (Methods in Molecular Biology) by Mohammed Zaki (Editor), Chris Bystroff (Editor) This book covers elements of both the data-driven comparative modeling approach to structure prediction and also recent attempts to simulate folding using explicit or simplified models. Despite the unsolved mystery of how a protein folds, advances are being made in predicting the interactions of proteins with other molecules, such as small ligands, nucleic acids or other proteins. Also rapidly advancing are the methods for solving the inverse folding problem, the problem of finding a sequence to fit a structure. This book focuses on the various computational methods for prediction, their successes and their limitations, from the perspective of their most well known practitioners. |
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Oxidative Folding of Peptides and Proteins (RSC Biomolecular Sciences) by Luis Moroder (Editor), Johannes Buchner (Editor) This is the first monograph to provide a comprehensive overview of this exciting and rapidly developing area. It offers in-depth insights into the mechanisms of in vivo and in vitro oxidative folding of proteins as well as mono- and multiple-stranded peptides. Procedures applied for laboratory and industrial purposes are also discussed by top experts in the field. |
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Structure and Mechanism in Protein Science: A Guide to Enzyme Catalysis and Protein Folding by Alan Fersht (Author) Fersht’s Structure and Mechanism in Protein Science is a defining exploration of this new era, an expert depiction of the core principles of protein structure, activity, and mechanism as understood and applied today. A thorough recasting of Fersht’s previous text, the book takes a more general look at mechanisms in protein science, emphasizing the unity of concepts in folding and catalysis and the importance of the relationships between basic chemistry, kinetics, thermodynamics, and structure. |
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Protein Structure, Stability, and Interactions (Methods in Molecular Biology) by John W. Shriver (Editor) In the areas of biochemistry and cell biology, characterizations of stability and molecular interactions call for a quantitative approach with a level of precision that matches the fine tuning of these interactions in a living cell. Supporting and up-dating previous Methods in Molecular Biology™ volumes, Protein Structure, Stability, and Interactions approaches its subject with a focus on theory and practical applications for both established methods as well as exciting new procedures. The volume presents an overview of many techniques currently used to study protein stability and interactions, including scanning and titration calorimetry, spectroscopic methods, high field NMR, and analytical ultracentrifugation. As a volume of the highly successful Methods in Molecular Biology™... |
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Prediction of Protein Structures, Functions, and Interactions by Janusz Bujnicki (Author) The growing flood of new experimental data generated by genome sequencing has provided an impetus for the development of automated methods for predicting the functions of proteins that have been deduced by sequence analysis and lack experimental characterization. Prediction of Protein Structures, Functions and Interactions presents a comprehensive overview of methods for prediction of protein structure or function, with the emphasis on their availability and possibilities for their combined use. Methods of modeling of individual proteins, prediction of their interactions, and docking of complexes are put in the context of predicting gene ontology (biological process, molecular function, and cellular component) and discussed in the light of their contribution to the emerging... |
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Introduction to Protein Structure: Second Edition by Carl Branden (Author), John Tooze (Author) Karolinska Institute, Stockholm, Sweden. Textbook on the atomic structures of proteins. For students. Includes colorful illustrations. Previous edition: c1991. Softcover, hardcover also available. |
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