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Organized by Alessandra Carbone ( IHeS, Bures-sur-Yvette, France ) Organized by Misha Gromov ( IHeS, Bures-sur-Yvette, France ) Organized by Fran ois K(r)p s ( CNRS-Genopole-, evry, France ) Organized by Eric Westhof ( Universit(r) Louis-Pasteur, Strasbourg, France ). This proceedings volume explores the pathways and mechanisms by which constituent residues interact and fold to yield native biological macromolecules (catalytic RNA and functional proteins), how ribosomes and other macromolecular complexes self-assemble, and relevant energetics considerations. At the week-long interactive conference, some 20 leading researchers reported their most pertinent results, confronting each other and an audience of more than 150 specialists from a wide range of scientific disciplines, including structural and molecular biology, biophysics, computer science, mathematics, and theoretical physics. The fourteen papers OCo and audience interaction OCo are edited and illustrated versions of the transcribed oral presentations. The proceedings have been selected for coverage in: . OCo Biochemistry & Biophysics Citation Index(tm). OCo Index to Scientific & Technical Proceedings (ISTP CDROM version / ISI Proceedings). OCo CC Proceedings OCo Biomedical, Biological & Agricultural Sciences. Contents: Evolution-Based Genome Analysis: An Alternative to Analyze Folding and Function in Proteins (S Benner); Conformation of Charged Polymers: Polyelectrolytes and Polyampholytes (J-F Joanny); Statistically Derived Rules for RNA Folding (M Zuker); Experimental Approaches to RNA Folding (S Woodson); Some Questions Concerning RNA Folding (F Michel); RNA Folding in Ribosome Assembly (J R Williamson); From RNA Sequences to Folding Pathways and Structures: A Perspective (H Isamber t); An Evolutionary Perspective on the Determinants of Protein Function and Assembly (O Lichtarg e); Some Residues are more Equal than Others: Application to Protein Classification and Structure Prediction (A Kister & I Gelfan d); Structure-Function Relationships in Polymerases (M Delarue); The Protein-Folding Nucleus: From Simple Models to Real Proteins (L Mirn y); Chaperonin-Mediated Protein Folding (D Thirumalai); Virus Assembly and Maturation (J E Johnson); The Animal in the Machine: Is There a Geometric Program in the Genetic Program? (A Danchin). Readership: Researchers, academics and graduate students in structural biology, cellular and molecular biology, biophysics, biochemistry and biomathematics/bioinformatics."
This volume explores experimental and computational approaches to measuring the most widely studied protein assemblies, including condensed liquid phases, aggregates, and crystals. The chapters in this book are organized into three parts: Part One looks at the techniques used to measure protein-protein interactions and equilibrium protein phases in dilute and concentrated protein solutions; Part Two describes methods to measure kinetics of aggregation and to characterize the assembled state; and Part Three details several different computational approaches that are currently used to help researchers understand protein self-assembly. Written in the highly 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 laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Thorough and cutting-edge, Protein Self-Assembly: Methods and Protocols is a valuable resource for researchers who are interested in learning more about this developing field.
The book provides insights into the research of the Kurt Wüthrich laboratories from 1996-2020. During this time period, the technique of nuclear magnetic resonance (NMR) spectroscopy in solution went through several breakthroughs, while maturing into a standard method of structural biology. With the introduction of TROSY (transverse relaxation-optimized spectroscopy), the range of accessible molecular sizes was extended about thirty-fold, and efficient protein structure determination resulted from the demands of the structural genomics initiative. Applications in fundamental biology and biomedicine include studies of prion proteins and prion diseases (TSEs), the SARS-Corona virus proteome, trans-membrane signalling by G protein-coupled receptors (GPCRs), and signal transfer by pheromones.Key publications from the Kurt Wüthrich laboratories are placed in perspective, providing insights into new aspects of NMR spectroscopy in structural biology. In addition to methods development, this includes applications in diverse areas of biological research, such as prion proteins and their role in transmissible spongiform encephalopathies (TSEs), trans-membrane signal transfer by G protein-coupled receptors (GPCRs), structural characterization of the SARS-Corona virus proteome, metabolic-flux profiling in bacterial cultures, and signal transfers by pheromones.
Self-assembly monolayer (SAM) structures of lipids and macromolecules have been found to play an important role in many industrial and biological phenomena. This book describes two procedures, namely the STM and AFM, that are used to study SAMs at solid surfaces. K.S. Birdi examines the SAMs at both liquid and solid surfaces by using the Langmuir monolayer method. This book is intended for researchers, academics and professionals.
Fundamentals of Molecular Structural Biology reviews the mathematical and physical foundations of molecular structural biology. Based on these fundamental concepts, it then describes molecular structure and explains basic genetic mechanisms. Given the increasingly interdisciplinary nature of research, early career researchers and those shifting into an adjacent field often require a "fundamentals" book to get them up-to-speed on the foundations of a particular field. This book fills that niche.
This fully updated and expanded edition addresses the origins of biological and synthetic life from a systems biology perspective.
Each year, Advances in Anesthesia brings you up-to-date with the latest knowledge from the preeminent practitioners in your field. A distinguished editorial board identifies current areas of major progress and controversy and invites specialists from around the world to contribute original articles on these topics.
Labs on Chip: Principles, Design and Technology provides a complete reference for the complex field of labs on chip in biotechnology. Merging three main areas— fluid dynamics, monolithic micro- and nanotechnology, and out-of-equilibrium biochemistry—this text integrates coverage of technology issues with strong theoretical explanations of design techniques. Analyzing each subject from basic principles to relevant applications, this book: Describes the biochemical elements required to work on labs on chip Discusses fabrication, microfluidic, and electronic and optical detection techniques Addresses planar technologies, polymer microfabrication, and process scalability to huge volumes Presents a global view of current lab-on-chip research and development Devotes an entire chapter to labs on chip for genetics Summarizing in one source the different technical competencies required, Labs on Chip: Principles, Design and Technology offers valuable guidance for the lab-on-chip design decision-making process, while exploring essential elements of labs on chip useful both to the professional who wants to approach a new field and to the specialist who wants to gain a broader perspective.
Self-assembling biomaterials: molecular design, characterization and application in biology and medicine provides a comprehensive coverage on an emerging area of biomaterials science, spanning from conceptual designs to advanced characterization tools and applications of self-assembling biomaterials, and compiling the recent developments in the field. Molecular self-assembly, the autonomous organization of molecules, is ubiquitous in living organisms and intrinsic to biological structures and function. Not surprisingly, the exciting field of engineering artificial self-assembling biomaterials often finds inspiration in Biology. More important, materials that self-assemble speak the language of life and can be designed to seamlessly integrate with the biological environment, offering unique engineering opportunities in bionanotechnology. The book is divided in five parts, comprising design of molecular building blocks for self-assembly; exclusive features of self-assembling biomaterials; specific methods and techniques to predict, investigate and characterize self-assembly and formed assemblies; different approaches for controlling self-assembly across multiple length scales and the nano/micro/macroscopic properties of biomaterials; diverse range of applications in biomedicine, including drug delivery, theranostics, cell culture and tissue regeneration. Written by researchers working in self-assembling biomaterials, it addresses a specific need within the Biomaterials scientific community. - Explores both theoretical and practical aspects of self-assembly in biomaterials - Includes a dedicated section on characterization techniques, specific for self-assembling biomaterials - Examines the use of dynamic self-assembling biomaterials