Dynamics Problem Recognition Biological (18 results)

Hardcover. Condition: Très bon. Ancien livre de bibliothèque avec équipements. Edition 1996. Ammareal reverse jusqu'à 15% du prix net de cet article à des organisations caritatives. ENGLISH DESCRIPTION Book Condition: Used, Very good. Former library book. Edition 1996. Ammareal gives back up to 15% of this item's net price to charity organizations.

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Taschenbuch. Condition: Neu. Druck auf Anfrage Neuware - Printed after ordering - From within complex structures of organisms and cells down to the molecular level, biological processes all involve movement. Muscular fibers slide on each other to activate the muscle, as polymerases do along nucleic acids for replicating and transcribing the genetic material. Cells move and organize themselves into organs by recognizing each other through macromolecular surface-specific interactions. These recognition processes involve the mu tual adaptation of structures that rely on their flexibility. All sorts of conformational changes occur in proteins involved in through-membrane signal transmission, showing another aspect of the flexibility of these macromolecules. The movement and flexibility are inscribed in the polymeric nature of essential biological macromolecules such as proteins and nucleic acids. For instance, the well-defined structures formed by the long protein chain are held together by weak noncovalent interac tions that design a complex potential well in which the protein floats, permanently fluctuating between several micro- or macroconformations in a wide range of frequencies and ampli tudes. The inherent mobility of biomolecular edifices may be crucial to the adaptation of their structures to particular functions. Progress in methods for investigating macromolecular structures and dynamics make this hypothesis not only attractive but more and more testable.

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Condition: New. Protein Structures: The Cooperative Substructure of Protein Molecules Y. Bai, S.W. Englander. Protein Folding: Approaches to the Determination of More Accurate Crossrelaxation Rates and the Effects of Improved Distance Constraints on Protein Solution Struc.

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Buch. Condition: Neu. Neuware - Protein Structures: The Cooperative Substructure of Protein Molecules; Y. Bai, S.W. Englander. Protein Folding: Approaches to the Determination of More Accurate Crossrelaxation Rates and the Effects of Improved Distance Constraints on Protein Solution Structures; G.C. Hoogstraten, J.L. Markley. Protein Interactions: How Conventional Antigens and Superantigens Interact with the Human MHC Class II Molecule HLADR1; T. Jardetzky. Nucleic Acids and Nucleic Acid-Protein Interactions: Stimulating the Dynamics of the DNA Double Helix in Solution; M. Hirshberg, M. Levitt. Membranes: Applications of Multidimensional Solidstate NMR Spectroscopy to Membrane Proteins; A. Ramamoorthy, et al. Carbohydrate Structure: Conformation, Mobility, and Function of the N-linked Glycan in the Adhesion Domain of Human CD2; G. Wagner, et al. Abstracts from Course: Protein Structures Abstracts: Solution Structure of the ETS-domain from Murine Ets1: A Winged-helix-turn-helix Motif; L.W. Donaldson. Protein Interactions Abstracts: Designing Mutant Hemoglobins; M. Madrid, et al. Nucleic Acids and Nucleic Acid-Protein Interactions Abstracts: A Study on the Dynamics of a DNA Binding Protein; L.M. Horstink, et al. Poster Abstracts. 55 additional articles. Index.

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Taschenbuch. Condition: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -From within complex structures of organisms and cells down to the molecular level, biological processes all involve movement. Muscular fibers slide on each other to activate the muscle, as polymerases do along nucleic acids for replicating and transcribing the genetic material. Cells move and organize themselves into organs by recognizing each other through macromolecular surface-specific interactions. These recognition processes involve the mu tual adaptation of structures that rely on their flexibility. All sorts of conformational changes occur in proteins involved in through-membrane signal transmission, showing another aspect of the flexibility of these macromolecules. The movement and flexibility are inscribed in the polymeric nature of essential biological macromolecules such as proteins and nucleic acids. For instance, the well-defined structures formed by the long protein chain are held together by weak noncovalent interac tions that design a complex potential well in which the protein floats, permanently fluctuating between several micro- or macroconformations in a wide range of frequencies and ampli tudes. The inherent mobility of biomolecular edifices may be crucial to the adaptation of their structures to particular functions. Progress in methods for investigating macromolecular structures and dynamics make this hypothesis not only attractive but more and more testable. 324 pp. Englisch.

Condition: New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. Proceedings of a NATO ASI and of the International School on Biological Magnetic Resonance Second Course on Dynamics and the Problem of Recognition in Biological Macromolecules held in Erice, Italy, May 19-30, 1995. From within complex structures of .

Taschenbuch. Condition: Neu. This item is printed on demand - Print on Demand Titel. Neuware -From within complex structures of organisms and cells down to the molecular level, biological processes all involve movement. Muscular fibers slide on each other to activate the muscle, as polymerases do along nucleic acids for replicating and transcribing the genetic material. Cells move and organize themselves into organs by recognizing each other through macromolecular surface-specific interactions. These recognition processes involve the mu tual adaptation of structures that rely on their flexibility. All sorts of conformational changes occur in proteins involved in through-membrane signal transmission, showing another aspect of the flexibility of these macromolecules. The movement and flexibility are inscribed in the polymeric nature of essential biological macromolecules such as proteins and nucleic acids. For instance, the well-defined structures formed by the long protein chain are held together by weak noncovalent interac tions that design a complex potential well in which the protein floats, permanently fluctuating between several micro- or macroconformations in a wide range of frequencies and ampli tudes. The inherent mobility of biomolecular edifices may be crucial to the adaptation of their structures to particular functions. Progress in methods for investigating macromolecular structures and dynamics make this hypothesis not only attractive but more and more testable.Libri GmbH, Europaallee 1, 36244 Bad Hersfeld 324 pp. Englisch.

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