UID:
almahu_9949251540802882
Format:
1 online resource (XVIII, 596 p. 115 illus., 4 illus. in color.)
Edition:
1st ed. 2008.
ISBN:
1-59745-398-6
Series Statement:
Methods in Molecular Biology, 484
Content:
As the emerging field of proteomics continues to expand at an extremely rapid rate, the relative quantification of proteins, targeted by their function, becomes its greatest challenge. Complex analytical strategies have been designed that allow comparative analysis of large proteomes, as well as in depth detection of the core proteome or the interaction network of a given protein of interest. In Functional Proteomics: Methods and Protocols, expert researchers describe the latest protocols being developed to address the problems encountered in high-throughput proteomics projects, with emphasis on the factors governing the technical choices for given applications. The case studies within the volume focus on the following three crucial aspects of the experimental design: 1) the strategy used for the selection, purification and preparation of the sample to be analyzed by mass spectrometry, 2) the type of mass spectrometer used and the type of data to be obtained from it, and 3) the method used for the interpretation of the mass spectrometry data and the search engine used for the identification of the proteins in the different types of sequence data banks available. As a part of the highly successful Methods in Molecular Biology™ series, the chapters compile step-by-step, readily reproducible laboratory protocols, lists of the necessary materials and reagents, and tips on troubleshooting and avoiding known pitfalls. Comprehensive and cutting-edge, Functional Proteomics: Methods and Protocols is an ideal resource for all scientists pursuing this developing field and its multitudinous data.
Note:
Bibliographic Level Mode of Issuance: Monograph
,
A Brief Summary of the Different Types of Mass Spectrometers Used in Proteomics -- Experimental Setups and Considerations to Study Microbial Interactions -- Proteomics -- Plant Proteomics -- Methods for Human CD8+ T Lymphocyte Proteome Analysis -- Label-Free Proteomics of Serum -- Flow Cytometric Analysis of Cell Membrane Microparticles -- Protein Expression Profiling -- Exosomes -- Toward a Full Characterization of the Human 20S Proteasome Subunits and Their Isoforms by a Combination of Proteomic Approaches -- Free-Flow Electrophoresis of the Human Urinary Proteome -- Versatile Screening for Binary Protein-Protein Interactions by Yeast Two-Hybrid Mating -- Native Fractionation: Isolation of Native Membrane-Bound Protein Complexes from Porcine Rod Outer Segments Using Isopycnic Density Gradient Centrifugation -- Mapping of Signaling Pathways by Functional Interaction Proteomics -- Selection of Recombinant Antibodies by Eukaryotic Ribosome Display -- Production of Protein Arrays by Cell-Free Systems -- Nondenaturing Mass Spectrometry to Study Noncovalent Protein/Protein and Protein/Ligand Complexes: Technical Aspects and Application to the Determination of Binding Stoichiometries -- Protein Processing Characterized by a Gel-Free Proteomics Approach -- Identification and Characterization of N-Glycosylated Proteins Using Proteomics -- Protein Analysis -- Data Standards and Controlled Vocabularies for Proteomics -- The PRIDE Proteomics Identifications Database: Data Submission, Query, and Dataset Comparison -- Searching the Protein Interaction Space Through the MINT Database -- PepSeeker: Mining Information from Proteomic Data -- Toward High-Throughput and Reliable Peptide Identification via MS/MS Spectra -- MassSorter: Peptide Mass Fingerprinting Data Analysis -- Database Similarity Searches -- Protein Multiple Sequence Alignment -- Discovering Biomedical Knowledge from the Literature -- Protein Subcellular Localization Prediction Using Artificial Intelligence Technology -- Protein Functional Annotation by Homology -- Designability and Disease -- Prism: Protein-Protein Interaction Prediction by Structural Matching -- Prediction of Protein Interaction Based on Similarity of Phylogenetic Trees -- Large Multiprotein Structures Modeling and Simulation: The Need for Mesoscopic Models -- Dynamic Pathway Modeling of Signal Transduction Networks: A Domain-Oriented Approach.
,
English
Additional Edition:
ISBN 1-58829-971-6
Language:
English
DOI:
10.1007/978-1-59745-398-1
