Biochemistry: International Edition
Autor Christopher K. Mathews, Kensal E. Van Holde, Kevin G. Ahernen Limba Engleză Mixed media product – 31 oct 1999
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Specificații
ISBN-13: 9780201702354
ISBN-10: 0201702355
Pagini: 1200
Greutate: 2.49 kg
Ediția:3Nouă
Editura: Pearson Education
Colecția Pearson Education
Locul publicării:Upper Saddle River, United States
ISBN-10: 0201702355
Pagini: 1200
Greutate: 2.49 kg
Ediția:3Nouă
Editura: Pearson Education
Colecția Pearson Education
Locul publicării:Upper Saddle River, United States
Cuprins
I. THE REALM OF BIOCHEMISTRY.
1. The Scope of Biochemistry.
2. The Matrix of Life: Weak Interactions in an Aqueous Environment.
3. The Energetics of Life.
II. MOLECULAR ARCHITECTURE OF LIVING MATTER.
4. Nucleic Acids.
5. Introduction to Proteins: The Primary Level of Protein Structure.
6. The Three- Dimensional Structure of Proteins.
7. Protein Function and Evolution.
8. Proteins in Motion: Contractile Systems and Molecular Motors.
9. Carbohydrates.
10. Lipids, Membranes, and Cellular Transport.
III. DYNAMICS OF LIFE: CATALYSIS AND CONTROL OF BIOCHEMICAL REACTIONS.
11. Enzymes: Biological Catalysts.
12. Introduction to Metabolism.
IV. DYNAMICS OF LIFE: ENERGY, BIOSYNTHESIS, AND UTILIZATION OF PRECURSORS.
13. Carbohydrate Metabolism I: Anaerobic Processes in Generating Metabolic Energy.
14. Oxidative Processes: Citric Acid Cycle and Pentose Phosphate Pathway.
15. Electron Transport, Oxidative Phosphorylation, and Oxygen Metabolism.
16. Carbohydrate Metabolism II: Biosynthesis.
17. Photosynthesis.
18. Lipid Metabolism I: Fatty Acids, Triacylglycerols, and Lipoproteins.
19. Lipid Metabolism II: Membrane Lipids, Steroids, Isoprenoids, and Eicosanoids.
20. Metabolism of Nitrogenous Compounds: Principles of Biosynthesis, Utilization, and Turnover.
21. Metabolism of Nitrogenous Compounds: Amino Acids, Porphyrins, and Neurotransmitters.
22. Nucleotide Metabolism.
23. Metabolic Coordination, Metabolic Control, and Signal Transduction
V. INFORMATION.
24. Information Copying: Replication.
25. Information Restructuring: Restriction, Repair, Recombination, Rearrangement, and Amplification.
26. Information Readout: Transcription.
27. Information Decoding: Translation.
28. Eukaryotic Genes and Their Expression.
Answers to Problems.
Glossary.
Index.
1. The Scope of Biochemistry.
2. The Matrix of Life: Weak Interactions in an Aqueous Environment.
3. The Energetics of Life.
II. MOLECULAR ARCHITECTURE OF LIVING MATTER.
4. Nucleic Acids.
5. Introduction to Proteins: The Primary Level of Protein Structure.
6. The Three- Dimensional Structure of Proteins.
7. Protein Function and Evolution.
8. Proteins in Motion: Contractile Systems and Molecular Motors.
9. Carbohydrates.
10. Lipids, Membranes, and Cellular Transport.
III. DYNAMICS OF LIFE: CATALYSIS AND CONTROL OF BIOCHEMICAL REACTIONS.
11. Enzymes: Biological Catalysts.
12. Introduction to Metabolism.
IV. DYNAMICS OF LIFE: ENERGY, BIOSYNTHESIS, AND UTILIZATION OF PRECURSORS.
13. Carbohydrate Metabolism I: Anaerobic Processes in Generating Metabolic Energy.
14. Oxidative Processes: Citric Acid Cycle and Pentose Phosphate Pathway.
15. Electron Transport, Oxidative Phosphorylation, and Oxygen Metabolism.
16. Carbohydrate Metabolism II: Biosynthesis.
17. Photosynthesis.
18. Lipid Metabolism I: Fatty Acids, Triacylglycerols, and Lipoproteins.
19. Lipid Metabolism II: Membrane Lipids, Steroids, Isoprenoids, and Eicosanoids.
20. Metabolism of Nitrogenous Compounds: Principles of Biosynthesis, Utilization, and Turnover.
21. Metabolism of Nitrogenous Compounds: Amino Acids, Porphyrins, and Neurotransmitters.
22. Nucleotide Metabolism.
23. Metabolic Coordination, Metabolic Control, and Signal Transduction
V. INFORMATION.
24. Information Copying: Replication.
25. Information Restructuring: Restriction, Repair, Recombination, Rearrangement, and Amplification.
26. Information Readout: Transcription.
27. Information Decoding: Translation.
28. Eukaryotic Genes and Their Expression.
Answers to Problems.
Glossary.
Index.
Notă biografică
Christopher K. Mathews is Distinguished Professor and Chairman of the Department of Biochemistry and Biophysics at Oregon State University. Dr. Mathews was an Eleanor Roosevelt International Cancer Fellow at the Karolinska Institute in Stockholm in 1984-85 and Tage Erlander Guest Professor at Stockholm University in 1994-95. He has published several books and more than 125 scientific papers dealing with molecular virology, metabolic regulation, nucleotide enzymology, and biochemical genetics.
K.E. van Holde is Distinguished Professor Emeritus of Biophysics and Biochemistry at Oregon State University. Dr. van Holde's major research interest is the structure of chromatin; his work resulted in theaward of an American Cancer Society Research Professorship in 1977 and hiselection to the National Academy of Sciences in 1989. He has received Guggenheim, NSF, and EMBO Fellowships and is the author of two books and more than 175 scientific papers.
Kevin Ahern is a Senior Instructor in the Department of Biochemistry and Biophysics at Oregon State University, where he pioneered the development of Web-based courses for teaching biochemistry. He is a contributing editor to Science magazine and a columnist for Genetic Engineering News. He has edited two books, Biotechnology Software Reports - Computer Applications for Molecular Biologists and The Biotechnology Software Directory, A Buyer's Guide, and is the founder of DaVinci Press Ink, a scientific software consulting firm. Dr. Ahern's teaching experience includes undergraduate and graduate biochemistry courses.
K.E. van Holde is Distinguished Professor Emeritus of Biophysics and Biochemistry at Oregon State University. Dr. van Holde's major research interest is the structure of chromatin; his work resulted in theaward of an American Cancer Society Research Professorship in 1977 and hiselection to the National Academy of Sciences in 1989. He has received Guggenheim, NSF, and EMBO Fellowships and is the author of two books and more than 175 scientific papers.
Kevin Ahern is a Senior Instructor in the Department of Biochemistry and Biophysics at Oregon State University, where he pioneered the development of Web-based courses for teaching biochemistry. He is a contributing editor to Science magazine and a columnist for Genetic Engineering News. He has edited two books, Biotechnology Software Reports - Computer Applications for Molecular Biologists and The Biotechnology Software Directory, A Buyer's Guide, and is the founder of DaVinci Press Ink, a scientific software consulting firm. Dr. Ahern's teaching experience includes undergraduate and graduate biochemistry courses.
Caracteristici
- NEW - New accompanying media resources. Created by new co-author, Kevin Ahern, a Web site and CD-ROMs provide a valuable resource for students and instructors. Includes animations of difficult processes, maps of metabolic pathways with links to pertinent enzymes and intermediates, diagnostic quizzes, structures of molecules described in the text, an expanded Tools section with links to online techniques and databases used by biochemists, medical applications related to biochemical topics covered in the text, links to important biomedical sites, and more. Pg.___
- NEW - Keeping current with today's discoveries. This edition is thoroughly updated with the latest information, perspectives, and techniques in biochemistry. Examples include expanded discussion of protein folding and chaperone proteins (Chapter 6); molecular motors (Chapter 8); structures of mitochondrial respiratory complexes (Chapter 15); reactive oxygen species and human disease (Chapter 15); biochemical insights into obesity (Chapter 18); folic acid, vitamin B12, and the heart (Chapter 20); neurotransmitters and psychopharmacology (Chapter 21), new signal transduction pathways (Chapter 23); structures and mechanisms of DNA polymerases (Chapter 24); and eukaryotic gene expression (Chapter 28). Pg.___
- NEW - Enhanced accessibility while maintaining rigor. Bioenergetics introduced in Chapter 3 (i.e., the role of ATP as energy currency) is now covered later in the text in Chapter 12, removing some redundancy and enhancing accessibility. Each topic in the text is now introduced with an overview that outlines the material to be covered and highlights essential points. Pg.___
- NEW - Updated "Tools" of Biochemistry sections. A new section has been added on methods for detecting and analyzing protein-protein interactions. Modern variants of older techniques have been added, such as the sections on laser scanning confocal microscopy (Chapter 1) and the synthesis of combinatorial arrays of peptides (Chapter 5). The section on mass spectrometry (Chapter 6) has been expanded to reflect its growing importance and versatility. All Tools sections are supplemented with exercises, demonstrations, and links on the Web site. Pg.___
- NEW - More life science applications. The number of real-life clinical examples have been increased to include such topics as ribozymes as antiviral drugs (Chapter 11), dopamine receptors and drug addiction (Chapter 21), and telomerase and cancer (Chapter 28). Pg.___
- NEW - New problems test understanding. Most chapters include two to four new quantitative and discussion-type questions, with brief answers to all problems provided in the appendix. Pg.___
- NEW - Remarkable artwork. Many illustrations summarize individual topics and each chapter's art forms a coherent story that augments the textual presentation and allows students to easily review the content. Pg.___
- Complex metabolic pathways are presented step by step: introduction, followed by an overview and then details, and ending with reiteration of the overview and a discussion of regulation. Pg.___
- Concept statements in the margins throughout each chapter identify and summarize key ideas. Pg.___
- Summaries complement the introductory overviews and concept statements by organizing important concepts into a coherent framework at the end of each chapter. Pg.___