Synopses & Reviews
Continuing the tradition of its widely-praised previous editions, The World of the Cell, 7/e, covers some of the most difficult concepts for readers– bioinformatics, bioenergetics, metabolism, enzyme kinetics, thermodynamics, membrane transport, cell signaling, regulatory mechanisms, transcription and translation, signal transduction, and DNA replication and recombination–at the right level of depth and clarity. KEY TOPICS: A Preview of the Cell, The Chemistry of the Cell, The Macromolecules of the Cell, Cells and Organelles, Bioenergetics: The Flow of Energy in the Cell, Enzymes: The Catalysts of Life, Membranes: Their Structure, Function, and Chemistry, Transport Across Membranes: Overcoming the Permeability Barrier, Chemotrophic Energy Metabolism: Glycolysis and Fermentation, Chemotrophic Energy Metabolism: Aerobic Respiration, Phototrophic Energy Metabolism: Photosynthesis, The Endomembrane System and Peroxisomes, Signal Transduction Mechanisms: I. Electrical and Synaptic Signaling in Neurons, Signal Transduction Mechanisms: II. Messengers and Receptors, Cytoskeletal Systems, Cellular Movement: Motility and Contractility, Beyond the Cell: Cell Adhesion, Cell Junctions, and Extracellular Structures, The Structural Basis of Cellular Information: DNA, Chromosomes, and the Nucleus, The Cell Cycle, DNA Replication, and Mitosis, Sexual Reproduction, Meiosis, and Genetic Recombination, Gene Expression: I. The Genetic Code and Transcription, Gene Expression: II. Protein Synthesis and Sorting, The Regulation of Gene Expression, Cancer Cells, Principles and Techniques of Microscopy.
MARKET: For all readers interested in molecular biology.
About the Author
Wayne M. Becker taught cell biology at the University of Wisconsin, Madison until his recent retirement. His interest in textbook writing grew out of notes, outlines, and problem sets that he assembled for his students, culminating in Energy and the Living Cell, a paperback text on bioenergetics published in 1977, and The World of the Cell, the first edition of which appeared in 1986. He earned all his degrees at the University of Wisconsin, Madison. All three degrees are in biochemistry, an orientation that is readily discernible in his textbooks. His research interests have been in plant molecular biology, focused specifically on the regulation of the expression of genes that encode enzymes of the photorespiratory pathway. His interests in teaching, learning, and research have taken him on sabbatical leaves at Harvard University, Edinburgh University, the University of Indonesia, the University of Puerto Rico, Canterbury University in Christchurch, New Zealand, and the Chinese University of Hong Kong. His honors include a Guggenheim Fellowship, a Chancellor's Award for Distinguished Teaching, and a Visiting Scholar Award from the Royal Society of London.
Lewis J. Kleinsmith is an Arthur F. Thurnau Professor Emeritus of Molecular, Cellular, and Developmental biology at the University of Michigan, where he has served on the faculty since receiving his Ph.D. from Rockefeller University in 1968. His teaching experiences have involved courses in introductory biology, cell biology, and cancer biology, and his research interests have included studies of growth control in cancer cells, the role of protein phosphorylation in eukaryotic gene regulation, and the control of gene expression during development. Among his numerous publications, he is the author of Principles of Cell and Molecular Biology, first published in 1988, and several award-winning educational software programs. His honors include a Guggenheim Fellowship, the Henry Russell Award, a Michigan Distinguished Service Award, citations for outstanding teaching from the Michigan Students Association, a Thurnau Professorship, an NIH Plain Language Award, and a Best Curriculum Innovation Award from the EDUCOM Higher Education Software Awards Competition.
Jeff Hardin is a Professor in the Zoology Department at the University of Wisconsin-Madison. His research interests center on how cells migrate and adhere to one another to change the shape of animal embryos. Dr. Hardin's teaching is enhanced by his extensive use of video-microscopy and his Web-based teaching materials, which are used on many campuses in the United States and other countries. As part of his interest in teaching biology, Dr. Hardin has been involved in several teaching initiatives, including being a founding member of the University of Wisconsin system-wide instructional technology initiative known as BioWeb. He is currently faculty director of the Biology Core Curriculum, a four-semester honors biology sequence for undergraduates. His teaching awards include a Lily Teaching Fellowship and a National Science Foundation Young Investigator Award.
Gregory Paul Bertoni, the newest member of the author team, has been active in teaching and research for over 20 years. He earned a Ph.D. in Cellular and Molecular Biology from the University of Wisconsin-Madison, where his teaching experiences included introductory and graduate-level biochemistry, sophomore cell biology, and plant physiology. He also helped to develop a new course entitled “Ways of Knowing” designed to introduce entering freshmen to the learning process itself. His published research includes studies in bacterial pathogenesis, plant-microbe interactions, and plant gene expression. He is currently teaching biology and medical microbiology at Columbus State Community College in Columbus, Ohio, where he has just been nominated for a Distinguished Teaching Award. In addition, Dr. Bertoni is a freelance scientific writer who has contributed to text- and web-based projects in biology, physics, and microbiology. He is also a science editor for The Plant Cell, a leading research journal in plant biology and molecular biology.
Table of Contents
1. A Preview of the Cell
2. The Chemistry of the Cell
3. The Macromolecules of the Cell
4. Cells and Organelles
5. Bioenergetics: The Flow of Energy in the Cell
6. Enzymes: The Catalysts of Life
7. Membranes: Their Structure, Function, and Chemistry
8. Transport Across Membranes: Overcoming the Permeability Barrier
9. Chemotrophic Energy Metabolism: Glycolysis and Fermentation
10. Chemotrophic Energy Metabolism: Aerobic Respiration
11. Phototrophic Energy Metabolism: Photosynthesis
12. The Endomembrane System and Peroxisomes
13. Signal Transduction Mechanisms: I. Electrical and Synaptic Signaling in Neurons
14. Signal Transduction Mechanisms: II. Messengers and Receptors
15. Cytoskeletal Systems
16. Cellular Movement: Motility and Contractility
17. Beyond the Cell: Cell Adhesion, Cell Junctions, and Extracellular Structures
18. The Structural Basis of Cellular Information: DNA, Chromosomes, and the Nucleus
19. The Cell Cycle, DNA Replication, and Mitosis
20. Sexual Reproduction, Meiosis, and Genetic Recombination
21. Gene Expression: I. The Genetic Code and Transcription
22. Gene Expression: II. Protein Synthesis and Sorting
23. The Regulation of Gene Expression
24. Cancer Cells
Appendix Principles and Techniques of Microscopy
Photo, Illustration, and Text Credits