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The field of cell cycle regulation is based on the observation that the life cycle of a cell progresses through several distinct phases, G1, M, S, and G2, occurring in a well-defined temporal order. Details of the mechanisms involved are rapidly emerging and appear extraordinarily complex. Furthermore, not only is the order of the phases important, but in normal eukaryotic cells one phase will not begin unless the prior phase is completed successfully. Che- point control mechanisms are essentially surveillance systems that monitor the events in each phase, and assure that the cell does not progress prematurely to the next phase. If conditions are such that the cell is not ready to progress?for example, because of incomplete DNA replication in S or DNA damage that may interfere with chromosome segregation in M?a transient delay in cell cycle progression will occur. Once the inducing event is properly handled? for example, DNA replication is no longer blocked or damaged DNA is repaired?cell cycle progression continues. Checkpoint controls have recently been the focus of intense study by investigators interested in mechanisms that regulate the cell cycle. Furthermore, the relationship between checkpoint c- trol and carcinogenesis has additionally enhanced interest in these cell cycle regulatory pathways. It is clear that cancer cells often lack these checkpoints and exhibit genomic instability as a result. Moreover, several tumor suppressor genes participate in checkpoint control, and alterations in these genes are as- ciated with genomic instability as well as the development of cancer.

The field of cell cycle regulation is based on the observation that the life cycle of a cell progresses through several distinct phases, G1, M, S, and G2, occurring in a well-defined temporal order. Details of the mechanisms involved are rapidly emerging and appear extraordinarily complex. Furthermore, not only is the order of the phases important, but in normal eukaryotic cells one phase will not begin unless the prior phase is completed successfully. Che- point control mechanisms are essentially surveillance systems that monitor the events in each phase, and assure that the cell does not progress prematurely to the next phase. If conditions are such that the cell is not ready to progress?for example, because of incomplete DNA replication in S or DNA damage that may interfere with chromosome segregation in M?a transient delay in cell cycle progression will occur. Once the inducing event is properly handled? for example, DNA replication is no longer blocked or damaged DNA is repaired?cell cycle progression continues. Checkpoint controls have recently been the focus of intense study by investigators interested in mechanisms that regulate the cell cycle. Furthermore, the relationship between checkpoint c- trol and carcinogenesis has additionally enhanced interest in these cell cycle regulatory pathways. It is clear that cancer cells often lack these checkpoints and exhibit genomic instability as a result. Moreover, several tumor suppressor genes participate in checkpoint control, and alterations in these genes are as- ciated with genomic instability as well as the development of cancer.

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Part I. Induction and Detection of Changes in Cell Cycle Progression
 
 Methods to Induce Cell Cycle Checkpoints
 Howard B. Lieberman and Kevin M. Hopkins
 
 Methods for Synchronizing Mammalian Cells
 Michael H. Fox
 
 Enrichment of Cells in Different Phases of the Cell Cycle by Centrifugal Elutriation
 Tej K. Pandita
 
 Analysis of the Mammalian Cell Cycle by Flow Cytometry
 Haiying Hang and Michael H. Fox
 
 Methods for Detecting Cells in S Phase
 Wei-Hsin Sun and Melvin L. DePamphilis
 
 Yeast Cell Synchronization
 Audra Day, Colette Schneider, and Brandt L. Schneider
 
 Analysis of the Budding Yeast Saccharomyces cerevisiae Cell Cycle by Morphological Criteria and Flow Cytometry
 Hong Zhang and Wolfram Siede
 
 Analysis of the Fission Yeast Schizosaccharomyces pombe Cell Cycle
 Eliana B. Gomez and Susan L. Forsburg
 
 Part II. Analysis of Genes Involved in Checkpoint Control
 
 Strategies to Isolate Evolutionarily Conserved Cell Cycle Regulatory Genes
 Scott Davey
 
 Microarray Approaches for Analysis of Cell Cycle Regulatory Genes
 Sally A. Amundson and Albert J. Fornace, Jr.
 
 Using the Yeast Genome-Wide Gene-Deletion Collection for Systematic Genetic Screens
 Jian Zhang, Lisa Ottmers, and Brandt L. Schneider
 
 Gene Targeting in Cultured Human Cells
 Todd A. Waldman
 
 Use of In Vivo Gap Repair for Isolation of Mutant Alleles of a Checkpoint Gene
 Migdalisel Colon and Nancy C. Walworth
 
 In Vitro Mutagenesis to Define Functional Domains
 Jian Qin, Zhe Peng, and Maureen V. McLeod
 
 Use of Gene Overexpression to Assess Function in Cell Cycle Control
 Erik K. Flemington and Antonio Rodriguez
 
 Histone Acetylation/Deacetylation As a Regulator of Cell Cycle Gene Expression
 Chenguang Wang, Maofu Fu, and Richard G. Pestell
 
 Part III. Analysis ofProteins Involved in Checkpoint Control
 
 Cataloging Proteins in Cell Cycle Control
 Kazimierz O. Wrzeszczynski and Burkhard Rost
 
 Multidimensional Proteomic Analysis of Proteolytic Pathways Involved in Cell Cycle Control
 Michael W. Schmidt, Aruna Jain, and Dieter A. Wolf
 
 Purification and Identification of Protein Complexes That Control the Cell Cycle
 Matthew A. Burtelow, Vladimir N. Podust, and Larry M. Karnitz
 
 Xenopus Cell-Free Extracts to Study DNA Damage Checkpoints
 Vincenzo Costanzo and Jean Gautier
 
 Protein-Protein Interactions
 Graziella Pedrazzi and Igor Stagljar
 
 Detection of Kinase and Phosphatase Activities
 Sean M. Post and Eva Y.-H.P. Lee
 
 Monitoring Changes in the Subcellular Location of Proteins in S. cerevisiae
 Diego Rua, Teresa Holzen, Benjamin S. Glick, Stephen J. Kron, and Douglas K. Bishop
 
 Part IV. Chromosomes and the Cell Cycle
 
 Chromosomal Changes and Cell Cycle Checkpoints in Mammalian Cells
 Charles R. Geard and Brian Ponnaiya
 
 Detecting the Influence of Cell Cycle Regulatory Proteins on Human Telomeres
 Tej K. Pandita
 
 Monitoring Spindle Assembly and Disassembly in Yeast by Indirect Immunofluorescence
 Rita K. Miller
 
 Index

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