| File | Title | Manuscript Id |
|---|
| Chapter Introduction | lodish8e_ch19_1.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_1_dlap.xml | 56f563fc757a2e8473000002 |
| 19.1 Overview of the Cell Cycle and Its Control
| lodish8e_ch19_2.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_2_dlap.xml | 56f563fc757a2e8473000002 |
| The Cell Cycle Is an Ordered Series of Events Leading to Cell Replication
| lodish8e_ch19_3.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_3_dlap.xml | 56f563fc757a2e8473000002 |
| Cyclin-Dependent Kinases Control the Eukaryotic Cell Cycle
| lodish8e_ch19_4.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_4_dlap.xml | 56f563fc757a2e8473000002 |
| Several Key Principles Govern the Cell Cycle
| lodish8e_ch19_5.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_5_dlap.xml | 56f563fc757a2e8473000002 |
| Key Concepts of Section 19.1 | lodish8e_ch19_6.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_6_dlap.xml | 56f563fc757a2e8473000002 |
| 19.2 Model Organisms and Methods of Studying the Cell Cycle
| lodish8e_ch19_7.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_7_dlap.xml | 56f563fc757a2e8473000002 |
| Budding and Fission Yeasts Are Powerful Systems for Genetic Analysis of the Cell Cycle
| lodish8e_ch19_8.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_8_dlap.xml | 56f563fc757a2e8473000002 |
| Frog Oocytes and Early Embryos Facilitate Biochemical Characterization of the Cell Cycle Machinery
| lodish8e_ch19_9.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_9_dlap.xml | 56f563fc757a2e8473000002 |
| Fruit Flies Reveal the Interplay Between Development and the Cell Cycle
| lodish8e_ch19_10.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_10_dlap.xml | 56f563fc757a2e8473000002 |
| The Study of Tissue Culture Cells Uncovers Cell Cycle Regulation in Mammals
| lodish8e_ch19_11.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_11_dlap.xml | 56f563fc757a2e8473000002 |
| Researchers Use Multiple Tools to Study the Cell Cycle
| lodish8e_ch19_12.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_12_dlap.xml | 56f563fc757a2e8473000002 |
| Key Concepts of Section 19.2 | lodish8e_ch19_13.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_13_dlap.xml | 56f563fc757a2e8473000002 |
| 19.3 Regulation of CDK Activity
| lodish8e_ch19_14.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_14_dlap.xml | 56f563fc757a2e8473000002 |
| Cyclin-Dependent Kinases Are Small Protein Kinases That Require a Regulatory Cyclin Subunit for Their Activity
| lodish8e_ch19_15.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_15_dlap.xml | 56f563fc757a2e8473000002 |
| Cyclins Determine the Activity of CDKs
| lodish8e_ch19_16.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_16_dlap.xml | 56f563fc757a2e8473000002 |
| Cyclin Levels Are Primarily Regulated by Protein Degradation
| lodish8e_ch19_17.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_17_dlap.xml | 56f563fc757a2e8473000002 |
| CDKs Are Regulated by Activating and Inhibitory Phosphorylation
| lodish8e_ch19_18.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_18_dlap.xml | 56f563fc757a2e8473000002 |
| CDK Inhibitors Control Cyclin-CDK Activity
| lodish8e_ch19_19.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_19_dlap.xml | 56f563fc757a2e8473000002 |
| Genetically Engineered CDKs Led to the Discovery of CDK Functions
| lodish8e_ch19_20.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_20_dlap.xml | 56f563fc757a2e8473000002 |
| Key Concepts of Section 19.3 | lodish8e_ch19_21.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_21_dlap.xml | 56f563fc757a2e8473000002 |
| 19.4 Commitment to the Cell Cycle and DNA Replication
| lodish8e_ch19_22.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_22_dlap.xml | 56f563fc757a2e8473000002 |
| Cells Are Irreversibly Committed to Division at a Cell Cycle Point Called START or the Restriction Point
| lodish8e_ch19_23.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_23_dlap.xml | 56f563fc757a2e8473000002 |
| The E2F Transcription Factor and Its Regulator Rb Control the G1–S Phase Transition in Metazoans
| lodish8e_ch19_24.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_24_dlap.xml | 56f563fc757a2e8473000002 |
| Extracellular Signals Govern Cell Cycle Entry
| lodish8e_ch19_25.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_25_dlap.xml | 56f563fc757a2e8473000002 |
| Degradation of an S Phase CDK Inhibitor Triggers DNA Replication
| lodish8e_ch19_26.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_26_dlap.xml | 56f563fc757a2e8473000002 |
| Replication at Each Origin Is Initiated Once and Only Once During the Cell Cycle
| lodish8e_ch19_27.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_27_dlap.xml | 56f563fc757a2e8473000002 |
| Duplicated DNA Strands Become Linked During Replication
| lodish8e_ch19_28.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_28_dlap.xml | 56f563fc757a2e8473000002 |
| Key Concepts of Section 19.4 | lodish8e_ch19_29.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_29_dlap.xml | 56f563fc757a2e8473000002 |
| 19.5 Entry into Mitosis
| lodish8e_ch19_30.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_30_dlap.xml | 56f563fc757a2e8473000002 |
| Precipitous Activation of Mitotic CDKs Initiates Mitosis
| lodish8e_ch19_31.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_31_dlap.xml | 56f563fc757a2e8473000002 |
| Mitotic CDKs Promote Nuclear Envelope Breakdown
| lodish8e_ch19_32.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_32_dlap.xml | 56f563fc757a2e8473000002 |
| Mitotic CDKs Promote Mitotic Spindle Formation
| lodish8e_ch19_33.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_33_dlap.xml | 56f563fc757a2e8473000002 |
| Chromosome Condensation Facilitates Chromosome Segregation
| lodish8e_ch19_34.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_34_dlap.xml | 56f563fc757a2e8473000002 |
| Key Concepts of Section 19.5 | lodish8e_ch19_35.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_35_dlap.xml | 56f563fc757a2e8473000002 |
| 19.6 Completion of Mitosis: Chromosome Segregation and Exit from Mitosis
| lodish8e_ch19_36.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_36_dlap.xml | 56f563fc757a2e8473000002 |
| Separase-Mediated Cleavage of Cohesins Initiates Chromosome Segregation
| lodish8e_ch19_37.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_37_dlap.xml | 56f563fc757a2e8473000002 |
| APC/C Activates Separase Through Securin Ubiquitinylation
| lodish8e_ch19_38.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_38_dlap.xml | 56f563fc757a2e8473000002 |
| Mitotic CDK Inactivation Triggers Exit from Mitosis
| lodish8e_ch19_39.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_39_dlap.xml | 56f563fc757a2e8473000002 |
| Cytokinesis Creates Two Daughter Cells
| lodish8e_ch19_40.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_40_dlap.xml | 56f563fc757a2e8473000002 |
| Key Concepts of Section 19.6 | lodish8e_ch19_41.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_41_dlap.xml | 56f563fc757a2e8473000002 |
| 19.7 Surveillance Mechanisms in Cell Cycle Regulation
| lodish8e_ch19_42.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_42_dlap.xml | 56f563fc757a2e8473000002 |
| Checkpoint Pathways Establish Dependencies and Prevent Errors in the Cell Cycle
| lodish8e_ch19_43.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_43_dlap.xml | 56f563fc757a2e8473000002 |
| The Growth Checkpoint Pathway Ensures That Cells Enter the Cell Cycle Only After Sufficient Macromolecule Biosynthesis
| lodish8e_ch19_44.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_44_dlap.xml | 56f563fc757a2e8473000002 |
| The DNA Damage Response System Halts Cell Cycle Progression When DNA Is Compromised
| lodish8e_ch19_45.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_45_dlap.xml | 56f563fc757a2e8473000002 |
| The Spindle Assembly Checkpoint Pathway Prevents Chromosome Segregation Until Chromosomes Are Accurately Attached to the Mitotic Spindle
| lodish8e_ch19_46.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_46_dlap.xml | 56f563fc757a2e8473000002 |
| The Spindle Position Checkpoint Pathway Ensures That the Nucleus Is Accurately Partitioned Between Two Daughter Cells
| lodish8e_ch19_47.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_47_dlap.xml | 56f563fc757a2e8473000002 |
| Key Concepts of Section 19.7 | lodish8e_ch19_48.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_48_dlap.xml | 56f563fc757a2e8473000002 |
| 19.8 Meiosis: A Special Type of Cell Division
| lodish8e_ch19_49.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_49_dlap.xml | 56f563fc757a2e8473000002 |
| Extracellular and Intracellular Cues Regulate Germ Cell Formation
| lodish8e_ch19_50.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_50_dlap.xml | 56f563fc757a2e8473000002 |
| Several Key Features Distinguish Meiosis from Mitosis
| lodish8e_ch19_51.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_51_dlap.xml | 56f563fc757a2e8473000002 |
| Recombination and a Meiosis-Specific Cohesin Subunit Are Necessary for the Specialized Chromosome Segregation in Meiosis I
| lodish8e_ch19_52.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_52_dlap.xml | 56f563fc757a2e8473000002 |
| Co-orienting Sister Kinetochores Is Critical for Meiosis I Chromosome Segregation
| lodish8e_ch19_53.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_53_dlap.xml | 56f563fc757a2e8473000002 |
| DNA Replication Is Inhibited Between the Two Meiotic Divisions
| lodish8e_ch19_54.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_54_dlap.xml | 56f563fc757a2e8473000002 |
| Key Concepts of Section 19.8 | lodish8e_ch19_55.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_55_dlap.xml | 56f563fc757a2e8473000002 |
| Key Terms
| lodish8e_ch19_56.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_56_dlap.xml | 56f563fc757a2e8473000002 |
| Review the Concepts
| lodish8e_ch19_57.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_57_dlap.xml | 56f563fc757a2e8473000002 |
| References
| lodish8e_ch19_58.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_58_dlap.xml | 56f563fc757a2e8473000002 |
| Perspectives for the Future: Cell Cycle Checkpoints and Regulation
| lodish8e_ch19_59.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_59_dlap.xml | 56f563fc757a2e8473000002 |
| Classic Experiment 19-1: How Cyclins Were Discovered | lodish8e_ch19_60.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_60_dlap.xml | 56f563fc757a2e8473000002 |
| Classic Experiment 19-2: Synthesis and Degradation of Mitotic Cyclin Are Required for Progression through Mitosis | lodish8e_ch19_61.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_61_dlap.xml | 56f563fc757a2e8473000002 |
| Classic Experiment 19-3: The Formulation of the Checkpoint Concept | lodish8e_ch19_62.html | 56f563fc757a2e8473000002 |
| DLAP questions | lodish8e_ch19_62_dlap.xml | 56f563fc757a2e8473000002 |