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Chapter 18 The Cell-Division Cycle Essential Cell Biology FOURTH EDITION Copyright © Garland Science 2014 Alberts Bray Hopkin Johnson Lewis Raff Roberts Walter
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Cycle of Cell Reproduction Fig. 18-1
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Reproduction Rates Vary early Drosophila embryo nuclei (not cells yet) 6 minutes!
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Phases of Cell Cycle Fig. 18-2
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There are quality control checkpoints along the way. Fig. 18-3
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Cyclin/Cdk Complexes Regulate Progression Fig. 18-4
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Cyclin Abundance Regulates Cdk Activity Cdks present at all times; cyclin levels “cycle”. Fig. 18-8
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How We Know: Cyclin/M-Cdk was first discovered in fertilized frog and clam eggs.
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Cytoplasm from M phase fertilized egg induces mitosis in G2-arrested oocyte Fig. 18-7 Cyclin/M-Cdk is the active agent. (called Maturation Promoting Factor (MPF) arrested in G2
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Progesterone induces Cyclin/M-Cdk to promote maturation of oocytes during meiosis (Maturation Promoting Factor) Cyclin/M-Cdk
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Cyclin/Cdk Complexes Drive Progression of All Cell Cycle Stages We’ll just refer to them as S-Cyclin and M-Cyclin.
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Cyclin Abundance Determines Cdk Activity Cyclin abundance regulated by transcription and by proteolysis. Fig. 18-8
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Cyclin proteolysis triggered by ubiquitylation by APC allows exit from M phase Fig. 18-9
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M-Cdk activity also regulated by phosphorylation Fig. 18-10 phosphorylation controls entry into M phase P activating phosphate and kinase (CAK)
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Positive Feedback Loop from M-Cdk on Cdc25 Makes M phase Entry Signal More Robust Fig. 18-17 Wee1 kinase phosphorylation by M-Cdk activates Cdc25
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S-Cdk regulated by inhibitory proteins Inhibitory proteins control entry into S phase Fig. 18-11 S-
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p27 inactive cyclin-Cdk complex UBIQUITYLATION OF p27 BY SCF p27 proteolysis triggered by ubiquitylation by SCF allows entry into S phase Fig. 18-9 modified DESTRUCTION OF p27 IN PROTEASOME
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Replication complete? DNA damage? Chromosome attachment to spindle? Environmental cues? There are quality control checkpoints along the way. Fig. 18-12
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Environmental Cues Can Induce S Phase Entry Through Rb Inactivation Cyclins, etc. Fig. 18-14
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Internal Signals Can Induce Temporary Delay in S Phase Entry through p53 Activation Fig. 18-15 Checkpoint kinases (Chk) functions like p27
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Fig. 18-10 P activating phosphate and kinase (CAK) If DNA damage is detected during G2 phase, Cdc25 inactivation prevents entry into M phase.
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Replication Proteins Are Targets of Cyclin/S-Cdk Fig. 18-16 Cdc6 and ORC can only form pre-RC when de-phosphorylated ORC, Cdc6, and MCM phosphorylated, inactivating ORC & Cdc6 but activating MCM ensures pre-RC assembly once and only once/ cell cycle -P MCM
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Cyclin/Cdk Complexes Regulate Progression Fig. 18-4 What regulates Cdk Activity? Cyclin activates (its level cycles) Cdk inhibitors (p27 & p21) Cdk phosphorylation -activating kinase: CAK -inhibiting kinase: Wee1 -activating phosphatse: Cdc25
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Fig. 18-10 M-Cdk phosphorylation controls entry into M phase P activating phosphate and kinase (CAK) How will mutations in these phosphorylation sites affect the cell cycle?
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POLAR CHARGED POLAR UNCHARGED Ser, Thr, or Tyr mutated to Ala: can no longer be phosphorylated Ser, Thr, or Tyr mutated to Asp or Glu: mimics phosphorylation Effects of Mutating Phosphorylation Sites phosphorylation
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Fig. 18-10 M-Cdk phosphorylation controls entry into M phase P activating phosphate and kinase (CAK) mutating inhibitory PO 4 site to Glu mutating inhibitory PO 4 site to Ala mutating activating PO 4 site to Glu mutating activating PO 4 site to Ala constitutive entry into M phase unable to enter M phase constitutive entry into M phase Mutation phenotype Dom/Rec? Dom Rec Dom
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Mitosis: The Most Visibly Dramatic Part of Cell Cycle prophase metaphase anaphase telophase
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Panel 18.1 chromosomes condense mitotic spindle forms kinetochore forms nuclear envelope disperses chromosomes aligned chromosomes separate chromosomes decondense nuclear envelope reforms DNA replication
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Chromosome Proteins Are Targets of Cyclin/M-Cdk in Prophase Fig. 18-18 -Cohesin and Condensin are structurally related ring- forming proteins. -Cohesin holds sister chromatids together during metaphase. -Condensin condenses chromosomes into visible bodies. target of Cyclin/M-Cdk phosphorylation
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Mitosis requires assembly of two transient cytoskeletal structures Fig. 18-19 mitosis cytokinesis M phase
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Prophase: MT reorganization Prometaphase: chromosomes attach Metaphase: chromosomes align & separate Mitotic spindle assembly begins with centriole duplication during S phase Fig. 18-21
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Microtubule Associated Proteins (MAPs) are targets of Cyclin/M-Cdk during prophase dynamic instability increased interactions between MTs from opposite poles stabilize MT + ends motors cross-link interpolar MTs Fig. 18-22
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Sister chromatids bind kinetochore MTs from opposite poles during prometaphase, allowing separation during anaphase. kinetochore protein Fig. 18-24
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Sister chromatids bind kinetochore MTs from opposite poles and separate during anaphase. Fig. 18-27 metaphase anaphase
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Degradation of Securin and cleavage of Cohesin allow separation. Fig. 18-28
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kinesin motors dynein motors kinesin: dynein: MT disassembly from + ends Two processes at play during sister chromatid segregation Fig. 18-29 pushes poles apart pulls poles apart
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Kinetochore proteins bind microtubule sides, instead of ends, allowing assembly/disassembly at + end Alberts MBOC
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Nuclear Envelope Assembly/Reassembly During Mitosis Fig. 18-30 targets of Cyclin/M-Cdk phosphatase
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Nuclear division is followed by cytokinesis. Fig. 18-32
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Cells lose adhesion to their substratum and change shape during cytokinesis. Fig. 18-33
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Programmed cell death (apoptosis) is another mechanism for controlling cell numbers. apoptotic cells Fig. 18-35 Apoptosis needed for digit formation during embryonic development.
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Apoptosis needed for tail loss during frog metamorphosis tadpole adult frog Fig. 18-36
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Apoptosis also needed for neuron pruning during neural development Fig. 18-41
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Necrosis Apoptosis Apoptosis in Animal Fig. 18-37 Necrosis is messy; apoptosis is neat.
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Caspase enzymes mediate apoptosis. Fig. 18-38 cleave target proteins to kill cell allowing nuclease access to DNA
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External signaling molecules can induce apoptosis in a developmental program. Fig. 18-40 eliminates self-recognizing T cells from immune system
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Intrinsic signals can also induce apoptosis in response to DNA damage. Balance of pro-apoptotic and anti-apoptotic Bcl2 proteins determines outcome Fig. 18-39 pro-apoptotic DNA damage activates pro-apoptotic Bcl2 proteins
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Survival factors increase expression of anti-apoptotic Bcl2 proteins Fig. 18-42
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Growth Factors Control Cell Size (Growth) by Regulating Protein Synthesis & Degradation Fig. 18-43 Insulin is growth factor (Lab 4B) Cells remain in G 1 or G 0
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Extracellular signal proteins can control cell growth, division and/or survival. Muscle cells: control of both cell division and growth Neurons: primarily growth Liver cells: primarily division
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Chapter 19 Sexual Reproduction and the Power of Genetics Essential Cell Biology FOURTH EDITION Copyright © Garland Science 2014 Alberts Bray Hopkin Johnson Lewis Raff Roberts Walter
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Fig. 19-4 Most multicellular organisms reproduce sexually. fertilization of egg by sperm
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After fertilization, the diploid zygote then undergoes rounds of mitosis to generate a new multicellular adult. Fig. 19-5
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Meiosis differs from mitosis in also having a reductive division. Fig. 19-6 reductive division non-reductive division non-reductive division
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Physical Basis of reductive division: separation of chromosome homologues Fig. 19-7
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Physical Basis of reductive division: separation of chromosome homologues Fig. 19-8
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Fig. 19-9 Paired chromosome homologues after duplication (one from each parent) Synaptonemal Complex holds homologues together Cohesin holds sister chromatids together
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