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The Cell Cycle

The Cell Cycle. Pages 1067-1071, 1087-1088, 1105-1107. S phase. -Functions -Duplicate the DNA -Protein packing must be reproduced -2 issues facing DNA replication -Accuracy of replication -Copy DNA only once. Control of DNA Duplication. 2 steps in Replication

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The Cell Cycle

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  1. The Cell Cycle Pages 1067-1071, 1087-1088, 1105-1107

  2. S phase -Functions -Duplicate the DNA -Protein packing must be reproduced -2 issues facing DNA replication -Accuracy of replication -Copy DNA only once

  3. Control of DNA Duplication 2 steps in Replication 1. Late M/Early G1 -Formation of prereplicative complex (pre-RC) 2. Start of S phase -Preinitiation complex

  4. Initiation of DNA Replication ORCs are always bound to the origins pre-RC assembly: -Inhibited by Cdk activity -Stimulated by APC/C

  5. Initiation of DNA Replication -S-Cdk triggers the preinitiation complex -Diassembly of pre-RC -ORC and Cdc6 is P by Cdk -Cdc6 is degraded -Cdt1 is inhibited by geminin

  6. Initiation of DNA Replication -DNA Replication is completed -In late M, APC/C the degradation of geminin -Cdk activity is decreased, OCRs are dephosphorylated -Cdc6 is synthesized -pre-RC assembly

  7. Duplication of Chromatin Structure -Cdks stimulate synthesis of the 4 histone subunits -Nucleosome assembly factors typically associate with the replication fork -Histone modifying enzymes are thought to play a role

  8. Cohesins and Sister Chromatids -Cohesin – large protein complex which holds the sister chromatids together Smc (Structural Maintenance of Chromosomes)

  9. P Sister Chromatid Separation Securin inhibits separase Separase cleaves cohesin

  10. Creation of DNA Lesions

  11. DNA Damage Signaling Pathways

  12. DNA DamageCheckpoint Mdm2 – ubiquitin ligase p21 – CKI (Cdk Inhibitor Protein)

  13. Check1/2 Chk1/2 phosphorylate Cdc25 thereby inactivating the phosphatase activity resulting in inactive Cdk

  14. DNA Damage -Cell cycle is arrested until the damage is repaired -If it’s not repaired: 1. Unicellular organisms will resume their cycle taking a potential mutation over death 2. Multicellular organimsms will sacrifice a cell over the health of the organism

  15. Apoptosis Pages 1115-1128

  16. Apoptosis Apoptosis is one type of programmed Process of Apoptosis -Cells shrink and condense -Cytoskeleton collapses -Nuclear envelope disassembles -Nuclear chromatin fragments -Cell surface belbs and may break up (apoptotic bodies) -Cell surface is chemically altered -Macrophage engulfs the cell Process of Cell Necrosis -Cell insult or injury -Cells swell and burst -Cell contents are released -Inflammatory response

  17. Examples of Apoptosis 1. Number of cells -Nervous system

  18. Examples of Apoptosis 2. Development Paws of embryonic mouse

  19. Examples of Apoptosis 3. Regulate cell numbers -Liver 4. Quality control -Eliminates abnormal, misplaced, nonfunctional, or dangerous cells -Developing T and B cells that do not produce useful antigen receptors or that are self-reactive 5. Supply of cells -Large numbers of neutrophils are produced and stored awaiting infection

  20. Biochemical Characteristics DNA Cleavage -Endonuclease cleaves DNA into fragments between nucleosomes

  21. Biochemical Characteristics TUNEL Assay - TdT-mediated dUTP nick end labeling Phosphatidylserine localization -movement from the inner to outer membrane -marks the cell for macrophages

  22. Caspases -Enzymes responsible for apoptosis -A family of proteases that cleave proteins at aspartic acid residues -C for cysteine (in active site) and ASP for aspartic acid -Synthesized as inactive precursors, procaspases -Not all caspases are involved with apoptosis -ICE, interleukin-1-converting enzyme

  23. Procaspase Cleavage

  24. Caspases -Initiator procaspase, start the proteolytic cascade -Executioner procaspases, cleave and activate other executioner procaspases and other targets -Targets include: nuclear lamins, endonuclease inhibitor, cytoskeleton components, cell-cell adhesion proteins -The caspase cascade is: -Very destructive -Self-amplyfing -Irreversible

  25. Caspase Cascade

  26. Caspases -Initiator caspases have a caspase recruitment domain (CARD) that enables them to bind to adaptor proteins into activation complexes -In the complex, the initiator caspases are close enough to activate each other starting the cascade -2 Apoptotic pathways 1. Extrinsic Pathway 2. Intrinsic Pathway

  27. Extrinsic Pathway DISC – death-inducing signaling complex Inhibitors such as decoy receptors and intracellular blocking proteins

  28. Intrinsic Pathway Releases mitochondrial proteins into the cytoplasm Cytochrome C release can trigger apoptosis through interaction with the adapter protein Apaf1

  29. Intrinsic Pathway

  30. Classes of Bcl2 Proteins Bcl2 proteins –regulate apoptosis through controlling the release of cytochrome c

  31. Pro-Apoptotic BH123

  32. Regulation of Intrinsic Pathway BH3-only proteins activate apoptosis through direct binding with anti-apoptotic proteins -p53 activates BH3-only proteins (Puma and Noxa) -Bid – extrinsic and intrinsic pathways

  33. Model for IAPs

  34. Inhibition of Apoptosis (BH3-only pro-apoptotic) (Anti-apoptotic)

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