Molecular Cell Biology (Bio 5068) Cell Cycle I. Ron Bose, MD PhD November 14, 2017

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1 Molecular Cell Biology (Bio 5068) Cell Cycle I Ron Bose, MD PhD November 14, 2017

2 CELL DIVISION CYCLE M G2 S G1

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4 DISCOVERY AND NAMING OF CYCLINS A protein (called cyclin ) was observed to increase as cells approached mitosis, peak in mitosis and then precipitously disappear as cells exited mitosis.

5 Two proteins (cyclins A and B) increased as cells approached mitosis, peaked in mitosis and precipitously disappeared as cells exited mitosis.

6 The cell cycle is primarily regulated by cyclically activated protein kinases Figure 17-15, Molecular Biology of the Cell, 4th Edition

7 Overview of major cyclins and Cdks of vertebrates and yeast Table Molecular Biology of the Cell, 4th Edition

8 Evolution of cell cycle control: from yeast to humans Malumbres M, Nature Reviews Cancer 2009

9 Cdk activity is regulated by inhibitory phosphorylation and inhibitory proteins Why is cell cycle progression governed primarily by inhibitory regulation? Figure 17-18, Molecular Biology of the Cell, 4th Edition

10 Cell cycle control depends on cyclical proteolysis Figure Molecular Biology of the Cell, 4th Edition

11 UBIQUITIN-MEDIATED PROTEOLYSIS Deshaies RJ and Joazeiro CA. Annu Rev Biochem E1 (Ubiquitin activating enzyme) Binds to Ubiquitin in an ATP-dependent manner Passes Ubiquitin to E2 E2(Ubiquitin conjugating enzyme or UBC) At least 12 in yeast some are specific to a given target E3 (ubiquitin protein ligase) Large complex in both clam (cyclosome) and in frog (APC = anaphase promoting complex). Final transfer of ubiquitin to substrate can be mediated by E2 alone or E2 acting in concert with E3 UBIQUITIN-MEDIATED PROTEOLYIS Proteosome (26S complex) Structure from archaebacterium solved.

12 APC = A naphase P romoting C omplex Required for degradation of substrates at Metaphase to Anaphase transition ( ie : B-type Cyclins and securin) WD repeatcontaining proteins substrate for ubiquitination Have D or KEN Box Ubiq Ubiq Ubiq Ubiq Apcx Apc4 Cdc20 or Cdh1 / Hct1 Apc1 / BimE UBC Ring finger ( E2 ) Apc11 Cullin = Apc2 Apc5 Cdc27 Apc3 Apc7 Cdc23 Apc8 Cdc16 Apc6 Apc10 Cdc20 : targets cyclin A and B-type Cyclins, securin Cdh1 / Hct1 : targets Plk1 and B-type cyclins

13 SCF Ubiquitin Ligases Components: F Box: adapter Brings substrate to E3 ligase. F-box binds to Skp1 Additional protein interaction domains (PID: WD repeat, leucine-rich repeat) binds to substrate E2: UBIQ. Conjugating enzyme (transfers UB to substrate) Skp1: Bridges F-box to cullin Cullin: Organizes and activates E3 complex Recruits E2-UBIQ conjugating enzyme Ring finger protein Participates in E2 binding and catalysis

14 SCF E3 Ubiquitin Ligases O'Connell BC, Harper JW. Curr Opin Cell Biol. 2007

15 CELL CYCLE REGULATION OF Cdc2 Reversible phosphorylation Inhibitory kinase(s) Phosphatase(s) Protein-protein interactions T14 Y15 T161 P P P T161 P Cdc2 INACTIVE Cdc2 Cyclin B INACTIVE Cdc2 Cyclin B INACTIVE Cdc2 Cyclin B ACTIVE Cdc2 INACTIVE Cyclin B Activating Kinase(s) Ubiquitinmediated proteolyis

16 Cyclin-dependent Kinase Inhibitor Proteins (CKI s) 1. CIP/KIP family (p21cip1, p27kip1, p57kip2): a. Binds to Cdk2 and inhibits activity. b. Binds Cdk4/6 and helps assemble complexes with cyclins. 2. INK4 family (p16, p15, p18, p19). a. Specific for Cdk4 and Cdk6. b. Binds Cdk subunit alone and prevents cyclin binding c. Bind and inhibit Cdk4/6-Cyclin D heterodimers.

17 G1 Control M Cdk 4 & 6 Cyclin D1, 2, 3 INK4a proteins (p15,16, 18, 19) G2 S G1 Assembly & Sequestration Cdk2 Cyclin E Cip/Kip proteins (p21, p27, p57)

18 Mechanisms controlling G1/S-phase transition MITOGENIC or HORMONAL SIGNALS CYCLIN D Stability and CYCLIN D-dependent Kinases (Cdk4/Cdk6) Rb1 E2F Transcription factor Figure Molecular Biology of the Cell, 4th Edition

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20 G1 Control CYCLIN E CDK2 MITOGENIC SIGNALS CYCLIN D STABILITY CYCLIN D-DEPENDENT KINASES (Cdk4/Cdk6) RB E2F CYCLIN E S-Phase E2F Relief of Rb- mediated transcriptional repression CYCLIN A & S-PHASE GENES S-PHASE GENES S-Phase

21 G1 Control p27kip1 p27kip1-phosphorylation Ubiq-Mediated proteolysis Assembly & Sequestration CYCLIN E CDK2 MITOGENIC SIGNALS CYCLIN D STABILITY CYCLIN D-DEPENDENT KINASES (Cdk4/Cdk6) RB E2F CYCLIN E S-Phase E2F Relief of Rb- mediated transcriptional repression CYCLIN A & S-PHASE GENES S-PHASE GENES S-Phase

22 Checkpoints What are they? How were they defined? How does their derailment contribute to cancer?

23 CHECKPOINTS IMPROPER SPINDLE ASSEMBLY DNA DAMAGE UNREPLICATED DNA G2 M STOP! S G1 DNA DAMAGE

24 Checkpoints: intracellular signaling pathways that determine if previous steps are complete before proceeding onto the next stage (complete DNA synthesis before entering mitosis; spindles must be assembled before exiting metaphase and entering into anaphase) and whether there has been any damage to the DNA. DNA damage checkpoint: integrity of DNA DNA damage is repaired before entering S, completing S or entering M. DNA replication checkpoint: replication state of DNA Complete DNA synthesis before mitosis. Spindle assembly checkpoint: integrity of spindle spindles must be assembled before exiting metaphase into anaphase.

25 DNA DAMAGE RESPONSE PATHWAY G2-PHASE CHECKPOINT M G2 STOP! S G1 G1-PHASE CHECKPOINT S-PHASE CHECKPOINT

26 CELLULAR RESPONSES TO CHECKPOINT ACTIVATION (IR, etoposide, HU, gemcitibine, irinotecan, carboplatin ) CHECKPOINTS G1 S G2 M APOPTOSIS TEMPORARY CELL CYCLE ARREST & activation of DNA repair pathways SENESCENCE

27 Fig. 2 Chemo- & Radio-therapy IR Etoposide Gemcitabine Cytarabine 5-Fluorouracil Irinotecan Topotecan Cisplatin Carboplatin Signal ATM ATR Signaling Cascade CHK2 p53 CHK1 BAX PUMA p σ CDC25A RAD51 FAND2 FANCE Cellular Response Senescence Apoptosis Cell Cycle Arrest DNA Repair

28 DNA DAMAGE CHECKPOINTS IR/VP16 replication stress DNA DSBs ssdna ATM ATR Chk2 p53 Mdm2 Chk1 p21, σ Cdc25A Cyclin E / Cdk2 Cyclin B/Cdk1 DEATH G1 S G2 M G1-checkpoint S-phase checkpoint G2 checkpoint Overproduced in certain cancers. Inactivated in certain cancers.

29 DNA damage leads to cell cycle arrest in G1 Figure Molecular Biology of the Cell, 4th Edition

30 Mitogens stimulate cell division Figure Molecular Biology of the Cell, 4th Edition

31 Excessive stimulation of mitogenic pathways can lead to cell cycle arrest or cell death Figure Molecular Biology of the Cell, 4th Edition

32 Extracellular Survival Factors Suppress Apoptosis Figure Molecular Biology of the Cell, 4th Edition

33 Cell cycle regulators are frequently disrupted in cancer Malumbres M, Nature Reviews Cancer 2001

34 Overview of CDK inhibitors in clinical development for cancer therapy O Leary et al., Nature Reviews Clinical Oncology 2016

35 Turner et al, NEJM 2015

36 NEJM Nov. 3, 2016

37 Conclusions 1. The cell cycle is a coordinated and tightly organized process to ensure the successful replication of the cell. 2. Activity of CDK-Cyclins is determined by: 1. Synthesis of Cyclins. 2. Reversible phosphorylation/dephosphorylation of stimulatory and inhibitory sites on CDK. 3. Ubiquitin mediated degradation of Cyclins. 4. CDK inhibitors INK4 and CIP/KIP families. 3. Checkpoints can halt the cell cycle if all steps have not been properly completed. 4. Cancers have many alterations in cell cycle proteins and selective CDK4/6 inhibitors are now used in cancer treatment.