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Lab 7: Cell Division: Mitosis and Meiosis

Lab 7: Cell Division: Mitosis and Meiosis. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles. AIM: Describe how the cell cycle is regulated. Are there molecular signals in the cytoplasm that regulate the cell cycle?. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles.

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Lab 7: Cell Division: Mitosis and Meiosis

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  1. Lab 7: Cell Division: Mitosis and Meiosis

  2. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. Are there molecular signals in the cytoplasm that regulate the cell cycle?

  3. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. Are there molecular signals in the cytoplasm that regulate the cell cycle? Conclusion: The results suggest that molecules are present in the cytoplasm of cells in the S or M phase controlling the progression of phases. What are these molecules you ask?

  4. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. The cell cycle clock: Cyclins and Cyclin-Dependent Kinases What is a cyclin-dependent kinase (cdk)? It’s a group of related kinases (enzymes that phosphorylates molecules – usually proteins) that are activated by a group of proteins called cyclins. What is a cyclin? A group of proteins that are made in cycles (hence the name) and are allosteric activators of the cdk’s (activate them upon binding). Ex. “Cyclin B”

  5. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. Expression of human cyclins throughout the cell cycle

  6. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. The cell cycle clock: Cyclins and Cyclin-Dependent Kinases Give an example: Ex. “Cyclin B” (the cyclin in the figure to the right) begins to be made at the end of S phase and slowly increases in concentration throughout G2. When the concentration gets high enough, Cyclin B will bind to Cdk-1 (the Cdk shown in the diagram to the right), activating it. “Cyclin B” + Cdk-1 = MPF MPF stand for maturation-promoting factor –(aka mitosis-promoting factor). ****All molecular binding (binding of two molecules) is concentration dependent.

  7. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. The cell cycle clock: Cyclins and Cyclin-Dependent Kinases Give an example: Ex. MPF will activate mitosis at the G2 checkpoint by going around and phosphorylating a number of proteins including: 1. Condensins Proteins involved in condensing the chromosomes. 2. Histones – to condense DNA 3. Proteins involved in microtubule spindle fiber formation 4. Lamins The proteins that hold the nuclear envelope together (nuclear lamina)

  8. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. The cell cycle clock: Cyclins and Cyclin-Dependent Kinases Give an example: How will the MPF complex be turned off? High levels of MPF result in the phosphoylation of proteins that will degrade (break down) Cyclin-B - negative feedback

  9. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. All of the various cyclins and Cdk’s are part of the… Cell Cycle Control System

  10. Lab 7: Cell Division: Mitosis and Meiosis Recall that mitotic cell division is regulated by Cyclin and Cdk’s (cyclin dependent kinases).

  11. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. Checkpoints of the Cell Cycle Control System There are three major checkpoints: A. G1 checkpoint - Passing G1 checkpoint = point of no return - Cell can halt at this checkpoint and remain there for their lifetime -external and internal signals required to pass this checkpoint • Growth Factor (external signal) like PDGF (platelet derived growth factor), which stimulates division near a wound. • Enough nutrients/enzymes (internal)

  12. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. Checkpoints of the Cell Cycle Control System There are three major checkpoints: B. The G2 checkpoint Ex) Is all the DNA replicated? Ex) Is the DNA too damaged from replication (too many mistakes made) to continue? If yes, apoptosis; if no, continue to mitosis. -Internal signals only

  13. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. Checkpoints of the Cell Cycle Control System There are three major checkpoints: C. The M (metaphase) checkpoint Ex) Are all the sister chromatids present and attached to microtubules and ready to be pulled apart? -internal signals only

  14. Chapter 12/13 - Cell Cycle, Meiosis, and Sexual cycles AIM: Describe how the cell cycle is regulated. Checkpoints Review

  15. Lab 7: Cell Division: Mitosis and Meiosis

  16. Lab 7: Cell Division: Mitosis and Meiosis Lectin - Highly specific carbohydrate-binding proteins - Present throughout nature Ex) Concanavalin A Jack Bean ConA – pdb code: 3CNA Jack Bean - Promotes cell division in plant cell by binding to cell surface receptors that have been glycosylated with very specific polysaccharide chains.

  17. Lab 7: Cell Division: Mitosis and Meiosis What’s a Lectin? Ex) Concanavalin A Jack Bean ConA – pdb code: 3CNA Jack Bean

  18. Lab 7: Cell Division: Mitosis and Meiosis

  19. Lab 7: Cell Division: Mitosis and Meiosis

  20. Lab 7: Cell Division: Mitosis and Meiosis After the procedure you should see this for both the lectin-treated (experimental) and untreated (control) groups:

  21. Lab 7: Cell Division: Mitosis and Meiosis Data from one group: Untreated (Control) Lectin-Treated (Expt)

  22. Lab 7: Cell Division: Mitosis and Meiosis

  23. Lab 7: Cell Division: Mitosis and Meiosis Untreated (Control) Percentage of cell in interphase = 234/306*100= 76.5 % We now know to expect that in a standard onion plant, 76.5% of the cells will be in interphase…. Lectin-Treated (Expt) Therefore, if we have 392 total cells, we expect, if standard, 392*.765 to be in interphase = 300 cells – expected value

  24. Lab 7: Cell Division: Mitosis and Meiosis Lectin-Treated (Expt) 300 cells in interphase – expected value Therefore 92 cells in mitotic phase – expected value Now calculate the chi2 and determine a p-value…

  25. Lab 7: Cell Division: Mitosis and Meiosis Now calculate the chi2 and determine a p-value… = (277-300)2/300 + (115-92)2/92 = 529/300 + 529/92 DOF = # groups – 1 = 2 -1 = 1 = 1.76 + 5.75 P < .01 = 7.51 There is less than 1% probability that there is no difference (null hypothesis). Therefore, there is >99% that there is a difference and therefore the data supports the alternative hypothesis.

  26. Lab 7: Cell Division: Mitosis and Meiosis

  27. Lab 7: Cell Division: Mitosis and Meiosis

  28. Lab 7: Cell Division: Mitosis and Meiosis

  29. Lab 7: Cell Division: Mitosis and Meiosis Hela cell karyotype Normal cell karyotype

  30. Lab 7: Cell Division: Mitosis and Meiosis Hela cell karyotype

  31. Lab 7: Cell Division: Mitosis and Meiosis HPV – Human Papillomavirus -most common STD - Infects genital areas as well as mouth and throat - Nearly everyone gets it at some point in their lives - 90% of cases fought off by immune systom and no symptoms arise. - The other 10%: - Genital Warts - Cervical Cancer *Nearly all cases of cervical cancer are caused by HPV!!!

  32. Lab 7: Cell Division: Mitosis and Meiosis How does HPV cause cancer? - HPV is a small DNA virus - Ligand/receptor interactions allow virus access to cell. - Genome of virus enters nucleus by unknown mechanism - Between 10 and 200 copies are inserted into persons nuclear DNA. - Protein E6 and E7 are the major oncogenic (cancer causing) proteins - “E” stands for early because the gene is transcribed early in the viral life cycle. “L” for late. HPV genome - ~8000bp

  33. Lab 7: Cell Division: Mitosis and Meiosis Why are E6 and E7 oncogenic? E6 functions by ubiquitinatingp53 Recall that adding the small protein ubiquitin to a protein targets it to be degraded by the proteosome! Both p53 (guardian angel) and pRb are tumor suppressor proteins.

  34. Lab 7: Cell Division: Mitosis and Meiosis p53 - Transcription factor - Goes to work when the cell is in bad shape (DNA damage, etc…) - Like batman - Turns on genes that code for proteins having to do with DNA repair, cell cycle arrest and apooptosis. p53 (“the guardian of the genome”) bound to an enhancer region of DNA “53” because its apparent mass is 53kDa or 53,000Da or 53,000amu.

  35. Lab 7: Cell Division: Mitosis and Meiosis pRb - Inhibits cell cycle progression at G1 checkpoints - Binds and inhibits transcription factors that want to turn on genes and push the cell into S phase. pRb (Retinoblastoma Protein) - Named such because if you both copies are mutated early in life you will get retinoblastoma (cancer of the eye’s retina) pRb is inactivated when it is phosphorylated by CDK/cyclin!!

  36. Lab 7: Cell Division: Mitosis and Meiosis

  37. Lab 7: Cell Division: Mitosis and Meiosis http://www.youtube.com/watch?v=pOROHmEmqmU Focus on meiosis part

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