2. Eukaryotic Cell Cycle Cell cycle: repeating sequence of cellular growth and division during the life of the cell – Interphase – Mitosis – Cytokinesis

3. Interphase Cell is growing and preparing to divide G1 (First Gap) phase – Cell grows rapidly S (synthesis) phase – Cell’s DNA is copied – Each chromosome now has 2 identical chromatids G2 (Second Gap) phase – Cell continues to grow and prepare for division – Microtubules form

4. Mitosis Process of dividing the nucleus into two daughter nuclei – Prophase – Metaphase – Anaphase – Telophase

5. Prophase Chromosomes condense Nuclear membrane dissolves Centrosomes (centrioles) move to opposite poles and spindle forms

6. Metaphase Condensed chromosomes line up at cell’s equator Spindle fibers link the individual chromatids to opposite poles

7. Anaphase Spindle fibers shorten Chromatids pulled to opposite poles of cell giving each pole identical sets of chromosomes

8. Telophase New nuclear envelope forms at each pole Spindle dissolves Chromosomes uncoil (chromatin)

9. Cytokinesis Cell membrane grows into the center of the cell and divides it into two daughter cells of equal size – each daughter cell has about half of the parent’s cytoplasm and organelles

10. Cytokinesis Animal cells: cell is pinched in half by a belt of protein threads Plant cells: vesicles holding cell wall material line up in the middle to fuse into a cell plate which separates the new cells

12. End Results Two identical cells New daughter cells half the size of the parent cell Each cell enters G1

13. Types of Cell Reproduction Asexual: single parent passes a complete copy of its genetic information to each of its offspring – Offspring look identical to parent (MITOSIS)

14. Types of Cell Reproduction Sexual: two parents give genetic material to produce offspring that are genetically different from their parents (MEIOSIS) What are some advantages of sexual reproduction?

15. Meiosis Process in which a cell is divided and produces gametes (sperm or eggs): 2 rounds of division (P-I, M-I, A-I, T- I, then P-II, M-II, A-II, and T-II) – end with 4 haploid cells

16. Homologous Chromosomes Chromosomes that are similar in size, shape, and in kinds of genes that they contain Each chromosome in a homologous pair comes from one of the two parents Each species has a different number

17. Chromosome Number Gametes are haploid Somatic cells are diploid Example:  Horse skin cell = 64 chromosomes = diploid (2n)  Horse egg cell = 32 chromosomes = haploid (n)

18. Chromosome Number Species: a population of organisms that are able to breed and produce fertile offspring – Same number of chromosomes

19. Crossing Over Prophase I Chromatids exchange genetic material between homologous chromosomes during meiosis  What is the advantage of crossing over?

20. Meiosis Two divisions to get 4 haploid cells

21. Comparing Mitosis and Meiosis

22. ProcessLocation# of Cells Produced Haploid/ Diploid Type of Cell Produced Importance of Process MitosisSomatic Cells (Ex: skin cells) 2diploidIdentical diploid cells Healing/repair, maintenance/replac ement of old cells, and growth MeiosisSex Cells (gametes) 4haploidDifferent haploid cells Reproductive purposes; increases genetic diversity amongst organisms Comparing Mitosis and Meiosis