1. Cell division Mitosis and Meiosis How cells divide

2. Purposes of Cell Division 1.Growth 2.Repair 3.Maintenance

3. Cell Division-the process by which a cell divides into two new daughter cells

4. - Has 4 phases: G1Interphase S G2 M - Mitosis The Cell Cycle- the activities of a cell from one cell division to the next

5. G1 – Gap phase 1 Growth - cell begins to grow in size; gets nutrients, builds cell parts If cell not big enough – when it divides the 2 daughter cells won't survive – not enough energy, not enough cell parts Mitochondria divide in plant and animal cells to make more (so there is enough for 2 cells) In plant cells chloroplasts divide to make more Cell checks if there is any damage – won't divide until it is repaired

6. S - Synthesis phase - Cell will duplicate, make an exact second copy of all it's chromosomes (1 chromosome = 1 molecule DNA) - This is when DNA Replication takes place G2 – Gap phase 2 - Cell gets ready to divide - Checks if all DNA is completely replicated - Check if there are no errors during Replication

7. Eukaryotic Chromosomes Organization

9. MITOSIS P- Prophase M- Metaphase A-Anaphase T-Telophase

11. Interphase chromosomes look like tangled rope, no individual chromosomes are visible – not condensed

12. Prophase chromosomes condense we clearly see them nuclear membrane breaks down centrioles move to opposite ends of cell

14. Metaphase The two identical pairs of chromosomes (sister chromatids) are sticking together Spindle fibers (come out of centrioles) – like ropes with hooks will attach to the chromosomes and pull them to the middle of the cell – the metaphase plate

16. Anaphase The spindle fibers contract (similar to muscles) The glue holding the two identical chromosomes (sister chromatids) breaks down The two sister chromatids are pulled by the spindle fibers to opposite ends of the cell

18. Telophase Chromosomes have moved to opposite ends Nuclear membrane re- forms around "new" chromosomes Cell begins Cytokinesis

20. Cytokinesis - The Cytoplasm and all its content divides in two - Cell division is complete: 2 new, daughter cells are formed - The daughter cells have identical chromosomes/DNA

21. Cytokinesis Animal Cells- microfilaments form a belt around the equator and contract to form two daughter cells.

22. Plant Cells- vesicles filled with cellulose fuse together at the equator to form a cell plate

24. Sexual Reproduction Meiosis

25. Cell Division and Reproduction Asexual reproduction-the production of genetically identical offspring from a single parent Types: Binary fission, budding, regeneration

26. Sexual reproduction-cells from two parents unite to form the first cell of a new organism

27. Budding Yeast Fission Yeast

29. Meiosis The process by which germ cells (sex cells) such as egg and sperm are created Has 2 divisions: Meiotic Division I and II Generates Genetic variety – the products of meiosis – the daughter cells – are NOT genetically identical Sexual Reproduction is responsible for the large variety of life on Earth

30. DNA replication 2 X 2n = 4n 2n 2 X 2n = 4n

31. Meiosis I Similar to Mitosis Phases are called Prophase I, Methapahse I, Anaphase I, Telophase I Major difference: Not only are sister chromatids together (the 2 exact copies of 1 chromosome), but two related, homologous chromosomes ( 1 from dad and the 1 form Mom) pair and recombine (mix and match) They exchange genetic information – mix and match – daughter cells are NOT identical to mother cell

32. Crossing Over Recombination of DNA occurs during prophase I of meiosis I Crossover, one piece of DNA from Mom's chromosome is replaced with another form Dad's

33. This increases the number of different gene combinations that occur in offspring

34. Meiosis II Phases are called Prophase II, Metaphase II, etc. The two daughter cells form Meiosis I divide again, but WITHOUT replicating their DNA Reduces DNA content in half – 2n to n The product of this division are 4 cells called gametes which have ½ the DNA – they are not identical to the original cell

35. Why reduce DNA content in half? Each gamete has now 1 of each chromosomes, so when it fuses with a gamete of the opposites sex it will have 2 of each (1 from Dad, 1 from Mom) – n + n = 2n Answer: Fertilization Everyone begins life as this single cell called a zygote or fertilized egg. The zygote or fertilized egg then grows by mitosis, producing Billions and Billions of cells with 46 chromosomes each

36. Fertilization How many chromosomes does each cell in human body have? Answer: 46 How many chromosomes are in the sex cells? Answer 23 Why is this important in fertilization? Answer: When sperm and egg fuse they each have 23 chromosomes. 23 (mom) + 23(dad) = 46 chromosomes

37. Genetic Variation Why does everyone look different? – The answer is genetic variation: different combinations of our parent’s DNA create different variations of people. Two main sources of genetic variation are recombination and mutations during sexual reproduction

38. Mutations We already know what mutations are - change in the sequence of nucleotides in the DNA, can be beneficial or harmful Only mutations in sex cells (sperm and egg) can be passed on to an offspring Helps to make different combinations of DNA and as a result different people

39. Recombination Crossover of the two related chromosomes (1 Dad and 1 Mom) produces mix and match – new combinations in DNA sequence in a chromosome These chromosomes are separated randomly during meiosis II – different gametes (egg or sperm cells) will have different combinations of chromosomes: remember there are 23 chromosomes – how many different combinations?

40. Recombination continued 2 X 23 chromosomes – randomly separated + the mix and match during crossover = Millions of different combinations A couple can produce a variety of offspring (how different are you from your siblings?) This is why we say that sexual reproduction generates all the variety of life on Earth.