1. Cell Cycle The cell cycle consists of three phases:
Interphase, which has 3 stages (G1, S, G2)
Mitosis – division of nucleus, which consists of 4 stages (PMAT)
Cytokinesis – division of the cytoplasm

2. Mitosis
A single parent passes a complete copy of its genetic information to each of its offspring
Form of asexual reproduction
Somatic cells in humans reproduce this way. (Somatic cells = nerve, muscle, skin, blood, etc.)

3. Asexual Reproduction
Offspring formed through asexual reproduction are genetically identical to the parent.
Different types:
Binary fission
Budding
Fragmentation

4. Asexual Reproduction Advantages: Disadvantages:
Simplest, most efficient method of reproduction
Can produce a lot of offspring in a short amount of time without using a lot of energy
Disadvantages:
Cannot adapt easily to a changing environment, which may cause entire population to die out
No genetic variation in the populations

5. Sexual Reproduction
Two parents give genetic material to produce offspring.
Germ cells are specialized cells for reproduction.
The reproductive cells are called gametes. (Egg and sperm)
Which combine during fertilization to form a zygote.
A single cell that is produced by union of two gametes.

6. Chromosomes Humans have 46 chromosomes or 23 pair
44 of these chromosomes are called autosomal chromosomes, which means chromosomes that do not determine sex.
The other 2 chromosomes are sex chromosomes, X and Y.
Females are XX
Males are XY

7. Human Chromosomes

8. Chromosomes
When fertilization occurs, 2 cells combine to form a zygote.
This zygote can only have 46 chromosomes in humans.
But how can 2 cells combine and still have only 46 chromosomes?
Because gametes are formed through meiosis.

9. Your cells have 23 pairs (46 total) of chromosomes:
plus X from Mom
plus X or Y from Dad
TOTAL = 46 chromosomes
Cells with two copies of each chromosome are diploid.

10. Diploid organisms must produce specialized cells for reproduction
Gametes (egg/sperm)
Gamete cells are haploid
Cells with only ONE copy of each chromosome pair

11. Chromosome Number Diploid Haploid 2n 1n
Cells that have 2 copies of each chromosome.
Cells that have 1 copy of each chromosome.
One copy came from mother cell and one came from father cell.
The chromosome came from either the mother or the father.

12. Why Meiosis?
Meiosis is needed to produce haploid cells with unpaired chromosomes from diploid cells.
Haploid cells are needed for sexual reproduction.
Sexual reproduction is needed for genetic diversity.

13. Meiosis
A form of cell division that produces daughter cells with half the number of chromosomes that are in the parent cell.
Used only to make gametes
Occurs only in reproductive organs
Produces genetically different daughter cells.

14. Cell Types Somatic Cells Gametes
These are body cells such as blood, skin, muscle, etc.
These are cells that are used for reproduction.
These cells are diploid in most animals.
These cells are haploid in most animals.
These cells are produced by mitosis in most animals.
These cells are produced by meiosis in most animals.

15. MEIOSIS

16. Meiosis Germ cells spend most of their time in Interphase.
During the S phase of Interphase the DNA is replicated.
In Meiosis though, two divisions of the nucleus occur producing four cells.
Meiosis I and II

17. Meiosis I
Remember each of our cells are diploid, which means that we have 2 copies of the #1 -22 chromosomes (Mom & Dad)
The two copies of the #1 chromosome are called homologous chromosomes.
The same for the two copies of the #2, #3, #4, etc.
They are all homologous chromosomes.

18. Homologous Chromosomes
Homologous chromosomes are chromosomes that are similar in size, shape, and have the same genes on them.
In meiosis I, the 2 copies of each chromosome pair up with each other.
Homologous Chromosomes

19. Homologus Chromosomes

20. Meiosis I
During meiosis I, the homologous chromosomes pair up and then are separated. Goes through PMAT
Forms 2 cells with half of the genetic material as the parent cell (haploid).

21. Meiosis II
These two cells then begin to divide again, but this time without an Interphase.
Why is that important?
Second division looks a lot like mitosis

22. Meiosis II
Chromosomes are separated into individual chromatids. (PMAT2)
Results in four haploid cells genetically different from each other and their parent.

23. Why go to all this trouble?
Genetic Variation – Meiosis mixes up chromosomes in the gametes.
You can have any combination of chromosomes 1 – 22 in egg/sperm
One possible combination:
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22

24. Variety is the spice of life!
223 possible combinations in just one egg/sperm by combining chromosomes randomly
8,388,608 different egg/sperm can form as a result of meiosis!
Genetic variation is made possible by sexual reproduction and gives organisms an advantage.

25. Mix it up even more!
Genetic variation is the different combinations of genes found in a population.
3 key contributions to genetic variation
Independent Assortment
Crossing Over
Random Fertilization

26. Independent Assortment
Occurs during metaphase I
Random separation of homologous chromosomes.
They can arrange so many different ways that the cells formed can have a variety of different chromosome combinations.
8,388,608 possible gametes in parents

27. Independent Assortment

28. Crossing Over Occurs during prophase I
The arms of homologous chromosomes can switch pieces (i.e. genetic material).

29. Crossing Over
Chromosomes can be formed that contain genes from both parents
Result: Unique, new assortment of genes! (genetic variation)

30. That is why YOU are so unique!
Random Fertilization
Any of these different sperm from an individual could fertilize any egg if they came into contact.
In humans, each parent could make about 8 million different gametes.
That give us 8 million x 8 million = almost 70 trillion possible children per couple!!
That is why YOU are so unique!

31. Meiosis Square Dance

32. Life Cycle of Sexually Reproducing Organisms
Zygote: A single diploid cell that is produced by union of two gametes (egg and sperm in humans).
Repeated Cell Cycles (Mitosis): will form a multicellular organism, made of many genetically identical diploid cells.
Meiosis: will occur in specialized organs (ovaries and testes in humans) to produce gametes.
Fertilization: will join two gametes to produce zygote and the cycle starts again.

34. Methods of Reproduction
Asexual Reproduction
Sexual Reproduction
One parent cell.
Two parent cells.
New cell will have same chromosome number as parent cell.
New cell will have ½ the chromosome number of the parent cell.
New cells contain the exact same DNA as the parent.
New cells will contain a combination of DNA from both parents.
Repeated mitosis
Meiosis and Fertilization