1. MITOSIS & MEIOSIS
2. CELLS & CELL DIVISION Organisms are composed of cells
Cells arise from preexisting cells
Cells have various components
Organelles
Chromosomes
Contain genetic material (DNA)
Different species have different numbers of chromosomes
Cell division segregates these components into daughter cells
3. CELL DIVISION Two types of eukaryotic cell division
Mitosis
Produces identical cells
Meiosis
Produces sperm & egg
4. CELL CYCLE Interphase
No division
Preparation for mitosis
Chromosomes replicate
Mitotic phase
Mitosis
Division of the nucleus
Equally divides chromosomes
Cytokinesis
Divides cytoplasm (& organelles)
5. INTERPHASE Preparation for mitosis
Chromosomes replicate
1 chromosome ? 2 sister chromatids
6. MITOSIS Chromosomes equally divided into two daughter cells
Four stages
Prophase
Metaphase
Anaphase
Telophase
7. PROPHASE Chromosomes condense
Become thick and distinct
Nuclear membrane disassociates
Mitotic spindle begins to form
8. METAPHASE Chromosomes line up on equatorial plate
Mitotic spindle complete
Attached to chromosomes at centromere (kinetochore)
Also attached to centrioles (north & south poles)
Sister chromatids attached to opposite poles
9. ANAPHASE Sister chromatids separate
Now independent chromosomes
Move to opposite poles
Ultimately reach opposite poles
10. ANAPHASE Forces separating chromatids/chromosomes
Separation of poles
Shortening of microtubules
Kinetochore “eats” its way toward pole
11. TELOPHASE Prophase in reverse
Chromosomes decondense
Nuclear membranes reform
Mitotic spindle disappears
Cytokinesis generally begins
12. CYTOKINESIS Division of the cytoplasm
Generally begins during telophase
Protein ring contracts
Cleavage furrow forms
Cells ultimately separated
Organelles distributed to each daughter cell
13. MITOTIC CELL DIVISION Summary of mitotic cell division
One cell ? two identical cells
In humans 46 ? 46 + 46
14. MITOTIC CELL DIVISION Mitotic cell division produces daughter cells identical to the original cell
Many organisms reproduce �asexually via mitotic cell division
Sexual reproduction requires a �different type of cell division
15. SEXUAL REPRODUCTION Some cells can form gametes
Germ cells ? sperm & egg
Occurs in gonads
Testes & ovaries
Gametes must have reduced chromosome number
46 sperm + 46 egg ? 92 (too many!!!)
23 sperm + 23 egg ? 46 (normal number)
Meiosis halves chromosome number
16. CELL DIVISION Two types of eukaryotic cell division
Mitosis
Produces identical cells
Meiosis
Produces sperm & egg
17. HUMAN GENOME Most human cells possess 46 chromosomes
23 pairs of chromosomes
2 copies of each chromosome
Pairs of “homologous” chromosomes
18. HUMAN GENOME Most human cells possess 46 chromosomes
23 pairs of chromosomes
2 copies of each chromosome
Pairs of “homologous” chromosomes
“Diploid”
Sperm & egg possess 23 chromosomes
No pairs
1 copy of each chromosome
Produced by meiosis
“Haploid”
19. MEIOSIS Ultimately produces four haploid cells
Involves two divisions
Meiosis I
Prophase I
Metaphase I
Anaphase I
Telophase I
Meiosis II
Prophase II
Metaphase II
Anaphase II
Telophase II
20. INTERPHASE Preparation for meiosis
Chromosomes replicate
1 chromosome ? 2 sister chromatids
21. PROPHASE I Chromosomes condense
Homologous chromosomes paired
Nuclear membrane disassociates
Spindle begins to form
22. METAPHASE I Chromosomes line up on equatorial plate
Spindle complete
Attached to �chromosomes and �poles
Paired homologous �chromosomes �attached to opposite �poles
23. ANAPHASE I Homologous chromosomes separate
Sister chromatids remain attached
Move to opposite poles
Ultimately reach opposite poles
24. TELOPHASE I Prophase in reverse
Chromosomes decondense
Nuclear membranes reform
Spindle disappears
Cytokinesis
Products of meiosis I are haploid
No homologous pairs
No DNA replication prior �to meiosis II
25. MEIOSIS II Same as mitosis
26. MEIOSIS SUMMARY
27. MEIOTIC CELL DIVISION Summary of meiotic cell division
One cell ? four non-identical cells
In humans 46 ? 23 + 23 + 23 + 23
28. FERTILIZATION
29. WHY BOTHER WITH SEX? Asexual reproduction produces offspring genetically identical to the parent
Sexual reproduction produces genetically unique offspring
Increases genetic variation within a population
How is this accomplished?
Why is this genetic variation important?
30. GENETIC VARIATION Meiosis produces haploid cells
Different from the diploid parent cell
Different from each other
This genetic difference is due to two factors
Independent segregation of chromosomes
Genetic recombination (crossing over)
31. INDEPENDENT SEGREGATION The segregation of one chromosome pair is independent of the segregation of other pairs
32. INDEPENDENT SEGREGATION What is the chance that any particular gamete will receive only red chromosomes?
2n = 4
2n = 6
2n = 8
2n = 46
33. GENETIC VARIATION The independent segregation of different pairs of homologous chromosomes alone allows one person the ability to produce more genetically unique gametes than the number of people on earth
Crossing over further increases this genetic variation
34. CROSSING OVER While homologous chromosomes are paired in prophase I of meiosis, crossing over can occur
Breaking and rejoining of chromosomes
Reciprocal exchange of portions of homologous chromosomes
Crossing over further increases genetic variation
35. MITOSIS & MEIOSIS
36. NONDISJUNCTION Errors sometime occur, resulting in the unequal segregation of chromosomes
37. NONDISJUNCTION The effects of nondisjunction and other chromosomal alterations will be discussed later, during our discussion of �genetics
