1. Cellular Reproduction, Part 1: Mitosis Lecture 10 Fall 2008

2. Cell Theory Cell theory: All organisms are made of cells1
Cell theory:
All organisms are made of cells
All cells arise from preexisting cells
How do new cells arise?
Cell division
the reproduction of cells

3. Cell Division What is cell division used for? Growth Wound repair2
Cell Division
What is cell division used for?
Growth
Wound repair
Reproduction
Both sexual and asexual

4. Cell Division Multicellular organisms start out life as a single cell3
Fig. 8.1
Multicellular organisms start out life as a single cell
A series of cell divisions occur that give rise to all the cells in an organisms body

5. Cell Division Two components Cytokinesis (“cell movement”)4
Two components
Cytokinesis (“cell movement”)
Division of the cytoplasm into two daughter cells
Division of the nucleus (and of the DNA)

6. Cell Division Two different types of nuclear division possible Mitosis5
Two different types of nuclear division possible
Mitosis
Form of cell division that leads to identical daughter cells with the full complement of DNA
Occurs in somatic cells
Cells of body that are not reproductive cells
Meiosis
Form of cell division that leads to non-identical daughter cells with one-half the complement of DNA
Forms gametes
Reproductive cells (sperm cells & egg cells)

7. Chromosomes Genome Gene Prokaryotes have one long DNA molecule6
Genome
the complete complement of an organisms genetic material, DNA
Gene
a discrete unit of hereditary information consisting of a specific nucleotide sequence in DNA
Prokaryotes have one long DNA molecule
Eukaryotes have many DNA molecules = chromosomes
Chromosome: a thread-like, gene-carrying molecule located in the nucleus

8. Chromosomes 7
Chromosomes in the nucleus contain most of an organisms genes
Some DNA in mitochondria and chloroplasts
Number of chromosomes vary depending on species
Somatic cells of humans = 46 chromosomes
Two sets of 23 chromosomes
23 from egg and 23 from sperm
Gametes of humans = 23 chromosomes

9. Chromosomes Chromosomes made of chromatin8
Chromosomes
Chromosomes made of chromatin
Complex of DNA and protein molecules
Role of protein molecules
Organize chromatin
Help control activity of gene
Mass of long fibers spread out in the nucleus
Chromatin fibers form compact chromosomes only during cell division
Each chromosome contains one very long, linear DNA molecule that carries several hundred to a few thousand genes
Fig. 12.3

10. DNA Packing 9
Chromosomes condense to structures visible with a light microscope
Histones attach to DNA
Histones – small proteins that assist with DNA packing
Creates an area called a nucleosome
DNA wrapped around histones
“beads on a string”
Tight helical fiber
Supercoil
More looping & folding
Fig

11. Replication of Chromosomes10
DNA needs to be duplicated prior to cell division
Duplicated chromosome = sister chromatids
Held together by adhesive proteins (cohesins)
Centromere
Specialized region where sister chromatids most closely attached
During mitosis, sister chromatids separate, one each to the two daughter cells
Once separated, they are now individual chromosomes
Fig. 12.4

12. The Cell Cycle Cell cycle Life cycle of the cell11
Cell cycle
Life cycle of the cell
Starts with origination of a cell and ends with cell division
Two main phases
Interphase
~90% of time
Mitotic phase
~10% of time
Fig. 12.5

13. The Cell Cycle Interphase Normally activity of cell12
Interphase
Normally activity of cell
Cell grows as it produces more contents of cell cytoplasm
Chromosome duplication occurs
Fig. 12.5

14. The Cell Cycle Interphase G1 (first gap) S phase (synthesis)13
Interphase
Cell growth occurs in all three sub-phases
G1 (first gap)
S phase (synthesis)
Chromosome replication
Sister chromatids
G2 (second gap)
Cell preparing to divide
Fig. 12.5

15. Mitosis Mitotic phases Prophase Prometaphase Metaphase Anaphase14
Mitotic phases
Prophase
Prometaphase
Metaphase
Anaphase
Telophase
Cytokinesis occurs during telophase

16. Activity

17. G2 of Interphase Chromosomes (chromatin) duplicated15
Chromosomes (chromatin) duplicated
Chromosomes still uncondensed
Not clearly distinguishable as separate chromosomes
Centrosome
Non-membrane bound organelle
Organizes the cell’s microtubules
Centrosome replicates into 2
Contains centrioles
Structures made of microtubules
Found only in animals
Microtubules will form even if centrioles destroyed
Fig. 12.6

18. Mitosis: Prophase Chromosomes condense Formation of mitotic spindle16
Chromosomes condense
Each chromosome appears as two identical sister chromatids joined together
Formation of mitotic spindle
Centrosomes move towards poles of cell
Microtubules extend from centrosomes
Asters – short microtubules extending from centrosome
Will guide the separation of the daughter chromosomes
Fig. 12.6

19. Mitosis: Prometaphase17
Breakdown of nuclear envelope
Microtubules of mitotic spindle start to attach to chromosomes
Centromere contains special attachment proteins
kinetochore
Movement of chromosomes towards center of cell
Non-kinetochore microtubules interact with others from opposite pole
Fig. 12.6

20. Mitosis: Metaphase Centrosomes at opposite poles18
Centrosomes at opposite poles
Mitotic spindle fully formed
Chromosomes lined up at equator of cell (metaphase plate)
Each sister chromatid is attached to a kinetochore microtubule
Other non-kinetochore microtubules meet with each other from opposite ends of the cell
Fig. 12.6

21. Mitosis: Anaphase Sister chromatids of each chromosome separate19
Sister chromatids of each chromosome separate
Cohesion proteins cleaved
Now a “daughter” chromosome
Chromosomes move away from center, towards poles
Kinetochore microtubules shorten & bring chromosomes with them towards each pole
Read Fig Inquiry
Cell elongates
Non-kinetochore microtubules lengthen
Pushes poles of cell further apart
End of Anaphase
Both poles have equivalent and complete set of chromosomes
Fig. 12.6

22. Mitosis: Telophase Chromosomes at poles of cell20
Chromosomes at poles of cell
Two daughter nuclei begin to form in the cell
Nuclear envelope forms around each one
Chromosomes become less condensed
Mitotic spindle deconstructed
Fig. 12.6

23. Cytokinesis Cytokinesis in animals Cleavage Cleavage furrow21
Cytokinesis in animals
Cleavage
Cleavage furrow
Shallow groove at equator of cell
Parent cell “pinched” in two by contraction of ring of microfilaments
Fig. 12.9

24. Cytokinesis Cytokinesis in plants Cell wall material bound in vesicles22
Cytokinesis in plants
Cell wall material bound in vesicles
Vesicles line up, fuse to form cell plate
Grows until it fuses with plasma membrane
Cell wall contents bind with cell wall
Fig. 12.9

25. Asexual Reproduction Mitosis also used to reproduce entire organisms23
Mitosis also used to reproduce entire organisms
Asexual reproduction
Reproduction involving only one parent that produces genetically identical (clone) offspring
Does not involve sperm and egg (no meiosis)
Fig. 8.2

26. Asexual Reproduction 24
Japanese knotweed broken stem sprouts shoots and roots
Aspen root “suckers” – produce new shoots and stems

27. Asexual Reproduction Binary fission Prokaryotes Not mitosis25
Binary fission
Prokaryotes
Not mitosis
Single large circular chromosome
Chromosome duplicated
Starts at origin of replication
Copy of origin site moves to other pole of cell
Cell elongates
Plasma membrane grows inward to form two daughter cells
Fig

28. Evolution of Mitosis 26
Hypothesis: mitosis evolved from binary fission in prokaryotes
Some similar proteins
Possible intermediate stages still seen other organisms
Fig