1. CELL DIVISION AND REPRODUCTION
Mitosis
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2. 8.1 Cell division plays many important roles in the lives of organisms
Cell division
is reproduction at the cellular level,
requires the duplication of chromosomes, and
sorts new sets of chromosomes into the resulting pair of daughter cells.
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3. 8.1 Cell division plays many important roles in the lives of organisms
Two types of cell division
Mitosis
asexual reproduction
reproduction of single-celled organisms,
reproduction of multicellular organisms
growth: increase in size
onion root tips
fertilized eggadult
repair and replacement of cells
Student Misconceptions and Concerns
1. As the authors note in Module 8.1, biologists use the term daughter to indicate offspring and not gender. Students with little experience in this terminology can easily become confused.
2. Some basic familiarity or faint memory of mitosis and meiosis might result in a lack of enthusiasm for mitosis and meiosis in some of your students. Consider beginning such lectures with important topics related to cellular reproduction. For example, cancer cells reproduce uncontrollably, stem cells have the capacity to regenerate lost or damaged tissues, and the study of embryonic stem cells is variously restricted and regulated.
Teaching Tips
Sometimes the most basic questions can challenge students and get them focused on the subject at hand. Consider asking your students why we expect that dogs will produce dogs, cats will produce more cats, and chickens will only produce chickens. Why does like produce like? 3

4. 8.1 Cell division plays many important roles in the lives of organisms
Two types of cell division
Meiosis
Production of gametes (reproductive cells)
Used in sexual reproduction
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5. 8.2 Prokaryotes reproduce by binary fission (Sexual or asexual reproduction?)
Prokaryotes (bacteria and archaea) reproduce by binary fission (“dividing in half”).
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6. Division into two daughter cells
Figure 8.2A_s3
Plasma
membrane
Prokaryotic
chromosome
Cell wall
Duplication of the chromosome
and separation of the copies 1
Continued elongation of the
cell and movement of the copies 2
Division into
two daughter cells 3 6

7. THE EUKARYOTIC CELL CYCLE AND MITOSIS
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8. 8.3 Eukaryotic chromosomes
Eukaryotic cells
store most of their genes on multiple chromosomes within the nucleus. (How many chromosomes in a human cell?)
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9. 8.3 Chromatin and chromosomes
Eukaryotic chromosomes are composed of chromatin
DNA + protein
To prepare for division, the chromatin becomes chromosomes
Why is this coiling of chromatin important?
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10. Chromosomes DNA molecules Sister chromatids Chromosome duplication
Figure 8.3B
Chromosomes
DNA molecules
Sister
chromatids
Chromosome
duplication
Sister
chromatids
Centromere
Figure 8.3B Chromosome duplication and distribution
Chromosome
distribution
to the
daughter
cells 10

11. 8.4 The cell cycle multiplies cells
The cell cycle is an ordered sequence of events that extends
from the time a cell is first formed from a dividing parent cell
until its own division.?
Do all cells divide
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12. I N T E R P H A S G1 (first gap) S (DNA synthesis) M G2 (second gap)
Figure 8.4 I N T E R P H A S G1
(first gap) S
(DNA synthesis) M
Cytokinesis G2
(second gap)
Mitosis
Figure 8.4 The eukaryotic cell cycle T MI O IC PH A SE 12

13. 8.4 Interphase Most of the cell cycle is spent in Interphase (90%)
Cell performs its various functions.
white blood cells
Intestinal cells
Pancreatic cells
A cell will
Make more cytoplasm/create organelles/grow in size
Synthesize proteins
Synthesize DNA

14. 8.5 Cell division (10 %)
Mitosis: Chromosomes are divided equally between two identical daughter nuclei
prophase,
prometaphase
metaphase,
anaphase, and
telophase.
Cytokinesis: cytoplasm is divided
Two identical daughter cells are produced..
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15. 8.5 Cell division is a continuum of dynamic changes
A mitotic spindle is
required to divide the chromosomes,
composed of microtubules, and
produced by centrosomes
organize microtubule arrangement and
contain a pair of centrioles in animal cells.
Video: Animal Mitosis
Video: Sea Urchin (time lapse)
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16. (with centriole pairs) Fragments of the nuclear envelope Early mitotic
Figure 8.5_1
MITOSIS
INTERPHASE
Prophase
Prometaphase
Centrosomes
(with centriole pairs)
Fragments of
the nuclear
envelope
Early mitotic
spindle
Centrosome
Kinetochore
Centrioles
Chromatin
Centromere
Nuclear
envelope
Plasma
membrane
Chromosome,
consisting of two
sister chromatids
Spindle
microtubules 16

17. Telophase and Cytokinesis
Figure 8.5_5
MITOSIS
Metaphase
Anaphase
Telophase and Cytokinesis
Metaphase
plate
Cleavage
furrow
Nuclear
envelope
forming
Mitotic
spindle
Daughter
chromosomes 17

18. 8.5 Interphase The cytoplasmic contents double, Two centrosomes form,
The cytoplasmic contents double,
Two centrosomes form,
chromosomes duplicate in the nucleus during the S phase, and
Nucleoli, sites of ribosome assembly, are visible.
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19. 8.5 Cell division: Mitosis
8.5 Cell division: Mitosis
Prophase
In the cytoplasm microtubules begin to emerge from centrosomes, forming the spindle.
In the nucleus
chromosomes coil and become compact and
nucleoli disappear.
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20. 8.5 Cell division: Mitosis
8.5 Cell division: Mitosis
Prometaphase
Spindle microtubules reach chromosomes, where they
attach at kinetochores on the centromeres of sister chromatids and
move chromosomes to the center of the cell through associated protein “motors.”
The nuclear envelope disappears.
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21. 8.5 Cell division: Mitosis
8.5 Cell division: Mitosis
Metaphase
The mitotic spindle is fully formed.
Chromosomes align at the cell equator.
Kinetochores of sister chromatids are facing the opposite poles of the spindle.
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22. 8.5 Cell division: Mitosis
8.5 Cell division: Mitosis
Anaphase
Sister chromatids separate
Daughter chromosomes are moved to opposite poles
motor proteins move the chromosomes along the spindle microtubules and
kinetochore microtubules shorten.
The cell elongates
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23. 8.5 Cell division: Mitosis
8.5 Cell division: Mitosis
Telophase
The cell continues to elongate.
The nuclear envelope forms around chromosomes at each pole
Chromatin uncoils and nucleoli reappear.
The spindle disappears.
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24. 8.5 Cell division: Mitosis
During cytokinesis, the cytoplasm is divided into separate cells.
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25. 8.6 Cytokinesis differs for plant and animal cells
In animal cells, cytokinesis occurs as
a cleavage furrow forms from a contracting ring of microfilaments, interacting with myosin
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26. Cleavage furrow Daughter cells
Figure 8.6A
Cytokinesis
Cleavage
furrow
Contracting ring of
microfilaments
Daughter
cells
Figure 8.6A Cleavage of an animal cell
Cleavage
furrow 26

27. 8.6 Cytokinesis differs for plant and animal cells
In plant cells, cytokinesis occurs as
a cell plate forms in the middle, from vesicles containing cell wall material,
Animation: Cytokinesis
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28. Cytokinesis New cell wall Cell wall of the parent cell Cell wall
Figure 8.6B
Cytokinesis
New
cell wall
Cell wall
of the
parent cell
Cell wall
Plasma
membrane
Daughter
nucleus
Vesicles
containing
cell wall
material
Cell plate
Daughter
cells
Figure 8.6B Cell plate formation in a plant cell
Cell plate
forming 28