1. Biology Sylvia S. Mader Michael Windelspecht
Chapter 9
The Cell Cycle and Cellular Reproduction
Lecture Outline
See separate FlexArt PowerPoint slides for all figures and tables pre-inserted into PowerPoint without notes. 1
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 1

2. Biology, 9th ed,Sylvia Mader
Chapter 09
Outline
The Cell Cycle
9.1 The Cell Cycle
9.2 Mitosis and Cytokinesis
9.3 The Cell Cycle and Cancer
9.4 Prokaryotic Cell Division

3. Biology, 9th ed,Sylvia Mader
Chapter 09
9.1 The Cell Cycle
The Cell Cycle
The cell cycle is an orderly set of stages from the first division to the time the resulting daughter cells divide
Just prior to the next division:
The cell grows larger
The number of organelles doubles
The DNA is replicated
The two major stages of the cell cycle:
Interphase (includes several stages)
Mitotic Stage (includes mitosis and cytokinesis)

4. Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Interphase S
(growth and DNA
replication)
G1 checkpoint
Cell cycle main checkpoint.
If DNA is damaged, apoptosis
will occur. Otherwise, the cell
is committed to divide when
growth signals are present
and nutrients are available. G1
G2 checkpoint
Mitosis checkpoint.
Mitosis will occur
if DNA has
replicated properly.
Apoptosis will
occur if the DNA is
damaged and
cannot be repaired. G2
(growth and final
preparations for
division) G1
(growth) G0 M G2
Cytokinesis
elophase
Prophase
Anaphase
Metaphase
Late prophase T M
M checkpoint
Spindle assembly
checkpoint. Mitosis
will not continue if
chromosomes are
not properly aligned.

5. Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle
The Cell Cycle
Interphase
Most of the cell cycle is spent in interphase
Cell performs its usual functions
Time spent in interphase varies by cell type
Nerve and muscle cells do not complete the cell cycle (remain in the G0 stage)

6. Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle
The Cell Cycle
Interphase consists of: G1, S, and G2 phases
G1 Phase:
Recovery from previous division
Cell doubles its organelles
Cell grows in size
Cell accumulates raw materials for DNA synthesis
S Phase:
DNA replication
Proteins associated with DNA are synthesized
Chromosomes enter with 1 chromatid each
Chromosomes leave with 2 identical chromatids (sister chromatids) each
G2 Phase:
Between DNA replication and onset of mitosis
Cell synthesizes proteins necessary for division

7. Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle
The Cell Cycle
M (Mitotic) Stage
Includes:
Mitosis
Nuclear division
Daughter chromosomes are distributed by the mitotic spindle to two daughter nuclei
Cytokinesis
Division of the cytoplasm
Results in two genetically identical daughter cells

8. Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle
The Cell Cycle
The cell cycle is controlled by internal and external signals
A signal is a molecule that either stimulates or inhibits a metabolic event.
Internal signals
Family of proteins called cyclins that increase and decrease as the cell cycle continues
Without cyclins, the cell cycle stops at G1, M or G2 (checkpoints)
Allows time for any damage to be repaired

9. Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle
The Cell Cycle
Apoptosis is programmed cell death
It involves a sequence of cellular events:
fragmenting of the nucleus,
blistering of the plasma membrane
engulfing of cell fragments.
Apoptosis is caused by enzymes called caspases.
Mitosis and apoptosis are opposing forces
Mitosis increases cell number
Apoptosis decreases cell number

10. Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle
Apoptosis
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
apoptotic cell
blebs
DNA
fragment
Cell rounds
up, and nucleus
collapses.
Chromatin
condenses, and
nucleus fragments.
Plasma membrane
blisters, and blebs
form.
Cell fragments
contain DNA
fragments.
cell
fragment
Courtesy Douglas R. Green/LaJolla Institute for Allergy and Immunology

11. Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle
The Cell Cycle
Apoptosis
Cells harbor caspases that are kept in check by inhibitors
Can be unleashed by internal or external signals
Signal protein p53
Stops the cell cycle at G1 when DNA is damaged
Initiates an attempt at DNA repair
If successful, the cycle continues to mitosis
If not, apoptosis is initiated

12. Regulation at the G1 Checkpoint
Biology, 9th ed,Sylvia Mader
Chapter 09
Regulation at the G1 Checkpoint
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
CDK
not present
CDK present P
E2F binds to DNA. P RB
protein
E2F RB
protein
E2F
E2F
DNA
released
E2F
E2F not released
phosphorylated RB
cell cycle
proteins a.
no DNA
damage
breakdown
of p53
p53
p53 binds to DNA.
DNA
damage P P P P
DNA
DNA
phosphorylated p53
DNA repair
proteins
apoptosis b.

13. 9.2 Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
9.2 Mitosis and Cytokinesis
The Cell Cycle
DNA is in very long threads
Chromosomes
Stretched out and intertwined between divisions
DNA is associated with histones (proteins)
DNA and histone proteins are collectively called chromatin
Before mitosis begins:
Chromatin condenses (coils) into distinctly visible chromosomes
Each species has a characteristic chromosome number

14. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
The diploid (2n) number includes two sets of chromosomes of each type
Humans have 23 different types of chromosomes
Each type is represented twice in each body cell (diploid)
Only sperm and eggs have one of each type ·termed haploid (n)
The haploid (n) number for humans is 23
Two representatives of each chromosome type
Makes a total of 2n = 46 in each nucleus
One set of 23 from individual’s father (paternal)
Other set of 23 from individual’s mother (maternal)

15. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
At the end of S phase:
Each chromosome internally duplicated
Consists of two identical DNA chains
Sister chromatids (two strands of genetically identical chromosomes)
Attached together at a single point (called centromere)
During mitosis:
Centromeres holding sister chromatids together separate
Sister chromatids separate
Each becomes a daughter chromosome
Sisters of each type are distributed to opposite daughter nuclei

16. Duplicated Chromosomes
Biology, 9th ed,Sylvia Mader
Chapter 09
Duplicated Chromosomes
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
sister chromatids
centromere
kinetochore
one chromatid a.
9,850 b.
© Andrew Syred/Photo Researchers, Inc.

17. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
Just outside the nucleus is the centrosome
This is the microtubule organizing center in animal cells
Organizes the mitotic spindle
Contains many fibers
Each fiber is composed of a bundle of microtubules
In animals, the centrosome contains two barrel-shaped centrioles
Oriented at right angles to each other within the centrosome
Each has 9 triplets of microtubules arranged in a cylinder
Centrosome was also replicated in S-phase, so there are two centrosomes before mitosis begins

18. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
Phases of Mitosis:
Prophase
Chromatin has condensed
Chromosomes are distinguishable with microscope
Each chromosome has two sister chromatids attached at the centromere
Nucleolus disappears
Nuclear envelope disintegrates
Spindle begins to assemble
The two centrosomes move away from each other
Microtubules form star-like arrays termed asters

19. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
Phases of Mitosis
Prometaphase
The centromere of each chromosome develops two kinetochores
Specialized protein complex
One attached to each sister chromatid
Physically connect sister chromatids with specialized microtubules (kinetochores)
These connect sister chromatids to opposite poles of the mother cell

20. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
Stages of Mitosis
Metaphase
Chromosomes are pulled around by kinetochore fibers
Forced to align across the equatorial plane of the cell
Metaphase plate - Represents plane through which mother cell will be divided
Anaphase
Centromere dissolves, releasing sister chromatids
Sister chromatids separate
Now called daughter chromosomes
Pulled to opposite poles along kinetochore fibers

21. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
Stages of Mitosis
Telophase
Spindle disappears
Now two clusters of daughter chromosomes
Still two of each type with all types represented
Clusters are incipient daughter nuclei
Nuclear envelopes form around the two incipient daughter nuclei
Each daughter nucleus receives one chromosome of each type

22. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
Cytokinesis = division of cytoplasm
Allocates the mother cell’s cytoplasm equally to daughter nucleus
Encloses each daughter cell in its own plasma membrane
Often begins in anaphase
Animal cytokinesis:
A cleavage furrow appears between daughter nuclei
Formed by a contractile ring of actin filaments
Like pulling on a drawstring
Eventually pinches the mother cell in two

23. Mitosis and Cytokinesis
Biology, 9th ed,Sylvia Mader
Chapter 09
Mitosis and Cytokinesis
The Cell Cycle
Cytokinesis in plant cells begins with the formation of a cell plate
Rigid cell walls outside plasma membrane do not permit furrowing
Many small membrane-bounded vesicles
Eventually fuse into one thin vesicle extending across the mother cell
The membranes of the cell plate become the plasma membrane between the daughter cells
The space between the daughter cells becomes filled with the middle lamella
Daughter cells later secrete primary cell walls on opposite sides of the middle lamella

24. Cytokinesis in Animal Cells
Biology, 9th ed,Sylvia Mader
Chapter 09
Cytokinesis in Animal Cells
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
X 4,000
Cleavage furrow
Contractile ring
X 4,000
(top): © Thomas Deerinck/Visuals Unlimited; (bottom): © SPL/Getty RF

25. Phases of Mitosis in Animal and Plant Cells
Biology, 9th ed,Sylvia Mader
Chapter 09
Phases of Mitosis in Animal and Plant Cells
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
has centrioles
centrosome
Animal Cell
at Interphase
aster
20 µm
duplicated
chromosome
20 µm
spindle
pole
9 µm
metaphase plate
chromosomes at
20µm
daughter chromosome
20µm
cleavage furrow
16µm
nuclear
envelope
fragments
centromere
kinetochore
nucleolus
MITOSIS
chromatin
condenses
nucleolus
disappears
spindle
fibers forming
spindle fiber
kinetochore
kinetochore
spindle fiber
polar spindle fiber
Metaphase
Centromeres of duplicated chromosomes
of fully formed spindle). Kinetochore spindle
are aligned at the metaphase plate (center
fibers attached to the sister chromatids
come from opposite spindle poles.
Telophase
Daughter cells are forming
as nuclear envelopes and
nucleoli reappear. Chromosomes will
become indistinct chromatin.
Early Prophase
Centrosomes have duplicated.
Chromatin is condensing into
chromosomes, and the nuclear
envelope is fragmenting.
Prophase
duplicated chromosomes are visible.
Nucleolus has disappeared, and
Centrosomes begin moving apart,
and spindle is in process of forming.
Prophase
duplicated chromosomes are visible.
Nucleolus has disappeared, and
Centrosomes begin moving apart,
and spindle is in process of forming.
Anaphase
Sister chromatids part and become daughter
chromosomes that move toward the spindle
poles. In this way, each pole receives the same
number and kinds of chromosomes as the parent cell.
centrosome
lacks centrioles
Plant Cell
at Interphase
25µm
cell wall
chromosomes
6.2µm
spindle pole lacks
centrioles and aster
20µm
spindle fibers
6.2µm
6.2µm
cell plate
6.6µm
Animal cell(Early prophase, Prophase, Metaphase, Anaphase, Telophase): © Ed Reschke; Animal cell(Prometaphase): © Michael Abbey/Photo Researchers, Inc.;
Plant cell(Early prophase, Prometaphse): © Ed Reschke; Plant cell(Prophase, Metaphase, Anaphase): © R. Calentine/Visuals Unlimited; Plant cell(Telophase): © Jack M. Bostrack/Visuals Unlimited; 25

26. Phases of Mitosis in Animal and Plant Cells
Biology, 9th ed,Sylvia Mader
Chapter 09
Phases of Mitosis in Animal and Plant Cells
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
centrosome
has centrioles
Animal Cell
at Interphase
aster
20 µm
duplicated
chromosome
20 µm
spindle
pole
9 µm
chromosomes at
metaphase plate
20 µm
daughter chromosome
20 µm
cleavage furrow
16 µm
Telophase
Daughter cells are forming
as nuclear envelopes and
nucleoli reappear.
Chromosomes will
become indistinct chromatin.
nuclear
envelope
fragments
kinetochore
centromere
nucleolus
chromatin
condenses
MITOSIS
nucleolus
disappears
spindle
fibers forming
kinetochore
spindle fiber
kinetochore
spindle fiber
polar spindle fiber
Early Prophase
Centrosomes have duplicated.
chromosomes, and the nuclear
Chromatin is condensing into
envelope is fragmenting.
Prophase
Nucleolus has disappeared, and
duplicated chromosomes are visible.
Centrosomes begin moving apart,
and spindle is in process of forming.
Prometaphase
The kinetochore of each chromatid is
attached to a kinetochore spindle fiber.
Polar spindle fibers stretch from each
spindle pole and overlap.
Metaphase
Centromeres of duplicated chromosomes
of fully formed spindle). Kinetochore spindle
are aligned at the metaphase plate (center
fibers attached to the sister chromatids
come from opposite spindle poles.
Anaphase
Sister chromatids part and become daughter
poles. In this way, each pole receives the same
chromosomes that move toward the spindle
number and kinds of chromosomes as the parent cell.
Telophase
centrosome
lacks centrioles
Plant Cell
at Interphase
25 µm
cell wall
chromosomes
6.2 µm
spindle pole lacks
centrioles and aster
20 µm
spindle fibers
6.2 µm
6.2 µm
cell plate
6.6 µm
Animal cell(Early prophase, Prophase, Metaphase, Anaphase, Telophase): © Ed Reschke; Animal cell(Prometaphase): © Michael Abbey/Photo Researchers, Inc.; Plant cell(Early prophase, Prometaphse):
© Ed Reschke; Plant cell(Prophase, Metaphase, Anaphase): © R. Calentine/Visuals Unlimited; Plant cell(Telophase): © Jack M. Bostrack/Visuals Unlimited;

27. Phases of Mitosis in Animal and Plant Cells
Biology, 9th ed,Sylvia Mader
Chapter 09
Phases of Mitosis in Animal and Plant Cells
The Cell Cycle
Functions of mitosis:
Permits growth and repair.
In flowering plants, meristematic tissue retains the ability to divide throughout the life of the plant
In mammals, mitosis is necessary when:
A fertilized egg becomes an embryo
An embryo becomes a fetus
A cut heals or a broken bone mends

28. Phases of Mitosis in Animal and Plant Cells
Biology, 9th ed,Sylvia Mader
Chapter 09
Phases of Mitosis in Animal and Plant Cells
The Cell Cycle
Stem Cells
Many mammalian organs contain stem cells
Retain the ability to divide
Red bone marrow stem cells divide to produce various types of blood cells
Therapeutic cloning to produce human tissues can begin with either adult stem cells or embryonic stem cells
Embryonic stem cells can be used for reproductive cloning, the production of a new individual

29. Reproductive and Therapeutic Cloning
Biology, 9th ed,Sylvia Mader
Chapter 09
Reproductive and Therapeutic Cloning
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
remove and
discard egg
nucleus
egg
remove
Go nucleus
Implant
embryo
into
surrogate
mother
fuse egg
with Go
nucleus
Go cells from
animal to be
cloned
culture
embryonic
stem cells
a. Reproductive cloning
Clone is born
remove and
discard egg
nucleus
egg
nervous
remove
Go nucleus
fuse egg
with Go
nucleus
blood
Go somatic cells
culture
embryonic
stem cells
muscle
b. Therapeutic cloning

30. 9.3 The Cell Cycle and Cancer
Biology, 9th ed,Sylvia Mader
Chapter 09
9.3 The Cell Cycle and Cancer
The Cell Cycle
Abnormal growth of cells is called a tumor
Benign tumors are not cancerous
Encapsulated
Do not invade neighboring tissue or spread
Malignant tumors are cancerous
Not encapsulated
Readily invade neighboring tissues
May also detach and lodge in distant places (metastasis)
Results from mutation of genes regulating the cell cycle
Development of cancer
Tends to be gradual
May take years before a cell is obviously cancerous

31. The Cell Cycle and Cancer
Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle and Cancer
The Cell Cycle
Characteristics of Cancer Cells
Lack differentiation
Are non-specialized
Are immortal (can enter cell cycle repeatedly)
Have abnormal nuclei
May be enlarged
May have abnormal number of chromosomes
Often have extra copies of genes
Do not undergo apoptosis
Normally, cells with damaged DNA undergo apoptosis
The immune system can also recognize abnormal cells and trigger apoptosis
Cancer cells are abnormal but fail to undergo apoptosis

32. The Cell Cycle and Cancer
Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle and Cancer
The Cell Cycle
Characteristics of Cancer Cells
Form tumors
Mitosis is normally controlled by contact with neighboring cells – contact inhibition
Cancer cells have lost contact inhibition
Undergo metastasis
Original tumor easily fragments
New tumors appear in other organs
Undergo angiogenesis
Formation of new blood vessels
Brings nutrients and oxygen to the tumor

33. Biology, 9th ed,Sylvia Mader
Chapter 09
Progression of Cancer
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
New mutations arise, and one cell (brown) has the ability to start a tumor.
primary tumor
lymphatic
vessel
blood
vessel
Cancer in situ. The tumor is at its place of origin. One cell (purple)
mutates further.
lymphatic
vessel
blood
vessel
Cancer cells now have the ability to invade lymphatic and blood vessels
and travel throughout the body.
New metastatic tumors are found some distance from the primary tumor.

34. Cancer Cells vs. Normal Cells
Biology, 9th ed,Sylvia Mader
Chapter 09
Cancer Cells vs. Normal Cells
The Cell Cycle

35. The Cell Cycle and Cancer
Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle and Cancer
The Cell Cycle
Origin of Cancer
Oncogenes
Proto-oncogenes promote the cell cycle in various ways
If a proto-oncogene is mutated, it may become an oncogene
Tumor suppressor genes inhibit the cell cycle in various ways
If a tumor suppressor gene becomes inactive, it may promote cancer development
Both proto-oncogenes and tumor suppressor genes are normally regulated in coordination with organism’s growth plan

36. The Cell Cycle and Cancer
Biology, 9th ed,Sylvia Mader
Chapter 09
The Cell Cycle and Cancer
The Cell Cycle
Origin of Cancer
Chromosomes normally have special material at each end called telomeres
These get shorter each cell division
When they get very short, the cell will no longer divide
Telomerase is an enzyme that maintains the length of telomeres
Mutations in telomerase gene:
Cause telomeres to continue to lengthen, which
Allows cancer cells to continually divide

37. Biology, 9th ed,Sylvia Mader
Chapter 09
Causes of Cancer
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Heredity
Radiation
sources
growth
factor
growth factor
Activates signaling
proteins in a stimulatory
pathway that extends
to the nucleus.
Viruses
receptor
protein
Pesticides
and
herbicides
oncogene P
a. Influences that cause mutated proto-oncogenes
(called oncogenes) and mutated tumor
suppressor genes P
activated
protein
signaling P
protein
signaling
Stimulatory
pathway
phosphate
gene product
promotes
cell cycle
b. Effect of growth factor
Inhibitory
pathway
gene product
inhibits
cell cycle
proto-oncogene
Codes for a growth factor,
a receptor protein, or a
signaling protein in a
stimulatory pathway.
If a proto-oncogene
becomes an oncogene,
the end result can be
active cell division.
c. Stimulatory pathway and
inhibitory pathway
tumor suppressor gene
Codes for a signaling
protein in an inhibitory
pathway. If a tumor
suppressor gene mutates,
the end result can be
active cell division.
d. Cancerous skin cell
1,100X
d: © Biophoto Associates/Photo Researchers, Inc.

38. 9.4 Prokaryotic Cell Division
Biology, 9th ed,Sylvia Mader
Chapter 09
9.4 Prokaryotic Cell Division
The Cell Cycle
The prokaryotic chromosome is a ring of DNA
Folded up in an area called the nucleoid
1,000 X the length of cell
Replicated into two rings prior to cell division
Replicated rings attach to the plasma membrane
Binary fission
Splitting in two
Two replicate chromosomes are distributed to two daughter cells
Produces two daughter cells identical to original cell – asexual reproduction

39. Biology, 9th ed,Sylvia Mader
Chapter 09
Binary Fission
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
chromosome
1. Attachment of chromosome to
a special plasma membrane
site indicates that this
bacterium is about to divide.
cell wall
plasma
membrane
cytoplasm
© Dennis Kunkel Microscopy, Inc./Visuals Unlimited
SEM
2,345X

40. Binary Fission The Cell Cycle Biology, 9th ed,Sylvia Mader Chapter 09
Slide #40
Binary Fission
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
chromosome
1. Attachment of chromosome to
a special plasma membrane
site indicates that this
bacterium is about to divide.
cell wall
plasma
membrane
cytoplasm
2. The cell is preparing for binary
fission by enlarging its cell wall,
plasma membrane, and overall
volume.
© Dennis Kunkel Microscopy, Inc./Visuals Unlimited
SEM
2,345X 40

41. Binary Fission The Cell Cycle Biology, 9th ed,Sylvia Mader Chapter 09
Slide #41
Binary Fission
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
chromosome
1. Attachment of chromosome to
a special plasma membrane
site indicates that this
bacterium is about to divide.
cell wall
plasma
membrane
cytoplasm
2. The cell is preparing for binary
fission by enlarging its cell wall,
plasma membrane, and overall
volume.
3. DNA replication has produced
two identical chromosomes.
Cell wall and plasma membrane begin to grow inward.
© Dennis Kunkel Microscopy, Inc./Visuals Unlimited
SEM
2,345X 41

42. Binary Fission The Cell Cycle Biology, 9th ed,Sylvia Mader Chapter 09
Slide #42
Binary Fission
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
chromosome
1. Attachment of chromosome to
a special plasma membrane
site indicates that this
bacterium is about to divide.
cell wall
plasma
membrane
cytoplasm
2. The cell is preparing for binary
fission by enlarging its cell wall,
plasma membrane, and overall
volume.
3. DNA replication has produced
two identical chromosomes.
Cell wall and plasma membrane begin to grow inward.
4. As the cell elongates, the
chromosomes are pulled apart.
Cytoplasm is being distributed
evenly.
© Dennis Kunkel Microscopy, Inc./Visuals Unlimited
SEM
2,345X 42

43. Binary Fission The Cell Cycle Biology, 9th ed,Sylvia Mader Chapter 09
Slide #43
Binary Fission
The Cell Cycle
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
chromosome
1. Attachment of chromosome to
a special plasma membrane
site indicates that this
bacterium is about to divide.
cell wall
plasma
membrane
cytoplasm
2. The cell is preparing for binary
fission by enlarging its cell wall,
plasma membrane, and overall
volume.
3. DNA replication has produced
two identical chromosomes.
Cell wall and plasma membrane begin to grow inward.
4. As the cell elongates, the
chromosomes are pulled apart.
Cytoplasm is being distributed
evenly.
5. New cell wall and plasma
membrane has divided the
daughter cells.
© Dennis Kunkel Microscopy, Inc./Visuals Unlimited
SEM
2,345X 43

44. Functions of Cell Division
Biology, 9th ed,Sylvia Mader
Chapter 09
Functions of Cell Division
The Cell Cycle