Download Chapter 9 Cell Division

Chapter 9
Cellular Reproduction
Mitosis
And
The Cell Cycle
Cellular Growth



Cells grow until they
reach their size limit,
then they either stop
growing or divide.
Cell size is limited.
Most cells are less
than 100 micrometers
in diameter (smaller
than the period at the
end of the sentence in
your book)
Cell Size Limitation

Ratio of surface area to volume





Area covered by the plasma membrane
Volume – space taken by the inner contents of
the cell (organelles, cytoplasm, nucleus)
To calculate ratio: multiply length x width x
height of cell
The larger the cell, the less efficient it is
Small cells have a higher ratio of surface area
to volume and can sustain themselves more
easily.
Why does a high ratio of surface area to
volume benefit a cell?
Easier to transport substances
 As cell grows, its volume increases much
more rapidly than the surface area making
it difficult for the cell to supply nutrients
and to expel waste products.
 The smaller the cell, the more efficient it is
 Cells remain small to maximize the ability
of diffusion and motor proteins to
transport nutrients and waste products.

Cellular Communication

The need for signaling proteins to move
throughout the cell limits cell size

If cell becomes too large, it becomes almost
impossible for cellular communications

i.e., the signals that trigger protein synthesis might
not reach the ribosome fast enough for protein
synthesis to occur to sustain the cell
The Cell Cycle
Once a cell reaches its size limit – either it will
stop growing or it will divide
 Most cells divide
 Prevents cell from getting too large
 Allows for cell to reproduce
 Allows for growth
 Allows injuries to heal
 Cell grows and divides – The Cell Cycle –
One complete cycle produces two cells from each
original cell – provides continuous production of
new cells

The Cell Cycle

Three main stages

Interphase – cell growth, cell functions, copies DNA

3 stages
 Gap 1 – cell growth and normal functions
 Synthesis – DNA is replicated
 Gap 2 – cell prepares for Mitosis

Mitosis – cell’s nucleus and nuclear material divide

4 stages





Prophase
Metaphase
Anaphase
Telophase
Cytokinesis – cytoplasm divides, creating new cells
Synthesis stage of Interphase
Involves:
Chromosomes –
structures that contain
genetic material of cell
– passed on from
generation to
generation
Chromatin: relaxed
form of DNA in cell’s
nucleus
Prokaryotic Cell Division


Reproduce by a
method called binary
fission.
Eukaryotes use the
method known as the
Cell Cycle.
The Cell Cycle
Mitosis
Phases of Mitosis (PMAT)
Interphase-prior to
mitosis
Mitosis:
 Prophase
 Metaphase
 Anaphase
 Telophase

Interphase



Cell grows
Carries out normal cell
processes
DNA replicates
Prophase




Nuclear membrane
disintegrates
Nucleolus disappears
Chromosomes
condense
Spindle apparatus
begins to form
between poles
Metaphase

Chromosomes attach to spindle fibers and
align along equator of cell
Anaphase

Microtubules shorten, moving
chromosomes to opposite poles
Telophase
Chromosomes reach poles of cell
 Nuclear envelope re-forms
 Nucleolus reappears
 Chromosomes decondense

Cytokinesis

In plant cells:


Cell plate forms
Dividing daughter cells
In animal cells:
*Cleavage furrow forms at
equator of cell and
pinches inward until cell
divides in two
Cell Cycle Regulation
The normal cell cycle is regulated by cyclin
proteins.
 The timing and rate of cell division are
important to the health of an organism.
 Rate varies depending on type of cell.
 Role of cyclins: cyclins bind to enzymes
called cyclin-dependent kinases (CDKs)
in the stages of the cell cyle

Cell Cycle Regulation





Different cyclin/CDK combinations control
different activities at different stages in the cell
cycle.
Figure 9.11 on page 253 (know when cyclins/CDK
become active)
In G1 stage of interphase , the combination of
cyclin and CDK signals the start of the cell cycle.
Different cyclin/CDK combinations signal other
activities (DNA replication, protein synthesis, and
nuclear division)
The same cyclin/CDK combination also signals
the end of the cell cycle.
Cell Cycle Regulation
Quality control checkpoints
 A checkpoint near the end of the G1 stage
monitors for DNA damage and can stop
the cycle before entering the S stage of
interphase
 Spindle checkpoints also in place – if a
failure of the spindle fibers is detected, the
cycle can be stopped before cytokinesis.
 Note checkpoints on figure 9.11

Abnormal Cell Cycle: Cancer




Although there are checkpoints in cell cycle, the
process sometimes fails.
Cancer is the uncontrolled cell growth and
division of cells – a failure in the regulation of the
cell cycle.
Cancer cells can kill an organism by crowding out
normal cells, resulting in the loss of tissue
function.
Cancer cells spend less time in interphase than
normal cells, can grow and divide unrestrained as
long as they are supplied with essential nutrients.
Cancer



Causes – mutations or
changes in the segments
of DNA that control the
production of proteins
Repair system of these
changes fail
Environmental factors can
affect the occurrence as
well – carcinogens:
substances and agents
known to cause cancer
Cancer
Avoiding carcinogens can reduce the risk
of cancer.
 FDA works to make sure that what you eat
and drink are safe
 Known carcinogens – asbestos, tobacco,
radiation
 Ways to protect yourself –sunscreen, don’t
smoke or use tobacco, etc.

Cancer
Cancer genetics – chance of cancer
increases with age due to changes in DNA
 Inheriting risk increases chances of
getting cancer

Apoptosis







Not every cell is destined to survive
Some cells go through a process called
apoptosis – programmed cell death
Shrink and shrivel in a controlled process
All animal cells appear to have apoptosis
Example – human hands and feet – prevents
webbing
Example – plants – loss of leaves
Also occurs in cells that are damaged beyond
repair- protecting organisms from developing
cancerous growths
Stem Cells


Most cells are
designed for
specialized function
Stem cells are
unspecialized cells
that can develop into
specialized cells when
under the right
conditions
Stem Cells

Two basic types


Embryonic stem cells
Adult stem cells
Embryonic Stem Cells
Once a sperm fertilizes the egg, the
resulting mass of cells divides repeatedly
until there are about 100 – 150 cells.
 Not specialized yet – embryonic stem cells
 If separated, each of these has the
capability of developing into a wide variety
of specialized cells
 Controversial because of ethical concerns

Adult Stem Cells





Found in various tissues in the body
Might be used to maintain and repair the same
kind of tissue in which they are found
A newborn has adult stem cells
Might be able to develop into different kinds of
cells, providing new treatments for many
diseases and conditions
Less controversial because the adult stem cells
can be obtained with the consent of their donors
Treatment Using Adult Stem Cells


In 1999, researchers
at Harvard Medical
School used nervous
system stem cells to
restore lost brain
tissue in mice
In 2000, a team of
researchers at the
University of Florida
used pancreatic stem
cells to restore
pancreas function in a
mouse with diabetes