Lecture Outline
From Cell To Silver
Salmon
A. The cycle of life includes fertilization of
gametes, cell division and growth, production of gametes, and death.
B. All of life depends on the capacity of cells
to divide.
9.1 Dividing
Cells: The Bridge Between Generations
A. Overview of Division Mechanisms
1. Before cells are able to reproduce, there
must be a division of the nucleus and its DNA.
2. Mitosis and meiosis are eukaryotic nuclear
division mechanisms that lead to the distribution of DNA to new nuclei in
forthcoming daughter cells.
a. Mitosis is used by multicelled
organisms for growth by repeated divisions of somatic cells.
b. Meiosis occurs only in germ cells that divide
to form gametes.
B. Some Key Points About
Chromosomes
1. Each chromosomes is
a molecule of DNA complexed with proteins.
a. Prior to division, each threadlike chromosome
is duplicated to form two sister chromatids held together by a centromere.
b. The centromere is
also the region where the duplicated chromosome will attach to the microtubules
of the spindle during nuclear division.
2. Proteins called histones tightly bind to DNA
and cause spooling into a structural unit called a nucleosome.
C. Mitosis and the Chromosome Number
1. Each species has a characteristic chromosome
number (for example: human somatic cells contain 46 chromosomes).
2. Chromosomes exist as pairs: one member of
each pair from each parent.
a. Somatic cells are diploid; that is, they have
two of each type of chromosome.
b. Germ cells (egg and sperm) are haploid–only
one chromosome of each type.
3. Mitosis maintains the chromosome number of
the species through all the divisions of development, growth, and repair.
9.2 The Cell
Cycle
A. The cell cycle is a recurring sequence of
events that extends from the time of a cell’s formation until each division is
completed.
B. The Wonder of Interphase
1. Most of a cell’s existence (about 90 percent)
is spent in interphase; mitosis occupies only a small part.
2. During interphase the cell’s mass increases,
the cytoplasmic components approximately
double in number, and the DNA is
duplicated (S).
a. In G1, most of the carbohydrates, lipids, and
proteins for a cell's own use and for export are assembled.
b. In the S phase, the cell copies its DNA and
synthesizes proteins used in organizing the condensed chromosomes.
c. In G2, the proteins that will drive mitosis
to completion are produced.
3. Some cells are arrested in interphase and
never divide again (example: brain cells).
C. Mitosis Proceeds Through
Four Stages
1. The four sequential stages of mitosis are:
prophase, metaphase, anaphase, and telophase.
2. The spindle apparatus moves the chromosomes.
a. The spindle apparatus is composed of two sets
of microtubules.
b. Microtubules (components of the cytoskeleton)
extend from the two “poles” of the cell and overlap at the cell equator.
9.3 Mitosis
A. Prophase: Mitosis Begins
1. Chromosomes become visible as rodlike units, each consisting of two sister chromatids.
2. In the cytoplasm, the microtubules of the
cytoskeleton break apart and begin reassembling near the nucleus.
a. Microtubules are composed of numerous
subunits called tubulins.
b. Some microtubules extend from the centromeres
to one of the two poles; others extend from the poles, overlap in the middle of
the cell, but do not contact the chromosomes.
3. The nuclear envelope begins to disintegrate.
4. The centrioles,
which have duplicated by the time prophase is underway, are now moved by the
microtubules to the opposite poles of the cell
B. Transition to Metaphase
1. The nuclear membrane now breaks up completely
in the transition between pro- and metaphase.
2. Sister chromatids, each attached to microtubules,
become oriented toward opposite poles.
3. When all the chromosomes are aligned at the
cell’s equator, halfway between the poles, we call the stage metaphase.
C. From Anaphase Through
Telophase
1. Sister chromatids separate and move toward
opposite poles.
a. Microtubules attached to the centromeres shorten and pull the chromosomes toward
the poles.
b. Other microtubules at the spindle poles ratchet past each other to push the two
spindle poles apart.
c. Once separated, each chromatid
is now an independent chromosome.
2. Telophase begins
when the two daughter chromosomes of each original chromatid
pair arrive at opposite poles.
a. Chromosomes return to the threadlike form
typical of interphase.
b. The nuclear envelope reforms from the fusion
of small vesicles
c. Each daughter cell has the same number of
chromosomes as the parent cell; mitosis is complete.
9.4 Division of
the Cytoplasm
A. Cell Plate Formation in Plants
1. Because of the rather rigid cell wall, the
cytoplasm of plant cells cannot just be pinched in two.
2. Instead vesicles containing remnants of the microtubular spindle form a disklike
structure during cell plate formation.
B. Cytoplasmic
Division of Animal Cells
1. The flexible plasma membrane of animal cells
can be squeezed in the middle to separate the two daughter cells–a process
called cleavage.
2. Parallel arrays of contractile microfilaments
slide past one another at the cleavage furrow, pulling the plasma membrane
inward.
C. Perspective on Mitotic Cell Division
1. Mitosis usually proceeds with astonishing
accuracy.
2. Occasionally, there are mistakes that lead to
omission of chromosome parts and at other times chromosomes (and their cells)
duplicate unchecked.