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Transcript
Lecture # 14
Chapter 7
Mitosis and Meiosis
7.1 Prokaryotes Have a Simple Cell Cycle
• Prokaryotic cells divide asexually
– These cells possess a single
circular chromosome, containing
about 1000 genes
– The chromosome is replicated
– The cell then divides into two cells,
a process called binary fission
Fig. 7.1
7.2 Eukaryotes Have a Complex Cell Cycle
• Cell division in eukaryotes is more complex than in
prokaryotes because
– 1. Eukaryotic contain far more DNA
– 2. Eukaryotic DNA is packaged differently
• It is in linear chromosomes compacted with proteins
• Some eukaryotes also
make exact copies of
themselves via asexual
reproduction
amoeba
7.2 Eukaryotes Have a Complex Cell Cycle
Interphase
Mitosis
Cytokinesis
– G1 phase
• Primary growth phase
– S phase
• DNA replication
– G2 phase
• Microtubule synthesis
– M phase
• Chromosomes pull apart
– C phase
• Cytoplasm divides
Fig. 7.2 How the cell cycle works
7.3 Chromosomes
• Diploid cells have two similar copies of each chromosomes
• Chromosomes exist in somatic cells as pairs
– Homologous chromosomes or homologs
• Replicated chromosomes consist of two identical
sister chromatids
– These are held together at the centromere
Fig. 7.3
• Before a cell starts
dividing, the
chromosomes
duplicate
• This process
produces identical
sister chromatids
Chromosome
duplication
Sister
chromatids
• When the cell divides,
the sister chromatids separate
• Each of the two daughter cells has a
complete and identical set of chromosomes
Centromere
Chromosome
distribution
to
daughter
cells
• Humans have 46
chromosomes or 23
pairs of homologs
• The chromosomes
can be organized by
size into a karyotype
Fig. 7.4
•
•
A typical human chromosome contains about 1000 genes and about 140
million nucleotides in its DNA
• About 5 cm in stretched length
• 2,000 printed books of 1,000 pages each!
In the cell, however, the DNA is coiled into chromatin
– Complex of DNA (~ 40%) and proteins (~ 60%)
Levels of eukaryotic chromosome organization
•The DNA helix is wrapped around positively-charged proteins, called histones
•200 nucleotides of DNA coil around a core of histones, forming a nucleosome
•The nucleosomes coil into solenoids
•Solenoids are then organized into looped domains
•The looped domains appear to form rosettes on scaffolds
Fig. 7.5
7.2 Eukaryotes Have a Complex Cell Cycle
Eukaryotic cells divide in
one of two ways
– Meiosis
• Occurs in germ
(reproductive)
cells
• Results in the
production of
gametes
– Mitosis
• Occurs in
somatic (nonreproductive)
cells
Haploid gametes (n = 23)
Egg cell
Sperm cell
MEIOSIS
FERTILIZATION
Diploid
zygote
(2n = 46)
Multicellular
diploid adults
(2n = 46)
Mitosis and
development
7.4 Mitisos
Mitotic cell division allows a fertilized egg to develop
into an embryo, an adolescent and eventually an
adult
sea urchin
embryo
• Organisms can regenerate some body parts
These sea stars are regenerating using mitosis.
What can humans regenerate?
skin
Dead
cells
- Asexual
reproduction,
development,
growth and cell
replacement
are mitotic
divisions
Epidermis,
the outer
layer of the
skin
Dividing
cells
Dermis
Prophase
• Chromosomes coil
• Nuclear membrane
breaks down
• Spindle fibers form
Metaphase
• Chromosomes
line up on the
midline
• Spindle fibers
attach to
centromeres
Anaphase
• Centromeres divide
• Spindle fibers shorten
• Sister chromatids
separate and move to
opposite poles
Telophase
• Cell elongates
• Nuclear membrane reforms
•
• Chromosomes uncoil
• Spindle disappears
Cytokinesis
• Division of the cytoplasm
• Cleave furrow forms at
equator of the cell
• Constriction tightens by
contraction of filaments
• Cell is divided into two
identical cells
• Cytokinesis
• Animal cells
– Cleavage furrow forms,
pinching the cell in two
Fig. 7.8
• Plant cells
– Cell plate forms,
dividing the cell
in two