11_4
TRANSCRIPT
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11-4 Meiosis
P275
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Homologous chromosomes
Pair of chromosomes that one comes from the male parent and the corresponding one from the female parent
Homologous ≠ identical
same genes in same loci
same length
same shape
may not the same alleles for one gene
Homologous chromosomes
Alleles
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Diploid & Haploid Cells
• two copies of each chromosome
• homologous pairs• body cells
• one copy of each chromosome
• no homologous pairs• gametes (sex cells)
Sperm
Egg
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Egg
Sperm
Zygote
Sperm?meiosis
Egg
fertilisation
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The purpose of meiosis is to produce gametes. A (haploid) gamete (sex cell, sperm or egg cell) has half the number of chromosomes compared to a (diploid) somatic cell (body cell). A male and a female gamete may then fuse to form a zygote, which will have the same number of chromosomes as a somatic cell.
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Human chromosomes
Diploid cells: 23 pairs of homologous chromosomes
1st-22nd pairs: autosomes
23rd pair: sex chromosome
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Human chromosomes
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1-22 pairs : autosomes, 23 pair : sex chormosome
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Karyotype (the type of nucleus)
• The number and appearance of the chromosomes in an organism
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Karyotyping
• Arrange the chromosomes in pairs according to their size and structure
• Collect cells• Culture cells• Stop cell division at metaphase• Staining chromosome• Pair (Length, Shape, Position of
centromeres, Bands) • Diagnosis (number, gender,
abnormality)
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8
4
3
1 : x,y
Fruit fly’s somatic cells How many pairs
of sex
chromosomes ?
How many pairs of
autosomes?
How many pairs of
homologous
chromosomes?
How many
chromosoems
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A B
C D
What is the correct gamete produced by the germ cell
germ cell
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Meiosis Overview
reduction division number of chromosomes per cell halvedseparation of homologous chromosomes 1 diploid 4 genetically different haploid DNA copied once, cell divide twice
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Sperms are produced by … meiosis
The chromosomes in the nucleus
are copied
Four haploid daughter cells
Diploid parent cell
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Eggs are also produced by meiosis
Haploid
Diploid parent cell
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Phases of meiosis
interphase (DNA replication before meiosis I)
PROPHASE I
METAPHASE I
ANAPHASE I
TELOPHASE I
PROPHASE I
METAPHASE I
ANAPHASE I
TELOPHASE I
MEIOSIS IMEIOSIS I
PROPHASE II
METAPHASE II
ANAPHASE II
TELOPHASE II
PROPHASE II
METAPHASE II
ANAPHASE II
TELOPHASE II
MEIOSIS IIMEIOSIS II
no interphase (no DNA replication
before meiosis II)
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Meiosis I
(reduction division)
Interphase I Prophase I Metaphase I Anaphase I
Cells undergo a round of DNA replication, forming duplicate Chromosomes.
Each chromosome pairs with its corresponding homologous chromosome to form a tetrad.
Spindle fibers attach to the chromosomes.
The fibers pull the homologous chromosomes toward the opposite ends of the cell.
Telophase I
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Prophase 1
1. Supercoil of chromosomes
2. Spindle form3. Synapsis
(homologous pair to form bivalents)
4. Crossing over5. Nuclear envelope
breaks down
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• The key to the process of meiosis is the Synapsis in Prophase I and the splitting of the homologues in Anaphase I.
• One event that can take place during meiosis is crossing over.
• Crossing over is the exchange of genetic material between two homologous chromosomes which have paired up during Prophase I.
• The result of crossing over is genetic recombination.
Synapsis & Crossing over
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Metaphase 1
1. Spindle network complete
2. Bivalents line up on equator
3. Centromere attached to microtubules
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Anaphase 1
1. Centromeres do not split
2. Microtubules contract to separate homologous pairs
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Telophase 1
1. Chromosomes uncoil
2. Spindle breaks down
3. Nuclear envelope reform
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Meiosis II
(similar to mitosis)
Meiosis I results in two haploid (N) daughter cells, each with half the number of chromosomes as the original.
Prophase II Metaphase II Anaphase II Telophase II
The chromosomes line up in a similar way to the metaphase stage of mitosis.
The sister chromatids separate and move toward opposite ends of the cell.
Meiosis II results in four haploid (N) daughter cells.
There is no DNA
replication
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Prophase 2
1. Supercoil of chromosomes
2. Spindle form
3. Nuclear envelope breaks down
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Metaphase 2
1. Chromosomes move to equator
2. Spindle network complete
3. Centromere attach to spindle
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Anaphase 2
1. Centromere split
2. Microtubules contract and sister chromatids separate
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Telophase 2
1. Chromosomes uncoil
2. Spindle breaks down
3. Nuclear envelope reforms
Cytokinesis 2
1. 4 haploid cells
2. 1 or many undergo differentiation into gametes
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Which steps in meiosis are important in
producing genetic variety?
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1. Crossing over in prophase 1
• Homologous chromosomes exchange nonsister chromatids
chiasmata
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2. Independent assortment in metaphase 1
• Bivalents line up on equator in a random way
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Possibilities of Crossing over
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e.g. 46 chromosomes, 23 pairs2n = 46; n = 232n = 223 = ~ 8 million possible combinations!
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3. Random fertilization
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Gamete formation in animals
• Male gametes (sperms) are formed through spermatogenesis
• Female gametes (egg) are formed through oogenesis
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Growth Meiosis I Meiosis II
spermatids (n)
secondary spermatocytes
(n)
primary spermatocyte
(2n)
spermato-gonium (2n )
sperm (n)
a) Spermatogenesis
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Growth Meiosis I Meiosis II
ovum (n)
primary oocyte (2n)
oogonium (2n) secondary
oocyte (n)
polar body (n)
polar bodies (n)
b) Oogenesis
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Comparing mitosis and meiosis
• Mitosis: 2 genetically identical diploid cells• Meiosis: 4 genetically different haploid cells
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