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Meiosis and Sexual Reproduction. Chapter 10. Why Sex. Fig. 10-1b, p.154. Why sex?. Asexual Easier, faster Big population Indentical Bits can make whole indv. No new combos All inherit the same info Clones parthogenesis. Sexual Changing env More variety New combos - PowerPoint PPT PresentationTRANSCRIPT
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Chapter 10Chapter 10
Meiosis and Sexual Meiosis and Sexual ReproductionReproduction
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Fig. 10-1b, p.154
Why SexWhy Sex
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Why sex?Why sex? Asexual
Easier, faster Big population Indentical Bits can make whole
indv. No new combos All inherit the same
info Clones parthogenesis
Sexual Changing env More variety New combos Involves meiosis
(gametes) and fertilization
allele
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Fig. 43-2c, p.756
Cost of Sexual ReproductionCost of Sexual Reproduction
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43.1 (p. 756)43.1 (p. 756)Cost of Sexual ReproductionCost of Sexual Reproduction
Specialized cells and structures must be formed Special courtship, and parental behaviors can be
costly Timing of gamete formation and mating Nurturing developing offspring, either in egg or
body, requires resources from mother
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10.2 What Meiosis Does10.2 What Meiosis Does
Meiosis – nuclear division that divides parental c-some # by half in specialized reproductive cells Ex: anther, ovules
antherovary
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Homologous Chromosomes Homologous Chromosomes Carry Different AllelesCarry Different Alleles
Homologous c-some –
same shape, length
and assortment of
genes, line up with
each other
Paternal and maternal
chromosomes can
carry different alleles
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Chromosome NumberChromosome Number
Sum total of chromosomes in a cell
Germ cells are diploid (2n)
Gametes are haploid (n)
Meiosis halves chromosome number
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Meiosis: Two DivisionsMeiosis: Two Divisions
Two consecutive nuclear divisions Meiosis I – aligns with partner
Meiosis II – sister chromatids separate
DNA is not duplicated between
divisions
Four haploid nuclei form
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10.4 Factors Contributing to 10.4 Factors Contributing to Variation among OffspringVariation among Offspring
Crossing over during prophase I
Independent assortment
Random alignment of chromosomes
at metaphase I
Random combination of gametes at
fertilization
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Crossing OverCrossing Over
•Each chromosome
becomes zippered to its
homologue
•All four chromatids are
closely aligned
•Nonsister chromosomes
exchange segments
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Effect of Crossing OverEffect of Crossing Over
After crossing over, each
chromosome contains both maternal
and paternal segments
Creates new allele combinations in
offspring
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Independent AssortmentIndependent Assortment Microtubules from spindle poles attach to
kinetochores of chromosomes randomly, between Prophase I and Metaphase I
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Possible Chromosome Possible Chromosome CombinationsCombinations
As a result of random alignment, the
number of possible combinations of chromosomes in a gamete is:
2n
(n is number of chromosome types)
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FertilizationFertilization
Which two gametes unite is random Adds to variation among offspring
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Life CyclesLife Cycles
• PlantPlant • AnimalAnimal
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sporophyte
meiosisdiploid
fertilization
zygote
gametes
gametophytes
spores
haploid
Fig. 10-8a, p.162
Plant Life Cycle
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multicelledbody
meiosisdiploid
fertilization
zygote
gametes
haploid
Fig. 10-8b, p.162
Animal Life Cycle
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44.244.2SpermatogenesisSpermatogenesis
Spermatogonium (2n) divides by mitosis to form primary spermatocyte (2n)
Meiosis produces haploid spermatids Spermatids mature to become sperm
Figure 44.4Page 775
movie
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Male Hormonal ControlMale Hormonal Control
Hypothalamus
Anterior Pituitary
GnRH
LHFSH
Sertoli Cells
Leydig Cells Testes
Testosterone
Inhibin
Formation and Development of Sperm
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44.144.1Oocytes Arrested in Meiosis IOocytes Arrested in Meiosis I
Girl is born with primary oocytes already
in ovaries
Each oocyte has entered meiosis I and
stopped
Meiosis resumes, one oocyte at a time,
with the first menstrual cycle
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Ovarian Ovarian CycleCycle
secondary oocyte
antrum
primordial follicle
corpus luteum
first polar body
Follicle
grows and
matures
Ovulation
occurs
Corpus
luteum
formsFigure 44.8Page 778
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primordial follicle
Ovulation. Mature follicle ruptures and releases the secondary oocyte and the first polar body.
Primary oocyte, not yet released from meiosis I. A cell layer is forming around it. A follicle consists of the cell layer and the oocyte.
A corpus luteum forms from remnants of the ruptured follicle.
A transparent and somewhat elastic layer, the zona pellucida, starts forming around the primary oocyte.
first polar body
secondary oocyte
Mature follicle. Meiosis I is over. The secondary oocyte and first polar body are now formed.
A fluid-filled cavity (antrum) starts forming in the follicle’s cell layer.
The corpus luteum breaks down when the woman doesn’t get pregnant.
Fig. 44-8b, p.778
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Female Hormonal ControlFemale Hormonal Control
Hypothalamus
Anterior pituitary
GnRH
LH FSH
OvaryEstrogen
Progesterone,estrogens
follicle growth, oocyte maturation
Rising estrogen stimulates surge in LH
Corpus luteumforms
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MitosisMitosis FunctionsFunctions
Asexual Asexual reproductionreproduction
Growth, repair Growth, repair Occurs in somatic Occurs in somatic
cellscells Produces clonesProduces clones
Mitosis & Meiosis Mitosis & Meiosis ComparedCompared
Meiosis Function
Sexual reproduction
Occurs in germ cells
Produces variable offspring
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Prophase vs. Prophase I Prophase vs. Prophase I
Prophase (Mitosis)Prophase (Mitosis) Homologous pairs do not interact with Homologous pairs do not interact with
each othereach other
Prophase I (Meiosis) Prophase I (Meiosis) Homologous pairs become zippered Homologous pairs become zippered
together and crossing over occurstogether and crossing over occurs
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Anaphase, Anaphase I, and Anaphase, Anaphase I, and Anaphase IIAnaphase II
Anaphase I (Meiosis)Anaphase I (Meiosis)
Homologous chromosomes separate from Homologous chromosomes separate from
each othereach other
Anaphase/Anaphase II (Mitosis/Meiosis)Anaphase/Anaphase II (Mitosis/Meiosis)
Sister chromatids of a chromosome Sister chromatids of a chromosome
separate from each otherseparate from each other
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Results of Mitosis and Results of Mitosis and MeiosisMeiosis
MitosisMitosis Two diploid cells producedTwo diploid cells produced
Each identical to parentEach identical to parent
MeiosisMeiosis Four haploid cells producedFour haploid cells produced
Differ from parent and one anotherDiffer from parent and one another
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An Ancestral ConnectionAn Ancestral Connection
Was sexual reproduction a giant evolutionary Was sexual reproduction a giant evolutionary
step from aseuxal reproduction?step from aseuxal reproduction?
Giardia intestinalisGiardia intestinalis
ChlamydomonasChlamydomonas
Recombination mechanisms are vital for Recombination mechanisms are vital for
reproduction of euk cells may have evolved from reproduction of euk cells may have evolved from
DNA repair mechanisms in prok ancestorsDNA repair mechanisms in prok ancestors