Chapter 9: Reproduction Lecture Presentation PDF

Summary

This presentation covers various aspects of reproduction, including differentiating between asexual and sexual reproduction, exploring meiosis and mitosis, examining chromosome abnormalities, and detailing human embryonic development. It's designed for a high school or introductory level biology course.

Full Transcript

 Key Questions
What is asexual reproduction and how does it differ from sexual reproduction. Provide
examples of asexual reproduction.
What are homologous chromosomes? How many homologous chromosomes do humans have?
What is a karyotype? What can we learn by looking at a karyotype?
Differentiate between haploid and diploid numbers.
Define meiosis and explain its importance.
List and describe the events of meiosis I.
List and describe the events of meiosis II.
How does nondisjunction happen during meiosis? What does it result in?
How do mutations, crossing over, segregation of chromosomes, independent assortment
of chromosomes, and random fertilization all contribute to genetic variation?
Compare and contrast mitosis and meiosis.
List and describe the functions of primary and accessory reproductive organs in males and
females.
List and describe the functions of hormones that control reproduction in males and females.
List and describe the events of the ovarian and uterine cycle of a female. Explain the importance of
their overlapping.
Explain how spermatogenesis and oogenesis differ as well as the factors that control these
factors.
Describe the process of fertilization.
Describe the major events of human embryonic fertilization.
What are some hormones and physiological changes that occur during pregnancy?
9.1 Asexual vs. Sexual
Reproduction
Asexual: organisms form clones
Sexual: occurs via gametes
Homologous Chromosomes
A complete set of identical
chromosomes inherited by each
parent
Mitosis vs Meiosis
Mitosis (asexual):
Occurs in body
cells

Cell replication
that forms new
body cells to
replace old/injured
cells

Forms 2 identical
daughter cells each
Mitosis vs Meiosis
Meiosis (sexual):
Occurs in the testes
& ovaries

Cell replication that
forms gametes (sex
cells)

Forms 4 daughter
cells each with the
haploid
chromosomes (23
Karyotype
Polyploidy
Having extra sets of chromosomes (3n, 4n, 8n, etc.)

Caused by nondisjunction of all chromosomes

Rare, usually fatal in animals

Common in plants (30-80%)
polyploids often thrive better and grow taller
some are sterile (seedless)
 Interphase:
MeiosisG1 S  G2
Meiosis I:
1. Prophase I
2. Metaphase I
3. Anaphase I
4. Telophase I
Cytokinesis I
Meiosis II:
5. Prophase II
6. Metaphase II
7. Anaphase II
8. Telophase II
Cytokinesis
 9.2 The Process of Meiosis I
2 pairs of homologous
chromosomes
1 pair long to represent
one set and the other pair
short
Pink came from the
mother
Blue came from the father

1 pink long, 1 blue long
1 pink short, 1 blue
short
9.2 Cell Cycle of Sex Cells
Begins with Interphase
 Meiosis I: Prophase I

animation
Meiosis I Prophase I
Crossing over
Meiosis I: Metaphase I
Tetrads
(homologous
chromosome pairs)
randomly line up
in the middle of the
cell

Centromere
attaches to a
spindle fiber
 Meiosis I: Anaphase I

Homologous chromosome pairs separate
Centromeres to not break
Segregation & Independent Assortment

animation
 Meiosis I: Telophase I

Cytokinesis: cell separates into 2 daughter
cells
Each chromosome contains 2 identical
chromatids
(1 chromosome) – cells are haploid
Meiosis I
 No Interphase II
Cells do briefly rest between Meiosis I
& II
No replication of DNA
 9.3 Meiosis II – Prophase II
very similar to prophase in mitosis
 Meiosis II – Metaphase II
very similar to metaphase in mitosis
 Meiosis II – Anaphase II
very similar to anaphase in mitosis
 Meiosis II – Telophase II
very similar to telophase in mitosis
Meiosis I
and II
Differences between male and
female meiosis
BioFlix: Meiosis
 Meiosis Video
https://www.youtube.com/watch?v=k
Qu6Yfrr6j0
 9.4 Sources of Variation

1.) Mutations (change in DNA
sequence)

2.) Crossing Over of Genes

3.) Independent Assortment &
Segregation

4.) Random Fertilization
 Sources of Variation -
Mutations
Alterations in
DNA
(genes)

Base
changes
 Sources of Variation – Cross-
Overs
Exchange of genes
between chromatids

Recombinant
chromosomes (DNA)

Genes occupy a locus –
genes close together
move together: Linked
Genes
Sources of Variation – Cross-
Overs
 Sources of Variation – Independent
Assortment & Segregation
Homologous chromosomes separate based on how
they line up.

Chromosomes are “sorted” into daughter cells
based on how they line up in metaphase.

Different sequences results in different
combinations
 Independent Assortment
2n where n= #pairs of
chromosomes

Cell with 3 pairs can have
8 different daughter cell
combinations.

23 = 2 X 2 X 2 = 8

Humans 23 pairs:
8,388,608
 Sources of Variation – Random
Fertilization

Random sperm/egg

1 in
72,000,000,000,000
Chromosome Abnormalities
Non-disjunction:
– When chromosomes fail to separate
correctly during meiosis I or meiosis II
– Results in loss or gain of chromosomes
in egg or sperm cells
– Examples:
Trisomy
Monosomic
9.5 Chromosome
Abnormalities
 Nondisjunction of Sex
Chromosomes

Klinefelter Syndrome:
XXY; male

Turner Syndrome: XO;
female
Down Syndrome
 Down Syndrome

Amniocentesis
Procedure to extract
fetal cells and
examine
chromosomes
Sex Chromosomes
Chromosome Mutations
 Chromosome Mutations
Translocation Chromosome
Chronic duplication
myelogenous Fragile X
leukemia
Fragile X Syndrome
 9.6 Sex Chromosomes &
Biological Sex Determination
XX or XY

Y chromosome triggers
release of
testosterone for the
development of a
male.

Females: oogenesis
begins and stops in
meiosis I
Karyotype
9.7 Sexual Development
 Male Reproductive Anatomy
Primary Organs Accessory Organs
Testes  Epididymis
Seminiferous Tubules  Vas Deferens
make sperm  Seminal Vesicle
Interstitial Cells  Prostate Gland
make testosterone  Bulbourethral
Penis Gland
Spermatogenesis
All 4 cells made during
meiosis will become
sperm cells
 Hormone Regulation
Gonadotropin-releasing hormone (GnRH):
from hypothalamus controls hormone
release from anterior pituitary: FSH and LH

Follicle-stimulating hormone FSH: triggers
spermatogenesis & production of semen
Luteinizing Hormone (LH): triggers
production of testosterone
 Hormone Regulation
Testosterone
Secondary sex
characteristics
 Female Reproductive Anatomy
Primary Organs Accessory Organs
Ovaries  Fallopian (uterine)
Follicles contain tubes
oocytes & make  Uterus
estrogen  Vagina
Oogenesis
egg supply determined by birth

puberty --> menopause releases them

primary oocytes - begin meiosis I and
doesn’t complete it

after puberty: once a month an egg
grows: continues meiosis I

produces secondary oocyte & 1 polar
body
 Oogenesis
secondary oocyte stops in
metaphase II and is released:

if not penetrated by sperm
meiosis is not completed and
shedding of uterine line
occurs
if penetrated by sperm,
meiosis is completed

Note: the ruptured follicle is now
known as the corpus luteum.
 Hormone Regulation
GnRH: from hypothalamus controls hormone
release from anterior pituitary: FSH and LH

FSH: triggers oogenesis & production of
estrogen
LH: triggers production of progesterone &
estrogen & maintains the uterus
 Hormone Regulation
Estrogen
Secondary sex
characteristics
 Menstrual Cycle
Ovarian Cycle: Changes that occur in the
ovaries

Uterine Cycle: Changes that occur in the
uterus

Must be coordinated – average cycle is 28
days
 Ovarian Cycle
Ovarian Cycle

1. Follicular Stage:
Follicle enlarges and
oocyte matures

2. Ovulation: release of
ovum

3. Corpus Luteum: a
ruptured follicle
 Uterine Cycle
Uterine Cycle

1. Menstrual Phase

2. Proliferative/
Secretory Phases
 9.8 Fertilization &
Pregnancy
Ovulation is typically day 14 of cycle

Oocyte is viable 24 hrs. after it leaves the ovary.

Sperm retain their fertilizing power within female
reproductive tract up to 3 days after
ejaculation. ("super sperm" are viable for 5
days.)

Intercourse must occur no more than 5 days
before ovulation and no later than 24 hrs. after
the oocyte is ovulated
Fertilization
 Fertilization
Sperm fuses to oocyte membrane and activates it
(depolarizes)
1.) Triggers cortical reaction (exocytosis of
enzymes) which inactivates sperm receptors &
hardens zona pellucida
2.) completes meiosis II
3.) activates enzymes for mRNA for rapid protein
synthesis

male pronucleus fuses with female pronucleus =
zygote
Human Embryonic
Development
 Pre-Embryonic Development
Cleavage: Rapid
mitosis, little growth by
36 hrs. after
fertilization, the 1st
cleavage division
produces 2 ID cells
which divide to produce
4 cells then 8:
eventually form solid
ball of cells termed
morula
Pre-Embryonic Development
 Implantation
Trophoblast releases
enzymes to digest
endometrium

Trophoblast forms
chorionic villi which
grow into
endometrium
 Implantation
hCG: Human Chorionic
Gonadotropin:
secreted by the trophoblast
prompts the corpus luteum to
secrete progesterone

hCG usually detectable in
mothers blood by 3rd week of
gestation

hCG levels decline after 4
months
Embryonic Development
 Embryonic Development
Gastrulation:
cells move toward
primitive streak
(central line)
produces 3 layered
sheet of cells
termed embryonic
disc which will
become the
embryo
Gastrulation
Pregnancy
Placenta
 Fertilization & Pregnancy
Gestation period: the time during which
development occurs (280 days)
First Trimester
– Rudiments of all major organ systems appear
Second Trimester
– Development of organs and organ systems
– Body shape and proportions change
By end, fetus looks distinctively human
Third Trimester
– Rapid fetal growth and deposition of adipose tissue
– Most major organ systems are fully functional
 Fertilization & Pregnancy
The First Trimester
Most dangerous period in prenatal life
40% of conceptions produce embryos that
survive past first trimester
First Trimester
 Twins
Rates of Multiple Births
Twins in 1 of every 89 births
Triplets in 1 of every 892 (7921)
births
Quadruplets in 1 of every 893
(704,969) births
 Activity 3 pg. 141
Comparing Mitosis & Meiosis
Mitosis Meiosis
Occurs in all cells beginning with
zygote
Produces four daughter cells
Daughter cells are haploid
Important for maintaining
homeostasis
Only occurs during formation of
gametes
Produces two daughter cells
Goes through the phases once
Introduces genetic variability
Synapsis and crossing over occur
Daughter cells are diploid
Reduces chromosome number by
half
 Activity 3
Comparing Mitosis & Meiosis
Mitosis Meiosis
Occurs in all cells beginning with x
zygote
Produces four daughter cells x
Daughter cells are haploid x
Important for maintaining x
homeostasis
Only occurs during formation of x
gametes
Produces two daughter cells x
Goes through the phases once x
Introduces genetic variability x
Synapsis and crossing over occur x
Daughter cells are diploid x
Reduces chromosome number by x
half
 Mitosis and Meiosis Lab
Report
1. Why is mitosis critical for life?
– Used for replacement of damaged and dying cells
– Allows for growth of organism
2. What is the diploid number for human cells?
– 46
3. Prophase—c; Prometaphase—e; Metaphase---d;
Anaphase—b; Telophase—a
4. Differences between mitosis and meiosis
– # of cells at end; function; genetic variation at end;
number of cell/nuclear divisions; homologous
chromosomes pair during meiosis
5. Similarities between mitosis and meiosis
– Both start with diploid cells; DNA is replicated during
Interphase