Lecture 9: Sex Determination and Gametogenesis PDF

Summary

These lecture notes cover sex determination and gametogenesis. They describe the role of chromosomes in sex determination and differentiate between primary and secondary sex determination. The document also explores mechanisms in mammals and Drosophila.

Full Transcript

Lecture 9: Sex determination
and gametogenesis
Textbook
Chapter 6 (pages 176 – 187)
Chapter overview
Mammalian sex determination
How do chromosomes dictate testes or ovary formation? What gene
regulatory networks are activated by the Y and X chromosomes?
Primary vs. secondary sex determination
What happens when there are mutations in key genes responsible for
sex determination?
Drosophila sex determination
A cascade of alternative RNA splicing events dictates sex
determination
Mammalian gametogenesis: spermatogenesis + oogenesis
“Sexual reproduction is … the
masterpiece of nature” – Erasmus Darwin

Different species produce offspring in different ways.
Mechanisms of sex determination
Chromosomal sex determination
Examples: Mammals, birds, Drosophila
Mammals: XY sex chromosomes; XY à formation of testes; XX à formation of ovaries
Birds: males have ZZ, and females have ZW
Drosophila: The Y chromosome plays no role in sex determination, but the number of X
chromosomes determines sexual phenotype

Environmental sex determination
Example: the temperature at which the embryos incubate determines whether
the embryo will develop into a male or female
Mammalian sex determination

X-bearing sperm + X-bearing egg à genetically
female XX

Y-bearing sperm + X-bearing egg à genetically
male XY

But how does having a Y chromosome promote
testis formation? How does having two X
chromosomes promote ovary development and
egg production?
Mammalian sex
determination
Mammalian embryos have a
bipotential gonad.

Gonad: organ of the reproductive
system that produces and releases the
gametes (the reproductive cell of an
animal or plant)
XX à ovary
XY à testes
The importance of the Y chromosome in
mammalian sex determination

Each sperm should normally
have 22 autosomes + either
a single X or Y chromosome.

Each oocyte should have 22
autosomes + a single X
chromosome.
The importance of the Y chromosome in
mammalian sex determination

Errors in meiosis during
gamete formation can lead
to the generation of gametes
with abnormal numbers of
sex chromosomes.
The importance of the Y chromosome in
mammalian sex determination

Gametes with an abnormal
amount of sex chromosomes
will lead to the creation of
zygotes with extra X
chromosomes (XXX or XXY),
extra Y chromosomes (XYY),
or missing a sex
chromosome (X0).
The importance of chromosomes in mammalian
sex determination
Individuals with only a single X chromosome develop external female
genitalia but they are underdeveloped – Turner syndrome (XO)
A second X chromosome is necessary to complete development of the ovaries
(people with a single X chromosome begin making ovaries but ovarian follicles
cannot be maintained).

The presence of a Y chromosome initiates development of testis.
Individuals with a Y chromosome develop testis and male genitalia, even
if they have two X chromosomes – Klinefelter syndrome (XXY)
Infertility in almost all affected people. Compared with XY individuals, they have
lower levels of androgens (male hormones) and more estrogens (female hormones).
 Mammalian sex determination
Secondary sex
determination
Primary sex
XY or XX determination (sexual phenotype
chromosomes (gonads - testis or outside the gonads
ovaries) – male and female
duct systems and
external genitalia)

Gonads produce
XY or XX chromosomes
hormones and paracrine
dictate the fate of the
factors that govern
bipotential cells of the
secondary sex
early gonad.
determination.
 Secondary sex determination
Primary sex
determination
Genital ridge
(mesoderm origin)
The differentiation of the genital ridge into the
bipotential gonad requires 4 genes: Sf1, Wt1, Lhx9,
Gata4

Mice lacking any of these genes have no gonads.
XX: Wnt4 + Rspo1 activate the canonical Wnt pathway
à β-catenin activated.

β-catenin activates transcription of ovarian
gonadal cells.
XY: the Y chromosome contains a gene called “Sry”.
This is the testes-determining gene.
Sry acts as a transcription factor to activate
expression of a transcription factor called “Sox9”.
Sox9 activates genes that dictate testes formation.
 Germ stem cells (the precursors of the egg
and sperm) develop outside the bipotential
gonad and migrate into the gonadal tissue
during week 6.
Germ cells, like the gonad, are also
bipotential. The gonad dictates whether they
will become sperm or oocytes.
In humans, gonadal rudiments remain
sexually indifferent until week 8.
 At 8 weeks, the gonadal
tissue begins developing
into a testes or ovary.
The sperm is housed in the
seminiferous tubule.
The oocyte/egg is housed in
follicles within ovarian
follicles.
Primary sex determination mechanism (XX)
In the absence of a Y chromosome:
Wt1, Lhx9, Gata4 and Sf1 à Wnt4 and
Rspo1 are upregulated.
Wnt4 and Rspo1 trigger Wnt/β-catenin
pathway signaling.
β-catenin activates further ovarian
development and blocks the
transcription of the testis-promoting
transcription factor Sox9.
β-catenin is an important “anti-
testis/pro-ovary” molecule, and it is
found in the female gonads of all
vertebrates.
Primary sex determination mechanism (XX)
Rspo1 mutations lead to 46,XX
female-to-male sex reversal.
Individuals with this condition
have two X chromosomes, but
develop male external genitalia
and small testes, and are usually
infertile.
Affected individuals typically need
male sex hormones during
puberty to induce male secondary
sex characteristics.
Primary sex determination mechanism (XX)
A duplication of the region on
chromosome 1 that contains both
the Wnt4 and Rspo1 genes in XY
individuals results in 46,XY male-
to-female sex reversal.
The overactivated β-catenin
pathway overrides the effect of Sry
and Sox9.
Primary sex determination mechanism (XY)
In the presence of a Y
chromosome: Wt1,Lhx9, Gata4,
and Sf1 à activate the Sry gene
on the Y chromosome (sex-
determining region of the Y
chromosome).
Primary role of Sry à activation of
the Sox9 transcription factor
(autosomal gene, found on
chromosome 17).
Sox9 is found in all vertebrates,
Sry is only found in mammals.
Birds, fish, frogs: Sox9 activated
by Dmrt1
Primary sex determination mechanism (XY)
Sox9:
activates its own promoter
inhibits β-catenin’s ability to
induce ovary formation
activates transcription of
testis-promoting genes
(including anti-Mullerian
hormone, Dmrt1, Fgf9)
Sry – the testis determining factor in mammals
SRY-positive 46,XX testicular disorder:
The SRY gene has been translocated onto one of the X chromosomes, so the
affected individual develops male gonads despite having two X chromosomes.
Female-to-male sex reversal. No Y
chromosome à
no
SRY-negative 46,XX testicular disorder:
spermatogenesis
The affected individual has XX chromosomes but develops male genitalia. This
is due to a duplication of the SOX9 gene on chromosome 17 which triggers
testis formation. Female-to-male sex reversal.

46,XY gonadal dysgenesis or Swyer syndrome:
The SRY gene on the Y chromosome has been deleted or mutated, leading to
development of female phenotypes despite the presence of a Y chromosome.
Male-to-female sex reversal. Gonads are underdeveloped and oocytes are not
produced.
 Secondary sex determination
Primary sex
determination
Secondary sex determination

Following their formation, gonads secrete
hormones and factors that trigger secondary sex
determination.

Two phases of secondary sex determination:
organogenesis in the embryo, puberty in
teenagers
Secondary sex determination

Two undifferentiated duct systems are present in
the embryo: Mullerian duct and Wolffian duct.

Hormones and other factors secreted from the
gonads will lead to their maintenance or
destruction.
Estrogen secreted by ovaries: maintenance of Mullerian
ducts à oviduct, uterus, cervix, vagina

Testosterone secreted by testis: maintenance of the
Wolffian ducts à vans deferens, epididymis, seminal vesicle
Since XX gonads do not secrete testosterone, the Wolffian
duct atrophies in females (it requires testosterone for
maintenance).
Secondary sex determination - XY
Within the developing testes, two types of cells are made: Leydig cells
and Sertoli cells

Leydig cells:
Secrete testosterone (an androgen) which promotes maintenance of the Wolffian
ducts and development of external male genitalia.
Sertoli cells:
Secrete anti-Mullerian hormone (AMH) which causes degeneration of the Mullerian
duct.

These two pathways are independent of each other.
Androgen insensitivity syndrome
Individuals have XY chromosomes but have a
mutation in the receptor that responds to
testosterone.
Testes development is normal. Sertoli cells
secrete AMH and Leydig cells secrete
testosterone.
AMH à Mullerian ducts degenerate (no internal
secondary female sex organs)
Testosterone à cannot respond to testosterone,
no Wolffian duct maintenance or external male
genitalia
Androgen insensitivity syndrome
Individuals can respond to estrogen made by
the adrenal glands (produced normally in both
XX and XY individuals) à external genitalia is
female (labia, clitoris, vagina, breasts).

Individuals with androgen insensitivity syndrome
have external female genitalia, lack internal
female genitalia (uterus, oviduct; because the
Mullerian duct degenerated), and have internal
testes.
DHT
Testosterone promotes formation of male
structures that derive from the Wolffian duct but
must be converted to dihydrotestosterone (DHT)
to masculinize the urethra, prostate, penis and
scrotum.
DHT is most active prenatally and in early
childhood.
5-alpha reductase deficiency
Individuals lack the gene/enzyme (5-alpha reductase) that converts testosterone into DHT.
XY children have functional testes, Wolffian duct development and Mullerian duct degeneration.
Because of the lack of DHT, when the children are born, they have female external genitalia.
At puberty, the testes produce a large amount of testosterone that overrides the lack of DHT. Scrotum
descends and male external genitalia becomes apparent.
Syndrome appears in ~1% of boys in Las Salinas in the Dominican Republic.

About half of individuals
affected with this enzyme
deficiency will identify as
males after puberty.
Secondary sex determination - XX
Estrogen (from the mother and then from the fetal ovaries)
causes differentiation of the Mullerian duct into the female
reproductive tract and the formation of the external sex organs.

Estrogen is needed in both males and females.
Male estrogen receptor knockout mice develop very few sperm –
sterile
Female estrogen receptor knockout mice – germ cells die, no oocyte
development
X chromosome inactivation
(dosage compensation)
Female mammals have 2 X chromosomes, which would
mean double the transcription of those genes and double
the gene products compared to males.
To regulate dosage, one of the X chromosomes is
randomly inactivated in each cell of the implanted
embryo, and all descendants of those cells keep the
same X chromosome inactivated.
Inactivation – formation of tightly bound heterochromatin
through histone modifications
Inactivated X chromosome forms a Barr body.
Calico cats – an illustrative example of X
chromosome inactivation
Calico is a description of a cat’s coat
color - a calico cat is a domestic cat of
any breed with a tri-color coat. Calico
cats are usually always female.
The gene that dictates coat color (orange
or black) is located on the X
chromosome.
Male cats only inherit one X chromosome
and are therefore only either orange or
black.
Female cats can be heterozygous at that
gene. This leads to some groups of cells
where the black allele was inactivated,
and others where the orange allele was
inactivated à patches of black and
orange.