BMS 532.13 SexLinked Heredity.pptx

Transcript

Sex-Linked
Heredity and Sex
Determination
BMS 532
BLOCK 2 LECTURE 6
 Objectives
1. Define the following terms: homogametic, heterogametic, hemizygous, haploinsufficiency, nondisjunction, genic,
environmental, and sexual determination.

2. Compare and contrast sex chromosomes and sex determination across species

3. Explain the distinction between a homogametic and heterogametic individual in XX/XY and ZZ/ZW sex determination

4. Assess the outcomes for a given mating under XX/XY and ZZ/ZW organisms in terms of biological sex expectations and
features associated with or influenced by sex chromosomes

5. Evaluate the consequences of changes in genes, environment, and sex chromosome content for sex determination and
development of secondary sexual characteristics
◦ Outline how climate change is proposed to be altering male:female ratios in turtles, alligators and crocodiles

6. Compare and contrast the X and Y chromosomes

7. Explain why it is necessary to have regions of similarity between the human X and Y chromosomes

8. Using the Morgan Fruit Fly experiments as a foundation, assess outcomes for a given mating and explain the role of
reciprocal crosses in defining sex-linked inheritance
◦ Summarize Morgan’s and Bridge’s fruit fly experiments and their outcomes

9. Explain X-linked inheritance in terms of human health and disease and Explain the consequences for nondisjunction in
terms of genotype and phenotype

10. **Determine probabilities for offspring inheriting a particular trait (autosomal vs. sex-linked)
LO1

Terminology
Sex Chromosomes = chromosomes that contain the genetic information
necessary to confer biological sex and influence development of secondary
sexual characteristics
Homogametic = has gametes with the same sex chromosomes
Heterogametic = has gametes with different sex chromosomes
Hemizygous = containing only 1 copy of a chromosome that can be or is
typically observed in a pair
Haploinsufficiency = loss of 1 copy results in a situation where the remaining
copy cannot compensate and make sufficient product; reduced function is
expected due to the insufficient levels of product
◦ NOTE: genes exclusive to the Y or X in humans are NOT haploinsufficient as proper
gene dosage is 1
◦ This is why some genes on the X MUST be inactivated (see epigenetics lecture)
LO2
Sex Chromosomes and Sex
Determination
In sexual reproduction, differences between the 2 sexes are
established by key genes often located on specific sex chromosomes
Sex chromosomes can vary across different organisms
Sex chromosomes do NOT have to involve 2 distinct chromosome
types in the pair
◦ Humans: XX females vs XY males
◦ Grasshoppers: XX females vs XO males (males have fewer chromosomes than
females)

When the chromosome pairing involves one biological sex having
fewer chromosomes, meiosis will result in gametes that have unequal
chromosome numbers
LO1, LO2,
LO3, LO4
More on Sex Chromosomes
and Sex Determination
Heterogametic Sex = sex
with 2 different
chromosomes
ZZ vs ZW
◦In many species, the
heterogametic sex is the
female
◦This system is found in
birds, snakes, butterflies,
some amphibians and some
fish
LO1, LO3,
LO4

XY Heredity (Humans)
In humans, males are
heterogametic
X and Y can pair during Meiosis
because of structural similarity in
the chromosomes (regions of
homology)
◦ Pseudoautosomal regions
Crossing-over occurs in these
regions
Because these are regions of
similarity that do contain genes,
these regions escape X-
inactivation ensuring proper
gene dosage for those genes
LO1, LO2,
LO5 Sex Determination without Sex
Chromosomes
(Genic or Environmental)
While biological sex is frequently determined by
genes, the location of those genes can very
especially if there are no sex chromosomes
◦No visible difference in the chromosomes of males and
females and no sex chromosomes
Genic Determination
◦Genes at one or more loci determine sex without specific sex
chromosomes
LO1, LO2,
LO5 Sex Determination without Sex
Chromosomes
(Genic or Environmental)
Environmental Sex
Determination
◦Environment is either partially
or completely responsible for
sex determination
◦Organism has equal chance to
be either sex but cannot be
both at the same time
◦Ex: slipper limpet (Crepidula
fornicata)
◦Sequential hermaphroditism
LO1, LO2,
LO5 Sex Determination without Sex
Chromosomes
(Genic or Environmental)
Environmental Sex
Determination
◦Reptiles including
turtles, crocodiles,
alligators and some
birds
◦ Temperature-based
sex determination

https://www.sciencedirect.com/science/article/abs/pii/S0006320717308534
LO1, LO2,
LO5 Sex Determination without Sex
Chromosomes
(Genic or Environmental)
Environmental Sex Determination
◦ For turtles, warmer temperatures result in more females, colder temperatures yield
more males
◦ For alligators, colder temperatures result in more females, warmer temperatures
yield more males
◦ For bearded dragon lizards, environment influences the phenotype rather than the
genotype.
◦ ZZ is male except when the embryo is incubated at high temperatures, then ZZ is
phenotypically female even though genotypical male.

https://www.sciencedirect.com/science/article/pii/B9780123749307100019
LO1, LO2,
LO5 Sex Determination without Sex
Chromosomes
(Genic or Environmental)
Environmental Sex Determination
◦Crocodiles
◦Sex determination is more complex
◦32-33°C nest temperature = male crocs
◦Any other temperature = females

https://www.sciencedirect.com/science/article/pii/B9780123749307100019
LO1, LO2,
LO5
Global Warming and Sex
Determination
Increasing global temperatures for sex determination based on temperature
is altering the ratio of males to females and disrupting reproductive potential

All
Mal
e

All
Femal
e

https://onlinelibrary.wiley.com/doi/full/10.1111/eva.13226
LO1, LO2

Mammalian Biological Sex
Determination
Genes typically located on the Y chromosome confer key
proteins for defining the production of testes
Loss of genes in an XY individual will result in phenotypical
development as female
Phenotypic development as female with functional ovaries in the
absence of genes is not guaranteed thus there is no actual
biological default sex as previously thought
Presence of small portions of the Y chromosome in XX
individuals has been shown to be sufficient to cause
phenotypical male development implying only a small portion of
the chromosome is actually needed for sex determination
LO1, LO2,
LO6
Human Biological Sex
Determination
SRY gene on Y chromosome confers testes development
◦ Transcription factor
◦ Activation of the gene occurs at roughly 6 weeks development
◦ Prior to the activation of key genes gonads are undifferentiated
◦ SRY is located in close proximity to the pseudoautosomal region

Once triggered, testes begin to form and secrete
◦ Testosterone to promote development of male characteristics and
◦ Mullerian inhibitory substance (MIS) to suppress/degenerate female
reproductive ducts

In the absence of SRY, ovaries can develop (estrogen and no MIS)
Absence of proper gene activity can hinder development and
result in sterility
LO6, LO7

More about the X and Y
Chromosomes
Although the main components of sex determination are located
on these chromosomes, autosomal genes are also
important
◦ There are actually more genes associated with sexual development on the
autosomes but they require activation typically triggered by the genes on
the sex chromosomes

The X and Y chromosomes also contain genes NOT associated
with sexual development
◦ The inheritance of those genes do not follow Mendel’s laws
Males in XY inheritance are hemizygous (only one copy of
some genes)
LO6, LO7

More on Pseudoautosomal
Regions
Distal region of short arms of X and Y
= highly similar DNA sequences
(PAR1)
◦ Areas for crossing over in male meiosis that
resembles autosomal crossing-over

Region of homology at distal end
of long arms that also experience
alignment and crossing-over (PAR2)
All genes within PAR1 are NOT
inactivated in women
◦ Need 2 copies (dosage compensation)

There is a high recombination
frequency in PAR1
LO1, LO2,
LO3, LO4

Summary
LO1, LO2,
LO8

Sex-Linked Inheritance
Inheritance patterns for genes on the sex chromosomes differs from that for
autosomes
Since the X chromosome has more genes located on it, most sex-linked
inheritance is condensed to X-linked inheritance
Sex-linked inheritance results in differential expression of traits between
males and females
Thomas Hunt Morgan and his fruit fly experiments were a major series of
experiments demonstrating X-linked inheritance with differential expression
of traits between males and females
LO8, LO9

Morgan’s Crosses

Parental Generations
2 crosses that are reciprocal parents
are needed to define X-linked
inheritance
◦ 1) Red-eyed female x White-eyed male
◦ Offspring = All Red Eyes (no difference between males
and females)
◦ Morgan then took these offspring (F1) and crossed them
(generated F2)
◦ 2) White-eyed female x Red-eyed male
◦ Offspring = All Red-eyed Females and All White-eyed
males
◦ Morgan then took these offspring (F1) and crossed them
(generated F2)

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 Morgan’s Crosses

F1 crosses
◦ 1) Heterozygous Female x Red-eyed Male
◦ All females red-eyed
◦ Half the males white-eyed
◦ 2) Heterozygous Female x White-eyed
Male
◦ 50% red-eyed males and females
◦ 50% white-eyed males and females

The discrepancy between males
and females in presentation of
the phenotype is a hallmark of X-
linked or sex-linked inheritance
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LO8, LO9
LO8, LO9

Morgan’s Fruit Fly Experiments Summary
Morgan’ s genetic principles:
Sex-linked inheritance based on mutations observed in
males only
Gene linkage based on the inheritance of genes as a
single unit
Chromosome mapping based on recombination
frequencies between linked genes
 Deviations from
Expectations
Morgan’s cross shown here should produce
100% red eyed F1 flies.

Out of 1237 F1 flies screened, 1234 had red
eyes

◦ Three white-eyed male flies were observed

Further similar crosses continued to produce a
low frequency of white-eyed males that was too
high to be explained by random mutation.

Calvin Bridges was assigned by Morgan to work
on the problem

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 Bridge’s Experiments in Fruit
LO8, LO9

Flies:
Nondisjunction
After repeating several crosses similar to
Morgan’s, Bridge discovered that only
certain matings produced the unexpected
results
Bridges hypothesized that the exceptional
white-eyed female strain possessed two X
chromosomes and a Y chromosome.
◦ XXY flies develop as females and can exhibit
recessive traits

Bridges proposed that about 10% of the
time during meiosis, the two X
chromosomes fail to separate from each
other
◦ Failure to properly separate chromosomes =
Nondisjunction
LO8, LO9

Nondisjunction
More evidence for the
chromosome theory of
inheritance
Failure to properly
separate chromosomes
leads to inappropriate
gene content in the
offspring
Many of the genetic
options produce nonviable
offspring (embryonic
lethal)
◦ YY (always) and XXX (usually)
LO10

Example Time!!
Autosomal vs Sex-Linked
You are curious about a given trait and its inheritance.
There are 2 variants of the trait with clear dominance.
How could you determine whether the trait is
autosomal or sex-linked?
◦What is your hypothesis?
◦What crosses would you perform?
Autosomal vs Sex-Linked
Human Color-Blindness
Human color blindness is an X-linked trait.
Define the expected outcomes for offspring if two individuals reproduce who
are in pairings as follows:
Homozygous NOT Color-Blind Female x Color-Blind Male
Heterozygous Female x Not Color-Blind Male
Heterozygous Female x Color-Blind Male