BMS 532 Lecture Packet PDF

Summary

This document is a lecture packet for a biology course, covering probability concepts, and rules pertaining to genetics analysis. It includes topics such as addition rule, multiplication rule, and more complex probabilities.

Full Transcript

Merged Lecture
Packet
MBG Block 2
10/2/24 to 10/4/24
A way to save time swapping between content…
LO1,
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Probability Rules
Addition Rule:
◦The probability of obtaining one or the other of two mutually
exclusive events is the sum of their individual probabilities
Multiplication Rule:
◦The probability of two independent events occurring
simultaneously equals the product of their individual
probabilities

You have actually been doing this for years. We are simply
naming the rules and discussing how they work in Genetics
analysis.
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When to use each rule…
Good rule of thumb to use when determining which rule is preferable:
◦ AND versus OR
◦ AND = multiplication rule OR = addition rule

If only one option of 2 is possible in a given question = OR
If multiple events that are independent or combine repeated events = AND

What is the chance that a male and then a female will be born?
◦ Male vs female = OR = addition rule 1 out of 2
◦ First a male then a female = AND = multiplication rule of the 2 individual
probabilties
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Addition Rule
The probability of obtaining one or the other of 2 mutually exclusive events,
A or B, is the sum of the separate probabilities
Probability of WW or Ww =
Probability of WW + Probability of Ww

Every time you use a punnet square and say the probabilities of getting
particular phenotypes, you are using the ADDITION RULE!
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Product Rule
The probability that two or more What is the probability that a
independent outcomes will occur is couple’s first 3 children will exhibit a
equal to the product of their recessive trait if both parents are
individual probabilities heterozygotes?
Aa X Aa
Use Punnett Squares! What is the probability of aa?
Then what is the probability of aa
1. Calculate the individual happening 3 times?
probabilities ◦ Probability 1 x 2 x 3
2. Multiply the individual probabilities
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Product Rule
Can be used to predict the outcome of a cross involving two or more genes
AaBbCC X AabbCc
What is the probability that the offspring will be AAbbCc?

Probability of AA?
Probability of bb?
Probability of Cc?

P = pAA x pbb x pCc
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More Complex Probabilities
X
Consider Mendel’s cross of two heterozygous tall
plants.
What is the likelihood of having three offspring where
two are normal height and one is short?
This is more difficult because there are multiple ways
this could occur with three offspring.
Tall could be TT or Tt = 1/4 + 1/2 = 3/4 or
Short must be 1/4.
Each grouping is 3/4 x 3/4 x 1/4 = 9/64.
9/64 + 9/64 + 9/64 = 27/64. This can become or
tedious.

7
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
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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
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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
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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
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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
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Summary
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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)

26
 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
27
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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
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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)
Principles and
Processes of
Epigenetics
CHANGES IN GENE EXPRESSION WITHOUT CHANGING
THE GENETIC CODE
BMS 532 BLOCK 2 LECTURE 7
 Objectives
1. Define the following terms: epigenetics, euchromatin, heterochromatin, imprinting, and
X-inactivation/Lyonization
2. Compare and contrast euchromatin and heterochromatin and Compare and contrast constitutive and
facultative heterochromatin
3. Summarize the process of Methylation and Chromatin remodeling and Compare and contrast DNA and
histone methylation
◦ Identify the role of the following players: CRCs, Histone methyltransferases, DNA methyltransferases, and histone
deacetylases

4. Outline the importance of heterochromatin to gene regulation and chromosome function and the role
remodeling plays in development
5. Assess the consequences for gene regulation following or as induced by changes in chromatin structure
6. Evaluate imprinting and the role of imprinting in gene regulation and human health
◦ Define imprinting and differentially methylated regions
◦ Compare and contrast maternal and paternal imprinting
◦ Explain the process of imprinting in gametogenesis
◦ Summarize the role of demethylation and re-methylation in imprinting
◦ Compare and contrast Prader-Willi and Angelman Syndromes in terms of inactivation, loss of genetic information, and genes involved in the
disorders (from the perspective of which are expressed and which are lost)

7. Evaluate lyonization/x-inactivation in terms of process and effects on gene expression
◦ Explain the process of lyonization/X-inactivation and its connection to inactive chromatin
◦ Compare and contrast imprinted lyonization from random lyonization
◦ Summarize the process of x-inactivation and explain the role of mRNA in the process
◦ List and explain the consequences/effects of X-inactivation (define dosage compensation and explain its role in proper cell function)

8. Define mosaicism and explain the role of x-inactivation in generating mosaic phenotypes
LO1

Terminology
Epigenetics
◦ The study of the manner in which expression of heritable genetic traits are modified by
environmental influences or other mechanisms without a change in DNA sequence
Euchromatin
◦ The state of chromatin in which it is partially or fully uncoiled and genetically active; light-
staining
Heterochromatin
◦ The state of chromatin in which it is tightly coiled and considered molecularly inactive; dark-
staining
◦ Constitutive Chromatin
◦ Region of heterochromatin that is never transcribed
◦ Facultative Chromatin
◦ Region of heterochromatin that is silenced and can become active
◦ Regions that become heterochromatic in certain cells/tissues

Lyonization/X-Inactivation
◦ Inactivation of genes on the X chromosome that exhibit dosage effects
LO1,
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Euchromatin
Loosely coiled during
interphase
◦Beads-on-a-string
conformation
Condensed during mitosis
Often undergoing active
transcription
G-banding: Light Bands
LO1,
LO2

Heterochromatin
Late Replicating; highly
inaccessible by the
replication machinery
Remains condensed from
prophase through the mitotic
cycle
Can be constitutive or
facultative
NOT transcriptionally active
G-banding: dark bands
LO1,
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LO4,

DNA Methylation
LO5

Addition of methyl group
to cytosine or adenine
DNA bases
Cytosine methylation is
associated with
heterochromatin formation
and repression of gene
expression
Important process in
epigenetics and in genetic
disease
LO3,
Ability of a methylated DNA to influence an adjacent promoter is a function of the number of
LO4, modified sites.
LO5

38
Michela Curradi et al. Mol. Cell. Biol. 2002;22:3157-3173
 Methylation Process
LO3

39
LO3,
LO4,
LO5

HISTONE Methylation
Histone Methyltransferases add methyl groups to specific histone residues
◦ This correlates with changes in heterochromatin and euchromatin as well

CHROMATIN REMODELING
The molecular mechanism of chromatin remodeling frequently involve repositioning,
acetylation, methylation, and/or replacement of histone variants
Several different multi-protein complexes, known as chromatin-remodeling complexes
(CRCs), can restructure chromatin to increase or decrease transcription
CRCs use energy derived from ATP to initiate changes
CRCs can
disrupt nucleosome structure without displacing them or
reposition the nucleosomes making key DNA-binding sites accessible
LO1, Heterochromatin vs
LO2,
LO3 Euchromatin
LO1,
LO2,
LO3, Euchromatin vs
Heterochromatin
LO4,
LO5

42
LO1,
LO2,
LO3

Facultative Heterochromatin
SILENCED euchromatin
Deactivated by multiple
processes
◦Changes in Methylation
◦Hypoacetylation
◦Changes in the timing of DNA
replication
Mono and Dimethylated
H3-Lys9
LO1,
LO2,
LO3 Constitutive
Heterochromatin
DNA which is theoretically
never transcribed but
plays critical structural
roles
Highly repetitive
sequences
Significant percentage of
human genome (15-20%)
Trimethylated H3-Lys9
 Chromatin Remodeling
LO1,
LO3,
Complex:
LO5 Activity and

Consequences
Remodeling does not solely have to be
about heterochromatin and euchromatin
transitions
Shifting the material associated with
nucleosomes can also influence gene
expression even when not tightly coiled
Chromatin
Remodeling
Complex:
Activity and
Consequenc
es
LO1,
LO5
Importance of
Heterochromatin
Originally thought to be a repository of “junk” DNA
Findings now indicate that is has structural and
functional importance
◦ Believed to confer strength and protection to centromeres
◦ May protect against change in sequence; can prevent crossing over
◦ May aid in alignment and separation of chromosomes during mitosis
and meiosis
◦ Heterochromatic regions of Y-chromosome have been shown to
contain fertility factors
◦ Heterochromatin also serves to more “permanently” turn off genes
that were used in development and are no longer needed
◦ Role in cellular specialization and differentiation
LO1,
LO3,
LO5

Model for the
molecular
mechanisms of
gene silencing
mediated by DNA
methylation.

49
Michela Curradi et al. Mol. Cell. Biol. 2002;22:3157-3173
LO1,
LO6

Epigenetics and Imprinting
Core phenotypic changes due to changes in gene
expression WITHOUT changes in the core DNA sequence
Differentially methylated domains of imprinted genes contain
CpG-rich, imperfect tandem repeats resulting in a RELATED
DNA STRUCTURE implicated in imprinting
◦ Specifically, the establishment and maintenance of parent of
origin-specific methylation patterns

PATERNALLY imprinted
◦ Paternal gene is OFF
◦ Maternal gene is ON

MATERNALLY imprinted
◦ Maternal gene is OFF
◦ Paternal gene is ON
LO1,
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Imprinting in Gametogenesis
Original imprinting in the gamete is erased
prior to spermatogenesis and oogenesis
Selective silencing
Different genes are silenced during
oogenesis than spermatogenesis leading to
specific maternal vs paternal imprinting
patterns
De-methylation and Re-methylation cycles
to add and erase imprinting
LO1,
LO6

Imprinting in Gametogenesis
Erasure via
DEMETHYLATION
(active or passive)
Multiple
mechanisms
including
deamination
followed by repair
and exclusion or
regulation of key
maintenance
molecules like
LO1, Differentially Methylated
LO6
Regions and Disorders (23 DMRs
exist)
White circle = maternal differentially
methylated regions
Black circle = paternal differentially
methylated regions
BWS = Beckwith-Wiedemann
Syndrome
AS= Angelman Syndrome
PWS= Prader-Willi Syndrome
SRS= Silver-Russell Syndrome
TNDM transient neonatal diabetes
mellitus
RB Retinoblastoma Important considerations for imprinting
UPD14 uniparental disomy 14 in the use of assisted reproductive
PHP1b pseudohypoparathyroidism type technologies
https://www.ncbi.nlm.nih.gov/pmc/article
1b s/PMC4182590/pdf/RMB2-13-193.pdf
LO1,
LO7

X-Inactivation Introduction
First described by Geneticist Mary Lyon
Lyonization = X chromosome
inactivation
Necessary for maintaining the balance
of X-linked genes
Happens early in development during
embryogenesis
X-inactivation in human tissues is
either RANDOM or imprinted
Some genes on the inactive X (Xi) are
still transcribed
LO1,
LO7

Effects of X-Inactivation
Dosage Compensation
◦Total amount of gene product between males and females is
made essentially equal
Mosaicism
◦Different cells within an individual can have different
chromosomal make-up
Variable Expression
◦Females heterozygotes for disease alleles can have different
or varying manifestations
LO1,
LO7
Structure of Inactive X
Chromosome
X-chromosome inactivation is a form of
epigenetics
Facultative Heterochromatin
Hypermethylated and hypoacetylated
histones
85% silenced with genes escaping
inactivation primarily located on the
short (p) arm
Inactivated X’s pick up stain more due
Inactive X = Barr Body to increased presence of methyl groups
 Process of
LO1,
LO7
X-
Inactivation
Determine Number of
Xs
Choose extra X to
inactivate
Initiate Inactivation
Expand/Spread the
Inactivation Signal
along appropriate
regions of
chromosome
Maintain the
inactivation
LO1,
LO7
 Mosaicism
LO1,
LO7,
LO8

Anhidrotic Ectodermal Dysplasia
◦ Patches of skin without sweat glands
◦ It is similar to the mosaicism observed with calico cats

Other diseases are also observed to be mosaic due
to random X-inactivation
LO5, Summarizing Methylation and
LO6,
LO7
X-inactivation
LO5,
LO6, Errors in Heterochromatin
LO7
Formation and/or Epigenetics and
Human Disease
Facioscapulohumeral muscular dystrophy
◦ Characterized by weakness and atrophy of particular muscle groups
(predominantly face, shoulders, and upper arms)
Friedreich’s ataxia
◦ Characterized by impaired or uncoordinated muscle movement
Fragile X syndrome
◦ Characterized by developmental delays and learning difficulties
◦ Expansion of CGG sequence repeats in FMR1 gene
◦ More CGG = More Methylation Potential

Prader-Willi Syndrome and Angelman Syndrome
LO5,
LO6,
LO7
Disease Examples
NOTE: These are not necessarily diseases of imprinting but
rather diseases that differentially manifest due to patterns of
imprinting
MATERNALLY IMPRINTED PATERNALLY IMPRINTED

Prader-Willi Syndrome ANGELMEN SYNDROME
Maternal copy is OFF; Paternal is Paternal Copy is OFF; Maternal is
deleted or lost or inappropriate pattern deleted, or lost or inappropriate pattern
placed placed
Loss of 15q11-13 Loss of 15q11-13
Gene Expression Lost = SNRPN and Gene Expression Lost = UBE3A
NDN
Developmental and intellectual
Hypotonia, obesity, hypogonadism deficiencies, epilepsy and tremors
LO5,

Prader-Willi vs. Angelman
LO6,
LO7
Mitochondrial
Genetics
BMS 532 MOLECUL AR BIOLOGY AND GENETICS
BLOCK 3 LECTURE 6
Objectives
1. Define the following terms: nucleoid, variable expression/variable patterns,
parental leakage, and heteroplasmy
2. Explain the size and susceptibility to damage of the mitochondrial genome
3. Explain how inheritance of mitochondria differs from autosomal or sex-
linked inheritance
4. List the different options for mitochondrial inheritance
5. Explain the role of mitochondrial DNA in human disease
6. Assess the inheritance of mitochondrial genomes based on the expected
inheritance patterns and parental expression of the mitochondria
LO1, LO2
Mitochondrial Genome
(mtDNA)
Circular genome (~16,500 base pairs)
mtDNA is arranged with proteins
into complexes = Nucleoids
◦ Contains all of the information for
propagation, transcription, stabilization
of the genome, and the small amount of
repair they can perform
◦ Very limited repair abilities with high
susceptibility to mutation (repair has
evolved to deal with ROS but still
limited)
◦ Mutations can occur in somatic cells and
be propagated within a tissue causing
accumulation of the altered
mitochondria with aging

Chinnery and Hudson
LO1, LO3

More Mitochondrial Genetics
Transcription and translation are possible within the
mitochondria and resemble prokaryotic processes including
polycistronic mRNA
Variants of mitochondrial genomes have been identified via
resequencing analyses
Most humans actually contain multiple mitochondrial
genotypes with specific patterns of variants accumulating
in different tissues over time
Mitotic events and the equal division of the cytoplasm
mean that it is possible for a cell expressing multiple
mitochondria to have offspring inheriting variable patterns
of the mitochondria
LO1, LO2,
LO3, LO4

Mitochondrial Inheritance
Most of the cytoplasm and therefore cytoplasmic material is contained within the
oocyte thus mitochondria and their genomes are most often maternally inherited
◦ NOTE: Chloroplast inheritance is similar

Inheritance patterns can vary among species
◦ Mammals = maternal inheritance
◦ Yeast (i.e. S. cerevisiae) = Biparental inheritance
◦ Plants (mitochondria AND chloroplasts)
◦ Angiosperms = most often maternal though biparental is possible
◦ Gymnosperms = usually paternal inheritance

MOST offspring do NOT inherit any paternal mitochondria when maternal inheritance
is expected
Parental Leakage refers to the occasional inheritance of mitochondria via sperm
when maternal inheritance is typical
◦ Mouse example = 1 to 4 per 100,000 mitochondria are inherited via paternal means
LO1, LO2,
LO3, LO5

Mitochondrial Inheritance
Cannot use traditional Punnett
squares to evaluate inheritance
Must consider:
1) mode of inheritance (Maternal?
Paternal? Biparetal?)
2) whether parent of origin has the ability
to express more than one type
◦ Heteroplasmy = expressing mutations
alongside normal counterparts
◦ More than one type of mitochondria present
◦ Variable proportions of mutant and wildtype
versions are possible

Also must consider the genotype to
phenotype ratio

Knorre 2019
LO1, LO2,
LO3

Mitochondrial Inheritance
In situations where more than one type of mitochondrion is
observed, the inheritance of the mitochondria is more
varied
◦ Example: If a plant has more than one chloroplast (one for green and one
for white) and exhibits a mixed phenotype (both green and white) in their
leaves
◦ the offspring could have white leaves, green leaves, or the mixture observed in the parent
◦ Tying this to mitochondria, if two types of mitochondria are present in the
maternal parent
◦ the offspring could inherit one, the other, or both
◦ NOTE: some evidence in humans implicates familial specific biparental
inheritance in humans (Luo et al 2018) though it could also be considered
this variable inheritance from a maternal source with more than one mtDNA
option
LO1, LO5
Mitochondrial Disease and
Inheritance
There is a wide range of
consequences and significant
implications for mtDNA in human
health
Multiple tissues and organs can be
affected by altered mitochondrial
function
◦ Somatic mutations can lead to tissue specific
consequences over time

The complex inheritance patterns mean
that there are different considerations
for mtDNA disorders
◦ Maternal inheritance complicates female fertility
for individuals with mitochondrial disorders

Chinnery and Hudson
LO6

Determining Inheritance
Two individuals of a species have offspring.
The maternal individual is heteroplastic while the paternal
individual is homoplastic.
Answer the following questions:
◦ If maternal mitochondrial inheritance is expected:
◦ What is the potential for the offspring?
◦ What is the potential for the next generation if the offspring are all female? All male?
◦ If paternal mitochondrial inheritance is expected:
◦ What is the potential for the offspring?
◦ What is the potential for the next generation if the offspring are all female? All male?