Ecb6 Lecture Ch19 PDF - Sexual Reproduction and Genetics

Summary

This ECB6 lecture covers sexual reproduction and genetics, including topics such as generating genetic variation, meiosis and fertilization, Mendel's laws of inheritance, and the benefits of sexual reproduction. The lecture also discusses gene duplications, mutations, and more.

Full Transcript

CHAPTER 9
CHAPTER 19

Sexual Reproduction
and Genetics
Dr. Moe Abbas

Copyright © 2023 by W. W. Norton & Company, Inc.
 For Chapter 9, you are only responsible for what is in this
lecture

For chapter 19 you are responsible for this lecture and the book
 For your last
lecture:
Generating genetic variation
THE BENEFITS OF SEX
MEIOSIS AND FERTILIZATION
MENDEL AND THE LAWS OF
INHERITANCE
GENETICS AS AN EXPERIMENTAL TOOL
EXPLORING HUMAN GENETICS
Generating genetic variation
Horizontal gene transfer (more predominant in
prokaryotes)
Don’t confuse it with Vertical gene transfer in
eukaryotes

non-sexual movement of genetic information between genomes.
Incoming DNA or RNA can replace existing genes, or can introduce
 Point Mutations and their
effect

Point Mutations Are Caused by Failures of the Normal Mechanisms for
Copying and Repairing DNA
Mutations Can Also Change the Regulation of a
Gene
DNA Duplications Give Rise to Families of Related Genes
 The globin case of gene duplications

Fetal hemoglobin
has a higher
affinity for oxygen
> adults. A
property important
for oxygen transfer
from mother to
child.
2nd duplication Most gene
event duplications are
1st duplication
not functional and
event are heavy with
mutations. We call
them
pseudogenes.
Question: Why do cells keep non functional genes? Why
 The bulk of the human genome is made of repetitive
nucleotide sequences and other non-protein-coding DNA.

LINEs (long interspersed nuclear elements) = 6000
– 8000 bps
SINEs (short interspersed nuclear elements) = 500
Class of DNA sequences known as transposable elements (TEs). TEs can
bps
move and duplicate themselves within the genome, which can result in
the creation of new, repetitive DNA sequences.

They do not code for proteins; instead, they play
various roles in chromosome structure and function.
 The bulk of the human genome is made of repetitive
nucleotide sequences and other non-protein-coding DNA.

Some scientists classify LINEs and
SINEs as retrotransposons

DNA transposons move using a cut-and-paste mechanism. In
contrast, retrotransposons move in a copy-and-paste fashion by
duplicating the element into a new genomic location via an RNA
intermediate. Thus, retrotransposons increase their copy number
more rapidly than DNA transposons.
 The bulk of the human genome is made of repetitive
nucleotide sequences and other non-protein-coding DNA.

Simple sequence repeats (SSRs)
or microsatellites are DNA stretches
consisting of short, tandemly repeated di-,
tri-, tetra-or penta-nucleotide motifs
 The bulk of the human genome is made of repetitive
nucleotide sequences and other non-protein-coding DNA.
 The bulk of the human genome is made of repetitive
nucleotide sequences and other non-protein-coding DNA.
Chapter 19!
 THE BENEFITS OF
SEX
What is the ultimate goal of Cells?
Reproduction is a way to make new organisms that can grow. Thus, every organism’s
apparent “goal” is to fill the available world with its offspring, that is, with "self".

Asexual Sexual
reproduction reproduction
Fast, allows a In general, slow leads
theocratically to genetically different
unlimited number of organisms.
identical offspring’s. Most multicellular
Identical to the organisms are here
parental line but not all
(Observation not a
rule!)
Parthenogenesis: oocytes that develop
with out sperm/fertilization

Extra reading if you like: Sexual reproduction in Paramecium and
 Sexual reproduction involves both Diploid and haploid
cells 2 n
2n 1 copy
copies

Most Cells are Diploids or
haploids
Extra reading if
you chromosomes
Polytene like of plants and
fruit flies can be 1024-ploid.Ploidy of
systems such as the salivary
gland, elaiosome, endosperm,
and trophoblast can exceed this, up to
Homologous 1048576-ploid in the silk glands of the
Chrs, each commercial silkworm Bombyx mori.
inherited from
different parent
2
n Somatic cells vs germ
line cells

n

2
n

No
2 Precursor
progeny
n s of future
generatio
 Sexual reproduction generates
genetic diversity
If maternal and paternal homologs carry the same genes, why
would sexual reproduction produce genetic diversity?
llele: Variant version of a gene. Do say two alleles of a gene
Gene pool: All genes (ANDnotalleles)
2 genes!within a
population.
Many number
Gene frequency: genes areof multi-allelic!
times an allele occur in a
gene pool.

https://virtualbiologylab.org/ModelsHTML5/PopGenFishbowl/ Extra reading if you like
PopGenFishbowl.html Eye color determination
2 major eye color
genes and 14 more
genes determining the
expression of this
Sexual reproduction gives organisms a competitive
advantage in a changing environment

Genetic reshuffling

Genetic improvement is
conditional
Adaptation to a changing
environment

Extra reading if you like: moth adaptation
 2. Meiosis and
Fertilization
Special cell division in sexually
reproducing organisms that reduces the
number of chromosomes in gametes

Duplicated
Homologous
Chromosomes Pair
During Meiotic
Prophase
Crossing-Over Occurs Between
the Duplicated Maternal and
Paternal Chromosomes in Each
Bivalent

Number of chrs n 2n
 Chromosome pairing is key in
Meiosis

From a cell-biological point of view in mitosis the homologous chromosomes
do not pair, they are not in the proper configuration to support crossing over.

From a molecular-mechanistic point of view crossing over is usually initiated
by a double-strand break (a cut through both chains of the double helix) in one
of the interacting partners. The specialized enzymes that make these double
strand breaks are not usually expressed during mitosis.
Future reading no need to memorise
 Notice the
similarities and
differences

Figure 6–31 Homologous reco
Chromosome Pairing and Crossing-Over Ensure the
Proper Segregation of Homologs
Haploid Gametes Contain Reassorted Genetic
Information >> Independent Assortment

 Independent assortment
 2n different haploid gametes
(with n different
chromosomes)
 Here n = 3, and there are 23,
or 8
 n=23  223

 8.388.608 possibilities (Without crossing
over)

 No two similar organisms
Haploid Gametes Contain
Reassorted Genetic Information
>> Crossing over
How many different
gametes can you make?

~limitless genetic
variations
Meiosis Is Not Flawless
Nondisjunction
~10% of egg meiosis
~3% of sperm meiosis (cell cycle
checkpoint)
Aneuploidy = wrong number of
chromosomes
 MENDEL AND THE LAWS OF
INHERITANCE
I am convinced that it will not be long before the whole
world acknowledges the results of my work.

Mendel Disproved the Alternative Theories of
Inheritance
Mendel Studied Traits That Are Inherited in a Discrete Fashion

Characters

Traits
Mendel Studied Traits That Are Inherited in
a Discrete Fashion

Advantages of using peas
Short generation time
Large numbers of
offspring
Mating could be
controlled;
self-pollinated
cross-pollinated
Mendel chose:
only those characters that occur in 2 distinct alternative
forms (yellow/green for example)
plants that were true-breeding (plants that produce
offspring of the same variety when they self-pollinate)
 Hybridization
 Hybridization -> two
contrasting, true-breeding
varieties
 P generation = true-
breeding parents
 F1 generation = hybrid
offspring of the P
generation
 F2 generation = from F1
individuals self-pollinate or
cross-pollinate with other F1
hybrids
 Mendel’s 3 laws

The Law of Segregation

The Law of Independent assortment

The Law of Dominance
 The Law of Segregation

In the 1800s, the explanation of
heredity was the “blending”
hypothesis
Mendels F1 generation were purple
Blending hypothesis must be wrong!
 The Law of Segregation

Mendel crossed the F1 hybrids,

>> many of the F2 plants had
purple flowers, but some had
white

>> ratio of about 3 purple to 1
white flower in the F2 generation
 The Law of Segregation

Mendel reasoned > only purple flower factor
affects color in F1 hybrids

Mendel called
purple flower color a dominant trait
white flower color a recessive trait
White flower factor not diluted or destroyed
because it reappeared in the F2 generation
 The Law of Segregation

Mendel observed
same pattern in 6 other characters
each represented by two trait

What Mendel called a “heritable
factor” is what we now call a gene

Notice the ratio! A 3:1 ratio doesn’t
mean if there were only 4 offspring's 3
will be different to 1!
 Mendel’s
Model

 Mendel developed a model to
explain the 3:1 inheritance
pattern in F2
1. Alternative versions of genes
(alleles):
account for variations in
inherited characters
resides at a specific locus on a
specific chromosome
Mendel’s Model + the law of
dominance
 Mendel developed a model to explain the 3:1 inheritance pattern in
F2
1. Alternative versions of genes (alleles):
account for variations in inherited characters
resides at a specific locus on a specific chromosome
2. Every organism inherits 2 alleles (per character), one from each
parent
3. If alleles are different
the dominant allele, determines the organism’s appearance
the recessive allele, has no noticeable effect on appearance
4. law of segregation:
The 2 alleles separate (segregate) at gamete formation
end up in different gametes
Mendel’s Model

 Model explains 3:1 ratio in the F2
 Punnett square > Possible
combinations of sperm and egg
 dominant allele > capital letter >P
 recessive allele > lowercase letter >p
Video: Mendel’s Cross on Flower Color
Mendel’s Model

 Model explains 3:1 ratio in the F2
 Punnett square > Possible
combinations of sperm and egg
 dominant allele > capital letter >Y
 recessive allele > lowercase letter >y
Useful Genetic Vocabulary
 Homozygote: organism with two identical alleles for a gene
homozygous for the gene controlling that character
 Heterozygote: organism with two different alleles for a
gene
heterozygous for the gene controlling that character
 Phenotype: physical appearance (purple)
 Genotype: genetic makeup (Pp or PP)
 In the example of flower color in pea plants, PP and Pp
plants have the same phenotype (purple) but different
genotypes
Phenotype and
Genotype
 The Law of Independent Assortment

 Law of segregation > followed a single character
 F1 is monohybrid
Heterozygous for one character
 Cross between such heterozygotes is called a monohybrid
cross
The Law of Independent Assortment

 Now 2 characters (color and
shape)
 Dihybrids in F1 generation,
heterozygous for both characters
 Dihybrid cross > are the 2
characters independent or
dependent?
Mendels second law:

The Law of Independent
Assortment
Genes for different traits are sorted
separately from one another so that the
inheritance of one trait is not dependent
on the inheritance of another.
The Law of Independent Assortment
 Using dihybrid cross, Mendel
developed the law of
independent assortment
 Each pair of alleles segregates
independently of any other pair
of alleles (during gamete
formation)
The Law of Independent Assortment
 Using dihybrid cross, Mendel
developed the law of
independent assortment
 Each pair of alleles segregates
independently of any other pair
of alleles (during gamete
formation)
 Only applies for genes of
different chromosomes
Or far apart on same
chromosome (why?)
 What happens to genes close to
each other on a chromosome?
Genes That Lie on the Same Chromosome
Can Segregate Independently by Crossing-
Over
 Linkage map = genetic map of chromosome based on
recombination frequencies
 Distances between genes expressed as map units;
one map unit = 1% recombination frequency
 Map units indicate relative distance and order, not precise
locations of genes
Genes That Lie on the Same Chromosome
Can Segregate Independently by Crossing-
Over

 Genes far apart on same
chromosome >
recombination frequency
near 50%
 Such genes are physically
linked, but genetically
unlinked, and behave as if
found on different
chromosomes
 Ideas of dominance and interaction

Different Alleles can have
different
function/expression
 Ideas of dominance and interaction
Allelic interactions

Complete dominance Incomplete dominance Co-dominance
Dominant allele fully expressed neither allele fully expressed Both allele fully expressed
 Ideas of dominance and interaction

Sex linked traits
Traits that are usually carried on sex
chromosomes
e.g. Color blindness, hemophilia
 Ideas of dominance and interaction

Pleiotropy
a single gene
affects two or
more
characters

Extra reading
if you like:
genetic cause
of sickle cell
anemia
 Ideas of dominance and interaction

Environmen
t

Effect of
epigenetics
 Ideas of dominance and interaction

Polygenics
Traits that are
determined
by multiple
genes

Extra reading if
you like:
genetic
relationship
between eye or
skin colour
Mendel’s Law of Segregation Applies to All
Sexually Reproducing Organisms
A pedigree shows the risks of first-cousin
marriages

Recessive allele that
causes a disease is rare >
unlikely that two carriers
will meet and mate
Consanguineous matings
(between close relatives)
increases chance that both
parents carry same rare
allele
Most societies and
cultures have laws or
taboos
family members that show the deaf phenotype are indicated against marriages
by a blue symbol, those
that do not by a gray symbol between close relatives
 Example
Huntington's disease Example
cystic fibrosis
EACH OF US CARRIES MANY POTENTIALLY
HARMFUL RECESSIVE MUTATIONS
MOST MUTATIONS ARE NEUTRAL
DELETERIOUS MUTATIONS THAT ARE DOMINANT >
FAST ELIMINATION FROM POPULATION
RECESSIVE MUTATIONS REMAIN AT LOW
FREQUENCY IN POPULATION
The Classical Genetic Approach Begins with
Random Mutagenesis

Can you
guess which
mutation
type is the
least likely
to be
effective?
Why?
Panel 19–1 (Part 1) Some essentials of
classical genetics
Genetic Screens Identify Mutants Deficient
in Specific Cell Processes

Different
screen to
identify
Conditional Mutants Permit the Study of Lethal
Mutations

Biochemistry 2019 58 (13), 1738-1
DOI: 10.1021/acs.biochem.8b00964
 CHAPTER CONTENTS

THE BENEFITS OF SEX
MEIOSIS AND FERTILIZATION
MENDEL AND THE LAWS OF INHERITANCE
GENETICS AS AN EXPERIMENTAL TOOL
EXPLORING HUMAN GENETICS
 Single-nucleotide polymorphisms (SNPs) are points
in the genome that differ by a single nucleotide pair
between one portion of the population and another

SNPs occur
everywhere!
What their effect is
will depend on where
they occurred.

Coding region 
Promoter elements 
Introns 
Transposons 

We all have SNPs!!
Genetic drifting: drifting of the frequency of an allele relative to that of the other
alleles in a population over time because of chance or random event
Natural Variation is an excellent tool to
study genetics
Genome-wide
Association
Studies

We use Natural
variation and
SNPs to identify
new role for
genes
Genome-wide Association Studies Can Aid the
Search for Mutations Associated with Disease
SNP analysis can pin down the location of
a mutation that causes a genetic disease
Genome-wide association studies identify DNA variations that are significantly
more frequent in people with age-related macular degeneration (AMD).

100,000 SNPs in each of 146 people
A quantitative trait
locus (QTL) is a region
of DNA which is
associated with a
particular phenotypic trait,
which varies in degree
and which can be
attributed

Really good for
mono-allelic
traits
 Lecture Slides
This concludes the Slide Set for Chapter 19
Essential Cell Biology, Sixth Edition

No more MBLS-101 lectures!
You survived!

Copyright © 2023 by W. W. Norton & Company, Inc.