Lecture3-GeneticsSimpleTraits.pdf

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Mentimeter questions
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 Genetic Variation,
Chromosomal Inheritance
and Simple Traits
Lecture 3
Today’s Objectives
Finish reviewing the building blocks of life,
including (slides from lecture 2)
Cell types (eukaryotic vs. prokaryotic, somatic vs
gamete)
Define some of those terms on the
DNA TERMS AND CONCEPTS TO KNOW
Proteins slide from lecture 2

Discuss protein synthesis
Review cellular division
Learn how genetic variation is produced
Today’s Objectives
Finish reviewing the building blocks of life,
including (slides from lecture 2)
Cell types (eukaryotic vs. prokaryotic, somatic vs
gamete)
DNA
Proteins
Discuss protein synthesis
Review cellular division
Learn how genetic variation is produced
The Cell
Prokaryote Eukaryote

6
Eukaryotic Cell Contains DNA
Contains mtDNA
Animal Cell

7
What is a chromosome?
Chromatin
Loose form of DNA
Chromosome
Discrete structures; condensed DNA

Supercoiling
8
Homologous Pairs of Chromosomes

9
 Homologous Pairs of Chromosomes

Homologs = same genes at same loci
- Basically, identical pairs
10
Homologous
pair…

11
Eukaryotic Cell Types
Somatic
All body cells
Ancient Greek (soma) for
‘body’
Direct cell activity
Diploid
Contain 46 chromosomes
Gametes

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Eukaryotic Cell Types
Somatic
Gametes (Ancient Greek
(gamos) for “marriage)
Reproductive cells
Males: sperm
Females: egg
Provides cytoplasm, including
mitochondria (w/ mtDNA)
Transmit genetic information
Haploid
Contain 23 chromosomes

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DNA Structure (a discovery collective effort)

James Watson & Francis Crick

Maurice Wilkins
Rosalind Franklin

14
Anatomy of DNA

15
Anatomy of DNA
Made up of nucleotides = molecules consisting
of a nitrogen base and a sugar + phosphate

16
Anatomy of DNA
DNA = Deoxyribose Nucleic Acid
2 chains of nucleotides

S = sugar
(deoxyribose)

P = phosphate group

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Anatomy of DNA
Cytosine (C) ≡ Guanine (G)
Thymine (T) ≡ Adenine (A)

18
DNA Replication
Occurs whenever a
cell divides into 2 new
cells

Step 1 = Denaturation
helicase
Step 2 = Annealing
primase
Step 3 = Extension
DNA polymerase
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DNA Code
Gene – a sequence of nucleotides that codes
for a protein
Proteins are made up of amino acids
DNA instructions are a triplet of bases
AGA TAC GCT AAT TCA
Code is universal

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Today’s Objectives
Finish reviewing the building blocks of life,
including (slides from lecture 2)
Cell types (eukaryotic vs. prokaryotic, somatic vs
gamete)
DNA
Proteins
Discuss protein synthesis
Review cellular division
Learn how genetic variation is produced
What is a gene?
A sequence of DNA bases that specifies the
order of amino acids in a protein
DNA Code
Gene – a sequence of nucleotides that codes
for a protein
Proteins are made up of amino acids
DNA instructions are a triplet of bases
AGA TAC GCT AAT TCA
Code is universal
Gene Expression and Protein
Synthesis
We say a gene is expressed when it is used as
a template to build a protein
Protein synthesis takes place outside the
nucleus and requires ribonucleic acid (RNA)
What makes RNA different from DNA?
 Protein Synthesis Step 1
1. Transcription
DNA is used as template to
create messenger RNA
(mRNA)
2. Translation
 Step 1

Protein Synthesis
1. Transcription
DNA is used as template to
create messenger RNA
(mRNA) Step 2

2. Translation
Uses mRNA as a template
to create a sequence of
amino acids
Transfer RNA (tRNA) assists
in the assembly of proteins
Proteins
Functions
Initiate and enhance chemical interactions
Provide structure to cells
Transport molecules from cell to cell
Examples
Hemoglobin
Enzymes
Hormones
Regulatory proteins
Today’s Objectives
Finish reviewing the building blocks of life,
including (slides from lecture 2)
Cell types (eukaryotic vs. prokaryotic, somatic vs
gamete)
DNA
Proteins
Discuss protein synthesis
Review cellular division
Learn how genetic variation is produced
Eukaryotic Cell Types
Somatic
All body cells
Direct cell activity
Diploid
Contain 46 chromosomes
Divide via mitosis
Gametes
Reproductive cells
Males: sperm
Females: egg
Provides cytoplasm, including
mitochondria (w/ mtDNA)
Transmit genetic information
across generations through
sexual reproduction
Haploid
Contain 23 chromosomes
Produced via meiosis 29
Lifecycle of a Somatic Cell

(a.k.a. DNA
replication)
Lifecycle of a Somatic Cell

(a.k.a. DNA
replication)
What is a chromosome?
Chromatin
Loose form of DNA
Chromosome
Discrete structures; condensed DNA
 Somatic cells undergo mitosis
2 daughter cells that are identical to the parent cell
Meiosis Produces 4 unique daughter cells
These 4 unique daughter cells are the gametes
Meiosis Produces 4 unique daughter cells
These 4 unique daughter cells are the gametes
Mitosis Meiosis
Additional Resources for
Mitosis and Meiosis
https://www.youtube.com/watch?v=IQJ4DBkCn
co
https://www.youtube.com/watch?v=VzDMG7ke
69g
Today’s Objectives
Finish reviewing the building blocks of life,
including (slides from lecture 2)
Cell types (eukaryotic vs. prokaryotic, somatic vs
gamete)
DNA
Proteins
Discuss protein synthesis
Review cellular division
Learn how genetic variation is produced
How is genetic variation
produced?
 Allele “A”:
TGAGGACTCCTCT
TT
A a
Allele “a”:
TGAGGACACCTCT
TT
How is genetic variation
produced?
1. Mutation
 Mutations
Somatic mutations vs.
germ-line mutations
Mutations can be
beneficial, harmful, or
neutral
A source of new genetic
variation
How is genetic variation
produced?
1. Mutation
2. Random assortment
Random Assortment
How is genetic variation
produced?
1. Mutation
2. Random assortment
3. Recombination (crossing over)
Meiosis Produces 4 unique daughter cells
These 4 unique daughter cells are the gametes
Meiosis Produces 4 unique daughter cells
These 4 unique daughter cells are the gametes
How is genetic variation
produced?
1. Mutation
Occurs through
2. Random assortment sexual reproduction
3. Recombination (crossing over)
Sexual vs. Asexual Reproduction

https://www.youtube.com/watch?v=fcGDUcGjcyk
 Terms and Concepts to Know
Homologous pair Meiosis
Mitosis Somatic cell
RNA Gamete
mRNA Haploid
Transcription Diploid
Translation Mutation
tRNA Somatic vs. germ-line
Uracil vs. thymine mutation
ribosome Random assortment
Sexual vs. asexual Recombination
reproduction (crossing over
Before the next class
Lecture Question 3 – During which phase of protein synthesis is
DNA used as a template to make RNA?
Readings -
ANY ADDITIONAL
QUESTIONS?
ASK THEM HERE:

I will answer at the start of
the next class…

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