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Michael Philips

Michael Philips

Structure of Proteins

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Table of Contents

Section 1: The Beginnings of Molecular Biology
Biochemistry Review: Importance of Chemical Bonds

53m 29s

Intro
0:00
Lesson Overview
0:14
Chemical Bonds
0:41
Attractive Forces That Hold Atoms Together
0:44
Types of Bonds
0:56
Covalent Bonds
1:34
Valence Number
1:58
H O N C P S Example
2:50
Polar Bonds
7:23
Non-Polar Bond
8:46
Non-Covalent Bonds
9:46
Ionic Bonds
10:25
Hydrogen Bonds
10:52
Hydrophobic Interactions
11:34
Van Der Waals Forces
11:58
Example 1
12:51
Properties of Water
18:27
Polar Molecule
13:34
H-bonding Between Water H20 Molecules
19:29
Hydrophobic Interactions
20:30
Chemical Reactions and Free Energy
22:52
Transition State
23:00
What Affect the Rate
23:27
Forward and Reserve Reactions Occur Simultaneously But at Different Rate
23:51
Equilibrium State
24:29
Equilibrium Constant
25:18
Example 2
26:16
Chemical Reactions and Free Energy
27:49
Activation Energy
28:00
Energy Barrier
28:22
Enzymes Accelerate Reactions by Decreasing the Activation Energy
29:04
Enzymes Do Not Affect the Reaction Equilibrium or the Change in Free Energy
29:22
Gibbs Free Energy Change
30:50
Spontaneity
31:18
Gibbs Free Energy Change Determines Final Concentrations of Reactants
34:36
Endodermic vs. Exothermic Graph
35:00
Example 3
38:46
Properties of DNA
39:37
Antiparallel Orientation
40:29
Purine Bases Always Pairs Pyrimidine Bases
41:15
Structure Images
42:36
A, B, Z Forms
43:33
Major and Minor Grooves
44:09
Hydrogen Bonding and Hydrophobic Interactions Hold the Two Strands Together
44:39
Denaturation and Renaturation of DNA
44:56
Ways to Denature dsDNA
45:28
Renature When Environment is Brought Back to Normal
46:05
Hyperchromiicity
46:36
Absorbs UV Light
47:01
Spectrophotometer
48:01
Graph Example?
49:05
Example 4
51:02
Mendelian Genetics & Foundational Experiments

1h 9m 27s

Intro
0:00
Lesson Overview
0:22
Gregor Johann Mendel
1:01
Was a Biologist and Botanist
1:14
Published Seminal Paper on Hybridization and Inheritance in the Pea Plant
1:20
Results Criticized
1:28
Father of Modern Genetics
1:59
Mendel’s Laws
2:19
1st Law: Principle of Independent Segregation of Alleles
2:27
2nd Law: Principle of Independent Assortment of Genes
2:34
Principle of Independent Segregation (of Alleles)
2:41
True Breeding Lines / Homozygous
2:42
Individuals Phenotypes Determined by Genes
3:15
Alleles
3:37
Alleles Can Be Dominant or Recessive
3:50
Genotypes Can be Experimentally Determined by Mating and Analyzing the Progeny
5:36
Individual Alleles Segregate Independently Into Gametes
5:55
Example 1
6:18
Principle of Independent Segregation (of Alleles)
16:11
Individual Genes Sort Independently Into Gametes
16:22
Each Gamete Receives One Allele of Each Gene: 50/50 Chance
16:46
Genes Act Independently to Determine Unrelated Phenotypes
16:57
Example: Punnett Square
17:15
Example 2
21:36
The Chromosomal Theory of Inheritance
30:41
Walter S Sutton Linked Cytological Studies with Mendels Work
31:02
Diploid Cells Have Two Morphologically Similar Sets of Chromosomes and Each Haploid Gamete Receives One Set
31:17
Genes Are on Chromosome
31:33
Gene for Seed Color’s on a Different Chromosome Than Gene for Seed Texture
31:44
Gene Linkage
31:55
Mendel’s 2nd Law
31:57
Genes Said to Be Linked To Each Other
32:09
Linkage Between Genes
32:29
Linkage is Never 100% Complete
32:41
Genes are Found on Chromosomes
33:00
Thomas Hunt Morgan and Drosophila Melanogaster
33:01
Mutation Linked to X Chromosome
33:15
Linkage of White Gene
33:23
Eye Color of Progeny Depended on Sex of Parent
33:34
Y Chromosome Does Not Carry Copy of White Gene
33:44
X Linked Genes, Allele is Expressed in Males
33:56
Example
34:11
Example 3
35:52
Discovery of the Genetic Material of the Cell
41:52
Transforming Principle
42:44
Experiment with Streptococcus Pneumoniae
42:55
Beadle and Tatum Proposed Genes Direct the Synthesis of Enzymes
45:15
One Gene One Enzyme Hypothesis
45:46
One Gene One Polypeptide Theory
45:52
Showing the Transforming Material was DNA
46:14
Did This by Fractionating Heat-Killed “S” Strains into DNA, RNA, and Protein
46:32
Result: Only the DNA Fraction Could Transform
47:15
Leven: Tetranucleotide Hypothesis
48:00
Chargaff Showed This Was Not the Case
48:48
Chargaff: DNA of Different Species Have Different Nucleotide Composition
49:02
Hershey and Chase: DNA is the Genetic Material
50:02
Incorporate Sulfur into Protein and Phosphorous into DNA
51:12
Results: Phosphorase Entered Bacteria and Progeny Phage, But no Sulfur
53:11
Rosalind Franklin’s “Photo 51” Showing the Diffraction Pattern of DNA
53:50
Watson and Crick: Double Helical Structure of DNA
54:57
Example 4
56:56
Discovery of the Genetic Material of the Cell
58:09
Kornberg: DNA Polymerase I
58:10
Three Postulated Methods of DNA Replication
59:22
Meselson and Stahl: DNA Replication is Semi-Conservative
1:00:21
How DNA Was Made Denser
1:00:52
Discovery of RNA
1:03:32
Ribosomal RNA
1:03:48
Transfer RNA
1:04:00
Messenger RNA
1:04:30
The Central Dogma of Molecular Biology
1:04:49
DNA and Replication
1:05:08
DNA and Transcription = RNA
1:05:26
RNA and Translation = Protein
1:05:41
Reverse Transcription
1:06:08
Cracking the Genetic Code
1:06:58
What is the Genetic Code?
1:07:04
Nirenberg Discovered the First DNA Triplet That Would Make an Amino Acid
1:07:16
Code Finished in 1966 and There Are 64 Possibilities or Triplet Repeats/ Codons
1:07:54
Degeneracy of the Code
1:08:53
Section 2: Structure of Macromolecules
Structure of Proteins

49m 44s

Intro
0:00
Lesson Overview
0:10
Amino Acids
0:47
Structure
0:55
Acid Association Constant
1:55
Amino Acids Make Up Proteins
2:15
Table of 21 Amino Acid Found in Proteins
3:34
Ionization
5:55
Cation
6:08
Zwitterion
7:51
Anion
9:15
Example 1
10:53
Amino Acids
13:11
L Alpha Amino Acids
13:19
Only L Amino Acids Become Incorporated into Proteins
13:28
Example 2
13:46
Amino Acids
18:20
Non-Polar
18:41
Polar
18:58
Hydroxyl
19:52
Sulfhydryl
20:21
Glycoproteins
20:41
Pyrrolidine
21:30
Peptide (Amide) Bonds
22:18
Levels of Organization
23:35
Primary Structure
23:54
Secondary Structure
24:22
Tertiary Structure
24:58
Quaternary Structure
25:27
Primary Structure: Specific Amino Acid Sequence
25:54
Example 3
27:30
Levels of Organization
29:31
Secondary Structure: Local 3D
29:32
Example 4
30:37
Levels of Organization
32:59
Tertiary Structure: Total 3D Structure of Protein
33:00
Quaternary Structure: More Than One Subunit
34:14
Example 5
34:52
Protein Folding
37:04
Post-Translational Modifications
38:21
Can Alter a Protein After It Leaves the Ribosome
38:33
Regulate Activity, Localization and Interaction with Other Molecules
38:52
Common Types of PTM
39:08
Protein Classification
40:22
Ligand Binding, Enzyme, DNA or RNA Binding
40:36
All Other Functions
40:53
Some Functions: Contraction, Transport, Hormones, Storage
41:34
Enzymes as Biological Catalysts
41:58
Most Metabolic Processes Require Catalysts
42:00
Most Biological Catalysts Are Proteins
43:13
Enzymes Have Specificity of Reactants
43:33
Enzymes Have an Optimum pH and Temperature
44:31
Example 6
45:08
Structure of Nucleic Acids

1h 2m 10s

Intro
0:00
Lesson Overview
0:06
Nucleic Acids
0:26
Biopolymers Essential for All Known Forms of Life That Are Composed of Nucleotides
0:27
Nucleotides Are Composed of These
1:17
Nucleic Acids Are Bound Inside Cells
2:10
Nitrogen Bases
2:49
Purines
3:01
Adenine
3:10
Guanine
3:20
Pyrimidines
3:54
Cytosine
4:25
Thymine
4:33
Uracil
4:42
Pentoses
6:23
Ribose
6:45
2' Deoxyribose
6:59
Nucleotides
8:43
Nucleoside
8:56
Nucleotide
9:16
Example 1
10:23
Polynucleotide Chains
12:18
What RNA and DNA Are Composed of
12:37
Hydrogen Bonding in DNA Structure
13:55
Ribose and 2! Deoxyribose
14:14
DNA Grooves
14:28
Major Groove
14:46
Minor Groove
15:00
Example 2
15:20
Properties of DNA
24:15
Antiparallel Orientation
24:25
Phosphodiester Linkage
24:50
Phosphate and Hydroxyl Group
25:05
Purine Bases Always Pairs Pyramidine Bases
25:30
A, B, Z Forms
25:55
Major and Minor Grooves
26:24
Hydrogen Bonding and Hydrophobic Interactions Hold Strands Together
26:34
DNA Topology - Linking Number
27:14
Linking Number
27:31
Twist
27:57
Writhe
28:31
DNA Topology - Supercoiling
31:50
Example 3
33:16
Section 3: Maintenance of the Genome
Genome Organization: Chromatin & Nucleosomes

57m 2s

Intro
0:00
Lesson Overview
0:09
Quick Glossary
0:24
DNA
0:29
Gene
0:34
Nucleosome
0:47
Chromatin
1:07
Chromosome
1:19
Genome
1:30
Genome Organization
1:38
Physically Cellular Differences
3:09
Eukaryotes
3:18
Prokaryotes, Viruses, Proteins, Small Molecules, Atoms
4:06
Genome Variance
4:27
Humans
4:52
Junk DNA
5:10
Genes Compose Less Than 40% of DNA
6:03
Chart
6:26
Example 1
8:32
Chromosome Variance - Size, Number, and Density
10:27
Chromosome
10:47
Graph of Human Chromosomes
10:58
Eukaryotic Cell Cycle
12:07
Requirements for Proper Chromosome Duplication and Segregation
13:07
Centromeres and Telomeres
13:28
Origins of Replication
13:38
Illustration: Chromosome
13:44
Chromosome Condensation
15:52
Naked DNA to Start
16:00
Beads on a String
16:13
Mitosis
16:52
Start with Two Different Chromosomes
17:18
Split Into Two Diploid Cells
17:26
Prophase
17:42
Prometaphase
17:52
Metaphase
19:10
Anaphase
19:27
Telophase
20:11
Cytokinesis
20:31
Cohesin and Condensis
21:06
Illustration: Cohesin and Condensis
21:19
Cohesin
21:38
Condensin
21:43
Illustration of What Happens
21:50
Cohesins
27:23
Loaded During Replication and Cleaved During Mitosis
27:30
Separase
27:36
Nucleosomes
27:59
Histone Core
28:50
Eight Histone Proteins
28:57
Octamer of Core Histones Picture
29:14
Chromosome Condensation via H1
30:59
Allows Transition to Compact DNA
31:09
When Not in Mitosis
31:37
Histones Decrease Available Binding Sites
32:38
Histone Tails
33:21
Histone Code
35:32
Epigenetic Code
35:56
Phosphorylation
36:45
Acetylation
36:57
Methylation
37:01
Ubiquitnation
37:04
Example 2
38:48
Nucleosome Assembly
41:22
Duplication of DNA Requires Duplication of Histones
41:50
Old Histones Are Recycled
42:00
Parental H3-H4 Tetramers Facilitate the Inheritance of Chromatin States
44:04
Example 3
46:00
Chromatin Remodeling
48:12
Example 4
53:28
DNA Replication

1h 9m 55s

Intro
0:00
Lesson Overview
0:06
Eukaryotic Cell Cycle
0:50
G1 Growth Phase
0:57
S Phase: DNA & Replication
1:09
G2 Growth Phase
1:28
Mitosis
1:36
Normal Human Cell Divides About Every 24 Hours
1:40
Eukaryotic DNA Replication
2:04
Watson and Crick
2:05
Specific Base Pairing
2:37
DNA Looked Like Tetrinucleotide
2:55
What DNA Looks Like Now
3:18
Eukaryotic DNA Replication - Initiation
3:44
Initiation of Replication
3:53
Primer Template Junction
4:25
Origin Recognition Complex
7:00
Complex of Proteins That Recognize the Proper DNA Sequence for Initiation of Replication
7:35
Prokaryotic Replication
7:56
Illustration
8:54
DNA Helicases (MCM 2-7)
11:53
Eukaryotic DNA Replication
14:36
Single-Stranded DNA Binding Proteins
14:59
Supercoils
16:30
Topoisomerases
17:35
Illustration with Helicase
19:05
Synthesis of the RNA Primer by DNA Polymerase Alpha
20:21
Subunit: Primase RNA Polymerase That Synthesizes the RNA Primer De Navo
20:38
Polymerase Alpha-DNA Polymerase
21:01
Illustration of Primase Function Catalyzed by DnaG in Prokaryotes
21:22
Recap
24:02
Eukaryotic DNA Replication - Leading Strand
25:02
Synthesized by DNA Polymerase Epsilon
25:08
Proof Reading
25:26
Processivity Increased by Association with PCNA
25:47
What is Processivity?
26:19
Illustration: Write It Out
27:03
The Lagging Strand/ Discontinuing Strand
30:52
Example 1
31:57
Eukaryotic DNA Replication - Lagging Strand
32:46
Discontinuous
32:55
DNA Polymerase Delta
33:15
Okazaki Fragments
33:36
Illustration
33:55
Eukaryotic DNA Replication - Okazaki Fragment Processing
38:26
Illustration
38:44
When Does Okazaki Fragments Happen
40:32
Okazaki Fragments Processing
40:41
Illustration with Okazaki Fragments Process Happening
41:13
Example 2
47:42
Example 3
49:20
Telomeres
56:01
Region of Repetitive Nucleotide Sequences
56:26
Telomeres Act as Chromosome Caps by Binding Proteins
57:42
Telomeres and the End Replication Problem
59:56
Need to Use a Primer
59:57
DNA Mutations & Repairs

1h 13m 8s

Intro
0:00
Lesson Overview
0:06
Damage vs. Mutation
0:40
DNA Damage-Alteration of the Chemical Structure of DNA
0:45
DNA Mutation-Permanent Change of the Nucleotide Sequence
1:01
Insertions or Deletions (INDELS)
1:22
Classes of DNA Mutations
1:50
Spontaneous Mutations
2:00
Induced Mutations
2:33
Spontaneous Mutations
3:21
Tautomerism
3:28
Depurination
4:09
Deamination
4:30
Slippage
5:44
Induced Mutations - Causes
6:17
Chemicals
6:24
Radiation
7:46
Example 1
8:30
DNA Mutations - Tobacco Smoke
9:59
Covalent Adduct Between DNA and Benzopyrene
10:02
Benzopyrene
10:20
DNA Mutations - UV Damage
12:16
Oxidative Damage from UVA
12:30
Thymidine Dimer
12:34
Example 2
13:33
DNA Mutations - Diseases
17:25
DNA Repair
18:28
Mismatch Repair
19:15
How to Recognize Which is the Error: Recognize Parental Strand
22:23
Example 3
26:54
DNA Repair
32:45
Damage Reversal
32:46
Base-Excision Repair (BER)
34:31
Example 4
36:09
DNA Repair
45:43
Nucleotide Excision Repair (NER)
45:48
Nucleotide Excision Repair (NER) - E.coli
47:51
Nucleotide Excision Repair (NER) - Eukaryotes
50:29
Global Genome NER
50:47
Transcription Coupled NER
51:01
Comparing MMR and NER
51:58
Translesion Synthesis (TLS)
54:40
Not Really a DNA Repair Process, More of a Damage Tolerance Mechanism
54:50
Allows Replication Past DNA Lesions by Polymerase Switching
55:20
Uses Low Fidelity Polymerases
56:27
Steps of TLS
57:47
DNA Repair
1:00:37
Recombinational Repair
1:00:54
Caused By Ionizing Radiation
1:00:59
Repaired By Three Mechanisms
1:01:16
Form Rarely But Catastrophic If Not Repaired
1:01:42
Non-homologous End Joining Does Not Require Homology To Repair the DSB
1:03:42
Alternative End Joining
1:05:07
Homologous Recombination
1:07:41
Example 5
1:09:37
Homologous Recombination & Site-Specific Recombination of DNA

1h 14m 27s

Intro
0:00
Lesson Overview
0:16
Homologous Recombination
0:49
Genetic Recombination in Which Nucleotide Sequences Are Exchanged Between Two Similar or Identical Molecules of DNA
0:57
Produces New Combinations of DNA Sequences During Meiosis
1:13
Used in Horizontal Gene Transfer
1:19
Non-Crossover Products
1:48
Repairs Double Strand Breaks During S/Gs
2:08
MRN Complex Binds to DNA
3:17
Prime Resection
3:30
Other Proteins Bind
3:40
Homology Searching and subsequent Strand Invasion by the Filament into DNA Duplex
3:59
Holliday Junction
4:47
DSBR and SDSA
5:44
Double-Strand Break Repair Pathway- Double Holliday Junction Model
6:02
DSBR Pathway is Unique
6:11
Converted Into Recombination Products by Endonucleases
6:24
Crossover
6:39
Example 1
7:01
Example 2
8:48
Double-Strand Break Repair Pathway- Synthesis Dependent Strand Annealing
32:02
Homologous Recombination via the SDSA Pathway
32:20
Results in Non-Crossover Products
32:26
Holliday Junction is Resolved via Branch Migration
32:43
Example 3
34:01
Homologous Recombination - Single Strand Annealing
42:36
SSA Pathway of HR Repairs Double-Strand Breaks Between Two Repeat Sequences
42:37
Does Not Require a Separate Similar or Identical Molecule of DNA
43:04
Only Requires a Single DNA Duplex
43:25
Considered Mutagenic Since It Results in Large Deletions of DNA
43:42
Coated with RPA Protein
43:58
Rad52 Binds Each of the Repeated Sequences
44:28
Leftover Non-Homologous Flaps Are Cut Away
44:37
New DNA Synthesis Fills in Any Gaps
44:46
DNA Between the Repeats is Always Lost
44:55
Example 4
45:07
Homologous Recombination - Break Induced Replication
51:25
BIR Pathway Repairs DSBs Encountered at Replication Forks
51:34
Exact Mechanisms of the BIR Pathway Remain Unclear
51:49
The BIR Pathway Can Also Help to Maintain the Length of Telomeres
52:09
Meiotic Recombination
52:24
Homologous Recombination is Required for Proper Chromosome Alignment and Segregation
52:25
Double HJs are Always Resolved as Crossovers
52:42
Illustration
52:51
Spo11 Makes a Targeted DSB at Recombination Hotspots
56:30
Resection by MRN Complex
57:01
Rad51 and Dmc1 Coat ssDNA and Promote Strand Invasion and Holliday Junction Formation
57:04
Holliday Junction Migration Can Result in Heteroduplex DNA Containing One or More Mismatches
57:22
Gene Conversion May Result in Non-Mendelian Segregation
57:36
Double-Strand Break Repair in Prokaryotes - RecBCD Pathway
58:04
RecBCD Binds to and Unwinds a Double Stranded DNA
58:32
Two Tail Results Anneal to Produce a Second ssDNA Loop
58:55
Chi Hotspot Sequence
59:40
Unwind Further to Produce Long 3 Prime with Chi Sequence
59:54
RecBCD Disassemble
1:00:23
RecA Promotes Strand Invasion - Homologous Duplex
1:00:36
Holliday Junction
1:00:50
Comparison of Prokaryotic and Eukaryotic Recombination
1:01:49
Site-Specific Recombination
1:02:41
Conservative Site-Specific Recombination
1:03:10
Transposition
1:03:46
Transposons
1:04:12
Transposases Cleave Both Ends of the Transposon in Original Site and Catalyze Integration Into a Random Target Site
1:04:21
Cut and Paste
1:04:37
Copy and Paste
1:05:36
More Than 40% of Entire Human Genome is Composed of Repeated Sequences
1:06:15
Example 5
1:07:14
Section 4: Gene Expression
Transcription

1h 19m 28s

Intro
0:00
Lesson Overview
0:07
Eukaryotic Transcription
0:27
Process of Making RNA from DNA
0:33
First Step of Gene Expression
0:50
Three Step Process
1:06
Illustration of Transcription Bubble
1:17
Transcription Starting Site is +1
5:15
Transcription Unit Extends From the Promoter to the Termination Region
5:40
Example 1
6:03
Eukaryotic Transcription: Initiation
14:27
RNA Polymerase II Binds to TATA Box to Initiate RNA Synthesis
14:34
TATA Binding Protein Binds the TATA Box
14:50
TBP Associated Factors Bind
15:01
General Transcription Factors
15:22
Initiation Complex
15:30
Example 2
15:44
Eukaryotic Transcription
17:59
Elongation
18:07
FACT (Protein Dimer)
18:24
Eukaryotic Transcription: Termination
19:36
Polyadenylation is Linked to Termination
19:42
Poly-A Signals Near the End of the pre-mRNA Recruit to Bind and Cleave mRNA
20:00
Mature mRNA
20:27
Dissociate from Template DNA Strand
21:13
Example 3
21:53
Eukaryotic Transcription
25:49
RNA Polymerase I Transcribes a Single Gene That Encodes a Long rRNA Precursor
26:14
RNA Polymerase III Synthesizes tRNA, 5S rRNA, and Other Small ncRNA
29:11
Prokaryotic Transcription
32:04
Only One Multi-Subunit RNA Polymerase
32:38
Transcription and Translation Occurs Simultaneously
33:41
Prokaryotic Transcription - Initiation
38:18
Initial Binding Site
38:33
Pribnox Box
38:42
Prokaryotic Transcription - Elongation
39:15
Unwind Helix and Expand Replication Bubble
39:19
Synthesizes DNA
39:35
Sigma 70 Subunit is Released
39:50
Elongation Continues Until a Termination Sequence is Reached
40:08
Termination - Prokaryotes
40:17
Example 4
40:30
Example 5
43:58
Post-Transcriptional Modifications
47:15
Can Post Transcribe your rRNA, tRNA, mRNA
47:28
One Thing In Common
47:38
RNA Processing
47:51
Ribosomal RNA
47:52
Transfer RNA
49:08
Messenger RNA
50:41
RNA Processing - Capping
52:09
When Does Capping Occur
52:20
First RNA Processing Event
52:30
RNA Processing - Splicing
53:00
Process of Removing Introns and Rejoining Exons
53:01
Form Small Nuclear Ribonucleoproteins
53:46
Example 6
57:48
Alternative Splicing
1:00:06
Regulatory Gene Expression Process
1:00:27
Example
1:00:42
Example 7
1:02:53
Example 8
1:09:36
RNA Editing
1:11:06
Guide RNAs
1:11:25
Deamination
1:11:52
Example 9
1:13:50
Translation

1h 15m 1s

Intro
0:00
Lesson Overview
0:06
Linking Transcription to Translation
0:39
Making RNA from DNA
0:40
Occurs in Nucleus
0:59
Process of Synthesizing a Polypeptide from an mRNA Transcript
1:09
Codon
1:43
Overview of Translation
4:54
Ribosome Binding to an mRNA Searching for a START Codon
5:02
Charged tRNAs will Base Pair to mRNA via the Anticodon and Codon
5:37
Amino Acids Transferred and Linked to Peptide Bond
6:08
Spent tRNAs are Released
6:31
Process Continues Until a STOP Codon is Reached
6:55
Ribosome and Ribosomal Subunits
7:55
What Are Ribosomes?
8:03
Prokaryotes
8:42
Eukaryotes
10:06
Aminoacyl Site, Peptidyl tRNA Site, Empty Site
10:51
Major Steps of Translation
11:35
Charing of tRNA
11:37
Initiation
12:48
Elongation
13:09
Termination
13:47
“Charging” of tRNA
14:35
Aminoacyl-tRNA Synthetase
14:36
Class I
16:40
Class II
16:52
Important About This Reaction: It Is Highly Specific
17:10
ATP Energy is Required
18:42
Translation Initiation - Prokaryotes
18:56
Initiation Factor 3 Binds at the E-Site
19:09
Initiation Factor 1 Binds at the A-Site
20:15
Initiation Factor 2 and GTP Binds IF1
20:50
30S Subunit Associates with mRNA
21:05
N-Formyl-met-tRNA
22:34
Complete 30S Initiation Complex
23:49
IF3 Released and 50S Subunit Binds
24:07
IF1 and IF2 Released Yielding a Complete 70S Initiation Complex
24:24
Deformylase Removes Formyl Group
24:45
Example 1
25:11
Translation Initiation - Eukaryotes
29:35
Small Subunit is Already Associated with the Initiation tRNA
29:47
Formation of 43S Pre-Initiation Complex
30:02
Circularization of mRNA by eIF4
31:05
48S Pre-Initiation Complex
35:47
Example 2
38:57
Translation - Elongation
44:00
Charging, Initiation, Elongation, Termination All Happens Once
44:14
Incoming Charged tRNA Binds the Complementary Codon
44:31
Peptide Bond Formation
45:06
Translocation Occurs
46:05
tRNA Released
46:51
Example 3
47:11
Translation - Termination
55:26
Release Factors Terminate Translation When Ribosomes Come to a Stop Codon
55:38
Release Factors Are Proteins, Not tRNAs, and Do Not Carry an Amino Acid
55:50
Class I Release Factors
55:16
Class II Release Factors
57:03
Example 4
57:40
Review of Translation
1:01:15
Consequences of Altering the Genetic Code
1:02:40
Silent Mutations
1:03:37
Missense Mutations
1:04:24
Nonsense Mutations
1:05:28
Genetic Code
1:06:40
Consequences of Altering the Genetic Code
1:07:43
Frameshift Mutations
1:07:55
Sequence Example
1:08:07
Section 5: Gene Regulation
Gene Regulation in Prokaryotes

45m 40s

Intro
0:00
Lesson Overview
0:08
Gene Regulation
0:50
Transcriptional Regulation
1:01
Regulatory Proteins Control Gene Expression
1:18
Bacterial Operons-Lac
1:58
Operon
2:02
Lactose Operon in E. Coli
2:31
Example 1
3:33
Lac Operon Genes
7:19
LacZ
7:25
LacY
7:40
LacA
7:55
LacI
8:10
Example 2
8:58
Bacterial Operons-Trp
17:47
Purpose is to Produce Trptophan
17:58
Regulated at Initiation Step of Transcription
18:04
Five Genes
18:07
Derepressible
18:11
Example 3
18:32
Bacteriophage Lambda
28:11
Virus That Infects E. Coli
28:24
Temperate Lifecycle
28:33
Example 4
30:34
Regulation of Translation
39:42
Binding of RNA by Proteins Near the Ribosome- Binding Site of the RNA
39:53
Intramolecular Base Pairing of mRNA to Hide Ribosome Binding Site
40:14
Post-transcriptional Regulation of rRNA
40:35
Example 5
40:08
Gene Regulation in Eukaryotes

1h 6m 6s

Intro
0:00
Lesson Overview
0:06
Eukaryotic Transcriptional Regulations
0:18
Transcription Factors
0:25
Insulator Protein
0:55
Example 1
1:44
Locus Control Regions
4:00
Illustration
4:06
Long Range Regulatory Elements That Enhance Expressions of Linked Genes
5:40
Allows Order Transcription of Downstream Genes
6:07
(Ligand) Signal Transduction
8:12
Occurs When an Extracellular Signaling Molecule Activates a Specific Receptor Located on the Cell
8:19
Examples
9:10
N F Kappa B
10:01
Dimeric Protein That Controls Transcription
10:02
Ligands
10:29
Example 2
11:04
JAK/ STAT Pathway
13:19
Turned on by a Cytokine
13:23
What is JAK
13:34
What is STAT
13:58
Illustration
14:38
Example 3
17:00
Seven-Spanner Receptors
20:49
Illustration: What Is It
21:01
Ligand Binding That Is Activating a Process
21:46
How This Happens
22:17
Example 4
24:23
Nuclear Receptor Proteins (NRPs)
28:45
Sense Steroid and Thyroid Hormones
28:56
Steroid Hormones Bind Cytoplasmic NRP Homodimer
29:10
Hormone Binds NRP Heterodimers Already Present in the Nucleus
30:11
Unbound Heterodimeric NRPs Can Cause Deacetylation of Lysines of Histone Tails
30:54
RNA Interference
32:01
RNA Induced Silencing Complex (RISC)
32:39
RNAi
33:54
RISC Pathway
34:34
Activated RISC Complex
34:41
Process
34:55
Example
39:27
Translational Regulation
41:17
Global Regulation
41:37
Competitive Binding of 5 Prime CAP of mRNA
42:34
Translation-Dependent Regulation
44:56
Nonsense Mediated mRNA Decay
45:23
Nonstop Mediated mRNA Decay
46:17
Epigenetics
48:53
Inherited Patterns of Gene Expression Resulting from Chromatin Alteration
49:15
Three Ways to Happen
50:17
DNA Sequence Does Not Act Alone in Passing Genetic Information to Future Generations
50:30
DNA Methylation
50:57
Occurs at CpG Sites Via DNA Methyltransferase Enzymes
50:58
CpG Islands Are Regions with a High Frequency of CpG Sites
52:49
Methylation of Multiple CpG Sites Silence Nearby Gene Transcription
53:32
DNA Methylation
53:46
Pattern Can Be Passed to Daughter Cells
53:47
Prevents SP1 Transcription Factors From Binding to CpG Island
54:02
MECP2
54:10
Example 5
55:27
Nucleosomes
56:48
Histone Core
57:00
Histone Protein
57:03
Chromosome Condensation Via J1
57:32
Linker Histone H1
57:33
Compact DNA
57:37
Histone Code
57:54
Post-translational Modifications of N-Terminal Histone Tails is Part of the Epigenetic Code
57:55
Phosphorylation, Acetylation, Methylation, Ubiquitination
58:09
Example 6
58:52
Nucleosome Assembly
59:13
Duplication of DNA Requires Duplication of Histones by New Protein Synthesis
59:14
Old Histones are Recycled
59:24
Parental H3-H4 Tetramers
58:57
Example 7
1:00:05
Chromatin Remodeling
1:01:48
Example 8
1:02:36
Transcriptionally Repressed State
1:02:45
Acetylation of Histones
1:02:54
Polycomb Repressors
1:03:19
PRC2 Protein Complex
1:03:38
PRC1 Protein Complex
1:04:02
MLL Protein Complex
1:04:09
Section 6: Biotechnology and Applications to Medicine
Basic Molecular Biology Research Techniques

1h 8m 41s

Intro
0:00
Lesson Overview
0:10
Gel Electraophoresis
0:31
What is Gel Electraophoresis
0:33
Nucleic Acids
0:50
Gel Matrix
1:41
Topology
2:18
Example 1
2:50
Restriction Endonucleases
8:07
Produced by Bacteria
8:08
Sequence Specific DNA Binding Proteins
8:36
Blunt or Overhanging Sticky Ends
9:04
Length Determines Approximate Cleavage Frequency
10:30
Cloning
11:18
What is Cloning
11:29
How It Works
12:12
Ampicillin Example
12:55
Example 2
13:19
Creating a Genomic DNA Library
19:33
Library Prep
19:35
DNA is Cut to Appropriate Sizes and Ligated Into Vector
20:04
Cloning
20:11
Transform Bacteria
20:19
Total Collection Represents the Whole Genome
20:29
Polymerase Chain Reaction
20:54
Molecular Biology Technique to Amplify a Small Number of DNA Molecules to Millions of Copies
21:04
Automated Process Now
21:22
Taq Polymerase and Thermocycler
21:38
Molecular Requirements
22:32
Steps of PCR
23:40
Example 3
24:42
Example 4
34:45
Southern Blot
35:25
Detect DNA
35:44
How It Works
35:50
Western Blot
37:13
Detects Proteins of Interest
37:14
How It Works
37:20
Northern Blot
39:08
Detects an RNA Sequence of Interest
39:09
How It Works
39:21
Illustration Sample
40:12
Complementary DNA (cDNA) Synthesis
41:18
Complementary Synthesis
41:19
Isolate mRNA from Total RNA
41:59
Quantitative PCR (qPCR)
44:14
Technique for Quantifying the Amount of cDNA and mRNA Transcriptions
44:29
Measure of Gene Expression
44:56
Illustration of Read Out of qPCR Machine
45:23
Analysis of the Transcriptome-Micrarrays
46:15
Collection of All Transcripts in the Cell
46:16
Microarrays
46:35
Each Spot Represents a Gene
47:20
RNA Sequencing
49:25
DNA Sequencing
50:08
Sanger Sequencing
50:21
Dideoxynucleotides
50:31
Primer Annealed to a DNA Region of Interest
51:50
Additional Presence of a Small Proportion of a ddNTPs
52:18
Example
52:49
DNA Sequencing Gel
53:13
Four Different Reactions are Performed
53:26
Each Reaction is Run in a Lane of a Denaturing Polyacrylamide Gel
53:34
Example 5
53:54
High Throughput DNA Sequencing
57:51
Dideoxy Sequencing Reactions Are Carried Out in Large Batches
57:52
Sequencing Reactions are Carried Out All Together in a Single Reaction
58:26
Molecules Separated Based on Size
59:19
DNA Molecules Cross a Laser Light
59:30
Assembling the Sequences
1:00:38
Genomes is Sequenced with 5-10x Coverage
1:00:39
Compare Genomes
1:01:47
Entered Into Database and the Rest is Computational
1:02:02
Overlapping Sequences are Ordered Into Contiguous Sequences
1:02:17
Example 6
1:03:25
Example 7
1:05:27
Section 7: Ethics of Modern Science
Genome Editing, Synthetic Biology, & the Ethics of Modern Science

45m 6s

Intro
0:00
Lesson Overview
0:47
Genome Editing
1:37
What is Genome Editing
1:43
How It Works
2:03
Four Families of Engineered Nucleases in Use
2:25
Example 1
3:03
Gene Therapy
9:37
Delivery of Nucleic Acids Into a Patient’s Cells a Treatment for Disease
9:38
Timeline of Events
10:30
Example 2
11:03
Gene Therapy
12:37
Ethical Questions
12:38
Genetic Engineering
12:42
Gene Doping
13:10
Synthetic Biology
13:44
Design and Manufacture of Biological Components That Do Not Exist in Nature
13:53
First Synthetic Cell Example
14:12
Ethical Questions
16:16
Stem Cell Biology
18:01
Use Stem Cells to Treat or Prevent Diseases
18:12
Treatment Uses
19:56
Ethical Questions
20:33
Selected Topic of Ethical Debate
21:30
Research Ethics
28:02
Application of Fundamental Ethical Principles
28:07
Examples
28:20
Declaration of Helsinki
28:33
Basic Principles of the Declaration of Helsinki
28:57
Utmost Importance: Respect for the Patient
29:04
Researcher’s Duty is Solely to the Patient or Volunteer
29:32
Incompetent Research Participant
30:09
Right Vs Wrong
30:29
Ethics
32:40
Dolly the Sheep
32:46
Ethical Questions
33:59
Rational Reasoning and Justification
35:08
Example 3
35:17
Example 4
38:00
Questions to Ponder
39:35
How to Answer
40:52
Do Your Own Research
41:00
Difficult for People Outside the Scientific Community
41:42
Many People Disagree Because They Do Not Understand
42:32
Media Cannot Be Expected to Understand Published Scientific Data on Their Own
42:43
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